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User`s Manual - AYA Instruments

1. THD of V amp 1 Unbalnce factor of V amp I Phase Voltage 1 V2 V3 Vinavg e e e e line Voltage 12 V23 V31 Vilavg e e e e Current 11 12 13 In lavg e e e e Power P1 P2 P3 Psum e e e e REAL TIME Reactive Power Q1 Q2 Q3 Qsum e e e e METERING Apparent Power 51 52 3 Ssum e e e e Power Factor PF1 PF2 PF3 PF e e e e METERING Frequency F e e e e Load Features Load Features e e e e Four Quadrant Powers Four Quadrant Powers e e e e Energy Ep_imp Ep_exp Ep_total Ep_net e e e e ENERGY Reactive Energy Eq imp Eq exp Eq total Eq net e e e e DEMAND Apparent Energy Es e e e e Demand Dmd P Dmd Q Dmd S Dmd 11 x Dmd 12 Dmd I3 TIME OF USE Energy max demand Ee 12 Seasons 14 e DAYLIGHT SAVING wo formats adjust Month Day Hour Minute Month TIME Week First few weeks Hour Minute naana e age Maral unge S pr Unbalance U unbl P Current Unbalance unbl m m Factor oltage THD THD_V1 THD_V2 THD_V3 THD_Vavg e e e e MoNITORING POWER QUALITY Current THD HD 1 THD 12 THD THD_lavg e e e e Individual Harmonics Harmonics 2 to 63 e e e e oltage CrestFactor Crest Factor e e e e IF THFF e e e e Current K factor Factor e e e e a Each phase of V amp I Total of P Q S STATISTICS N ripe PF amp did of PQ amp S Each m
2. 3 2LL 3CT LINE BC 1AFUSE D 4 is i k o Terminal block o 66060 Vn V3 V2 V1 d 2 i7 Hoz Acuvim II e LOAD Fig 2 18 2LL 3CT 4 2LL 2CT LINE A BC 1AFUSE X i if Terminal block IL Q 0000 f Vs V3 v2 vi V Quia 121 Acuvim Il e O2 an 1 2 132 LOAD 26 Fig 2 19 2LL 2CT 5 1LN 1CT Wiring mode setting 1LN 1CT LINE A N 1A FUSE Acmin I Seriu Terminal block come LOAD Acuvim II Fig 2 20 Single phase 2Lines 6 1LL 2CT Wiring mode setting 1LL 2CT LINE A N B 1AFUSE La Terminal block I on 60600 VW V3 V2 vi EI G2 cme LOAD G 121 Acuvim II Fig 2 21 Single phase 3Lines fawim I Series 2 3 6 Communication Acuvim II series meter uses RS485 serial communication and the Modbus RTU protocol The terminals of communication are A B and S 14 15 16 A is differential signal B is differential signal and S is connected to the shield of the twisted pair cables Up to 32 devices can be connnected on a RS485 bus Use good quality shielded twisted pair cable AWG22 0 5mm or higher The overall length of the RS485 cable connecting all devices should not exceed 1200m 4000ft The Acuvim II series meter is used as a slave device of masters such as a PC
3. 139 5 3 ProfiBus Module AXM PRO 177 5 4 RS485 Module AXM RS485 194 Chapter 6 Communication 199 6 1 Modbus Protocol Introduction 200 6 2 Communication Format 6 3 Data Address Table and Application Details 208 6 3 1 System Parameter Setting 210 6 3 2 System Status Parameter 212 6 3 3 Date and Time Table 214 6 3 4 Over Under Limit Alarming Setting 214 6 3 5 I O Modules Settings 217 6 3 6 Metering Parameter Address Table 224 6 3 7 Data Logging 238 6 3 8 Time of Use TOU 247 Appedix 275 Congratulations You have purchased an advanced versatile multifunction power meter This meter can work as a remote terminal unit RTU that contributes to your system s stability and
4. uud Top View ood Bottom View 179 awim T Series fawim I Series 180 Side View 5 3 4 Installation Method PROFIBUS is linked to Acuvim Il meter by communication plug It can also be linked to other extended modules such as IO modules 1 Insert the installation clips to the counterpart of Acuvim II meter and then press the PROFIBUS module lightly so linking is established 2 Tighten the installation screws Note 1 Install IO Modules carefully to avoid damage 2 Under no circumstances should any installation be done with the meter powered on Failure to do so may result in injury or death 5 3 5 Definition of DP Interface The PROFIBUS module uses standard 9 pin D type connector to access PROFIBUS network The mechanical and electrical characteristics of connector are consistent with the requirements of IEC 807 3 The connector of PROFIBUS is a socket and the counterpart connector of cable is a plug Connector pins are distributed as follows Pins RS 485 ID Content Used by PROFIBUS 1 SHIELD Power GND NO 2 N24V 24V Output NO 3 B RXD TXD P Data P Receive Send YES 4 CNTR P Controlling P YES 5 C DGND Digital Ground YES 6 Vp Positive Voltage YES 7
5. A 4 20mA odule 1 AXMHO2 quj Analog Output Type B 0 20mA C 1 5V D 0 5V Module 2 A 4 20mA fa Analog Output Type B 0 20mA C1 5V D 0 5V Module A 4 20mA AXMHOS luf Analog Input Type B 0 20mA C 1 5V D 0 5V Module A 4 20mA E Analog Input Type B 0 20mA C 1 5V D 0 5V IO Module Ordering Example AXM IO2 1A Remote Display Option 282 DS2 Compatible with Acuvim II Series M DIN Mount models only 1 No more than 2 of the same I O modules may be attached to the meter example 2 AXM IO2 The same two I O modules must be a different component number Communication Option Module F NET Ethernet Module AXM NET AXM 7 3 PROFI Profibus Module AXM PROFI L RS485 Modbus RTU AXM RS485 Acuovine I Series Note 2 A maximum of 3 modules may be attached to the meter If a communication module is used example AXM NET it must be installed on the back of the meter FIRST before the other modules are attached 3 If you select Acuvim IIW products and prepared to use DI recorder func tion then select the IO module can only select logic number 1module fawim I Series Appendix C Revision History 1 0 20070915 First version P47 change the flow chart P86 change value of address 101dH from Reserved to Basic parameter mode 1 1
6. 3 3 Statistics Data 3 4 Demand Data 9 3 5 Harmonic Data nnn nnn 3 6 Expanded I O Module Data _ _ _ _ _ __ __ _ 3 7 Parameter Settings Mode 3 8 Page Recovery Function Chapter 4 Detailed Functions and Software 4 1 Basic Analog Measurements 4 2 Max Min o ooo eoe fawim I Series 4 3 Harmonics and Power Quality Analysis 68 4 4 Over Under Limit Alarming 69 4 5 Data Logging 9 77 4 6 Time of Use TOU 83 4 7 Power Quality Event Logging and Waveform Capture 89 4 8 Seal Function Chapter 5 Extended Modules 5 1 IO Modules 5 2 Ethernet Module AXM NET
7. 7800H 78021 format month day schedule word RAW 7B03H 7B05H The 2 holiday and schedule word R W 7B06H 7B08H The 3 holiday and schedule word 7B09H 7BOBH The 4 holiday and schedule word 7BOCH 7BOEH The 5 holiday and schedule word 7BOFH 7B11H The 6 holiday and schedule word 7B12H 7B14H The 7 holiday and schedule word 7B15H 7B17H The 8 holiday and schedule word 7B18H 7B1AH The 9 holiday and schedule word 7B1BH 7B1DH The 10 holiday and schedule word 7B1EH 7B20H The 11 holiday and schedule word 7B21H 7B23H The 12 holiday and schedule word 7B24H 7B26H The 13 holiday and schedule word 7B27H 7B29H The 14 holiday and schedule word 7B2AH 7B2CH The 15 holiday and schedule word 7B2DH 7B2FH The 16 holiday and schedule word 7B30H 7B32H The 17 holiday and schedule word 7B33H 7B35H The 18 holiday and schedule word 7B36H 7B38H The 19 holiday and schedule word 7B39H 7B3BH The 20 holiday and schedule word 7B3CH 7B3EH The 21 holiday and schedule word 7B3FH 7B41H The 22 holiday and schedule word 7B42H 7B44H The 23 holiday and schedule word 7B45H 7B47H The 24 holiday and schedule word 7B48H 7B4AH The 25 holiday and schedule word 7B4BH 7B4DH The 26 holiday and schedule word 7B4EH 7B50H The 27 holiday and schedule word 7B51H 7B53H The 28 holiday and schedule word 7B54H 7B56H The 29 holiday and schedule word Acuvisn I Sven Laman Series A 260 The 1 holida
8. 5 1 3 Appearance and Dimensions 90 00 4G P MES LUE 55 60 O ooooo0000O000Q O 19 50 Enclosure Installation screw Wiring Terminals Counterpart of clip OOC Linking pins Installation clip QOO C Linking socket Fig 2 1 Dimensions 5 1 4 Installation Method Environment Please verify the installation environment meets the requirements listed as follows 111 Bee I Seru follows I Series delete this Temperature Operation 25 C to 70 C Storage 40 C to 85 C Humidity LAMAN A 5 to 95 non condensing Location The Acuvim II meter and IO modules should be installed in a dry and dust free environment avoiding heat radiation and high electrical noise sources Installation Method With the link pins IO modules are linked to the meter and to each other The maximum number of extended modules linked to Acuvim II meter including 10 module Ethernet module Profibus module RS 485 module and BACnet module is three The communication modules must be installed first No other module can be installed before them 1 Insert the installation clips to the counterpart of Acuvim Il meter and then press the IO module lightly so linking is established 2 Tighten the installation screws 3
9. V 1 P Q S PF V_THD amp I THD each Over Under Limit phase and total or average ALARM Alarm Unbalance factor of V amp l load s itype Analog Input of each channel POWER QUALITY EVENT LOGGING SAG DIPS SWELL Voltage e F V1 2 3 Inavg V12 23 13 lavg 11 2 3 n avg P1 2 3 sum Q1 2 3 sum S1 2 3 sum PF1 2 3 PEU unbl I unbl Load Type Ep imp Data Logging 1 qi perde ana Eq_ B Data Logging Data Logging 2 imp Eq exp Eq total Eq net Es e e e OTHERS Data Logging 3 THD_V1 2 3 avg THD_11 2 3 avg Harmonics 2 to 63 Crest Factor THFF K Factor sequence and phase angles DI counter Al AO Dmd P Q S Dmd 11 2 3 ONBOARD MEMORY SIZE Memory Bytes 8MB 8MB 16MB RS485 Port Half COMMUNICATION Duplex Modbus RTU DNP3 0 Protocol e e e e Optical Isolated Year Month Date Hour Minute TIME Real Time Clock Second e e e e Switch Status DI Digital Input Wet o o e o Power Supply for DI 24Vdc e e o Relay Output RO NO Form A 1 0 OPTION Digital Output DO Photo MOS e e Pulse Output PO By using DO o o Analog Input Al 0 4 20mA 0 1 5V Sms g Input Al 4 1 e e e MODULE Analog Output AO 0 4 20mA 0 1 5V o o o Ethernet Modbus TCP HTTP SNMP SMTP SNTP S 2 9 Profibus DP Profibus DP VO COMMUNICATION Fr 7 ale lele e second way 3 RS485 Module Modbus RTU Protocol o e e o BACnet IP or MS TP Function Option Blank
10. Aawinm I Series Operating Range 20 60Vdc Burden 5W 1 0 Option Input Voltage Range 20 160Vac dc Voltage Range Input Current Max 2mA Start Voltage 15V Stop Voltage 5V Pulse Frequency Max 100Hz 50 Duty Ratio SOE Resolution 2ms 0 250Vac dc Load Current 100mA Max Output Frequency 25Hz 5096 Duty Ratio Isolation Voltage 2500Vac Switching Voltage Max 250Vac 30Vdc Load Current 5A R 2A L Set Time 10ms Max Contact Resistance 30mO Max Isolation Voltage 2500Vac Mechanical Life 1 5x10 Output Range 0 5V 1 5V 0 20mA 4 20mA Optional Accuracy 0 596 Temperature Drift 50ppm C typical Isolation Voltage 500Vdc Open Circuit Voltage 15V Input Range 0 5V 1 5V 0 20mA 4 20mA Optional Accuracy 0 296 Temperature Drift 50ppm C typical Isolation Voltage 500Vdc Output Voltage 24Vdc Output Current 42mA Load Max 21Dls Dimensions mm 96x96x51 Cut out 92x92 or 4 inch Round Protection Level IP54 Front IP30 Cover Weight g 350g Temperature 25 C 70 C Metering 40 C 85 C Storage Humidity 5 95 Non condensing 100 415Vac 50 60Hz 100 300Vdc Power Supply Category Ill Pollution degree 2 Power Consumption 5W Measurement Standard IEC 62053 22 ANSI C12 20 Environmental Standard IEC 60068 2 Safety Standard
11. Quantity of registers indicates how many words will be written Byte count indicates how many bytes will be written If quantity of register is N then byte count is Nx2 It is important to note the response has a 16 word frame so the maximum quantiy of registers should be less than 13 Otherwise it will return an error result Response The normal response returns the function code starting address and quantity of registers written 3 Byte1 FAH Byte2 10H 4 Byte3 starting address high byte Byte4 starting address low byte 3 Byte5 quantity of registers high byte Byte6 quantity of registers low byte Byte7 32 0 Example presetting import active enengy EP imp to 17807783 3Kwh Based on the relationship between the register value and the physical value we can get that the register value in hex is 0A9D4089H The data address of EP imp includes 4048H and 4049H Query FAH 10H 40H 48H 00H 02H 04H OAH Response FAH 10H 40H 48H 00H 02H 00H Example Projects To facilitate your understanding of the PROFIBUS module we have developed a PLC based DEMO engineering application program Please read DEMO procedure documentation for the specific information This DEMO is available upon request please call Technical Support 5 4 RS485 Module AXM 485 5 4 1 Communication Parameters Setting RS485 also known as EIA 485 is a telecommunications standard fo
12. 55 6mm Side View 90mm X O O v Top View o Beeuknes I Serin oooooooo oooooo00 Bottom View 5 2 4 Installation Method The Ethernet module is linked to the Acuvim Il meter by a communication plug It can also be linked to other extended modules like IO modules 1 Insert the installation clips to the counterpart of the meter and then press the Ethernet module lightly so linking is established 2 Tighten the installation screws fawim I Series 142 Note 1 Install Ethernet Module carefully to avoid damage 2 Under no circumstances should any installation be done with the meter powered on Failure to do so may result in injury or death 5 2 5 Definition of RJ45 Interface The Ethernet module uses a standard RJ45 connector to access the Ethernet network The mechanical and electrical characteristics of the connectors comply with the requirements of IEC 603 7 LED L Top View Script ID Content 1 TX Tranceive Data 2 TX Tranceive Data 3 RX Receive Data 4 n c Not connected 5 n c Not connected 6 RX Receive Data 7 n c Not connected 8 n c Not connected LED L yellow displays speed status LED on indicates 100Mbps while LED off indicates 10Mbps LED R green displays link and activity status combined LED on indicates link status while flashing LED indicates activity status 5 2 6 Cable Shield
13. BaudRate 19200 bps Parity None v Wiring PT and CT Ratios Voltage 3LN x PT1 400 0 Current 3CT x PT2 400 0 z Real Time Reading v tcn 4250 A Secondary v cr2 333 my C Primary 1 C Directiorr MIA Direction 1 B Direction Positive C Negative le Positive C Negative le Positive C Negative r Security Demand Type Demand Password 0000 ff Sliding Window Demand Averaging Interval Window 15 min C Thermal Demand MDO Energy Pulse Const m Other Watt 60000 Pulse kwh Tum On the Backlight 1 min var 8000 Pulse kvarh J p Energy Type Energy Reading VAR PF Convention M VAR Calculation Method C Fundamental Primary IEC Method 1 True Fund Harm Secondary C IEEE C Method 2 Generalized SUE Enabled C None C AXM4011 C AXMIO21 C AXMJO031 AXMJO12 C AXM4022 C AXM4032 Non Standard Seal Options of Seals Device Run Time DI Counters Device Clock TOU Related Communication Channel 1 Communication Channel 2 Update Device Fig 5 19 parameter setting of DO energy pulse constant 131 Acwin I Serin len Series A 5 1 10 Analog Output 1 Analog Output Relationship with Electrical Quantities The analog output circuit can convert anyone of 30 electrical quantities reference Chapter 6 which is selected by
14. Relay status Function code 01H for reading 05H for controlling output AXM IO11 0000H Relay1 ON 0 OFF bit 0001H Relay2 ON 0 OFF bit AXM IO31 0002H Relay3 ON 0 OFF bit 0003H Relay4 ON 0 OFF bit AXM IO12 0004H Relay5 ON 0 OFF bit 0005H Relay6 ON 0 OFF bit AXM IO32 0006H Relay7 ON 0 OFF bit 0007H Relay8 ON 0 OFF bit 6 3 7 Data Logging Data Logging Setting In order to generate historical logs for the selected parameters users should program the meter so that selected parameters from the cooresponding Modbus registers can be copied to the historical log record Since certain parameters occupy two registers to supplement this the programmable settings for the historical logs contain a list of descriptors Each descriptor lists the number of Modbus registers for the specified parameter By combining these two lists the historical log record can be interpreted For example Registers 4002H and 4003H are programmed to be recorded by the historical log Since 2 registers are used the corresponding descriptor is set as 2 These registers program the log to record Volts AN The historical log programmable settings are comprised of 3 blocks one for each log Each log works identical to each other therefore only historical log 1 is described here All register addresses in this section are shown within the address range of historical log 1 1100H 11DFH Histor
15. Transaction Transaction Protoco Protocol enathihi L nathilo Unit identifier hi identiferlo identifierhi identifierlo 9 9 identifier 00H 00H 00H 00H 00H OBH 01H Fun Data start Data start Data of Data tof Byte Value1 Value1 Value2 Value2 reg hi reg lo regs hi regslo count hi lo hi lo 10H 10H 08H 00H 02H 04H 01H FAH 00H 05H Response The normal response to a preset Multi Register request includes MBAP Header function code data start register and the number of registers Table 5 14 Preset Multi Registers Response Message Niet Sot Transaction Transaction Protocol Protocol Lenath hi lenathil Unit identifier hi identifierlo identifierhi identifierlo SP9 M en9t to identifier 00H 00H 00H 00H 00H 06H 01H Fun Data start reg hi Data start reg lo Data of regs hi Data of regs lo 10H 10H 08H 00H 02H Users may refer to the sixth chapter Communication and get the details of Acuvim Il series meter When using Modbus TCP function it is best to set the Scan interval of the software to under 1000 ms When using Third Party software it is best to set Frame interval for the Modbus TCP function to under 1000 ms 5 2 11 Webpage Browsing and Parameter Settings The Ethernet module supports HTTP protocol and has a Web Server function making the Acuvim II series meter accessible through Ethernet at anytime from anywhere Aawin I
16. P24V 24V output NO 8 A RXD TXD N Data N Receive Send YES 9 CNTR N Controlling N NO Note Pin 4 is used for RTS controlling and TTL which is optional 5 3 6 Cable Shielded twisted pair cable is recommended as reference to the EIA RS 485 standard If the interference is within the EIA RS 485 standard then non shielded twisted pair cable can may be used 5 3 7 Bus Terminal Based on DP standard the first station and the last station in PROFIBUS DP network should connect bus terminal resistor and it is not necessary for other stations as shown in the figure below Bee Sema fawim I Series 182 STATION 3 STATION 4 PON P N Vp Vp ee gem pm m I 3o00 13900 i i i I P o OP 1 T 1 l I l i STATION 1 2200 2200 STATION 2 i 1 i I N o ON I 1 i 390 lon i I i eccl aero eeu DGND DGND Connection of many DP stations The bus terminal is composed of three resistors and connection wire where Vp is the supply positive voltage and DGND is the Digital Ground When the bus is idle the bus terminal makes the data P level higher than data N so the bus s idle signal is always 1 5 3 8 Address Setting The PROFIBUS module can only be used as a slave in the PROFIBUS network Its slave address ranges from 0 to 126 which can only be set by the front panel of the m
17. Bee Sexe hiro WLI o 8 50 D Load gt T Hn Li mx M2Axe x2 Fig 5 30 5 Set Subnet Mask in the third setting page such as 255 255 255 0 Press V A key to go to the setting page Users may set the parameters in the area pointed out in Figure 5 31 The cursor starts at the first digit After setting the Subnet Mask press the V A key to accept Press the P key again to go to the fourth setting page for Gateway JCtG Mj c2 gt aI CC E A TW See E 2 a TN D by d UEMAS 4 n x2 zx Bix2 wn Fig 5 31 148 6 Set Gateway in the fourth setting page such as 192 168 1 1 Press the V A key to go to the setting page Users may set the parameters pointed out in Figure 5 32 The cursor starts at the first digit After setting the Gateway press the V A key to accept Press the P key to go to the fifth setting page for DNS Primary Server Wig ILI o7 50 gp Load BATE WAY a x2 Mx M3ix2 su Fig 5 32 149 Beatos I Serier Pee I Series 7 Set DNS Primary Server in the fifth setting page such as 202 106 0 20 Press the V A key to go to the setting page Users may set the parameters pointed out in Figure 5 33 The cursor starts at the first digit After setting the DNS Primary Server press the V A key to accept Press the P key to go to the sixth setting page for DNS Secondary Server Note the DNS paramters must be set corre
18. O 00000kvar Dmd VA Total 0 00000 kVA Dmdl 0 0000 4 Dmd1B 0 0000 4 DmdlC 0 0000 A Fig 4 1 Real Time Metering Demand This meter consists of several types of demand calculation total active power demand total reactive power demand total apparent power demand phase A current demand phase B current demand and phase C current demand When demand is reset demand memory registers are set as 0 Demand calculating mode can be set as sliding window and thermal according to user The figure 4 7 shows how it works When using the sliding window interval method user selects an interval from 1 to 30 minutes which is the period of the calculation The demand updates every 1 minute as the window slides once Thermal demand method calculates the demand based on a thermal response which mimics a thermal demand meter User selects the period for the calculation and the demand updates at the end of each period Energy This meter measures and accumulates energy in different directions import and export For real time energy monitoring it accumulates energy for kWh kvarh and kVAh continuous since its last reset Calculating mode 1 User can select different energy calculating modes fundamental based or full wave based either from the meter front or via communication Fundamental based calculating is used to accumulate energy without taking harmonics into consideration while full wave based calculating is used to accumulate energy
19. 54 2500 kvar 2000 1 3 6 29 47 VA Total Demand 190 750kVA 2000 1 3 amp O00000kV 2013 5 22 13 42 49 Unbalance V 200 0 2000 1 1 1 39 24 00 2013522 134248 Unbalance 200 0 2000 1 1 0 12 32 00 2013522 134249 THD Volts AN AB 20 55 2000 1 3 6 42 38 0 00 2013 5 22 134249 THD Volts BN CA 10 59 2000 1 3 7 05 01 0 00 2013522 134248 THDVolsCN BC 18 26 2000 1 3 6 42 38 0 00 2013522 134249 THDIA 29 97 2000 1 3 6 32 27 0 00 2013 5 22 13 42 49 THD B 28955 2000 1 3 6 42 32 0 00 2013522 134248 THDIC 2387 2000 1 3 6 38 56 0 00 2013522 1342 00 1A Demand 167 25A 2000 1 3 6 19 47 1B Demand 167 254 2000 1 3 6 19 47 1 C Demand 167 254 2000 1 3 6 19 47 Reset Max and Min Fig 4 3 Max Min mane Series A 4 2 Max Min 4 3 Acuvim Il series meter logs maximum and minimum value statistics for phase line voltages current power reactive power apparent power power factor frequency demand unbalance factor THD as well as the time they occur All data is stored in non volatile memory so that statistic information can be preserved even when meter is shut off All maximum and minimum data can be accessed via communication or from the meter front but time stamps can only be accessed via communication Statistics can be cleared via communication or from the meter front Harmonics and Power Quality Analysis 1 Harmonics Acuvim II series meter can measure and analyze THD harmonics harmonics 2 to 63 ev
20. A Before triggering point 10 U1 waveforms 10 U2 waveforms 10 U3 waveforms 1011 waveforms 10 I2 waveforms 10 I3 waveforms After triggering point 10 U1 waveforms 10 U2 waveforms 10 U3 waveforms 10 11 waveforms 10 I2 waveforms 10 13 waveforms 2 Waveform Capture Group Waveform Capture can log up to 100 groups of waveform data When the 100 group data is full it does not respond to any waveform triggering condition Only when all the waveform data is reset emptied waveform capturing function will be normal When the waveform data is emptied new waveform data starts from the 1st group The waveform data will not be lost when the power is off Note since the amount of each waveform group data is large it takes more time to write into the flash memory Therefore Waveform Capture only responds to one triggering condition at one time During the process of writing data into the flash memory it does not respond to new triggering condition After the process of memory writing it will respond to new waveform triggering condition 3 Waveform Capture Triggering Condition 1 Manual Triggering Manually trigger one group waveform capture 2 DI Triggering DI Triggering must fulfill the following two conditions at the same time IO modules with the logical address of 1 AXM IO11 AXM IO21 AXM I031 DI channel type is set as State The Modbus address assigns two bits for the DI channel When they are set as 0
21. hITT C MLIO Kx Ho Exo Fig 5 38 13 After configuring AXM Net settings completely press H key and V A key simultaneously to return to menu selecting mode 5 2 9 Searching IP Address of Ethernet Module The utility software of Acuvim II series meter supports a meter search function Users can use this function to obtain IP and MAC addresses of Ethernet Modules Operation steps Acmin T Seriu 1 Click Start menu of utility software 2 Click Search Device menu ET Readings Settings Help 1 2 8 Ri Ro Ra E mB Er EEN N Ss S2 Sal Connect Connection Settings Volts AB 000v lA 0 00004 Ge CM Vols BC 000v 18 0 00004 Exit Vols CA 000v Ic 0 00004 J Voie TN Average 00V VolslLAveage 0 00 l Average 0 00004 Watt O0000KwW VARA O000kva VAA 0 00000 kVA Watt B 0 00000kW VARB 000000kvar VAB 0 00000 kVA Watc 0 00000 kW VARC 0 00000 kvar VAC 0 00000 kVA Watt Total 000000 kW VAR Total 0 00000 kvar VA Total 0 00000 kVA PwrFactorA 1000 Frequency 0 00 Hz Load Type R Pw FactorB 1000 IN 0 00004 PeFadoaC 1000 UnbslanceV 00x Pwr Factor Total 1 000 Unbalance 00x Dmd Watt Total 0 00000kwW md VAR Total 0 00000kvar DmdVA Total 0 00000 kVA Did A 0 0000 A DmdlB 0 00004 DmdlC 000004 Fig 5 39 155 3 Utility software pop ups Search Device s window and the window displays IP address and MAC address of module Eo Ene 1 2 10 f Fi Ro Fam BBs Eo BEN
22. 1032 AXM IO3 module in logic NO 2 in sequence One group of records is an unsigned long integer for example 4349H to 434aH registers record the number of pulses for DI1 circuit of AXM IO11 AXM IO1 module in logic NO 1 Figure 5 16 shows the recorded number of pulses read on screen hd i VEL T e 8 copes 50 ee AIUT L tl amp 700 Oo toa LiR3 mm HB Fig 5 16 recorded number of pulses read on the screen Figure 5 17 shows the recorded number of pulses read by the utility software Start Readings Settings Help Seb are 2868 B SEX T ea i Aawim I Seriu Relay 1 OFF Control Relay 2 OFF Control DII 4 DIZ 4 DI3 OFF DI4 OFF DIS OFF DIG OFF AXM I022 Dit ON DI2 ON DI3 OFF DI4 OFF AD 1 2 500V AD 2 2 500 V AXM 1032 Relay 1 OFF Control Relay2 ON Control Dit OFF DI2 OFF DI3 ON Di4 ON Alt 2052 Al2 2114 Fig 5 17 recorded number of pulses read by the utility software Parameter Settings for Counting Input Pulses Take AXM IO11 AXM IO1 module in logic NO 1 for example 1 109eH register if the bit is set as 1 the counterpart digital input circuit is set to be a counter of input pulses 2 109fH register this register is an unsigned integer If this register is A and the digital input circuit is set to be a pulse counter then the real number of pulses counted by this DI circuit will be as follows fa
23. 79BEH 79E7H and Tariff Number of the 10 d pams as word R W Schedule 1 schedule From 1 to 14 Segmen Th 79E8H 7A11H and Tariff Number of the 11 de Same as word R W schedule 1 schedule From 1 to 14 Segmen Th 7A12H 7A3BH and Tariff Number of the 12 de ES word R W schedule 1 schedule From 1 to 14 Segmen Th 7A3CH 7A65H and Tariff Number of the 13 ds Md word R W schedule 1 schedule From 1 to 14 Segmen The sameas 7A66H 7A8FH and Tariff Number of the 14 2 word R W 1 schedule schedule Holiday Setting da a and the schedule Of the 7A96H 7A98H rd word 7A90H 7A92H SEI word R W 1 holiday 7A93H 7A9SH data and the schedule Of the Word RW 2 holiday data and the schedule Of the R W 3 holiday 18 holiday 7A99H 7AOBH da a and the schedule Of the Word 4 holiday 7A9CH 7A9EH da a and the schedule Of the word 5 holiday JA9FH 7AA1H da aand the schedule Of the word 6 holiday JAA2H 7AAAH da a and the schedule Of the word 7 holiday JAASH 7AA7H da aand the schedule Of the Word 8 holiday JAABH 7AAAH da a and the schedule Of the word 9 holiday data and the schedule Of the 7AABH 7AADH 10 holiday word JAAEH 7ABOH data and the schedule Of the word 11 holiday data and the schedule Of the 7AB1H 7AB3H 12 holiday word data and the schedule Of the 7AB4H 7AB6H 13 holiday word data and the schedule Of the
24. 821 VAR PF Convention cR S22 energy clear ce S23 calculation method of reactive power Dj S24 energy type Dj S25 pulse counter clear ce S26 SOE enable Sy S27 Profibus address S S28 Basic Param eter m ode a 829 password ce 30 Parity Setting CE S31 Parity Setting2 To dear the Max and Min value does not mean write 0 to all the registers it wll copy the metering value to the statistic registers and start a new statistic period Yes clear No notdear To adjust polarity of current the three current s direction can be set as Negative which means reversing 180 degrees and Positive which means normal 0 IEC 1 IEEE Yes clear No notclear 0 true 1 generalized Q 5 P Pre primary energy Sec secondary energy Range from 0 6 0 not dear 1 AXMHO11 clear 2 AXM IO21 dear 3 AXMHOS1 clear 4 AXMHO 12 dear 5 AXM4O22 clear 6 AXM I032 clear Range from 0 6 0 disable 1 AXM IO11 enable 2 AXMJO 21 enable 3 AXM IO31 enable 4 AXM IO12 enable 5 AXM IO22 enable 6 AXMIO32 enable Any integer from 0 126 Pre prim ary basic param eters Sec secondary basic param eters R efer to page 102 Basic Analog M easurem ents for m ore details Last page of the system parameter setting Setthe password in this page and make sure to remember t
25. Acuvim II Series Power Meter User s Manual Wu AL LU Vy Copyright 2013 V2 01 This manual may not be altered or reproduced in whole or in part by any means without the expressed written consent of Accuenergy 3 8 A 1 The information contained in this document is believed to be accurate at the time of publication however Accuenergy assumes no responsibility for any errors which may appear here and reserves the right to make changes without notice Please ask the local representative for latest product specifications before ordering Document 1040E2201 Revision Date Jun 2013 aman Series A Please read this manual carefully before installation operation and maintenance of Acuvim Il series meter The following symbols in this manual and on Acuvim ll series meters are used to provide warning of danger or risk during the installation and operation of the meters Electric Shock Symbol Carries information about procedures which must be followed to reduce the risk of electric shock and danger to personal health gt gt Safety Alert Symbol Carries information about circumstances which if not considered may result in injury or death dus This mark indicates that this product is UL listed Installation and maintenance of the Acuvim II series meter should only be performed by qualified competent professionals who have received training and should have experience with high volta
26. address registers record 20 groups of SOE records 4439H records the IO module which generates the SOE records For example if register 4439H is 1 the 20 groups of SOE records are all generated by AXM IO11 AXM IO1 module in logic NO 1 The 20 groups of SOE records are arranged based on time When more than 20 groups of SOE records are generated the records will begin at the first one When the Acuvim Il meter is powered on the SOE begins to record immediately The data in the SOE records will not be lost if the meter is powered off When the enabled SOE function is changed the records will be lost All groups of SOE records are in the same format Take the first group of SOE records for example 4399H to 439fH registers record the time information including year month day hour minute second and millisecond 43a0H register records the state information which is an unsigned integer where bit 0 records DI1 state bit 1 records DI2 state and so on For example if 43a0H is 1 it means that DI1 is 1 and others are all 0 Acmin T Seriu Note If one of digital input circuits is set to be a pulse counter when the IO module is SOE enabled then the counterpart bit of 43a0H register will always be 0 Data of SOE records can only be read by the utility software it cannot be read on screen Figure 5 14 shows the data information of SOE records of AXM IO12 AXM IO1 module in logic NO 2 read by the u
27. there is no phase C voltage or current to phase A voltage angle factor display d Energy Press E key to display energy and real time clock The screen will roll to the next page when E is pressed again It will go back to the first screen if you press E at the last screen Acuvim Il series meter can be set to record primary energy or secondary energy The unit of energy is kWh for active energy kvarh for reactive energy and kVAh for apparent energy The running time has a resolution of 0 01h The meter begins accumulating time upon initial powering up of the unit The accumulated time is stored in the non volatile memory It can be reset via communication or from the meter front The following figure shows the sequence CE y E Consumption energy Meter running hours D lt gt Generation energy Time hh mm ss E gt RES Total energy Date yyyy mm dd lt gt Ice Net energy Total electrical degree CE The absorption reactive energy Net reactive energy oy CE The generation Total reactive reactive energy energy CE Sharp Import energy gt Y Sharp Import max demand p Sharp Import max demand year month day Sharp Export energy A e gt 5 Sharp Import max demand hour min sec Sharp Export max demand Sharp import reactive energy ins Yy Sharp Export reactive energ
28. 0 999999999 Es sharp 723AH 723BH 0 999999999 723CH 723DH amp imp peak 0 999999999 0 999999999 0 999999999 0 999999999 723EH 723FH Ep exp peak 7240H 7241H Eq_imp peak 7242H 7243H Eq_exp peak 7244H 7245H s peak 0 999999999 7246H 7247H E impyvalley 0 999999999 7248H 7249H Ep exp valley 0 999999999 724AH 724BH Eq imp valley 0 999999999 724CH 724DH Eq_exp valley 0 999999999 Es valley 724EH 724FH 7250H 7251H 7252H 7253H 0 999999999 0 999999999 0 999999999 Ep_imp normal Ep_exp normal 7254H 7255H Eq imp normal 0 999999999 7256H 7257H Eq_exp normal 0 999999999 7258H 7259H Es normal 0 999999999 725AH 725BH Eb imp sum 0 999999999 725CH 725DH Ep exp sum 0 999999999 725EH 725FH Eq_imp sum 0 999999999 7260H 7261H Eq_exp sum 0 999999999 7262H 7263H Fs sum 0 999999999 The address area include the max of Ep imp Ep exp Eq im Eq exp Es Current demand and time stamp When tariff setting parameter is sharp peak valley and normal Function 03H Read Bee I Series Max of Ep_imp sharp demand and time stamp 7500H 503H format power year mon Day Hour Min 32 68 32767 int R Sec 7504H 7507H Max of Ep_exp sharp demand and time 32768 32767 Int R stamp 7508H 750bH Ma
29. 7AB7H 7AB9H 14 holiday word data and the schedule Of the 7ABAH 7ABCH 15 holiday word data and the schedule Of the 7ABDH 7ABFH 16 holiday word data and the schedule Of the 7ACOH 7AC2H 17 holiday word JAC3H 7ACSH data and the schedule Of the word Bee Sema iwim I Series A 258 JACGH 7AC8H data and he schedule Of the Word R W 19 holiday data and the schedule Of the 7AC9H 7ACBH 20 holiday word R W JACCH 7ACEH data and he schedule Of the word R W 21st holiday JACEH 7AD1H data and he schedule Of the word R W 22 holiday 7AD2H 7AD4H data and he schedule Of the Word R W 23 holiday data and the schedule Of the 7AD5H 7AD7H 24 holiday word R W data and the schedule Of the 7AD8H 7ADAH 25 holiday word R W data and the schedule Of the 7ADBH 7ADDH 26 holiday word R W data and the schedule Of the 7ADEH 7AEOH 27 holiday word R W data and the schedule Of the 7AE1H 7AE3H 28 holiday word R W data and the schedule Of the 7AE4H 7AE6H 29 holiday word R W data and the schedule Of the 7AE7H 7AE9H 30 holiday word R W 7AEAH Holiday setting enable word R W 7AEBH Start year holiday setting word R W 7AECH End year holiday setting word R W The address area include ten years holiday setting Function 03H Read 10H Preset Table 6 27 Data address of ten years holiday The 1 holiday and schedule
30. ALL types follow the same protocol With optimized high speed low cost communication links PROFIBUS DP is especially used in automatic controlling systems and equipment level decentralized O communication It can meet real time response stability and reliability of equipment level and distributed controlling systems The PROFIBUS module uses PROFIBUS DP VO protocol 5 3 2 PROFIBUS module application notes Please read appendix of technical data and specifications of PROFIBUS module before using it In addition please read the communication addresses of MODBUS protocol which are the communication addresses for the PROFIBUS Bee I Series 178 module as well The PROFIBUS module can only be used as slave in PROFIBUS network Its slave address ranges from 0 to 126 which can only be set by the panel If the address is changed it will take effect immediately The PROFIBUS module s baud rate can be adaptive between 9 6Kbps to 12Mbps in PROFIBUS network The PROFIBUS module terminals should be connected properly to avoid problems during installation Please read GSD file of the PROFIBUS module carefully before using The GSD file contains technial information such as device name ID number and so on Please read the communication data format thoroughly as this is a key point of the PROFIBUS module 5 3 3 Appearance and Dimensions 90mm 55 6mm 2
31. Mail To 2 Mail To 3 Subject Mail Server SMTP Server User Name Password Mail Content Triggered Sending Acuvim II Example Technical Support jabc accuenergy com ed Example abo acouenergy com Example sbo gmail com Example abo yahoo com Metering Example test mail pail accuenergy com c test amp accuenergr com c Hlalerm Event s0E Event Timed Sending 60 min Time Scope 5 1440min 0 for disable metering Energy ElHamonis sequence Mimax and Min ElAlarm Record MISOE Record reset Fig 5 46 171 Bev I Series d Web Configuration Settings Webpage Figure 5 47 Webpage Settings page Users set the Device Description according to the meter type fawim I See E Metering Webserver Main Page Data Settings Webpage Configuration Setting Module Status Device Description Acuvim II Series Example Feed line s name Fig 5 47 e Management webpage Figure 5 48 Management webpage Users can easily update the software online by selecting the updated file which can be got from Accuenergy Corporation The Reboot NET module option resets the module itself IP Address 192 168 1 254 Subnet Mask 255 255 255 0 Gateway 192 168 1 1 DNS Primary 202 106 0 20 DNS Secondary 202 106 196 115 MODBUS Port 502 HTTP Por
32. Range from 2000 5999 the default value is 502 Range from 6000 9999 the default value is 80 0 No resetting 1 Reset module after modifying parameters 2 Reset module to default values 0 No resetting 1 Reset password Note The figure shows the rolling sequence for using key P If using E key for rolling page the sequence will reverse BACnet IP module rolling sequence BACnet IP setting b01 DHCP setting 0 b02 IP address b03 Submask b04 Gateway T 5 DNS1 DNS2 Ols Ol Cnet Port b08 BACnet resetting selection The selection of DHCP setting MANU or AUTO Default setting MANU IP address has four segments Any segment can be set from0 255 Default setting 0 0 0 0 Submask has four segments Any segment can be set from0 255 Default setting 0 0 0 0 Gateway has four segments Any segment can be set from 0 255 Default setting 0 0 0 0 DNS 1 has four segments Any segment can be set from 0 255 Default setting 0 0 0 0 DNS2 has four segments Any segment can be setfrom0 255 Default setting 0 0 0 0 Range from1 65535 the default value is 47808 0 Noresetting 1 Reset module 2 Reset module to default values before module reset 59 ceu I Series A Reeve I Series BACnet MS TP module rolling sequence BACnet MS TP Setting Range from 0 127 the default B01 MS TP node add value is 0 Baud 0 9600 1 19200 2 38400 B02 MS TP baud 3 5760
33. Take AXM 1O21 AXM IO2 module in logic NO 1 for example DO working mode 10a5H register this register determines the working mode of DO circuits If the register is 0 then DO1 and DO2 will work in energy output mode If the register is 1 then DO1 and DO2 will work in alarm mode DO pulse width 10a6H register when DO circuits work in energy output mode this register determines the width of energy pulses DO1 output type 10a7H register when DO circuits work in energy output mode this register determines the energy output type for DO1 If this register is 0 DO1 outputs nothing If this register is 1 DO1 outputs import active energy If this register is 2 DO1 outputs export active energy If this register is 3 DO1 outputs import reactive energy If this register is 4 DO1 outputs export reactive energy DO2 output type 10a8H register when DO circuits work in energy output mode this register determines the energy output type for DO2 The value of this register is defined as the same as DO1 output type register DO1 output type register and DO2 output type register can be set to the same value or not The parameter setting is shown in Figure 5 19 Settings Help 1210 85 p Communication Channel 1 Protocol Modbus v Address 1 BaudRate 19200 bps Parity None v J Communication Channel 2 Protocol Defaut v Address 1
34. gt 0 word R Current Harmonics even HD odd HD K factor are shown as below Harmonics of I1 40c8H 40e5H the 2 to 31 F19 gt 0 word R Harmonics of I1 PS d 4560H 457fH the 32 to 63 F19 gt 0 wor R 40e6H Odd HD of I1 F20 gt 0 word R 40e7H Even HD of I1 F21 gt 0 word R 40e8H K Factor of 11 F23 0 65535 word R 40e9H 4109H Parameters of I2 Same as I1 word R Harmonics of I2 4580H 459fH the 32 to 63 F19 gt 0 word R 410aH 412aH Parameters of I3 Same as I1 word R asaonaasee annenicser io F19 gt 0 word R MAX MIN records MAX MIN value and time stamp Function code 03H for reading 4136H MAX of V1 F11 32768 32767 int R 4137H 413cH me stamp yyyyimm p time int R dd hh mm ss 413dH MAX of V2 F11 32768 32767 int Time stamp yyyy mm a P 413eH 4143H ddibihemmiss 3 time int 4144H MAX of V3 F11 32768 32767 int Time stamp yyyy mm 4145H 414aH dakbihimmiss 3 time int 414bH MAX of V12 F11 32768 32767 int Time stamp yyyy mm E 414cH 4151H ddihihimmss 3 time int 4152H MAX of V23 F11 32768 32767 int E Time stamp yyyy mm E i 4153H 4158H ddihlhimm ss 3 time int 4159H MAX of V31 F11 32768 32767 int Time stamp yyyy mm j 415aH 415fH ddihbimm ss 3 time int 4160H MAX of I1 F12 32768 32767 int Time stamp yyyy mm i i 4161H 4166H dedihshemriss 3 time int 41
35. including fundamental and harmonics Note When fundamental based calculating mode is selected PF calculation will be based on the fundamental wave Aawim I Seru Aawin I Series 2 There are two ways to calculate reactive energy power Mode 0 real reactive energy Q Mode 1 general reactive energy Q 4s P 3 User can choose primary energy or secondary energy either by pressing keys from the meter front or via communication as shown in figure 4 7 Note Acuvim ll is able to display either primary energy or secondary energy on the LCD screen however it is only able to send out pulses according to secondary energy via the AXM IO module mee 2268 66 Bi Ep imp 148 kwh Eq imp 135kvarh Ep exp iikwh Eq esp D 6 kvarh Ep total 16 0 kwh Eq total 14 1 kvarh Ep net 13 8 kWh Eq net 12 3 kvarh Es 25 8 kVAh THD Volts AN AB 0 00 THD 1A 0 00 THD Volts BN CA 0 00 THD IB 0 00 THD Volts CN BC 0 00 THDIC 0 00 THD Volts Average 0 00 THD Average 0 00 Odd THD Even THD THFF Crest Factor KFactor ond sd Harmonic V A 0 00 0 00 0 000 E Harmonic V B 0 00 0 00 0 00 0 000 Harmonic V C 0 00 0 00 0 00 0 000 Harmonic LA 0 00 0 00 0 0 Harmonic B 0 00 0 00 0 0 Harmonic C 0 00 0 00 0 0 am i Fig 4 2 Energy and Power Quality Parameters Current direction adjustment Under normal circumstances current flows from input terminal 1 to ter
36. shown in fig 2 9b The meter should be set to 3LN for both voltage levels LINE 1AFUSE Acuvim II Fig 2 9a 3LN direct connection 1AFUSE i t Qvt Acuvim II LOAD Fig 2 9b 3LN with 3PT 3 Phase 3 Line Direct Connection Mode 3LL In a 3 Phase 3 Line system power line A B and C are connected to V1 V2 and V3 directly Vn is floated The voltage input mode of the meter should be set to 3LL Beca I Series fawim I Series LINE A B CN 1AFUSE EA Ovi OV Acuvim Il 4j LOAD v3 Qva Fig 2 10 3LL 3 Phase 3 Line direct connection 3 Phase 3 Line open Delta Mode 2LL Open delta wiring mode is often used in high voltage systems V2 and Vn are connected together in this mode The voltage input mode of the meter should be set to 2LL for this voltage input wiring mode LINE A B C M 1A FUSE Ovi if Ove Acuvim II vs X 1 ew LOAD Fig 2 11 2LL with 2PTs 2 3 4 Current Input Wiring 3CT The 3CT current wiring configuration can be used when either 3CTs are connected as shown in Fig 2 13 or 2CTs are connected as shown in Fig 2 14 22 to the system In either case there is current flowing through all three current terminals Terminal Block ve Acuvim II LOAD Fig 2 12 3CTs a LINE A B c Terminal Bl
37. yyyy mm 1 3 41b5H 41baH ddihhirimiiss 3 time int 41bbH MAX of V1 V12 THD F18 32768 32767 int S Time stamp yyyy mm E 41bcH 41c1H dinis 3 time int 41c2H MAX of V2 V31 THD F18 32768 32767 int is Time stamp yyyy mm E 41c3H 41c8H ddkhhimmess 3 time int 41c9H MAX of V3 V23 THD F18 32768 32767 int Time stamp yyyy mm 41caH 41cfH ddihhimm ss 3 time int 41d0H MAX of I1 THD F18 32768 32767 int iia 41d1H 41d6H IMS Stamp yyyyemm es time int R dd hh mmiss 41d7H MAX of I2 THD F18 32768 32767 int R N 41d8H 41ddH Time stamp yyyy mm 3 time int R dd hh mm ss 41deH MAX of I3 THD F18 32768 32767 int R z aidfH 41eaH Time stamp yyyy mm p time int R dd hh mmiss The addresses for the MIN value of the above parameters are located in 41e5H to 4293H They have the same format as the MAX value Sequence component U1 U12 I1 are consisting of real part and complex part They have positive sequence negative sequence and zero sequence Data type is int Function code 03H for reading 4294H positive sequence real part of UA F11 32768 32767 int R 4295H_ positive sequence complex part of UA F11 32768 32767 int R 4296H negative sequence real part of UA F11 32768 32767 int R 4297H negative sequence complex part of UA F11 32768 32767 int R 4298H
38. 0079 3 622 Ju e 92 00 0 3 622 Panel Panel Fig 2 2 Panel Cutout 2 Remove the clips from the meter and insert the meter into the square hole from the front side Please note optional rubber gasket must be installed on the meter before inserting the meter into the cut out Pu 7 f Panel Peek I Series Al Fig 2 3 Put the meter into the opening 3 Install clips on the back side of the meter and secure tightly to ensure the meter is affixed to the panel Fig 2 4 Use the clips to fix the meter on the panel Note The display meter and the remote display unit have the same installation method The DIN rail meter is simply installed on a 35mm DIN rail fawim I Series 2 3 Wiring 2 3 1 Terminal Strips There are four terminal strips at the back of the Acuvim II series meter The three phase voltage and current are represented by using 1 2 and 3 respectively These numbers have the same meaning as A B and C or R S and T used in other literature Current Input Terminal Strip 111 112 121 122 131 132 1 2 3 4 5 6 Voltage Input Terminal Strip VOGOVKOY 7 8 9 10 V1 v2 v3 VN Power Supply Terminal Strip Communicati
39. 20070930 P93 change the description of Basic analog measurement P101 P102 change the description Counting number of 1 0 modules P50 change the flow chart add the function AO is 209 1015 de A parameters setting via the front panel Change the AO mode see IO Module User s Manual P64 m mE P69 Peo Add 3 demand parameters for alarm 1 22 20080625 Add transforming data type 1 23 20080710 Change the ordering information 1 30 20080912 Change the type of AO and Al to be read only 1 40 20090305 Open the address of AO AI type set add current demand maximum current demand and current demand alarm 1 50 20090520 Add Acuvim IIR 1 51 20090626 Change the content 1 52 20090818 Change the content P121 Add Data logging operation examples Change the 133 20030203 content of renal a 4 g Add Acuvim IIE functions Add User s Manual of the 1 60 20100930 accessory modules IO Modules Ethernet Module Profibus Module Change the maximum Data Logging sectors from 64 to 63 1 61 20101122 In the chapter of Tou 6 3 8 add the address of the max of demand and DST 1 62 20110228 Change DI input voltage range Change AD output address 284 1 63 20120417 Change Time of use TOU Increase in Acuvim IIW Update the method for generating CRC value 1 64 20120724 Change the voltage rated value and voltage swell threshold 1 65 20120913 Change the Weekend Setting in TOU Add the parameter setting page and BACne
40. 3376832767 int R demand 4607 460cH_ TME stamp F3 Time int i yyyy mm dd hh mm ss 46odH Max ofPhaseB current 13 32768 32767 int R demand 460e 4613H ime stamp F3 Time int 5 yyyy mm dd hh mm ss aera MakotPhaseCieument pue 33768 32767 int R demand 4615 461AH Me stamp F3 Time int i yyyy mm dd hh mm ss DI Status Current DI status if related I O module isn t connected the DI status will be set to 0 Function code 02H for reading T Sexe AXM IO11 E 0000H DI 1 ON 0 OFF bit E 0001H DI2 1 ON 0 OFF bit lt gt 0002H DI3 1 ON 0 OFF bit 0003H DI4 1 ON 0 OFF bit 0004H DIS 1 ON 0 OFF bit 0005H DI6 1 ON 0 OFF bit AXM 1021 0006H DI7 1 ON 0 OFF bit 0007H DI8 1 ON 0 OFF bit 0008H DI9 1 ON 0 OFF bit 0009H DI10 1 ON 0 OFF bit AXM IO31 000aH DI11 1 ON 0 OFF bit 000bH DI12 1 ON 0 OFF bit 000cH DI13 1 ON 0 OFF bit 000dH Di14 1 ON 0 OFF bit AXM 1012 000eH DI15 1 ON 0 OFF bit O00fH DI16 1 ON 0 OFF bit 0010H DI17 1 ON 0 OFF bit 0011H DI18 1 ON 0 OFF bit 0012H DI19 1 ON 0 OFF bit 0013H DI20 1 ON 0 OFF bit AXM 1022 0014H DI21 1 ON 0 OFF bit 0015H DI22 1 ON 0 OFF bit 0016H DI23 1 ON 0 OFF bit 0017H DI24 1 ON 0 OFF bit AXM 1032 0018H DI25 1 ON 0 OFF bit 0019H D126 1 ON 0 OFF bit Bee I Series 001aH DI27 1 ON 0 OFF bit 001bH D128 1 ON 0 OFF bit
41. 4013H Phase line current 11 F Rxx CT1 CT2 float R 4014H 4015H Phase line current I2 F Rxx CT1 CT2 float R 4016H 4017H Phase line current I3 F Rxx CT1 CT2 float R 4018H 4019H Average current lavg F Rxx CT1 CT2 float R 401aH 401bH Neutral current In F Rxx CT1 CT2 float R 401cH 401dH Phase A power Pa F P Rxx PT1 PT2 x CT1 CT2 float R 401eH 401fH Phase B power Pb F P Rxx PT1 PT2 x CT1 CT2 float R 4020H 4021H Phase C power Pc F P Rxx PT1 PT2 x CT1 CT2 float R 4022H 4023H System power Psum F P Rxx PT1 PT2 x CT1 CT2 float R Phase A ti 4024H 4025H nase reactive Fl Q Rxx PT1 PT2 x CT1 CT2 float power Qa Ph B ti 4026H 4027H d reactive Power E Q Rxx PT1 PT2 x CTI CT2 float Phase C ti 4028H 4029H 95 reactive F1 Q Rxx PT1 PT2 x CT1 CT2 float power Qc 402aH 402bH iin reactive power E g Rxx PT1 PT2 x CT1 CT2 float 402cH 402d Phase A apparent F1 S Rex PTI PT2 CTI CT2 float power Sa 402eH 402fH hase B apparent F1 S Rxx PT1 PT2 CT1 CT2 float power Sb 4030H 4031H hase C apparent Fl S Rxx PT1 PT2 x CT1 CT2 float power Sc len Series A System apparent 4032H 4033H S Rxx PT1 PT2 x CT1 CT2 float power Ssum 4034H 4035H Phase A power factor PF Rx float PFa 4036H 4037H Phase B power factor PF Rx float PFb 4038H 4039H Phase C power factor PF Rx float PFc 403aH 403bH 5 Stem power factor PF Rx f
42. 7BF9H The 22 holiday and schedule word 7BFAH 7BFCH The 23 holiday and schedule word 7BFDH 7BFFH The 24 holiday and schedule word 7C00H 7C02H The 25 holiday and schedule word te gee Laman Series A 262 7C03H 7C05H The 26 holiday and schedule word R W 7C06H 7C08H The 27 holiday and schedule word R W 7C09H 7COBH The 28 holiday and schedule word R W 7COCH 7COEH The 29 holiday and schedule word R W 7COFH 7C11H The 30 holiday and schedule word R W 7C12H The 3 setting year word R W 7C13H Holiday number of the 3 year R W The 1 holiday and schedule CIAM Teer format month day schedule word RW 7C17H 7C19H The 2 holiday and schedule word R W 7C1AH 7C1CH The 3 holiday and schedule word R W 7C1DH 7C1FH The 4 holiday and schedule word R W 7C20H 7C22H The 5 holiday and schedule word R W 7C23H 7C25H The 6 holiday and schedule word R W 7C26H 7C28H The 7 holiday and schedule word R W 7C29H 7C2BH The 8 holiday and schedule word R W 7C2CH 7C2EH The 9 holiday and schedule word R W 7C2FH 7C31H The 10 holiday and schedule word R W 7C32H 7C34H The 11 holiday and schedule word R W 7C35H 7C37H The 12 holiday and schedule word R W 7C38H 7C3AH The 13 holiday and schedule word R W 7C3BH 7C3DH The 14 holiday and schedule word R W 7C3EH 7C40H The 15 holiday and schedule word R W 7C41H
43. 7C43H The 16 holiday and schedule word R W 7C44H 7C46H The 17 holiday and schedule word R W 7C47H 7C49H The 18 holiday and schedule word R W 7C4AH 7C4CH The 19 holiday and schedule word R W 7C4DH 7C4FH The 20 holiday and schedule word R W 7C50H 7C52H The 21 holiday and schedule word R W 7C53H 7C55H The 22 holiday and schedule word R W 7C56H 7C58H The 23 holiday and schedule word R W 7C59H 7C5BH The 24 holiday and schedule word R W 7C5CH 7C5EH The 25 holiday and schedule word R W 7C5FH 7C61H The 26 holiday and schedule word R W 7C62H 7C64H The 27 holiday and schedule word R W 7C65H 7C67H The 28 holiday and schedule word R W 7C68H 7C6AH The 29 holiday and schedule word R W 7C6BH 7C6DH The 30 holiday and schedule word R W 7C6EH The 4 setting year word 7C6FH Holiday number of the 4th year word The 1 holiday and schedule ZCT0H ICT OE format menih day schedule word 7C73H 7C75H The 2 holiday and schedule word 7C76H 7C78H The 3 holiday and schedule word 7C79H 7C7BH The 4 holiday and schedule word 7C7CH 7C7EH The 5 holiday and schedule word 7C7FH 7C81H The 6 holiday and schedule word 7C82H 7C84H The 7 holiday and schedule word 7C85H 7C87H The 8 holiday and schedule word 7C88H 7C8AH The 9 holiday and schedule word 7C8BH 7C8DH The 10 holiday and schedule word 7C8EH 7C90H The 11 holiday and schedule word 7C91H 7C93H The 12 holiday and schedule
44. DI Function Code 02 Function Code 02 1 On 0 Off There are 38 Dls in the meter and the starting address is OOOOH The following query is to read the 4 Dls Status of address 1 of Acuvim II series meter Query Table 5 7 Read 4 Dis Query Message Transaction Transaction Protocol Protocol Lenath hi Length lo Unit identifier hi identifier lo identifier hi identifier lo 9 9 identifier 00H 00H 00H 00H 00H 06H 01H Data start Data start Data of regs Data of regs Fun A reg hi reg lo hi lo 02H 00H 00H 00H 04H Response The response includes MBAP Header function code quantity of data characters and the data characters An example response to read the status of 4 Dis DI1 On DI2 On DI3 On DI4 On is shown as Table 5 8 The status of each is responding to the last 4 bit of the data Aawim I Seru leo Series A DI1 bitO Table 5 8 Read 4 Dis Response Message DI2 bit1 DI3 bit2 DI4 bit3 Transaction Transaction Protocol Protocol L nathihi Lenathilo Unit identifier hi identifierlo identifier hi identifier lo 9 9 identifier 00H 00H 00H 00H 00H 04H 01H Fun Byte count Data 02H 01H OFH The content of the data is T 6 5 4 3 2 1 0 0 0 0 0 1 1 1 1 LSB c Read Data Function Code 03 Query This function allows the users to obtain the measurement res
45. Install other IO modules the same way Note 1 Install IO Modules carefully to avoid damage 2 Under no circumstances should any installation be done with the meter powered on Failure to do so may result in injury or death Fig 5 2 Installation of IO modules 5 1 5 Wiring of IO Modules Terminal strips of AXM IO1 modul Digital Input Relay Output vcr 200000000000 aa a oa ae ae aa a a ESI EST ar Toe os or os Te oe rer e Roo Fig 5 3 Terminal strips of AXM IO1 module DI1 to DIC digital input terminals where DIC is the common terminal for DI1 to DI6 circuits RO1 to ROC relay output terminals where ROC is the common terminal for RO1 and RO2 circuits V24 and V24 auxiliary voltage supply terminals Doniin Sven Bee Series Terminal Strips of AXM 1O2 Module Digital Input Analog Output Digital Output 2220200009000 Aenea Eee T2 Toc eoo Fig 5 4 Terminal strips of AXM IO2 module DI1 to DIC digital input terminals where DIC is the common terminal for DI1 to DI4 circuits AO1 AO1 AO2 AO2 analog output terminals DO1 to DOC digital output terminals where DOC is the common terminals for DO1 to DO2 Terminals strips of AXM IO3 module ETT mero ea 2020200009000 Sete se ee er For oe os or Toe Tee pre To Te 7 Fig 5 5 Terminal strips of AXM IO3 module DI1 to DIC digital input terminals where DIC is the commo
46. Log 3 to record power quality parameters Historical Log parameters can be selected from the following thirteen groups Becas I Series Real Time Metering Frequency Instantaneous Voltage Instantaneous Current Total and Per Phase Power and Power Factor Neutral Current unbalance V I load type Current demand and Per Phase Total Power demand Energy Ep imp Ep exp Ep total Ep net Eq imp Eq exp Eq total Eq net and Es THD Volts AN AB THD 2 63 Harmonic Magnitudes ODD EVEN CF and THFF of Volts AN AB THD Volts BN BC THD 2 63 Harmonic Magnitudes ODD EVEN CF and THFF of Volts BN BC THD Volts CN CA THD average THD 275 63 Harmonic Magnitudes ODD EVEN CF and THFF of Volts CN CA THD IA THD 2 63 Harmonic Magnitudes ODD EVEN KF of IA THD IB THD 2 63 Harmonic Magnitudes ODD EVEN KF of IB THD IC THD average THD 2 63 Harmonic Magnitudes ODD EVEN KF of IC Sequence Component positive negative and zero sequence Phase Angles the angle between U1 and other voltage and current parameters DI Counter the DI numbers of the IO modules fawim I Series AO AI Raw Value the AO output register values and the Al sample register values AO AI Value the AO output values and the AI sample values The following procedures show how to select and store parameters in historical log 1 The Group field determines the items that are available for se
47. M31 M32 ROT RO2 CH CH M31 M32 pul I MSA Bde 4 M31 M32 Counter 1 CH CP M31 M32 Counter 2 CP ro M31 M32 Counter 3 CP M31 M32 Counter 4 cr aD M31 M32 AL go M31 M32 Al1 AI2 input CH M21 22 AO M21 M22 AO1 AO2 output M21 M22 pulse count i M21 M22 Counter 1 Q Y M21 M22 Counter 2 0 Y Es 4 M22 Counter 3 vy Counter 4 SHE 3 7 Note The figure shows the rolling sequence for using key P If using E key for rolling page the sequence will reverse Parameter Setting Mode Pressing H and V A simultaneously will activate the display mode selection and the cursor will flash Press P or E to move the cursor right or left To enter parameter setting mode move the cursor to Setting then press V A In the parameter setting mode parameters such as system parameters expanded I O module parameters alarm parameters and Ethernet module parameters can be read and modified a Password Inquiry Parameter setting mode is password protected Before entering the password and getting into the parameter setting mode the meter s device communication address will display for 3 seconds A four digit password 0000 to 9999 is required ever
48. O modules such as DI status pulse counter number relay status analog input and analog output etc In this mode the first page is module selection You can choose to view the available modules that are attached to the meter If no expanded I O modules are connected the screen will display NO IO a Module Selection No commands are associated with the key H in the module selection screen Press P to move the cursor downwards the cursor will move to the top when it reaches the bottom If only one module is connected Pressing P will have no effect Press E to move the cursor upwards the cursor will move to the bottom when it reaches the top If only one module is connected Pressing E will have no effect Press V A to select the module and enter the I O module data selection mode Bee I Seru Bee I Series a kb uw As shown in the figure three modules are connected AXM IO11 AXM IO21 AXM 1O31 which are indicated by M11 M21 M31 respectively The cursor points to M21 which indicates that AXM IO21 is chosen now b I O Module Data Selection Press H to return to module selection screen Press P to move the cursor downwards the cursor will move to the top when it reaches the bottom Please note that there are 3 parameters for AXM IO1 3 parameters for AXM IO2 and 4 parameters for AXM 1O3 Press E to move the cursor upwards the cursor will move to the bottom when it reaches the top P
49. PLC Data Collector or RTU If the master does not have RS485 communication port a converter such as a RS232 RS485 or a USB RS485 converter will be required Typical RS485 network topologies include line circle and star wye The shield of each segment of the RS485 cable must be connected to the ground at one end only Every A should be connected to A B to B or it will influence the network or even damage the communication interface The connection topology should avoid T type which means there is a new branch and it does not begin from the beginning point Keep communication cables away from sources of electrical noise whenever possible When using a long communication cable to connect several devices an anti signal reflecting resistor typical value 1200 3000 0 25W is normally added to the end of the cable beside the last meter if the communication quality is distorted Use RS232 RS485 or USB RS485 converter with optical isolated output and surge protection Chapter 3 Meter Display and Parameter Settings 3 1 Display Panel and Keys 3 2 Metering Data 3 3 Statistics Data 3 4 Demand Data 3 5 Harmonic Data 3 6 Expanded I O Module Data 3 7 Parameter Settings Mode 3 8 Page Recovery Function fawim I Series w Detailed human machine interface of the meter will be described in this chapter This includes viewing real time metering data and setting parameters using different key combina
50. Relay Function Code 01 Function Code 01 This function code is used to read relay status in Acuvim II series meter 1 On 0 Off There are 8 Relays in the meter and the starting address is 0000H The following query is to read 2 Relays Status of the meter Address 1 Beca I Series Series Aman A Query Table 5 5 Read 2 Relays Status Query Message Transaction Transaction Protocol Protocol Lenath hi Length lo Unit identifier hi identifierlo identifier hi identifier lo 9 9 identifier 00H 00H 00H 00H 00H 06H 01H Fun Data start reg hi Data start reg lo Data of regs hi Data of regs lo 01H 00H 00H 00H 02H Response The Acuvim II series meter response includes MBAP Header function code quantity of data byte and the data For example response to read the status of Relay 1 and Relay 2 is shown as Table 5 6 The status of Relay 1 and Relay 2 is responding to the last 2 bit of the data Table 5 6 Read 2 Relays Status Response Message Relay 1 bitO Relay 2 bit1 Transaction Transaction Protocol Protocol Lenath hi Length lo Unit identifier hi identifierlo identifier hi identifier lo g g identifier 00H 00H 00H 00H 00H 04H 01H Fun Byte count Data 01H 01H 02H The content of the data is 7 6 5 4 3 2 1 0 0 0 0 0 0 1 0 MSB LSB Relay 1 OFF Relay 2 ON b Read Status of
51. See The Ethernet module supports IE Browser 6 0 and higher editions and the Webpage Settings only support ASCII characters The IP address will be referred to as 192 168 1 200 for the remainder of this chapter 1 Main page Users enter the correct IP address and HTTP port of the module in the address bar of the web browser This provides access to Data Settings and Module Status B Metering Webserver ACTUZW AGY sen tane Acuvim Il Series Meter Web Server Data Settings The Acuvim II Series Meter is a high end multifunction power meter manufactured by the Accuenergy Itis the ideal choice for monitoring and controlling of power distribution systems The Acuvim II Series Meter may be used as a data gathering device for an intelligent Power Module Status Distribution System or Plant Automation System All monitored data is available via a digital RS485 communication port running Modbus RTU Protocol Ethemet and Profibus DP communication are also options and with new wireless technologies and protocols currently under development the applications for the Acuvim Il Series Meter is limitless The main application fields are e Metering of distribution feeders transformers generators Capacitor banks and motors Medium and low voltage systems e Commercial industrial utility Power quality analysis Fig 5 42 2 Module Status Webpage By selecting the Module Status link users can view the
52. Single channel alarming settings 104eH First group parameter code F1 0 79 word First group comparison 1 greater than 2 104fH 9 p P F1 equal to 3 less word mode than Laman Series A Related with 1050H First group setpoint value F10 F18 Soe word R W parameters 1051H First group delay FI 0 3000 10ms word R W O none 1052H First group output to relay F1 1 8 related relay word R W 1053H Aa th Same as the 109dH 2 to 16 group first group word R W Alarming parameter code table 216 0 Frequency 1 Va 2 Vb 3 Vc 4 Average phase 5 Uab voltage 6 Ubc 7 Uca 8 Average line voltage 9 Line current of F Line current of Line current of phase phase A phase B C A li 12 AEE 13 Neutral current 14 Power of phase A current 15 Power of phase B 16 Power of phase C 17 Power of all Reactive power of Reactive power of Reactive power of 18 19 20 phase A phase B phase C Reactive power of Apparent power Apparent power of 21 22 23 all of phase A phase B 24 Apparent power 25 Apparent power 26 PF of A of phase C of all 27 PF of B 28 PF of C 29 PF Volt OMAgE Current unbalance Load characteristic R 30 unbalance factor 31 32 factor _unbl L C U_unbl THD_V1 V1 or THD_V2 V2 or 33 v12 34 v31 35 THD_V3 V3 or V23 36 Average THD_V 37 THD l1 38 THD 12 Averag
53. and processing functions In additon to measuring various parameters the meter is able to perform demand metering harmonic analysis max min statistic recording over under limit alarming energy accumulating and data logging High Accuracy Accuracy of Voltage and Current is 0 296 True RMS Accuracy of Power and Energy is 0 296 while monitoring all four quadrants Compact and Easy to Install This meter can be installed into a standard ANSI C39 1 4 Round or an IEC 92mm DIN Square cut out With the 51mm depth after mounting the Acuvim ll series meter can be installed in a small cabinet Mounting clips are used for easy installation and removal Easy to Use All metering data and setting parameters can be accessed by using the front panel keys or via the communication port Setting parameters are stored in the EEPROM so that content will be preserved when the meter is powered off Multiple Wiring Modes The Acuvim ll series meter can be used in high voltage low voltage three phase three wires three phase four wires and single phase systems using different wiring mode settings High Safety High Reliability Acuvim ll series meter was designed according to industrial standards It can run reliably under high power disturbance conditions This meter has been fully tested for EMC and safety compliance in accordance with UL and IEC standards heim d Sot Function Comparison of Acuvim Il series Meters
54. and schedule word R W 7DCFH 7DD1H The 26 holiday and schedule word R W 7DD2H 7DD4H The 27 holiday and schedule word R W 7DD5H 7DD7H The 28 holiday and schedule word R W 7DD8H 7DDAH The 29 holiday and schedule word R W 7DDBH 7DDDH The 30 holiday and schedule word R W 7DDEH The 8 setting year word R W 7DDFH Holiday number of the 8 year word R W TDEONS DEZH format month day schedule word RAN 7DE3H 7DE5H The 2 holiday and schedule word R W 7DE6H 7DE8H The 3 holiday and schedule word R W 7DE9H 7DEBH The 4 holiday and schedule word R W 7DECH 7DEEH The 5 holiday and schedule word R W 7DEFH 7DF1H The 6 holiday and schedule word R W 7DF2H 7DF4H The 7 holiday and schedule word R W 7DF5H 7DF7H The 8 holiday and schedule word R W 7DF8H 7DFAH The 9 holiday and schedule word R W 7DFBH 7DFDH The 10 holiday and schedule word R W 7DFEH 7E00H The 11 holiday and schedule word R W 7E01H 7E03H The 12 holiday and schedule word R W 7E04H 7E06H The 13 holiday and schedule word R W 7E07H 7E09H The 14 holiday and schedule word R W 7EQAH 7E0CH The 15 holiday and schedule word R W Beatos I Serier aman Series A 268 7EODH 7EOFH The 16 holiday and schedule word R W 7E10H 7E12H The 17 holiday and schedule word R W 7E13H 7E15H The 18 holiday and schedule word R W 7E16H 7
55. and the value 0000H will turn it off all other values are invalid and will not affect that relay The example below is a request to Acuvim II series meter address 1 to turn on Relay 1 Table 5 11 Control Relay Query Message Transaction Transaction Protocol Protocol L thhi Li thil Unit identifier hi identifierlo identifierhi identifierlo 9 PI identifier 00H 00H 00H 00H 00H 06H 01H Fun Data start reg hi Data start reg lo Value hi Value lo 05H 00H 00H FFH 00H Series AWA A Response The normal response to the command request is to retransmit the message as received after the Relay status has been altered Table 5 12 Control Relay Response Message Transaction Transaction Protocol Protocol L ihhilL thi Unit identifier hi identifierlo identifierhi identifierlo 9 n9 9 identifier 00H 00H 00H 00H 00H 06H 01H Fun Data start reg hi Data start reg lo Value hi Value lo 05H 00H 00H FFH 00H e Preset Reset Multi Register Function Code 16 Query Function code 16 allows the user to modify the contents of a Multi Register The example below is a request to an Acuvim II series meter address 1 to Preset CT1 500 and CT2 5 CT1 data address is 1008H and CT2 data address is 1009H Table 5 13 Preset CT Value Query Message
56. be 50 alarm will be triggered when the frequency is greater than 50Hz Note setpoint value is the same as the actual value of the selected parameter Delay time If the alarms condition lasts for the preset time period the alarm signal will be triggered The delay range is from 0 to 3000 unit 10ms When it is set to 0 there is no delay alarm will be triggered when the alarm condition is met If it is set to 20 there will be a 200ms 20 x 10ms delay Output to relay 0 alarming signal will not be sent to RO if it is set as 1 and AXM 1011 is connected it will output to RO1 when alarm triggers RO1 will be turned off when all alarms output to RO1 are cleared RO2 RO8 work in the same manner as RO1 Note 1 If RO is under alarming mode it can only work in latch mode I Sexe 2 If the number is 51 79 there are special guide for contrast method and meaning of parameters please refer to Chapter 6 CRIAM A After setting up the alarming parameters user must also setup the global settings in order for the alarm to work properly 2 Global settings Register addresses for global alarm settings are from 1046H 104dH Please refer to section 5 3 page 95 Global alarming settings for more details Global alarming enable determines whether the alarming function of the meter is activated or not The alarming function is enabled when it is set as 1 When Alarming flash enable is set as 1 back
57. chapter carefully before beginning installation 2 1 Appearance and Dimensions Bein I Multifunction Power Meter e 8 amp o Gasket WR E VA 96 00 3 800 96 00 3 800 Front View of the Display Meter Gasket and Remote Display Unit 7 60 0 300 LI 3 C LIL p M g j 3 8 g 2 5 S x 8 8 8 z E 5 ES E m ITT m En 35 90 3590 1413 1413 7 LL SEM 50 70 1 996 12 8 128 50 70 1 996 1400 0 504 0 504 0 551 Side View of the Side View of the Side View of the Display Meter Remote Display Unit DIN rail Meter 96 00 3 800 a G2 DGD 96 00 3 800 Rear View ggg 29 Rear View of the Re mote Display Unit Installation Clip Unit mm inches Fig 2 1 Appearance and dimensions of Acuvim II series meter Table 2 1 LCD Display Part name of Acuvim II series meter Large bright white backlight LCD display Q Front Casing Visible portion for display and control after mounting onto a panel Key Four keys are used to select display and set The Acuvim II series meter enclosures is made of high amp Enclosure A A strength anti combustible en
58. current P for active power Q for reactive power S for apparent power PF for power factor F for frequency 7 for phase angles DMD for demand Mxx for expanded IO module type and display setting page number Unbalance THD TDD MAX MIN Item Icons Unbalance for unbalance of the voltage and current THD for total harmonics distortion TDD for total demand distortion MAX for maximum and MIN for minimum e d Load rate 4 Load L Displays the percentage of load current to the nominal current Four quadrant icon Load type icon T 7 quadrant of the system power mw inductive load 4 capacitive load 1 2 2 3 3 1 avg N 1 2 3 for 3 phase A B C 1 2 2 3 3 1 for 3 phase line to line AB BC CA avg for average and N for neutral Energy icon Imp Total Net Exp Imp import energy Exp export energy Total absolute sum of Imp and Exp energy Net algebraic sum of Imp and Exp energy Acuovine I Series leto Series A 10 Units measured voltage V kV current A kA active power kW MW reactive power kvar Mvar apparent power kVA MVA frequency Hz active energy kWh reactive energy kvarh apparent energy kVAh percentage 96 phase angle 11 Communication icon No icon no communication One icon query sent Two icons query sent and response received 12 Energy p
59. data byte contains the input addressed in the query The other inputs follow toward the high order end of this byte and from low order to high order in subsequent bytes Example reading 4 DI statuses starting address is 0000H Use 6 channels Query 06H 02H 00H 00H 00H 04H 00H Response 06H 02H 01H 06H 00H DI status MSB LSB DI1 OFF DI2 ON DI3 ON DIA OFF 189 Aawim I Seriu Aawin I Series 5 3 15 Format of function code 03H This function code is used in MODBUS RTU to read the contents of a continuous block of holding registers in Acuvim Il meter In PROFIBUS DP the format of function code 03H is defined as follows Query FemeByes Caption Byte1 Channels can be chosen from 1 to 8 Byte2 03H Byte3 starting address high byte Byte4 starting address low byte Byte5 quantity of registers high byte Byte6 quantity of registers low byte Byte7 32 0 Quantity of registers indentifes how many words will be read Response The channel of inquiry frame Byte2 03H Byte3 byte count Byte4 Register value1 high byte Byte5 Register value1 low byte Byte6 Byte32 Byte count indentifies how many bytes will be read The register data in the response message is packed as two bytes per register with the binary contents correctly justified with each byte For each register the 190 first byte
60. first out recycling log NOTES If the memory of the historical data log is full the meter will erase the first sector in which the memory size is 65536 bytes 64kb The following sector the second sector will become the first sector and the data from the erased sector will not be recoverable Therefore user should save the whole log before memory is full to maintain all the data There are two display fields at the bottom of the data log setting screen They show the registers in the logs the total bytes used and the bytes remaining for this historical log These fields are updated as you make selections on the screen The total number of bytes available per log record is approximately 234 2 Retrieving logs There are two ways of retrieving the logs read one window and read all The retrieval screen is shown in Fig 4 9 Beca I Serier 3 A Se Ge amp 1 2 AON Re oDe SEX n sss 3 EN UN mS E FINO E Max Records 29m RecudSiee M LastRecod Tine Senp 2313624101817 ES Stm Record Tne WAR Tol vaa ab PAG hr PFa A Po Footer B Pw Facer Pr Fact ToUrbslreo V Urban x 1 ROOTED Wow ie DE OIRE QUOTA Oa 1900 108 136 100 10 2 20001 4 20 33 09 0 00000 kvar O CO00kvA OOO0DOkVA ODOOOKYA OO0D0OkVA 1 000 1 00 1 000 1 000 00x 3 20004 4 20 34 09 fononokva Acao Noon WA
61. increasing while value reaches Newest Waveform Group Number If the value added 4 the value will be larger than Newest Waveform Group Number Second retrieving method is retrieving all waveforms data When 0x8E01H Waveform Group Number is set to 1 121 each time only one group data of each number will be retrieved then Waveform Group Number for Retrieving 8E01H will automatically add 1 after retrieving At next time new Waveform Group Number will be retrieved Waveform Group Number will stop increasing after value reach 121 Note The range of 0x8E01H is 0 121 within setting range windows 8E04H 8E43H are corresponding to waveform data 0 Only retrieving waveform record reasons 1 Time and reasons of waveforms 2 11 Each waveform number of ten waveforms before U1 waveform triggered S 12421 Each waveform number of ten waveforms before U2 waveform is triggered 22431 Each waveform number of ten waveforms before U3 waveform is triggered 32 41 Each waveform number of ten waveforms before I1 waveform is triggered 42 51 Each waveform number of ten waveforms before I2 waveform is triggered 52 61 Each waveform number of ten waveforms before I3 waveform is triggered 62 71 Each waveform number of ten waveforms after U1 waveform is triggered 72 81 Each waveform number of ten waveforms after U2 waveform is triggered 82 91 Each waveform number of ten waveforms after U3 waveform is triggered 92 101 Each waveform n
62. is set as 3 the first 3 slots of the holiday schedule must be set otherwise it will be considered as an invalid input TOU function will be disabled Note User can either customize the TOU calendar factory settings or use the default factory settings User can reset the TOU calendar to its default value either via communication or from the meter front 8 Holiday schedule The holiday schedule uses the same format as the TOU seasons MM DD ID User can select which TOU schedule to be used for the holiday The dates of the holiday schedule do not need to be organized in a sequential order i e the first slot can be January 1 the second slot can be December 26 and the third slot can be December 25 9 Daylight saving time DST Daylight saving time can be enabled in one of two formats The fixed date option or a fixed day of one of the weeks in the month also named as the non fixed date option if you choose a fixed date option you set the format according to a fixed date for the daylight saving time switch the format month day hour minute adjust time in minutes If you choose non fixed date option DST will be implemented by which day of which week whose setting format is month which day i e Tuesday which week i e 1st week hour minute adjust time in minutes Bee I Seru Aawin I Serie By using the function you can cause the instrument to automatically switch to and from daylight saving time
63. modules which is displayed in the utility software as follows where AXM IO12 AXM IO1 module in logic NO 2 AXM 1022 AXM IO2 module in logic NO 2 and AXM IO32 AXM 1O3 module in logic NO 2 are linked to Acuvim II meter Start Readings Settings Help Kel mre 2 RORA AXM 1012 Relay 1 ON Control Relay 2 OFF Control Ey Eo BE En 2 Bee I Seriu DI1 ON DI2 ON DI3 ON DI4 OFF DIS OFF DIG OFF AXM 1022 DI1 ON DI2 ON DS OFF DI4 OFF AD 1 2 500 V A02 2 500 V AXM 1032 Relay OFF Control Relay2 ON Control Dii OFF DI2 OFF DI3 ON DI4 ON ALT 2053 Al2 2114 Fig 5 12 functions of IO modules 5 1 6 Detection of Remote Signals The digital input circuit can be set to detect remote signals a Detection of Remote Signals When digital input circuit detects a qualified voltage input it will show 1 on screen and ON in utility software Otherwise it will show 0 on screen and OFF in utility software Bee I Series MD d d w aa FI pe ee d qD d ll c g j LY T Atl Fig 5 13 showing DI state on screen b Record of SOE When the digital input circuit is set to detect remote signals the recording function of SOE can be enabled Therefore when the remote signals change the IO module can record this information accordingly SOE Record including 4399H to 4439H address registers 4399H to 4438H
64. nonnonkvA nomnnkvA 7 000 1 000 4 000 1000 nnt 4 20001 4 20 35 09 0 00000 kvar 0 00000kVA OLCOOKV ODO0OOKVA OOOO kVA 1 000 1 000 1 0 1 000 00x i aisa Ove amonak oook aooaa oOMONKA 10D 190 10 106 00x G 20001203709 00D kva omava noka naka nomoka 1000 100 mn 1000 oox 7 2000 1 20 38 09 0 00000 kvar 0 00000kVA OLOCODKVA ODUDOK A ODDDODRVA 1 000 1 000 1 00 1 000 00x g 20001 4 20 39 09 DODO va Q ODUDO KA Q UODUOKV OOODOOKYA OOOUUUKMA 7 000 1 000 1 000 1000 oo 3 2000 1 4 20 40 09 0 00000 kvar O CO000 kVA O 0000kV OO0000kvA OO0D00kVA 1 000 1 000 1 000 1 000 00 10 20001 4 20 47 09 0 00000 kvar 0 00000kVA OLCODKV DODUOOKNA OOOO kVA 1 000 1 00 1 00 1 000 00x TH Jesoor 2n4z08 nomoka DC0OUOIvA O00001 aooo oomookva 10 1mo 100 1 000 00 2 200014204309 0 00000 kvar 0 00000 kVA O DCDOKVA O DOOODKVA OOOO KYA 1 000 1 000 1 0 1 000 00x El 0001420409 00000 hve 0 00000 kVA OUDCDOKVA O QOO0DKVA OODDDDKVA 1 000 1 000 1 000 1 000 005 14 20001 4 20 45 09 0 00000 kvar O 00000kVa Q 00O00kv ODOOOOKYA OO0D00KVA 1 000 1 00 1 000 1 000 00x E 20001204609 0 00000 kvar O C0000kVA OOOQDOKVA 000000KMA OODDODKVA 1 000 1000 1 00 1 000 00x 16 20004 4 20 47 08 0 00000 kvar O C0000 kVA O DOCOOkVA OO0000kvA 00000 KA 1 000 1 000 1 000 1 000 00 e Jamon 264600 noon var amona O00000 A 00000014 ODQXU A 7 000 100 10 1000 00 18 20001 4 2048 08 0 00000 kvar 0 00000kvA O 0O0DOkVA ODOOOOKVA QDODODKVA 1 000 1 000 1 00 1 000 00x 1S 200014 205009 omo
65. range setting point 3 and AO following value range setting end point are increasing value while they should be within range of AO following value Otherwise the function of AO will be affected Frequency 45HZ 65HZ real setting value is 4500 6500 Phase voltage V1 V2 V3 and average phase voltage 0 480V real setting value is 0 4800 Line voltage V12 V23 V31 and average line voltage 0 831V real setting value is 0 8310 Current I1 I2 I3 and average current 0 10A real setting value is O 10000 Power Pa Pb and Pc 4800 4800W real setting value is 4800 4800 System power 14400 14400W real setting value is 14400 14400 Reactive power Qa Ob and Oc 4800 4800 Var real setting value is 4800 4800 System reactive power 14400 14400 Var Apparent power Sa Sb and Sc 0 4800VA real setting value is 0 4800 System apparent power 0 14400VA real setting value is 0 14400 Power factor PFa PFb PFc and System power factor 1 1 real setting value is 223 Beatos I Series fawim I Series 1000 1000 3 AO output range setting AO output value range setting start point AO1 output value range setting point 2 AO1 output value range setting point 3 and AO output value range setting end point are increasing value while they should be within range of AO output value When AO type is 0 20mA the setting value range is 0 4915 and the relationship is mA setting value 20 4096 When AO ty
66. same as the one the onboard RS485 port is using If the master does not have RS485 communication port a converter such as a RS232 RS485 or a USB RS485 converter will be required Typical RS485 network topologies include line circle and star The shield of each segment of the RS485 cable must be connected to the ground at one end only The default baud rate of RS485 module is 38400 bps Users can change the baud rate in system settings S03 of the Acuvim II series meter cna MT 2ud mr ac e 50 D Load 306400 a IM x2 MAx2 M3ix2 m The data format is start bit 8n data bit parity stop bit NON1 NON2 odd and even can be selected for parity mode on S32 of Setting page of Acuvim IIR and Acuvim IIE meter Not support Acuvim II meter NON1 represents 197 Aawim I Series non parity single stop bit NON2 represents non parity double stop bit odd represents odd parity single stop bit even represents even parity single stop bit As is shown the RS485 modules parity is set as None 2 Pee I Series Please note if AXM NET is used RS 485 module s parity PAR2 must be set as None in order to have the meter recognize the AXM NET Setting cia AAJ J1 Friunm e Me 50 D Load 5 4 6 Communication Address Please refer to Chapter 6 for Modbus register addresses 198 Chapter 6 Communication 6 1 Modbus Protocol Introduction 6 2 Communication Format 6 3 Dat
67. schedule word R W 7BA7H 7BA9H The 26 holiday and schedule word R W 7BAAH 7BACH The 27 holiday and schedule word R W 7BADH 7BAFH The 28 holiday and schedule word R W 7BBOH 7BB2H The 29 holiday and schedule word R W 7BB3H 7BB5H The 30 holiday and schedule word R W 7BB6H The 2 setting year word R W 7BB7H Holiday number of the 2 year word R W The 1 holiday and schedule 7BBBH 7BBAM format month day schedule werd 7BBBH 7BBDH The 2 holiday and schedule word 7BBEH 7BCOH The 3 holiday and schedule word 7BC1H 7BC3H The 4 holiday and schedule word 7BC4H 7BC6H The 5 holiday and schedule word 7BC7H 7BC9H The 6 holiday and schedule word 7BCAH 7BCCH The 7 holiday and schedule word 7BCDH 7BCFH The 8 holiday and schedule word 7BDOH 7BD2H The 9 holiday and schedule word 7BD3H 7BD5H The 10 holiday and schedule word 7BD6H 7BD8H The 11 holiday and schedule word 7BD9H 7BDBH The 12 holiday and schedule word 7BDCH 7BDEH The 13 holiday and schedule word 7BDFH 7BE1H The 14 holiday and schedule word 7BE2H 7BE4H The 15 holiday and schedule word 7BE5H 7BE7H The 16 holiday and schedule word 7BE8H 7BEAH The 17 holiday and schedule word 7BEBH 7BEDH The 18 holiday and schedule word 7BEEH 7BFOH The 19 holiday and schedule word 7BF1H 7BF3H The 20 holiday and schedule word 7BF4H 7BF6H The 21 holiday and schedule word 7BF7H
68. seders transformers generators SOE Record tors systems nu silty Power quality analysis Fig 5 50 Metering webpage includes the data of real time parameters for Acuvim II series meter There are thirty nine parameters such as Volts AN A Watt A Energy webpage includes the energy data for Acuvim II series meter There are nine parameters such as Delivered kWh kVAh len Series A Harmonics webpage includes harmonics parameters for Acuvim II series meter such as THD Volts Average Sequence webpage includes the sequence and angle parameters for Acuvim ll series meter There are fifteen parameters such as positive sequence of VA the angle VB to VA Max and Min webpage includes the max and min data of parameters for Acuvim Il series meter There are twenty five parameters such as Volts AN 1A and Watt Total Demand Alarm Record webpage includes alarm records for Acuvim II series meter There are sixteen records record Each record includes Time Stamp Limit ID Status Alarm Channel and Value SOE Record webpage includes SOE record for Acuvim II series meter There are twenty records Each record includes Time Stamp DI Status IO Status webpage includes DI status or DI counters DO status RO status Analog Input values and Analog Output values 5 2 12 Email Function The Ethernet module supports SMTP protocol which provides email capabilities Before sending emails users m
69. the following assumptions e The log is Historical Log 1 The Log contains VAN VBN VCN 12 bytes the interval is 1min the sectors is 10 the registers is 6 the logging timer function is disabled Retrieval is starting at record offset 0 oldest record No new records are recorded to the log during the log retrieval process a Data logging settings Now set the data log 1 according to the assumptions 1 Set the data log with VAN VBN VCN here we should set their modbus address 0x4002 0x4003 0x4004 0x4005 0x4006 and 0x4007 to 0x1102 0x1103 0x1104 0x1105 0x1106 and 0x1107 And the discripter is 2 50 set the 0x0202 and 0x0200 to 0x1177 and 0x1178 2 The register is 6 and sector is 10 so we set 0x060A to 0x1100 3 The interval is 1min so set the 0x0001 to 0x1101 4 The logging timer function is disabled so set the 0 to 0x11b9 b Log Retrieval Procedure Aawim I Seru fawim I See The following procedure documents how to retrieve a single log from the oldest record to the newest record 1 Compute the number of records per window as follows RecordsPerWindow 246 RecordSize 246 24 10 2 Write the Records per window and Record offset in this example set the Ox0AOB and 0x0000 to 0x6001d and 0x6002 This step tells the meter what data to return in the window 3 Read the record window status from 0x6001 If the Window Status is OxFF go to step 2 If the Window Status is OxOB
70. the same way as MODBUS RTU It is recommaneded to refer to the communicaion part of the Acuvim II manual Chapter 6 for the list of MODBUS RTU addresses function codes the relationships between values etc Some examples are 1 There are various function codes such as 01H 02H 03H 05H 10H for the various categorized parameters Different function codes have different formats of query and response frames 2 There is a specific relationship between numerical value in register of Acuvim Il meter and the real physical value 3 Different parameters may have different data length and data type These three points are also suitable for the PROFIBUS DP protocol in PROFIBUS module Acuovine I e Note the following communication formats are suitable for the application data but not for the PROFIBUS DP s frame characteristic data Function codes such as 01H 02H and 03H are inquiry commands For users to quickly switch the inquiry contents we define 8 channels named 1 to 8 in order to update data more quickly 5 3 12 Format of function code 01H Function code 01H is used to read relay status in MODBUS RTU In PROFIBUS DP the format of function code 01H is defined as follows Query Famebyes Caption 0 8 Bytel Channels can be chosen from 1 to 8 Byte2 01H Byte3 starting address high byte Byte4 starting address low byte Byte5 quantity of coils high byte Byte6 quantity of coils low byte Byt
71. time vV V Demand calculating 100EH mode vV vV 100FH Clear demand memory y Vv 1012H Current I1 direction X Vv 1013H Current I2 direction y y 1014H Current I3 direction X Vv 1015H VAR PF convention y y 1016H Energy clear X Vv Energy calculating 1017H mode vV v Reactive power 1018M measuring mode y v 1019H Energy display mode vV V 101DH Basic parameter mode V y Sealed Nonstandard 101551 Parameters Selection 7 y Note means these addresses will be blocked for keys and communication and means this function is unavailable 101 I Seria HOMI A aman Series A 102 Energy 4048H 4049H Energy IMP 404AH 404BH Energy EXP 404CH 404DH Reactive energy IMP y y y 404EH 404FH Reactive energy EXP E vV 4050H 4051H Energy TOTAL v 4052H 4053H Energy NET 5 y 4054H 4055H Reactive energy TOTAL Vv 4056H 4057H Reactive energy NET Vv 4058H 4059H Apparent energy Vv Og 10A5H Working mode of DO 1 and 2 V v 10A6H DO pulse width V V 10A7H DO1 output y Vv 10A8H DO2 output V V 10B7H Working mode of DO 3 and 4 V Vv 10B8H DO pulse width Vv V 10B9H DO3 output V V 10BAH DO4 output V y Sealed Nonstandard Parameters 1 When bit 0 of address 101EH is valid parameters about 1 communication should be blocked OFFEH Communication Protocol 1 y y OFFFH Parity Setting 1 E Vv 1
72. unsigned integer where bitO determines DI1 s working mode bit1 determines DI2 s working mode and so on If the bit is 1 then the DI circuit is set to be a pulse counter Otherwise the DI circuit is set to detect remote signals Figure 5 13 shows the parameter setting of digital input circuits 101bH register this register is an unsigned integer it determines that which IO module will be SOE enabled If register is 0 then any IO module is SOE disabled If register is 1 then AXM IO11 AXM IO1 module in logic NO 1 is SOE enabled If register is 2 then AXM IO21 AXM IO2 module in logic NO 1 is SOE enabled If register is 3 then AXM IO31 AXM IO3 module in logic NO 1 is SOE enabled If register is 4 then AXM IO12 AXM IO1 module in logic NO 2 is SOE enabled If register is 5 then AXM IO22 AXM IO2 module in logic NO 2 is SOE enabled If register is 6 then AXM IO32 AXM IO3 module in logic NO 2 is SOE enabled Only one IO module can be SOE enabled at one time If the IO module is not linked to the Acuvim Il power meter then there is no need to enable SOE function in the software Figure 5 15 shows the parameters setting of IO module s SOE function Start Readings Settings Help ar imre 2 9r 68 G se Be Ep EC E 2 Voltage 3LN Ed Curent 3CT x Security r Communication Password 0 Addess BaudRate 19200 v bps Witing PT and CT Ratios PT1 220 0 v Cri A PT2
73. when the meter detects a new event such as an Alarm Event or SOE Event Timed Sending means users can receive mail every 5 1440 minutes user settable reporting Metering Energy Harmonics Sequence Max Min Alarm Record and SOE Record Sending Modes can be set as follows Setting Triggered Sending mode users can select one or all of the checkboxes below Triggered Sending includes Alarm Event and SOE Event as seen in Figure 5 46 Triggered Sending mode is disabled if neither Alarm Event or SOE Event is selected Setting Timed Sending mode users enter a number between 5 and 1440 minutes into the box beside Timed Sending This number is the interval time between mail Sending mode is disabled if 0 is entered Users can also select which parameters to receive reports on by checking the checkboxes below Timed Sending in Figure 5 46 Setting both Triggered Sending and Timed Sending mode users follow the steps for both Triggered Sending and Timed Sending above None mode users disable both Triggered Sending and Timed Sending modes Note Mail Server part includes SMTP Server User Name and Password For the SMTP Server users can input either domain name such as mail accuenergy com or an IP address such as 222 128 6 73 which is from mail accuenergy com resolved A user name and password will be required to log in Mail Information Mail From Mail To st
74. word 7C94H 7C96H The 13 holiday and schedule word 7C97H 7C99H The 14 holiday and schedule word 7C9AH 7C9CH The 15 holiday and schedule word 7C9DH 7C9FH The 16 holiday and schedule word 7CAOH 7CA2H The 17 holiday and schedule word 7CA3H 7CA5H The 18 holiday and schedule word 7CA6H 7CA8H The 19 holiday and schedule word 7CA9H 7CABH The 20 holiday and schedule word 7CACH 7CAEH The 21 holiday and schedule word Beatos I Serier mane Series A 264 7CAFH 7CB1H The 22 holiday and schedule word R W 7CB2H 7CB4H The 23 holiday and schedule word R W 7CB5H 7CB7H The 24 holiday and schedule word R W 7CB8H 7CBAH The 25 holiday and schedule word R W 7CBBH 7CBDH The 26 holiday and schedule word R W 7CBEH 7CCOH The 27 holiday and schedule word R W 7CC1H 7CC3H The 28 holiday and schedule word R W 7CC4H 7CC6H The 29 holiday and schedule word R W 7CC7H 7CC9H The 30 holiday and schedule word R W 7CCAH The 5 setting year word R W 7CCBH Holiday number of the 5th year word R W The 1 holiday and schedule TEGEHSTCCEH format onthi schedule word R W 7CCFH 7CD1H The 2 holiday and schedule word R W 7CD2H 7CD4H The 3 holiday and schedule word R W 7CD5H 7CD7H The 4 holiday and schedule word R W 7CD8H 7CDAH The 5 holiday and schedule word R W 7CDBH 7CDDH The 6 holiday and schedule word R W 7CDEH 7CEOH T
75. yyyy mm dd hh mm ss ms r word i lt DI are arranged according to expanded I O module addresses user can check othe counting number of DI along with those modules The DI counting records are stored in a non volatile memory and will not be erased during power off They can be reset via communication and panel Data type is dword Function code 03H for reading AXM IO11 4349H 434aH 0 4294967295 dword R DI1 pulse counter number F1 mane Series A 434bH 434cH DI2 pulse counter number F1 0 4294967295 dword R 434dH 434eH DI3 pulse counter number F 0 4294967295 dword R 434fH 4350H DI4 pulse counter number F1 0 4294967295 dword R 4351H 4352H DI5 pulse counter number F1 0 4294967295 dword R 4353H 4354H DI6 pulse counter number F1 0 4294967295 dword R AXM IO21 4355H 4356H DI7 pulse counter number F1 0 4294967295 dword R 4357H 4358H DI8 pulse counter number F1 0 4294967295 dword R 4359H 435aH DI9 pulse counter number F1 0 4294967295 dword R 435bH 435cH DI10 pulse counter number F1 0 4294967295 dword R AXM I031 435dH 435eH DI11 pulse counter number F1 0 4294967295 dword R 435fH 4360H DI12 pulse counter number F1 0 4294967295 dword R 4361H 4362H DI13 pulse counter number F1 0 4294967295 dword R 4363H 4364H DI14 pulse counter number F1 0 429496
76. zero sequence real part of UA F11 32768 32767 int R 4299H zero sequence complex part of UA F11 32768 32767 int R 429aH _ positive sequence real part of IA F12 32768 32767 int R 429bH positive sequence complex part of IA F12 32768 32767 int R 429cH negative sequence real part of IA F12 32768 32767 int R 429dH negative sequence complex part of IA F12 32768 32767 int R 429eH zero sequence real part of IA F12 32768 32767 int R 429fH zero sequence complex part of IA F12 32768 32767 int R Phase angle All voltage and current s phase angles corresponding to V1 V12 are stored here You can find out the phase sequence according to them Data type is 231 aman Series A 232 word Function code 03H for reading 42a0H phase angle of V2 to V1 V1 V2 3 4 phase angle of V23 to V12 V12 V23 3 3 F25 0 3600 word 42a1H phase angle of V3 to V1 V1 V3 3 4 phase angle of V31 to V12 V12 V31 353 F25 0 3600 word 42a2H phase angle of 11 to V1 V1 11354 phase angle of v12 l1 353 1 to V12 F25 0 3600 word 42a3H phase angle of 2 12 3 4 phase angle of V12 12 353 to V1 V1 2 to V12 F25 0 3600 word 42a4H phase angle of 13 13 3 4 phase angle of V12 13 353 to V1 V1 3 to V12 F25 0 3600 word 42a5H Reserved word 42a6H Reserved word 42a7H Reserve
77. 0 it means DI Triggering Disabled 01 means DI Triggering will be implemented when DI state changes from OFF to ON 10 means DI Triggering will be implemented when DI state changes from ON to OFF 11 means DI Triggering will be implemented when DI state has any change 3 Voltage Sag Triggering As mentioned in Voltage Sag event logging when Voltage Sag Triggering Waveform is enabled both event logging and waveform capture will be implemented at the same time once a voltage sag happens 4 Voltage Swell Triggering As mentioned in Voltage Swell event logging when Voltage Swell Triggering Waveform is enabled both event logging and waveform capture will be implemented at the same time once a voltage swell happens 5 Over current Triggering When Over current Triggering is enabled if any phase of the three phase current is higher than the set value rated value x thredshold 96 the waveform capture will be implemented If one phase is over current any other phase over current cannot implement the waveform capture Only when all of the phase current restore back to normal waveform capture will be responding 4 Waveform Capture Retrieve Because of large quantity of saved waveform waveform retrieving window use 64 addresses to make retrieving data easier which keeps consistent with 95 Aawim I Seru fawim I Series recording points of one period There are two retrieving methods one retrieve w
78. 0 b03 bod BAG 0 No resetting 1 Reset module 2 Reset net module to default values before module reset Q Q Max Info Range from1 255 the default Frames value is 1 Resetting Selection f Alarm Parameter In the alarm parameter mode user can view and modify the parameters Key functions for finding the alarm parameter Press H to return to parameter selection mode The screen will roll to the next page each time P is pressed and will return to the first page when P is pressed at the last page The screen will roll to the last page each time E is pressed and will return to the last page when E is pressed at the first page Press V A to modify the selected parameter Key functions for modifying the parameter Press H to move the flashing cursor to the next position Press P to increase the number by 1 Press E to decrease the number by 1 Press V A to confirm the modification and return to parameter selection mode The following figure shows the sequence Alarming setting L 4 su A01 Alarming able en Ce A02 Backlight flashing CP y A03 Alarming records enable CP y A04 AND logic enable Soy A05 Alarming output to DO 1 CP y A06 Alarming output to DO 2 I y A07 Alarming output to DO 3 CP y A08 Alarming output to DO 4 Yes Alarm enable No Alarm disable It can be
79. 0 waveforms 64 x 10 x 6 words U1 U2 U3 I1 I2 I3 After triggering point 10 waveforms 64x10x6 words Timestamp Year W1 Month W2 Day W3 Hour W4 Minute W5 Second W6 Millisecond W7 Triggering Condition W8 Manual Triggering 0 disable 1 enable W9 AXM 11 DI Triggering bit1 bit DI1 bit3bit2 DI2 bit5bit4 DI3 bit7bit6 DI4 bit9bit8 DI5 bit11bit10 DI6 W10 AXM 21 DI Triggering bit1bitO DI7 bit3bit2 DI8 bit5bit4 DI9 bit7bit6 DI10 W11 AXM 31 DI Triggering bitlbitO DI11 bit3bit2 DI12 bit5bit4 DI13 bit7bit6 DI14 Two bits meaning 00 No DI Triggering 01 DI Triggering from OFF to ON 10 DI Triggering From On to OFF W12 Voltage Sag Triggering 0 disabled BitO 1 u1 voltage sag waveform 0 no u1 waveform Bit1 1 u2 voltage sag waveform 0 no u2 waveform Bit2 1 u3 voltage sag waveform 0 no u3 waveform W13 Voltage Swell Triggering 0 disabled BitO 1 u1 voltage swell waveform 0 no u1 waveform Bit1 1 u2 voltage swell waveform 0 no u2 waveform Bit2 1 u3 voltage swell waveform 0 no u3 waveform W14 Over current Triggering 0 disabled Beatos I Serier BitO 1 11 voltage over current waveform 0 no 11 waveform Series Bit1 1 12 voltage over current waveform 0 no I2 waveform Awam Bit2 1 13 voltage over current waveform 0 no I3 waveform W15 W16 0 Reserved Waveform Order
80. 000H Password y y 1001H Communication address 1 V V 1002H Baud rate 1 y y 2 When bit 1 of address 101EH is valid parameters about 2nd communication should be blocked 102FH Baud rate2 y y 1030H Parity Setting 2 Vv Vv 1031H Communication address 2 y y Ethernet Module DHCP setting IP address 1st byte high IP address 2nd byte low IP address 3rd byte high IP address 4th byte low Submask 1st byte high Submask 2nd byte low Submask 3rd byte high Submask 4th byte low Gateway 1st byte high Gateway 2nd byte low Gateway 3rd byte high Gateway 4th byte low DNS1 1st byte high DNS1 2nd byte low DNS1 3rd byte high DNS1 4th byte low DNS2 1st byte high DNS2 2nd byte low DNS2 3rd byte high DNS2 4th byte low Modbus Tcp Ip port Http port lt lt lt lt lt lt lt lt lt lt j lt lt lt j lt lt lt js lt lt lt lt j ee BACnet Module BACnet module enable DHCP setting lt j i 103 Bee I Series Been I Series 104 IP address 1st byte high IP address 2nd byte low IP address 3rd byte high IP address 4th byte low Submask 1st byte high Submask 2nd byte low Submask 3rd byte high Submask 4th byte low Gateway 1st byt
81. 021 MDI 1 Type DI 2 Type DI 3 Type DI 4 Type MDI Pulse Const State State State State a f Pulse 1 Counter E Counter lr Counter Counter Energy Pulse Alarm 1 DO Type MDO Energy Pulse Mode Raw Channel of AO DO 1 Output DO 2 Output Pulse Width AO Type orama TAD Input Output Transfer Curve Min a m E TEES ipee T Output in 1 a i AXM 1031 DI1 Type DI2 Type DI3 Type DI 4 Type DI Pulse Const State State State State fl Puse 1 Counter Counter Counter i Counter I MRO Type pRO Relay Control Output Mode j Relay Control Latch Ate ERES ype C Alam Momentary On Time Bp ms Save Load Update Device Fig 5 22 Parameter setting of IO modules 137 Been I Seriu LAM I Serea A 138 5 1 11 Analog Input Analog input circuits supply 4 types of input modes including 0 to 20mA mode 4 to 20mA mode 0 to 5V mode and 1 to 5V mode Figure 5 23 shows the relationship between AI value and input analog value Al value ranges from 0 to 4095 without any unit Al value is displayed in hex on screen Figure 5 24 shows the AI value read on screen AI Value AI Value AI Value AI Value 4095 7 0 gt 0 20 mA 4 Fig 5 23 relationship between Al value and input analog
82. 06H 03H 00H 00H 00H 21H 84H 65H The meaning of each abbreviated word is Addr Address of slave device Fun Function code Data start reg HI Start register address high byte Data start reg LO Start register address low byte Data of reg HI Number of register high byte Data of reg LO Number of register low byte CRC16 HI CRC high byte CRC16 LO CRC low byte 1 Reading Relay Status Function Code 01 This function code is used to read the status of the relay in the meter 1 On 0 Off Relay1 s address is 0000H Relay2 s address is 0001H and so on The following query is to read the relay status for the meter with communication address 17 Query Table 6 4 Read the status of Relay1 and Relay2 Query Message Relay start Relaystart Relay of Relay of CRC16 CRC 16 Addr Fun reg HI reg LO regs HI regs LO HI LO 11H 01H 00H 00H 00H 02H BFH 5BH Response Bee I Series The Acuvim ll series meter response includes the meter address function code quantity of data byte the data and error checking An example response to read the status of Relay1 and Relay2 is shown as Table 5 5 The status of Relay1 and Relay2 are responding to the last 2 bits of the data Relay1 bitO Relay2 bit1 Table 6 5 Relay status response Address Function code Byte count Data CRC high CRClow 11H 01H 01H 02H D4H 89H The content of the data
83. 0c3H santos 0 Refer to following table word R W parameter AO3t formi 10c4H TM Refer to following table word R W parameter AO4t formi 10c5H ML Refer to following table word R W parameter AO transforming parameter settings 0 Frequency 1 Va 2 Vb 3 Vc 4 Average phase 5 Uab voltage 6 Ubc 7 Uca 8 Average line voltage 9 Line current of 10 Line current of 1 Line current of phase A phase B phase C 12 Average line current 13 Neutral current 14 Power of phase A 15 Power of phase B 16 Power of phase C 17 Power of all m Reactive power of i Reactive power of E Reactive power of phase A phase B phase C Reactive power of Apparent power of Apparent power of 21 22 23 all phaseA phase B 2 Apparent power of 35 Apparent power of 26 PF of A phase C all 27 PF of B 28 PF of C 29 PF AO1 Gradient r Number Selection of TT Gradient 10d0H input outpuctranster 1 2 2 Gradient INT P P 3 3 Gradient curve AO following value range setting start point 10d1H Please see Note INT AO following value i range setting point 2 INT AO following value 10d3H range setting point 3 INT fawim I See AO1 following value Od4H range setting end NT R W point AO type of 0 24A or 0 6 AO1 output range 0 4915 ae Duo setting start point AO type of 4 24A or 1 6 N RW 819 4915 Od6H AO1 output ra
84. 0mA or from 4to 20mA 2 digital outputs DO Can be used in alarm mode or energy pulse output mode Both ofthe digital outputs work in the same mode When it operates in energy pulse output mode it can output various types of energy The AXM IO3 module is composed of 4 digital inputs DI Each digital input can be used to detect remote signals or be used as an input pulse counter When it is used to detect remote signals it can also enable SOE sequence of events recording the events and time of the events 2 relay outputs RO Can be used for controlling or alarming Each of the relay outputs work in the same mode When it operates in controlling mode there are two output options latching mode and pulse When it operates in alarm mode it has only one latching output mode 2 analog inputs Al Can detect input analog voltage or analog current When it detects input analog voltage the range of voltage is from 0 to 5V or from 1 to 5V When it detects input analog current the range of current is from 0 to 20mA or from 4 to 20mA Bee I Seru leet Series A 110 5 1 2 List of Functions of IO Modules Detection of remote signals Recording of SOE Counting of input pulses Output remote controlling by relay Output alarm by relay Output alarm by digital output Output power pulses by digital output Analog output Analog input 24V isolated voltage output
85. 1 schedule word 8 Seagmentand Tariff TERES BBN Number of the 1 schedule word 9 Seagment and Tariff BREL EON Number of the 1 schedule word 10 Seagment and Tariff CSa SOIM Number of the 1 schedule Wo 11 Seagment and Tariff deol nod Number of the 1 schedule word 12 Seagment and Tariff 7865H 7867H Number of the 1 schedule werd 13 Seagment and Tariff 7868H 786AH Number of the 1 schedule word 14 Seagment and Tariff 786BH 786DH Number of the 1 schedule werd From 1 to 14 Segment Pemes 786EH 7897H and Tariff Number of the 2th x word 1 schedule schedule Bee J Sema fawim I See 256 From 1 to 14 Segment 7898H 78C1H and Tariff Number of the 3 The SOC a gt word R W schedule 1 schedule From 1 to 14 Segment eeen 78C2H 78EBH and Tariff Number of the 4 it word R W schedule 1 schedule From 1 to 14 Segment eect ade 78ECH 7915H and Tariff Number of the 5 a word R W schedule 1 schedule From 1 to 14 Segmen The carne 7916H 793FH and Tariff Number of the 6 word R W schedule 1st schedule From 1 to 14 Segmen The dmeas 7940H 7969H and Tariff Number of the 7 st word R W schedule 1 schedule From 1 to 14 Segmen The same as 796AH 7993H andTariff Number of the 8 st word R W schedule 1 schedule From 1 to 14 Segmen Th 7994H 79BDH and Tariff Number of the 9 ae sams as word R W schedule 1 schedule From 1 to 14 Segmen Th
86. 10Vac Accuracy 0 2 full scale Nominal Current 5 Aac 1 Aac Metering Range 0 10 A ac Withstand 20Arms continuous 100Arms for 1 second non recurring Burden 0 05VA typical amp 5Arms Pickup Current 0 196 of nominal Accuracy 0 296 full scale Accuracy Parameters Accuracy Resolution Rane Voltage 0 2 0 1V 20V 1000kV Current 0 2 0 001A 5mA 50000A Power 0 2 1W 9999MW 9999MW Reactive Power 0 2 1Var 9999MVar 9999MVar Apparent Power 0 2 1VA 0 9999MVA Power Demand 0 2 1W 9999MW 9999MW Reactive Power Demand 0 296 1Var 9999MVar 9999MVar Apparent Power Demand 0 2 1VA 0 9999MVA Power Factor 0 2 0 001 1 000 1 000 Frequency 0 2 0 01Hz 45 00 65 00Hz Energy Primary 0 2 0 1kWh 0 99999999 9kWh Secondary 0 2 0 001kWh 0 999999 999kWh Reactive Primary 0 2 O 1kvarh 0 99999999 9kvarh Energy Secondary 0 2 0 001kvarh 0 999999 999kvarh Apparent Primary 0 2 0 1kVAh 0 99999999 9kVAh Energy Secondary 0 2 0 001kVAh 0 999999 999kVAh Harmonics 1 0 0 1 gt 0 0 Phase Angle 2 0 0 1 0 0 359 9 Imbalance Factor 2 0 0 1 gt 0 0 Running Time 1second day 0 01h 0 9999999 99h Temperature Drift lt 100ppm C 0 596o year Control power Operating Range 100 415Vac 50 60Hz 100 300Vdc Burden 5W Withstand 3250Vac 50 60Hz 1min Installation Category III Distribution 277 Acmin T Series
87. 14 109eH DI1 6 type 0 Bit4 DIS Bit5 DIG word R W 0 DI 1 pulse counter 109fH DI pulse constant 0 1 65535 word R W 10a0H Working mode of relay 1 0 0 control output word Rw and 2 1 alarming output 10a1H Output mode of relay 1 0 0 latch 1 pulse word R W and 2 10a2H Pulse width 50 50 3000ms word R W AXM 1O21 2 0 5V 3 1 5V 0a3H DI7 10 type 0 Bit2 DI9 Bit3 DI10 word R W 0 DI 1 pulse counter 0a4H DI pulse constant 0 1765535 word R W 0a5H Working mode of DO 0 O pulse output word R W 1 alarming output 0a6H DO pulse width 20 20 1000ms word R W 0 none 1 consumption power 0a7H DO1 output 0 2 gererating power word R W 3 absorption reactive power 4 generating reactive power 0a8H DO2 output 0 Same as above word R W 0a9H AO12type Joco D ORAOmA Te 3520mA word R W AXM 1031 Bees I Seriu BitO DI11 Bit1 D112 10aaH DI11 14 type 0 Bit2 DI13 Bit3 DI14 word R W 0 DI 1 pulse counter 10abH DI pulse constant 0 1 65535 word R W 10acH Working mode of relay 3 0 0 control output word and4 1 alarming output 10adH Output mode of relay 3 0 0 latch 1 pulse word and4 10aeH Pulse width 50 50 3000ms word 0 0 20mA 1 4 20mA 10afH AI1 2 type 1or2 2 0 5V 3 1 5V word AXM 1012 Bit DI15 Bit1 DI16 Bit2 DI17 Bit3 DI18 10b0H DH5 20type O pita D119 Bit D
88. 220 0 v tT2 5 A MI A Directi 1 B Direction Positive Negative le Positive Negative C Direction Positive Negative Tum On the Backlight 0 Othe D0 Energy Pulse Const E min 1Puse 1 O 1kWh Demand Typ Thermal Demand Sliding Window Demand Demand 1Puses O 1kvath Averaging Interval Window fi EB min Energy Type 74 Energy Reading VAR PF Convention YAR Calculation Method Fundamental C Primary IEC C Method 1 True C Fund Harm Secondary C IEEE Method 2 Generalized SDE Enabled C None C AXM4011 C AXMJ021 C AXMJO031 AXMJO12 C AXM1022 C AXM4032 Fig 5 15 param 5 1 7 Pulse Counter eters setting of IO module s SOE function The digital input circuit can also be set to count pulses Recorded number of pulses including 4349H to 4380H address The 4349H to 4380H registers record 28 groups of individual number of individual number of pulses This includes 6 groups of records for AXM IO11 AXM IO1 module in logic Update Device Aawim I Seriu Bee I Series 126 NO 1 4 groups of records for AXM IO21 AXM IO2 module in logic NO 1 4 groups of records for AXM IO31 AXM IO3 module in logic NO 1 6 groups of records for AXM IO12 AXM IO1 module in logic NO 2 4 groups of records for AXM 1O22 AXM IO2 module in logic NO 2 and 4 groups of records for AXM
89. 3 0 range is 065534 Selectform1200 2400 4800 9600 19200 38400 bps Baud rate for external RS485 module Select from 4800 9600 19200 38400 bps Ethernet module and Profibus module only selects 38400 bps Voltage wiring mode can be one of 3LN 2LL 3LL 1LN or 1LL Current wiring mode can be one of 3CT CT CT PT1 primary nominal value of PT range from 50 0V 500 000 0V PT2 secondary nominal value of PT range from 50 0V 400 0V Ifno PT used setPT1 and PT2 as the nominal voltage of the meter CT primary value of CT range from 1A 50000A CT2 secondary value of CT choose from 1A or 5A When the PT is 0 333mV voltage type choose 333 Witch is active energy of each pulse from DO The pulse of each 1kWh energy can be set to 800 60000 pul kWh secondary Witch is reactive energy of each pulse from DO The pulse of each Tkvarh energy can be set to 800 60000 pul kvarh secondary The on time can be set from 0 to 120 Minute The backlight will always be on ifthe setting value is 0 Ifitis other value itmeans after thatlong time itwill goes offifno key has been pressed It will be on whenever you press any key ifitis off 1 sliding block 2 thermal Range from 1 30 minutes Yes clear No notclear ce S16 max min clear ce S17 run hour clear ce S18 11 direction c S19 12 direction ce 20 13 direction ce
90. 6 bit 0 word R W r 50 0 500000 0 1006H PT1 Low 16 bit 220 0 word R W 1007H PT2 220 0 50 0 400 0 word R W 1008H CT1 5 1 50000 word R W 1009H CT2 5 1 5 333 word R W 00aH kWh pulse constant 1 800 60000 word R W 00bH kvarh pulse constant 1 800 60000 word 100cH LCD backlight time 1 0 120 word O0dH Demand slid window time 15 1 30 word 00eH Demand calculating mode 1 Vstiding window word 2 thermal OOfH Clear demand memory 0 Only 1 works word 010H Max Min clear 55H Only OAH works word 011H Run time clear 0 Only 1 works word 012H Current 11 direction 0 Positive word Negative 013H Current I2 direction 0 9 Fositive word Negative 014H Current I3 direction 0 Positive word Negative 015H VAR PF convention 0 0 IEC 1 IEEE word 016H Energy clear 0 Only 1 works word 0 fundamental 017H Energy calculating mode 1 sf llsave word 018H Reactive power measuring 0 0 real 1 general word mode 019H Energy display mode 0 0 primary 1 secondary word 0 none 1 reset 101aH Ethernet module reset 0 2 load derauitandireset word 0 none 1 AXM IO11 101bH SOE enable 0 ZUAXM 102 T dE AXMAQ word 4 AXM 1012 5 AXM 1O22 6 AXM 1032 ceu I Series A O none 1 AXM IO11 2 AXM 1O21 3 AXM 1O31 101cH Pulse counter clear 0 4 AXM 1012 5 AXM 1022 word R W 6 AXM 1032 101dH Basic parameter mode 0 O secondary 1 primary word R W Aawin I Seriu No
91. 67H MAX of 12 F12 32768 32767 int i Time stamp yyyy mm E gt 4168H 416dH ddibbirimiss 3 time int 416eH MAX of I3 F12 32768 32767 int Time stamp yyyy mm E a 3 416fH 4174H ciens 3 time int 4175H MAX of system power F13 32768 32767 int Time stamp yyyy mm E 4176H 417bH deihhimmiss 3 time int 417cH MAX of system reactive pig 3276832767 int power Time stamp yyyy mm E 1 417dH 4182H ddiihimm ss 3 time int 4183H Qiii ia F15 32768 32767 int apparent power Time stamp yyyy mm E 1 i 4184H 4189H ddihsmmiss 3 time int 418aH MAX of power factor F16 32768 32767 int aman I Series A len Series A 230 Time stamp yyyy mm 418bH 4190H dd bliramss F3 time int 4191H MAX of frequency F10 32768 32767 int Time stamp yyyy mm e 3 4192H 4197H dd hhina 3 time int 4198H MAX of power demand F13 32768 32767 int Time stamp yyyy mm P i y 4199H 419eH dbhilammess 3 time int 419fH MAX of reactive BOWEN eng 25376633767 int demand Time stamp yyyy mm E 1 41a0H 41a5H ddihihimm ss 3 time int 41a6H MAX of apparent power ci 32768 32767 int demand Time stamp yyyy mm x s i 41a7H 41acH deabbihsmrmiss 3 time int 41adH MAX of voltage cgo 33768 32767 int unbalance factor Time stamp yyyy mm v y 41aeH 41b3H ddihlhimmiss 3 time int 41b4H MAX of current p17 3276832767 int unbalance factor Time stamp
92. 7295 dword R AXM IO12 4365H 4366H DI15 pulse counter number F 0 4294967295 dword R 4367H 4368H DI16 pulse counter number F 0 4294967295 dword R 4369H 436aH DI17 pulse counter number F 0 4294967295 dword R 436bH 436cH DI18 pulse counter number F 0 4294967295 dword R 436dH 436eH DI19 pulse counter number F 0 4294967295 dword R 436fH 4370H DI20 pulse counter number F 0 4294967295 dword R AXM IO22 4371H 4372H DI21 pulse counter number F 0 4294967295 dword R 4373H 4374H DI22 pulse counter number F 0 4294967295 dword R 4375H 4376H DI23 pulse counter number F 0 4294967295 dword R 4377H 4378H DI24 pulse counter number F 0 4294967295 dword R AXM 1032 4379H 437aH DI25 pulse counter number F 0 4294967295 dword R 437bH 437cH DI26 pulse counter number F 0 4294967295 dword R 437dH 437eH DI27 pulse counter number F 0 4294967295 dword R 437fH 4380H DI28 pulse counter number F 0 4294967295 dword R Al input value The output of Al is mapped to the range of 0 4095 according to its sampling value using some algorithm Data type is word Function code 03H for reading Please refer to Chapter 5 Extended Modules for more details 4385H Al1 sampling value 0 4095 word R 4386H Al2 sampling value F1 0 4095 word R 4387H Al3 sampling value F1 0 4095 word R 4388H Al4 sampling value F1 0 4095 word R AO output The output of AO is the actual v
93. DO addr DO addr Value Value CRC 16 CRC 16 T Lm HI LO HI LO HI LO 11H 05H 00H 00H FFH 00H 8EH AAH Response The normal response to the command request is to retransmit the message as received after the relay status has been altered Table 6 11 Control Relay Response Message Aawim I Seriu Relay addr Relay addr Value Value CRC CRC iauadal Fun HI LO HI LO HI LO 11H 05H 00H 00H FFH 00H 8EH AAH 5 Preset Reset Multi Register Function Code 16 Query Function 16 allows the user to modify the contents of a multi register Some registers of Acuvim II series meter can have their contents changed by this message The example below is a request to an Acuvim II series meter with the address of 17 to preset Ep imp as 17807783 3KWh while its HEX value is OA9D4089H Ep imp data address is 4048H and 4049H Table 6 12 Preset Multi Register Query Message Data start Data start Data of Data 0 Add Fi Byte Count d A reg HI reg LO reg HI reg LO oaa 11H 10H 40H 48H 00H 02H 04H Value HI Value LO Value HI Value LO CRC HI CRC LO OAH 9DH 40H 89H F1H 6AH Response The normal response to a preset multi register request includes the Acuvim II series meter address function code data start register the number of registers and error checking Table 6 13 Preset Multi Register Response Message Data start Dat
94. Data address of TOU parameter setting includes basis parameter of TOU time zone setting parameter of TOU time table setting parameter of TOU and holiday setting parameter of TOU Function 03 code 10 reset Table 6 26 data address of TOU Season Number 0 12 Acuovine I Series default is 0 7801H Schedule Number 0 14 Word 7802H Segment Number 0 14 Word 7803H Tariff Number 0 3 Word Weekend Setting bit0 Sunday bit1 7804H bit6 Monday Saturdaybit 1 means 0 127 Word using energy bit 0 means not using energy 7805H Weekend Schedule 0 14 Word 7806H Holiday Number 0 30 Word 7807H Time of Use factory setting 1 enable Word Choice of calculation auto reset 7808H 0 End of Momth 1 enable Word TOU auto reset fixed date day 7809H default is 1 Word TOU auto reset fixed date hour 780AH default is 0 1431 Word 780BH TOU auto reset fixed date minute 0 23 Word default is 0 780CH TOU auto reset fixed date second 0 59 Word default is 0 780DH TOU auto reset fixed date second 0 59 Word Bee I See 254 0 the setting of parameter is correct 1 tariff setting error 2 schedule setting error 4 segment setting error 8 season setting error 16 parameter of season setting error 780EH Error Code default 32 holiday setting error 64
95. E18H The 19 holiday and schedule word R W 7E19H 7E1BH The 20 holiday and schedule word R W 7E1CH 7E1EH The 21 holiday and schedule word R W 7E1FH 7E21H The 22 holiday and schedule word R W 7E22H 7E24H The 23 holiday and schedule word R W 7E25H 7E27H The 24 holiday and schedule word R W 7E28H 7E2AH The 25 holiday and schedule word R W 7E2BH 7E2DH The 26 holiday and schedule word R W 7E2EH 7E30H The 27 holiday and schedule word R W 7E31H 7E33H The 28 holiday and schedule word R W 7E34H 7E36H The 29 holiday and schedule word R W 7E37H 7E39H The 30 holiday and schedule word R W 7E3AH The 9 setting year word R W 7E3BH Holiday number of the 9 year word R W The 1 holiday and schedule TE3CHS E3EH format month day schedule word RAW 7E3FH 7E41H The 2 holiday and schedule word R W 7E42H 7E44H The 3 holiday and schedule word R W 7E45H 7E47H The 4 holiday and schedule word R W 7E48H 7E4AH The 5 holiday and schedule word R W 7E4BH 7E4DH The 6 holiday and schedule word R W 7E4EH 7E50H The 7 holiday and schedule word R W 7E51H 7E53H The 8 holiday and schedule word R W 7E54H 7E56H The 9 holiday and schedule word R W 7E57H 7E59H The 10 holiday and schedule word R W 7E5AH 7ES5CH The 11 holiday and schedule word R W 7E5DH 7E5FH The 12 holiday and schedule word R W 7E60H 7E62H The 13 holiday and schedule word R W 7E63H 7E65H The 14 holida
96. Eo XC B Ey N S1 S2 531 2 DI Triggering Waveform Capture Acmin T Seriu DI 111 Disabled x D1112 Disabled x D1113 Disabled EZ DI 114 Disabled x D1115 Disabled x bitt amp Disabled z DI 211 Disabled x D1212 Disabled xl D1212 Disabled x D1214 Disabled zi DI 311 Disabled 01312 Disabled z DI 313 Disabled x 01314 Disabled El Rated Voltage 400 v Rated Curent 1 A Voltage Swell T Over Current Triggering Waveform Capture Theshold 100 Threshold 100 x T Triggering Waveform Capture Voltage Sag E Note Level Threshold 50 x Voltage swells and voltage sags wil trigger the event log Hal cycle Threshold 10 Halicycle I Triggering Waveform Capture Save Load Update Device Fig 4 12 4 Event Log Retrieve When a new event log commences the newest event number address OX8CFDH contains the newest event number When the log is being retrieved the starting event log number OX8CFEH and the event quantity for each retrieve OX8CFF must be set correctly It must be ensured that the starting number of event log should equal or smaller than the newest log number When setup is correct reading registers OX8D00H OX8D4FH will acquire the event log data Each time a maximum of 10 logged events can be retrieved The event log retrieve page is in the figure below The Modbus register address of the event log is in the table belo
97. I20 Word 0 DI 1 pulse counter 10b1H DI pulse constant high 0 1265535 word 10b2H Working mode of relay 5 0 0 control output Word and 6 1 alarming output 10b3H Output mode of relay 5 0 0 latch werd and 6 1 pulse 10b4H Pulse width 50 50 3000ms word AXM IO22 BitO DI21 Bit1 DI22 10b5H DI21 24type 0 Bit2 DI23 Bit3 DI24 word 0 DI 1 pulse counter 10b6H DI pulse constant 0 1 465535 word aman Series A 220 Working mode of 0 pulse output 1057H DO3 4 9 1 alarming output word R W 10b8H DO Pulse width 20 20 1000ms word R W 0 none 1 consumption power 2 gererating power 10b9H DO3output 0 3 absorption reactive word R W power 4 generating reactive power 10baH DO4 output 0 Same as above word R W 0 0 20mA 1 4 20mA 10bbH AO3 4 type 1or2 2 0 5V 3 1 5V word R W AXM 1032 BitO DI25 Bit DI26 10bcH DI25 28 type 0 Bit2 DI27 Bit3 DI28 word R W 0 DI 1 pulse counter 10bdH Dl pulse constant 0 1465535 word R W 10beH Working mode of relay 0 0 control output word RAW 7and8 1 alarming output 10bfH Output mode of relay 0 0 latch 1 pulse word R W 7and8 10cOH Pulse width 50 50 3000 word R W 0 0 20mA 1 4 20mA 10c1H AI3 4 type 1or2 2 0 5V 3 1 5V word R W AO transforming select 10c2H AOT transforming 0 Refer to following table word R W parameter AO2t formi 1
98. IEC 61010 1 UL 61010 1 EMC Standard IEC 61000 4 2 3 4 5 6 8 11 CISPR 22 Outlines Standard DIN 43700 ANSI C39 1 279 Bee I Seriu 2 wire connection RS 485 Standard MODBUS RTU Protocol or DNP3 0 Protocol Up to 38400 baud rate 10M 100M BaseT MODBUS TCP IP Protocol Data Browsing through HTTP Sends e mail automatically PROFIBUS DP VO Protocol Work as PROFIBUS slave baud rate adaptive up to 12M Typical input bytes 32 typical output bytes 32 PROFIBUS standard according to EN 50170 vol 2 2 wire connection RS 485 Optional MODBUS RTU Protocol Up to 38400 baud rate 2 wire connection BACnet Protocol RJ45 BACnet Protocol Aawin I Series Ethernet Optional PROFI BUS Optional BACnet MS TP Optional BACnet IP Optional Appendix B Ordering Information Acuvim ll series meter DIN Rail Option Frequency Current Input Power Supply P1 100 415Vac 50 60Hz 100 300Vdc P2 20 60Vdc I 5A 5Amp 1A 1Amp 333mv Voltage type Acmin T Seriu 50 50Hz 60 60Hz D Standard with LCD display M DIN rail mount no LCD I Acuvim Il I Acuvim IIR I Acuvim IIE L Acuvim IIW Acuvim Il Base Meter Ordering Example Acuvim IIR D 60 5A P1 I O Option module Module 1 ENEN d Module 2 281 Aawin I Series
99. N 5652 Sal fawim I Series Volts AN oov Volts AB oov lA 0 00004 Volts BN oov Volts BC oov 18 aoma Vote CN 000v Volts CA oov Ic 0 00004 Volts LN Average 0 00 V Volts LL Average 000V l Average 0 00004 Watt A 0 00000 kW VARA 00000kvar VAA 0 00000 kVA Walt B 0 00000 kw n wate 6 00000 kw Search Device s in LAR Watt Total 0 00000 kw Pw FactorA 1 000 Pwr Factor B 1 000 PwractrC 1 000 PwrFactorTolal 1 000 Dmd Watt Total 0 00000 kW DmdlA 0 00004 DmdiB 0 00004 DmdlC 0 00004 Fig 5 40 Note This function is used only in LAN not used in WAN or direct connect to computer 5 2 10 Description of Modbus TCP protocol The Modbus TCP protocol is used for communication in Ethernet modules The protocol sets up master slave link in Ethernet First master device client sets up TCP link with slave device server Second master device sends request frame to slave device and slave device receives request frame and returns response frame to master device Figure 5 41 displays working mode of Modbus TCP protocol Request Indication a gt Modbus Client Modbus Server re Confirmation Response E Fig 5 41 x 1 Protocol a Data Frame Format Table 5 1 MBAP Header Function Data 7x8 Bits 8 Bits Nx8 Bits b Modbus Application Header MBAP Header Field The Modbus application header field is the start of the data frame and consists of seven byt
100. NA Cy IOo o O Chapter 2 Installation 2 1 Appearance and Dimensions 2 2 Installation Methods 2 3 Wiring 2 3 1 Terminal Strips 2 3 2 Power Requirements 2 3 3 Voltage Input Wiring 2 3 4 Current Input Wiring 2 3 5 Frequently Used Wiring Methods 2 3 6 Communication I Sexe Considerations When Installing Meters Awam Installation of the meter must be performed by qualified personnel only who follow standard safety precautions through the installation procedures Those personnel should have appropriate training and experience with high voltage devices Appropriate safety gloves safety glasses and protective clothing are recommended A 2 During normal operation dangerous voltage may flow through many parts of the meter including terminals and any connected CTs Current Transformers and PTs Potential Transformers all I O Inputs and Outputs modules and their circuits All primary and secondary circuits can at times produce lethal voltages and currents AVOID contact with any current carrying surfaces The meter and its I O output channels are NOT designed as primary protection devices and shall NOT be used as primary circuit protection or in an energy limiting capacity The meter and its I O output channels can only be used as secondary protection AVOID using the meter under situations where failure of the meter may cause injury or death AVOID using the meter for any application where risk of f
101. P at the last screen The following figure shows the sequence m 1D 3 ph power and3 ph power total Y D 3 ph reactive power and ph reactive power total tD 3 ph apparent power and 3 ph apparent power total y 3 ph power factor CP total power tota reactive power total apparent power Y C2 system power factor and frequency CP Note When the meter is set to 2LL or 3LL only the fifth screen system power and the sixth screen system power factor amp frequency will be displayed When the meter is set to 1LN there are only phase A power and phase A power factor display Beca I Serier When the meter is set to 1LL there are no phase C power and phase C power factor display c Phase Angles and Unbalance Press H to display phase angles and unbalance data The screen will roll to the next page when H is pressed again It will go back to the first screen if you press H at the last screen The following figure shows the sequence Unbalance factor j Voltage phase angle Y H Current phase angle EL CH When using 2LL or 3LL wiring setting mode voltage stands for line to line voltage Otherwise voltage stands for line to neutral voltage When the meter is set to 1LN there is only phase A current to phase A voltage angle display fawim I Series When the meter is set to 1LL
102. Page Data Settings Password Module Status Submit Reset Fig 5 44 b Network Settings Webpage Figure 5 45 Network Settings webpage It supports two network setting modes Manual or Auto There are two port settings HTTP port and Modbus TCP port Bee I Seriu The default value of Modbus TCP port is 502 and the user defined range is 2000 5999 The default value of HTTP port is 80 and the user defined range is 6000 9999 E Metering Webserver ACTUZEAGY Main Page Data Settings Network Parameter Configuration Module Status Manual Setting Auto Setting Network Parameter IP Address 192 168 1 43__ Example 192 168 1 254 Subnet Mask 255 255 255 0 Example 255 255 255 0 Gateway 192 168 1 t Example 192 168 1 1 DNS Primary Server 12 168 1 4 txampie 202 105 0 20 DNS Secondary Server 192 168 16T Example 202 106 196 115 Port Setting MODBUS Port 502 _ Default 502 Scope 2000 5999 HTTP Port 80 petautt 80 scope 6000 9999 Sub Fig 5 45 fawim I See c Mail Settings Webpage Figure 5 46 Mail Settings webpage Users can choose between 4 mail sending modes Triggerd Sending Timed Sending both Triggered and Timed Sending and None Boxes marked with cannot be left blank Triggered Sending means users will receive mail
103. Read the data window 4 Read the data window and compute next Expected Record offset Compute the next expected record offset by adding Records Per Window and go to step 2 e If there are no remaining records after the current record window stop reading 6 3 8 Time of use Data address of TOU energy The data address save the parameter of energy which includes Data address of last month TOU energy Data address of current month TOU energy Data address of TOU parameter setting and Data address of TOU default parameter Except for the data address of TOU default parameter the data address is read with 03 code preset with 16 code Data address of prior month TOU Data add f t a msnm A rL Basis parameter of TOU eason parameter setting of TOU Data address of Data address of TOU P TOU energy pa rametersetting Schdule setting of TOU Holiday setting of TOU asis default parameter of TOU Dataadeese ot TOU eason default parameter setting of TOU default parameter Schedule default setting of TOU oliday default setting of TOU Fig 6 1 Division plan of TOU energy 247 Aidit Sot fawim I See Type of addres
104. The 30 holiday and schedule word R W 7D82H The 7 setting year word R W 7D83H Holiday number of the 7 year word R W The 1 holiday and schedule cDEAT A DRN format menih sy time table word RAN 7D87H 7D89H The 2 holiday and schedule word R W 7D8AH 7D8CH The 3 holiday and schedule word R W 7D8DH 7D8FH The 4 holiday and schedule word R W 7D90H 7D92H The 5 holiday and schedule word R W 7D93H 7D95H The 6 holiday and schedule word R W 7D96H 7D98H The 7 holiday and schedule word R W 7D99H 7D9BH The 8 holiday and schedule word R W 7D9CH 7D9EH The 9 holiday and schedule word R W 7D9FH 7DA1H The 10 holiday and schedule word R W 7DA2H 7DA4H The 11 holiday and schedule word R W 7DA5H 7DA7H The 12 holiday and schedule word R W 7DA8H 7DAAH The 13 holiday and schedule word R W 7DABH 7DADH The 14 holiday and schedule word R W 7DAEH 7DBOH The 15 holiday and schedule word R W 7DB1H 7DB3H The 16 holiday and schedule word R W 7DB4H 7DB6H The 17 holiday and schedule word R W The 1 holiday and schedule 7DB7H 7DB9H The 18 holiday and schedule word R W 7DBAH 7DBCH The 19 holiday and schedule word R W 7DBDH 7DBFH The 20 holiday and schedule word R W 7DCOH 7DC2H The 21 holiday and schedule word R W 7DC3H 7DC5H The 22 holiday and schedule word R W 7DC6H 7DC8H The 23 holiday and schedule word R W 7DC9H 7DCBH The 24 holiday and schedule word R W 7DCCH 7DCEH The 25 holiday
105. This number will equal the Max Records when the log has filled This value will be set to 1 when the log is reset Record Size The number of bytes in this record including the time stamp The record s format in the meter is record number 4bytes time stamp 6bytes data1 dataN 2Nbytes CRC 2bytes First Record Time stamp Time stamp of the oldest record Last Record Time stamp Time stamp of the newest record Log Retrieval Block The log retrieval block consists of 2 parts the header and the window The header is used to verify the data shown within the requested log window The window is a sliding block of data that can be used to access any record in the specified log Registers 6000H 6003H Size 4 Registers Nnnnnnnn log type 6000H Log type R W SSSSSSSS reserve d b 6001H Record number RAW nnnnnnnn record number status WWWWWWWW status 6002H 6003H offset R W 6004H 607eH window R Log type The log to be retrieved Write this value to set which log is being retrieved 0 Historical Log 1 1 Historical Log 2 2 Historical Log 3 Records number The number of records that fit within a window This value is settable any number less than a full window may be used This number tells the retrieving program how many records to expect to be fetched in the window record number x Record Size bytes used in the window This value should be 123 x 2 Recor
106. When the clock starts to run to daylight saving time the meter will automatically adjust the clock to a time period in advance while the clock is running to the end of daylight saving time meter will automatically adjust the clock pushed back to a time period as shown in Fig 4 10 Daylight Saving Time IV DST Enable DST Format Format Format 1 DST Start Apr 1 Day 12 How 25 Min Adjust Time 5 Minutes DST Ending a 2 Day 0 Hour 12 Min Adjust Time 45 Minutes M Format 2 DST Start Ma ljea ru ja Uo p Adjust Time 2 Minutes DST Ending Apr T 2nd Sun at IE p35 Adjust Time 60 Minutes Fig 4 10 Daylight saving time setting interface 10 Ten year Holiday setting Users can preset holidays of the next decade via the meter software The holiday format is month day year holiday code holiday schedule After the format setup click on Make Holiday Settings 10 year then a holiday table for the next decade will be generated Holiday Auto Switch When Ten year Holiday is enabled if the current year of the meter falls into the Ten year Holiday setting it automatically loads the Ten year Holiday settings into the current TOU settings If the current year of the meter does not fall into the Ten year Holiday setting it remains the current TOU 3 i settings 3 IV Enable Holidays Years Settings Start Year 2010 EndingYear 2019 mist Year Ho
107. a Address Table and Application Details 6 3 1 System Parameter Setting 6 3 2 System Status Parameter 6 3 3 Date and Time Table 6 3 4 Over Under Limit Alarming Setting 6 3 5 I O Modules Settings 6 3 6 Metering Parameter Address Table 6 3 7 Data Logging 6 3 8 Time of use fawim I Series 9 This chapter will mainly discuss how to handle the meter via the communication port using software Itis highly recommanded that previous chapters be read before moving onto Chapter 5 a familiarity with Modbus would also be helpful Modbus Protocol Introduction Modbus RTU protocol is used for communication in Acuvim II series meters Data format and error check methods are defined in Modbus protocol The half duplex query and respond mode is adopted in Modbus protocol There is only one master device in the communication network The others are slave devices waiting for the query of the master Transmission mode The mode of transmission defines the data structure within a frame and the rules used to transmit data The mode is defined in the following which is compatible with Modbus RTU Mode Framing Table 6 1 Data Frame Format Address Function Data Check 8 Bits 8 Bits Nx8 Bits 16 Bits Coding System 8 bit binary Start bit 1 Data bits 8 Parity no parity odd parity even parity Stop bit 1or2 Error checking CRC check Address Field The address field of a message frame co
108. a mode scroll the cursorto Max Min then press V A In statistics data mode the meter displays the maximum values and minimum values for voltage current power power factor unbalance demand THD etc User should note that time stamp for the parameters can be viewed only from the software through communication No commands are associated with the key Hin Max Min display mode When P is pressed again the screen will roll to the next page and will roll back to the first screen when pressed atthe last page When E is pressed the screen will roll back to the previous page and will roll back to the last screen when pressed at the first page Press V A to switch the view between maximum and minimum For example ifthe current display is the maximum phase voltage value when V A is pressed the display will show the minimum phase voltage value If V A is pressed again the display will switch back to show the maximum phase voltage value The following figure shows the sequence ja CP Max value of phase voltage Max value of the line to line voltage y CPD Max value of current Ss CP Max value of power Max value of CP unbalance factor Max value of power CP factor amp frequency Note i The figure shows the rolling sequence when pressing P The sequence will be reversed when pressing E ii When the meter is set to 2LL or 3LL the first screen max
109. a start Data of Data of CRC16 reg hi reg lo reg hi Reg lo hi 11H 10H 40H 48H 00H 02H D6H Addr Fun 6 3 Data Address Table and Application Details There are several rules to follow in using the meter 1 Data type fawim I See bit refers to binary word refers to 16 bit unsigned integer using one data address and 2 bytes of memory it varies from 0 to 65535 int refers to 16 bit integer using one data address and 2 bytes of memory it varies from 32768 to32767 dword refers to 32 bit unsigned integer using two data addresses and 4 bytes of memory with high word at the front and low word at the end it varies from 0 to 4294967295 Rx high word 65536 low word float refers to 32 bit single value using two data addresses and 4 bytes of memory it varies from 1 175494E 38 to 3 402823E 38 2 Relationship between communication value and numerical value It is important to note the numerical value may not be the same as the communication value The following table shows how they respond to each other Note In current channel CT are optional which include voltage type CT or current type CT 1 When current type CT is selected and the value of CT2 is 1 or 5 and using relationship listed below to count primary value the value of CT2 should be original 1 or 5 2 When voltage type CT is selected and the value of CT2 is 333 and using relationship listed b
110. alue of output There are 2 output options for AO V or mA Over under limit or Data type is float Function code 03H for reading Please refer to Chapter 5 Extended Modules for more details 4389H 438aH Value of A01 float R 438bH 438cH Value of A02 F1 float R 438dH 438eH Value of A03 F1 float R 438fH 4390H Value of A04 F1 float R SOE Records There are 20 groups of records with the same format Function code 03H for reading Before gathering SOE records the selected I O module must be SOE enabled If the SOE enabled I O module is not connected SOE record logs will not be collected Please refer to Chapter 5 Extended Modules for more details im Sena faw lee Series A 236 First group time stamp 42930439M yyyy mm dd hh mm ss ms word n 43a0H First group DI status F1 word R 43a1H 4438H 2 to 20 group word R O none T AXM IOT 1 2 AXM 1O21 4439H 1 0 module of SOE F1 3 AXM 1O31 word R 4 AXM 1012 5 AXM 1O22 6 AXM 1032 Current demand Include real time current demand the maximum current demand and time of occurance Function code 03H for reading 4600H 4601H Phase A current demand F1 I Rxx CT1 CT2 float R 4602H 4603H Phase B current demand F1 I Rxx CT1 CT2 float R 4604H 4605H Phase C current demand F1 I Rxx CT1 CT2 float R aspe MaxofPhaseAcurrent pis
111. an error will be reported CRC calculation is first started by preloading the whole 16 bit register to 1 s The process begins by applying successive 8 bit bytes of the message to the current contents of the register Only the eight bits of data in each character are used for generating the CRC Start and stop bits and the parity bit do not apply to the CRC When generating the CRC each 8 bit character is exclusive ORed with the register contents The result is shifted towards the least significant bit LSB with a zero filled into the most significant bit MSB position The LSB is extracted and examined if the LSB equals to 1 the register is exclusive ORed with a preset fixed value if the LSB equals to 0 no action will be taken This process is repeated until eight shifts have been performed After the last eighth shift the next 8 bit byte is exclusive ORed with the register s current value and the process repeats for eight more shifts as described above After all the bytes of the message have been applied the final contents of the register which should exchange the high byte and the low byte is the CRC value When the CRC is appended to the message the low order byte is appended first followed by the high order byte Bee I Seru 6 2 Communication Format Explanation of frame Table 6 3 Explanation of frame Addr Fun Data start Data start Data of Data of CRC 16 CRC 16 reg HI reg LO regs HI regs LO HI LO
112. ange setting start point Y1 AO1 output value range setting point 2 Y2 AO1 output value range setting point 3 Y3 and AO output value range setting end point Y4 are increasing value while they should be within range of AO output value When AO type is 0 20mA the corresponding range is 0 24mA the setting value range is 0 4915 and the relationship is mA setting value 20 4096 When AO type is 4 20mA the corresponding range is 4 24mA the setting value range is 819 4915 and the relationship is mA setting value 20 4096 When AO type is 0 5V the corresponding range is 0 6V the setting value range is 0 4915 and the relationship is V setting value 5 4096 When AO type is 1 5V the corresponding range is 1 6V the setting value range is 819 4915 and the relationship is V setting value 5 4096 Please note a gt If the voltage input wiring of the meter is 2LL or 3LL then the analog outpus relative to phase voltage neutral current phase active reactive apparent power and phase power factor will always be 0 b The maximum of analog output is 1 2 times the range 2 Display of Analog Output Bee J Sema Value of analog output is displayed in hex on screen The relationship between displayed value and real value of analog output is Displayed Value Real value x20mA current output mode 4096 Displayed Value or Real value x5V voltage output mod
113. aveform record reasons another retrieve all data of one group waveform Two methods are shown below First retrieving method is only retrieving waveform record reasons When 0x8E01H Waveform Group Number is set to 0 waveform record reason can be retrieved from data retrieving window by changing Waveform Group Number for Retrieving BEO0H Waveform record reason is 16 bytes and data window are 64 bytes so that is the reason why each retrieving access include 4 group records For example if the total number of Waveform Group Number for Retrieving is 19 the by this method only through 5 times retrieving all 20 groups waveform can be retrieved Before retrieving user should write 0 to 8E01H and 1 to 8E00H while at first time retrieving addresses from 8E00 to 8E43 these window data are the reasons of waveform group 1 2 3 4 After retrieving Waveform Group Number for Retrieving BEO0H will automatically update to 5 While at second time retrieving addresses from 8E00 to 8E43 these window data are the reasons of waveform group 5 6 7 8 Waveform Group Number for Retrieving BEO0H will stop increasing after the value reaches 17 Note Unless user retrieves all data from 8bE00H to 8E43H in one time Waveform Group Number for Retrieving 8E00H will automatically add 4 otherwise Waveform Group Number for Retrieving BEO0H will keep present value if only retrieving partial data Waveform Group Number for Retrieving BEOOH will stop
114. cH 759fH Max of Ic all demand and time stamp 32768 32767 Int 2 The address area include Daylight saving time DST setting Function 03H Read 10H Preset Bee J Sema Bee I Series 252 7700H DST enable pale Word Rw 1 enable 7701H DST format ee Word R W 1 format 2 Format 1 7702H DST Start Mon 1 12 Word R W 7703H DST Start Day 1 31 Word R W 7704H DST Start Hour 0 23 Word R W 7705H DST Start Min 0 59 Word R W 7706H DST Start Adjust time Unit Min 14120 Default 60 Word R W 7707H DST Ending Mon 1412 Word R W 7708H DST Ending Day 1431 Word R W 7709H DST Ending Hour 0 23 Word R W 770AH DST Ending Min 0 59 Word R W 770BH DST Ending Adjust time Unit Min 1 120 Default 60 Word R W Format 2 770CH DST Start Mon 1 12 Word R W 0 6 0 Sunday 770DH DST Start week 1 6 Monday to Word R W Saturday 770EH DST Start First few weeks 145 Word R W 770FH DST Start Hour 0 23 Word R W 7710H DST Start Min 0 59 Word R W 7711H DST Start Adjust time Unit Min 1 120 Default 60 Word R W 7712H DST Ending Mon 1412 Word R W 0 6 0 Sunday 7713H DST Ending Week 1 6 Monday to Word R W Saturday 7714H DST Ending First few weeks 145 Word R W 7715H DST Ending Hour 0 23 Word R W 7716H DST Ending Min 0 59 Word R W 7717H DST Ending Adjust time Unit Min 1 120 Default 60 Word R W
115. communication way if they can be accessed before but in sealed status these parameters cannot be modified by keys or communication way any more fawim I Serin Addresses about seal function are 101EH and 101FH Address 101EH is about parameters blocked by seal which can be configured by users These setting will be valid only when seal is in sealed status Address 101FH is about if seal function is valid When the panel is normal one or the seal panel is in invalid sealed status this address will show seal is open When the seal is valid this address will show sealed status and corresponding parameters will be blocked BitO 1st communication parameters Bit1 2nd communication parameters Sealed Nonstandard Bit2 run time clear Parameters Selection Bit3 DI pulse count Bit4 TOU 1 valid of corresponding selection 0 invalid Ox0A Seal sealed Other Seal opened 101EH 101FH Seals status Parameters blocked by seal As long as seal is in sealed status parameters below must be blocked no matter what value of address 101EH System parameters setting 1003H Voltage input wiring J 3 type Current input wiring 1004H ype Vv y 1005H PT1 High 16 bit Vv Vv 1006H PT1 Low 16 bit y y 1007H PT2 Y Vv 1008H cn v v 1009H CT2 y y 100AH kWh pulse constant X Vv 100BH Kvarh pulse constant y Vv Demand slid window 100DH
116. contains the high order bits and the second contains the low order bits It is important to note The response has a 16 word frame so the maximum quantity of registers should less than 15 Otherwise it will return an error result Aawim I Seriu Example reading 3 measured data F V1 V2 from Acuvim II meter The data address of F includes 4000H and 4001H The data address of V1 includes 4002H and 4003H The data address of V2 includes 4004H and 4005H Use 7 channels Query 07H 03H 40H 00H 00H 06H 00H Response C7H CCH CDH 42H C8H 33H 33H 00H F 42480000H 50 00HZz V1 42C7CCCDH 99 9v V2 42C83333H 100 1v Note the relationship between the numerical value in the register of the meter and the actual physical value is described in detail in Chapter 6 5 3 16 Format of function code 10H This function code is used in MODBUS RTU to write a block of continuous registers in the Acuvim Il meter such as system parameters setting and so on In PROFIBUS DP the format of function code 10H is defined as follows I Sexe Query HORAM s FAH Byte2 10H Byte3 starting address high byte Byte4 starting address low byte Byte5 quantity of registers high byte Byte6 quantity of registers low byte Byte7 byte count Byte8 register value 1 high byte Byte9 register value 1 low byte Byte10 register value 2 high byte Byte11 register value 2 low byte Byte32 0
117. ctly to use the SMTP functions CSeHmg NOS e wo me M x Li L3 Load n LI Nap Tic t PIRE 724 004 Eix Eix axe a Fig 5 33 8 Set DNS Secondary Server in the sixth setting page such as 202 106 196 115 Press the V A key to go to the setting page Users may set the parameters pointed out in Figure 5 34 The cursor starts at the first digit After setting the DNS Secondary Server press the V A key to accept Press the P key to go to the seventh setting page for the Modbus TCP port Note the DNS paramters must be set correctly in order to use the SMTP functions Noe eg Ly oe ae I ri Z x ne LI LL Load Li Z i 2 D lu DENN tl INSE HD Mx Exe ma Fig 5 34 151 Bee J Sema Reeve I Series 152 9 Set Modbus TCP port in the seventh setting page such as 502 Press the V A key to go to the setting page Users may set the parameters pointed out in Figure 5 35 The cursor starts at the first digit After setting the Modbus TCP port press the V A key to accept Press the P key to go to the eighth setting page for the HTTP port The Modbus TCP port s default value is 502 and the user defined range of port is 2000 5999 If the set port is not in the correct range the set port will return to the default value siTe MOT Maud mmo T ae FEBR ai gsi M xe Be Mx2 W 2 ra Fig 5 35 10 Set HTTP port in the eig
118. d word 42a8H Reserved word Alarming records There are 16 groups of records with the same format Function code 03H for reading 10H for writing Please refer to Chapter 4 for more details 42a9H First group alarming status F1 0 65535 word 42b3H 42bcH Second group Same as the first group 42bdH 42c6H Third group Same as the first group 42c7H 42d0H Fourth group Same as the first group 42d1H 42daH Fifth group Same as the first group 42dbH 42e4H Sixth group Same as the first group 42e5H 42eeH Seventh group Same as the first group 42efH 42f8H Eighth group Same as the first group 42f9H 4302H Ninth group Same as the first group 4303H 430cH Tenth group Same as the first group 430dH 4316H Eleventh group Same as the first group 4317H 4320H Twelfth group Same as the first group 4321H 432aH Thirteenth group Same as the first group 432bH 4334H Fourteenth group Same as the first group 4335H 433eH Fifteenth group Same as the first group 433fH 4348H Sixteenth group Same as the first group Counting number of I O Modules T Sexe A2aaH First group alarming F1 0 50 Word R parameter code A2abH First group over under limit F10 F18 Related with word R N or reset value parameters p First group Time stamp E deach tenet
119. d Size rounded down The greater this number is the faster the retrieving speed is For example with a record size of 50 the Records number 123 x 2 50 4 92 4 Status The status of the current window Since the time to prepare a window may exceed an acceptable Modbus delay 1 second this acts as a ready status flag to notify when the window is ready for retrieval When this value indicates that the window is not ready the data in the window should be ignored Window Status is Read only any writes are ignored This value also indicates the memory erasing status when setting the date logging settings bH Window is Ready FFH Window is Not Ready aaH memory is erasing bbH memory erasing is finished Bee I Seru fawim I Series Offset The offset of the record number of the first record in the data window and the record number of the first record time stamp Setting this value controls which records will be available in the data window When the log is retrieved the first oldest record is latched This means that offset 0 will always point to the oldest record at the time of latching Window The actual data of the records arranged according to the above settings Note If the logging timer is disabled the first recording sector will be erased when the log is full Therefore user should not read the whole log when the used record numer is near to the max record number Under this condi
120. d and time stamp 32768 32767 7558H 755bH Max of Ib valley demand and time stamp 32768 32767 755cH 755fH Max of Ic valley demand and time stamp 32768 32767 nt 7560H 7563H Max of Ep_imp normal demand and time stamp 32768 32767 nt D D aD avD aD 7564H 7567H Max of Ep_exp normal demand and time stamp 32768 32767 nt 7568H 756bH Max of Eq_im normal demand and time stamp 32768 32767 nt 756cH 756fH 7570H 7573H 7574H 7577H 7578H 757bH 757cH 757fH Max of Eq exp normal demand and time stamp Max of Es normal demand and time stamp demand and time stamp Max of Ib normal demand and time stamp Max of la normal Max of Ic normal demand and time stamp 32768 32767 32768 32767 32768 32767 32768 32767 32768 32767 nt nt Int Int Int 7580H 7583H Max of Ep imp all demand and time stamp 32768 32767 Int 7584H 7587H Max of Ep exp all demand and time stamp 32768 32767 Int 7588H 758bH Max of Eq im all demand and time stamp 32768 32767 Int 758cH 758fH Max of Eq exp all demand and time stamp 32768 32767 Int 7590H 7593H Max of Es all demand and time stamp 32768 32767 Int 7594H 7597H Max of la all demand and time stamp 32768 32767 Int 7598H 759bH Max of Ib all demand and time stamp 32768 32767 Int DD DI DDI DDI Dalal aa 759
121. d be used under high power fluctuation conditions Terminals for the control power supply are 11 12 and 13 L N and Ground A switch or circuit breaker shall be included in a building installation It shall be in close 17 Bee I Seru fawim I Series proximity to the equipment within easy reach of the operator and shall be marked as the disconnecting device for the equipment 1 AFUSE o OL Power Supply o On Acuvim II Grond O Fig 2 7 Power supply A fuse typical 1A 250Vac should be used in the auxillary power supply loop No 13 terminal must be connected to the ground terminal of the switchgear An isolated transformer or EMC filter should be used in the control power supply loop if there is a power quality problem in the power supply 1 AFUSE J NOTE o Ou LOH Power Supply A filter should be o 0 NO used if there is Oe cO an EMI problem EMC Filter Fig 2 8 Power supply With EMC filter Choice of wire of power supply is AWG22 16 or 0 6 1 5mm Voltage Input Acuvim Il Maximum input voltage for the Acuvim II series meter shall not exceed 400LN 690LL VAC rms for three phase or 400LN VAC rms for single phase Potential Transformer PT must be used for high voltage systems Typical secondary output for PTs shall be 100V or 120V Please make sure to select an appropriate PT to maintain t
122. d for those parameters For example In order to record Volts AN into the historical log Volts AN s Modbus address 4002H and 4003H are assigned and programmed to the log record list so that information can be stored into the historical log registers Each unused register item should be set to 0000H or FFFFH to indicate no parameters are associated with them The actual size of the record and the number of items in the register list which are used is determined by the registers in the header e Valid register address ranges that can be recorded in the historical log registers are 4000H 412BH 4294H 42A8H 4349H 4398H 4500H 461BH 3 Item Descriptor List Registers 1177H 11B1H Size 1 byte per item 117 bytes 59 registers While the register list describes what to log the Item descriptor list describes how to interpret that information Each descriptor describes how many Modbus addresses are used to describe a parameter Either 1 or 2 addresses will be used for each parameter For example If the first descriptor is 2 and the second descriptor is 1 then the first 2 register items belong to the 1 descriptor and the 3 register item belongs to the 2 descriptor NOTE As can be seen from the example above it is not a 1 to 1 relation between the register list and the descriptor list A single descriptor may refer to two register items 4 Logging Timer setting If data logging only record one period data or on
123. different tariffs as well as the time stamp of the maximum value It can also clear the maximum demand under diferent tarifs Except normal energy parameter readings Acuvim IIE has 2 separate logs Current Month TOU and Prior Month TOU When setup appropriately and when TOU is enabled energy will be accumulated in a month to month basis The current energy usage will be stored under Current Month TOU and is divided up into different tariffs When next month or counting period starts all Current Month TOU values will be moved to Prior Month TOU There are two ways of automatic resetting of current month TOU 1 End of Month This is the default method All values from Current Month TOU will be copied over to Prior Month TOU at the very beginning of each month the frst day of eachmonth at time 00 00 00 Current Month TOU will be cleared and reset to 0 2 Assigned Clock User can select when the values from Current Month TOU would be copied over to Prior Month TOU User can set the time in the following format DD HH MM SS DD stands for day HH stands for hour MM stands for minute SS stands forsecond Similar to the previous method once Current Month TOU is transferred to Prior Month TOU all values from Current Month TOU will be cleared and reset to O 4 7 Power Quality Event Logging and Waveform Capture Power Quality Event Logging When a power quality event happens such as voltage sag and swell Acuvim IIW will record
124. dled and the count of actual data bytes in the field For example if the master requests a slave to read a group of holding registers function code 03 and the data field specifies the starting register and how many registers are to be read If the master writes to a group of registers in the slave function code 10 hexadecimal the data field specifies the starting register how many registers to write the count of data bytes to follow in the data field and the data to be written into the registers Table 5 4 Transaction identifier hi 00H Transaction Protocol Protocol Unit identifierlo identifier hi identifier lo 00H Length hi Length lo identifier 00H 00H 06H 01H Datastartreghi Data start reg lo Data of regs hi Data of regs lo 40H 00H 00H 48H As shown in Table 5 4 the meaning of each abbreviated word is Transaction identifier hi Transaction Identifier high byte Transaction identifier lo Transaction Identifier low byte Protocol identifier hi Protocol Identifier high byte Protocol identifier lo Protocol Identifier low byte Length hi length high byte Length lo length low byte Unit identifier slave address Fun function code Data start reg hi start register address high byte Data start reg lo start register address low byte Data of regs hi number of register high byte Data of regs lo number of register low byte a Read Status
125. dth range is 50 3000 ms Range from 0 to 3 0 0 20mA 1 4 20mA 2 0 5V 3 1 5V Be aware that modules with current option cannot be set as voltage type i e option 2 and 3 are unavailable modules with voltage option cannot be set as current type i e option 0 and 1 are unavailable Note The figure shows the rolling sequence for using key P If using E key for rolling page the sequence will reverse 56 e BACnet and Ethernet Module Parameter When the second communication protocol is set to BACnet there is parameters display related to BACnet while these pages only show as modules successfully connecting with meter If meter does not detect any module there will show LOADING page To set these parameters first select then modify and save On the one side if there is no extra BACnet module setting will be meaningless and not saved after shutting down On the other side setting is valid and will be saved into BACnet module when there is a BAVnet module attached When second communication protocol is other protocol there is parameters display related to Ethernet The condition is same as above Key functions for finding the Ethernet module parameter Press H to return to parameter selection mode The screen will roll to the next page each time P is pressed and will return to the first page when P is pressed at the last page The screen will roll to the last page each time E is pressed and will return to the last page
126. e 39 THD 13 40 THD 41 All sampling value 42 Al2 sampling 43 AI sampling 44 Al4 sampling value value value 45 Active power 46 Reactive power 47 Apparent power demand of all demand of all demand of all 48 Current demand 49 Current demand 50 Current demand of of phase A of phase B phase C 51 Teversed phase 5 79 pi1 DI28 sequence Note 1 When reversed phase sequence 51 is selected whether the value of comparison mode or setpoint value is set or not doesn t affect alarm result and angle of Ub to Ua will be recorded 2 When DI 52 79 is selected whether the value of comparison mode is set or not doesn t affect alarm result and as long as setpoint value is set to 1 2 or 3 1 stands for DI alarm is from OFF to ON and recovery is from ON to OFF 2 stands for DI alarm is from ON to OFF and recovery is from OFF to ON 3 stands for DI alarm from ON to OFF and recovery is from OFF to ON and present DI status is recorded 6 3 5 I O Modules Settings 1 0 module setting changes will be made only if the corresponding I O modules are installed no changes will be made otherwise Please check the I O module connection status before doing any settings Function code 03H for reading 10H for writing Please refer to Chapter 5 Extended Modules for more details Bee I Seru Laman Series A 218 AXM 1O11 BitO DI7 Bit1 DI8 BitO DI1 Bit1 DI2 Bit2 DI3 Bit3 D
127. e 4096 As shown in Figure 5 21 the displayed value of AO1 is 0x0800 so the real value of AOI is 0x0800 4096 x5V or 0x800 4096 x20mA Met d ro eee T DEFF B DEE B RU Fig 5 21 AO value read on screen 3 Parameter Setting Take AXM 1O21 AXM IO2 module in logic NO 1 for example 135 aman Series A 136 Electrical quantities relative to AO1 10c2H register this register determines which electrical quantity AO1 should be relative to see Chapter 6 for explaination For example if this register is 0 then AO1 is relative to Frequency Electrical quantities relative to AO2 10c3H register this register determines which electrical quantity AO2 should be relative to The value of this register is defined as the same as Electrical quantities relative to AO1 10c2H register Electrical quantities relative to AO1 10c2H register and Electrical quantities relative to AO2 10c3H register can be set to the same value The parameter setting is shown in Figure 5 22 mre 91 8 A i Ey B BE En N 5 2 DI 1 Type DI 2 Type DI 3 Type DI 4 Type DI 5 Type 16 Type G State f State f State State State State Counter Counter Counter Counter Counter Counter 1 i RO Type MRO Relay Control Output Mode DI Pulse Cont Relay Control Latch i 1 Pulse 1 C Alam k Momentary On Time ms AXM 1
128. e high Gateway 2nd byte low Gateway 3rd byte high Gateway 4th byte low DNS1 1st byte high DNS1 2nd byte low DNS1 3rd byte high DNS1 4th byte low DNS2 1st byte high DNS2 2nd byte low DNS2 3rd byte high DNS2 4th byte low MAC address BACnet baud rate Max info frames BACnet Port eRRRERE RE ReRIR RIRRRIRRIRE RE RA Ae RREIR eRRRRRIRE RIR RIRIRIRRRIRERIRAaRqE REIE PROFIBUS Module PROFIBUS address Y 1011H Run time clear y 3 When bit 2 of address 101EH is valid parameters below should be blocked Y 101CH Pulse counter clear 4 When bit 3 of address 101EH is valid parameters below should be blocked 109eH DI1 6 type V y 109fH DI pulse constant X Vv 10a3H DI7 10 type V y 10a4H DI pulse constant y Vv 10aaH DI11 14 type V vV 10abH DI pulse constant X Vv 10b0H DI15 20 type V vV 10b1H DI pulse constant y y 10b5H DI21 24 type v v 10b6H DI pulse constant y y 10bcH DI25 28 type Vv V 10bdH DI pulse constant Vv Vv 5 When bit 4 of address 101EH is valid parameters below should be blocked 103fH Week y 1040H Year Vv 1041H Month V 1042H Day V 1043H Hour V 1044H Minute V 1045H Second V Note Standard time is valid within 5 minutes it will be invalid i
129. e energy NET F5 F8 999999999 dword R W 4058H 4059H Apparent energy F6 F9 0 999999999 dword R W Harmonics THD Harmonics odd HD even HD Crest Factor THFF K factor etc are all stored here The data type is word Voltage parameters refer to line voltage when it is set to 2LL 3LL and phase voltage for others Function code 03H for reading The following are the THD of voltage and current 405aH THD V1 of V1 V12 F18 gt 0 word R 405bH THD_V1 of V2 V31 F18 gt 0 word R 405cH THD_V1 of V3 V23 F18 gt 0 word R 405dH Average THD_V F18 gt 0 word R 405eH THD l1 F18 gt 0 word R 405fH THD_I2 F18 gt 0 word R 4060H THD_I3 F18 gt 0 word R 4061H Average THD I F18 2 0 word R Voltage Harmonics even HD odd HD Crest Factor are shown as below 4062H 407fH oe nee F19 gt 0 word fawim I See 228 Harmonics of V1 V12 the 32 to 63 4500H 451fH the 32 to 63 F19 gt 0 word R 4080H Odd HD of V1 V12 F20 gt 0 word R 4081H Even HD of V1 V12 F21 gt 0 word R 4082H Crest Factor of V1 V12 F22 0 65535 word R 4083H THFF of V1 V12 F24 gt 0 word R 4084H 40a5H Parameters of V2 V31 Same as V1 word R Harmonics of V2 V31 E 4520H 453fH the 32 to 63 F19 gt 0 word R 40a6H 40c7H Parameters of V3 V23 Same as V1 word R Harmonics of V3 V23 E 4540H 455fH the 32 to 63 F19
130. e5 outputs value high byte Byte6 outputs value low byte Byte7 32 0 Note Because PROFIBUS DP VO exchanges information data periodically controlling information such as function code 05H should be used carefully Response The normal response to the command request is to retransmit the message as received after the relay status has been altered Byte1 FAH Byte2 05H Byte3 outputs address high byte Byte4 outputs address low byte Byte5 outputs value high byte Byte6 outputs value low byte Byte7 32 0 aman Series A Example setting Relay2 on Query Response FAH 05H 00H 01H FFH 00H 00H 5 3 14 Format of function code 02H Function code 02H is used to read DI status in MODBUS RTU In PROFIBUS DP the format of function code 02H is defined as follows Query Byte1 Channels can be chosen from 1 to 8 Byte2 02H Byte3 starting address high byte Byte4 starting address low byte Byte5 quantity of digital inputs high byte Byte6 quantity of digital inputs low byte Byte7 32 0 Response Byte1 The channel of inquiry frame Byte2 02H Byte3 byte count Byte4 inputs status Byte5 inputs status2 or 0 Byte6 inputs status3 or 0 Byte7 inputs status4 or 0 Byte8 32 0 The digital inputs in the response message are packed as one input per bit of the data field Status is indicated as 1 ON O OFF The LSB of the first
131. e7 32 0 Because 16 words are required for IO data in GSD file all other bytes after Byte7 are set to O aman Series A Response Below is the response that a slave device would send to a master Byte1 The channel of inquiry frame Byte2 01H Byte3 byte count Byte4 Coil status Byte5 32 0 The coils in the response message are packed as one coil per bit of the data field Status is indicated as 12ON and 0 OFF The LSB of the first data byte contains the output addressed in the query The other coils follow toward the high order end of this byte and form low order to high order in subsequent bytes Example reading Relay1 and Relay2 status start register address is 0000H Use 4 channels Query 04H 01H 00H 00H 00H 02H 00H Response 04H 01H 01H 02H 00H 00H 00H Coil Status 0 0 0 0 0 0 1 0 MSB LSB Relay 1 OFF Relay 2 ON 5 3 13 Format of function code 05H The message with function code 05H in MODBUS RTU forces a single relay either on or off The data value FFOOH will set the relay on and the value 0000H will turn it off All other values are invalid and will not affect that relay Acmin I Seriu In PROFIBUS DP the format of function code 05H is defined as follows Query FrameBytes 0 0 0 Capgion Byte FAH Byte2 05H Byte3 outputs address high byte Byte4 outputs address low byte Byt
132. eal choice for replacing traditional analog electric meters In additon to providing clear real time readings on the meter front it can also be used as a remote terminal unit RTU for monitoring and controlling for a SCADA system Users can access all measurement parameters via the standard RS485 communication port or the optional Ethernet port with the Modbus protocol Energy Management The Acuvim II series meter is able to measure bidirectional four quadrants kWh and kvarh It provides maximum minimum records for power usage and power demand parameters All power and energy parameters can be viewed remotely via software in order to easily monitor various parameters In addition measurement tables can be viewed from the free Acuview software Remote Power Control This meter is designed for measuring and monitoring power quality parameters Since different I O modules can be added to the meter this expands the capabilities and provides a very flexible platform for using the meter as a distributed RTU for metering monitoring and remote controlling all in one unit Power Quality Analysis Utilizing digital signal processing DSP technology the Acuvim II series meter provides high accuracy power quality analysis and supports remote monitoring via the Ethernet module The meter continuously updates metering results and allows users to access the meter online to monitor parameters such as voltage and current THD harmonics vol
133. ease by one each time P is pressed and will return to the 2 when P is pressed at the 63 harmonic The harmonic order will decrease by one each time E is pressed and will return to the 63 when E is pressed at the 2 harmonic Press V A to switch display between voltage harmonics and current harmonics The following figure shows the sequence The 2nd harmonic The 2nd harmonic ratio of voltage ratio of current s jc The 3rd harmonic CVIA The 3rd harmonic ratio of voltage ratio of current o gt The 4th harmonic The 4th harmonic M ratio of voltage ratio of current 63rd harmonic ratio of voltage CP Note 1 The figure shows the rolling sequence when pressing P If E is pressed the sequence will reverse 2 Harmonic is 2 63 3 6 3 When the meter is set to 1LN there is only phase A display for voltage and current harmonic magnitude 4 When the meter is set to 1LL there is no phase C display for voltage and current harmonic magnitude Expanded I O Module Data Pressing H and V A simultaneously will activate the display mode selection and the cursor will flash Press P or E to move the cursor right or left To access data from the expanded I O modules move the cursor to Digital I O then press V A to enter the expanded I O module data mode In the expanded I O module data mode the meter displays the data from expanded I
134. ed twisted pair cable standard 568A or standard 568B is usually recommended as reference to the EIA TIA standard 5 2 7 Connection Method 1 Direct Connect The Ethernet module uses cross line standard 568A to connect to computers The module supports Modbus TCP and HTTP functions for a direct connection 2 Indirect Connect The Ethernet module uses straight line standard 568B to access the Ethernet through a router or hub 5 2 8 Initializing Ethernet Module AXM NET Module s default settings are as follows IP Address 192 168 1 254 Subnet Mask 255 255 255 0 Gateway 192 168 1 1 This information can be found by using the keys on the meter front The following process shows how to configure Ethernet module settings by using the front panel Bee I Seru I Sexe LAMAN A 144 1 Pressing H key and V A key simultaneously on the meter will go to the menu selecting mode Cursor Meter flashes in this mode 5o ns Load Bnx2 Ex Mz g Fig 5 25 2 Press P key or E key to move the cursor to Setting Press V A key to go to the meter parameter setting mode Device address page is the first page of Setting mode It shows the Modbus address of the device for several seconds and then the screen goes to Access Code page Press V A key to go to the parameter setting page Press P key or E key to move the cursor to NET Press V A key to go to the Ethernet module sett
135. elow to count primary value the value of CT2 should not be 333 but 1 T Sexe OMA Numerical value equals to N System parameters NE No unit F1 communication value Eu Run time T Rx 100 Hour F2 Clock Numerical value equals to nitoftime F3 communication value Energy primary Ep Rx 10 kWh F4 Reactive energy primary Eq Rx 10 kvarh F5 Apparent energy primary Es Rx 10 kVA F6 Energy secondary Ep Rx 1000 kWh F7 Reactive energy secondary Eq Rx 1000 kvarh F8 Apparent energy secondary Es Rx 1000 kVA F9 Frequency F Rx 100 Hz F10 Voltage U Rx X PT1 PT2 10 V F11 Current current demand I Rx X CT1 CT2 1000 A F12 Power demand P Rx X PT1 PT2 X CT1 CT2 Ww F13 Reactive power demand Q Rx X PT1 PT2 X CT1 CT2 var F14 Apparent power demand S Rx X PT1 PT2 X CT1 CT2 VA F15 Power factor PF Rx 1000 No unit F16 Unbalance factor Unbl Rx 1000 X100 No unit F17 THD THD Rx 10000 X 100 No unit F18 Harmonics HDn Rx 10000 X 100 No unit F19 Total odd HD HDo Rx 10000 X 100 No unit F20 Total even HD HDe Rx 10000 X 100 No unit F21 Crest factor CF Rx 1000 No unit F22 K factor KF Rx 10 No unit F23 THFF THFF Rx 10000 X 100 No unit F24 Phase angle Phase angle Rx 10 Degree F25 Important Note Regions from System parameters settings to Data logging 3 settings are the regions that can be set and modified Please follow these guideli
136. en HD odd HD crest factor THFF K factor etc They are shown in figure 4 2 2 Phase angle Phase angle indicates the angle between phase A voltage and other voltage current parameters Angle ranges from 0 to 360 degrees This function is to help users find out the relationship between all input signals avoiding wrong wiring When it is set to 2LL or 3LL it gives out the phase angles of u23 u31 i1 i2 i3 corresponding to u12 When it is set to 3LN it gives out the phase angles of u2 u3 i1 i2 and i3 corresponding to u1 When it is set to 1LL it gives out the phase angles of u2 i1 i2 corresponding to u1 They are shown in figure 4 4 3 Sequence component and unbalance analysis Acuvim Il series meter is able to perform sequential analysis for the input signal It looks at the positive sequence negative sequence and zero sequence of the fundamental frequency and performs unbalance analysis for voltage and current Sequence components are shown in figure 4 4 unbalance of voltage and current are shown in figure 4 1 Acuovine I Series 7a oe e122 OR eas iji Es BEN N amp 2 Pos Sequence Phasor V A 0 0 0 0 Pos Sequence Phasor A 0 000 0 000 Neg Sequence Phasor V A 0 0 0 0j Neg Sequence Phasor A 0 000 0 000j Zero Sequence Phasor V A 0 0 0 0 Zero Sequence Phasor A 0 000 0 000 PhAngle VAN VAN 0 0 Ph Angle A V AN 00 Ph ngeVBN VAN 00 PhAng
137. es Table 5 2 Field lenn Description Transaction 2 Bytes Identification of a Modbus Request Response transaction Identifier Protocol Identifier 2 Bytes Modbus protocol 0 Length 2 Bytes Number of following bytes Unit Identifier 1 Byte Slave address in the range of 0 247 decimal c Function Field The function code field of a message frame contains eight bits Valid codes are in the range of 1 255 decimal When a message is sent from a client to a server device the function code field tells the server what kind of action to perform Table 5 3 fawim I Series 2 Format of communication Explanation of frame 01 Read Relay Output Status Obtain current status of Relay Output 02 Read Digital Input DI Status Obtain current status of Digital Input 03 Read Data Obtain current binary value in one or more registers 05 Control Single Relay Output Force Relay to a state of on or off 16 Write Multiple registers Place specific value into a series of consecutive multiple registers d Data Field The data field is constructed using sets of two hexadecimal digits in the range of 00 to FF hexadecimal The data field of messages sent from a master to slave devices contains additional information which the slave must use to take the action defined by the function code This can include items like discrete and register addresses the quantity of items to be han
138. eter in SYS sub menu of Acuvim II Setting menu If the address is changed it will take effect immediately Figure bellow shows the address setting of PROFIBUS module cron OOMEe act Pc oo THIC a 42 2LLI Mos I T TECH maa rr LULULI a m wa m uu Address setting of PROFIBUS module 5 3 9 Baud Rate The PROFIBUS module s baud rate can be adaptive between 9 6Kbps to 12Mbps in PROFIBUS network 183 Bee I Series fawim I Series 5 3 10 GSD Files A PROFIBUS DP master can exchange data with various slave devices In order to indentify a slave device it is necessary to obtain the technical data of the device itself The file where the data is described is called Device Description Data File GSD Because of the importance of GSD file please read it carefully before using the PROFIBUS module The GSD file is provided in pure text format with detailed comments m Asa DP slave device the PROFIBUS module supports protocol of VO revision m The PROFIBUS module s data interface is a 16 word input output interface 5 3 11 Information Exchange A variety of information from the Acuvim II meter can be transmitted by the PROFIBUS module such as electrical quantities and other parameters The basic communication method of the Acuvim II meter is RS 485 which uses protocol of MODBUS RTU In order to use the same address lists as MODBUS RTU the communication formats of PROFIBUS DP is categorized in
139. f not in this range Address Parameter Keys Communication TOU 1039H Ten years download setting enable V 103aH Fee of sharp demand clear y 103bH Fee of peak demand clear y 103cH Fee of valley demand clear y 103dH Fee of normal demand clear Vv 103eH Total fee of demand clear y 105 lee wt I Seriee A aman Series A 106 Current and last month TOU energy 7200H 7263H Current and last month TOU energy V DST setting 7700H 7717H DST setting V Season setting 7800H 780EH Basis parameter of TOU y 7820H 7AECH Season setting y Ten years holiday setting 7B00H 7E97H Ten years holiday setting V 5 110 Modules 5 2 Ethernet Module AXM NET 5 3 ProfiBus Module AXM PRO 5 4 RS485 Module AXM 485 5 110 Modules 5 1 1 The Purpose of IO Modules The standard Acuvim II meter base does not have any built in IO functions However with the addition of the extended modules multiple IO options can fawim I See be added These functions include digital input pulse counter relay output analog output analog input etc There are three types of IO modules AXM IO1 AXM IO2 and AXM IO3 Please note that a maximum of 3 modules may be attached to the meter If a communication module is used it must be installed on the back of the meter first before any IO modules are attached No more than 2 of the same ty
140. g When any phase of the three phase voltage is lower than the set value voltage rated value x threshold there will be a voltage sag event When one phase voltage sag happens the other phase will not respond to voltage sag event logging Only when all of the phases voltage restore back to normal a new voltage sag event will be responded 2 Voltage Swell When any phase of the three phase voltage is higher than the set value voltage rated value x threshold there will be an Voltage Swell event When one phase Voltage Swell happens the other phase will not respond to Voltage Swell event logging Only when all of the phases voltage restore back to normal a new Voltage Swell event will be responded Note The following figure depicts how to set the parameters for Power Quality Event Logging and Waveform Capture In the parameter settings Voltage Sag and Voltage Swell share the same voltage rated value The parameters for event logging includes voltage rated value voltage sag threshold voltage sag half cycle count and voltage swell threshold Those parameters also fit voltage sag waveform capture The other triggering conditions for Waveform Capture can be set when necessary When the Waveform Capture triggering by Voltage Sag and Voltage Swell is enabled the corresponding event log and waveform will be recorded when Voltage Sag or Voltage Swell happens Help i Ed 9 1 2 7E O f ES O Ri Ro Ra S me En
141. ge and current devices Accuenergy shall not be responsible or liable for any damages caused by improper meter installation and or operation Chapter 1 Introduction ooo 1 1 1 Meter Overview as 2 1 2 Areas of Application 1 3 Functionality Bee I Seru Chapter 2 Installation 2 1 Appearance and Dimensions 2 2 Installation Methods 2 3 Wiring me 2 3 1 Terminal Strips 2 3 2 Power Requirement 2 3 3 Voltage Input Wiring 2 3 4 Current Input Wiring 2 3 5 Frequently Used Wiring Methods 2 3 6 Communication Chapter 3 Meter Display and Parameter Settings 3 1 Display Panel and KeyS 3 2 Metering Data
142. gineering plastic G DIN rail Used for Installation 35mm rail of the DIN rail Meter Voltage Input Terminals Used for voltage input Current Input Terminals Used for current input Power Supply Terminals Used for control power input Communication Terminals Communication output 9 Interface Used for link the remote display unit and the DIN rail meter Installation Clip Used for fixing the meter to the panel Gasket Insert the gasket in between the meter and the cutout to cover up gaps from the round hole 13 Peek I Series 2 2 Installation Methods Environmental I Sexe Before installation please check the environment temperature and humidity to ensure the Acuvim II series meter is being placed where optimum performance will occur JOM A Temperature Operation 25 C to 70 C Storage 40 C to 85 C Humidity 5 to 95 non condensing The Acuvim II series meter should be installed in a dry and dust free environment Avoid exposing meter to excessive heat radiation and high electrical noise source Installation Steps The Acuvim Il series meter can be installed into a standard ANSI C39 1 4 Round or an IEC 92mm DIN Square form 1 Cut a square hole or round hole on the panel of the switch gear The cutting size is shown in fig 2 2 Unit mm inches s E di 101 695 b 4 000 405 0 0 92
143. he 7 holiday and schedule word R W 7CE1H 7CE3H The 8 holiday and schedule word R W 7CD4H 7CE6H The 9 holiday and schedule word R W 7CE7H 7CE9H The 10 holiday and schedule word R W 7CEAH 7CECH The 11 holiday and schedule word R W 7CEDH 7CEFH The 12 holiday and schedule word R W 7CFOH 7CF2H The 13 holiday and schedule word R W 7CF3H 7CF5H The 14 holiday and schedule word R W 7CF6H 7CF8H The 15 holiday and schedule word R W 7CF9H 7CFBH The 16 holiday and schedule word R W 7CFCH 7CFEH The 17 holiday and schedule word R W 7CFFH 7D01H The 18 holiday and schedule word R W 7D02H 7D04H The 19 holiday and schedule word R W 7D05H 7D07H The 20 holiday and schedule word R W 7D08H 7DOAH The 21 holiday and schedule word R W 7DO0BH 7DODH The 22 holiday and schedule word R W 7DOEH 7D10H The 23 holiday and schedule word R W 7D11H 7D13H The 24 holiday and schedule word R W 7D14H 7D16H The 25 holiday and schedule word R W 7D17H 7D19H The 26 holiday and schedule word R W 7D1AH 7D1CH The 27 holiday and schedule word R W 7D1DH 7D1FH The 28 holiday and schedule word 7D20H 7D22H The 29 holiday and schedule word 7D23H 7D25H The 30 holiday and schedule word 7D26H The 6 setting year word 7D27H Holiday number of the 6 year word The 1 holiday and schedule DOSE DEA format month day schedule word 7D2BH 7D2DH The 2 holiday and schedule w
144. he display mode selection and the cursor will flash Press P or E to move the cursor right or left To enter harmonic mode move the cursor to Harmonic then press V A In the harmonic data mode meter displays the harmonic ratio of voltage and current THD odd HD even HD THFF CF and KF a Power Quality Data Press H to display power quality data When H is pressed again the screen will roll to the next page and will roll back to the first screen when pressed at the last page Bee I Seru No commands are associated with keys P and E in Harmonic display mode Press V A to switch to harmonic ratio data display Y THD of voltage amp o avg The K factor of CH current A N Odd harmonic CH distortion of voltage Even harmonic distortion of current A Even harmonic distortion of voltage o Odd harmonic Y CH distortion of current A THFF CHD CH THD of current amp Y avg Crest factor of A Voltage Note When the meter is set to 1LN there is only phase A display for voltage THD voltage odd HD voltage even HD THFF voltage crest factor current THD current odd HD current even HD and current K factor When the meter is set to 1LL there is no phase C display Bee I Series 42 b Harmonic Ratio Data Press H to switch to power quality data display The harmonic order will incr
145. he master requests a slave to read a group of holding registers function code 03 the data field specifies the starting register and how many registers are to be read If the master writes to a group of registers in the slave function code 10 hexadecimal the data field specifies the starting register how many registers to write the count of data bytes to follow 201 Peek I Series fawim I Series in the data field and the data to be written into the registers If no error occurs the data field of a response from a slave to a master contains the data requested If an error occurs the field contains an exception code that the master application can use to determine the next action to be taken The data field can be nonexistent of zero length in certain kinds of messages Error Check Field Every message includes an error checking field which is based on the Cyclical Redundancy Check CRC method The CRC field checks the contents of the entire message It is applied regardless of any parity check method used for the individual characters of the message The CRC field is two bytes long containing a 16 bit binary value The CRC value is calculated by the transmitting device and is appended to the message The receiving device recalculates the CRC value during reception of the message and compares the calculated value to the actual value it received in the CRC field If the two values are not equal
146. he measurement accuracy of the meter When connecting using the star configuration wiring method the PT s primary side rated voltage should be equal to or close to the phase voltage of the system to utilize the full range of the PT When connecting using the delta configuration wiring method the PT s primary side rated voltage should be equal to or close to the line voltage of the system A fuse typical 1A 250Vac should be used in the voltage input loop The wire for voltage input is AWG16 12 or 1 3 2 0mm Note In no circumstance should the secondary of the PT be shorted The secondary of the PT should be grounded at one end Please refer to the wiring diagram section for further details Current Input Current Transformers CTs are required in most engineering applications Typical current rating for the secondary side of the CT shall be 5A standard or 1A Optional please refer to the ordering information appendix for further details CTs must be used if the system rated current is over 5A The accuracy of the CT should be better than 0 596 with rating over 3VA is recommended in order to preserve the meter s accuracy The wire between CTs and the meter shall be as short as possible The length of the wire have an effect on the accuracy The wire size of current input is AWG15 10 or 1 5 2 5mm Note The secondary side of the CT should not be open circuit in any circumstance when the power is on There should not be any fuse or swi
147. he new password or you may notuse the meter properly Onboard RS485 port Parity setting It can be selected from NON1 NON2 Odd and Even NON1 represents non parity single stop bit NON 2 represents non parity double stop bit odd represents odd parity single stop bit even represents even parity single stop bit By default it is set as NONT RS485 module Parity setting It can be selected from NON1 NON2 Odd and Even Please refer to S31 for each selection details By default it is set as NON1 only applies to IIR and IIE only applies to IIR and IIE 51 MA lee Ser A fawim I See ce 532 type of energy 0 Base 1 full ce j 533 frequency 0 50HZ 1 60HZ 2 400HZ D 534 second proci 1 BACnet 0 other protocols ce 535 first communication 0 MODBUS 1 DNP3 0 protocol c i 536 second communication optional range of 1 247 address ce 537 alarm clear OxOA clear other no Note The figure shows the rolling sequence for usingthe P key If using the E key for rolling page the sequence will reverse d Expanded I O Module Parameter In the expanded I O module parameter mode user can choose to view the available modules that are attached to the meter and modify their parameters If no expanded I O modules are connected the screen will display NO IO To return to system parameter setting mode main menu press H no commands a
148. hth setting page such as 80 Press the V A key to go to the setting page Users may set the parameters pointed out in Figure 5 36 The cursor starts at the first digit After setting the HTTP port press the V A key to accept Press the P key to go to the ninth setting page for the reset mode The HTTP port s default value is 80 and the user defined range of port is 6000 9999 If the set port is not in the correct range the set port will return to the default value oe NOG Hiii OMOT F Ln o Es EJ i Ex Mx Wz Fig 5 36 11 Set resetting mode in the ninth setting page Select RESET to reset the module Selecting NO will not reset the module Selecting DEFAULT will load the module with default settings and reset module Press the V A key to go to the setting page and the parameter pointed out in Figure 5 37 will flash Press the P or E key to select the configuration mode Press the V A key to accept Note When configuring Ethernet module settings completely users must select RESET to restart module and new settings will take effect Bee IJ Sema Bee Sexe poo NUS NE OCC T n L oS 5o gs p aN mx Max Mixo Y Fig 5 37 12 The password of AXM NET module can be reset by selecting RESET The password then becomes 12345678 Selecting NO means no change Press V A key to accept OOCEC i OOcCe NU Frnaa RES so g
149. ical Log 1 11COH 127FH Historical Log 2 1280H 133FH Historical Log 3 Block Size 192 registers per log 384 bytes Data Log Setting s address map 1100H 1101H 1102H 1176H 1177H 11b1H 11B2H 11B5H Header Register List Item Descriptor List Logging Timer setting The following are the details 1 Header Registers 1100H 1101H Size 2 Registers Address 1100H 1101H Byte O low byte 1 high byte 2 low byte 3 high byte Value Sectors Registers Interval Registers The number of registers to log in the record range from 0 117 The size of the record in memory is 12 4 Registers x 2 Sectors The number of memory sectors allocated to this log Each sector is 64kb in size 100 sectors are available for allocation among the three historical logs Valid allocation range is from 0 100 When the sector is set 0 this log is disable Aawim I Seru Bee I Series Interval The data capture interval for historical log records Valid time interval can be set from 0 1440 minutes When the interval is set to 0 this log is disable 2 Register List Registers 1102H 1176H Size 1 or 2 register s per parameter 117 available registers per historical log The register list controls which Modbus registers are recorded in each historical log record Since many parameters such as Voltage Energy etc take up more than 1 register multiple registers are allocate
150. ing mode press P and E simultaneously will enter the TOU mode In metering mode the meter displays measurements such as voltage current power power factor phase angle unbalance etc In the TOU mode meter displays the energy maximum demand and it s time in different tariffs a Voltage and Current Press V A to read voltage and current in the metering area The screen will roll to the next page when V A is pressed again It will go back to the first screen if you press V A at the last screen The following figure shows the sequence 8 y Three phase Voltage amp avg D y Three phase Current amp In E Y Line Voltage amp av Q D Y Three phase Current amp avg LC 8 Series AMA A Note When the meter is set to 2LL or 3LL there is no phase voltage or neutral current display Therefore only the third screen line voltage amp avg and the the fourth screen three phase current amp avg will be displayed When the meter is set to 1LN there are only phase A voltage and phase A current display without line voltages or other displays When the meter is set to 1LL there are no phase C voltage and phase C current display b Power Power Factor and Frequency Press P to display power related data The screen will roll to the next page when P is pressed again It will go back to the first screen if you press
151. ing page zd J Tau aun E E ann LILGG Me x mz QOL 1 Fig 5 26 145 Bee J Sema 7 ii L i 4 zz pc jg c3rE La TD x2 Bax Exo Ima I wy Fig 5 27 LOCIr z C bh 2 Lh 4 zz OF La Mx Mx xz Fig 5 28 146 3 Set configuration mode in the first setting page AUTO means that users configure module settings with DHCP protocol while MANU means that users configure module settings with manual setting Press V A key to go to the setting state and the area pointed out in Figure 5 29 will flash Press P key or E key to select configuration mode press V A key to accept Press the P key again to go to the second setting page for IP Address Note If you select the AUTO mode please go to step 11 directly and reset module Wait until the reset is finished and find the new IP address in the following step 7i Getting nii 07 rp IL DHE eU 5o Load JM VH P d nini MRNLD x2 xz NEUE Fig 5 29 4 Set IP Address in the second setting page such as 192 168 1 254 as shown below Press the V A key to go to the IP setting page Users may set the parameters in the area pointed out in Figure 5 30 The cursor starts at the first digit After setting the IP address press the V A key to accept Press the P key again to go to the third setting page for Subnet Mask Bee I Series
152. ircuit can work in alarm state or work in energy pulse output state Digital output circuit form is Photo MOS The simplified circuit is shown in Figure 5 8 DO1 VCC Photo MOS OUT L Va y Power Supply J DOC IO Module Fig 5 8 schematic diagram of digital output circuit 1 mane Series A When J is in low state as shown in Figure 5 8 OUT is in low state When J is in high state OUT is in high state OUT can therefore output pulse signals under the control of J The max output voltage and current of digital output circuit are 250V and 100mA respectively Another drawing of the alarming output with buzzer is shown in Figure 5 9 Buzzer VCC oDO1 Photo MOS External Power Supply u V4 SP AC DC J DOC 1O Module Fig 5 9 schematic diagram of digital output circuit 2 The wire of the digital output circuit should be chosen between AWG22 16 or 0 5 1 3 mm Wiring of Analog Output Circuit There are 2 analog output circuits in AXM IO2 modules The terminals of the analog output circuits are AO1 AO1 and AO2 AO2 The analog output circuit can convert any one of 30 electrical quantities which is selected by user to analog voltage or current The analog output circuit supplies 4 output modes including 0 to 20mA mode 4 to 20mA mode 0 to 5V mode and 1 to 5V mode The
153. ire may occur a All meter terminals should be inaccessible after installation Do NOT perform Dielectric HIPOT test to any inputs outputs or communication terminals High voltage testing may damage electronic components of the meter m Applying more than the maximum voltage the meter and or its modules can withstand will permanently damage the meter and or its modules Please refer to the specifications for all devices before applying voltages m When removing meter for service use shorting blocks and fuses for voltage leads and power supply to prevent hazardous voltage conditions or damage to CTs CT grounding is optional m ACCUENERGY recommends using a dry cloth to wipe the meter BY THE MANUFACTURER THE PROTECTION PROVIDED BY THE NOTE IF THE EQUIPMENT IS USED IN A MANNER NOT SPECIFIED A EQUIPMENT MAY BE IMPAIRED NOTE THERE IS NO REQUIRED PREVENTIVE MAINTENANCE OR INSPECTION NECESSARY FOR SAFETY HOWEVER ANY REPAIR OR s MAINTENANCE SHOULD BE PERFORMED BY THE FACTORY DISCONNECT DEVICE The following part is considered the equipment disconnect device A SWITCH OR CIRCUIT BREAKER SHALL BE INCLUDED IN THE INSTALLATION THE SWITCH SHALL BE IN CLOSE PROXIMITY TO THE EQUIPMENT AND WITHIN EASY REACH OF THE OPERATOR THE SWITCH SHALL BE MARKED AS THE DISCONNECTING DEVICE FOR THE EQUIPMENT Beca I Seven aman Series A The installation method is introduced in this chapter Please read this
154. is 7 6 5 4 3 2 1 0 0 0 0 0 0 0 1 0 MSB LSB Relay1 OFF LSB Relay2 ON Left to LSB 2 Read Status of DI Function Code 02 1 On 0 Off DI1 s address is OOOOH DI2 s address is 0001H and so on The following query is to read the Status of 4 Dls of Acuvim II series meter with communication address 17 Query Table 6 6 Read 4 Dis Query Message Addr Fun DI start addr HI DI start addr LO DI num HI DI num LO CRC 16 HI CRC 16 LO 11H 02H 00H 00H 00H 04H 7BH 59H Response The Acuvim ll series meter response includes the meter address function code quantity of data characters the actual data characters and error checking An example response to read the status of 4 Dls are shown in Table in 5 7 The DI status corresponds to the last 4 bits of the data DI1 bitO DI2 bit1 DI3 bit2 DI4 bit3 Table 6 7 Read Status of DI Address Function code Byte count Data CRC high CRClow 11H 02H 01H 03H E5H 49H The content of the data is 7 6 5 4 3 2 1 0 0 0 0 0 0 0 1 1 MSB LSB Dl1 On DI2 On DI3 Off DIA Off 3 Read Data Function Code 03 Query This function allows the master to obtain the measurement results from the Acuvim Il series meter Table 6 8 is an example of reading the measured data F V1 and V2 from slave device number 17 the data address of F is 4000H 4001H V1
155. it3bi 2 DIT2 AXM 31 word R W bit5bit4 DI13 0 0 bit7bit6 DI14 The same as above 50V 400V or ec x word RAW 50V 690V onlyin 400 400 3LL Voltage Sag E 1 Enable Teang j owad RW anie a Voltage Sag Threshold word R W 20 100 50 59 E ee word R W 4 200 half cycles 10 10 Voltage Swell A 1 Enable wd word R W 0 Disable 0 0 orti word RW 50 140 100 100 Reserved word R W i ra word R W 500 5000 mA 5000 5000 Over current 1 Enable Triggering word R W 0 Disable 0 0 Waveform Over current word R W 50 150 100 100 Threshold Clear Waveform word R W 0X55 enable 0 0 800FH Clear Power Quality Event word R W 0X55 enable 0 0 Note In 3LL and 2LL voltage rated value is line voltage in 3LN 1LN and 1LL voltage rated value is phase voltage Bee I Seru Waveform Capture Data Retrieve Address Waveform Capture includes timestamp triggering condition and waveform data Every group uses the same data format Only one group of waveform is saved in the registers When retrieving the waveform firstly write 1 8 group number into 0X801FH then read the registers after it to acquire waveform corresponding to the written group number The relationship between voltage waveform value and real value Real Value Unit V Waveform Value 37 59105 The relationship between current waveform value and real value Real Value Unit A Wavefo
156. lable from 01 to 14 The dates should be organized so that they are in sequence according to the calendar 83 Bee I Series Bee I Series year the earlier date comes first and the later date comes last For example if 3 seasons are selected the date parameters are January 1 June 6 and September 7 and TOU schedule 02 01 03 will be used respectively the first TOU season table slot shall enter 01 01 02 the second slot shall enter 06 06 01 and the third slot shall enter 09 07 03 Entering 01 01 02 for the first slot 09 07 03 for the second slot and 06 06 01 for the third slot is considered invalid 3 Schedule setting parameter The number of available TOU schedules depends on the schedule setting parameter The parameter can be selected from any integer between 1 to 14 This parameter determines the number of TOU schedules available for the TOU calendar setting A maximum of 14 TOU schedules from TOU Schedule 1 to TOU Schedule 14 can be used 4 Segment setting parameter Each TOU schedule consists of various timing segments The number of segments depends on the segment setting parameter setup The parameter can be selected from any integer between 1 to 14 inclusively User must enter the correct value for the segment setting parameter in accordance to the TOU schedule table If the segment setting parameter is set as 3 the first 3 slots of the TOU schedule table must be set otherwise it wi
157. le B V AN 00 PhAngleVCN VAN 0 0 Ph Angle I C V AN 00 Ph Angle V AB V AB Ph Angle A V AB Ph Angle V BC V AB Ph Angle B V AB Ph Angle V CA V AB Ph Angle C V AB Fig 4 4 Sequence component and Phase angle for example 3LN 4 4 Over Under Limit Alarming Acuvim Il series meter has over under limit alarming capabilites When the monitored parameter goes over under the preset limit and stays at the level over the preset amount of time delay the over under limit alarm will be triggered The over under limit value and its time stamp will be recorded in the Bee I Seriee 70 alarming log The meter can record up to 16 alarming records When extended I O modules are attached digital outputs DO and relay outputs RO can be triggered upon alarm conditions and used to activate downstream devices such as a beacon light or a buzzer Before using the alarming function alarm conditions such as logic dependency target setpoint time delay etc must be set correctly Settings can be accessed and modified from the software via communication connection as shown in Fig 4 5 Start Readings Settings Help ee 1 2S fs 9 sw BEB CE N 2 Iv Enable Alarm I Enable Backlight Flashing DINNER m Frequency Hz zl lt 20 00 300 PIM iP le ol 2 C Frequens ta z eo a Ceiri r Pa m T fe
158. lection 1 Select a Group The possible selections are Real Time Metering Energy THD Volts AN AB THD Volts BN BC THD Volts CN CA THD IA THD IB THD IC Sequence Component Phase Angles DI Counter AO AI Raw Value and AO AI Value 2 Select items for your log a Highlight the parameter s you want to log into the meter s memory b Click Add to add the parameter to the Selected Parameter Area c To remove parameter s highlight them in the Selected Parameter Area and click Remove 3 Set the logging interval in minutes Interval can be set from 0 1444 minutes according to different application The logging interval determines when the meter takes a snapshot When interval is set as O the set of historical data log is disabled 4 There are 100 sectors in total for the 3 historical data logs User can assign different sector size to each log according to different applications as long as the total sector sizes of the 3 logs do not exceed 100 5 Three Modes of historical log A Model if correctly set historical log can record without setting date and time depending on first in first out recycling log B Mode2 if correctly set historical log as set date and time can record within begin to end time Record will stop after buffer is full C Mode3 if correctly set historical log as set hour and minute only can record while the running time is equal to setting hour and minute depending on first in
159. lidays foro m ems ws mos 09 e 7 omo ooo 003000 53000 000000 000000 12 19 000000 oomoo foooooo foooooo foooooo 00 0000 18 aajo ooo ooo foo 000000 000000 24 sona ooo Jood000 o o 0003 a Settings Year 2 0 Holiday Number 5 2nd Year Holidays E i Cr CE E CO I c 06016 7 lorar7 ene pos oo wo 9009 a ajoo 50000 oo 053000 000900 000000 18 foa oo oo o 0009000 00000 as aoa oo oo o 000000 000000 ao Settings Year on Holiday Number 10 Fig 4 11 ten years holiday table 11 Weekend Schedule Weekend Setting bitO Sunday bit1 bit6 Monday to Saturday bit 0 means not effective bit 1 means effective For example when the Weekend Setting bitO is 1 it means Sunday is effective When the Weekend Setting bit1 is 1 it means Monday is effective For example if a user wants to set Saturday and Sunday effective he should put 65 1000001 into the Weekend Setting field When the meter clock is within the preset Weekend Schedule the 87 fawim I Serin energy will accumulate under the tariff that corresponds to the Schedule Note Holiday schedule has the highest priority among all the schedules Weekend schedule s priority is followed by Holiday schedule When Holiday schedule is not enabled Weekend schedule has the highest priority overiding the normal weekday schedule Acuvim IIE can record maximum power and current demand under
160. light will flash when alarm is triggered Alarming channel enable setting determines whether the corresponding alarm group is enabled or not There are 16 groups in all and each one is corresponding to one bit of a 16 bit register The corresponding bit must be set to 1 in order to activate the alarm channel Logic AND between alarm setting The 16 alarming records in the meter are divided into 8 pairs Each pair has two alarm groups The two groups can be logically AND by controlling the logic check box When two groups are AND alarming triggers only if both AND conditions are met If the AND logic box is unchecked the two alarm channels will work independently The 8 AND logic pairs are arranged as follows 1 2 channel form Pair 1 3 4 channel form Pair 2 5 6 channel form Pair 3 7 8 channel form Pair 4 9 10 channel form Pair 5 11 12 channel form Pair 6 13 14 channel form Pair 7 15 16 channel form Pair 8 This function is controlled by the lower 8 bits of the 16 bit register and each bit is corresponding to a pair 1 means this function is enabled and 0 means disabled Alarming output to DO1 setting When Digital output mode is set to 1 DO1 can be used as alarming output A 16 bit register is used to perform this function its bit0 bit15 correspond to the 1 16 group respectively When the related I O module is connected and is under alarming mode and if the corresponding bit i
161. ll be considered as an invalid input TOU function will be disabled 5 TOU schedule format Each TOU schedule represents a 24 hour cycle Similar to TOU season format enter the start time into the TOU schedule table slot following this format HH MM ID HH stands for hour in 24 hr format MM stands for minutes and ID stands for tariffs available from 00 to 03 The time should be organized according to the hour sequence For example if 3 segments are selected timing parameters are 01 00 15 30 22 45 the order of the 3 segments should be one of the following 01 00 15 30 22 45 or 15 30 22 45 01 00 or 22 45 01 00 15 30 Entering time information in a wrong sequence for example entering 15 30 01 00 22 45 is considered as an invalid operation TOU function will be disabled 6 Tariff setting parameter This parameter corresponds to the number of tariffs available for the TOU calendar and can be selected from any integer from 0 to 3 The four tariffs sharp peak valley and normal are represented by 4 integers 0 1 2 and 3 respectively If the tariff setting parameter is set to 3 all of the 4 tariffs will be available for the TOU calendar if the parameter is set to 1 only the first 2 tariffs sharp and peak will be available 7 Holiday setting parameter This parameter can be set from any integer between 1 and 30 meaning a maximum of 30 holidays can be programmed to the TOU calendar If the holiday setting parameter
162. llocate available system resources among the three logs to increase or decrease the size of the individual historical logs The total size is no more than 100 sectors that has 64k bytes The data log 1 setting is shown in Fig 4 8 Aawin I Series FT JE pret 2 9t 8 Ri Ro Ra E s A En Eo BE En N 8 5652 Sa Data Log 1 Settings Frequency i Volts AN FT a Volts BN Voks CN Vots LN Average Vots AB 4 Vols BC Pwr Factor A ES Volts CA Pw Factor B Vots LL Average Put Factor C IA Pwr Factor Total 1B i Unbalance V lt lt Remove Ic Unbalance lu l Average Load Type IN Watt Demand Watt A VAR Demand Clear All Watt B VA Demand Watt C 1A Demand Watt Total 1B Demand VARA 1C Demand a VARB s VARC E Registers and Sectors Bites Registers 78 Total Bytes Used 156 Sectore EJ Drag the bar to control Bytes Remaining 78 Other Logging Interval D H min Logging Mode Continuous T Seta D Hou fo Hmn Start Time 2000 1 1 0 00 00 C Interval End Time 2000 1 1 j 0 00 00 Save Load Update Device Fig 4 8 The data log 1 setting 78 Having three sets of historical logs provides you with the option of programming each log with unique parameters For example you can program Historical Log 1 to record measured values parameters for example Frequency Voltage Current Log 2 to record energy values parameters and
163. loat PFsum Voltage unbalance 403cH 403dH Unbalance Rx x 100 float factor U_unbl 403eH 403fH Current unbalance Unbalance Rx x 100 float factor _unbl 4040H 4041H RS criaracteristic L C 76 0 67 0 82 0 ASCII float 4042H 4043H Power demand P Rxx PT1 PT2 x CT1 CT2 float Reacti 4044H 4045H C actiVe power P Rxx PT1 PT2 x CT1 CT2 float demand n t 4046H 4047H Parent power P Rxx PT1 PT2 x CT1 CT2 float demand Note when transformers are set to 330mV take CT2 as 1 Real time energy measurement Data stored in this block can be preset or cleared Function code 03H for reading 10H for writing Data type dword It can be set as primary energy or secondary energy according to user Please refer to F7 F8 and F9 for more details about the relationship between numerical value in the register and the real physical value Address Parameter Code Range Datatype Property i 4048H 4049H Energy IMP F4 F7 0 999999999 dword R W SS 404aH 404bH Energy EXP F4 F7 0 999999999 dword R W N 404cH 404dH Reactive energy IMP F5 F8 0 999999999 dword R W 404eH 404fH Reactive energy EXP F5 F8 0 999999999 dword R W E 4050H 4051H Energy TOTAL F4 F7 0 999999999 dword R W 999999999 4052H 4053H Energy NET F4 F7 999999999 dword R W 4054H 4055H Reactive energy TOTAL F5 F8 0 999999999 dword R W 999999999 4056H 4057H Reactiv
164. ly start from one specific time corresponding time and logging mode should be set then data logging can work well Modbus address 11B2H is used as the logging mode select When value is 0 logging mode is set to model without time setting When value is 1 logging mode is set to mode2 so 11B3H 11B5H start year month day hour minute and second and 11B6H 11B8H end year month day hour minute and second should be set When value is 2 logging mode is set to mode3 so only 11B4H hour and 11B5H minute should be set How data logging works is in Chapter 4 Registers 11B3H 11B5H start time 11B6H 11B8H end time Size 2 Registers Byte 0 1 2 3 4 5 value month year hour day second minute Log Status Block The Log Status Block describes the current status of the log in question 6100H 6101H Max Records 0 468104 dword 6102H 6103H Used Records 1 468104 dword 6104H Record Size 14 246 word Bees I Series fawim I Series 6105H Reserved word R 6106H 6108H First Record Time stamp word R 6109H 610bH Last Record Time stamp word R 6200H 620bH Data logging 2 status Same as the first group 6300H 630bH Data logging 3 status Same as the first group Max Records The maximum number of records the log can hold given the record size and sector allocation Used Records The number of records stored in the log
165. mary mI A Direction 1 B Direction 1 Direction Positive C Negative Positive Negative Positive Negative Security Demand Type Demand Password 0000 Sliding Window Demand es Interval Window 15 H min C Thermal Demand L J DO Energy Pulse Const Other Watt 0000 Pulse kwh Tum On the Backlight 1 min van 5000 Pulse kvarh Energy Type Energy Readin VAR PF Conventior VAR Calculation Method C Fundamental Primary IEC Method 1 True Fund Harm C Secondary C IEEE C Method 2 Generalized SOE Enabled C None C AXM4011 C AXMJO21 C AXMIO31 AXM1O12 C AXM4022 C AXMJ032 Non Standard Seal Options of Seals Device Run Time Communication Channel 1 DI Counters Communication Channel 2 Device Clock TOU Related Save Load Update Device Fig 4 7 basic settings 4 5 Data Logging The Acuvim IIR IIE IIW meter provides data logging that records the data at a set interval This meter has 8 MegaBytes of memory which gives it extensive data logging capabilities It has a real time clock that allows logs to be time stamped 77 when log events are created 1 Data log settings The Acuvim IIR IIE IIW meter has three sets of historical data logs Each log can be independently programmed with individual settings meaning that each can be used to monitor different parameters You can program up to 117 parameters per log You also have the ability to a
166. mber to Newest Event Group Number 8CFFH No 1 Event Timestamp High Byte 8D00H Year word R Time Low Byte Month Timestamp High Byte 8D01H Day word R Time Low Byte Hour Timestamp High Byte 8D02H Minute word R Time Low Byte Second apos Timestamp Word R Time Millisecond Voltage Sag or 0 disabled 8D04H Voltage Swell word R 1 Voltage Sag condition 2 Voltage Swell 50V 400V or 8D05H Rated Value word R 50V 690V only in 3LL 273 Acmin T Seriu fawim I Serin Voltage Sag 20 100 8D06H Threshold word Voltage Swell 50 140 96 Voltage Sag Event Half Cycle 4 200 SQ Count werd Voltage Swell Event 0 BDOBFESDO No 2 Event word FH 8D10H 8D17H No 3 Event word 8D18H 8D1FH No 4Event word 8D20H 8D27H No 5 Event word 8D28H 8D2FH No 6 Event word Appendix Appendix A Technical Data and Specifications Appendix B Ordering Information Appendix C Revision History Bee I Serin 276 Appendix A Technical data and Specification Input ratings Active power according to IEC 62053 22 Class 0 2S according to ANSI C12 20 Class 0 2 Reactive according to IEC 62053 23 Class 2 Metered Value 2 63 Nominal Full Scale 400Vac L N 690Vac L L Withstand 1500Vac continuous 3250Vac 50 60Hz for 1 minute Input Impedance 2Mohm per phase Metering Frequency 45Hz 65Hz Pickup Voltage
167. minal 2 i e from 111 to 112 for phase A current however current may flow in the opposite direction due to incorrect wiring setup Instead of rewiring the system the meter provides users an option to reverse the polarity of the current By default current direction is set as positive to reverse the current polarity by 180 degrees user can set current direction as negative Refer to Fig 4 7 for more details Aawim I Seriu Start Readings Settings Help Se mee 2868 B BiG AN Channel Maximum Time Stamp Minimum Time Stamp Volts AN 381 00 V 2000 1 3 6 32 36 0 00V 2013522 134249 Volts BN 38050 V 2000 1 3 6 59 37 0 00 V 134249 Volts CN 38050V 2000 1 5 3 43 48 0 00V 134249 Volts AB 659 30 2000 1 3 6 32 36 0 00V 134248 Volts BC 658 90 2000 1 5 1 17 25 0 00V 134249 Volts CA 659 30 2000 1 3 6 32 36 0 00V 2013522 134248 lA 393 50A 2000 1 3 7 23 34 0 0000 4 2013 5 22 13 42 49 1B 39225A 2000 1 3 6 35 58 0 0000 A 2013 5 22 134249 ic 39275A 2000 1 3 6 41 14 0 0000 A 2013522 134248 Watt Total 285750KwW 2000 1 5 1 15 16 285 250kW 2000 1 5 1 14 32 VAR Total 336 000kvar 2000 1 3 6 33 02 285 000 kvar 2000 1 3 6 18 18 VA Total 442500kvA 2000 1 3 amp 0 00000kvA 2013 5 22 13 42 49 Pwr Factor Total 1 000 2013 5 22 1 000 2000 1 1 1 26 42 Frequency 58 21 Hz 2000 1 5 3 0 00 Hz 2013 5 22 13 42 49 Watt Total Demand 138 000kw 2000 1 35 44 7500kW 2000 1 3 6 29 47 VAR Total Demand 104 000 kvar 2000 1 3 amp
168. mode M11 M12 realy working pattern M11 M12 relay output pulse width DI of AXM IO1 can be used as the pulse counter each DI function corresponds to one bit of a 6 bit register The correspondence bit of 0 means that the DI works as the digital status input and the correspondence bit of 1 means that the DI works as the pulse counter For example if the setting value is 000001 it means that DI1 is set as the pulse counter and other Dis work as digital status inputs f the DI works as a pulse counter when the number of pulses counted by the DI equals to the pulse constant the pulse counter will increase by one This means that the actual pulse number equals the number of pulses counted multiplied by the pulse constant Relays of AXM IO1 can be used as alarm output or control output ALM alarm output CTRL control output When set as control output relays have two control methods latch or pulse LATCH latch mode PUL pulse mode If relay pulse control method is selected the relay contact will close for a preset period and open afterwards The pulse width range is 50 3000 ms Module M 21 M22 VO M21 M22 Module Le Gio M21 M22 pulse counter enable Y M21 M22 pulse constant Y M21 M22 DO output mode Y M21 M22 DO pulse width Y M11 M12 DO1 output type Y M11 M12 DO2 output type D M11 M12 AO type Y M11 M12 AO 1 transf
169. ms Jae e eee r al w T few pae eo o rr ee a E E T p i ir m T famo Aa fp r r r r 3 az C Frequency Hz AP eo 0 Pe ar ae z 4B I Frequency Hz z zoo a s Paa T Frequency Hz x zoo a FREFRECHEPEI zi a mo M Frequency Hz z ooo fj 2 ss zl 1 Frequency Hz z po a FRICEECEECHI oo wa T eo size f aoe ee mo 7 remote Aae E rr rr a wa D Feuno Ap dpo f LEN HE RECNI si 15 I Frequency Hz gt fo00 fj F n s s E me l Frequency Hz z gt z0 0 s si Save Load Update Device Fig 4 5 Alarm Setting 1 Single Alarming Group Setting Table 4 1 indicates the first group of settings there are 16 groups in total with the same format Table 4 1 First Group of Alarming Settings Acuovine I Series 104eH First group parameter code 0 79 R W 104fH First group comparison mode 1 larger 2 equal 3 smaller R W 1050H First group setpoint value Related with parameters R W 1051H First group delay time 0 3000 10ms R W 1052H First group output to relay O none 1 8 related relay R W Parameter code select target parameter for alarm monitoring For example 0 frequency 44 Al4 sampling data Comparison mode set alarming condition 1 greater than 2 equal to 3 smaller than For example if you choose target parameter to be frequency condition to be greater than and setpoint to
170. n terminal for DI1 to DI4 circuits RO1 to ROC relay output terminals where ROC is the common terminal for RO1 and RO2 circuits Al1 Al1 Al2 Al2 analog input terminals Sequence of DI RO DO AO Al in IO modules according to the logical order in the communication address table of the main body DI Sequence AXM IO11 AXM IO1 module in logic NO 1 DI1 6 AXM IO21 AXM IO2 module in logic NO 1 DI7 10 AXM 1O31 AXM IO3 module in logic NO 1 DI11 14 AXM 1012 AXM IO1 module in logic NO 2 DI15 20 AXM 1022 AXM 1O2 module in logic NO 2 DI21 24 AXM 1O32 AXM 1O3 module in logic NO 2 DI25 28 RO Sequence AXM IO11 AXM IO1 module in logic NO 1 RO1 2 AXM 1031 AXM IO3 module in logic NO 1 RO3 4 AXM 1O12 AXM IO1 module in logic NO 2 RO5 6 AXM 1032 AXM 1O3 module in logic NO 2 RO7 8 DO Sequence AXM IO21 AXM IO2 module in logic NO 1 DO1 2 AXM 1022 AXM 1O2 module in logic NO 2 DO3 4 AO Sequence AXM IO21 AXM IO2 module in logic NO 1 AO1 2 AXM 1O22 AXM IO2 module in logic NO 2 AO3 4 Al Sequence AXM IO31 AXM IO3 module logic NO 1 AI1 2 AXM 1032 AXM 1O3 module in logic NO 2 Al3 4 Wiring of Digital Input Circuit There are 6 digital input circuits 4 digital input circuits and 4 digital input 115 Bee I Seru Bee I Series circuits in AXM IO1 AXM IO2 and AXM IO3 modules respectively The digital input circuit can be used to detect remote signals or be used as an in
171. nalog Measurements 4 2 Max Min 4 3 Harmonics and Power Quality Analysis 4 4 Over Under Limit Alarming 4 5 Data Logging 4 6 Time Of Use TOU 4 7 Power Quality Event Logging and Waveform Capture 4 8 Seal function Aawan I Series 4 1 64 The Acuvim II series meter contains advanced metering tools and is able to measure a multitude of power energy and power quality parameters Some advanced functions may not be accessible directly from the meter front therefore every meter comes with a powerful software that helps access the information This chapter introduces these functions and the software Basic Analog Measurements Acuvim II series meter can measure voltage current power frequency power factor demand etc With high accuracy as shown via the software below Volts AN 0 00 Volts AB 0 00V lA 0 0000 A Volts BN 0 00 V Volts BC 0 00 V IB 0 0000 A Volts CN 0 00V Volts CA 000V IC 0 0000 A Volts LN Average 0 00 V Volts LL Average 0 00 V Average 0 0000 A Watt 0 00000kw VAR A O 00000kvar VAA 0 00000 kVA Watt B 0 00000kw VAR B 0 00000kvar VAB 0 00000 kVA Watt C 0 00000kw VARC 00000kvar VAC 0 00000 kVA Watt Total 0 00000 kW VAR Total Q 00000kvar V Total 0 00000 kVA Pwr Factor A 1 000 Frequency 0 00 Hz Load Type R Pwr Factor B 1 000 IN 0 0000 A Pwr Factor C 1 000 Unbalance V 00 Pwr Factor Total 1 000 Unbalance 00 Reset Demand DmdWatt Total O 00000kW Dmd VAR Total
172. nd AO2 transforming parameter Range 0 29 see Chapter 5 page 99 AO transforming parameter settings for more details Wess Sata Bee I Series Module M 31 M32 VO M31 M32 Module p M31 M32 counter enable pulse 0 Y M31 M32 pulse 0 Y working pattern M31 M32 output pulse width constant Y M31 M32 relay output mode Y M31 M32 relay relay 0 Y M31 M32 Al type DI of AXM IO3 can be used as the pulse counter each DI function corresponds to one bit of a 4 bit register The correspondence bit of 0 means that the DI works as the digital status input and the correspondence bit of 1 means that the DI works as the pulse counter For example if the setting value is 0001 it means that DIT is set as the pulse counter and other Dls work as digital status inputs If the DI works as a pulse counter when the number of pulses counted by the DI equals to the pulse constant the pulse counter will increase by one This means that the actual pulse number equals the number of pulses counted multiplied by the pulse constant When set as control output relays have two control methods latch or pulse Relays of AXM IO3 can be used as alarm output or control output ALM alarm output CTRL control output If relay pulse control method is selected the relay contact will close for a preset period and open afterwards The pulse wi
173. nes when communicating with the meter Aawan I Series 1 When function code 10H is used one communication command can only modify contents in one region such as System parameters settings System status parameter Date and Time table Over under limit alarming Global settings Over under limit alarming Single settings I O Modules settings Data logging 1 settings Data logging 2 settings Data logging 3 settings It can not be accomplished in one communication order to modify contents in both of two or more regions above 2 When function code 03H is used the rules and limitations described above will not be applied 6 3 1 System Parameter Setting System parameters determine how the meter works Please refer to Chapter 3 and Chapter 4 for more details Function code 03H for reading 10H for writing Data type word Format code F1 OffdH Frequency 0 0 50Hz 1 60Hz Word R W First communication 0 MODBUS Protocol Protocol o 1 DNP3 0 Protocol Word FUN 2 0 EVEN 1 odd 2 NON2 Parity Setting 3 3 NON1 word R W Password 0 0 9999 word R W 1 247 MODBUS Communication address 1 0 65534 DNP3 0 word R W Baud rate 19200 1200 38400 word R W Voltage input wiring type 0 a TATLN 2 2LL 3 3LL word R W Current input wiring type 0 0 3CT 1 1CT 2 2CT word R W 1005H PT1 High 1
174. ng end point should be set At the same time AO1 output range setting start point AO1 output range setting point 2 AO1 output range setting point 3 and AO1 output range setting end point should be set 2 Following value range setting AO following value range setting start point X1 AO1 following value range setting point 2 X2 AO1 following value range setting point 3 X3 and AO following value range setting end point X4 are increasing value while they should be within range of AO following value Otherwise the function of AO will be affected Frequency 45HZ 65HZ real setting value is 4500 6500 Phase voltage V1 V2 V3 and average phase voltage 0 480V real setting value is 0 4800 Line voltage V12 V23 V31 and average line voltage 0 831V real setting value is 08310 Current 11 12 13 and average current 0 10A real setting value is O 10000 Power Pa Pb and Pc 4800 4800W real setting value is 4800 4800 System power 14400 14400W real setting value is 14400 14400 Bee I Seru Bee I Series Reactive power Qa Qb and Qc 4800 4800 Var real setting value is 4800 4800 System reactive power 14400 14400 Var Apparent power Sa Sb and Sc 0 4800VA real setting value is 0 4800 System apparent power 0 14400VA real setting value is 0 14400 Power factor PFa PFb PFc and System power factor 1 1 real setting value is 1000 1000 3 AO output range setting AO output value r
175. nge NT R W setting point 2 0d7H AO1 output range NT R W setting point 3 Od8H AO1 output range NT R W setting end point AO2 Gradient m 10d9 10E1H Setting same as AO1 same as AO1 N R W AO3 Gradient a 10E2H 10EAH Setting same as AO1 same as AO1 N R W AO4 Gradient es 10EBH 10F3H Setting same as AO1 same as AO1 N R W Note 1 AO Gradient Number Selection of input output transfer curve When number is 1 only AO following value range setting start point AO following value range setting end point AO1 output range setting start point and AO1 output range setting end point should be set When number is 2 only AO following value range setting start point AO1 following value range setting point 2 AO following value range setting end point AO1 output range setting start point AO1 output range setting point 2 and AO1 output range setting end point should be set When number is 3 only AO following value range setting start point AO1 following value range setting point 2 AO1 following value range setting point 3 and AO following value range setting end point should be set At the same time AO1 output range setting start point AO1 output range setting point 2 AO1 output range setting point 3 and AO1 output range setting end point should be set 2 following value range setting AO following value range setting start point AO1 following value range setting point 2 AO1 following value
176. ntains eight bits Valid slave device addresses are in the range of 0 247 decimal A master addresses a slave by placing the slave address in the address field of the message When the slave sends its response it places its own address in this address field of the response to let the master know which slave is responding Function Field The function code field of a message frame contains eight bits Valid codes are in the range of 1 255 decimal When a message is sent from a master to a slave device the function code field tells the slave what kind of action to perform Table 6 2 Function Code 01 Read Relay Output Status Obtain current status of Relay Output 02 Read Digital Input DI Status Obtain current status of Digital Input Obtain current binary value from one or more 03 Read Data b registers 05 Control Relay Output Force relay state to ON or OFF Place specific binary values into a series of consecutive Multiple Registers 16 Press Multiple Register Data Field The data field is constructed using sets of two hexadecimal digits in the range of 00 to FF hexadecimal The data field of messages sent from a master to slave devices contains additional information which the slave must use to take the action defined by the function code This can include items such as register addresses the quantity of items to be handled and the count of actual data bytes in the field For example if t
177. ock be Qi t r1 G2 l Le Acuvim Il E Hom 132 LOAD QD Fig 2 13 3CTs b 2CT The difference between Fig 2 14 and Fig 2 15 is that no current flows through current input terminal 121 and 122 The meter should be set to the I2 value which is calculated from formula i1 i2 i3 0 The current input mode of the meter should be set to 2CT Acuovine I Series auwim I See Terminal Block Acuvim Il Fig 2 14 2CTs 1CT LINE B C Terminal Block EO t A 2 9 pO Acuvim Il 2 O22 A HO 132 LOAD Fig 2 15 1CT 2 3 5 Frequently Used Wiring Method In this section the most common voltage and current wiring combinations are shown in different diagrams In order to display measurement readings correctly please select the appropriate wiring diagram according your setup and application 1 3LN 3CT with 3 CTs LIN A B E C N 1A FUSE Terminal block Qn 6 00 vs V3 V2 VI e One z Quin Acuvim II dM LOAD Fig 2 16 3LN 3CT 2 3LN 3CT with 2 CTs LINE B C N 1AFUSE Terminal block om 0000 Vs V3 V2 V1 n2 Quan Acuvim Il HO lz a 132 LOAD Fig 2 17 3LN 3CT with 2CTs 25 Acmin T Series Pee I Series
178. on Terminal Strip EI xr zl c EI LI LI a a 1 12 13 Comm Port n ABS Power Supply 14 15 16 Fig 2 5 Terminal Strips of Acuvim II series meter A4 DANGER Only the qualified personnel does do the wire connection work Make sure the power supply is cut off and all the wires are powerless Failure to observe it may result in severe injury or death J NOTE Make sure the control power terminal of the meter ground is connected to the safety Earth of switchgear A NOTE Make sure the voltage of power supply is the same as what the meter needed for its control power Safety Earth Connection Before setting up the meter s wiring please make sure that the switch gear has an earth ground terminal Connect both the meter s and the switch gear s ground terminal together The following ground terminal symbol is used in this user s manual Fig 2 6 Safety Earth Symbol 2 3 2 Power Requirement Control Power There are 2 options for the Control Power of the Acuvim Il series meter 1 Standard 100 415Vac 50 60Hz or 100 300Vdc 2 Low Voltage DC Option 20 60Vdc The 2 options must be chosen according to the application Please see the ordering information appendix for further details The meter s typical power consumption is very low and can be supplied by an independent source or by the measured load line A regulator or an uninterrupted power supply UPS shoul
179. ord 7D2EH 7D30H The 3 holiday and schedule word 7D31H 7D33H The 4 holiday and schedule word 7D34H 7D36H The 5 holiday and schedule word 7D37H 7D39H The 6 holiday and schedule word 7D3AH 7D3CH The 7 holiday and schedule word 7D3DH 7D3FH The 8 holiday and schedule word 7D40H 7D42H The 9 holiday and schedule word 7D43H 7D45H The 10 holiday and schedule word 7D46H 7D48H The 11 holiday and schedule word 7D49H 7D4BH The 12 holiday and schedule word 7D4CH 7D4EH The 13 holiday and schedule word 7D4FH 7D51H The 14 holiday and schedule word 7D52H 7D54H The 15 holiday and schedule word 7D55H 7D57H The 16 holiday and schedule word 7D58H 7D5AH The 17 holiday and schedule word 7D5BH 7D5DH The 18 holiday and schedule word 7D5EH 7D60H The 19 holiday and schedule word Beca I Serier fawim I See 266 7D61H 7D63H The 20 holiday and schedule word R W 7D64H 7D66H The 21 holiday and schedule word R W 7D67H 7D69H The 22 holiday and schedule word R W 7D6AH 7D6CH The 23 holiday and schedule word R W 7D6DH 7D6FH The 24 holiday and schedule word R W 7D70H 7D72H The 25 holiday and schedule word R W 7D73H 7D75H The 26 holiday and schedule word R W 7D76H 7D78H The 27 holiday and schedule word R W 7D79H 7D7BH The 28 holiday and schedule word R W 7D7CH 7D7EH The 29 holiday and schedule word R W 7D7FH 7D81H
180. orming parameter Y M11 M12 AO2 transforming parameter DI of AXM IO2 can be used as the pulse counter each DI function corresponds to one bit of a 4 bit register The correspondence bit of 0 means that the DI works as the digital status input and the correspondence bit of 1 means that the DI works as the pulse counter For example if the setting value is 0001 it means that DI1 is set as the pulse counter and other Dls work as digital status inputs f the DI works as a pulse counter when the number of pulses counted by the DI equals to the pulse constant the pulse counter will increase by one This means that the actual pulse number equals the number of pulses counted multiplied by the pulse constant DO of AXM IO1 can be used as either alarm output or energy pulse output ALM alarm output PUL energy pulse output Range from 20 1000 ms Choose output energy type for DO1 Range from 0 4 0 no output 1 import active energy 2 export active power 3 import reactive energy 4 export reactive energy Follow the DO1 setup method to setup DO2 If DO type is set as alarm output DO1 and DO2 output type parameters will have no effect Range from 0 to 3 0 0 20mA 1 4 20mA 2 0 5V 3 1 5V Be aware that modules with current option cannot be set as voltage type i e option 2 and 3 are unavailable modules with voltage option cannot be set as current type i e option 0 and 1 are unavailable For AO1 a
181. parameter of holiday setting error 256 tariff of schedule setting error 512 time of schedule setting error 1024 period of schedule setting error 048 period of weekend setting error 4096 weekend setting error Season Setting 7820H 7822H data and Season table Of the word R W 1 Season 7823H 7825H data and Season table Of the word R W 2 Season 7826H 7828H data and Season table Of the word R W 3 Season 7829H 782BH data and Season table Of the word R W 4 Season 782CH 782EH data and Season table Of the word R W 5 Season 782FH 7831H data and Season table Of the word R W 6 Season 7832H 7834H data and Season table Of the word R W 7 Season 7835H 7837H data and Season table Of the word R W 8 Season 7838H 783AH data and Season tableOf the word R W 9 Season 783BH 783DH data and Season tableOf the word R W 10 Season 783EH 7840H data and Season tableOf the word R W 11 Season data and Season tableOf the 7841H 7843H 1o cereos word R W Schedule Setting 1 Seagment and Tariff Tien Number of the 1 schedule word iad 2 Seagment and Tariff cee Number of the 1 schedule weed 3 Seagment and Tariff iia ic Number of the 1 schedule word 4 Seagment and Tariff Usa Ditters Number of the 1 schedule word 5 Seagment and Tariff a Number of the 1 schedule word 6 Seagment and Tariff ANLE Number of the 1 schedule werd 7 Seagment and Tariff ene E Number of the
182. pe IO modules can be attached According to the diference in communication with Acuvim Il meter each type of IO module also has two modes logic NO 1 and logic NO 2 This means two of each type of IO module can be linked to the Acuvim Il meter simutaneously one being logic NO 1 and the other being logic NO 2 The AXM IO1 module is composed of 6 digital inputs DI Each digital input can be used to detect remote signals or be used as an input pulse counter When it is used to detect remote signals it also can enable SOE sequence of events recording the event and time of the event 2 relay outputs RO Can be used for controlling or alarming Each of the relay outputs work in the same mode When it operates in controlling mode there are two output options latching and pulse When it operates in alarm mode it has only one latching output mode 24V isolated power supply Used as an auxiliary power supply for digital inputs The AXM IO2 module is composed of 4 digital inputs DI Each digital input can be used to detect remote signals or be used an input pulse counter When it is used to detect remote signals it can also enable SOE sequence of events recording the events and time of the events 2 analog outputs AO Can output analog voltage or analog current When it outputs analog voltage the range of voltage is from 0 to 5V or from 1 to 5V When it outputs analog current the range of current is from 0 to 2
183. pe is 4 20mA the setting value range is 819 4915 and the relationship is mA setting value 20 4096 When AO type is 0 5V the setting value range is 0 4915 and the relationship is V setting value 5 4096 When AO type is 1 5V the setting value range is 819 4915 and the relationship is V setting value 5 4096 6 3 6 Metering Parameter Address Table Basic Analog measurements There are two different modes to read basic analog measurements one is secondary mode and another is primary mode In primary mode the numerical value in the register of the meter is equal to the real physical value In secondary mode the relationship between the numerical value in the register and the real physical value is shown in the following table Rx is the numerical value in register of Acuvim Il series meter Function code 03H for reading iin 4000H 4001H Frequency F F Rx float R N 4002H 4003H Phase voltage V1 F U Rxx PT1 PT2 float R t 4004H 4005H Phase voltage V2 F U Rxx PT1 PT2 float R E 4006H 4007H Phase voltage V3 F U Rxx PT1 PT2 float R a 4008H 4009H Average voltage Vavg F U Rxx PT1 PT2 float R 400aH 400bH Line voltage V12 F U Rxx PT1 PT2 float R 400cH 400dH Line voltage V23 F U Rxx PT1 PT2 float R 400eH 400fH Line voltage V31 F U Rxx PT1 PT2 float R 4010H 4011H Average line voltage pi U Rxx PT1 PT2 float R Vlavg 4012H
184. points to the SYS which means system parameter is selected C System Parameter Setting Users can select and modify system parameter in the system parameter setting mode Acuvion I Sven Key functions for selecting a parameter Press H to return to parameter selection mode The screen will roll to the next page each time P is pressed and will return to the first page when P is pressed at the last page The screen will roll to the last page each time E is pressed and will return to the last page when E is pressed at the first page Press V A to modify the selected parameter Key functions for modifying the parameter Press H to move the flashing cursor to the next position Press P to increase the number by 1 Press E to decrease the number by 1 Press V A to confirm the modification and return to parameter selection mode The following figure shows the sequence AMA aman Se A 50 SYS setting y cm 501 first communication address ei 02 Baud rate i S03 Baud rate c S04 Voltage wiring amp S05 Current wiring S07 PT2 c S08 CT c S09 CT2 e S10 pulse constant for active energy gt S11 pulse constant for reactive energy ei _ S12 backlight time S13 demand calculation method S14 demand window c S15 demand clear MODBUS range is 1 247 DNP
185. put pulse counter VCC Optical K coupler R Din 1 oOUT b 20 160V AC DC Electrical 4 Adjuster o o DIC lO module Fig 5 6 schematic diagram of digital input circuit The circuit drawing of digital input is simplified as shown in Figure 5 6 When K is switched off OUT is in high state When K is switched on OUT is in low state The external power supply for the digital input is 20 160 Vad Vdc The max current in the loop line is 2mA The wire of digital input should be chosen between AWG22 16 or 0 5 1 3mm Wiring of Relay Output Circuit There are 2 relay output circuits in AXM IO1 and AXM 1O3 modules respectively The relay output circuit can work in controlling state or an alarm state When it operates in controlling state it has two optional output modes latching and pulse When it operates in alarm state it has only one latching output mode Relay type is mechanical Form A contact with 3A 250Vac or 3A 30Vdc A mediate relay is recommended in the output circuit as in Figure 5 7 3 External mediate relay c power supply 777s 4 li l hg i I 10 module coill control lt l output o I ROC Ig Fig 5 7 schematic diagram of relay output circuit The wire of relay output should be chosen between AWG22 16 or 0 5 1 3mm Wiring of Digital Output Circuit There are 2 digital output circuits in AXM IO2 module The digital output c
186. r binary serial communications between devices RS485 is the most versatile communication standard in the standard series defined by the EIA and it is currently a widely Bee I Series used communication interface in data acquisition and control applications where multiple nodes communicate with each other The RS485 signals are floating and each signal is transmitted over a differential signal line and a differential signal line The RS485 receiver compares the voltage difference between both lines instead of the absolute voltage level on a signal line If the differential signal and differential signal lines are twisted better communication performance can be achieved The twisted pair adds immunity to fight noise If high noise immunity is needed often a combination of twisting and shielding is used For example shielded twisted pair or foiled twisted pair networking cables 5 4 2 Function Description of RS485 module AXM RS485 module uses RS485 serial communication and the Modbus RTU protocol just like the onboard RS485 port of the Acuvim II series meter It provides a second RS485 port for serial communication and it can be working with the onboard RS485 serial communication simultaneously The terminals of communication are A B and S A is differential signal B is differential signal and S is connected to the shield of the twisted pair cables Up to 32 devices can be connected on a RS485 bus without repeate
187. rd F2 0 999999999 1035H Run time low word Bit AXM 1O11 Bit1 AXM 1O12 Bit2 AXM 1O21 Expanded Bit3 AXM 1O22 1036H IO a Bit4 AXM 1031 word connecting status Bits AXM IO32 0 disconnected 1 connected 1037H Reserved 2nd 1038H communication TeBacnet Protocol Word i 0 Other Protocol selection 1039H Jen Los download 1 enable is valid Word setting enable Fee of sharp Ox0A clear 1038H demand clear Other not clear Word 103bH Fee of peak demand Ox0A clear Word clear Other not clear 103cH Fee of valley OxOA clear Word demand clear Other not clear iwim I Series A auwim I See Fee of normal OxOA clear 1030M demand clear Other not clear Word Rw 103eH Total fee of demand Ox0A clear Word Rw clear Other not clear Note 1 Please refer to Chapter 3 and Chapter 4 for more details about parameter settings 2 When 1038H is 1 second communication protocol is set to BACnet protocol while second communication should select BACnet module When 1038H is 0 second communication protocol is set to other protocols while second communication should select second RS 485 module PROFIBUS module or Ethernet module If selected protocol doesn t match attached module communication can not process 6 3 3 Date and Time Table Function code 03H for reading 10H for presetting 103fH week F3 0 6 word R W 1040H Year F3 2000 2099
188. re associated with other keys in this screen Key functions for I O module selection Press H to return to parameter selection mode Press P to move the cursor downwards The cursor will move to the top when it reaches the bottom If there is only one module connected pressing P will have no effect Press E to move the cursor upwards the cursor will move to the bottom when it reaches the top If there is only one module connected pressing E will have no effect Press V A to select the module and enter the I O module parameter setting mode Beca I Sven Key functions for setting the I O module parameter Press H to return to I O module selection mode The screen will roll to the next page each time P is pressed and will return to the first page when P is pressed at the last page The screen will roll to the last page each time E is pressed and will return to the last page when E is pressed at the first page Press V A to modify the selected parameter Key functions for modifying the parameter Press H to move the flashing cursor to the next position Press P to increase the number by 1 Press E to decrease the number by 1 Press V A to confirm the modification and return to parameter selection mode The following table shows the sequence Bee Series 54 ModuleM 11 M12 1 0 M11 M12 Module CV A 5 M11 M12 pulse counter enable M11 M12 pulse constant M11 M12 relay output
189. reliability by providing real time power quality monitoring and analysis When you open the package you will find the following items Acuvim II series meter Terminal Blocks Rubber Gasket Product Disk Manual Warranty Software 1 3 Installation clips 4 1 1 Additional documentation Quick Setup Guide Calibration Certificate 2 Aun BWN To avoid complications please read this manual carefully before installation and operation of the Acuvim ll series meter Chapter 1 Introduction Chapter 2 Installation and Wiring Chapter 3 Meter Display and Parameter Settings Chapter 4 Detailed Functions and Software Chapter 5 Extended Modules Chapter 6 Communication Appendix Technical Data Specifications and Ordering Information Acuvion I Seven LL Chapter 1 Introduction 1 1 Meter Overview 1 2 Areas of Application 1 3 Functionality 1 1 Meter Overview Series Powerful Multifunction Power Meter Awam The Acuvim II series multifunction digital power meter is designed using modern MCU and DSP technology It integrates three phase energy measuring and displaying energy accumulating power quality analysis malfunction alarming data logging and network communication A vivid LCD display with large characters and time of use programmable backlight provides a clear real time data readout A An Ideal for Electric Automation SCADA Systems The Acuvim II series meter is the id
190. ress V A to select the parameter and enter the display of the data c I O module data display Press H to return to I O module data selection screen The screen will roll to the next page each time P is pressed and will return to the first page when P is pressed at the last page If only one page exists pressing P will have no effect The screen will roll to the last page each time E is pressed and will return to the last page E is pressed at the first page If only one page exists pressing E will have no effect No commands are associated with the key V A in this display The following figure shows the sequence M11 M12 cu M14 M12 DI1 3 aS te M11 M12 DI IO M11 or M12 M11 M12 DI4 6 M11 M12 RO fe 7I M11 M12 RO1 RO2 M11 M12 pluse i gt r M11 M12 count Counter 1 CP M11 M12 Counter 2 Sy Mt4 M12 Counter 3 CP M11 M12 Counter 4 Oy M14 M12 Counter 5 Sy M14 M12 Counter 6 qup 45 Aawim I Serieus fawim I Series 46 M21 M22 10 M21 or M22 M21 M22 DI M21 M22 DI1 4 Module M31 M32 IO M31 or M32 Cn M31 M32 DI M31 M32 DI1 4 CH a M31 M32 RO a
191. rks in alarming mode a 16 bit register is used to control which channels are associated with this output Similar to the alarm channel selection this 16 bit value is expressed in decimal when reading on the meter front For example 00000 means that no alarm channels are associated to this output 00001 means that alarm channel 1 is associated to DO1 65535 means that all alarm channels are associated to DO1 Refer to section 4 4 for more details If 2 AXM IO2 modules are attached to the meter DO1 and DO2 denote to the first and the second DO channel of AXM IO21 DO3 and DO4 denote to the first and the second DO channel of AXMIO22 respectively DO2 DO3 and DO4 use the same setup method as DO1 Wade Sat Bee I Series w Note The figure shows the rolling sequence for using key P If using E for rolling page the sequence will reverse Page Recovery Function Acuvim ll series meter has a page recovery function This means that the meter stores current display page in the non volatile memory upon power loss and reloads the page when power recovers If power goes off when viewing under the parameter setting mode the meter will show voltage display when power recovers If power goes off when viewing under the expanded I O module data mode and if this expanded I O module is not connected when power recovers the meter will show the voltage display page instead Chapter 4 Detailed Functions and Software 4 1 Basic A
192. rm Value 1683 153 When users select 333mV Voltage type CT real Value Unit A Waveform Value 15869 87 The voltage and current value obtained from the waveform are the PT or CT secondary side value Read FC03 Preset FC16 For more information please refer to Chapter 4 7 Aawin I Sees 1 100 Note When the value avon is smaller than or equal 8E00H Group Number q Word R W is to newest waveform for Retrieving record group number this value is valid 8EO1H Waveform Waveform number Word R W group number 0 121 OxOBH window data is valid Waveform OxFF window data is 8E02H record window invalid Word R status OxAA waveform record memory is clearing data is invalid Newest 1 100 8E03H Waveform 0 no record Word R Group Number Waveform 8E04H 8E43H CCOrd data 32768 32767 Word R retrieving window Power Quality Event Retrieve Address Power quality event includes timestamp triggering condition and related settings Every group uses the same data format Only 10 groups of data are saved in the registers When retrieving the event data its parameters must be correctly set in order to get correct information Read FC03 Preset FC16 For more information please refer to Chapter 4 7 Newest Event 1 50000 SCFDH Group Number ward R 0 No Data 1 50000 E dE Note only valid 8CFEH word R W smaller or equal starting group nu
193. rs Use good quality shielded twisted pair cable AWG22 0 5mm or higher The overall length of the RS485 cable connecting all devices should not exceed 1200m 4000ft Every A should be connected to A B to B or it will influence the network or even damage the communication interface When using a long communication cable to connect several devices an anti signal reflecting resistor typical value 1200 3000 0 25W is normally added to the end of the cable beside the last meter if the communication quality is distorted 5 4 3 Appearance and Dimensions Y 22mm n n ll side view 90 00mm lt gt KA N o yl E E Q uy N O o Td top view inina Seven Aawinm I Seriu ERE CHO CH xN bottom View 5 4 4 Installation Method The RS485 module is linked to the meter by a communication plug It also can be linked to other extended modules 1 Insert the installation clips to the counterpart of the meter and then press the RS485 module lightly so linking is established 2 Tighten the installation screws Note 1 Install AXM RS485 Module carefully to avoid damage 196 2 Under no circumstances should any installation be done with the meter powered on Failure to do so may result in injury or death 5 4 5 Connection Method The RS485 module is using 2 wire half duplex communication mode which is the
194. rs can determine the over under limit duration by checking the time difference Here is the 1 group of records Other groups of records have the same format Table 4 2 Alarming status of the 1 group of record 42a9H First group alarming status 0 65535 42aaH First group parameter code 0 50 42abH First group over under limit or reset value Related with parameters 42acH 42b2H st group time occur time yyyy mm dd hh mm ss ms Alarming status indicates information of current alarm status It is a 16 bit unsigned integer Parameter code is stored in the higher 8 bits Bit1 indicates whether logic AND is enabled or not 1 means enabled and 0 means not BitO indicates whether alarming has occured or recovered 1 means occurred and 0 means recovered Undefined bits are 0 Parameter code specifies the monitored parameter Value shows the recorded value of the selected parameter when an alarm is triggered and when it recovers Bees I Series Aawinm I Serien Time indicates the time stamp with the accuracy in milliseconds ms Alarming event will set bitO of system status 102EH to be 1 When software send clear alarm command BitO of system status 102EH will be set to 0 Alarming group number 1032H the range is 0 16 0 is no alarm record and others stand for which record is newest alarm Alarming group number can be saved during meter power off and it i
195. s address is 4002H 4003 and V2 s address is 4004H 4005H Bee I Seru fawim I Series Table 6 8 Read F V1 V2 Query Message Addr Fun Data start Data start Data of Data of CRC16 CRC 16 addr HI addr LO regs HI regsLO regsHI regsLO 11H 03H 40H 00H 00H 06H D2H 98H Response The Acuvim ll series meter response includes the meter address function code quantity of data bytes data and error checking An example response to read F V1 and V2 F 42480000H 50 00Hz V1242C7CCCDH 99 9V V2 42C83333H 100 1V is shown Table 6 9 Read F V1 and V2 Message Addr Fi Byte Datal Data1 Data 2 Data2 Data3 Data3 Data4 Data4 FoU count H I0 m 0 H 0 H IO 11H 3H OCH 42H 48H 00H OOH 42H C7H CCH CDH Data5 Data5 Data 6 Data6 CRC16 CRC16 HI LO HI LO HI LO 42H C8H 33H 33H CAH 7FH 4 Control Relay Function Code 05 Query This message forces a relay to either turn ON or OFF Any relay that exists within the Acuvim II series meter can be forced to either ON or OFF status The data value FFOOH will set the relay on and the value 0000H will turn it off all other values are invalid and will not affect that relay The example below is a request to the Acuvim Il series meter with the address of 17 to turn on Relay1 Table 6 10 Control Relay Query Message Add F
196. s cycling recording Here is an example Start Readings Setting PAIN Gran 2268 B BRN No Time Stamp ms Alarm Channel Value Status limtlD 1 2000 1 4 20 15 03 38 Frequency 0 00 Hz Dut 1 2 0001 1 1 0 00 00 1 Volts AN 0 00 V In 0 3 0001 1 1 0 00 00 0 Frequency 0 60 Hz In 0 4 0001 1 1 0 00 00 0 Frequency 0 00 Hz In 5 0001 1 1 0 00 00 0 Frequency 0 00 Hz In 0 6 0001 1 1 0 00 00 0 Frequency 0 00 Hz In 0 7 0001 1 1 D Frequency 0 00 Hz In 0 8 0001 1 1 D Frequency 0 00 Hz In D 3 0001 1 1 D Frequency 0 00 Hz In D 10 0001 1 1 D Frequency 0 00 Hz In 0 11 0001 1 1 D Frequency 0 00 Hz In 0 12 0001 1 1 0 Frequency 0 00 Hz In 0 13 0001 1 1 1 0 Frequency 0 00 Hz In 0 14 0001 1 1 0 00 00 0 Frequency 0 00 Hz In 0 15 0001 1 1 0 00 00 0 Frequency 0 00 Hz In 0 16 0001 1 1 0 00 00 0 Frequency 0 00 Hz In 0 New Alarm Record Yes Reset Alarm Log Newest Alarm Record No 1 Fig 4 6 Alarming records Start Readings Settings Help Aawim I Seriu e mre 1 286 G a Be Ey N 2 p Communication Channel 1 Protocol Modbus v Address 1 Baud Rate 19200 v bps Parity None v Communication Channel 2 Protocol Default v Address 1 Baud Rate 19200 bps Parity None v Wiring PT and CT Ratios Real Time Reading Voltage 3N v pTi 400 0 v cn 250 A Secondary Cunent xr x Pr2 jaooo v cr2 3 mw Pri
197. s parameter range Data type access 7200H 7201H 0999999999 Dword R W Ep imp sharp 7202H 7203H Ep_exp sharp 0 999999999 Dword R W 7204H 7205H Eq_im sharp 0 999999999 Dword R W 7206H 7207H REM 0 999999999 Dword R W 7208H 7209H adi 0 999999999 Dword R W 720AH 720BH 0 999999999 Dword R W Ep_imp peak 720CH 720DH Ep_exp peak 0 999999999 Dword R W 720EH 720FH Eq_imp peak 0 999999999 Dword R W 7210H 7211H Eq_exp peak 0 999999999 Dword R W 7212H 7213H Es peak 0 999999999 Dword R W 7214H 7215H 0 999999999 Dword R W Ep imp valley 7216H 7217H Ep expivalley 0 999999999 Dword R W 7218H 7219H Eq_imp valley 0 999999999 Dword R W 721AH 721BH M 0 999999999 Dword R W 721CH 721DH s valley 0 999999999 Dword R W 721EH 721FH 0999999999 Dword R W Ep imp normal 7220H 7221H Ep exp normal 0999999999 Dword R W 7222H 7223H Eq_imp normal 0 999999999 Dword R W 7224H 7225H Eq_exp normal 0 999999999 Dword R W Es normal 7226H 7227H 0 999999999 Dword R W 7228H 7229H Ep_imp sum 0 999999999 Dword R W 722AH 722BH Ep_exp sum 0 999999999 Dword R W 722CH 722DH Eq_imp sum 0 999999999 Dword R W 722EH 722FH Eq_exp sum 0 999999999 Dword R W 7230H 7231H Es sum 0 999999999 Dword R W Table 6 25 Data address of last and current month 7232H 7233H 7234H 7235H 0 999999999 0 999999999 Ep_imp sharp Ep_exp sharp Beca I Series 7236H 7237H Eq_imp sharp 0 999999999 7238H 7239H Ed_exp sharp
198. s set to 1 and the alarming condition is met alarm signal will be sent to DO1 DO1 will be turned off when all alarms correspond to DO1 are cleared If related bit is set to 0 that alarm channel will not issue alarm signal to DO1 DO2 DOA work in the same manner DO1 After completing the setup steps correctly alarming function can be used 3 Setting Example Here is an example showing how to apply the logic AND function for a pair of alarm channels The conditions are as follows 11 greater than 180A delay 5s for the 1 alarm channel U1 less than 9980V delay 10s for the 2 alarm channel No alarm signals will be sent to outputs The CT primary value of I1 is 200A and CT2 is 5A The PT ratio for U1 is 10000 100 The following shows how all the related registers are to be set Settings of first group Parameter code 104eH is set to 9 which stands for 11 Comparison mode 104fH is set to 1 which stands for greater than Setpoint value 1050H is set to 4500 according to the relationship between actual value and communication value I Rx CT1 CT2 1000 Bee I Seru Bee I Series Delay time 1051H is set to 500 so the actual delay time is 500 10ms 5s Output to relay 1052H is set to 0 because there is no output to RO Settings of second group Parameter code 1053H is set to 1 which stands for U1 Comparison mode 1054H is set to 3 which stands for smaller than Setpoin
199. selected as cue signal for alarming Yes backlight flashes upon alarm condition No no backlight flashing There are 16 alarm channels available Each channel is controlled and enabled 1 bit each from a 16 bit register Bit value of 1 means that the corresponding alarm channel is enabled whereas 0 means that the channel is disabled The meter will display the value of this 16 bit register in decimal numbers for different channel combination For example 00000 means that all channels are disabled 00001 means only the first channel is enabled 65535 means that all channels are enabled Refer to section 4 4 on page 65 for more details AND logic relationship can be set among channels When an AND logic is in place both channels have to be triggered before the meter sends out the alarm signal The logic can be set according to the predefined rule refer to section 4 4 for more details User can setup up to 8 logic relationships for alarming Each logic relationship is controlled and enabled 1 bit each from a 16 bit register only the lower 8 bits are used Bit value of 1 means that the corresponding logic relationship is enabled whereas 0 means that the relationship is disabled The meter will display this 8 bit value in decimal numbers for different relationship combination For example 000 means that all relationships are disabled 001 means only the first relationship is enabled 255 means that all relationships are enabled When DO1 wo
200. simplified circuit is as shown in Figure 5 10 3 E WA AO VCC vec YCC N VO VO n load Me Ir i AO Na AO d R1 load R R2 AO Current analog output Voltage analog output Fig 5 10 schematic diagram of analog output circuit The Load Capability of Analog Output Circuit 0 to 20mA mode the max load resistance is 5000 4to 20mA mode the max load resistance is 5000 0 to 5V mode the max load current is 20mA 1 to 5V mode the max load current is 20mA Wiring of Analog Input Circuit There are 2 analog input circuits in AXM IO3 modules The terminals of analog input circuit are Al1 Al1 and Al2 AI2 The analog input circuit supplies 4 input modes including 0 to 20mA mode 4 to 20mA mode 0 to 5V mode and 1 to 5V mode The simplified circuit is as shown in Figure 5 11 Alto a pd VI VI i ADC R ADC St Al l Ry N Al fawim I See aA 4 Current analog input Voltage analog input Fig 5 11 schematic diagram of analog input circuit 24V Isolated Power Supply To simplify and make more convenient for the end user there is a DI auxiliary power supply provided in AXM IO1 module The voltage of the DI auxiliary power supply is 24Vdc 1W This power supply can NOT be used for other purposes Figure 5 12 shows the function of IO
201. status and change the settings of the Ethernet module e Wetering Webserver ACCUENERGY Main Page Data Settings Device Description Acuvim Il Mail From Acuvim Il Module Status DHCP Mode MANUAL Mail to 1 abc accuenergy com cn IP Address 192 168 1 43 Mail to 2 Subnet Mask 955 255 2550 Mail to 3 Gateway 192 168 1 1 Subject Metering DNS Primary 192 168 1 4 SMTP Server mail accuenergy com cn DNS Secondary 192 1683 1 167 User Name test accuenergy com cn MODBUS Port 502 Triggered Sending Alarm Event SOE Event HTTP Port 80 Timed Sending 60min DAC Addams LO EON Isti contis Metering Energy Harmonics Sequence MaxMin Alarm Record SOE Record Meter Model Acuvim IIR Meter SN ATR1005089 Meter Firmware 222 NET Firmware 220 Default Frequency 50Hz Device Clock 2012 8 19 18 45 48 Fig 5 43 167 Becas I Seriee auwim I Series 3 Settings Webpage By selecting the Settings link users can access Network Settings Mail Settings Webpage Settings Load Default and Password Setting When accessing the Settings link users will be prompted to enter a password The default password is 12345678 a Password Webpage Figure 5 44 Password webpage If the password is valid the browser will go to the Network Settings webpage If an incorrect password is used users will be notified of Invalid Password E metering Webserver ACCUENERGY Main
202. t 80 Wetering Webserver ACCUENzHEY Main Page Data Settings Module Status ct an updated file Update Load os O Reboot Submit efault Setting NET Module JC Browse Note Reboot the NET module after the update Fig 5 48 173 Bees I Seriu Aawin I Seriu f Password Setting Webpage Figure 5 49 Password Setting webpage To change the password users need to input the current password first E Metering Webserver ACCUZNERGY Main Page Data Settings Change Password Module Status Current Password New Password 6 12bits Confirm Password 6 12bits Submit Reset Fig 5 49 174 4 Data Webpage Click Data Link to Visit Data webpages There are seven kinds of data webpages They are Metering webpage Energy webpage Harmonics webpage Sequence webpage Max and Min webpage Alarm Record webpage and SOE Record webpage Each webpage shows the working status of the meter Acuovine I Series Metering Webserver Manna Acuvim Il Web Server Data Metering j 1mulifunction power meter m formonitoring and controlling Settings j Energy ms Acwit b Module Status Harmonics onitored data is available via a gi new cation are also options and with protocols ci Sequence 1 Ii meter are limitless Max and Min Lac Alarm Record
203. t parameter setting page Data logging Record mode description 2 01 20130621 Waveform recording function Sealing function AO function Voltage wiring Harmonic content rate range Net electric range Clear alarm directives Your Power and Automation Partner ALCCUZIVEHGY Accuenergy Corporation Los Angeles Toronto Beijing North America Toll Free 1 877 721 8908 Web www accuenergy com Email support accuenergy com
204. t value 1055H is set to 998 according to the relationship between actual value and communication value U Rx X PT1 PT2 10 Delay time 1056H is set to 1000 so the actual delay time is 1000 10ms 10s Output to relay 1057H is set to 0 because there is no output to RO Global settings Alarming channel enable setting 1048H set to 0003H to enable the first and the second channel Logic AND between alarming setting 1049H set to 0001H to enable logic AND in Pair 1 Alarming output to DO1 setting 104aH set to 0 since no output to DO1 Alarming output to DO2 setting 104bH set to 0 Alarming output to DO3 setting 104cH set to 0 Alarming output to DO4 setting 104dH set to 0 Alarming flash enable 1047H set to 0 to disable backlight flashing when alarming occurs Global alarming enable 1046H set to 1 to enable over under limit alarming 4 Records of Alarming Event Acuvim Il series meter has built in alarm logging capabilities 16 entries can be recorded in total The record sequence of these entries do not depend on the sequence of the 16 alarm channels The meter begins logging alarm status starting from the 1 record location to the last one Alarm logs are being recorded in a cycle fashion which means the latest event will overwrite the oldest record When over under limit parameters return to normal its value and time stamp will be recorded as well Therefore use
205. tage and current value obtained from the waveform are the PT or CT secondary side value The waveform capture retrieve page is shown in Figure 4 14 98 Acuvim IIW Utility Software Start Readings Settings Help 20 Glo 1 2 RONE RR Rll Accuenergy rporation Retrieve Waveform Save Clear Log No I Time Stamp ms Reason 1 2012 4 4 15 24 14 312 Trigger by Over Current 2 2012 44 15 24 15 333 Trigger by Voltage Sag 74 8 3 2012 4 4 15 24 15 772 Trigger by Voltage Sag 4 2012 4 4 15 24 16 195 Trigger by Voltage Sag 5 2012 4 4 15 24 17 715 Trigger by DI 111 from ON to OFF B 2012 4 4 15 25 03 836 Trigger by DI 111 from OFF to ON T 2012 4 4 15 25 09 323 Trigger by DI 111 from ON to OFF 8 2012 4 4 15 25 16 257 Trigger by DI 111 from OFF to ON Newest Waveform Record No Capture Waveform Waveform Graph 2012 4 4 15 24 15 333 Trigger by Voltage Sag f 1244 15 24 15 3 124 4 15 24 15 347 754 a l a Volts A Vols B Vols C 1A 1B ETE Fig 4 14 99 Bee I Seriu 4 8 Seal Function The panel with seal which has sealed key control is different with one without seal When the seal is in opened status functions are same like normal meters But when the seal is in sealed status some functions of meters which include parameters blocked by seal and optional parameters will be blocked These parameters can still be accessible by keys and
206. tage crest factor current K factor and voltage and current unbalance factor etc Data Logging The Acuvim IIR IIE IIW meter contains 8 megabytes IIW contains 8 megabytes of onboard memory for data logging and historical trending Since the meter contains a real time clock all events and logged data will be time stamped Time of use TOU Acuvim IIE User can assign up to 4 different tariffs sharp peak valley and normal to different time period within a day according to the billing requirements The meter will calculate and accumulate energy to different tariffs according to the meter s internal clock timing and TOU settings Power Quality Event Logging When a power quality event happens such as voltage sag and swell etc Acuvim IIW will record the timestamp and the triggering condition of the event It can save up to 50 000 power quality events Waveform Capture Acuvim IIW can record 100 groups of voltage and current waveforms It logs at 64 points per cycle It provides the waveform record of 10 cycles before and after the triggering point It also supports a settable triggering condition Bee I Seru fawim I See 1 2 Areas of Application 1 3 Power Distribution Automation Electric Switch Gear and Control Panels Industry Automation Building Automation Energy Management Systems Marine Applications Renewable Energy Functionality Multifunction Acuvim Il meters provide powerful data collecting
207. tch in the CT loop One end of the CT loop should be connected to the ground Vn Connection Vn is the reference point of the Acuvim II series meter voltage input Low wire resistance helps improve the measurement accuracy Different system wiring 19 Bee I Seru fawim I Series modes require different Vn connection methods Please refer to the wiring diagram section for more details Three Phase Wiring Diagram This meter can satisfy almost any kind of three phase wiring diagrams Please read this section carefully before choosing the suitable wiring method for your power system Voltage and current input wiring mode can be set separately in the meter parameter setting process The voltage wiring mode can be set as 3 phase 4 line Wye 3LN 3 phase 3 line direct connection 3LL 3 phase 3 line open delta 2LL single phase 2 line 1LN and single phase 3 line 1LL The current input wiring mode can be set as 3CT 2CT and 1CT The voltage mode can be grouped with the current mode as 3LN 3CT 3CT or 2CT 3LL 3CT 2LL 3CT 2LL 2CT 1LL 2CT 1LN 1CT 2 3 3 Voltage Input Wiring 3 Phase 4 Line Wye Mode 3LN The 3 Phase 4 Line wye mode is commonly used in low voltage electric distribution power systems For voltage lower than 400LN 690LL Vac power line can be connected directly to the meter s voltage input terminal as shown in fig 2 9a For high voltage systems over 400LN 690LL Vac PTs are required as
208. te when OFFEH is 0 first communication protocol is set to MODBUS while OFFEH is 1 first communication protocol is DNP3 0 At this time special DNP3 0 software is needed and normal software will be invalid 6 3 2 System Status Parameters System status indicates what events happened in the meter what kinds of flags are read by user and the index of the storage of events Flags should be cleared after being read by the controller otherwise new data will not be stored properly Function code 03H for reading 10H for writing Data type word BitO 1st communication parameters Bit1 2nd communication Sealed nr 101EH Nonstandard s turitime cear Word R W Paramarere Bit3 DI pulse count Bit4 TOU 1 valid of corresponding selection 0 invalid Ox0A Seal sealed Other 101FH Seal status Word R W Seal opened 1020H Reserved 1021H Alarm record clear OXON clear Word R W Other not clear 1022H 102DH Reserved BitO new alarming or not 102eH System status Bit1 new SOE or not word R 102fH Baud rate2 38400 4800 38400 word R W 0 EVEN 1 odd 2 NON2 1030H Parity Setting2 3 NON1 word R W toai e 1 247 word address2 Alseminaarod 0 no alarming record 1032H ogee F1 1 716 last alarming record word number group number 0 no SOE record 1033H SOE group number F1 1420 last SOE group word number 1034H Run time high wo
209. the event timestamp and the triggering condition It can save up to 50 000 events Beatos I Series 1 Event Logging Data format Timestamp 4 words Triggering Condition 1 word Rated Value 1 word Threshold 1 word Half Cycle Count 1 word Each event has 8 words in total Event Time W1 Year High Byte Month Low Byte W2 Day High Byte Hour Low Byte W3 Minute High Byte Second Low Byte W4 Millisecond Triggering Condition W5 Voltage Sags or Voltage Swells 0 logging disabled BitO 1 u1 voltage sag 0 no u1 voltage sag Bit1 1 u2 voltage sag 0 no u2 voltage sag Bit2 1 u3 voltage sag 0 no u3 voltage sag Bit3 1 u1 voltage swell 0 u1 no voltage swell Bit4 1 u2 voltage swell 0 u2 no voltage swell Bit5 1 u3 voltage swell 0 u3 no voltage swell Rated Value W6 Voltage rated value Threshold W7 Threshold for voltage sag and swell Half Cycle count W8 Voltage Swell 0 Voltage Sag 4 200 2 Logging Events The event logging feature can log 50000 events If the 50000 events are full no more events will be logged even if the triggering condition happens The user 89 fawim I Series must clear the event log and then the logging will log the new event When the log is cleared the new event will be logged from the first event happening There will be no data loss after the power is off 3 Event Logging Triggering Conditions 1 Voltage Sa
210. tility software Start Readings Settings Help a wB i mre 2 72 O 8 Bs Bo REB 2 No Time Stamp ms D1 j pi2 Jos Di4 jos oe 1 2007 6 28 15 20 22 603 OFF OFF OFF OFF OFF OFF 2 2007 6 28 15 20 43 969 ON ON ON OFF OFF OFF 3 2007 6 28 15 20 43 969 ON ON ON OFF OFF OFF 4 2007 6 28 15 20 43 963 ON ON ON OFF OFF OFF 5 2007 6 28 15 20 43 969 ON ON ON OFF OFF OFF 5 2007 6 28 15 20 49 328 OFF ON OFF OFF OFF OFF 7 2007 6 28 15 20 49 328 OFF OFF OFF OFF OFF OFF 8 2007 6 28 15 20 04 653 OFF OFF OFF OFF OFF ON 3 2007 6 28 15 20 04 654 OFF OFF OFF OFF OFF OFF 2007 6 28 15 20 08 224 ON ON ON OFF OFF OFF 2007 6 28 15 20 08 224 ON ON ON OFF OFF OFF 2007 6 28 15 20 08 224 ON ON ON OFF OFF OFF 2007 6 28 15 20 15 45 ON ON ON ON ON OFF 2007 6 28 15 20 15 45 ON ON ON ON ON OFF 2007 6 28 15 20 15 47 ON ON ON ON ON ON 2007 6 28 15 20 19 238 OFF OFF OFF ON ON ON 2007 6 28 15 20 19 239 OFF OFF OFF ON ON ON 2007 6 28 15 20 19 239 OFF OFF OFF ON ON ON 2007 6 28 15 20 22 601 OFF OFF OFF ON OFF ON 2007 6 28 15 20 22 602 OFF OFF OFF OFF OFF ON pe per pary par re a aal Suoouomurouo co Newest SOE Record No 7 SOE Records from AXM4O12 Fig 5 14 data information of SOE records read by the utility software fawim I Series c Parameter Setting of Detection of Remote Signals Take parameter setting of AXM IO11 AXM IO1 module in logic NO 1 for example 109eH register this register is an
211. tion Display Panel and Keys The front of the Acuvim II series meter consists of an LCD screen and four control keys All the display segments are illustrated in fig 3 1 Users should note that all the segments will not display in a single page under normal conditions 4 Meter Max Min Demand Harmonic Setting Digital 1 0 Lamm x2 wp wp wd wb T MUN UN 77 1 pf ND ME mw UnbalanceMAX e 2 3 M JW Ji MokA a ces 77 JN EN EL NE eas Js o toad 3 1 JW jur jwi jwi kv a fot Jnd ond NE mva os jwi Wid wi rte Fie 1 pad psp TT s Mx ee B BB BERESENS 17 x2 x2 2 a ut EE 13 Fig 3 1 All Display Segments Display mode indication Shows different modes on the display area Meter for real time measurement Max Min for statistic data Demand for power demand data Harmonic for harmonic data Setting for parameters setting Digital I O for expanded IO module data Four lines of AW digits in the metering area Main display area displays metering data such as voltage current power power factor frequency unbalance phase angle etc Displays statistics such as maximum and minimum demand data display settings and expanded I O data Four H and five P digits Displays energy data and real time clock Also used for the setting mode and digital I O mode display I Three ping digits B uy Item Icons U for voltage I for
212. tion user should read the Used Records field and compare it to the previous Used Records field from the last reading before retrieving the information and reading the window If the current Used Records field is greater than the Used Records field from the last reading and if the Offset field is less than the difference between the current and previous Used Records field the first sector has been erased and the difference between the Used Records field should be subtracted from the recording number If the Offset field is greater than the difference between the current and previous Used Records field the Offset number should be subtracted from the recording number To avoid this situation user should read the log before it is almost full For example Data logging 1 has 3 sectors and each has 448 records and the total records are 1344 If you press the Read All button when the Used Records number is at 1340 and if the first sector is erased before the information is transferred to the computer the data stored in this sector is erased permanently and cannot be retrieved If the records from the first sector can be retrieved before it gets erased the new value of Offset will equal to the original Offset field minus the value of the difference between the current and previous Used Records field Data logging opration examples The following example illustrates a data logging opertation The example makes
213. ttings TOU setting User can set a maximum of 12 TOU seasons each season can be assigned to a TOU schedule a maximum of 14 TOU schedules are available Each schedule can be divided up into 14 segments in which each segment can have its own tariff User can customize the TOU calendar including its tariffs seasons schedules and segments according to different applications To make sure that the TOU calendar is setup correctly the meter will check the TOU settings according to the predefined rules see below for TOU setting format requirement for details TOU function will be disabled if the TOU calendar is set up incorrectly If no errors are found in the calendar and the TOU function is enabled TOU energyaccumulation will begin TOU setting format requirement 1 Season setting parameter The calendar year will be divided up into different seasons depending on the season setting parameter The parameter can be selected from any integer between 1 to 12 User must enter the correct value for the season setting parameter in accordance to the TOU season table If the season setting parameter is set as 2 the first 2 slots of the TOU season table must be set otherwise it will be considered as an invalid input TOU function will be disabled 2 TOU season format Enter the start date into the TOU season table slot following this format MM DD ID MM stands for the month DD stands for the day and ID stands for the TOU schedule ID avai
214. ulse output indicator J l No icon no pulse output With icon icon blinks when sending pulse output 13 Expanded I O module indicator M1 x2 M2 x2 M3 x2 M1 one AXM IO1 connected M1x2 two AXM IO1 connected None no AXM IO1 connected M2 one AXM IO2 connected M2x2 two AXM IO2 connected None no AXM IO2 connected M3 one AXM 1O3 connected M3x2 two AXM IO3 connected None no AXM IO3 connected 14 Profibus module indicator Profi bus No icon Profibus module not connected With icon Profibus module connected 15 Ethernet module indicator pz No icon Ethernet module not connected With icon Ethernet module connected when the Second Communication Protocol is setting as Others BACnet module connected when the Second Communication Protocol is setting as BACnet 16 T1 T2 TS T4 Current tariff 17 Time icon Q Time display There are four keys on the front panel labeled H P E and V A from left to right Use these four keys to read real time metering data set parameters and navigate the meter Note If the LCD backlight is off pressing any key one time will bring the 32 backlight on 3 2 Metering Data Pressing H and V A simultaneously will activate the display mode selection and the cursor will flash Press P or E to move the cursor right or left To enter the metering mode move the cursor to Meter then press V A Beatos I Series In the meter
215. ults of Acuvim II series meter Table 5 9 is an example of reading the 6 measured data Time from server device address 1 the data start address is 1040H Table 5 9 Read Time Query Message Transaction Transaction Protocol Protocol Lenathihi Length l Unit identifier hi identifier lo identifier hi identifier lo 9 9 identifier 00H 00H 00H 00H 00H 06H 01H Data start Data start Data of Data of Fun A i reg hi reg lo regs hi regs lo 03H 10H 40H 00H 06H Response IJ Sema An example response to read Time 2006 12 18 14 15 20 is shown as Table 5 10 ANa Table 5 10 Read Time Response Message Transaction Transaction Protocol Protoco llenathihit Wlanathil Unit lt identifier hi identifierlo identifier hi identifier lo g 9 identifier 00H 00H 00H 00H 00H OFH 01H Byte Data1 Data1 Data2 Data2 Data3 Data3 Data4 Data4 Data5 Data5 Data6 Data6 count hi lo hi lo hi lo hi lo hi lo hi lo 03H OCH 07H D6H OOH OCH OOH 12H OOH OEH OOH OFH OOH 14H Fun d Control Relay Function Code 05 Query The message forces a single Relay either on or off Any Relay that exists within the Acuvim II series meter can be forced to be either status on or off The address of Relay starts at 0000H and the meter has eight Relays The data value FFOOH will set the Relay on
216. umber of ten waveforms after 11 waveform is triggered 1024111 Each waveform number of ten waveforms after I2 waveform is triggered 1124121 Each waveform number of ten waveforms after 13 waveform is 97 Acuvion I Sven Bee I Series triggered Note Unless user retrieves all data from 8E00H to 8E43H in one time Waveform Group Number for Retrieving 8E01H will automatically add 1 or Waveform Group Number for Retrieving BEO1H will keep present value if only retrieving partial data 1 100 Waveform Group Note When the value is smaller than or equal to 8E00H p A Number for Retrieving newest waveform record group number this value is valid Waveform Group Waveform number SEOIH Number 0 121 OxOBH window data is valid 8E02H Waveform record OxFF window data is invalid window status OxAA waveform record memory is clearing data is invalid Newest Waveform 1 100 8E03H Group Number O no record 8E04H Waveform record data 8E43H S retrieving window boss iud 5 Relationship between voltage or current waveform value and real value The relationship between voltage waveform value and real value Real Value Unit V Waveform Value 37 59105 The relationship between current waveform value and real value Real Value Unit A Waveform Value 1683 153 When users select 333mV Voltage type CT real Value Unit A Waveform Value 15869 87 The vol
217. user to analog voltage or current The analog output circuit supplies 4 output modes including 0 to 20mA mode 4 to 20mA mode 0 to 5V mode and 1 to 5V mode Figure 5 20 shows the relationship between analog output and various electrical quantities mA V X4 Y4 Fig 5 20 Relationship between analog output and various electrical quantities Note Following part introduce how AO function works Addresses about AO function are from 10DOH to 10F3H which include three groups parameters such as Gradient Number AO following value range AO output range 1 AO Gradient Number Selection of input output transfer curve When number is 1 which includes X1 Y1 and X4 Y4 only AO following value range setting start point AO following value range setting end point AO1 output range setting start point and AO1 output range setting end point should be set When number is 2 which includes X1 Y1 X2 Y2 and X4 Y4 only AO following value range setting start point AO1 following value range setting point 2 AO following value range setting end point AO1 output range setting start point AO1 output range setting point 2 and AO1 output range setting end point should be set When number is 3 which includes X1 Y1 X2 Y2 X3 Y3 and X4 Y4 only AO following value range setting start point AO1 following value range setting point 2 AO1 following value range setting point 3 and AO following value range setti
218. ust set their own DNS Server Please refer to Network settings which includes DNS Server setting Please note as per 3 c of Section 5 2 11 there are three modes users can select The first is Trigged Sending which means once new events happen users can receive email notifications immediately The second is Timed Sending mode Users can receive emails based on preset time invervals 5 1440 minutes which include all information on Data webpage The third mode is a combination of Triggered Sending and Timed Sending 5 3 ProfiBus Module AXM PRO 5 3 1 Introduction of PROFIBUS Technology PROFIBUS Process Field bus is an international field bus standard which is widely used in automation technology of manufactures and flow industry It is a widely used open digital communication system which is suitable for high speed time critical and high reliability communications Bee I Seru PROFIBUS is one kind of open style field bus standard which is promoted by SIEMENS Corporation In 1989 it became the German standard DIN19245 in 1996 it became the European standard EN50170 in 1999 it was accepted as part of the international standard IEC61158 and in 2001 it became the Chinese national standard JB T 10308 3 2001 for field bus of machinery industry controlling systems There are 3 types of PROFIBUS PROFIBUS DP Decentralized Periphery PROFIBUS PA Process Automation and PROFIBUS FMS Field bus Message Specification
219. value MI l M3 I l oc Muon Li LILI a E 00 Load 1 2 L nann Li LLLI T Hi m Fig 5 24 Al value read on screen 5 2 Ethernet Module AXM NET 5 2 1 Introduction to Ethernet Ethernet was originally developed by Xerox and then developed further by Xerox DEC and Intel Ethernet uses a Carrier Sense Multiple Access with Collision Detection CSMA CD protocol and provides transmission speeds up to 10 Mbps Bee I Seru Now Ethernet stands for LAN with CSMA CD protocol Ethernet is the most current communication standard in LAN This standard defines the used type of cable and the method of Signal processing in LAN 5 2 2 Function Description of Ethernet module Please read appendix of technical data and specifications of Ethernet module before using The Ethernet module supports Modbus TCP protocol It is used as a server the default value of the protocol port is 502 and the user defined range of the protocol port is 2000 5999 The device address is the same as the meter The Ethernet module supports SMTP protocol It has an email function and supports Send mail for timing mode and Send mail for event mode The Ethernet module supports HTTP protocol It is used as an HTTP server the default value of the protocol port is 80 and the scope of the protocol port is 6000 9999 fawim I Series 140 5 2 3 Appearance and Dimensions
220. value of phase voltage will not be displayed iii When the meter is set to 1LL there are no such displays as phase C voltage Ubc and Uca line voltage phase C current three phase voltage and current unbalance factor Uc and IC THD phase C current demand etc iv When the meter is set to 1LN there is only phase A display of phase voltage and current only Ua and la THD display only demand display of phase A And there are no such displays as three phase voltage and current unbalance factor line voltage etc Bee I Seru Bee I Series 3 4 Demand Data 3 5 Pressing H and V A simultaneously will activate the display mode selection and the cursor will flash Press P or E to move the cursor right or left To enter demand mode move the cursor to Demand then press V A In the demand data mode the first screen displays the demand of active power reactive power and apparent power and the second screen displays the current demand of phase A phase B and phase C When the meter is set to 1LL there is no phase C current demand display When the meter is set to 1LN there are no phase B and C current demand display As shown in the figure system active power demand is 3 285kW system reactive power demand is 0 kvar system apparent power demand is 3 285 kVA Co Jego sa monn kvar ys 2000 5 ZLLE LL 5 n 8 un m gs Harmonic Data Pressing H and V A simultaneously will activate t
221. w see details in Chapter 6 Aawin I Series 8CFDH The newest event number word R Range 1 50000 0 No event 8CFEH The starting event log number word R W Range 1 50000 Note smaller than or equal to the newest event number 8CFFH The event quantity of each time word R W 1 10 retrieve Bom E Es Bo BEB ENN 5652 Sa 2 wt OREO Ree Newest Event Record No 8 Read newest 10 records x Stat Record No f1 Read Stop Save No Time Stamp ms Reason Rating fV Threshold Half cycle 1 2013 6 24 10 48 51 472 Voltage Saq B 400 50 10 2 2013 6 24 10 49 07 864 Voltage Sag 400 50 10 3 2013 6 24 10 49 34 869 Voltage Sag 400 50 10 4 2013 6 24 10 49 41 767 Voltage Sag B 400 50 10 5 2013 6 24 10 53 04 900 Voltage Sag C 400 50 10 6 2013 6 24 10 53 16 908 Voltage Sag C 400 50 10 7 2013 6 24 10 53 20 845 Voltage Sag C 400 50 10 8 2013 6 24 10 53 24 897 Voltage Sag 400 50 10 Fig 4 13 Waveform Capture Acuvim IIW can record 100 groups of voltage and current waveform data at a sampling rate of 64 points per cycle It provides the captured waveform of 10 cycles before and after the triggering point including U1 U2 U3 11 12 13 The triggering condition is settable 1 Waveform Capture Data Format 92 Timestamp 7 words Triggering Condition 9 words Kept Data Storage 48 words U1 U2 U3 I1 I2 I3 Before triggering point 1
222. wa OOOiA DIVA oook ODOIA 1000 10 100 1000 00x 25 onoo14205 09 omowa oook ooa ooowa O00010A 19 10 10 1 000 205 E 20001 4 20 52 09 0 00000 kvar 0 00000 kVA O OOCOOKVA 000000KVA Oooo kvA 1 000 1 000 1 00 1 000 00 a amasa nono var aooaa oook aoka oomoka 100 100 100 1000 anx a anasan nomoka omowa noa aowa nomma too 100 100 to anx wa 0 00000 kvar OCODMOKVA D OCOOKVA 000000kVA DODDOUDKNA 1 000 1 000 1 000 1 000 sex Y Fig 4 9 Retrieval screen The read one window method allows you to access and read a specific log location at an offset from the first log The window record num is the maximum number of record entries the software can read at a time it is calculated by 246 Record Size The larger this number is the faster data can be retrieved Log type is the logs you want to retrieve for example log type 0 is data logging 1 log type 1 is data logging 2 and log type 2 is data logging 3 The read all method accesses and reads the historical data log automatically the offset increases automatically until all the logs are retrieved The data logs contents are shown at the bottom of the page 4 6 Time of use TOU User can assign up to 4 different tariffs sharp peak valleyand normal to different time period within a day according to the billing requirements The meter will calculate and accumulate energy to different tariffs according to the meter s internal clock timing and TOU se
223. when E is pressed at the first page Press V A to modify the selected parameter Key functions for modifying the parameter Press H to move the flashing cursor to the next position Press P to increase the number by 1 while the number was 9 Ethernet or 7 BACnet IP or 3 BACnet MS TP the number will return to O after press P Press E to decrease the number by 1 while the number was 0 the number will return to 9 Ethernet or 7 BACnet IP or 3 BACnet MS TP after press E Press V A to confirm the modification and return to parameter selection mode The following figure shows the sequence of Ethernet module Bee I Seru auwim I Serin 58 A Ethernet setting Y N01 DHCP setting PO y 0 N02 IP Address CP y N03 Submask Nog Ethernet resetting selection CP 4 N10 Password resetting selection The selection of DHCP setting MANU or AUTO Default setting MANU IP address has four segments Any segment can be set from 0 255 Default setting 192 168 1 254 Submask has four segments Any segment can be set from 0 255 Default setting 255 255 255 0 Gateway has four segments Any segment can be set from 0 255 Default setting 192 168 1 1 DNS1 has four segments Any segment can be set from 0 255 Default setting 202 106 0 20 DNS2 has four segments Any segment can be set from 0 255 Default setting 0 0 0 0
224. wim I Series Real number of pulses A x Recorded number of pulses For example if A 20 the recorded number of pulses counted by DI1 circuit of AXM IO11 is 100 4349H to 434aH registers then the real number of pulses is 20x100 2000 The parameter setting is shown in Figure 5 13 5 1 8 Relay Output Relays in IO modules can work in two different modes one is controlling mode and the other is alarm mode For controlling mode relays can be switched on and off directly For alarm mode the action of relays is controlled by whether the alarm has occurred or not There are two mode selections for relay output one is latching and the other is pulse For the latching mode the relay can be used to output two status on or off For the pulse mode the output of the relay changes from off to on for a period of time and then goes off The period can be set from 50 to 3000ms Note when relay is working in alarm mode the default output mode is latching mode a Display of Relay State If relay state is ON it means that relay is switched on If relay state is OFF it means that relay is switched off Figure 5 18 shows the status of relays read on screen Figure 5 12 shows the status of relays read by the utility software ha 4 rea ez Tht Con LIN ms c Bh nrc CB GFF nn n LI Fig 5 18 status of relays read on screen b Parameter Setting Take AXM IO11 AXM IO1 module in logic NO 1 for e
225. word R W 1041H Month F3 1412 word R W 1042H Day F3 1 431 word R W 1043H Hour F3 0 23 word R W 1044H minute F3 0 59 word R W 1045H second F3 0 59 word R W 6 3 4 Over Under Limit Alarming Setting This setting consists of global alarm settings and single channel alarm settings Global alarm settings contain settings of all global variables There are 16 groups of records with the same format Function code 03H for reading 10H for writing Please refer to Chapter 4 for more details Global alarming settings 1046H Global alarming enable O disable 1 enable word R W 1047H Alarming flash enable O disable 1 enable word R W 1048H Alarming channel enable setting 0 65535 BitO channel 1 1 enable O disable Bit1 channel 2 Bit15 channel 16 word 1049H Logic And between alarming setting 0 255 BitO first logic switch T enable O disable Bit1 second logic switch Bit7 eighth logic switch word 104aH Alarming output to DO1 setting 0 65535 BitO channel 1 output 1 enable 0 disable Bit1 channel 2 output Bit15 channel 16 output word R W 104bH Alarming output to DO2 setting 0 65535 The same as previous word R W 104cH Alarming output to DO3 setting 0 65535 The same as previous word R W 104dH Alarming output to DO4 setting 0 65535 The same as previous word R W
226. x of Eq_im sharp demand and time 32768 32767 Int R stamp 750cH 750fH Max of Eq exp sharp demand and time 32768 32767 Int R stamp 7510H 7513H Max of Es sharp demand and time stamp 32768 32767 Int R 7514H 7517H Max of la sharp demand and time stamp 32768 32767 Int R 7518H 751bH Max of Ib sharp demand and time stamp 32768 32767 Int R 751cH 751fH Max of Ic sharp demand and time stamp 32768 32767 Int R 7520H 7523H Max of Ep_imp peak demand and time 32768 32767 Int R stamp 7524H 7527H Max of Ep_exp peak demand and time 32768 32767 Int R stamp 7528H 752bH Max of Eq_im peak demand and time 32768 32767 Int R stamp 752cH 752fH Max of Eq exp peak demand and time 32768 32767 Int R stamp 7530H 7533H Max of Es peak demand and time stamp 32768 32767 Int R 7534H 7537H Max of la peak demand and time stamp 32768 32767 Int R 7538H 753bH Max of Ib peak demand and time stamp 32768 32767 Int R 753cH 753fH Max of Ic peak demand and time stamp 32768 32767 Int R 7540H 7543H buc Ep imp valley demand and time 32768 32767 Int R 7544H 7547H Max of Ep_exp valley demand and time stamp 32768 32767 7548H 754bH Max of Eq_im valley demand and time stamp 32768 32767 754cH 754fH Max of Eq_exp valley demand and time stamp 32768 32767 7550H 7553H Max of Es valley demand and time stamp 32768 32767 7554H 7557H Max of la valley deman
227. xample RO working mode 10a0H register this register determines the working mode of relays If the register is 0 then RO1 and RO2 will work in controlling mode If the register is 1 then RO1 and RO2 will work in alarm mode RO output mode 10a1H register this register determines the output mode of relays If the register is 0 then RO1 and RO2 will work in latching output mode If the register is 1 then RO1 and RO2 will work in pulse output mode RO pulse width 10a2H register when the relays are working in pulse mode this register determines the period of time which can be set from 50 to 3000ms For example if this register is 100 the relay RO1 or RO2 will be switched on for 100ms after receiving ON instruction and then be switched off The parameter setting is shown in Figure 5 13 Bee J Sema fawim I Series 5 1 9 Digital Output There are two mode selections for the digital output circuit one being alarm mode and the other being energy output mode For alarm mode action of digital output circuit is controlled by whether the alarm is triggered or not For energy output mode digital output circuits can output various types of energy such as import active energy export active energy import reactive energy and export reactive energy When outputting energy pulses pulse width can be set from 20 to 1000ms The minimum interval between two pulses is 20ms Parameter Setting
228. y Sharp import reactive max demand 8 Y Sharp Apparent energy Sharp Export reactive max demand Y l oS Peak Import energy Sharp Apparent max demand Y Peak Import max demand 8 o6 PeakA pparent max demand en zs Valley Apparent max demand I 8 je a 5 5 a Normal Apparent max de 09690000 89896 Total Apparent energy CE 8 B gt Total Apparent max demand 37 iwim I Series A fawim I Series 3 3 e TOU display Press P and E simultaneously to enter the TOU Energy and maximum demand page Press E display the TOU energy Press P display the TOU maximum demand Press again display the TOU maximum demand year month and date Press again display the TOU maximum demand hour minute and second Press H would change the tariffs page It displays energy under different tariffs in the energy page It also displays demand under different tariffs in the maximum demang page Press V A would display different type energy and maximum demand Press P and E simultaneously to exit current page and return to metering mode Statistics Data Pressing H and V A simultaneously will activate the display mode selection and the cursor will flash Press P or Eto move the cursor right or left To enter the statistics dat
229. y and schedule 7B57H 7B59H The 30 holiday and schedule word R W 7B5AH The 1 setting year word R W 7B5BH Holiday number of the 1 year word R W Zeb Ber format month day schedule word SM 7B5FH 7B61H The 2 holiday and schedule word R W 7B62H 7B64H The 3 holiday and schedule word R W 7B65H 7B67H The 4 holiday and schedule word R W 7B68H 7B6AH The 5 holiday and schedule word R W 7B6BH 7B6DH The 6 holiday and schedule word R W 7B6EH 7B70H The 7 holiday and schedule word R W 7B71H 7B73H The 8 holiday and schedule word R W 7B74H 7B76H The 9 holiday and schedule word R W 7B77H 7B79H The 10 holiday and schedule word R W 7B7AH 7B7CH The 11 holiday and schedule word R W 7B7DH 7B7FH The 12 holiday and schedule word R W 7B80H 7B82H The 13 holiday and schedule word R W 7B83H 7B85H The 14 holiday and schedule word R W 7B86H 7B88H The 15 holiday and schedule word R W 7B89H 7B8BH The 16 holiday and schedule word R W 7B8CH 7B8EH The 17 holiday and schedule word R W 7B8FH 7B91H The 18 holiday and schedule word R W 7B92H 7B94H The 19 holiday and schedule word R W 7B95H 7B97H The 20 holiday and schedule word R W 7B98H 7B9AH The 21 holiday and schedule word R W 7B9BH 7B9DH The 22 holiday and schedule word R W 7B9EH 7BAOH The 23 holiday and schedule word R W 7BA1H 7BA3H The 24 holiday and schedule word R W 7BA4H 7BA6H The 25 holiday and
230. y and schedule word R W 3 7E66H 7E68H The 15 holiday and schedule word R W S 7E69H 7E6BH The 16 holiday and schedule word R W N 7E6CH 7E6EH The 17 holiday and schedule word R W f 7E6FH 7E71H The 18 holiday and schedule word R W E 7E72H 7E74H The 19 holiday and schedule word R W 7E75H 7E77H The 20 holiday and schedule word R W 7E78H 7E7AH The 21 holiday and schedule word R W 7E7BH 7E7DH The 22 holiday and schedule word R W 7E7EH 7E80H The 23 holiday and schedule word R W 7E81H 7E83H The 24 holiday and schedule word R W 7E84H 7E86H The 25 holiday and schedule word R W 7E87H 7E89H The 26 holiday and schedule word R W 7E8AH 7E8CH The 27 holiday and schedule word R W 7E8DH 7E8FH The 28 holiday and schedule word R W 7E90H 7E92H The 29 holiday and schedule word R W 7E93H 7E95H The 30 holiday and schedule word R W 7E96H The 10 setting year word R W 7E97H Holiday number of the 10 year word R W Manual 8000H Triggering word R W OXAA Enable 0 Waveform O Disable bit1bitO DI1 bit3bit2 DI2 bit5bit4 DI3 bit7bit6 DI4 bit9bit8 DI Triggering DI5 biti 1bit10 DI6 8001H AXM 11 word R W 00 Disable 0 01 From OFF to ON 10 From ON to OFF 11 Any DI state change Bee Series DI Triggering Bit1bitO DI7 bit3bit2 DI8 bit5bit4 DI9 8002h AXM 21 ward oR bit7bit6 DI10 3 The same as above Bit1bitO DI11 DI Triggering b
231. ytime before accessing the parameter setting mode The default password is 0000 After entering the password press V A to go to the parameter selection page The meter will be still in the password inquiry page if a wrong password is entered The following figure shows the password inquiry page Setting MEE g id LI UR vu nnnn a Li LELILI Bee I Seru To input password I Series Press H to move the flashing cursor to the next position Press P to increase the number by 1 Press E to decrease the number by 1 LAMAN A Press V A to confirm the password b Parameter Selection Mode There are four parameters to choose from in the parameter selection manual system expanded I O module Ethernet module and alarm No commands are associated with the H key in the parameter selection manual Press P to move the cursor downwards the cursor will move to the top when it reaches the bottom Press E to move the cursor upwards the cursor will move to the bottom when it reaches the top 5 gt e 50 Qu Load LJ 2 lF HLPI F m qI i 2H rd asii Press V A to select and modify the parameter The figure shows the parameter selection page SYS stands for system parameter I O stands for expanded 1 O module parameter NET stands for Ethernet module parameter and ALM stands for alarm parameter As shown in the figure the cursor

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