OPERATION AND CONFIGURATION MANUAL
Contents
1. 7 Y Calibration N Xx ea IN e H Output J Outputs J Pita Inputs win baton H Cal mV H Tools N Test Serial RS 485 r 5 HB5 Type Format Baudrate el gt lt gt y Y oFF dE SE ASC HH ee EF IFelF3IFAIFSIFEIF 1 4800 960 co i3200 eld FOIFSIE DIE DOE RIF 38400 51600 1 5200 lt Pam 4 Parity Transmission Rate Termination PIAl our RL E ElElr gt _ Y nont EUEn odd HS 0 eS 38 LF Cr VEE mont q5 150 300 600 4 gE aa lt Prot Adress RTermination Plr ole Aldid rE Er nent 5 485 IF lt eel 4 When TYPE parameter is in mode ACII or RTU these functions are not enabled Figure 3 4 1 Communication port RS 485 3 4 1 MODE EYPE Transmission mode These are the options DEACTIVATED off No data transmission DEMAND n Data transmission on external request through the serial port STREAM t Continuous data transmission ASCII ASE 1 MODBUS ASCII RTU EDS MODBUS RTU 34 2 FORMAT For Format of the transmitted data for DEMAND and STREA2. d ou d_out N VL i Type i REL i Ll _ Y _ Enter numerical off 9055 AcE Pr Et In rEL ies value Pi P EL a I P EL DEr o OnE 155 ui larAn9 AES ERFE Pe int PC_CEr ES a lt ZA TRIP i BAND HYSTERESIS D_LOC i HOLD i DELAY i El IP fi Diela HS Dal ole Holt al li DIELS lt E Y ar ru y Enter numerical Enter numerical Cam Enter numerical Enter numerical G Bun Sr value value value value Bd lt lt lt 1 lt 2 lt Figure 3 7 1 Digital outputs 3 7 1 D OUT N d_oUE n Digital output number Possible options 3 7 10 3 3 7 2 VL i UL Is the value at which the selected output operates This value should be between MAX and MAX and also should be compatible with the scale division d and dF see 3 2 2 and 3 2 3 This value never can be smaller than 99999 If the introduced value is incorrect the display will show the sl a rie L m error 3 14 Configuration 3 7 3 TYPE i EYPE Type of output action These are the options OFF OFF __ Deactivated GROSS Sr055 Gross weight value as reference NET NEE Net weight value as reference REL P_rEL REL n_r EL REL P_PrEL REL n_Pr EL ZERO UEro ZERONET Une
3. ET EP 1 e Message In LEEP during Message PL waiting for Mensaje rEnatE waiting parameters initialization PC communication for PC communication Figure 5 1 1 Tools 5 1 1 Weight x10 H_rES Displays the weight value with a resolution multiplied by ten 5 1 2 mV Metro 5 IGnAL Displays the ADC value output in mV 5 1 3 Print Cal P_CAL Allows the user to print the parameters through RS 232 port 5 1 4 Par Reset PrESEt Resets all the parameters to the default configuration 5 1 5 SW Update UPDALE It allows the user perform a software device update through a PC program Bootloader SWIFT It is necessary to place the right PIN number afterwards the device stays waiting the PC communication If communication is not running and EXIT key is pressed the device will restart 5 1 Tools amp Test 5 1 6 Remote Calibration CAL _PL It allows the user perform a remote calibration through a PC program It is necessary to place the right PIN number afterwards the device stays waiting the PC communication To modify metrological parameters it is necessary that the calibration switch see figure 3 1 1 unlocked at the time of entering the configuration menu Changing these parameters will increase the calibration counter If communication is not running and EXIT key is pressed
4. RA ee ee ee ee ee ee ee ee ee ee ee 6 4 8 5 MODBUS Proio sl EE ES hte Bean 6 5 6 5 1 General Characteristics sic 6 5 6 5 2 MODBUS supported functions r 6 5 6 5 3 Warnings and saving parameters in the NVM nonvolatile memory 6 5 6 5 4 Parameters and variables addressing ee ee Re ee ee ee ke ee 6 6 65 8 Command Register es ae 6 6 6 5 6 Returned Error Codes ii ee 6 6 6 5 7 Using the command register een 6 7 6 5 8 Numerical data format een een 6 8 65 9 MODBUS address conversion r 6 8 6 5 10 Registers address tables de 6 9 6 5 11 Binary mode on digital outputs u en ee 6 17 7 Connections ae ae 7 1 7 1 Load Cell COMECION ns ee le 7 1 7 2 Loadicell sealifi da a s seca tes S N SM soe Saya a Q E ER Ge a as 7 1 8 Appendix Power supply accessory 8 1 ses id ER a RE us su ME EE aren seus wed N ON EE ER 8 1 8 2 General specifications da EE ren 8 1 8 3 Conformity Declaratii ss se een 8 2 9 Appendix Installation in protected area 9 1 Operation 1 Introduction 1 1 Indicator Characteristics 1 1 1 Load Cell connection Full scale input signal 13 9 mV V Input impedance 200 MO typical Internal resolution Converter AD 24 bits 16 700 000 counts 8 350
5. Command Registers Address Description Comments 41001 Command Register See table 6 5 7 2 41002 Command Data H 41003 Command Data L 41004 Status Command Register Only read See table 6 5 7 3 Table 6 5 7 1 The command register reading 41001 has the same answer as the status register 41004 Writing a command code in the command register will cause an action according to the following table Available Commands Code Function 1 Zeroing 2 Automatic Tare Prefixed tare first of all write the 3 tare value in the command register data 6 Exit tare Print prints a ticket if RS 232 port is configured in ticket mode 30 Reset device 32 Save in NVM nonvolatile memory the modified registers Cancel allows to cancel functions if for any reason they 1100 stay in a state indefinitely because a non stability or a load cell error Table 6 5 7 2 During command 32 execution save in NVM the device response with error code 6 SERVER DEVICE BUSY to any MODBUS command When sending 1 zero 2 automatic tare and 7 print commands the device can take a while for executing them i e non stable weight During this time if we attempt to read the command status through 41001 or 41004 registers we will get the correspondent code function and value 4 in status executing command pending When a function is in 4 status executing pending is possible to send
6. KEYB LOCK Keyboard lock PRINT LOCK PRINT key lock TARE LOCK TARE key lock ZERO LOCK ZERO key lock F LOCK F key lock 3 3 7 PRINT MINIMUM Prt Is the minimum weight value in divisions at which a print ticket request it is accepted The value can be within 0 and 255 divisions Any attempt to make an impressions with the weight below the EEC IN will be displayed programmed the error 3 3 8 TICKET PrE_tE Select the type of ticket to be printed with the Print key These are the options OFF No ticket printing EE Standard ticket 3 3 9 TICKET ID E id Edit the number of the next printing ticket The minimum value is 1 and the maximum is 65 000 If Er L a higher or a lower value is introduced the will be displayed 3 8 Configuration 3 4 Communication port RS 485 Within the Communication port RS 485 level parameters showed in Figure 3 4 1 can be found Once we have introduced the Id_2802 of the device optional if we want modify protected parameters we are inside the configuration menu being the first configuration screen and from there we can move along the configuration menu NE NE O Neuf Scale Def H Options Serial RS 485 JU Serial RS 232 H Analog Digital L N ANO
7. 19200 38400 57600 115200 Refers to the 7 possible values OFF 100 250 500 1000 2000 5000 10000 Refers to the 4 possible values CRLF CR ETX NONE Refers to the 15 possible values See table 0 command 32 in the command register except the set points that are saved directly when writing the registers 11 Parameter s changes in serial ports are effective after reset the device So it is mandatory to send the 12 E2PROM records command to not lose any changes When the register 41150 Binary mode status is set to 1 digital outputs acts in binary mode and disable the D OUT menu configuration 6 11 Communications Table K Available Commands Code Function 1 Semi automatic Zeroing 2 Semi automatic Tare Prefixed tare first of all write the 3 tare value in the command register data 6 Exit tare 7 Print prints a ticket if RS 232 port is configured in ticket mode 30 Reset device 32 Save in E2P Cancel allows to cancel functions if for any reason they 100 stay in a state indefinitely because a non stability or a load cell error Table 6 5 10 1 2 Table L Reading command status register 16 bits High byte 8 bits Low byte 8 bits Executing command code Status according to table Value Command execution command 6 5 7 2 1 Correct 2 Error during execution 4 Execution pending 8 Cancelled command through executing cance
8. EIA weight value see 3 3 7 Check that MAX value is correct m Foo MAX E Ir CA CP rir Not accomplished lt 100000 Change DIV to accomplish the relation WAK Check that DIV value is correct E cirjd Not accomplished 7 lt 100000 Change MAX to accomplish the relation Lol b RE Power failure Check power supply ID The maximum number of calibrations f i U LIE L HL CO 9 999 has been reached Contact your technical service Unplugged Plug it in Indicator failure Contact your technical service 1 6 Maintenance 1 6 1 Cleaning a Unplug the device from supply b Clean the indicator with a clean and dry cloth CAUTION Never use alcohol or solvents to clean the indicator These chemical products could damage it Make sure that water does not enter the indicator It could damage electronic components Operation 2 Operation 2 1 Turning the indicator on To turn the indicator on connect it to the power supply The switch on process will first display a test countdown sequence with the weighing LEDs blinking at each step The sequence ends with the software version 3 the equipment serial number Snr and finally the number of performed calibrations AL hd DO ME NET EM PT E nd 0x NET PT 0 NET PT hd ES 0 ME NET EM PT ME 0 NET PT hd ES NET E PT ME h 4 MO NET PT 0 NET PT nd N
9. Hy 1 H 0 CAP 7 Hy 1 L d Loc 1 0 OFF 1 0N Timer 1 0 200 200 equals to 20 0s Delay 1 VL2 Setpoint 2 H 0 200 200 equals to 20 0s CAP CAP VL2 Setpoint 2 L Type 2 0 15 See table I Rel 2 0 3 0 Setpoint 1 1 Setpoint 2 2 Setpoint 3 Trip 2 0 3 Y See table J Band 2 H 0 CAP Band 2 L 0 CAP Hy 2 H Hy 2 L d _ Loc 2 Timer 2 0 OFF 1 ON 0 200 200 equals to 20 0s Delay 2 0 200 200 equals to 20 0s VL3 Setpoint 3 H CAP CAP VL3 Setpoint 3 L Type 3 0 15 7 See table I Rel 3 0 3 0 Setpoint 1 1 Setpoint 2 2 Setpoint 3 Trip 3 0 3 Y See table J Band 3 H 0 CAP 41117 045C 116 Hy 3 H Long 0 CAP Yes 41118 Hy 3 L Yes 41119 045E 118 d Loc 3 Byte 0 OFF 1 ON Yes Byte 0 200 ei ad 2 Timers 200 equals to 20 0s Yes 6 10 Communications Address Hexa Command Address Decimal Command Address E2PROM Register ao Description Format Values Range Comments Byte 0 200 41121 200 equals to 20 0s 0460 1120 Delay 3 Digital Input 1 OFF TARE CLR TARE ZERO PRINT LOW HIGH Type 1 Func 1 Digital Input 2 OFF TARE CLR TARE ZERO PRINT LOW HIGH Type 2 Fu
10. being the first configuration screen and from there we can move along the configuration menu 7 PET Sr Z Scale Def H Options H Serial RS 485 a Serial RS 232 e H ee MH ua H Digital Inputs H an H Cal mV Y Tools Test IN utpu Y _ utputs e W N WI masses x y Go Z Go J Analog Output R_ out Type Output Error LB PE olule Put Error lt y y 9055 nEt 4 20 0 20 0 5 0 10 FULL Hold DEro Min Full TW Min TW Full EF SEE Enter numenrical value Enter numerical value lt EEUE gt SEE IE E Pal Pal Pas Figure 3 6 1 Analog Output 3 12 Configuration 3 6 1 TYPE EYPE Weight value for the analog output signal These are the options 9r055 Gross weight value is taken as reference nee Net weight value is taken as reference 3 6 2 OUTPUT oUtPUE Possible options mA 4 20 mA U 5 V u 1D v When configuring the analog output please check the physical wire connection according to the diagram wiring 3 6 3 ERROR Error Outpu
11. ify Digtal Digital inputs Calibration H Calmv H Toots H Test x EN ER BER Output J Outputs j With masses PN PEN y Cal mV Lcap Lnum LSn Zero Dead load LIC RP HL ajo pol dE Aldi IL lt Y ADC Value Enter coeff Y Enter numerical ee numerical value value EIS rr un 3 Y Enter numerical Enter numerical Ge ie value vaue value IE LO e Figure 4 2 1 Numerical calibration 4 2 1 LCAP LCAP Nominal capacity Emax of one of the load cells from the scale It is expressed in the same decimal point used in MAX and DIV see scale definition 3 2 1 3 2 2 and 3 2 3 4 2 2 LNUM Lno Number of load receiver supports All supports must be counted both those which rest on load cells and those which do not 4 3 Calibration 4 2 3 L Sn LSn Load cells nominal sensibility in mV V if values are not the same calculate the average 4 2 4 ZERO UEro Automatic zero adjustment To automatically adjust the zero value make sure there is not any weight on it and press the enter key The indicator will show the present coefficient value On pressing enter again the message CALIB will be shown while the indicator as
12. see 5 1 1 we can see the weight of the scale multiplied by ten This weight is the gross weight GW above the load cells We will calculate the Deal Load of the system by subtracting the gross weight GW obtained in paragraph 4 the net weight NW known or estimated of the material inside the silo So Deal Load is DL GW NW u Now we have to set this value of Deal Load obtained in JEHd_L and validate the value Once the dEAd_L value is validated the device recalculates the new zero and adjusts the system saving the adjustment parameters 4 5 Tools amp Test 5 Tools amp test 5 1 Tools Within the tools level parameters showed in Figure 5 1 1 can be found Once we have introduced the ld 2802 of the device optional if we want to modify the protected parameters we are inside the configuration menu being the first configuration screen the next from there we can move along the configuration menu E N N nee s7 Sf ma N ma ST Scale Def JA Options Y serial RS 485 H Serial rs 222 H Analog Digital _ Digital Inputs Calibration 1 C SN DX f Output EN Outputs PAS J with masses N ea N CalmV H Tools H Test AN IN JP Tools Weight x10 mV metro P_Cal YES N Display weight x10 Display mV 1D hl EE Message Pr int during printing Par Reset SW Update CAL_PC
13. 4 2 3 4 5 6 8 11 EN55024 EN61000 6 2 EN61204 3 heavy industry level criteria A MTBF 1172 3K hrs min MIL HDBK 217F 25 C OTHERS DIMENSIONS 25 x 93 x 56 mm WxHxD TRANSPORT WEIGHT 0 1 KG 8 1 Appendix Power supply accessory optional 8 2 8 3 Conformity Declaration MW MEAN WELL EC Conformity Declaration For the following equipment Product Name Switching Power Supplies Model Designation DR 15 X X 5 12 15 24 is herewith confirmed to comply with the requirements set out in the Council Directive the following standards were applied RoHS Directive 2011 65 EU Low Voltage Directive 2006 95 EC EN60950 1 2006 A11 A1 A12 TUV certificate No R50058736 Electromagnetic Compatibility Directive 2004 108 EC EMI Electro Magnetic Interference Conducted emission Radiated emission EN55022 2006 A1 2007 Class B EN55011 2007 A2 2007 Group 1 Class B EN61000 6 3 2007 Harmonic current EN61000 3 2 2006 Voltage flicker EN61000 3 3 2008 EMS Electro Magnetic Susceptibility EN55024 1998 A1 2001 A2 2003 EN61204 3 2000 EN61000 6 2 2005 ESD air EN61000 4 2 2009 Level3 8KV ESD contact EN61000 4 2 2009 Level2 4KV RF field susceptibility EN61000 4 3 2006 A1 2008 Level3 10V m EFT bursts EN61000 4 4 2004 Level3 2KV SKHz Surge susceptibility EN61000 4 5 2006 Level4 2KV Line Line Conducted susceptibility EN61000 4 6 2009 Level3 10V Magnetic field immunity EN61000 4 8 1993 A
14. OFF 1 ON It allows reading the status of the digital inputs Consult X Answer X I PERDE Xs X X X X Data transfer in ASCII format Xn 6 2 2 Data Format 6 2 Status of the digital input n 0 Low 1 High F1 Format lt STX gt POL ppppppp IU G N IS T F2 Format POL nnnnnnn T F3 Format lt STX gt 1 0 POL nnnnnnn lt ETX gt T F4 Format POL aaaaaaa T F5 Format lt STX gt POL nnnnnnn lt ETX gt T F6 Format Used for a remote display The content of the display is transmitted in hexadecimal D7 D6 D5 D4 D3 D2 D1 Status T Digit code bit 7 segment DP bit 6 segment A bit 5 segment B bit 4 segment C bit 3 segment D bit 2 segment E bit 1 segment F bit 0 segment G Status code bit 7 accumulation activated bit 6 0 fixed bit 5 0 fixed bit 4 piece counting activated bit 3 preset tare PT bit 2 ZERO bit 1 NET bit 0 STABLE Communications F7 Format lt STX gt status POL ppppppp T The status is obtained when you add to Ox20hex the values of the lighted status LEDs Gross 0x01 hex Zero 0x08hex Net 0x02hex Standstill 0
15. Polarity Ey Weight gt 0 u Weight lt 0 U Units K kg T t G g L Ib im oz without unit G N Gross Net G Gross N Net S Status i Valid weight M Motion O Overload Invalid weight T Termination CR CR LF ACK ASCII 6 NAK ASCII 21 6 3 Protocol RS 232 This is the communication between two pieces of equipment point per point with a maximum distance of 15 m Protocol format Command CR All commands in section 6 1 6 4 Network Communications RS 485 This is the communication between several items of equipment 100 maximum in a BUS with a maximum link distance of 1 200 m The SWIFT indicator can only be the SERVER and it must be assigned a unique address from 1 to 99 Client queries and servers responses have the following formats Client query p dd TCR Termination CR fixed Command Address 2 bytes decimal see 3 4 8 Start client query 6 4 Communications Server response gt lad oS TERMIN Termination see 3 4 6 Response Address 2 bytes decimal see 3 4 8 Start server response There are three types of responses Data Received and responded query command ACK Received and understood command NAK Received but not understood command 6 5 MODBUS Protocol 6 5 1 General Characteristics The MODBUS protocol that incorporates this device is based on the specifications of the guide MODBUS over serial line specification and implementation guide
16. V1 02 published by the Modbus Organization www modbus org This protocol allows interconnecting multiple devices server to a device client this client is able to interact individually with them through RS 485 channel There are two different formats for MODBUS communication ASCII and RTU both supported for this device To activate the MODBUS protocol in the device ASCII or RTU format in option TYPE see 3 4 should be selected Parameters baud rate and parity must be the same in the SWIFT as in all the others It is also necessary to configure the bus address on each device to be able to identify each device in the bus see 3 4 8 6 5 2 MODBUS supported functions Function Description 3 0x03 Table 6 5 2 1 6 5 3 Warnings and saving parameters in the NVM nonvolatile memory Many of the writing parameters are saved in NVM This memory has limited writing cycles typically 100 000 so we should avoid writing continuously on it In E2PROM column is indicated if a Holding Register is saved or not in the NVM Set points registers from 41010 to 41015 are saved directly when modifying The rest of parameters only are saved in E2PROM when the correspondent command the 32 is written in the command register register 41001 When turning off the device if the writing command is not executed the written value will not be stored recovering the last stored value 6 5 Communications 6 5 4 Parameters and variabl
17. avoids the possibility to unscrew the connections once is installed This plastic plate should be sealed through two screws which fix the plate to the device 7 1 Appendix Power supply accessory optional 8 Appendix Power supply accessory 8 1 Features i aga Power supply 100 240V AC Universal AC input Full range Protections Short circuit Overload Over voltage Cooling by free air convection Can be installed on DIN rail TS 35 7 5 or 15 Isolation class II LED indicator for power on No load power consumption lt 0 5W 100 full load burn in test 8 2 General specifications DC VOLTAGE 24V RATED CURRENT 0 63A OUTPUT CURRENT RANGE 0 0 63A VOLTAGE ADJ RANGE 21 6 26 4V VOLTAGE TOLERANCE 1 0 VOLTAGE RANGE 85 264VAC 120 370VDC INPUT FRECUENCY RANGE 47 63 HZ AC CURRENT 0 88A 115VAC 0 48A 230VAC WORKING TEMP 20 60 C WORKING HUMIDITY 20 90 RH non condensing ENVIRONMENT STORAGE TEMP HUMIDITY 40 85 C 10 95 RH TEMP COEFFICIENT 0 03 C 0 50 C VIBRATION 1 0 SAFETY STANDARDS UL609050 1 TUV EN609050 1 approved design refer to EN50178 WITHSTAND VOLTAGE P O P 3KVAC ISOLATION RESISTANCE P O P 100M Ohms 500VDC 25 C 70 RH SAFETY amp EMC EMC EMISSION Compliance with EN55011 EN55022 cispr22 EN61204 3 Class B EN61000 3 2 3 EMC IMMUNITY Compliance with EN61000
18. the Cancel command code 100 to cancel it When reading the status register command afterwards the cancel command has been sent we can have two different answers 1 Cancel code function and status 2 error Indicates there is no executing pending function 2 Function codes 1 2 or 7 and status 8 cancel command Indicates corresponding function has been canceled Reading the status register 41004 we can tell if the command has been successfully executed The read data format is as follows 6 7 Communications Status register reading 16 bits High byte 8 bits Low byte 8 bits Executing command code Status according to table 6 5 7 2 Value Command execution 1 Correct 2 Error during execution 4 Execution pending 8 Cancelled command through executing cancel command code 100 Table 6 5 7 3 Command 3 Prefixed Tare needs a previous writing in data register 41002 and 41003 Is a 32 bits value this value should be within the scales capacity and should be compatible with the scale division If these conditions are not accomplished an error will be shown during the command execution Command 32 save in NVM saves the data in a nonvolatile memory If this command is not sent data will be lost when restarting the device The writing in a nonvolatile memory is a slow process during this time the device answer with the error SERVER DEVICE BUSY 6 5 8 Numerical data format Registers in MODBU
19. 0 C to 50 C Storage temperature 25 C to 60 C Size 146 5 x 76 x 35 mm Weight 0 3 kg Mounting DIN Rail mounting Ingress protection ratio IP40 1 1 Operation 1 2 Key board The keyboard is located on the front of the instrument and has 5 keys These keys have simultaneous detection of pressing in more than one key Keys Normal status Setup mode Exit any operation Up a level exit configuration mode Acquire a Zero Move to the left Cursor change option Es Tare the scale Move to the right Cursor change option F Setpoints programming Increase the digit Cursor Print Selection Down a level Confirm 1 3 Display and Luminous Information The indicator consists of a main display four luminous weight indicators and 6 digital input output indicator status lights The arrangement can be seen in figure 1 3 1 n d EE in Di Weighing LED Main Display wt gt 04 NET MM PT EN EE area Digital Input and Output Leds LOAD CELL RS 232 RS 485 DIGITAL OUT OWER ANALOG OUT et a ar O a 1 ER 7 MEE O N o Slo E 1 9 9 u of EE sm a gt 5 b Som EE o a SRSSSR SES SS I 33822 2 8 234 8223 Figure 1 3 1 Display and luminous information 1 3 1 Weighing function LEDs Indicator Meaning h Scale is in standstill mode 0 Zero NET Tare PT Prefixed tare Operation 1 4 L
20. 000 Measurement rate 2 400 measurements per second Linearity error lt 0 01 of measurement level Zero stability 150 nV C max Span stability 3 5 ppm C max Excitation voltage 5 0 0 5 VDC Transducer maximum resistance 1 000 kQ Transducer minimum resistance 58Q 6 cells of 3500 12 cells of 700Q Wire length 400 m mm max 6 wires 30 m mm max 4 wires 1 1 2 Operator Interface Own protocols Modbus RTU and ASCIl Main display 6 digit LED 10 mm Keyboard Keyboard with 5 keys 1 1 3 Serial Communications COM1 Bi directional RS 232 Dist up to 15m COM2 Half duplex RS 485 Dist up to 1 200m and 32 devices Transmission rates 115200 57600 38400 19200 9600 and 4800 bauds 3 digital inputs Opto isolated with status LED Viow 0 8V Vinich 2 4V Vimax 30V Number of bits and parity 8 bits no parity 8 bits even parity an 8 bits oda parity 1 1 4 Input Output Options 3 digital outputs Relay outputs with status LED Normally Open N O Umax 30V AC 30V DC Imax 100mA Analog output Only SWIFT A version Galvanic insulation output 16 bits D A Voltage output 0 10 5V nom load gt 10kQ Current output 0 21mA loop resistance lt 500 Q 1 1 5 Power Power supply 10V to 28V DC Consumption 4W max 1 1 6 Environmental and Mechanical Operating temperature 2
21. 03 If for any reason the command cannot be executed the system will give an error message 6 5 6 Returned Error Codes When the device receives a MODBUS command correct address and checksum answers with the data requested or with a status operation indication When an error appears answers with the following standard codes Error Code Possible causes ILLEGAL 1 Received function do not recognized by the device FUNCTION Wrong received format command No registers in this address Intent to write in only read register x a 2 Intent to write in register only accessible in REMOTE ADDRESS mode Guts Intent to partial one register write in a 32 bits two registers variable Wrong written value in a variable ED Example out of range not compatible with scale BE 3 division etc Written command do not recognized in command register see 6 5 5 SERVER Error when saving in NVM nonvolatile memory DEVICE 4 Intent to write in a digital output not configured as FAILURE remote mode PC_ Ctrl SERVER Atthis moment the device cannot process the DEVICE 6 command BUSY Table 6 5 6 1 6 6 Communications 6 5 7 Using the command register Besides the reading and writing parameters and variables through the MODBUS registers the user can execute actions in the device through the command register We use the following registers
22. 1 2001 Level4 30A m Voltage dip interruption EN61000 4 11 2004 295 dip 0 5 periods 30 dip 25 periods 295 interruptions 250 periods Keyed carrier immunit ENV50204 1995 Level3 10V m 900MHz Note The power supply is considered as a component that will be operated in combination with final equipment Since EMC performance will be affected by the complete installation the final equipment manufacturers must re qualify EMC Directive on the complete installation again For guidance on how to perform these EMC tests please refer to TDF Technical Documentation File This Declaration is effective from serial number EB2xxxxxxx Person responsible for marking this declaration Mean Well Enterprises Co Ltd Manufacturer Name No 28 Wuquan 3rd Rd Wugu Dist New Taipei City 248 Taiwan R O C Manufacturer Address Johnny Huang Senior Verification Engineer Ted Cheng Product Manager Name Position j Name Position Signature Taiwan Dec 20 2012 Place Date Version 2 U 004 JO SI18D POT ZL 40 U OGE JO SIOD peo1 Y WNWIKEN EN 9 1 Appendix Installation in protected area Installation in protected area 9 Appendix VIYV SNOGHYVZVH VJIyYV 33VS am Bis I i N he pee N KOEI preus pl us m weis O A l 7 poy BiS4 l I 1 peis l BiS P BiS smo H L96Z ES CN Bis Si i BET 8 Bis gt
23. ATE aLLcREE L eek ee ek seek be Rek Geek Gee Rek eek ee 3 12 3 5 6 TERMINATION EEr RE EN OS ee Ee Nate alts tek Vaso 3 12 3 6 Analog OUIBUL ss EE ES uu idee sie 3 12 36 TYPE EIFE ES ORE EE ee ee 3 13 3 62 OUTPUT BEE FEE oe EE ee ee se 3 13 36 8 ERROR EA ni ita 3 13 2 64 MIN Fee Diese oe iama to IS OE en 3 13 363 PUL BEE ES oe ee n tat a ak Var ce a Ama le athe ara 3 13 36 6 TW MIN fobt ED one ee ee ee Ee ee ee u 3 13 2 6 A EF os De ten Satins rennen 3 13 3 7 Digital Outputs u uu titi ce ER BEE GR Ke De ge ee 3 14 37 11 OU ENG dale EE ea 3 14 Tv SED EME ese ee ee GE Treat Se sayay AE 3 14 9 79 PER EIE DE O Na Ee an Te 3 15 ABEL GEE EE ed IE AS AA ORT ae 3 15 375 BIBI EK GE a ee Be he ee naa 3 15 3 26 BAND BA ME RE SR ER Net en an 3 16 3 7 7 HYSTERESIS i HJ ED Ge Ge oe ee ge ee 3 16 O78 LOCKED IE Eo EE DE ae 3 16 3 139 THORENS HO ye SE EE ee kah ee ee Ee EE et 3 16 A A GE a YT 3 16 8 Digital od EA ee ds 3 17 3 8 1 D_INNUM cos ER Re Eee en ES WERE UTE GR 3 17 982 S TPE e a 27 ee SE PE wen a AE EA iS 3 17 3 83 FUNCTION i DEE tt bes ste Ge GE De Re 3 17 3 8 4 Examples of appliGaliGR ies EL AE Ee De SE De kayanka rd 3 17 Ealibratien is ES EI Ge De DR EE RE a EG De we RE Ee ees 4 1 4 1 Calibration with masses LAL N ass a io 4 1 ERA ZERO Eros 4 1 4 1 2 SPAN 5PAn UR 4 1 411 3 STS PANG Se aaa s aa ta ed 4 2 4 1 4 LIN LIN CyLIN_ It Er E Med ee 4 2 42 Numerical Calibration CAL less sha RA ee e
24. Address Hexa Decimal Command Command Address Register Length Words Description Format Read Data Net weight H Net weight L Gross weight H Gross weight L Tare H Tare L Weight status See table A A D converter internal counts H A D converter internal counts L mV V Integer m mV V status Byte See table B Analog output status Integer See table C Instrument On line Byte Digit display 1 Byte See table D Digit display 2 Byte See table D Digit display 3 Byte See table D Digit display 4 Byte See table D Digit display 5 Byte See table D Digit display 6 Byte See table D 28 Display Led status Integer See table E 29 Software version AB Integer Software version 30 Software version CD Integer ABCDEFGH 31 Software version EF Integer ASCII code of every Integer character Software version GH Example 1 00204 H digit always is Ox00 Long Serial N 0000000 9999999 18 19 20 21 22 23 24 25 26 27 ojojojojojojojojojojojojojo l l sll ll lel slel le ls lt 32 33 Indicator serial number H Indicator serial number L Table 6 5 10 2 1 1 The mV V is indicated in absolute value without sign In the status register reg 300020 the polarity is indicated If the absolute value exceeds 65535 the Overflow bit of the status
25. CHP Yus ga katu a usu RD DS ER Np Sere Ed ee ances 3 3 37228 BEELD SES amta n EDS DS huy Me y EE EE a 3 4 9 238 DEE ES DE EE ED EE Se ek od SONY ee Core 3 4 3 24 ZERO TRACK DEERE en al aaa 3 4 3 2 5 ZERO RANGE 0 sa EE EA EE EEE 3 4 3 26 AUTO ZERO nl Cad ata 3 4 3 27 Minimum Range Limit UNIEN ek ana ota SE A aa aus 3 4 23 IN Ti HIERIE ss ath OE haah ED pap ea 3 4 9 3 ee ei EE OR aa y N EE ER 3 5 3310 ELTERMETIEER AE ee E GR En ae a 3 6 3 3 2 BAND find ns 3 7 3 3 3 PERIOD PEr lod il EP TT idea E 3 7 3 3 4 TARE LOCK Ena chaste delet RE re Mea oa ee de cla ER 3 7 3 35 LANGUAGE da N 3 7 3 3 6 KEYLOCK Hab ya ee ER 3 8 3 3 7 VPBINEMINIMUMIFFEj seen end 3 8 3 3 8 TICKET Pret i E E ES EER E ER EE 3 8 3 3 9 TICKET ID Ah REED SE DR DENS RR lt 3 8 3 4 Communication port BS 485522 us aza RE N N EE Ee ee 3 9 3 4 1 MODE ESF Ee ee A AS EG ee aie ater 3 9 3 4 2 PORT F ee leere 3 9 34 32 BAD A De ete ie nn ne ee 3 10 34 4 BARE N a eR er Se ra de a de a ee Sete eee 3 10 34 5 TRANSMISSION RATE OU CRE ee ee ee ee ee ee ee ee ee ee 3 10 SWIFT User s Manual 4 5 3 4 6 TERMINATION EEr es aaa 3 10 347 PROTOGOL Pro a A O AO 3 10 34 8 ADD ne aa EE RR EE N an 3 10 3 4 9 Ed Eed ER RE RE EE OE EO 3 10 3 5 communication por A EE SEE SIEBERT 3 11 351 MODO C EE Vere an dd ed Peed cud 3 11 3 5 2 EEN Ee Ee A EE Ee WE N 3 11 35 3 BAUD GEREP os o CU a atl sie 3 11 85 4 PARA PPF se mu N N ee e e T E 3 12 3 5 5 TRANSMISSION R
26. ET PT NET PT hd NET PT 04 NET PT OS NET PT Oe NET PT h 4 04 NET PT md NET PT INDICATION SNR EXAMPLE SNR 1234567 Figure 2 1 1 Switch on sequence It is recommended that the instrument is allowed to warm up and stabilize for a period of 30 minutes before using it especially before a calibration In order to avoid warm up time and potential condensation in case of significant changes in the outside temperature the device can be left permanently connected 2 2 Entering Values To use some of the equipment functions it is necessary to enter numerical values Use the arrow keys to enter these values Use right Es and left and the up Q arrow keys to increase its value arrow keys to select the digit to be modified 2 1 Operation 2 3 Normal Weighing The measured weight is displayed 2 4 Zero The indicator has a manual zero ing function When you press the Zero key the indicator stores the current weight value as the zero of the system This key acts according to how the 0 top has been defined see 3 2 5 Operation It is possible to lock the zeroing key see 3 3 6 2 5 Tare 2 5 1 Activate tare Press the Tare key The current value will be stored as tare The NET led lights up Operation It is possible to lock the tare key see 3 3 6 2 5 2 Clearing a Tare Value To clear a tare register in normal operation that is to sa
27. M These are the options 1 Fe F3 F4 5 F6 F 1 FB F3 F D 3 9 Configuration 3 4 3 BAUD bAUd Transmission speed These are the options 4800 9600 19000 38400 57609 115200 3 4 4 PARITY Pfr Number of data bits and parity These are the options NONE 8 bits data no parity ELEn 8 bits data 1 bit even parity even odd 8 bits data 1 bit odd parity odd 3 4 5 TRANSMISSION RATE oU rAtE Inthe STREAM mode is the number of transmissions per second Possible options are 1 5 10 25 98 15 150 300 600 It should be noted that the format and the baud rate may limit the actual shipping 34 6 TERMINATION EE Termination of the data for DEMAND and STREAM These are the options L cd lt CR gt lt LF gt lt CR gt EL lt ETX gt none nothing 3 4 7 PROTOCOL Prot Protocol communication port Possible values non No protocol Fe Own RS 485 protocol 3 4 8 ADD Add It is the address of the equipment in a RS 485 network We can connect up to 32 devices in the bus Possible address values are 01 99 When having some devices connected to the same bus they should have different addresses 3 4 9 RTer CEEr Is the termination resistor for RS 485 bus Possible values are arr on We must have this option Om when the device is connected to the beginning or end of the 485 bus We have connected this resistor at each end of the bus 3 10 Configuration 3 5 Communication
28. No data transmission DEMAND de Data transmission on external request through the serial port STREAM S Continuous data transmission TIQUET E 3 Print out ticket 3 5 2 FORMAT For Format of the transmitted data for DEMAND and STREAM These are the options F i Fo F3 FH F5 F6 F1 FB F3 F F IF i F 13 see 6 2 2 3 5 3 BAUD bAUd Transmission speed These are the options 4808 9600 19000 3 09 LIN AMEN I IC rr 400 5 1600 1 i520 3 11 Configuration 3 5 4 PARITY PAr Number of data bits and parity These are the options NONE 8 bits data no parity EUEn 8 bits data 1 bit even parity even odo 8 bits data 1 bit odd parity odd 3 5 5 TRANSMISSION RATE oU ALE In the STREAM mode is the number of transmissions per second Possible options are I in Ic cn ann cnn La 5 i 5 50 IS 150 ALL OL It should be noted that the format and the baudrate may limit the actual shipping 3 5 6 TERMINATION EEr Termination of the data for DEMAND and STREAM These are the options trier lt CR gt lt LF gt Lr lt CR gt Et _ lt ETX gt none nothing 3 6 Analog Output EE to access to this menu with a device without analog output will show in the screen a 7 Analog output configuration level parameters showed in Figure 3 6 1 can be found Once we have introduced the Id_ 2802 of the device optional if we want to modify protected parameters we are inside the configuration menu
29. Related function decimal code function READ DISCRETE INPUTS 02 Table 6 5 10 2 6 FK Address Hexa Address Decimal Description Comment egister Command Command 10001 0000 0 Digital input 1 Status digital input 1 10002 0001 1 Digital input 2 Status digital input 2 10003 0002 2 Digital input 3 Status digital input 3 6 5 10 4 Coils Read write registers to consult modify the status of the three digital outputs A digital output only can be modified from MODBUS if it is configured parameter Type as remote mode PC_CTRL Related functions decimal code function READ COILS 01 WRITE SINGLE COIL 05 WRITE MULTIPLE COIL 15 Table 6 5 10 3 1 Ba dy 053 gay ee Description E2PROM Comment 00001 0000 0 Digital output 1 NO Read write digital output 1 00002 0001 1 Digital output 2 NO Read write digital output 2 00003 0002 2 Digital output 3 NO Read write digital output 3 6 16 Table 6 5 10 4 1 Communications 6 5 11 Binary mode on digital outputs Operating in binary mode the three relays work together as a binary output of 3 bits to show 8 different levels controlled by net weight These levels are controlled by 7 setpoints that can only be programmed and consulted through MODBUS These setpoints are independent of the three setpoints VL 1 VL 2 and VL 3 of D_OUT configuration This mode can be activated or disabled by a register Binary mode st
30. S protocol has 16 bits size To transmit the three basic numerical variables we use the following format Byte variables 8 bits 16 bits Register MSB Most significant byte LSB Low significant byte 0x00 Valor de la variable 8 bits Table 6 5 8 1 Integer variables 16 bits 16 bits Register MSB Most significant byte LSB Low significant byte Variable MSB Variable LSB Table 6 5 8 2 Long variables 32 bits We use two registers Assuming that we define the variable as four bytes numbered from 1 to 4 with 1 being the least significant would have the following format First register 16 bits MSB Most significant byte LSB Low significant byte 4th Byte of the variable 3rd Byte of the variable Table 6 5 8 3 Second register 16 bits MSB Most significant byte LSB Low significant byte 2nd Bite of the variable 1st Bite of the variable Table 6 5 8 4 6 5 9 MODBUS address conversion Data register tables have their addresses in standard Modbus format To convert this address into the necessary message for the Modbus format these operations should be done 6 8 Communications If the address of the table is lower than 1000 then you have to subtract 1 to send it to the device Example Digital output 1 access is through COIL 1 its address is 00001 The message should send the address 0 If the address is higher than 1000 and has the f
31. SWIFT WEIGHING INDICATOR AND HIGH SPEED TRANSMITTER OPERATION AND CONFIGURATION MANUAL SWIFT User s Manual Revision For software versions SWIFT CALIBRATION RECORD Record the calibration settings in the following table Serial Number March 2014 English 1 000X Model Operating Voltage 12 24 VDC Purchase Date Installation Date Calibration Coefficients ZERO SPAN Access Code ID 2802 WARNING Keep this number in a safe place This will be the only one that will let you access the protected parameters scale definition calibration and others SWIFT User s Manual SAFETY PRECAUTIONS WARNING SHOCK HAZARD Due to the risk of electrical shock this instrument must be installed WARNING SHOCK HAZARD For proper earthing the safety earth wire green or green yellow must be connected to the general earth wire N only by qualified personnel WARNING SHOCK HAZARD Signals connected to the communications modules RS 232 y RS 485 should be provided by a power supply with IT very low security levels CAUTION The integrated circuits in the SWIFT are sensitive to electrostatic discharge ESD Be sure to follow proper procedures for transporting storing and handling ESD sensitive components CAUTION Reference should be made to the enclosure in which the SWIFT is going to be mounted Degree of mechanical protection agai
32. The message Elri jel will appear if we set a higher value than the capacity of the scale or an incompatible value due to the scale division Exit When parameter d_LoL Z is an then the message Lal locked will be shown and will blink three times this parameter cannot be modified from this menu To lock the setpoint o see 3 3 6 2 3 Configuration 3 Configuration 3 1 Introduction Inside the configuration menu and the calibration menu we can find different types of parameters a Free access they can always be read and modified b Protected they can always be read but only modified under certain conditions There are two types of parameters Metrological parameters These parameters affect directly the calibration counter in the schemes are accompanied by the symbol To be able to modify these parameters it is necessary to set the correct PIN number and the calibration switch see figure 3 1 1 should be in the unlock position when getting into the configuration menu None metrological parameters These parameters do not affect to the calibration counter in the schemes are accompanied by the symbol To be able to modify these parameters it is only necessary to set the correct PIN number independently of the calibration switch position The calibration counter is shown on the display when turning on the indicator To prevent access to the protected parameters there is a switch located in the left
33. abel with characteristics and metrological identification It is located on the rear side of the indicator as shown in figure 1 4 1 It is a safety label which contains the characteristics of the device and metrological values and marks Figure 1 4 1 Label with characteristics and metrological identification layout Operation 1 5 Error Messages Main Display Condition Solution Erre 0 Scale is not empty Remove the weight Elric EEPROM failure Contact your technical service Err le Incorrect entered value Enter a value inside the range i Check that the selected working Eri 3 The pion me Syng 1a oe not mode and the configuration of the available with the current configuration device allow access to this option Eric cier No signal from the load cell i CO ANA deel Err 99 Reset caused by software supervisor ie nn are ACES ADC error o connector and load cell Rar rn ADC failure Contact your technical service Ao uE FR Analog output failure Contact your technical service EE Weight exceeds the maximum capacity Remove weight Enter signal exceeds the maximum range Check installation MAER IE Enter signal under the minimum range Check installation El III Weight on the scale under the minimum Place a weight above the minimum
34. access parameters LIN POINT LIN COR LIN_C Applied load known value of the mass chosen for the correction LIN Indication of the applied load These parameters allow the correction of a possible non linearity in the system This adjustment is performed in the point you choose from 0 to MAX After adjusting the scale zero and span if a linearity error is detected due to a discrepancy between the load and the system indication choose a point where discrepancy is more significant and then adjust linearity The linearity error disappears at that point and is fundamentally reduced in the rest of points see figure 4 1 4 1 INDICATION LINEARIZATION ERROR THEORETICAL STRAIGH men WEIGHT INDICATION MAX LINEARIZATION ERROR REAL FUNCTION vi WEIGHT INDICATION THEORETICAL STRAIGI LIN WEIGHT INDICATION REAL FUNCTION WEIGHT INDICATION LIN C LIN_C LIN_I 6 UNC MAX WEIGHT WEIGHT 0 LIN_C MAX Figure 4 1 4 1 Behavior linearity adjustment before and after respectively 4 2 Calibration This is the procedure 1 Select the Reset option in the LIN parameter in order to assess the system linearity without any pre existing correction The LIN parameter is deactivated and any previous correction is deleted 2 Place a known load in a point of the range where there is a significant linearity error Note down the indication value 3 Select ON in the LIN parameter and then you gain access to LIN_C and LIN
35. atus only accessible through MODBUS These registers are reinitialized to zero every time the device is powered on the value of the registers are not saved in E2PROM memory When the binary mode is activated the D_OUT configuration is disabled and the outputs trigger according to net weight and the binary setpoints configuration VLB 1 VLB 7 programmed in registries 41151 to 41164 on MODBUS as the following figure shows ia ETE MIE IN TE EER HERE ES L i Z T ibu s AECA Ml Q u EE DEE DE EE ED AA E SPS wh ZZ mz EN AS AA NEE EE EE MA MEEL EE N ENE WL EER HEES NOR EE AA AA NI ENE ET OIE NE AE ARE AN m BESEER Ze Z gt SE ERK AAA OAR ME NOS HA VLB4 NET weight ON ME ON of r DO2 OFF ON DO3 OFF Figure 6 5 11 1 Response of digital outputs in binary mode VLB1 VLB7 are the values of net weight programmed as the 7 binary setpoints MODBUS 41151 to 41164 registers and must contain valid values in ascending order it means VLB2 must to be higher than VLB1 and VLB3 must to be higher than VBL2 etc Digital outputs trigger according to the binary Gray code configuration 000 001 011 010 110 111 101 100 This configuration allows changing only one relay between one output and the next output The table 6 5 10 1 1 shows the 8 Holding Registers to control the relays in binary mode Gray code None of these registers are saved on E2PROM memory Restarting the device sets to ze
36. ce a certified test weight on the scale and press Enter The maximum scale value is displayed if the weight placed on the scale is different key in the real value Press the Enter key and CALIB is displayed while the unit calculates the span coefficient After accepting it it is stored It is recommended to keep this coefficient value or print it by means of printing the parameters see 5 1 3 4 1 Calibration Manual span adjustment this coefficient is an internal software value that corresponds to the calibration coefficient gain value of the scale To introduce manually the span value F key has to be pressed Then we select the corresponding digit with the Arrow Left and Arrow Right keys The selected digit value is modified with Arrow Up key A If a negative value has to be introduced it can only be done with the first left digit The negative sign appears after the 3 number ATTENTION The zero and span coefficients value is obtained by means of the impression of the parameters see 5 1 3 4 1 3 TW SPAN FSPAn Span fine adjustment Use the right left arrow keys to adjust this value Press Enter to store the value 4 1 4 LIN LIN_C y LIN_I L Int In_EL in To activate the linearity adjustment function These are the options OFF Linearity adjustment deactivated ON Linearity adjustment activated RESET Linearity adjustment deactivated and linearity adjustment parameters cleaning In On position you
37. display will show Z ja Els the error f IE 3 7 10 DELAY i dELAY Is the option to program a delay in seconds to activate the digital output If during this configured time the activation condition disappears the output will not activate Possible values 0 0 20 0 s If the programmed time is higher than 20 0 s the display will show m Ds the error MI IE 3 16 Configuration 3 8 Digital Inputs Within the Digital inputs configuration level parameters showed in figure 3 8 1 can be found Once we have introduced the ld 2802 of the device optional if we want to modify the protected parameters we are inside the configuration menu being the first configuration screen and from there we can move along the configuration menu EFi Sr Nr Se N Dita N 7 N bana Nr Nr N Scale Def y Options H Serial RS 485 H Serial RS 232 K Analog Digital _f Digital inputs ete aunty Cal mV H Tools H Test C ae Pe PEN IN Output AN Outputs FEN with masses A N EN P Digital Inputs din d in N Type i FUNCTION i un fi EE lt Y y 11213 SFFIER EICER E Eco Pr lat al RE Pan Figure 3 8 1 Digital inputs 3 8 1 D_IN NUM d in no Digital i
38. divisions 3 3 3 PERIOD PEr lod Inside this menu we can find the necessary parameters that will help us to define the stability of the system To meet the stability condition we must fulfill that the weight does not exceed the defined band in a period of time Period of time in which we want the weight remains within the selected stability band Doe possible options are ju c 25 milliseconds 50 50 milliseconds IDO 100 milliseconds 150 150 milliseconds cun 200 milliseconds eso 250 milliseconds 500 500 milliseconds DON 1000 milliseconds 3 3 4 TARE LOCK tArELC It allows activating and deactivating the tare lock The possible options are an OFF If that option is on the tare is locked keeps the tare That is the equipment default option and under which the tare is activated until it is manually deactivated see 2 5 2 When that option is OFF the tare acts as follows if after removing the weight its value is within the range of Y divisions around zero then the eduipment automatically deactivates the tare 3 3 5 LANGUAGE LAN9 You can choose among different languages for the printed ticket The possible options are SPR Spanish Por Portuguese Fre French Eng English Ser German CPE Catalan 3 7 Configuration 3 3 6 KEY LOCK Lol lt locks the keyboard The parameter treatment is performed with a 5 digit binary number The value 1 locks the function and the value 0 releases it These are the options
39. er numerical value A lt lt Figure 3 3 1 Options 3 5 Configuration 3 3 1 FILTER F ILtEr Filter level You can choose different filter levels or deactivate this function The higher the selected value the higher the filter level These are the options OFF 2 4 6 8 10 id M 6 8 c0 22 d Next we show the equivalence table between the type of filter and its stabilization time settling time FILTER LEVEL SETTLING TIME 0 2 2 65 ms 4 67 ms 6 85 ms 8 85 ms 10 85 ms 12 125 ms 14 285 ms 16 600 ms 18 1305 ms 20 1568 ms 22 2200 ms 24 2732 ms SETTLING TIME Time taken for the device versus a change in the input signal In figure 3 3 1 1 we can see the ADC response against an input weight variation ADC Indicator Response Filter Response Weight kg Time ms Settling Time Figure 3 3 1 1 3 6 Configuration 3 3 2 BAND bAnd Inside this menu we can find the necessary parameters that will help us to define the stability of the system To meet the stability condition we must fulfill that the weight does not exceed the defined band in a period of time The level at which motion is detected Out of this level there is no stability OFF Deactivated function the device always shows stable weight D Sd Half division id One division co Two divisions 5d Five divisions d Ten
40. es addressing The access and distribution to the parameters and variables in MODBUS registers is as follows 1 The digital inputs reading are done by the command READ DISCRETE INPUTS See table Discrete inputs 6 5 10 3 1 2 The digital outputs state reading is done by the command READ COILS See table Coils 6 5 10 4 3 The digital outputs writing is done by the command WRITE SINGLE COIL or WRITE MULTIPLE COIL See table Coils 6 5 10 4 To be able to write in a digital output is necessary to be configured as remote control PC_Ctrl See paragraph 3 7 3 4 The only reading parameters or variables are read by the command READ INPUT REGISTER See table Input Registers 6 5 10 2 1 5 The reading writing parameters are read by the command READ HOLDING REGISTER and are written by the command WRITE SINGLE REGISTER and WRITE MULTIPLE REGISTER See table Holding Registers 6 5 10 1 1 When writing a 32 bits variable it is important to keep in mind that should be done by command WRITE MULTIPLE REGISTER because MODBUS single register has 16 bits 6 5 5 Command Register The command register holding register 41001 is used to execute functions in the device These functions can be tare safe parameters in NVM etc In table 6 5 7 2 there the available commands are listed The execution is performed by writing the correspondent code in this register The PREFIXED TARE function needs writing the first tare value in command data register addresses 41002 410
41. ght of the product In this case we can perform the adjustment of the system and deduce the dead load of the system according to procedure example of use 2 The accuracy of the dead load obtained depends on the accuracy of the net weight We should keep in mind when modifying this parameter we are modifying the zero of the system and consequently the internal calibration counter will increase If we modify the gain of the device SPHn the dead load of the system will be recalculated The same happens when doing a zero through ZERO option see 4 2 4 Example of use 1 Performs the zero adjustment of the system knowing its dead load 1 First of all we should define the weighing system through menu dEF see 3 2 2 Once the definition it is done we have to enter in menu LAL see 4 2 and set the capacity sensitivity and number of load cells 3 Next we have to set the Dead Load value of the structure dEAd_L see 4 2 4 4 Calibration Example of use 2 Performs the deduction of the Dead Load of the system knowing its net Weight of the product 1 2 3 First of all we should define the weighing system through menu dEF see 3 2 Once the definition it is done we have to enter in menu LAL c see 4 2 and set the Dead Load value to 0 Next we have to perform the numerical calibration of the gain We have to set the capacity sensitivity and number of load cells see 4 2 With menu Weight x10 H_rE5
42. he Remote Controller 6 2 1 Remote Controller Commands Operation Commands Query Set weight in F4 format Equivalent to EXIT TARE keys Query Set weight with response according to the selected format see 3 4 2 Equivalent to PRINT key Reset system Equivalent to TARE key Equivalent to ZERO key Equivalent to gt key Equivalent to EXIT gt keys Weight query set The command does not require lt CR gt STX ENQ ETX Weight query the command does not require lt CR gt SYN Weight query the command does not require lt CR gt PAMANADOVOA gt S SETPOINTS Programming Allows the VL i parameter from the i digital output to be changed see 3 7 2 The decimal point is taken from the system In case of TYPE i REL o REL VL i pppppp 100 Program S P i Lp Consult S P ii It returns the value in the programmed format Data transfer in ASCII format E Sign positive value negative value Digital output number 1 4 p Weight 7 digits REMOTE Mode It allows changing the i digital output provided that this is programmed TYPE i REM see 3 7 3 Act Xx Oli x Consult X IO 6 1 Communications Read digital inputs Answer X O RESIES Xs X4 X3 X X Data transfer in ASCII format i Digital output number 1 4 Xn Status of the digital output n 0
43. ight lt VL i L Low Trip when weight gt VL i in_b In Band Trip hen weight gt VL i BD i or weight lt VL i BD i out Out Band Trip when VL i BD i lt weight lt VL i BD i If the digital output is set in the PE Ctr mode of the EYFE i parameter see 3 7 3 when you turn on the equipment the output configuration is determined by this operation mode HIGH ON LOW OFF 3 15 Configuration HIGH FUNCTION LOW FUNCTION Set Point Hysteresis Hysteresis Set Point rT L gt AT OFF OFF Figure 3 7 5 1 Set point Actuation TRIP High and Low IN BAND FUNCTION OUT BAND FUNCTION Hysteresis Band Band Hysteresis _ Set Point Set Point Band Hysteresis Hysteresis Es ss Z 4 Band i ON ON i OFF L L Figure 3 7 5 2 Setpoint Actuation TRIP In Band and Out Band 3 7 6 BAND i bd A numerical value which determines the value of the IN_B and OUT_B selections of the TRIP parameter 3 7 7 HYSTERESIS i HY Determines the hysteresis value which prevents chattering of the digital output 3 7 8 LOCKED i d_LoL It blocks the modification of VL i value through the keyboard key see 2 7 3 7 9 HOLD i Hold Is the option to program the minimum activation time of the selected output Possible values 0 0 20 0 s If the programmed time is higher than 20 0 s the
44. l command code 100 Table 6 5 10 1 3 While executing a command the device returns an error code 0x06 SERVER DEVICE BUSY to any client command Table F Code identification for Baudrate parameter Code Baudrate 0 4800 9600 19200 38400 57600 Table 6 5 10 1 4 POND Table G Code identification for Ou Rate parameters Transmission rate Transmission Code tale 0 1 1 5 2 10 6 12 Communications 25 50 75 150 300 O N or CO Table 6 5 10 1 5 600 Table H Code identification for Termination parameters Code Termination 0 CRLF 1 CR 2 ETX 3 NONE Table 6 5 10 1 6 Table I Code identification for Type parameters in digital outputs Code Function 0 OFF 1 GROSS 2 NET 3 P_REL 4 N REL 5 P PREL 6 N PREL 7 ZERO 8 ZERO NET 9 SS 10 INRANG 11 NEG 12 TARE 13 PRINT 14 PC CTRL Table 6 5 10 1 7 Table J Code identification for TRIP parameters in digital outputs Code TRIP 0 HIGH 1 LOW 2 INBAND 3 OUTBAND Table 6 5 10 1 8 6 13 Communications 6 5 10 2 Input Registers Read only registers to consult weight data or specific device data Related function decimal code function READ INPUT REGISTER 04 Address
45. nc 2 Digital Input 3 OFF 0 1 TARE 2 CLR TARE 3 ZERO 4 PRINT 0 LOW 1 HIGH Type 3 Func 3 Binary Mode Outputs 1 N Binary mode status 0 OFF 1 ON 12 Setpoint 1 BINOUT H CAP CAP 1 Setpoint 1 BINOUT L Setpoint 2 BINOUT H CAP CAP 1 Setpoint 2 BINOUT L Setpoint 3 BINOUT H CAP CAP 1 Setpoint 3 BINOUT L Setpoint 4 BINOUT H CAP CAP 1 Setpoint 4 BINOUT L Setpoint 5 BINOUT H Setpoint 5 BINOUT CAP CAP 1 Setpoint 6 BINOUT CAP CAP 1 Setpoint 7 BINOUT CAP CAP 1 L H Setpoint 6 BINOUT L H L Setpoint 7 BINOUT Table 6 5 10 1 1 1 Table K commands are executed writing the value in this register Read this registers returns the operation status same as register 41004 2 This value should be multiple to the digital division The decimal point does not take into account CAP is the scale capacity This value cannot be lower than 99999 display capacity Refers to the 4 possible values HIGH LOW INBAND OUTBAND These values are directly saved in E2PROM without sending command through the command register In the column are indicated if the register is saved in E2PROM The register is saved after written Refers to the 13 possible values 0 12 that correspond to F1 to F13 formats respectively Refers to the 7 possible baud rate values 4800 9600
46. nput number These are the options LE 3 8 2 TYPE i EYPE Input action These are the options OFF arr Deactivated TARE ERCE Tare CLRTARE CERFE Deactivate tare ZERO Utero Zero PRINT Pr int Print 3 8 3 FUNCTION i FUnD Input action mode These are the possible options LOW From HIGH to LOW Falling edge HIGH From LOW to HIGH Rising edge 3 8 4 Examples of application PUSH BUTTON LOGICAL RELAY V Vext 5 24VDC ORN 5 24VDC IN IN aa Figure 3 8 3 1 Examples of application 3 17 Calibration 4 Calibration 4 1 Calibration with masses LAL Within the Calibration with masses LAL configuration level parameters showed in Figure 4 1 1 can be found Once we have introduced the Id_2802 of the device optional if we want to modify the protected parameters we are inside the configuration menu being the first configuration screen the next from here we can move along the configuration menu f N N a N Digital N N ibration N s P gt Scale Det H Options Y serial RS 485 H Serial Rs 232 H SEN H Digital Inputs H Kae H Calmv H Toos H Test As IN IN of UP XS ups of A A AGUA masses IX N J Cal with masses CAL Ten un DO 10 a Y ADC value Enter numerical p
47. nst impact according to EN62262 indoor use IK05 IK08 for outdoor use CAUTION Calibration and configuration must be performed only by qualified personnel SWIFT User s Manual 1 Introduction el 1 1 1 1 Indicator Gharaeterisli s u u uuu uuu ee 1 1 LAT Load Gell COMME GION ssa neuen 1 1 11 2 Operator intentada naeh 1 1 1 1 3 Serial Communications EE eek 1 1 1 1 4 Input Output Options ee ee n ee ee ie 1 1 Wedd POWER EE O ee ee ee Assess aah coed atu Aan ali 1 1 1 1 6 Environmental and Mechanical ecos malta ea 1 1 12 ole ie RE RE N AE EI OR EE N 1 2 1 3 Display and Luminous Information 1 2 1 3 1 Weighing function LEDs anne en 1 2 1 4 Label with characteristics and metrological identification 1 3 1 5 Error Messages EO EN EE AE EE EE N ER ss usss 1 4 1 6 Mamieranee Eu 1 4 1 6 Cleaning an een 1 4 2 Opefallon an uu a saa ee nana 2 1 2 1 Turning the indicator on eek 2 1 2 27 Entering WANS oe u a aden L U etek deg ee ee ie ee pate totes awayu 2 1 2 3 Normal A 2 2 Ni RE AL EE AE EE EE OE N N 2 2 29 EE RE OR ae Geen culled N EER EE EE 2 2 2 5 1 Activate tale nase ae sk Hs 2 2 2 5 2 Clearing a Tare Value se EG EE RE N Ge ERG Ge Err rue anne es ee 2 2 2 6 O 2 2 2 7 SOON ee ee HE NE EE ER ee 2 3 3 COUNT 9UralloN gis u a aS ee ee 3 1 3 1 T N ige ed eie AE N 3 1 32 O di EE EE N AA OE EE N 3 3 ED MA
48. nt 4 3 WD A A AR 4 3 42 2 ENUM Eie EE oa Serre EE EE asina RE ee 4 3 AA MEE ROM ME E EE ee asa 4 4 4244 GEBORE SS Ee AE A a taste 4 4 42 5 Dead load EFL A a ace 4 4 Tools amp test is usu Qatun kaa daa een GER rede DE 5 1 A SERE EE N umu EE DE GE ED SE Ge Ge Pasa Ee ee ee 5 1 5 1 1 met 3 ES AE ota Nee sees th as satu ER hi sta u et 5 1 52 mV Metro 5 IA ot ccs EE ee AR Se ee trains be die 5 1 Bas Pi al PER Ds eo EE DER ee 5 1 5 14 Par a Ar ESL Me eed cle Seles p pa Oana EE n k 5 1 515 SW Update PAE rts cc cde cased een nern ee 5 1 54 6 Remote Calibration Feine 5 2 Be ESE wa aa ayay ED IE OE ER ER aio 5 2 SWIFT User s Manual 5 2 1 Digital outputs crete ansehen 5 2 5 22 Digital inputs E O iN ee IE tate tad 5 2 52 3 RS 262 ES DOE a a RE a ale ck aaa ee Hase 5 2 Dele A RS 485 5 499 ic ee epee EE A 5 2 5 25 Analog output Spee te ete ale ea Mes ke 5 2 6 Communications 6 1 6 1 Communication general characteristics AR AA ee 6 1 6 2 General Characteristics of the Remote Controller 6 1 6 2 1 Remote Controller Commands ese RA RA AA AE ee AA ee ee ee 6 1 622 Dala Formal ER N EE OG SE N eg TA Re ESE ENE ee 6 2 6 3 Protocol RS 292 u a u Ee DE ete EG lida EE DE ED Ge B 6 4 6 4 Network Communications RS 485
49. nu it is necessary following these steps ENTER INSIDE THE CONFIGURATION MENU Press and hold key amp while pressing key O Id 0000 The indicator will show the Id menu To select the digit use left right keys To change the value of the digit use up key Id2802 Once the id 2802 is introduced press key O to accept Figure 3 1 3 Enter in the configuration menu Once we have introduced the Id_2802 of the device optional we are inside the configuration menu being the first configuration screen and from there we can move along the configuration menu S Ber N Gallbrallon N Y Nr ia i Scale Def Options H Serial Rs 485 Serial Asa H Analog Digital H Dig Inputs Y Calibration Cal mV JH Tools Test E IN No JA Output Xe Outputs PEN e N with masses DES Y 2 Enter 2 key validates the selection If we ignore to enter the Id press enter key with 0000 indication or we input a wrong number we will get access to the menu but we will not be able to change protected parameters marked with a P The factory access code can be found on page 1 and cannot be modified Once entered in the calibration configuration menu the display will show us the position where we are To move through the menus use the cursors To move in the same level with left Se lt and 4 E right cursor gt gt to change the level use enter 2 andexit keys Once the
50. ollowing format 1xxxx 3xxxx or 4xxxx we have to delete the first digit and the remaining number should be subtract 1 This is the value to send Example To access to Command register 41001 we have to send 1000 address in decimal 03E8 hexadecimal 6 5 10 Registers address tables In these tables are indicated the addresses and the content of all the available registers In the first column you can find the address register and in the second and third column are the address converted to the required MODBUS command format in hexadecimal and in decimal 6 5 10 1 Holding Registers These are read write registers used to modify or consult parameters of the device You can also execute functions through the command register Related function decimal code function READ HOLDING REGISTER 03 WRITE SINGLE REGISTER 06 WRITE MULTIPLE REGISTER 16 Address Register Address Hexa Command Address Decimal Command Description Command Register Format Integer Values Range Comments See table K E2PROM 10 Command Data H Long See table K Command Data L See table K mn egies ETE 1 Integer Read only See table L H Setpoint 1 L Setpoint 2 L Setpoint 2 H L Setpoint 3 H Setpoint 3 L Temporal Setpoint 1 Temporal Setpoint 1 H L H L Temporal Setpoint 2 Temporal Setpoint 2 Temp
51. om there we can move along the configuration menu N Af Nr TR RE N lt scale Det H Options H Serial RS 485 H Serial RS 232 Analog Digital Y Digital Inputs Calibration Calmv H Tools A Test C JA we NT _ Output DES Outputs PES J with masses AN JM p Scale Def d E F y Cap Div Dp Zero Track FLIR P Hd gp O je fre RL 7 EIE EIE lt gt Enter numerical Y value 3 Man en 010 0 0 00 0 000 A 112151 0120150 ICU sr 105d ia cd 3d Hd 5d C ae lt TE Zero Range Auto Zero UnderL Units 0l lelolP gt 8 5 A c e UinldlElelt vla te lt _ gt 9 OO oUErt 200 FS9 E 3 Lb o none 160 160 160 160 Figure 3 2 1 3 2 1 MAX CAP Maximum capacity of the scale 3 3 Configuration 3 2 2 DIV d h Value of the scale division 32 3 DP dP Position of the decimal point By pressing the arrow keys you can move the decimal point to the de
52. oral Setpoint 3 H L Temporal Setpoint 3 pes 0 Off 1 AE 2 St 4 ASCII 5 RTU Format 0 12 9 Baudrate Parity 0 5 7 See table F 0 2 gt 0 None 1 Even 2 Odd Ou Rate 0 7 See table G Termination 0 3 See table H Protocol 0 None 1 RS485 Address 1 99 Bus termination Type 0 R Termination OFF 1 R Termination ON 0 3 gt 0 Off 1 dE 2 St 3 Ti Format 0 12 9 Baudrate Parity 0 5 7 See table F 0 2 gt 0 None 1 Even 2 Odd Delay 0 7 See table G Termination Type Byte 0 3 See table H 0 Gross 1 Net Communications Address Hexa Address Address Decimal Register E2PROM 10 Description Format Values Range Comments Command Command Output 0 4 20mA 1 0 20mA 2 0 5V 3 0 10V Error 0 FULL 1 HOLD 2 MIN 41063 426 1062 Aout 0 H Long 0 CAP Yes 41064 Aout 0 L Yes 41065 428 1064 Aout F H Long 0 CAP Y Yes 41066 Aout_F L Yes 41067 042A 1066 Aout F0 Integer 0 0xEFFF Yes 41068 042B 1067 Aout FF Integer 0 0xFFFF Yes VL1 Setpoint 1 H CAP CAP VL1 Setpoint 1 L Type 1 0 14 See table I Rel 1 0 2 0 Setpoint 1 1 Setpoint 2 2 Setpoint 3 Trip 1 0 3 Y See table J Band 1 H 0 CAP Band 1 L
53. parameter is a selected if you want to change it press enter key and set the desired value with increase key F 4 select the digit or chose an option with lt gt keys To accept the selection press enter key Exit from menu press exit key It is recommended to print the calibration parameters once the system is configured using P_cal function in submenu options see 5 1 3 Entering values and scrolling through the display digits should be performed as follows for coefficients over 6 digits always off 0 NET PT 4 value digits Position To enter Use lt gt keys to move through the digits Use 4 key to AS l Digit in position 1 only can be shifted to the left Z N hd L m NET I I I PT gt 3 2 Configuration NZ E a LI a I When pressing 4 moves the digit to the next ZX NZ wa Oo We vere ME JJ tt es EI OOTI The sign digit is the last position to the left No f JI possible to perform shifts to the left lt Z I 00 Change the sign or the digit value in P position m iI press A EN 3 2 Scale Definition Within the Scale Definition configuration level parameters showed in Figure 3 2 1 can be found Once we have introduced the Id_2802 of the device optional we are inside the configuration menu the first screen and fr
54. parameters 4 Key in the load value in the LIN_C parameter and press Enter to confirm 5 Key in the indication value in the LIN parameter and press Enter to confirm 6 The correction has been made 7 This procedure can be repeated without clearing the previous correction continue from point 2 This adjustment calculates an internal algorithm which will be applied whenever the LIN parameter is ON even if the indicator is redefined or recalibrated That is why it is important to deactivate it or delete it if its application is not important anymore However whenever a span adjustment is made SPAN parameter in the moment of validating the calculated coefficient a message notifies us that the LIN parameter is activated where appropriate 4 2 Numerical Calibration LAL I If there is no reference weight value it is possible to make a theoretical calibration using capacity and sensibility values mV V of the load cells used For a calibration of maximum precision you always have to use the calibration with masses Within the numerical calibration level parameters showed in Figure 4 2 1 can be found Once we have introduced the Id_2802 of the device optional if we to want modify the protected parameters we are inside the configuration menu being the first configuration screen the next from here we can move along the configuration menu j NG N Sr N digital N N S N N scale Det Options Serial RS 485 Serial RS 232 K Analog
55. port RS 232 Within the Communication port RS 232 level parameters showed in Figure 3 5 1 can be found Once we have introduced the ld 2802 of the device optional if we want to modify the protected parameters we are inside the configuration menu being the first configuration screen and from there we can move along the configuration menu Y SER RES g a p aa V Scale Def Y Options Serial RS 485 Serial RS 232 H Analog H Digital b Digital Inputs dd aa H Cal mV f Tools H Test C PAS Pas IN JN Output JA Outputs _ with masses DNS VES Serial RS 232 Type Format Baudrate LEPE Floir b Auld IE 4 oFF St Iti FFE FY FS FG FT E 800 S600 i 9208 x FRIFSIF OIF IF F 3 38400 51600 115000 lt Fe lt Parity Transmission Rate Termination PIAI au RAEE EEE 4 y x Y non EUEn odd S c5 59 ELF Cr El non A 15 150 300 600 n 4 el lt Figure 3 5 1 Communication port RS 232 3 5 1 MODO EYPE Transmission mode These are the options DEACTIVATED off
56. ption allows you check if the digital inputs are enabled 1 or not 0 5 2 3 RS 232 r5 030 This option allows you to test the RS 232 serial port Make an electronic bridge between Rx and Tx The display shows PASS if is successfully or FAR IL if not exceded 5 2 4 RS 485 r5 485 This option allows you to test the RS 485 serial port To pass this test leave the port without connecting strips The display shows FASS if is successfully or FR IL if not exceded 5 2 5 Analog output E_AoUE _ This option allows you to test the analog output It shows the value of zero cero and full scale FULL Esta opci n permite hacer un test de la salida anal gica Nos mostrar el valor del cero oer o y del fondo de escala FULL The kind of output will depend on how you have configured see 3 6 2 5 2 Communications 6 Communications The device has two serial communication ports One serial port RS 485 half duplex and a second port RS 232 The communication channel behavior is selected in paragraph 3 4 for RS 485 and in paragraph 3 5 for RS 232 6 1 Communication general characteristics The RS 232 port supports the communication formats shown in paragraph 6 2 The RS 485 port besides communication formats of paragraph 6 2 also supports net communication through simple format see 6 4 in MODBUS protocol ASCII or RTU The protocol selection is performed in paragraph 3 4 1 6 2 General Characteristics of t
57. register is activated and remains fixed in 65535 2 The high byte indicates the state and the low byte indicates the output Table A Status register Bit Description 0 Meaning 1 0 Weight Stable No Yes 1 Zero Indication No Yes 2 Tare Led Off On 3 Tare Led Preset Off On 4 Underload No Yes 5 Overload No Yes 6 Error Ref No Yes 7 ADC error No Yes Table 6 5 10 2 2 6 14 Communications Table 6 5 10 2 3 Table B Indication mV V status register Meani Bit Description 0 ae 1 0 Sign 1 Overflow No Yes 2 Error Ref No Yes 3 ADC error No Yes Overflow bit is activated when mV V value is higher than 65535 or lower than 65535 to indicate the read value is wrong Table C Analog output status High Byte Low Byte 0x00 4 20mA 0x00 No error 0x01 0 20mA 0x02 0 5V OxFF Analog output not available 0x03 0 10V Table 6 5 10 2 4 Table D Corresponding digit segments to bits jo ps ps pa ps CODO Table 6 5 10 2 5 6 15 Communications Table E Correspondence bits LED status Bit Indication PTare Net Zero Stable Out 1 Out 2 Out 3 In 1 In2 OO IO OI R O PO oO In3 6 5 10 3 Discrete Inputs Only read registers to consult the status of the three digital inputs
58. ro all the 7 binary setpoints and the 41150 register Binary mode status so digital outputs start working in the standard mode configured in the D_OUT menu Trying to access to digital output configuration or pressing E key while working in the binary E gt i ad ea w mode will show in the screen 11 J 6 17 Connections 7 Connections Shown below are the signal matching and connections marked on the front panel of the device LOAD CELL RS 232 RS 485 DIGITAL OUT DIGITALIN POWER ANALOG OUT Q Q o b o o 8 E 821255 og p papas ssbb seas 81 2 883 3 Figure 7 1 Connections matching 7 1 Load cell connection SIG SIGNAL UTILCELL Cell Wire SIG Colour Se IE SIG Red 3 SIG White Sense HG SENSE Blue Exc F SENSE Yellow EXC EXC Black SHIELD EXC Green SHIELD Shield Table 7 1 1 6 wire connection load cell In the case of using 4 wire connection cable a bridge between EXC to SENSE and EXC to SENSE should be made SIG SIGNAL UTILCELL Cell Wire SIG Colour ra SIG Red gt SIG White Sense 7 G SENSE bridge to EXC Exc IF SENSE bridge to EXC EXC EXC Black SHIELD EXC Green SHIELD Shield Table 7 1 2 4 wires connection load cell 7 2 Load cell sealing The sealing of the load cell connection should be done by using a transparent plastic plate that
59. sesses the present value Once accepted it will be stored It is recommended to keep this coefficient value or print it by means of printing the parameters see 5 1 3 Manual zero adjustment this coefficient is the internal value of the ADC and corresponds to the calibration zero value to introduce manually the zero value E key has to be pressed Then we select the corresponding digit with the Arrow Left and Arrow Right keys lt gt The selected digit value is modified with Arrow Up key 4 If a negative value has to be introduced it can only be done with the first left digit The negative sign appears after the 3 number ATTENTION The zero and span coefficients value is obtained by means of the impression of the parameters see 5 1 3 4 2 5 Dead load dEAd_L It is the dead load of the structure By changing this parameter changes the zero of the system This parameter can be used in scales where is not possible to empty the scale to perform the zero calibration of the system It can be used in the following cases In a weighing system where is not possible to empty it to perform the zero calibration but we know the dead load of the structure the zero calibration of the system can be done without being necessary empty the scale according to procedure example of use 1 Ina weighing system where is not possible to empty it to perform the zero calibration we do NOT know the dead load but we know the net wei
60. side of the indicator just above the load cell connector In the left position the switch allows protected parameters to be changed but in the right position the protected parameters cannot be changed Figure 3 1 1 Calibration switch detail Figure 3 1 2 shows the basic menu structure N g N Serial Serial Analog Digital E Calibration y i f a Scale Def Opti Digital Input p Cal mV Tool Test L Te N peons N RS 485 d RS 232 d Output EN Outputs u ae ie with masses 1 a EN ie J Test LESE E daUE Ed In S 232 S H85 E RoUE Tools Ut IL HES S MAL P_CRL P ESEt UPAREE CAL_PC Cal mv CAL e LEAP Loo LSn DEro dERG_L Calibration with masses CAL DEro SPAR FSPAN L init h EIL ht Digital Inputs d In dinno EYPE HIFU 1 Digital Outputs d aUE Ld oUEn UL 1 ESPE EL tee P ijbd THY Hd Lol Hatd dELRS J Analog Output A_oUE ESPE QUEPUE Error Rott 0 Rolt F Rott F Rolt FF Serial RS 232 5 23 ESPE For BRUG PR oU REE EEr Serial RS 485 5 485 ESPE For BAUD PA oU REE EEc Prot Add EE Options oft ton F LEE bAnd PEr fod EAE LO LAAS Lol PrE PrE E NE id Scale Def dEF ERP d i dP O ErAC O EoP O SEArE UndErt Un tt Figure 3 1 2 Basic menu structure 3 1 Configuration To enter inside the configuration me
61. sired position so the division of the scale would be in the same unit than the capacity of the scale 3 2 4 ZERO TRACK U tr AL The level at which the system is automatically zeroed as long as the weight is within the selected band and it is stable These are the options OFF Deactivated function D Sd 0 5 divisions ld 1 division cd 2 divisions Jd 3 divisions Hd 4 divisions 5d 5 divisions The indicator performs the zero tracking in the order of 0 5d seg 3 2 5 ZERO RANGE 0 toP The range within which the scale may be zeroed 0 key and zero track These are the options 19 Allows performing a zero if the weight value is lt 1 9 of the maximum capacity 00 Allows performing a zero for the 100 of the maximum capacity 3 2 6 AUTO ZERO 0 SERrE The indicator zeroes when it is turned on These are the options om Activated function off Deactivated function Recommendation Silos Tanks Hoppers Platforms ON OFF 3 2 7 Minimum Range Limit UndErL Selecting the point at which the computer indicates the input error signal below the minimum rangel l l l l lsls These are the options OLEFL Lower range egual to the maximum range changed sign 20d Lower range equal to 20 divisions 3 2 8 UNITS Un IE Weight unit of the scale These are the options Fa Kilogram LE Pound E Ton o Ounce 9 Gram none None 3 4 Configuration 3 3 Options Within
62. ss 55 INRANGE In An NEG nE9 TARE IN EAE Set point trips on the absolute set point value VL i plus the relative value REL i Set point trips on the absolute set point value VL i minus the relative value REL i Similar to REL REL except the set point trips on the absolute set point value plus a percentage of the relative value Similar to REL REL except the set point trips on the absolute set point value minus a percentage of the relative value The output trips if a zero is in the system The output trips if the net mode is activated and the display shows a zero The output trips if the scale is in the Standstill state The output trips if the weight value is within tMAX The output trips if the weight value is under zero The output trips if a tare is in the system PRINT Pr ink The output trips while printing PC_Ctr PL_C r Output controlled by the serial port 3 7 4 REL i rEL It defines the reference SETPOINT number on which REL or REL are applied It should be considered that the output number that we are defining must be higher than the reference number If this condition is not fulfilled the error message EL _Err will appear on the auxiliary display These are the options tod 3 7 5 TRIP i Er IP Configures the trip action for the digital outputs when it depends on the programmed weight value VL i See figures 3 7 5 1 y 3 7 5 2 These are the options H High Trip when we
63. t in case of system error These are the options FULL Salida MAX Hold Salida no se cambia Uero Salida MIN 3 6 4 MIN RoUE_D Minimum capacity for the analog output range 3 6 5 FULL Rolt _F Maximum capacity for the analog output range 3 6 6 TW MIN RoUE_FO Fine adjustment for the minimum analog output Modify the level pressing the arrow keys lt gt 3 6 7 TW FULL RoUt_FF Fine adjustment of the maximum analog output Modify the level pressing the arrow keys lt gt 3 13 Configuration 3 7 Digital Outputs Within the Digital outputs configuration level parameters showed in Figure 3 7 1 can be found Once we have introduced the ld 2802 of the device optional if we want to modify the protected parameters we are inside the configuration menu being the first configuration screen and from there we can move along the configuration menu a Ni f N Paas Af Ses Analog N Digital N y Calibration N f N S Scale Def H Options Sea acini aas asas Output 1 Outputs ET reus H with masses x Cal mV N Tools A Test IN Digital outputs
64. the Options configuration level parameters showed in Figure 3 3 1 can be found Once we have introduced the Id_2802 of the device optional we are inside the configuration menu being the first configuration screen and from there we can move along the configuration menu wa art Analog Digital N Calibration NS ic Scale Def sd Options semi He Sena RS 232 HO Output q e Hi Digital Inputs H with masses J Cal mV FR Tools H Test l Options o p E I on Filter Band Period Fa EAS PET Hold gt lt gt Y oFF 2 H 5181 le PRETE di eg e5 50 100 H 6 B en a eq 5d Da 152 209 250 cnn NON Es a eer OU lt 1 P P lt OP Tare lock Language Key lock Lt R c E L L L Aln 3 Loc Y SPR Por ErE En SEr CRE 00000 lt lt 4 P Print Minimum Ticket Ticket_ID Plre PlriEl IE E td _ gt y O Y enter numerical value OFF Si ent
65. the device will restart 5 2 Test Within the test level parameters showed in Figure 5 2 1 can be found Once we have introduced the Id_2802 of the device optional if we want modify protected parameters we are inside the configuration menu being the first configuration screen and from there we can move along the configuration menu Scale Def H Options OH Sora Rs 185 Sera rs232 H A H EE Digital nous H Ea a H Er aM N Test EESE Dig Out Dig In RS 232 RS 485 An Out E dfo uf gt e lol al eS 232 c S H85 El Alo ule p lt Eee EIE Y Y Y tlo ooe Tu 668 iras PRESSE fra FULL Figure 5 2 1 Test 5 2 1 Digital outputs E_doUE This option allows the user doing a test for the digital outputs by activating 1 or deactivating 0 these outputs To select an output we use right and left key To activate 1 or deactivate 0 the output press key This option allows to enable 1 disable 0 the digital outputs to execute a function test To select one the outptut we move the left rights keys To enable 1 disable 0 press the UP key To access this option the pin number is mandatory 5 2 2 Digital inputs t d in This o
66. x20nex F8 Format lt STX gt POL ppppppp Unit Unit Mode Mode T UNITS kg KG MODE Gross BR Ib Ib Net NT F9 Format T F10 Format lt STX gt lt STA gt ppppppp T lt STA gt status 1 character positive weight negative weight mg unsteady weight F11 Format lt STX gt Polarity ppppppp T Polarity Negative weight Zero or positive weight F12 Format lt STX gt lt STA gt weight T lt STA gt status 1 character S steady weight N unsteady weight Weight without decimal point gt 6 digits with decimal point gt 7 digits F13 Format lt STX gt lt STA gt weight T lt STA gt status 1 character S steady weight N unsteady weight Weight without decimal point gt 5 digits with decimal point gt 6 digits 6 3 Communications Definitions lt STX gt Start of Text ASCII 2 lt ETX gt End of Text ASCII 3 lt ENQ gt Enquire ASCII 5 lt SYN gt Synchronous Idle ASCII 22 lt CR gt Carriage Return ASCII 13 lt LF gt Line Feed ASCII 10 Space character 0 Character 0 T Character 1 ppppppp Weight value 7 characters nnnnnnn Net weight value 7 characters aaaaaaa Analog Digital converter filtered output 7 characters POL
67. y ost ae 16 lt P lt P CF ae Lin Lin_c Lin_i Lin ON Mar m ryt 1 L In _ Ir IL _ yyy gt Lin OFF ER OFF on r ESEE Enter value Enter value 6 lt Figure 4 1 1 Calibration with masses 4 1 1 ZERO DEro Automatic zero adjustment To automatically adjust the zero value make sure there is no weight on it and press the enter key The indicator will show the present coefficient value On pressing enter again the message CALIB will be shown while the indicator assesses the present value Once accepted it will be stored It is recommended to keep this coefficient value or print it by means of printing the parameters see 5 1 3 Manual zero adjustment this coefficient is the internal value of the ADC and corresponds to the calibration zero value to introduce manually the zero value E key has to be pressed Then we select the corresponding digit with the Arrow Left and Arrow Right keys The selected digit value is modified with Arrow Up key 4 If a negative value has to be introduced it can only be done with the first left digit The negative sign appears after the 3 number 4 1 2 SPAN SPAn Automatic span adjustment To automatically adjust the span pla
68. y when the tare lock option is on see 3 3 4 press Exit and then the Tare key Operation G gt If the tare lock is of F then the tare is automatically deactivated if the conditions described in 3 3 4 are met It is possible to lock the clearing tare key see 3 3 6 2 6 Ticket Printout To print a ticket through RS 232 communication port press the print key If the weight is under the divisions introduced in PRINT MIN function see 3 3 7 the display shows Elric Ple ln The RS 232 communication port should be configured as ticket mode see 3 5 1 Operation Ticket ID 1 Gross 100 0 kg Tare 0 0 kg Net 100 0 kg Figure 2 6 1 Ticket example It is possible to lock the print key see 3 3 6 2 2 Operation 2 7 Setpoint By pressing me E key the short configuration set point menu is accessed In this menu you can configure the weight value at which the selected output operates Operation The screen where you should select the number of the set point to configure appears VL i Figure 2 7 1 Setpoint To select the setpoint use these 8 keys The enter D key allows us to get into the edit mode Press Enter to accept Press Exit if you want to exit the menu without making any changes If you want to enter a negative set point the minus sign should be placed in the digit to the left
69. z o mat N g n MOA L 1 g V g pl us A esuag S su s m y x Hi Bisi Bis ssuss t 1 1 su S Pe pes i Bis gt I aa Te 13IMS I OLZZ mae sag y l Bis L isa A I SHONA Y Td3dd3d ty a I Halduve A134VS Vo p pous N i a bis i MILLA ST139 dvo7 MIDNILA XO NOLLONNP VI4V 03193108Yd NI NOILVTIVLSNI NOTES NOTES
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