USER MANUAL
Contents
1. 75 INE 75 Bee ae EET EE 76 PET da MENU ERE EE mni iue 77 FAS IIR lU TRUM 78 Ba I A EN NE NE 78 Pase 3 AEE 78 Sua IURE E A 79 ARS SIS EEE 79 AVA MIGNON EE 80 HON OIT 80 PINE NMEN e E N 80 20 ATEN md ERSTE E RURSUM EEUU TON STATE 80 Pase MENU ANGIN ett TUUS SM UC 80 91 81 PN 81 MN Mr 81 MN 81 TTT HHH E E ENA 81 ENN 81 Hol NM 82 PN 82 MN Nr 82 MUDBUS FROTOLUL e AKA QUARE EDO ANE EYA RUN I ERES 84 RS485 Wiring Diagram r senesrsvevenenenenenesveserenenenensssssenenenenensssesenenenenensnsesenenenenee 84 Computer Connection es esse sese 84 Message Format and Data Types of MODBUS RTU Protocol 85 Implemented functions for MODBUS RTU Protocol 85 Data and Setting Parameters for KLEA eee 86 Measured and Calculated Data 86 PVN 00 ge 0 NT 103 KLEA Setting Parameters r srsrsrarerenenenrnresevenenenenenssserenenenenensesesenenenenensssesenene 105 ARCHIVE HISTORY RECORDS sese 112 Hourly archive d e 114 Daily archive data sees 115 Monthly archive data sss 115 E AE A E A O E E 116 FACTORY DEFAULT SET TINGS aaa an 118 TECHNICAL SPECIFIC ATIONS ss ss sss sss sss sss sss sss asas asas 122 KI FA Maa ma AYA Energy Analyzer FIGURES Figure 1 1 KEANE 13 Figure 2 1 Mounting KLEA into the panel 15 Figure 2 2 FOUND KEEA TO the PANO iia NA GUN2. o 57 NM 57 PPU 57 NIE 57 FU 57 En NL 57 Harmonics VF 58 Seen leva EO T 59 JAER 59 Date TEN 61 SEE TGT 61 Password b AA os aset nG 62 EEE ME EE E 62 BEE SSELITICIS AA AA 63 NENNE 63 Instantaneous MEN usa Aha GAN 64 Peder 65 Current Month Menu sss sss sss essen 66 ENN 67 Active power MENU EEE 68 Reactive power MEN es sss esse AGA AGANG AA 68 Apparent power MENu aasa 68 MONO MENU RR RR 68 Mo 68 MON 68 Phasor Diagram WOU vcicesaieisscsesussosasvestutesverssavsedbotottossesostteneesebeanedboedsvevictaus 69 Signal NE season ud Sete i EAR TECUM WEE 69 Harmonics IV a RR 70 Table T 70 GIaDH TT 71 NE NE aT 71 Tai EE SN 71 Imp Active Menu Import Active Energy Menu sss 72 a P KI FA AV ma AYA Energy Analyzer 3 2 3 1 2 E NG pa 3 2 3 1 4 3 2 3 2 3 2 3 3 3 2 3 4 3 2 3 5 3 2 3 6 3 2 4 3 2 4 1 3 2 4 2 3 2 4 3 3 2 4 4 3 2 5 3 2 5 1 N 3 2 5 1 1 1 B2 Ji N 3 2 5 1 1 3 3 2 5 1 1 4 3 2 5 1 2 Duo 9 3 2 5 2 3 2 5 3 3 2 5 4 3 2 5 4 1 3 2 5 4 2 3 2 5 4 3 SECTION 4 4 1 4 2 4 3 4 4 4 5 4 5 1 4 5 1 1 4 5 2 4 5 3 4 5 3 1 4 5 3 2 4 5 3 3 4 5 4 Exp Active Menu The Consumed Active Energy Meny 73 Ind Reactive Menu Inductive Reactive Energy Menu 73 Cap Reactive Menu Capacitive Reactive Energy Menu 73 Ll CIE UM 74 EET 0 AA T T T 74 jd f 0
3. KI FA ev S AYA Energy Analyzer TABLE OF CONTENTS SECTION 1 GENERAL INFORMATION ccccccssssccccsscsccccccscscccceecees 10 1 1 DN 10 1 2 Eee AE Tis OE NE 10 1 3 Receipt Control and Contents of Delivery sss 11 1 4 KLEA Energy MA ved 11 1 5 KleaCom Software Eda 12 1 6 KLEA Front Pane eco son ANNA NAN AA 13 SECTION 2 INSTALLATION REN 15 2 1 Preparing TOF IristallatlODssssanoasmeivtehidienn taces bai vt viva essi tic Er iE otii 15 2 2 MOUNING RU 15 2 3 F lte BI se TTE OTT 19 2 3 1 Three Phase Connection With Neutral 3PAW ee 19 2 3 2 Three Phase Connection No Neutral 3P3W eee 20 2 3 3 Three Phase No Neutral Aron Connection eren 20 24 Este 21 SECTION 3 amplis T RD 23 3 1 First Power on SettingS RR 23 3 1 1 BIE 101010 PA AA 23 3 1 2 R 24 3 1 3 ME AA 25 3 1 4 Current Transformer Ratio CTR sss 25 3 1 5 Voltage Transformer Ratio VTR sss 27 3 1 6 oe 27 3 1 7 TT 28 3 2 SE Sel ANNA NO sae NAAANINAG 28 3 2 1 C gla L 29 3 2 1 1 suem AA 29 3 2 1 1 1 Ne 30 3 2 1 1 1 1 Current Transformer Ratio sese 30 3 2 1 1 1 2 Voltage Transformer Ratio sss 31 3 2 1 1 1 3 COn IOT 31 3 2 1 1 1 4 Ped 32 3 2 1 1 1 5 FONN 32 3 2 1 1 2 DEVICE 0 ENE AA 33 3 2 1 1 2 1 Eile Uie RR ee A 33 3 2 1 1 2 2 CON AS T 34 3 2 1 1 2 3 New Ge AA 34 3 2 1 1 2 4 ISTO
4. SECTION 3 MENUS 5 0 AO1 GND x 120 100x1 0 1v 200 100 x1 When measure is KLEA V1 L N 185V the result will be as follows 5 0 AO1 GND 200 100 x1 x1 x 185 100x1 0 4 25V Example2 Assume that the following have been assigned Input connection P tot total active power Output connection 4 20mA Min value 600W Max value 1000W Multiplier 1 Then when measure is KLEA P tot 732W the result will be as follows 20 4 AO1 GND 1000 600 x1 x 732 600x1 4 5 28mA When measure is KLEA V1 L N 992W the result will be as follows 20 4 AO1 GND 200 100 x1 x 992 600x1 4 19 68mA Example3 Assume that the following have been assigned Input connection Q tot total reactive power Output connection 10 10V Min value 1400VAr Max value 1800VAr Multiplier kilo When measure is KLEA S tot 1485000VAr the result will be as follows 10 10 AO1 GND 1800 1400 x1000 x 1485000 1400x1000 10 5 75V When measure is KLEA V1 L N 1695000VA the result will be as follows 10 10 1800 1400 x1000 AO1 GND x 1695000 1400x1000 10 4 75V 3 2 1 1 6 2 Output2 Menu Analog output 2 settings are the same as Output1 Analog output2 gives output from AO2 GND pins e P KI FA AV ma AYA Energy Analyzer SECTION 3 MENUS 3 2 1 1 6 3 Ou
5. 13 VEM V2 Figure 3 78 Harmonics in Table Format KI FA AV ma AYA Energy Analyzer SECTION 3 MENUS E 3 2 2 5 2 Graph Menu Current and voltage harmonics of each phase are displayed graphically See Figure 3 79 Operator can scroll inside graph menu by pressing right and left keys There are 6 graph pages V1 V2 V3 11 12 13 Measure gt Harmonics gt V1 96 berba bad Tra 1 1 11 2 31 41 51 13 VES v20 gt Figure 3 79 Harmonics in Graphical Format 3 2 3 Meters Menu In this menu the energy values of Tariff 1 and Tariff 2 meters are displayed Import active Export active Inductive reactive e Capacitive reactive When an energy meter reaches the value 50000000 0 Mega it will start to count from 0 0 3 2 3 1 Tariff 1 Menu T1 meter consists of import active export active inductive reactive and capacitive reactive energy values WE Alarms Analysis 4 WE Alarms Analysis 4 Figure 3 80 Tariff 1 Menu a P KI FA AV ma AYA Energy Analyzer SECTION 3 MENUS 3 2 3 1 1 Imp Active Menu Import Active Energy Menu Import active energy values are displayed as seen in the following figure Meters gt T1 gt Imp active Index 267500 1 Curr hour 0 5 Prev hour 0 6 Curr day 21 3 Prev day 22 6 Curr month 598 4 Prev month 439 5 Figure 3 81 Imp Active Energy Page Index active energy consumed up
6. 5 5V gt 5 125 5 125 V 0 10V gt 0 1025V output signal low value will not fall below zero 10 10V gt 10 25 10 25V 0 20MA gt 0 20 5 MA output signal low value will not fall below zero 4 20MA gt 3 9 20 5 MA When the value of Input mode parameter falls below Min value with an amplitude more than 2 5 or exceeds Max value with an amplitude again more than 2 5 output signal will change In this case output signals from AOX GND pins will operate as follows in order to indicate that there is a problem in the electrical network for 0 5 V setting AOX GND signal amplitude will be 10V for 5 5V setting AOX GND signal amplitude will be 10V for O 10V setting AOX GND signal amplitude will be 10 8 V for 10 10V setting AOX GND signal amplitude will be 10 8 V for 0 20 mA setting AOX GND signal amplitude will be 21 6 mA for 4 20 mA setting AOX GND signal amplitude will be 21 6 mA The amplitude of analog output signal on AO1 GND pins will be as calculated by the following formula NN Meas value Min value x Multip AO1 con low limit Max value Min value x Multip Example1 Assume that the following values have been assigned Input connection V1 L N phase neutral voltage of phase 1 Output connection 0 5V Min value 100V Max value 200V Multiplier 1 Then when measure is KLEA V1 L N 120V the result will be as follows a P KI FA AV ma AYA Energy Analyzer
7. Alarm ON Alarm OFF status 1206 31 Value of related alarm parameter 1208 32 Alarm time 1210 32 Alarm ID 1212 32 Alarm ON Alarm OFF status 32 Value of related alarm parameter 1224 34 Alarm Timestamp 34 Alarm time 1226 34 Alarm ID 34 Alarm ID 1228 34 Alarm Status 34 Alarm ON Alarm OFF status 1230 34 Alarm Value 34 Value of related alarm parameter 1232 35 Alarm Timestamp 35 Alarm time 1234 35 Alarm ID 35 Alarm ID 1236 35 Alarm Status 35 Alarm ON Alarm OFF status 1238 35 Alarm Value 35 Value of related alarm parameter 1240 36 Alarm Timestamp 1154 1156 1158 1160 26 Alarm time D 36 Alarm time KI FA ENT 7 mu Energy Analyzer SECTION 4 MODBUS PROTOCOL R W Unit Data Type 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int J D Uu A Le er
8. Curr Month L3 P Current Month Phase 3 Active Power RO W Cur Monho Pime Current Month Phase 3 Active Power ro Timestamp Curr Month L3 Current Month Phase 3 Current Curr Month L3 I time Current Month Phase 3 Current Timestamp Curr Month L3 Q Current Month Phase 3 Reactive Power Curr Month L3 Q time Current Month Phase 3 Reactive Power Timestamp Curr Month L3 S Current Month Phase 3 Apparent Power Cur Month L e time Current Month Phase 3 Apparent Power Timestamp 1 Month Ago Total Active Power 1 Month Ago Total Active Power Timestamp e P 32 bit unix time gt 32 bit float 32 bit unix time 32 bit float 32 bit unix time VA 32 bit float 32 bit unix time W 32 bit float 7 32 bit unix time 32 bit float 32 bit unix time 32 bit float 7 7 18 20 22 4 VAr 32 bit unix time A 32 bit float 32 bit unix time 32 bit float 32 bit unix time 32 bit float 32 bit unix time VAr 32 bit float 32 bit unix time A 32 bit float 32 bit unix time W 32 bit float 32 bit unix time 32 bit float 32 bit unix time 32 bit float 32 bit unix time 32 bit float A VAr 5 KI FA ENT 7 uu Energy Analyzer SECTION 4 MODBUS PROTOCOL R W Unit Data Type 32 bit unix time 32 bit float 32 bit unix time 32 bit float 32 bit unix time 32 bit float J D Uu A c Le et je Address Parameter 1 Month Ago Phase 1 Active Power 1 Month Ago Phase 1 Active Powe
9. For both of the warnings below there must be a current in the system which is higher than the threshold value of the current transformer if any If KLEA is placed in a panel which consumes power The arrow directions on Measure Instantaneous Active Power screen should be rightward as the phases consume power If there is a leftward arrow sign turn off the device cut off panel power and then cross connect K and L ends of the current inputs belonging to the related phase s After that check that all arrows are rightward on Measure gt Instantaneous gt Active Power screen If KLEA is placed in a panel which generates power The arrow directions on Measure Instantaneous Active Power screen should be leftward as the phases generate power If there is a rightward arrow sign turn off the device cut off panel power and then cross connect the K and L ends of the current inputs belonging to the related phase s After that check that all arrows are leftward on Measure gt Instantaneous gt Active Power screen KI FA AV ma AYA Energy Analyzer SECTION 2 INSTALLATION 2 3 Wiring Diagrams 2 3 1 Three Phase Connection With Neutral 3P4W Fa out1 Z O out2 Analog Outputs Optional A Out1 GND A Out2 A Out3 A Out4 Q e a a UO o rf HEN EN P Alarm Relay Outputs C NO adi eGSS A Power Supply Current Measurement Inputs KI EA R wn mm 7 AYA Digital Inputs RS485 1 Opti
10. KLEA settings are made in this menu Select Settings menu and press OK key When OK key is pressed submenus will appear as seen in the Figure 3 11 Under the Settings menu the following submenus exist Setup Date Time e System info e Password Restart Default Settings ETES Measure Meters Alarms Analysis Date Time System info 0 QL 9 0 A Password Restart Default settings U VE 5 0 A 5 0 A Figure 3 11 Settings Menu Setup Menu The following submenus are available inside Setup menu e Network Device Energy e Digital input e Digital output e Communication e Alarm e Clear The user can scroll inside the menus by pressing up and down keys Press OK key in order to access contents of each submenus the submenus under the setup menu In order for the new settings to be accepted by KLEA and stored in the memory operator should navigate back by pressing X key to Startup Screen from the tab at which change has been made When the operator returns to Startup page Settings changed Save message will appear on the screen If OK is pressed changes will be accepted and stored in permanent memory If X key is pressed the changes will not be accepted by KLEA and will not be stored in permanent memory e P KI FA ENT 7 mu Energy Analyzer SECTION 3 MENUS When Settings changed Save message appears on KLEA screen if OK is pressed setting changes will be accepted and sto
11. Parameters Records to be Cleared R W Value Modbus func 190 ma Energymete hw hr TOC TT Ww h me 1 4 Tamm Digtalinputcounters SWC o 1906 Tamm Tenna pas w me iso szbitint Poya T C o im xim aan adres w h loom sa szot Monhyachwereod WC o In order to complete to erase zeroize programmer should write 1 to the below MODBUS address 1898 32 bit int Complete erasing zeroizing 10H 06H In order to complete clearing process operator programmer should Write 1 to registers related with to be cleared parameters Then write 0 to 1898 register and 1 to 1899 register within 60 seconds KLEA anergy Analyzer FACTORY DEFAULT SETTINGS 2 FACTORY DEFAULT SETTINGS Default value Unit Setting Range Network Settings CurrentTranst Rato TR Of ag votage Trans Ratio VIP Do teoSo00 connection 3phasedwie Bphasedwiel3 phase 3wreaon Powerunt ol kio Klo Mega Device Settings language Engish Tl Trkgefknglis Pycom rss dedo leveldeeweld NewPassword Displyon Timedependent TimedependentContinuous Displayonime coo sec tago Energy Settings masete HH aO mase 6 O masane 00 lol og Sutody 0 1 om gt Sutomoth 1 1 m gt mem 00 mw Ramanan mme oo Wh o0s200000m0 Thame 00 wah 0200000000 mw om wa 0csaommoooo0 ma o0 kw
12. The last saved file number inside the daily memory can be accessed from the 32 bit parameter starting from Modbus address 1362 Refer to Table 4 4 Monthly archive data Recording of daily data changes with start of month Refer to 3 2 1 1 3 5 and start of day Refer to 3 2 1 1 3 4 settings The smallest and largest instantaneous values measured during one month period are saved as minimum and maximum values Likewise average values of measurements which were taken in one month period are saved as average values 14h function operates with file numbers File numbers 10001 10036 are used for MONTHLY data KLEA keeps a total of 36 monthly files in its specifically reserved memory for monthly data When 36 files of data are filled completely Klea starts to save data starting from 10001st file The last saved file number inside the monthly memory can be accessed from the 32 bit parameter starting from Modbus address 1364 Refer to Table 4 4 a KI FA ENT 7 mu Energy Analyzer SECTION 4 MODBUS PROTOCOL B 4 5 4 Clear Operator programmer can erase zeroize data stored in non volatile memory via MODBUS commands Erasable data are as follows energy meters all Tariff 1 and Tariff 2 meters demand values all digital input counters all variables mentioned above hourly archive records daily archive records monthly archive records alarm records Table 4 8 Clear Address Table Address Data Type
13. and kVArh C capacitive reactive index values can be monitored E 3 2 5 4 2 Daily Menu This menu consists of index values measured from start of day Refer to 3 2 1 1 3 4 up to present time kWh import active kWh E export active kVArh I inductive reactive and kVArh C capacitive reactive index values can be monitored D 3 2 5 4 3 Monthly Menu This menu consists of index values measured from start of month Refer to 3 2 1 1 3 5 and start of day Refer to 3 2 1 1 3 4 up to present time kWh import active kWh E export active kVArh I inductive reactive and kVArh C capacitive reactive index values can be monitored KI FA ENT 7 mu Energy Analyzer SECTION 4 MODBUS PROTOCOL e SECTION 4 MODBUS PROTOCOL m 4 1 RS485 Wiring Diagram RS485 WIRING DIAGRAM qXpOOOQQOOOOX X X XXXXpOOOQQOOOOO 1200 1200 l n Iy VA AY yi Y Y Terminating geg gE A laga PA Terminating resistor resistor Figure 4 1 RS485 Wiring Diagram B 4 2 Computer Connection KLEA can communicate with PCs via USB RS85 or RS232 RS485 converters di O 0 O oco POOO OG KLEA KLEA PC USB RS485 or RS232 RS485 converter Figure 4 2 Connection of KLEA to a PC KI FA AV ma AYA Energy Analyzer SECTION 4 MODBUS PROTOCOL 4 3 Message Format and Data Types of MODBUS RTU Protocol int float string KLEA implements modbus RTU protocol Modbus RTU message forma
14. e Address Parameter 36 Alarm ID 36 Alarm ON Alarm OFF status 36 Value of related alarm parameter 36 Alarm ID 36 Alarm Status 36 Alarm Value 37 Alarm Timestamp 1250 37 Alarm ID 37 Alarm ID 1252 37 Alarm Status 37 Alarm ON Alarm OFF status 37 Value of related alarm parameter 1264 39 Alarm time 1268 39 Alarm ON Alarm OFF status 1270 39 Value of related alarm parameter 1272 40 Alarm time 1274 40 Alarm ID 1276 40 Alarm ON Alarm OFF status 40 Value of related alarm parameter 1288 42 Alarm time 1292 42 Alarm ON Alarm OFF status 1294 42 Value of related alarm parameter 1296 43 Alarm time 1298 43 Alarm ID 1300 43 Alarm ON Alarm OFF status 43 Value of related alarm parameter 1312 45 Alarm Timestamp 45 Alarm time 1314 45 Alarm ID 45 Alarm ID 1316 45 Alarm Status 45 Alarm ON Alarm OFF status 1318 45 Alarm Value 45 Value of related alarm parameter 1320 46 Alarm Timestamp 46 Alarm time 1322 46 Alarm ID 46 Alarm ID 1324 46 Alarm Status 46 Alarm ON Alarm OFF status 1326 46 Alarm Value 46 Value of related alarm parameter 1328 47 Alarm Timestamp 1330 47 Alarm ID 1242 1244 1246 1248 37 Alarm time 47 Alarm time 47 Alarm ID p KI Energy Analyze EA r Address Parameter 1332 1334 1336 1338 1340 1342 1344 1346 49 Alarm ID 1348 49 Alarm Status 49 Alarm ON Alarm OFF status 13
15. 656 Tariff 2 Inductive Reactive Index 658 Tariff 2 Inductive Reactive Current Hour Tariff 2 Inductive Reactive Previous Hour 662 Tariff 2 Inductive Reactive Current Day 664 Tariff 2 Inductive Reactive Previous Day 666 T2 Ind React Curr Month Tariff 2 Inductive Reactive Current Month kVArh 32 bit float 674 Tariff 2 Capacitive Reactive Previous Hour kVArh 32 bit float kVArh 32 bit float kVArh 32 bit float kVArh 32 bit float kVArh 32 bit float T1 Rate3 Inductive Reactive Previous Day T1 Rate3 Inductive Reactive Current Month T1 Rate3 Inductive Reactive Previous Month T1 Rate3 Capacitive Reactive Index T1 Rate3 Capacitive Reactive Current Hour T1 3 Cap React Prev Hour T1 3 Cap React Curr Day T1 Rate3 Capacitive Reactive Previous Hour Z 2 E EEE EE EE EEE EEEE T1 Rate3 Capacitive Reactive Current Day A SON DE SE gt Z c Z 2 SE gt r SZZ S 2 gt 676 T2 Cap React Curr Day Tariff 2 Capacitive Reactive Current Day 678 T2 Cap React Prev Day Tariff 2 Capacitive Reactive Previous Day Tariff 2 Capacitive Reactive Current Month Tariff 2 Capacitive Reactive Previous Month DEMAND Current Month Total Active Power Current Month Total Active Power Timestamp Current Month Total Current 32 bit float 32 bit unix time 32 bit float Z c p V KI FA ENT 7 mu Energy Analyzer SECTION 4 MODBUS PROTOCOL R W Unit Data Type 32 bit unix
16. Menu Output gives output from D01 and DO1 pins Mode Press up and down keys to navigate between digital outputs Press OK on the desired output and options seen in Figure 3 36 will appear Any of them can be assigned as output operating mode Mode setting has the following options Off T1 kWh T1 kWh E TI kVArh I e T1 kVArh C T1 1 kWh T1 1 kWh E e T1 1 kVArh I e T1 1 kVArh C e T1 2 kWh T1 2 kWh E e T1 2 kVArh I e T1 2 kVArh C e T1 3 kWh T1 3 kWh E e T1 3 kVArh I e TI 3 kVArh C e T2 kWh e T2 kWh E e T2 kVArh I e T2 kVArh C e Digital Input Settings 5 Setup 5 Digital output gt Output1 Multiplier T1 2 kVArh I Figure 3 36 Output1 Menu e P KI FA AV ma AYA Energy Analyzer SECTION 3 MENUS Energy When the selected option mode option reaches the size of energy Output1 generates a pulse for Virtual Keyboard Refer to 3 1 4 Example Width It can be adjusted between 50 2500 msec for Virtual Keyboard Refer to 3 1 4 Example Multiplier Multiplier is of use only when Output1 5mode is adjusted as Digital input When digital input1 counter Refer to Digital input 3 2 3 6 reaches the multiplier digital output1 generates a pulse from DO1 and DO1 pins It can be adjusted between 1 10000 for Virtual Keyboard Refer to 3 1 4 Example Second example explains this implementation Example Assume the se
17. Phase3 current 29th harmonic 3 Phase3 current 31st harmonic Phase3 current 33rd harmonic 390 Phase3 current 43rd harmonic Phase3 current 45th harmonic Phase3 current 47th harmonic Phase3 current 49th harmonic Phase3 current 51st harmonic ALARM FLAGS Alarm flag 1 first 32 bit Alarm flag 2 second 32 bit TARIFF METERS 370 372 374 376 78 32 bit int 32 bit int a p KI FA ENT 7 uu Energy Analyzer SECTION 4 MODBUS PROTOCOL R W Unit Data Type kWh 32 bit float kWh 32 bit float kVArh 32 bit float kVArh 32 bit float kVArh 32 bit float kVArh 32 bit float J D Uu A E Le er o Address Parameter 428 T1 Exp Act Curr Month 430 T1 Exp Act Prev Month Tariff 1 Export Active Current Month Tariff 1 Export Active Previous Month T1 Ind React Index Tariff 1 Inductive Reactive Index T1 Ind React Curr Hour 432 434 436 T1 Ind React Prev Hour 4 T1 Ind React Curr Day Tariff 1 Inductive Reactive Current Day 38 440 Tariff 1 Inductive Reactive Previous Day kVArh 32 bit float 450 Tariff 1 Capacitive Reactive Previous Hour kVArh 32 bit float 456 Tariff 1 Capacitive Reactive Current Month kVArh 32 bit float 458 Tariff 1 Capacitive Reactive Previous Month kVArh 32 bit float 460 T1 Rate1 Import Active Index 32 bit float 462 T1 Rate 1Import Active Current Hour 32 bit float 464 T1 Rate1 Import Active Previous Hour 32 bit float 466 T1 Rate1 Import Act
18. V13 hi limit V15 hi limit V17 hi limit V19 hi limit V21 hi limit Delay MOOOOOCOOOO0O0 9000000000 Figure 3 55 Harmonics Menu Alarm relay Refer to 3 2 1 1 8 1 V L N Menu Alarm relay setting THDV High Limit High limit value for total harmonic distortion voltage alarm For Virtual Keyboard Refer to 3 1 4 Example In order to set an alarm for THDV operator should enter a high limit value larger than zero When high limit is entered as zero THDV alarm will be deactivated no alarm will be set It can be adjusted between 06100 THDV hi limit 0 0 Figure 3 56 THDV High Limit Setting a P KI FA ENT 7 mu Energy Analyzer SECTION 3 MENUS V3 V21 high limit 3 5 21 harmonic distortion high limit values are entered In order to set an alarm for V3 V5 V21 operator should enter a high limit value larger than zero When high limit is entered as zero 0 0 V3 V5 V21 alarm s will be deactivated no alarm will be set High limits can be adjusted between 044100 For Virtual Keyboard Refer to 3 1 4 Example V3 hi limit 0 0 V21 hi limit 0 0 Figure 3 57 V3 V21 Harmonic High Limit Delay See 3 2 1 1 8 1 V L N Menu Delay setting B 3 2 1 1 8 13 Harmonics I Menu Harmonics l settings are the same as the Harmonics V alarm settings S 3 2 1 1 9 Clear Menu In this tab operator can clear demand values energy tariff meter values and DI Digital Input counters All option cl
19. 1 7 Start When Start tab is selected press OK key to initialize Klea Startup Settings Language English Date 07 January 2013 Time 17 45 28 CTR 1 VTR 1 0 Connection Awire Ng Initializing Figure 3 9 Start KLEA first power on settings page only appears when KLEA is powered up for the first time after factory production Following this first initialization all the required settings including first power on page settings can be accomplished via Settings menu of KLEA 3 2 Startup Screen m After KLEA is turned on following page appears EE Measure Meters Alarms Analysis v 220 0 vn 9 0 220 0 v 2 9 0 220 0 v 5 9 0 Y Figure 3 10 Startup Screen At the top of the screen there are multiple selection menus In the middle instantaneous voltage and current values pertaining to each phase are shown At the bottom left of the screen current and voltage values of the three phases and connection type are shown At the bottom right corner system clock KLEA time is shown Operator can navigate between the multiple selection menus by pressing right and left arrow keys Press OK key to enter into any multiple selection menu When 3phase 4wire or ARON connection is selected VL N voltages are shown in startup screen When 3phase 3wire connection is selected VL L voltages are shown in startup screen KI FA ev S AYA Energy Analyzer SECTION 3 MENUS 3 2 1 Settings 3 2 1 1
20. 3 2 1 1 4 3 Input 3 Menu optional Input 3 is applicable to optional digital lO Klea models Input 3 applications and settings are the same as Input1 Digital input3 operates with DI3 and GND pins a P KI FA AV ma AYA Energy Analyzer SECTION 3 MENUS E 3 2 1 1 4 4 Input 4 Menu optional Input 4 is applicable to optional digital lO Klea models Input 4 applications and settings are the same as Input1 Digital input4 operates with DI4 and GND pins 2 3 2 1 1 4 5 Input 5 Menu optional Input 5 is applicable to optional digital lO Klea models Input 5 applications and settings are the same as Input1 Digital input5 operates with DI5 and GND pins 3 3 2 1 1 4 6 Input 6 Menu optional Input 6 is applicable to optional digital lO Klea models Input 6 applications and settings are the same as Input1 Digital input6 operates with DI6 and GND pins E 3 2 1 1 4 7 Input 7 Menu optional Input 7 is applicable to optional digital lO Klea models Input 7 applications and settings are the same as Input1 Digital input7 operates with DI7 and GND pins i 3 2 1 1 5 Digital Output Menu It comprises of Output and Output2 menus ETES Measure Meters Alarms Analysis 5 0 A 5 0 A Rate Measure Meters Alarms Analysis gy Digital input Digital output Communication Figure 3 35 Digital Output Menu optional digital I O model e P KI FA AV ma AYA Energy Analyzer SECTION 3 MENUS 3 2 1 1 5 1 Output
21. 606101 Klea optional digital IO model 606102 Klea optional 2 analog outputs model 606103 Klea optional 4 analog outputs model Please also check the contents of delivery as listed below e 1 pc KLEA 1 pc CD ROM User manuel and KleaCom software 2 pcs fixing brackets and screws 1 pc 4 pin female terminal block for alarm outputs NO C out2 C out1 NO 1 pc 6 pin female terminal block for current inputs 11 k1 12 k2 13 k3 1 pc 3 pin female terminal block for supply input Un 1 pc 3 pin terminal block for digital inputs DIT GND DI2 1 pc 4 pin female terminal block for voltage inputs L1 L2 L3 N e 1 pc 7 pin female terminal block for digital output and RS485 B GND1 A DO1 DO1 DO2 DO2 2 pcs 10 pin female terminal block for digital IO optional KLEA 606101 product DO3 DO3 DI3 GND3 1 pc 4 pin female terminal block for two analog output optional KLEA 606102 product AO1 GND AO2 GND 1 pc 8 pin female terminal block for four analog output optional KLEA 606103 product AO1 GND AO4 GND 3 1 4 KLEA Energy Analyzer KLEA is a multi functional energy analyzer KLEA e measures calculates current voltage and frequency active reactive and apparent power Current and voltage harmonics up to 51 harmonic THDV THDI Power factor cos for each phase e p KI FA AV ma AYA Energy Analyzer SECTIO
22. 71 3 and T2 can be entered inside this menu Thus operator can synchronize the official electric meter with KLEA tariff meters Operator can navigate inside Energy menu by pressing up and down keys Settings gt Setup gt Energy T1 1 start time 8 T1 2 start time 16 T1 3 start time U Start of day Start of month T1 kWh T1 kWh E T1 kVArh I T1 kVArh C T1 1 kWh T1 1 kWh E TI 1 kVArh I Figure 3 24 Energy Menu a P KI FA AV ma AYA Energy Analyzer Alarms Analysis 4 SECTION 3 MENUS 3 2 1 1 3 1 T1 1 start time Flectric meters can have more than one tariff and also individual tariffs can be sliced in time T1_1 abbreviation refers to the first time slice of tariff 1 meter T1 1 start time can be adjusted between 0 23 for Virtual Keyboard Refer to 3 1 4 Example TI rate1 meter the first time slice of T1 meter T1 1 counts between T1 1 start time andT1 2 start time Assume that T1 1 start time and T1_2 start time are adjusted as 8 and 16 respectively T1 rate1 meter T1_1 counts starting from 08 00 and ceases at 16 00 Settings gt Setup gt Energy T1 1 start time 8 T1 2 start time 16 T1_3 start time 0 Start of day 0 Start of month T1 kWh T1 kWh E T1 KVArh I T1 kVArh C T1 1 kWh T1 1 kWh E T1 1 kVArh I Figure 3 25 T1 1 start time 3 2 1 1 3 2 T1 2 start time T1_2 abbreviation refers to the second time slice of tariff 1 meter T1 2 start t
23. AW ON Ea AA ANAN 35 3 2 1 1 2 5 Pisplayon TINE maa ANNA AA AA AA NG 35 3 2 1 1 3 AL VEE EE 55 3 2 1 1 3 1 D E c e NA AA NOTA 36 3 2 1 1 3 2 HE 36 3 2 1 1 3 3 ME 37 KI FA AV ma AYA Energy Analyzer 3 2 1 1 3 4 TT 38 3 2 1 1 3 5 SE OLIN OE 38 3 2 1 1 3 6 FIK EE NN 38 3 2 1 1 3 7 EEE 38 3 2 1 1 3 8 HO HT 38 3 2 1 1 3 9 1d 7 EE 38 3 2 1 1 3 10 quis PE S 38 3 2 1 1 3 11 TE URNE 38 3 2 1 1 3 12 PETRY NE AA 38 3 2 1 1 3 13 14057 e 38 3 2 1 1 3 14 MN 39 3 2 1 1 3 15 HE 39 3 2 1 1 3 16 7 1 T 39 3 2 1 1 3 17 EL ATS nSsU M 39 3 2 1 1 3 18 MN 39 3 2 1 1 3 19 Lk SINE ANA ANAND BUKANA AA ANA AANGAL GAAN 39 3 2 1 1 3 20 EE ENE 39 3 2 1 1 3 21 EE EEE 39 3 2 1 1 3 22 T KIN REE TE 39 3 2 1 1 3 23 PE AA 39 3 2 1 1 3 24 PAA AN AA 39 3 2 1 1 3 25 PAN NAA 40 3 2 1 1 4 VIE AA 40 3 2 1 1 4 1 APU MONU RR 41 3 2 1 1 4 1 1 MO 41 3 2 1 1 4 1 2 BEE EN 42 3 2 1 1 4 2 Fa ET HA PE 42 3 2 1 1 4 3 Input 3 Menu optional sesnsnsnrnenrrenenerenenerenenenenenenrnenrnrsesesesesesesesnsesssnseesns 42 3 2 1 1 4 4 Input 4 Menu optional sssrin n eiai 43 3 2 1 1 4 5 Input 5 Menu optional eese eene tete tnn tntnonononis 43 3 2 1 1 4 6 Input 6 Menu optional eene tette ttn onia 43 3 2 1 1 4 7 Input 7 Menu optional eese eese a 43 3 2 1 1 5 VCE AO 010 naaa AA NAG 43 3 2 1 1 5 1 TN 44 3 2 1 1 5 2 NN 46 3
24. Energy Page Luse 72 Example Tor 5tart Or eT 72 Example for Start Of Day ssesersrnerensrnenersrnsnessensnesnsrnenessrnssessessnssesssnssessenssene 72 Example for Start of Month rsrsrsrnrsensnensverersrsnsesrsrsenenenenesenevsssssnsesesesenenene 73 RANN 74 HiNT 74 EE EST cscs case cesta 75 NE 75 Digital Input Menu Optional Digital I O model 76 sl 77 Phase MENU EE 78 TN 79 EEE EE 79 aAa NETO aNG ANNA AA E 80 HOME 80 EN 81 Se e RT Ts B BL ga EE vivat im 84 Connection of KLEA to a PC rsrsrsrsrnenrrrsrnrnenensrsrnrsenenensesessnssesersesesenesessesssenenns 84 Message FOrmat rusenenrsrenenrnverenensevevenensevenenensenenensesenenensevenenensevenensevenensssesenenens 85 int 32 DID data a e 85 Implemented functions for MODBUS RTU Protocol 85 Kile 0 US ais 87 Setting Parameters ussresesrsrsssnssenenrrersvssenenensnssnssenenenssssnsssnenenensssensnsnenenen 106 Descriptor BL 111 Archive History Record Table sss 112 CTE ar AGNOS TANG RR UE 116 KI FA AV ma AYA Energy Analyzer SECTION 1 GENERAL INFORMATION SECTION 1 GENERAL INFORMATION 1 1 Symbols Caution Wherever used this symbol indicates that there is important information that must be taken into consideration Danger of Electric Shock This symbol indicates that there is dangerous voltage or current 1 2 General Warn
25. L2 Harmonics39 L2 Harmonics41 L2 Harmonics43 L2 Harmonics45 L2 Harmonics47 L2 Harmonics49 L2 Harmonics51 Phase2 current 41st harmonic Phase2 current 43rd harmonic RO RO RO RO Ro Phase2 current 45th harmonic RO Ro o RO Ro RO RO Phase2 current 47th harmonic Phase2 current 49th harmonic Phase2 current 51st harmonic PHASE 3 276 L3V Phase3 voltage 78 E Phase3 current Phase frequency gt FIT Mild 32 bit float 32 bit float 292 L3 THDV Phase3 total har distortion of voltage 96 32 bit float o S AE N L3 THDI Phase3 total har distortion of current 296 L3 V Harmonics1 Phase3 voltage first harmonic 298 L3 V Harmonics3 300 L3 V Harmonics5 302 L3 V Harmonics7 304 L3 V Harmonics9 306 L3 V Harmonics11 308 L3 V Harmonics13 310 L3 V Harmonics15 Phase3 voltage 15th harmonic 312 L3 V Harmonics17 Phase3 voltage 17th harmonic 314 L3 V Harmonics19 316 L3 V Harmonics21 318 L3 V Harmonics23 320 L3 V Harmonics25 322 L3 V Harmonics27 324 L3 V Harmonics29 326 L3 V Harmonics31 Phase3 voltage 31st harmonic Phase3 voltage 33rd harmonic 338 Phase3 voltage 43rd harmonic a P 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bi
26. T1 1 can be entered in this tab 3 2 1 1 3 12 T1 1 kVArhi Initial value for inductive reactive energy of T1 1 can be entered in this tab 3 2 1 1 3 13 T1 1kVArhC Initial value for capacitive reactive energy of T1 1 can be entered in this tab e P E 3 2 1 3 3 2 1 E 3 2 1 D 3 2 1 3 3 2 1 3 3 2 1 E 3 2 1 D 3 2 1 3 2 1 2 3 2 1 m 3 2 1 KI FA AV ma AYA Energy Analyzer SECTION 3 MENUS 1 3 14 T1 2 kWh Initial value for import active energy ofT1 2 can be entered in this tab 1 3 15 T1 2kWheE Initial value for export active energy of T1 2 can be entered in this tab 1 3 16 T1 2kVArh I Initial value for inductive reactive energy of T1 2 can be entered in this tab 1 3 17 T1 2 kVArh C Initial value for capacitive reactive energy of T1 2 can be entered in this tab 1 3 18 T1 3 kWh Initial value for import active energy of T1 3 can be entered in this tab 1 3 19 T1 3 kWh E Initial value for export active energy of T1 3 can be entered in this tab 1 3 20 T1 3 kVArh I Initial value for inductive reactive energy of T1 3 can be entered in this tab 1 3 21 T1 3 kVArh C Initial value for capacitive reactive energy of T1 3 can be entered in this tab 1 3 22 T2 kWh Initial value for import active energy of T2 can be entered in this tab 1 3 23 T2 kWh E Initial value for export active energy of T2 can be entered in this tab 1 3 24 T2 kVArh I Initial
27. Virtual Keyboard Refer to 3 1 4 Example If a decimal number is to be entered as a VTR with the help of Klea arrow keys point to the x box on the Virtual Keyboard and press OK key In order for KLEA to perform accurate measurements the voltage transformer ratio should be entered correctly Settings gt Setup gt Network Connection HE Demand period 15 Power unit Figure 3 15 Setting Voltage Transformer Ratio 3 2 1 1 1 3 Connection KLEA may perform measurements with three different connection types 3 phase 4 wire connection 3 phase 3 wire connection e Aron connection Inside Network menu press up and down keys to select Connection Press OK key and the above connection types will appear on the screen Select the connection type and press OK to finish the setting Settings gt Setup gt Network ais IG y 3phase 3wire onnection SES Aron Demand period 15 Power unit Kilo Figure 3 16 Connection a Pp KI FA ENT 7 mu Energy Analyzer SECTION 3 MENUS 3 2 1 1 1 4 Demand Period Inside Network menu press up and down keys to select highlight Demand period menu item When Demand period is selected press OK key and KLEA virtual keyboard will appear on the screen Demand period can be adjusted between 1 60 minutes For Virtual Keyboard Refer to 3 1 4 Example Settings gt Setup gt Network CTR VTR Connection Power unit Figure 3 17 Demand Period 3 3 2
28. adjusted to be the same then analog output will not operate 3 2 1 1 6 1 5 Multiplier When Multiplier is selected press OK key and the options in Figure 3 43 will appear on the screen Press up and down keys to select the desired option and press OK key to complete the setting Multiplier coefficient options are as follows 7 e Kilo 1000 e Mega 1000000 For example assume that 10000000W and 350000000W are required to be entered for min and max values In this case if operator selected Mega in multiplier tab then it will be sufficient to enter 10 and 350 for min and max values Settings 5 Setup 5 Analog output gt Output1 Input mode V1 L Output conn 0 5V Kilo Min value Max value Nega ultiplier Figure 3 43 Multiplier e P AV aa AYA Energy Analyzer AO1 GND SECTION 3 MENUS Klea can output O 5V 5 5V O 10V 10 10V 0 20mA and 0 20mA range signals from AOX GND pins When the value of Input mode parameter falls below Min value with an amplitude less than 2 5 or exceeds Max value with an amplitude again less than 2 5 output signal will linearly follow this change For Output conn types whose low limit is zero output signal will not fall below zero only high limit will change linearly up to 2 596 of its value In summary output signals from AOX GND pins will operate as follows 0 5V gt 0 5 125V output signal low value will not fall below zero
29. be active 1 T2 mode should be selected in digital input1 and or digital input2 menu 2 DI and GND pins of the selected input should be short circuited Refer to 3 2 1 1 4 Digital input If Tariff 2 mode is NOT SELECTED in the digital input menu even though the related digital input pins are short circuited Tariff 2 will not be active Tariff 1 meter continues to operate 3 2 3 6 Digital Input Menu In this menu counters belonging to digital inputs are displayed Refer to 3 2 1 1 4 Digital input to adjust a digital input as a counter When DI1 and GND pins are short circuited for at least delay Refer to 3 2 1 1 4 1 2 Delay time digital input1 counter value increments by 1 When DI2 and GND pins are short circuited for at least delay Refer to 3 2 1 1 4 1 2 Delay time digital input2 counter value increments by 1 Meters Digital input Counter 2 Counter 3 Counter 4 Counter 5 Counter 6 Counter 7 Figure 3 89 Digital Input Menu Optional Digital I O model KLEA base model has 2 optional digital IO model has 7 counters KI FA ENT 7 mu Energy Analyzer SECTION 3 MENUS 3 2 4 Alarms Menu In this menu alarms can be monitored Alarms menu consists of Phase1 Phase2 Phase3 and Other submenus In Klea MODBUS table 50 alarm statuses can be saved Refer to Table 4 3 If the number of alarm statuses exceeds 50 51st alarm is overw
30. bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time J D Uu A Le er e Address Parameter 14 Alarm ID 14 Alarm ON Alarm OFF status 14 Value of related alarm parameter 14 Alarm ID 14 Alarm Status 14 Alarm Value 15 Alarm Timestamp 1074 15 Alarm ID 15 Alarm ID 1076 15 Alarm Status 15 Alarm ON Alarm OFF status 15 Value of related alarm parameter 1088 17 Alarm time 1092 17 Alarm ON Alarm OFF status 1094 17 Value of related alarm parameter 18 Alarm time 1098 18 Alarm ID 18 Alarm ON Alarm OFF status 18 Value of related alarm parameter 1112 20 Alarm time 1116 20 Alarm ON Alarm OFF status 1118 20 Value of related alarm parameter 1120 21 Alarm Timestamp 21 Alarm time 1122 21 Alarm ID 1124 21 Alarm ON Alarm OFF status 21 Value of related alarm parameter 1136 23 Alarm Timestamp 23 Alarm time 1138 23 Alarm ID 23 Alarm ID 1140 23 Alarm Status 23 Alarm ON Alarm OFF status 1142 23 Alarm Value 23 Value of related alarm parameter 1144 24 Alarm Timestamp 24 Alarm time 1146 24 Alarm ID 24 Alarm ID 1148 24 Alarm Status 24 Alarm ON Alarm OFF status 1150 24 Alarm Value 24 Value of related alarm parameter 1152 25 Alarm Timest
31. cde Rie HIER 16 Figure 2 3 Loosening of Terminal Block Screws esses 16 Figure 2 4 Inserting Cable into the Terminal Block sss 17 Figure 2 5 Fixing the Cable to the Terminal Block sss 17 Figure 2 6 KLEA Star WYE Connection Diagram eese retenta 19 Figure 2 7 KLEA 3 Phase Delta Connection Diagram esses 20 Figure 2 8 KLEA Aron Connection Diagram sesesererenenenenenenenenenenenenenenenesssssssseseseseseseses 20 Figure 2 9 me a m p HO 2 Figure 3 1 STG de e n Ts RE E 23 Figure 3 2 Lae AAC WAG L 23 Figure 3 3 BE EE 24 Figure 3 4 Example for Setting the Date sss sese 24 Figure 3 5 Current Transformer Ratio eee eeeeee eee eete teresa Ties 25 Figure 3 6 Entering Values to the Virtual Keyboard sss 26 Figure 3 7 Voltage Transformer Ratio sss 27 Figure 3 8 Connection TY DSS EE EEE 27 Figure 3 9 Eg EE EN EE EN eee 28 Figure 3 10 UP TN 28 Figure 3 11 ENN 29 Figure 3 12 KLEA Sava QUE T 30 Figure 3 13 Neve 30 Figure 3 14 Setting Current Transformer Ratio sss 30 Figure 3 15 Setting Voltage Transformer Ratio sss eenn 31 Figure 3 16 R c es le RE eae een ae 31 Figure 3 17 Deniand PL 32 Figure 3 18 POUR 32 Figure 3 19 PEN 33 Figure 3 20 Language SEI SCU van 33 Figure 3 21 NTN 34 Figure 3 22 Entering New Password sss sss
32. demand period e P KI FA AV ma AYA Energy Analyzer SECTION 3 MENUS 3 2 2 2 1 2 Active power menu The demand values for active power are as explained in the Demand 5Current Month gt Current submenu 3 2 2 2 1 3 Reactive power menu The demand values on the reactive power are as explained in the Demand gt Current Month gt Current submenu 3 2 2 2 1 4 Apparent power menu The demand values on the apparent power are as explained in the Demand gt Current Month gt Current submenu 3 2 2 2 2 1 month Ago Menu The demand values on the 1 month ago menu are as explained in the Demand 5 Current Month submenu 3 2 2 2 3 2 Months Ago Menu The demand values on the 2 months ago menu are as explained in the Demand Current Month submenu 3 2 2 2 4 3 Months Ago Menu The demand values on the 3 months ago menu are as explained in the Demand Current Month submenu KI FA AV ma AYA Energy Analyzer SECTION 3 MENUS 3 2 2 3 Phasor Diagram Menu In phasor diagram menu page at the right of the phasor diagram following information is listed e phase voltages V1 V2 V3 e phase currents 11 I2 13 e V1 V2 V2 V3 and V3 V1 phase difference angles e V1 11 V2 12 and V3 13 phase difference angles Within the phasor diagram currents are drawn with gray lines and voltages are drawn with black lines Within the phasor diagram same size circles have been added t
33. essen 34 Figure 3 23 Setting Display ON Te 35 Figure 3 24 Sy Ke UE 35 Figure 3 25 IR Ed AA Um 36 Figure 3 26 DNI CIA secs ca ca ccs A E N E E eee ee 37 Figure 3 27 HITEN 37 Figure 3 28 Digital Input MEN EN 40 Figure 3 29 Digital Input Menu With IO Option eres 40 Figure 3 30 MOGE ea cla 41 Figure 3 31 Digital Input OUTILBE EE E 41 Figure 3 32 BEEN eee 42 Figure 3 33 Tartt 1 Or Tariff 2 ACHVAllODLuss opas biete unies roter used io ase 42 KI FA AV ma AYA Energy Analyzer Figure 3 34 Bee Le Mie a AA AA 43 Figure 3 35 Digital Output Menu optional digital I O model 43 Figure 3 36 61519571 Ur E one 44 Figure 3 37 A alog OUUDUEIVIBITU aaa AA TA AGA ARS 46 Figure 3 38 MN 47 Figure 3 39 AUTOS REE 48 Figure 3 40 MUTU 49 Figure 3 41 voll ON JO OP NE 49 Figure 3 42 voll FF ION MN 49 Figure 3 43 Mil 50 Figure 3 44 elg aaa Na a LE 53 Figure 3 45 SELLING Baud AUC EE 53 Figure 3 46 DUN 54 Figure 3 47 ME SEE 54 Figure 3 48 EJ E 54 Figure 3 49 niam ES Te 55 Figure 3 50 PAV TOR dne s oe T 55 Figure 3 51 SSN 56 Figure 3 52 Ia IE AA EIN 56 Figure 3 53 NNN 57 Figure 3 54 La VE Te Limits Message ERE 58 Figure 3 55 ab GE AA AA 58 Figure 3 56 THDV High Limit Settings naina AKNG AN ibo ne bett 58 Figure 3 57 V3 V21 Harmonic High Limit resenerrnonoronenrneneresesseneneneresessenenenesesesssnenenesese
34. float kVArh 32 bit float kVArh 32 bit float kVArh 32 bit float kVArh 32 bit float kVArh 32 bit float kVArh 32 bit float kVArh 32 bit float kVArh 32 bit float kVArh 32 bit float kVArh 32 bit float kVArh 32 bit float Wh 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float VArh 32 bit float kVArh 32 bit float kVArh 32 bit float kVArh 32 bit float kVArh 32 bit float J D Uu A E D et e Address Parameter 604 T1_3 Ind React Prev Hour T1_3 Ind React Curr Day T1_3 Ind React Prev Day T1_3 Ind React Curr Month T1 3 Ind React Prev Month T1_3 Cap React Index T1 3 Cap React Curr Hour T1 Rate3 Inductive Reactive Previous Hour T1 Rate3 Inductive Reactive Current Day 608 610 612 614 616 618 620 622 T1 Rate3 Capacitive Reactive Previous Day 624 T1 Rate3 Capacitive Reactive Current Month 626 T1 Rate3 Capacitive Reactive Previous Month 628 Tariff 2 Import Active Index 630 Tariff 2 Import Active Current Hour 632 Tariff 2 Import Active Previous Hour 634 Tariff 2 Import Active Current Day 636 Tariff 2 Import Active Previous Day 638 Tariff 2 Import Active Current Month 640 Tariff 2 Import Active Previous Month 650 Tariff 2 Export Active Previous Day Tariff 2 Export Active Current Month 654 Tariff 2 Export Active Previous Month
35. terminal blocks and loosen their screws Figure 2 3 Loosening of Terminal Block Screws Before wiring up voltage and current ends to KLEA you must be sure that the power is cut KI FA ECT 7 Energy Analyzer SECTION 2 INSTALLATION KLEA is connected to current transformer s Before disconnecting current transformer leads be sure that they are short circuited elsewhere or connected to a parallel load which has sufficiently low impedance Otherwise dangerously high voltages will be induced at the current transformer leads Same phenomena also apply for putting into service The cable is placed into the related opening Figure 2 4 Inserting Cable into the Terminal Block After the cable is placed the screws are tightened and the cable is fixed Figure 2 5 Fixing the Cable to the Terminal Block The Terminal Block is inserted into its seat located on KLEA KI FA ev am Energy Analyzer SECTION 2 INSTALLATION If KLEA is used together with current transformers please pay attention to the following warning Threshold values for proper operation of current transformers differ according to the type and size of the transformers being used Before applying the points mentioned in the following warning please check that the measured current value is larger than the current threshold value of the current transformer Refer to manual or datasheet of the current transformer
36. up and down keys and then should press OK to select the desired option If language is selected as English other tabs within this page will also be in English Startup Settings 07 Ja 17 45 1 1 0 Startup Settings Date 07 January 2013 Time 17 45 28 CTR 1 VTR 1 0 Connection 3phase 4wire Connection 3phase 4wire Start Start Figure 3 2 Dil Language KI FA ENT 7 mu Energy Analyzer SECTION 3 MENUS 3 1 2 Date In order to change the date operator should press OK key when Date tab is highlighted Press right and left to move between day month and year entries Press up and down keys to change the values Press OK key to complete date setting Startup Settings Language English Time 17 45 28 CTR 1 VTR 1 0 Connection 3phase 4wire Start Figure 3 3 Date Example In order to enter 7 January 2013 Date 06 December 2012 BELG December 2012 69 O go DEG WOOO AS Date ya December PWE Date era January PIE NO e DE MOOD AS Date PANER A 2012 BEI FAERIT IOTER M 2013 69 e DE WOOD og Date 07 January 2013 OOOO OW Figure 3 4 Example for Setting the Date a P KI FA ev S AYA Energy Analyzer SECTION 3 MENUS 3 1 3 Time Time setting for KLEA is accomplished as explained in 3 1 2 Date menu 2 3 1 4 Current Transformer Ratio CTR In this tab current transformer ratio is entered The current transformer ratio ca
37. up and down keys to select highlight Contrast menu item Press OK key and contrast levels will appear on the screen as seen in Figure 3 21 Scroll inside contrast levels by pressing up and down keys press OK key to select the desired option Graphical LCD of KLEA darkens towards the Level 4 and lightens towards the Level 4 Settings gt Setup gt Device New password Display on Display on time Figure 3 21 Options for Contrast B 3 2 1 1 2 3 New Password Default password is 1 New password can be adjusted between 1 9999 For Virtual Keyboard Refer to 3 1 4 Example Settings gt Setup gt Device cem aa Ne P assword Display on time sel7 e fol limit High limit 9999 Figure 3 22 Entering New Password KI FA ENT 7 mu Energy Analyzer SECTION 3 MENUS E 3 2 1 1 2 4 Display on Selection e Continuous Time dependent If continuous is selected the backlight of KLEA graphical LCD will be turned on continuously If Time dependent option is selected the backlight of the graphical LCD remains open as long as display on time Settings Setup Device Language Contrast New password Display on Display on time Low limit Figure 3 23 Setting Display on Time Fo 3 2 1 1 2 5 Display on Time Display on time can be adjusted between 10 600 seconds For Virtual Keyboard Refer to 3 1 4 Example 3 2 1 1 3 Energy Menu Initial energy valuesforT1 T1 1 T1 2
38. value is 17 then there is alarm for that bit On the contrary a bit value of means that there is NO alarm for that bit The contents of alarm flag variables are listed below b7 b6 THDV1 I3 b15 b14 VLL2 VLL1 b23 b22 Q3 Q2 b31 b30 PF2 PF1 b29 Cos03 b4 11 b12 V3 Harmonics b20 P3 b28 Cos 2 Alarms 1 b3 V3 b11 V2 Harmonics b19 P2 b27 Cos01 a P b1 bo V1 Sic b9 b8 THDV3 THDV2 b17 b16 IN VLL3 b25 b24 S2 S1 NG Hn KI FA AV ma AYA Energy Analyzer b7 b6 I1 THDI3 Harmonics b15 b14 b23 b22 b31 b30 SECTION 4 MODBUS PROTOCOL Alarms 2 b5 b4 b3 b2 b1 bo THDI2 THDI1 F3 F2 F1 PF3 b13 b12 b11 b10 b9 b8 Battery Voltage 13 I2 Harmonics Harmonics O N O 1 IN O O v O co b17 b16 b29 A b28 b27 b26 O N UT 1 IN I Abbreviations used for the Alarm Flags are Temp V1 V2 V3 11 2 13 THDV1 THDV2 THDV3 V1 Harmonics V2 Harmonics V3 Harmonics VLL1 VLL2 VLL3 IN P1 P2 P3 Q1 Q2 Q3 S1 S2 3 Cos 1 Cos02 Cos03 PF1 Temperature Phase1 L N Voltage Phase2 L N Voltage Phase3 L N Voltage Phase1 Current Phase2 Current Phase3 Current Phase1 Total Harmonic Distortion in Voltage Phase2 Total Harmonic Distortion in Voltage Phase3 Total Harmonic Distortion in Voltage Phase1 Voltage Harmonics Phase2 Voltage Harmonics Phase3 Voltage Harmonics Phase1 Phase2 Voltage Phase2 P
39. value smaller than the high limit value When low limit and high limit values are entered to be the same V L N alarm will be deactivated no alarm will be set High Limit Delay High limit value for the V L N alarm For Virtual Keyboard Refer to 3 1 4 Example In order to set an alarm for V L N operator should enter a high limit value larger than the low limit value When low limit and high limit values are entered to be the same V L N alarm will be deactivated no alarm will be set When the related alarm parameter exceeds the Low limit or High Limit value before declaring an alarm Klea waits for delay time Similarly when the related alarm parameter enters into the limit values Klea waits for delay time before cancelling the alarm Delay can be adjusted between 049600 sec For Virtual Keyboard Refer to 3 1 4 Example BIEN U sec Figure 3 50 Alarm Time Setting Hysteresis It is the tolerance entered as percentage for high and low limits Hysteresis can be adjusted between 04320 For Virtual Keyboard Refer to 3 1 4 Example Examine following example and Figure 3 52 a P KI FA AV ma AYA Energy Analyzer SECTION 3 MENUS Hysteresis 0 0 Figure 3 51 Hysteresis Setting Example For the following figure Delay is adjusted to be zero At point A alarm occurs At point B alarm disappears At point C alarm occurs At point D alarm disappears Amplitud
40. 1 1 1 5 Power Unit KLEA displays total power or total energy values in two different units Kilo e Mega Inside Network menu press up and down keys to select highlight Power unit menu item When Power unit is selected press OK key and the aforementioned options will appear on the screen Press up and down keys to select the desired option and press OK key to complete the setting Po T S OTT CTR Connection 3phase Demand period 15 min Figure 3 18 Power Unit Setup e P KLEA Energy Analyzer SECTION 3 MENUS 3 2 1 1 2 Device Menu In this menu following settings can be accomplished e Language e Contrast e New Password e Display on e Display on Time SEE Measure Meters Alarms Analysis Settings gt Setup gt Device 5 0 A Contrast Level 0 New password 1 Display on Time dependent 5 0 A Display on time 600 5 0 A Figure 3 19 Device Menu D 3 2 1 1 2 1 Language Inside Device menu press up and down keys to select highlight Language menu item When Language is selected press OK key and the options in Figure 3 20 will appear on the screen Press up and down keys to select the desired option and press OK key to complete the setting Settings gt Setup gt Device Contrast New password Display on Display on time Figure 3 20 Language Selection KI FA ENT 7 mu Energy Analyzer B L M 3 MEN LER 3 2 1 1 2 2 Contrast Inside Device menu press
41. 1 Rate2 Inductive Reactive Previous Day kVArh 32 bit float 568 T1 Rate2 Capacitive Reactive Current Month kVArh 32 bit float 570 T1 Rate2 Capacitive Reactive Previous Month kVArh 32 bit float 572 T1 Rate3 Import Active Index 32 bit float 574 T1 Rate3 Import Active Current Hour 32 bit float 576 T1 Rate3 Import Active Previous Hour 32 bit float 578 T1 Rate3 Import Active Current Day 32 bit float 580 T1 Rate3 Import Active Previous Day 32 bit float 582 T1 Rate3 Import Active Current Month 32 bit float 584 T1 Rate3 Export Active Previous Month 32 bit float 586 T1 Rate3 Export Active Index 32 bit float 588 T1 Rate3 Export Active Current Hour 32 bit float 590 T1 3 Exp Act Prev Hour 32 bit float 592 T1 3 Exp Act Curr Day 32 bit float 594 T1 3 Exp Act Prev Day 32 bit float 596 T1 3 Exp Act Curr Month 32 bit float 598 T1 3 Exp Act Prev Month 32 bit float T1 3 Ind React Index VArh 32 bit float T1 3 Ind React Curr Hour VArh 32 bit float S SZ gt ar gt r gt ZE EX EX SE E 2 T1 Rate3 Export Active Previous Hour Z 2 T1 Rate3 Export Active Current Day Z c T1 Rate3 Export Active Previous Day T1 Rate3 Export Active Current Month SE gt T1 Rate3 Export Active Previous Month T1 Rate3 Inductive Reactive Index Z 2 i p BH 602 T1 Rate3 Inductive Reactive Current Hour KI FA ENT 7 uu Energy Analyzer SECTION 4 MODBUS PROTOCOL R W Unit Data Type kVArh 32 bit
42. 164 L2 PF Phase2 power factor 32 bit float 166 L2F 32 bit float L2 THDV 32 bit float I Phase2 frequency Z Phase2 total har distortion of voltage p O EA ENT 7 mu Energy Analyzer SECTION 4 MODBUS PROTOCOL R W Unit Data Type 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float J D Uu A E Le et o Address Parameter 170 Phase2 total har distortion of current 172 174 176 178 L2 THDI L2 V Harmonics1 L2 V Harmonics3 L2 V Harmonics5 L2 V Harmonics7 L2 V Harmonics9 Phase2 voltage 9th harmonic Phase2 voltage 11th harmonic 192 Phase2 voltage 21st harmonic Phase2 voltage 23rd harmonic Phase2 voltage 25th harmonic 198 Phase2 voltage 27th harmonic L2 V Harmonics29 Phase2 voltage 29th harmonic L2 V Harmonics31 Phase2 voltage 31st harmonic Phase2 voltage 33rd harmonic Phase2 voltage 35th harmonic 216 L2 V Harmonics45 Phase2 voltage 45th harmonic L2 V Harmonics47 Phase2 voltage 47th harmo
43. 2 Alarm ID 2 Alarm ON Alarm OFF status 2 Value of related alarm parameter 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 5 5 8 8 5 8 5 d de 299 dN 5 ie 5 5 5 5 3 8 5 8 3 8 5 8 3 e p C KI FA ENT 7 mu Energy Analyzer SECTION 4 MODBUS PROTOCOL R W Unit Data Type 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time J D Uu A E Le et o Address Parameter 978 3 Alarm ID 980 3 Alarm Status 3 Alarm ID 3 Alarm ON Alarm OFF status 3 Value of related alarm parameter 982 3 Alarm Value 984 4 Alarm Timestamp 4 Alarm time 986 4 Alarm ID 4 Alarm ID 988 4 Alarm Status 4 Alarm ON Alarm OFF status 990 4 Alarmvalue 4 Value of related alarm parameter 99 5 Atar
44. 2 14 53 15 F 16 IN 17 V12 18 V23 19 V31 20 tot 21 P tot 22 O tot 23 S tot SL6 0 Off 1 Relay1 2 Relay2 KI FA ENT 7 mu Energy Analyzer SECTION 4 MODBUS PROTOCOL EXAMPLE If slave ID is assigned as 157 Request KLEA Response Slave ID 01h Slave ID 01h Function code 10h Function code 10h Starting address high 08h Starting address high 08h Starting address low 26h Starting address low 26h Number of registers high 00h Number of registers high 00h Number of registers low 02h Number of registers low 02h Number of bytes 04h CRC high A2h Register value high 00h CRC low 63h Register value low 00h Register value high 00h Register value low 9Dh CRC high D7h CRC low F4h 4 5 3 ARCHIVE HISTORY RECORDS Archive records consist of blocks having 68 parameters Each parameter inside the archive block is a 32 bit length variable Archive data block is as shown in Table 4 7 The programmer will access archive by implementing 0x14 Read File Record function 0x14 Read File Record function accesses the data with file numbers For Klea File numbers 1 1920 are used to access HOURLY data File numbers 5001 5240 are used to access DAILY data File numbers 10001 10036 are used to access MONTHLY data e The last saved file number in the hourly data memory can be accessed from 1360 Modbus addressed parameter Refer to Table 4 4 e The last saved file number i
45. 2 1 1 5 3 OUTPUTS Menu optional srererororersvsrrrsvsnsnrnsrsrensserereneneneneneneneneneneneneseneseeee 46 3 2 1 1 5 4 Output4 Menu optional srsrerorerersnsrsrsvrnersvsrsrenenererenenenenenenensnsneneneneseneseee 46 3 2 1 1 5 5 OUTPUTS Menu optional srerersrorsrsvsrrrsvsnsrensnsrersserereneneneneneneneseneneneneseneseeee 46 3 2 1 1 5 6 Output6 Menu optional sss sese 46 3 2 1 1 5 7 Output7 Menu optional sss 46 3 2 1 1 6 Analog Output Menu Optional sss sss sese 46 3 2 1 1 6 1 TN e E 47 3 2 1 1 6 1 1 FUE TAOS eT eee 48 3 2 1 1 6 1 2 EE et deen aar eT 49 3 2 1 1 6 1 3 MANE ee E E 50 3 2 1 1 6 1 4 ED VEE 50 KI FA AV ma AYA Energy Analyzer 3 2 1 1 6 1 5 3 2 1 1 6 2 3 2 1 1 6 3 3 2 1 1 6 4 3 2 1 1 7 32 e 3 2 1 1 7 2 3 2 1 1 8 3 2 1 1 8 1 B Zu B 3 2 1 1 8 3 3 2 1 1 8 4 3 2 1 1 8 5 3 2 1 1 8 6 3 2 1 1 8 7 3 2 1 1 8 8 3 2 1 1 8 9 3 2 1 1 8 10 3 2 1 1 8 11 3 2 1 1 8 12 3 2 1 1 8 13 3 2 1 1 9 3 2 1 2 5 25159 3 2 1 4 3 2 1 5 3 2 1 6 3 2 2 WPA 5222 3 2 2 2 1 3 2 2 2 1 1 3 2 2 2 1 2 Dd A 3 2 2 2 1 4 K 3 2 2 2 3 32224 3 2 2 3 3 2 2 4 3 2 2 5 3 2 2 5 1 3 2 2 5 2 3 2 3 3 2 3 1 3 2 3 1 1 VET s Te GN 50 UMN 52 NN 53 NINE 53 Communication Nene 53 Baud Rate NEN ene 53 Sarai AA 54 NNN 54 VEN ME 54 VED NM 56 Current Menu arianen 56 a v 56 Siu MEC 56 SANG GGSS
46. 2 bit int TET xm mghumt zit 3 foey TRR Hysteresis 32 bit float APPARENT POWER ALARM Alarm Relay 32 bit int 2142 High Limit 32bitfloat 2146 Hysteresis 32bitfloat e P R W SEE 2 2 W W W R W R W R W R W sec sec LEN DEREN sec sec sec V sec sec A A sec sec Ar Ar sec A A sec o EJ HESS NE 0 ENS EJ EJ 0 0 Lo LO Lo 0 0 ERI DS pl 0 0 1 00E 10 1 00E 10 0 0 1500000 1500000 2600000 2600000 30000 30000 1 00E 10 1 00E 10 0 0 0 0 1 00E 10 sc 1 00E 10 20 KIEA ENT 7 ow Energy Analyzer SECTION 4 MODBUS PROTOCOL Address Parameter Data Type Descript R W Unit Low Limit High Limit NEUTRAL CURRENT ALARM 2148 Alarm Relay 32 bit int SL6 R W aso T tite RW A Lm um een ew Ja R W 2 30000 30000 SE Li N Hysteresis 32 bit float POWER FACTOR ALARM Alarm Relay 32 bit int o O law me manus o xbox law ne joey 32bem RW m R W Hysteresis 32 bit float COS ALARM Alarm Relay 32 bit int a E PAGA E Lawa emu Re law Hysteresis 32 bit float R W FREQUENCY ALARM Alarm Relay 32 bit int SL6 aso uowuimit T ow fz 2182 mighumt 2zbrfom RW ve Hysteresis 32 bit float R W 96 TEMPERATURE ALARM Alarm Relay 32 bit int LEN Lnd sec Bad
47. 50 49 Alarm Value 49 Value of related alarm parameter 1352 50 Alarm Timestamp 50 Alarm time 1354 1356 50 Alarm Status 50 Alarm ON Alarm OFF status 1358 50 Alarm Value 50 Value of related alarm parameter 1360 Hourly Archival File Nr Latest recorded hourly archival file number 1362 Daily Archival File Nr Latest recorded daily archival file number 1364 Monthly Archival File Nr Latest recorded monthly archival file number 4 5 1 1 47 Alarm Status 47 Alarm Value SECTION 4 MODBUS PROTOCOL J D Uu A E Le er o 47 Alarm ON Alarm OFF status 47 Value of related alarm parameter 48 Alarm Timestamp 48 Alarm time 48 Alarm ID 48 Alarm ID 48 Alarm Status 48 Alarm Value 48 Alarm ON Alarm OFF status 48 Value of related alarm parameter 49 Alarm Timestamp 49 Alarm time 50 Alarm ID 49 Alarm ID 50 Alarm ID LAST SAVED FILE NUMBERS R W Unit Data Type 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit int 32 bit int 32 bit int Unix time Unix time is the number of seconds elapsed since midnight 00 00 Coordinated Universal Time UTC of January 1 1970 not counting leap seconds Alarm Flags Each bit of an alarm flag variable corresponds to one alarm flag If any bit s
48. 59 Figure 3 58 GE 59 Figure 3 59 Sea EE 60 Figure 3 60 MT 60 Figure 3 61 Initial Value After Clear Process sss 60 Figure 3 62 PENT 61 Figure 3 63 DY SHINY Ta 61 Figure 3 64 FE SV ON HE 62 Figure 3 65 Seg ee ne ee ee 62 Figure 3 66 Default Settings Command sss 63 Figure 3 67 Me 63 Figure 3 68 Instantaneous MENU aaa NAG emerit 64 Figure 3 69 Connecting the K L ends of Current Correctly sss 65 Figure 3 70 Demana s eise tono tme umi itta d 65 Figure 3 71 Demana ae AA 65 Figure 3 72 ENN 66 Figure 3 73 Example of Current Month Menu sersrsssessrssnssessrnesessrsssessessnssssssnssessenenene 66 Figure 3 74 ali MENU 67 Figure 3 75 aate Diagrami dU NT 69 Figure 3 76 Sela MEN NEN AA 69 Figure 3 77 Harmonics MONU m 70 Figure 3 78 Harmonics in Table Format seserernonononevrernenensveversenenessvssersenenenssssesnenensnssssnsee 70 Figure 3 79 Harmonics in Graphical FOrmiat cccesesscsssssssesssssssssssessssesssssessssessseseees 71 a P KI FA AV ma AYA Energy Analyzer Figure 3 80 Figure 3 81 Figure 3 82 Figure 3 83 Figure 3 84 Figure 3 85 Figure 3 86 Figure 3 87 Figure 3 88 Figure 3 89 Figure 3 90 Figure 3 91 Figure 3 92 Figure 3 93 Figure 3 94 Figure 3 95 Figure 3 96 Figure 4 1 Figure 4 2 TABLES Table 4 1 Table 4 2 Table 4 3 Table 4 4 Table 4 5 Table 4 6 Table 4 7 Table 4 8 FINE 71 MP Active
49. 6 U U The start times should be different from each other Otherwise T1 1 T1 rate1 TI 2 T1 rate 2 and T1 3 T1 rate3 meters will not operate KI FA AV ma AYA Energy Analyzer SECTION 3 MENUS 3 2 1 1 3 4 Start of day Start of day can be adjusted between 0 23 for Virtual Keyboard Refer to 3 1 4 Example 3 2 1 1 3 5 Start of month Start of month can be adjusted between 1 28 for Virtual Keyboard Refer to 3 1 4 Example The settings listed below between 3 2 1 1 3 6 and 3 2 1 1 3 25 are used to synchronize the system electric meter and KLEA meter Each of the below items can be adjusted between 0 000420000000000 0 for Virtual Keyboard Refer to 3 1 4 Example Klea meters calculate energy by multiplying with CTR and VTR values User should take this fact into account when entering the below intial energy values 3 2 1 1 3 6 T1 kWh Initial value for import active energy of T1 can be entered in this tab 3 2 1 1 3 7 T1 kWh E Initial value for export active energy of T1 can be entered in this tab 3 2 1 1 3 8 T1 kVArh I Initial value for inductive reactive energy of T1 can be entered in this tab 3 2 1 1 3 9 T1 kVArh C Initial value for capacitive reactive energy of T1 can be entered in this tab 3 2 1 1 3 10 T1 1 kWh Initial value for import active energy of T1 1 can be entered in this tab 3 2 1 1 3 11 T1 1 kWh E Initial value for export active energy of
50. 600000 0 Low Limit High Limit CURRENT Low Limit High Limit 0 0 30000 0 0 0 30000 0 10000000000 0 10000000000 0 10000000000 0 10000000000 0 Low Limit High Limit VAr 10000000000 0 10000000000 0 VAr 10000000000 0 10000000000 0 Low Limit High Limit 0 010000000000 0 0 0 10000000000 0 Low Limit High Limit Cos 0 000 1 000 0 0004 1 000 Low Limit High Limit 0 000 1 000 0 000 1 000 Low Limit High Limit 0 0 90000 0 0 090000 0 Low Limit High Limit Low Limit 3570 N 9 P KLEA energy Analyzer FACTORY DEFAULT SETTINGS Default value Unit Setting Range Temp High Limit PH MHammonis 0000 THDHighlimt oo 96 0041000 3 121 a a ar eee Alarm Relay and Alarm Time of V L N V L L Current P Q S Cos PF IN F V Harmonics Harmonics and Temp alarms Alarm Relay 0f OffflyMReay aiae of w oegoo Alarm Time for V 0600 Harmonics Hysteresis of V L N V L L Current P Q S Cos PF IN F V Harmonics Harmonics and Temp alarms KI FA ev am Energy Analyzer TECHNICAL SPECIFICATIONS TECHNICAL SPECIFICATIONS Supply Voltage 85 300V AC DC Frequency 45 65 Hz Measurement Inputs Voltage 1 300 V RMS L N Current 0 05 6 ARMS Frequency 45 65 Hz Measurement Accuracy Current lt 0 3 Voltage lt 0 3 Active power lt 0 5 Reactive power lt 0 5 Apparent power l
51. Basang so E E sec LM LN sec C sec w oa 2 UN C C ab ab ab ao pum Hysteresis 32 bit float R W VOLTAGE HARMONICS ALARM Alarm Relay 32 bit int mm pm EE gt 2 2 5 2 5 5 2222 Delay 32 bit int R W sec 600 a P SEE KLEA Energy Analyzer SECTION 4 MODBUS PROTOCOL Address Parameter Data Type Descript R W Unit Low Limit High Limit CURRENT HARMONICS ALARM 2224 Alarm Relay 32 bit int SL6 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 2226 2228 2230 2232 2234 2236 2238 PS THDI High Limit 13 High Limit I5 High Limit I7 High Limit I9 High Limit 111 High Limit 113 High Limit 2240 115 High Limit 32 bit float 2242 117 High Limit 32 bit float DEVICE SETTINGS 2254 Password 2256 Display on SL9 E 90 PS Yo 9999 2258 Display on Time 2260 Serial Number 2262 Firmware Version 2264 Compiler Version 2266 Config Name 2278 Device Name DIGITAL OUTPUT SETTINGS OPTIONAL Output3 Mode RW Output3 Energy RW Output3 Width RW msec Output3 Multiplier RW fD O D e e 2290 2292 2294 2296 2298 2300 2302 2304 2306 2308 2310 2312 2314 IE 1 10000000000 2500 10000 5 Output4 Energy 32 bit float RW 1 10000000000 2500 10000 2 DD e Output4 Width 32 bit int RW msec Output4 Mode 32 bi
52. GS SL3 SL3 9 DIGITAL OUTPUT SETTINGS NNNHN Unit Low Limit High Limit min hour hour hour hour W kWh my kWh 3 msec msec 5 5 0 0 N NJ N N N 5000 5000 NO N Ww IUU UO 20000000000 0 20000000000 0 20000000000 0 20000000000 0 20000000000 0 20000000000 0 20000000000 0 20000000000 0 20000000000 0 20000000000 0 20000000000 0 20000000000 0 20000000000 0 20000000000 0 20000000000 0 20000000000 0 20000000000 0 20000000000 0 20000000000 0 20000000000 0 10000000000 2500 10000 20 10000000000 2500 10000 KIEA ENT 7 ow Energy Analyzer SECTION 4 MODBUS PROTOCOL DIGITAL INPUT SETTINGS COMMUNICATION ALARMS VOLTAGE L N ALARM Address Parameter Data Type Descript R W 2 SEE Unit Low Limit High Limit msec msec 2 2000 2 2000 5 247 2088 Alarm Relay 32 bit int SL6 2092 High Limit 32bitfloat Hysteresis 32bitfloat VOLTAGE L L ALARM Alarm Relay 32 bit int 2102 High Limit 32bitfloat Oo Hysteresis 32 bit float CURRENT ALARM Alarm Relay 32 bit int 2112 High Limit 32 bit float SL6 SL6 Hysteresis 32 bit float ACTIVE POWER ALARM Alarm Relay 32 bit int SL6 zuo H E oat aaa foey 22bem Hysteresis 32 bit float REACTIVE POWER ALARM SL6 SL6 Alarm Relay 3
53. If the entered password is correct Login success message appears on the screen Otherwise Password mismatch message will be displayed on the screen For Virtual Keyboard Refer to 3 1 4 Example ETIE Measure Meters Alarms Analysis 5 0 A 5 0 A Login required Login success Password mismatch 9 0 A Figure 3 64 Password 5 3 2 1 5 Restart Menu If OK key is pressed on the restart tab Are you sure message appears on the screen Press again OK key to restart Klea EE Measure Meters Alarms Analysis Setup Date Time A System info o 0 Password Restart Default settings 5 0 A 9 0 A Are you sure Figure 3 65 Restart KI FA ENT 7 mu Energy Analyzer SECTION 3 MENUS E 3 2 1 6 Default Settings This menu is used to return to factory default settings All settings except date and time return to the factory defaults Note Tariff meter indexes are not assumed to be a setting As a result index values will not be cleared via this menu ETES Measure Meters Alarms Analysis 0 0 A 5 0 A Default settings will be assigned Are you sure O 5 0 A Figure 3 66 Default Settings Command B 3 2 2 Measure Menu The following submenus are included under the measure menu Operator can navigate inside measure menu by up and down keys When the desired menu item is highlighted press OK key to select Following menu items are available Instantaneous e Demand Pha
54. MODBUS RTU protocol Starting address for measured and calculated data is O Example Three phase average voltage is read via the Oth and 1th registers 16 bits 16 bits 32 bit PC or PLC Request Slave ID 01h Function code 03h Register address high 00h Register address low 00h Number of registers high 00h Number of registers low 02h CRC high C4h CRC low OBh The Byte counts information of KLEA response is two times Number of registers value of PC request 1 register 2 bytes Register value high 0 and low 0 together with register value high 1 and low 1 constitute a 32 bit value This value should be converted typecasted to a float value KLEA Response Slave ID Function code Byte counts Register value high 0 Register value low 0 Register value high 1 Register value low 1 CRC high CRC low The float value of the mentioned 32 bit variable is 221 2143555 01h 03h 04h 43h 5DH 36H EOh 68h 4Dh KI FA ENT 7 mu Energy Analyzer SECTION 4 MODBUS PROTOCOL Table 4 4 Read only Data Address Parameter Description R W Unit Data Type 10 Average Cos of three phases 32 bit float 12 Average PF of three phases 32 bit float 1 Voltage V1 2 32 bit float Voltage V2 3 32 bit float Voltage V3 1 32 bit float Average of line to line voltage of three phases 32 bit float Neutral current 32 bit float THDV tot Total har distortion of v
55. N 1 GENERAL INFORMATION e KLEA has 1st tariff and 2nd tariff meters These meters record Imp Active Exp Active Inductive Reactive and Capacitive Reactive energy values There is an isolated RS485 port in KLEA e KLEA 1st Tariff and 2nd Tariff energy values can be assigned to digital outputs e It has 2 pieces of relay outputs Besides KLEA has numerous features such as Setting alarms for various measurement parameters e Monitoring official energy meters by means of assigning initial values for Klea tariff meters e Compatibility for 3 phase 3 wire 3 phase 4wire or aron connected systems e Avoiding unauthorized control by a 4 digit password KLEA Energy Analyzer has 2 programmable alarm relay outputs 2 digital outputs totally 7 pieces in optional digital IO model 2 digital input totally 7 pieces in optional digital IO model 1 piece of RS 485 communication port 2 4 analog outputs optional battery supported real time clock and memory e There are 6 keys and 160x240 graphical LCD on the front panel By means of them device settings and monitoring of measurement values can easily be accomplished 1 5 KleaCom Software Operator can remotely reach a Klea device via KleaCom software KleaCom software can communicate with only one Klea at the same time operator can reach other Klea devices on the same network by changing the slave ID All measured calculated parameters can be monitor
56. Normal Normal Normal Normal Normal Normal V harmonics THDV harmonics THDI F Figure 3 91 Phase1 Menu In Phase1 menu following alarm statuses are monitored V phase neutral voltage e current P active power Q reactive power S apparent power e cos PF power factor V harmonics any of 3 5 21 harmonic alarm statuses ORed THDV total harmonic distortion in voltage harmonics any of 3 5 21 harmonic alarm statuses ORed THDI total harmonic distortion in current Phase2 Menu Phase2 menu consists of the same items as Phase1 menu Please refer to 3 2 4 1 Phase1 menu for details Phase3 Menu Phase3 menu consists of the same items as Phase1 menu Please refer to 3 2 4 1 Phase1 menu for details KI FA ENT 7 mu Energy Analyzer SECTION 3 MENUS 3 2 4 4 Other Menu In Other menu explanations are the same as in Phase1 menu Alarms gt Other Normal Normal Alarm Temperature Normal Battery Normal Figure 3 92 Other Menu In Other menu following alarm statuses are monitored e VLL12 phase1 phase2 voltage e VLL23 phase2 phase3 voltage e VLL31 phase3 phase1 voltage IN neutral current e Temperature e Battery When the battery voltage falls below 1 9 V value Klea issues Battery alarm When Klea issues battery alarm contact your local authorized dealer or the nearest authorized de
57. Output1 Output5 generates pulse from DO5 and DO5 pins gt 3 2 1 1 5 6 Output6 Menu optional Output 6 applications and settings are the same as Output1 Output6 generates pulse from DO6 and DO6 pins 2 3 2 1 1 5 7 Output7 Menu optional Output 7 applications and settings are the same as Output1 Output7 generates pulse from DO7 and DO7 pins 5 3 2 1 1 6 Analog Output Menu Optional EE Measure Meters Alarms Analysis Output1 Output4 9 0 Communication 5 0 A Figure 3 37 Analog Output Menu KLEA has two different optional analog output models 2 analog output and 4 analog output models KI FA ENT 7 mu Energy Analyzer SECTION 3 MENUS Operator can adjust KLEA to give output from analog output channels for the following parameters voltage current active power reactive power apparent power frequency phase phase voltages neutral current total current total active power total reactive power and total apparent power pertaining to L1 L2 L3 phases Analog output channels can be adjusted to generate signals as 0 5V 0 10V 5 5V 10 10V 0 20mA 4 20mA Analog output menu comprises of the following submenus Output1 available in 2 analog and 4 analog outputs models Output2 available in 2 analog and 4 analog outputs models Output3 available only in 4 analog outputs model Output4 available only in 4 analog outputs model E 3 2 1 1 6 1 Output1 Menu Output1 menu comprises of the fo
58. W AO3 Input Mode SL10 SEE 2 100000 100000 100000 100000 2372 2374 2376 2378 2380 2382 AO3 Max Value RW A03 Min Value RW AO3 Multiplier SL12 RW AO4 Input Mode SL10 RW AO4 Output Conn SL11 RW 2384 AO4 Max Value RW 100000 100000 2386 AO4 Min Value 100000 100000 oo lam gym a2 mw ol 2 SAVE CHANGES TO PERMANENT MEMORY Write 1 198 rr Aa a a aaa 100000 100000 100000 100000 2370 AO3 Output Conn SL11 SEE 2 Valid for devices with optional Digital I O Valid for devices with optional Analog Output ar KI FA ANT T AYA Energy Analyzer SL1 0 3phase 4wire 1 3phase 3wire 2 Aron 0 Turkce 1 English 2 Pycckun SL2 0 Mega 1 Kilo 0 Level 4 1 Level 3 2 Level 2 3 Level 1 4 Level 0 5 Level 1 6 Level 2 7 Level 3 8 Level 4 SECTION 4 MODBUS PROTOCOL Table 4 6 Description List SL3 0 Off 1 kWh 1 2 kWh E 1 3 kVArh Cap 1 4 kVArh Ind 1 5 kWh 1 1 6 kWh E 1 1 7 kVArh Cap 1 1 8 kVArh Ind 1 1 9 kWh1 2 10 kWh E 1 2 11 kVArh Cap 1 2 12 kVArh Ind 1 2 13 kWh 1 3 14 kWh E 1 3 15kVArh Cap 1 3 16 kVArh Ind 1 3 17 kWh 2 18 kWh E 2 19 kVArh Cap 2 20 kVArh Ind 2 21 Digital Input 0 Continuous 1 Time Dependent SL4 0 Off 1 2nd tariff 2 Counter 0 V1 L N 1 V2 L N 2 V3 L N 3 11 4 12 5 13 6 P1 7 P2 8 P3 9 Q1 10 Q2 11 Q3 12 51 13 5
59. Wh 32 bit float kWh 32 bit float kWh 32 bit float kWh 32 bit float kWh 32 bit float kWh 32 bit float kWh 32 bit float kWh 32 bit float kWh 32 bit float J D Uu A D et o Address Parameter 516 518 520 522 524 526 528 530 532 T1 2 Imp Act Index T1 2 Imp Act Curr Hour T1 Rate2 Import Active Index T1 Rate2 Import Active Current Hour T1 2 Imp Act Prev Hour T1 Rate2 Import Active Previous Hour T1 2 Imp Act Current Day T1_2 Imp Act Prev Day T1 2 Imp Act Curr Month T1 2 Exp Act Prev Month T1 2 Exp Act Index T1 2 Exp Act Curr Hour T1 Rate2 Import Active Current Day T1 Rate2 Import Active Previous Day T1 Rate2 Import Active Current Month T1 Rate2 Export Active Previous Month T1 Rate2 Export Active Index T1 Rate2 Export Active Current Hour 534 T1 2 Exp Act Prev Hour T1 Rate2 ExportActive Previous Hour kWh 32 bit float 536 T1 2 Exp Act Curr Day T1 Rate2 Export Active Current Day kWh 32bitfloat 538 T1 2 Exp Act Prev Day T1 Rate2 Export Active Previous Day kWh 32bitfloat kWh 32 bit float kWh 32 bit float kVArh 32 bit float kVArh 32 bit float kVArh 32 bit float kVArh 32 bit float 540 T1 Rate2 Export Active Current Month 542 T1 Rate2 Export Active Previous Month 544 T1 Rate2 Inductive Reactive Index 546 T1 Rate2 Inductive Reactive Current Hour 548 T1 Rate2 Inductive Reactive Previous Hour 550 T1 Rate2 Inductive Reactive Current Day T
60. al S time 3 Months Ago Total Apparent Power Timestamp 3 months ago L1 P 3 Months Ago Phase 1 Active Power 3 months ago L1 P time 3 Months Ago Phase 1 Active Power Timestamp 3 months ago L1 3 Months Ago Phase 1 Current 8 3 months ago L1 I time 3 Months Ago Phase 1 Current Timestamp 32 bit unix time 90 3 months ago L1 Q 3 Months Ago Phase 1 Reactive Power VAr 32 bit float 3 months ago L1 Q time SION Md m 32 bit unix time Timestamp 904 3monthsagoLiS 3Months Ago Phase 1 Apparent Power 3 months ago L1 S 3 Months Ago Phase 1 Apparent Power RO VA 32 bit float 904 906 3 months ago L1 S time Sons N90 A Aa DH 32 bit unix time Timestamp 32 bit unix time 32 bit float 32 bit unix time gt 8 8 8 8 888 90 92 94 96 32 bit float 98 e P KI FA ENT 7 mu Energy Analyzer SECTION 4 MODBUS PROTOCOL Address Parameter Description R W Unit Data Type 3 months ago L2 P 3 Months Ago Phase 2 Active Power W 32 bit float 3 months ago L2 P time 3 Months Ago Phase 2 Active Power Timestamp 32 bit unix time 32 bit float 32 bit unix time 32 bit float 912 3 months ago L2 3 Months Ago Phase 2 Current 3 months ago L2 time 3 Months Ago Phase 2 Current Timestamp VAr 3 months ago L2 Q 3 Months Ago Phase 2 Reactive Power 3 months ago L2 Q time 3 Months Ago Phase 2 Reactive Power Timestamp 3 months ago L2 S 3 Months Ago Phase 2 Apparent Power 3 Months Ago Phase 2 Apparent Power T
61. aler B 3 2 5 Analysis Menu It consists of submenus shown in Figure 3 93 Analysis menu parameters can also be reached from MODBUS Refer to 4 5 3 Archive Records Figure 3 93 Analysis Menu Analysis menu parameters are not stored in permanent memory As a result all of analysis menu parameters will be cleared when Klea is turned off KI FA ENT 7 mu Energy Analyzer 3 2 5 1 Minimum Menu SECTION 3 MENUS It consists of hourly daily and monthly submenus 3 2 5 1 1 Hourly Menu Maximum Daily Average Monthly Energy V2 220 0 ve 220 0v B y Figure 3 94 Minimum Menu This menu displays the minimum instantaneous values measured calculated from the beginning of current hour up to present time 3 2 5 1 1 1 Phase1 Menu Minimum Hourly Maximum Daily Phase2 Average Monthly Phase3 Energy Other vz 220 0Vv 2 5 0 A Phase1 220 0v 8 0 04 Y Figure 3 95 Hourly Menu Voltage V current l active power P reactive power Q apparent power S cos power factor PF and frequency F values are displayed 3 2 5 1 1 2 Phase2 Menu Voltage V current l active power P reactive power Q apparent power S cos power factor PF and frequency F values are displayed 3 2 5 1 1 3 Phase3 Menu Voltage V current l active power P reactive power Q apparent power S cos power factor PF and frequency F values are displayed e P KI FA AV ma AYA E
62. amp 1066 1068 1070 1072 15 Alarm time D 25 Alarm time KI FA ENT 7 mu Energy Analyzer SECTION 4 MODBUS PROTOCOL R W Unit Data Type 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time J D Uu A Le er e Address Parameter 25 Alarm ID 25 Alarm ON Alarm OFF status 25 Value of related alarm parameter 25 Alarm ID 25 Alarm Status 25 Alarm Value 26 Alarm Timestamp 1162 26 Alarm ID 26 Alarm ID 1164 26 Alarm Status 26 Alarm ON Alarm OFF status 26 Value of related alarm parameter Ta 27 AlarmTimestamp Z Mam me 1176 28 Alarm time 28 Alarm ON Alarm OFF status 1182 28 Value of related alarm parameter 1184 29 Alarm time 1186 29 Alarm ID 1188 29 Alarm ON Alarm OFF status 29 Value of related alarm parameter 1200 31 Alarm time 1204 31
63. be adjusted between 041 3 2 1 1 8 9 IN Menu Alarm for neutral current is adjusted in this submenu Neutral current settings are the same as V L N Low and high limit values can be adjusted between 0490000 3 2 1 1 8 10 F Menu Alarm for frequency is adjusted in this submenu Frequency settings are the same as V L N Low and high limit values can be adjusted between 35070 3 2 1 1 8 11 Temp Menu Alarm for temperature is adjusted in this submenu Temperature settings are the same as V L N Low and high limit values can be adjusted between 204980 When the low and high limit values are entered the same KLEA will not issue an alarm Settings gt Setup gt Alarm gt Current Low limit High limit Delay Hysteresis Figure 3 53 Setting for No Alarm a P KI FA AV ma AYA Energy Analyzer SECTION 3 MENUS When operator enters a low limit value larger than the high limit Invalid limits Please check message appears on the screen Settings 5 Setup 5 Alarm 5 Current Alarm rela Relay1 Low limit 0 0 IM High limit d Invalid limits Delay 0 0 Please check Hysteresis 0 0 Figure 3 54 Invalid Limits message 3 2 1 1 8 12 Harmonics V Menu Inside Alarm menu when Harmonics V is highlighted press OK key and the following page will appear on the screen Settings gt Setup gt Alarm gt Harmonics V THDV hi limit 0 0 V3 hi limit V5 hi limit V7 hi limit V9 hi limit O V11 hi limit
64. d period 15 minutes Figure 3 71 Demand Example e P KI FA ENT 7 mu Energy Analyzer SECTION 3 MENUS 3 2 2 2 1 Current Month Menu This menu displays demand values of current active reactive and apparent power of three phases and their totals for the current present month Meters Alarms Analysis 4 Meters Alarms Analysis da Instantaneous Tass Instantaneous Demand Demand 1 month ago Act power i Phasor diagram 2 months ago Rea power Signals App power Harmonics Figure 3 72 Current Month Menu Start of day and start of month settings are adjusted in Settings gt Setup gt Energy menu Start of day and start of month are important for Curr Month 1 month ago 2 months ago and 3 months ago submenus Example Assume that start of day is 87 and start of month is 26 When time is 08 00 on 26th day of the month Current month values will be assigned as 9 1 month ago values 1 month ago values will be assigned as gt 2 months ago values 2 months ago values will be assigned as gt 3 months ago values And new values will be saved in current month menu Settings Setup gt Energy T1 1 start time 8 T1 2 start time 16 T1 3 start time U Start of day Start of month T1 kWh T1 kWh E T1 kVArh I T1 kVArh C T1 1 kWh T1 1 kWh E T1 1 kVArh I Figure 3 73 Example of Current Month Menu KI FA AV ma AYA Energy Analyz
65. e High limit RN L L oer Sar eae ee ae ee ee ee ee eee ee a ae ee ee Waveform Hysteresis EE ED JA Low limit A 7 Time Figure 3 52 Alarm Example 3 2 1 1 8 2 V L L Menu Alarm for phase to phase voltages is adjusted in this submenu V L L settings are the same as V L N Low and high limit values can be adjusted between 042600000 3 2 1 1 8 3 Current Menu Alarm for current is adjusted in this submenu Current settings are the same as V L N Low and high limit values can be adjusted between 04430000 3 2 1 1 8 4 P Menu Alarm for active power is adjusted in this submenu P settings are the same as V L N Low and high limit values can be adjusted between 10000000000610000000000 3 2 1 1 8 5 Q Menu Alarm for reactive power is adjusted in this submenu Q settings are the same as V L N Low and high limit values can be adjusted between 10000000000610000000000 e P KI FA ev S AYA Energy Analyzer SECTION 3 MENUS 3 2 1 1 8 6 S Menu Alarm for apparent power is adjusted in this submenu S settings are the same as V L N Low and high limit values can be adjusted between 0 0610000000000 3 2 1 1 8 7 Cos Menu Alarm for cos is adjusted in this submenu cos settings are the same as V L N Low and high limit values can be adjusted between 0 1 3 2 1 1 8 8 PF Menu Alarm for power factor is adjusted in this submenu Power factor settings are the same as V L N Low and high limit values can
66. e 3 41 Vout gt ON lout1 gt OFF After the dip switch adjustment setting will be completed vi rELRLDELLE 55553555 S S SS ZE Z gt T2 C M OY R E Figure 3 41 Vout1 gt ON lout1 gt OFF Assume that for analog output 1 output connection was selected as 4 20 mA refer to Figure 3 40 Then operator should adjust the analog output 1 dip switch as seen in Figure 3 42 Vout1 gt OFF lout1 gt ON After the dip switch adjustment setting will be completed o dig lt 3 lt 3 lt 5 lt Go VPA PAPA Q C aG a CAR EC 2 to M W ga Figure 3 42 Vout1 gt OFF lout1 gt ON a P KI FA ENT 7 mu Energy Analyzer SECTION 3 MENUS In order to obtain voltage output Vout1 should be set to ON and lout1 should be set to OFF If both switches are ON or OFF at the same time analog output will not operate correctly In order to obtain current output Vout1 should be set to OFF and lout1 should be set to ON If both switches are ON or OFF at the same time analog output will not operate correctly If the setting of output connection and setting of the dip switch are incompatible related analog output will not operate correctly 3 2 1 1 6 1 3 Min value The minimum value for the selected input mode See also 3 2 1 1 6 1 5 Multiplier setting 3 2 1 1 6 1 4 Max value The maximum value for the selected input mode See also 3 2 1 1 6 1 5 Multiplier setting If Min value and Max value are
67. ear on the screen Press up and down keys to select the desired option and press OK key to complete the setting EE Measure Meters Alarms Analysis Communication Alarm Clear Harmonics V Harmonics Temp Figure 3 47 Alarm Menu F 3 2 1 1 8 1 V L N Menu Inside Alarm menu when V L N is highlighted press OK key and the following page will appear on the screen Settings gt Setup gt Alarm gt V L N Low limit High limit Delay Hysteresis Figure 3 48 V L N Menu a P KI FA AV ma AYA Energy Analyzer SECTION 3 MENUS Alarm relay This setting is merely used to energize or not to energize a relay when an alarm occurs For alarm relay setting following options are available Off In case of V L N alarm none of the alarm relays is energized Relay1 In case of V L N alarm relay 1 is energized Relay2 In case of V L N alarm relay 2 is energized Press up and down keys to select the desired option and press OK key to complete the setting Alarm relay Off Figure 3 49 Alarm Relay Setup In order to adjust Klea to issue V L N alarms operator should adjust low limit and high limit values as described below When V L N of any of the three phases exceeds Low limit or High Limit Klea gives an alarm Low Limit Low limit value for the V L N alarm For Virtual Keyboard Refer to 3 1 4 Example In order to set an alarm for V L N operator should enter a low limit
68. ears all namely demand energy and DI counter values When Clear is highlighted press OK key and the following page will appear on the screen EE Measure Meters Alarms Analysis Are you sure Communication Alarm L y V O Figure 3 58 Clear Menu Scroll inside options by pressing up and down keys press OK key to clear the desired option When OK key is pressed Are you sure message will appear on the screen Press again OK key to clear the parameter press X key to exit with no change in the selected parameter Assume that Meters gt Tariff1 gt Imp Active Import active power submenu is as shown below e P KI FA ev am Energy Analyzer SECTION 3 MENUS Meters gt T1 gt Imp active Index 267500 1 Curr hour 0 5 Prev hour 0 6 Curr day 21 3 Prev day 22 6 Curr month 598 4 Prev month 439 5 Figure 3 59 Before Clear When the clear process is completed the submenu Meters gt T1 gt Imp Active will be as shown in the Figure 3 60 Meters gt T1 gt Imp active Index 0 0 Curr hour 0 0 Prev hour 0 0 Curr day 0 0 Prev day 0 0 Curr month 0 0 Prev month 0 0 Figure 3 60 After Clear After the clear process for index parameters a value different than zero may be observed This value is the initial value entered by the operator Assume that initial value of Setup gt Energy gt T1 kWh was entered as 2000 kWh In this case after the clear pr
69. ed with KleaCom All settings of Klea can be changed read via KleaCom software History archive data of Klea can be downloaded using KleaCom and this data can be listed in an MS Excel or WordPad file selectable KleaCom software is included in the CD ROM received with Klea package Latest version of KleaCom software can be downloaded from www klemsan com tr KI FA ev S AYA Energy Analyzer SECTION 1 GENERAL INFORMATION 1 6 KLEA Front Panel CON NU 4 W N 10 11 12 13 14 15 16 17 18 EE Measure Meters Alarms Analysis 220 0 vi 9 0 A 220 0 v 2 9 0 A 220 0 v 5 9 0 X OO LE ALL KA 17 22 Figure 1 1 KLEA Display Menus L N voltages belonging to three phases Currents of three phases Presence Absence of currents voltages belonging to three phases and phase sequence Selected connection type Alarm state symbol for any alarm Temperature alarm state symbol displayed only with a temperature alarm Alarm relay symbol If 1st and or 2nd alarm relay is assigned to any alarm and also if there is an alarm in the system at the same time this symbol shall appear on the screen 1 stands for 1st Alarm Relay and 2 stands for 2nd Alarm Relay KLEA digital output symbol 1 indicates digital output 1 and 2 indicates digital output 2 This symbol shall be displayed as long as width of the output pulse KLEA digital output symbol if there is an output from optional output3 output4 output5 o
70. er SECTION 3 MENUS 3 2 2 2 1 1 Current Menu This menu shows demand values of currents of each phase and the demand value for the sum of phase currents Date and time information for demand values can be seen on the screen Meters Alarms Analysis Measure gt Demand gt Curr month gt Current Current Act power 02 44 59 10 10 12 Rea power Phase 2 App power 29 59 11 10 12 5 A Phase 3 Example 09 10 12 Total 220 0 vB 50A 09 14 59 12 10 12 y Figure 3 74 Current Menu Assume that demand period is entered as 15 minutes Also assume that the current present month s current demand and date are Phase1 5 0 A 02 44 59 10 10 12 This means On October 10 2012 demand value of phase1 current in the time interval 02 29 59 02 44 59 is 5 0 A In order for KLEA to keep demand values for 1 month ago 2 months ago and 3 months ago demand period should be set as 1 2 3 4 5 6 10 12 15 20 30 or 60 min common divisors of 60 Otherwise 1 month ago 2 months ago and 3 months ago demand values will not be stored Example When the system clock is 15 07 00 assume that demand period is adjusted as 15 minutes Sequentially demand periods will be as follows 05 07 00 15 14 59 The 1st demand period 15 14 59 15 29 59 The 2nd demand period 15 29 59 15 44 59 The 3rd demand period 15 44 59 15 59 59 The 4th demand period 15 59 59 16 14 59 The 5th
71. etely Klea starts to save data starting from 1st file The last saved file number inside the hourly memory can be accessed from the 32 bit parameter starting from Modbus address 1360 Refer to Table 4 4 EXAMPLE Assume that a programmer will try to access a Klea with a slave ID number 1 Assume also that the last saved hourly file number of this device is 17 In this case data request and Klea response will be as follows Sorgu Klea cevap Slave ID 0x01 Slave ID 0x01 4 5 3 2 4 5 3 3 KI FA AV ma AYA Energy Analyzer SECTION 4 MODBUS PROTOCOL Sorgu Klea cevap Timestamp XXX Sub req 1 starting reg addr LO The parameters and CRC values in above tables are as they should be On the other hand Klea response is given to describe the message structure As a result values for variables are not defined Daily archive data Recording of daily data changes with start of day Refer to 3 2 1 1 3 4 setting The smallest and largest instantaneous values measured during one day period are saved as minimum and maximum values Likewise average values of measurements which were taken in one day period are saved as average values 14h function operates with file numbers File numbers 5001 5240 are used for DAILY data KLEA keeps a total of 240 daily files in its specifically reserved memory for daily data When 240 files of data are filled completely Klea starts to save data starting from 5001st file
72. eters given with RO Read Only in Table 4 5 are read only data They cannot be changed by the user This data is as given below Serial Number Firmware Version e Compiler Version 1998 addressed variable at the end of Table 4 5 is a W only writable variable a P KLEA Energy Analyzer 2000 2002 2004 2006 2008 2010 2012 2014 2016 2018 2020 2022 2024 2026 2028 2030 2032 2034 2036 2038 2040 2042 2044 2046 2048 2050 2052 2054 2056 2058 2060 2062 2064 2066 2068 2070 2072 2074 Address Parameter Power Unit T1 kWh TI kWhE TI kVArhl TI kVArhC T1 1 kWh T1 1 kWhE T1_2 kWh T1_2 kWhE T1_3 kWh T1_3 kWhE T2 kWh T2 kWhE T2 kVArhl T2 kVArhC Current Transf Ratio CTR Voltage Transf Ratio VTR 32 bit float Connection 32 bit int Demand Period PAA GERA T1 1 Start Time T1 2Start Time T1_3 Start Time Start of month T1 2 kVArhl 32 bit float T1 2 kVArhC 32 bit float Output1 Mode Output1 Energy Output1 Width Output1 Multiplier Output2 Mode Output2 Energy Output2 Width Output2 Multiplier SECTION 4 MODBUS PROTOCOL Table 4 5 Setting Parameters Data Type 32 bit float ENERGY 32 bit int T1 1 kVArhl 32 bit float T1 1 kVArhC 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float T1 3 kVArhl 32 bit float TI 3 kVArhC 32 bit float NETWORK SETTINGS Descript R W SL1 SL2 SETTIN
73. h o0mooomme mawe oo mw 00000000000 mawan o0 van 00000000000 mawame 09 WAh 00m200000m0 ma o om o0s200000m0 mawe 00 kmh 00000000000 mwm o WAh o0m2000000m0 mawame o van 00000000000 ma 00 om 00000000000 mane o om 002000000 maw owo Wh o0eo00mo mawe 7 ocaommoooo0 mW 99 mw o0eooomme mme 09 km 00000000000 Tawa 00 van 00000000000 Tame 00 wah O0eszoooommooo0 Digital Input Settings ar KI FA ANT T AYA Energy Analyzer FACTORY DEFAULT SETTINGS Default value Unit Setting Range Digital Output Settings Mode Output1 2 7 Energy Outputl 2 7 Width Output1 2 7 Multiplier Output1 2 Refer to 3 2 1 1 5 Digital Output 15500000 5052500 110000 kWh kVArh msec 7 Analog Output Settings Refer to 3 2 1 1 6 0 5V Refer to 3 2 1 1 6 Refer to 3 2 1 1 6 Refer to 3 2 1 1 6 Refer to 3 2 1 1 6 1 Kilo Mega Input mode Output conn V mA Min value Max value Multiplier Communications Settings Baud Rate Slave Id Alarm Settings V L N 38400 Bits sec 2400 4800 9600 19200 38400 5 7600 14 247 0 0 1500000 0 0 0 lt 1500000 0 Low Limit High Limit N V L L 0 0 lt 2600000 0 0 0 2
74. hase3 Voltage Phase3 Phase1 Voltage Neutral Current Phase1 Active Power Phase2 Active Power Phase3 Active Power Phase1 Reactive Power Phase2 Reactive Power Phase3 Reactive Power Phase1 Apparent Power Phase2 Apparent Power Phase3 Apparent Power Phase1 Cos Phase2 Cos Phase3 Cos Phase1 Power Factor e P KI FA AV ma AYA Energy Analyzer PF2 PF3 9 F2 F3 THDI1 THDI2 THDI3 I1 Harmonics I2 Harmonics I3 Harmonics SECTION 4 MODBUS PROTOCOL Phase2 Power Factor Phase3 Power Factor Phase1 Frequency Phase2 Frequency Phase3 Frequency Phase1 Total Harmonic Distortion in Current Phase2 Total Harmonic Distortion in Current Phase3 Total Harmonic Distortion in Current Phase1 Current Harmonics Phase2 Current Harmonics Phase3 Current Harmonics 3 4 5 2 KLEA Setting Parameters NOTE1 NOTE2 Operator programmer should use 10H Write Multiple Registers and 06H Write Single Register to change settings parameters Operator programmer should use 0x3H Read Holding Registers function to read setting parameters 1 register gt comprises of 2 bytes After Klea setting parameters have been changed in order for the new values to be saved in non volatile memory 0x0000 should be written to register 1998 and 0x0001 should be written in register 1999 within 60 seconds following the last setting change Only after that changes will be stored in the permanent memory 3 param
75. ime can be adjusted between 0 23 for Virtual Keyboard Refer to 3 1 4 Example T1 rate2 meter the second time slice of T1 meter T1 2 counts between T1 2 start time and T1 2 start time Example Assume that T1 2 start time and T1_3 start time are adjusted as 16 and 0 respectively T1 rate 2 meter T1_2 counts starting from 16 00 and ceases at 00 00 e P KI FA ECCS AYA Energy Analyzer Alarms Analysis 4 3 2 1 1 3 3 T1_3 start time SECTION 3 MENUS Settings gt Setup gt Energy T1 1 start time T1 2 start time T1 3 start time Start of day Start of month T1 kWh T1 kWh E T1 kVArh I T1 kVArh C T1 1 kWh T1 1kWhE T1 1 kVArh I Figure 3 26 T1 2 start time 8 16 U U T1_3 abbreviation refers to the third time slice of tariff 1 meter T1_3 start time can be adjusted between 0 23 for Virtual Keyboard Refer to 3 1 4 Example TI rate3 meter the second time slice of T1 meter T1 3 counts between T1_ 3 start time and T1 1 start time Example Assume that T1 3 start time and T1 1 start time are adjusted as 0 and 8 respectively T1 rate 3 meter T1 3 counts starting from 16 00 and ceases at 00 00 Alarms Analysis 4 Settings gt Setup gt Energy T1 1 start time T1 2 start time T1 3 start time Start of day Start of month T1 kWh T1 kWh E T1 kVArh I T1 kVArh C T1 1 kWh T1 1 kWh E T1 1 kVArh I Figure 3 27 T1 3 start time 8 1
76. imestamp 3 months ago L3 P 3 Months Ago Phase 3 Active Power 926 3 months ago L3 P time 3 Months Ago Phase 3 Active Power Timestamp 928 3 months ago L3 3 Months Ago Phase 3 Current 930 3 months ago L3 I time 3 Months Ago Phase 3 Current Timestamp 3 months ago L3 Q 3 Months Ago Phase 3 Reactive Power 3 months ago L3 Q time 3 Months Ago Phase 3 Reactive Power Timestamp 3 months ago L3 S 3 Months Ago Phase 3 Apparent Power 3 months ago L3 S time 3 Months Ago Phase 3 Apparent Power Timestamp DI COUNTERS Digital Input1 Counter Value Digital Input2 Counter Value OTHER Temperature Value System Date and Time DI COUNTERS OPTIONAL DIO MODEL 950 Digital Input3 Counter Value 952 DI4 Counter Digital Input4 Counter Value 954 DI5 Counter 956 DI6 Counter 958 DI7 Counter 32 bit unix time gt 32 bit float 32 bit unix time 908 914 920 922 3 months ago L2 S time 24 9 32 bit float 32 bit unix time 32 bit float 32 bit unix time VAr 32 bit float 32 bit unix time VA 32 bit float 32 bit unix time 32 bit float 32 bit float o C 32 bit float 32 bit float 32 bit unix time D 3 o lt 932 934 936 938 940 942 944 946 948 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float Digital Input5 Counter Value Digital Input6 Counter Value Digital Input7 Counter Value ALARM STATUSES 956 1 AlammValue ae of related alarm parameter 970
77. imestamp 2 months ago L2 Q 2 Months Ago Phase 2 Reactive Power 854 2 months ago L2 Q time 2 Months Ago Phase 2 Reactive Power Timestamp 2 months ago L2 S 2 Months Ago Phase 2 Apparent Power 2 months ago L2 S time 2 Months Ago Phase 2 Apparent Power Timestamp 2 months ago L3 P 2 Months Ago Phase 3 Active Power 2 months ago L3 P time 2 Months Ago Phase 3 Active Power 2 months ago L3 2 Months Ago Phase 3 Current 32 bit unix time z 32 bit float 2 months ago L2 P time 32 bit unix time 838 840 842 844 846 848 32 bit float 32 bit unix time VAr 32 bit float 32 bit unix time A 32 bit float 32 bit unix time 32 bit float 32 bit unix time 32 bit float 32 bit unix time 32 bit float 2 months ago L3 time 2 Months Ago Phase 3 Current Timestamp 2 months ago L3 Q 2 Months Ago Phase 3 Reactive Power 2 months ago L3 Q time 2 Months Ago Phase 3 Reactive Power Timestamp 2 months ago L3 S 2 Months Ago Phase 3 Apparent Power 8 2 months ago L3 S time 2 Months Ago Phase 3 Apparent Power Timestamp Ar 32 bit unix time gt 32 bit float 864 866 868 870 872 74 32 bit unix time 32 bit float 32 bit unix time 32 bit float 32 bit unix time 3 months ago Q top 3 Months Ago Total Reactive Power Ar 32 bit float 886 3 months ago Total Q time 3 Months Ago Total Reactive Power Timestamp 32 bit unix time gt 3 months ago Total S 3 Months Ago Total Apparent Power 32 bit float 3 months ago Tot
78. ings Do not work under live supply conditions Before installation turn off the power of the panel or any other related equipment Installation operation and commissioning putting into service of KLEA must be performed by qualified personnel The device must be put into service only after all connections are made e KLEA is connected to current transformer s Before disconnecting current transformer leads be sure that they are short circuited elsewhere or connected to a parallel load which has sufficiently low impedance Otherwise dangerously high voltages will be induced at the current transformer leads Same phenomena also apply for putting into service Keep and store away from moisture dust vibration and wet environment For cleaning remove the dust with a dry cloth Do not use abrasives solvents or alcohol There are no user serviceable parts inside Maintenance and calibration can only be carried out at manufacturer s end It is recommend to connect circuit breakers or automatic fuses between voltage inputs of Klea and the network e P KI FA ENT 7 mu Energy Analyzer SECTION 1 GENERAL INFORMATION E 1 3 Receipt Control and Contents of Delivery When you receive the package please be sure that e packing is in good condition product has not been damaged during transportation product name and reference order number conforms to your order KLEA Order Number Statement 606100 Klea base model
79. ital input 1 Counter is selected as the mode setting Under this condition each time DI1 and GND pins are short circuited Meters gt Digital input gt Digital input1 counter counts Figure 3 31 Alarms Analysis Meters gt Digital input Counter 2 0 Figure 3 31 Digital Input1 Counter a P KI FA ENT 7 mu Energy Analyzer SECTION 3 MENUS E 3 2 1 1 4 1 2 Delay Digital input delay can be adjusted between 10632000 milliseconds In order for 2nd tariff or Counter modes to be activated DI1 and GND pins should be short circuited at least delay period of time for Virtual Keyboard Refer to 3 1 4 Example Delay 100 msec Figure 3 32 Delay Example Digital input Input Mode Counter Delay 200 msec When DI1 and GND pins are short circuited for minimum 200 msec Inout 1 Counter increments by 1 Example Digital input Input Mode Tariff 2 Delay 200 msec In order for the Tariff 2 meter to be active DI1 and GND pins should be short circuited for minimum 200 msec Tariff 2 meter will be active during the course of short circuit time DI1 and GND DI1 and GND short circuit short circuit 200msec DI1 ve GND 100msec pM i ean open circuit pA tariff 1 counts tariff 2 counts Tariff 1 counts Figure 3 33 Tariff 1 or Tariff 2 Activation Bi 3 2 1 1 4 2 Input 2 Menu Input 2 applications and settings are the same as Input1 Digital input2 operates with DI2 and GND pins
80. ive Current Day 32 bit float 468 T1 Rate1 Import Active Previous Day 32 bit float 470 T1Rate1 Import Active Current Month 32 bit float 472 T1 Rate1 Import Active Previous Month 32 bit float 474 T1 Rate1 Export Active Index 32 bit float 476 T1 Rate1 Export Active Current Hour 32 bit float 478 T1 Rate1 Export Active Previous Hour 32 bit float 480 T1 Rate1 Export Active Current Day 32 bit float 482 T1 Rate1 Export Active Previous Day 32 bit float 484 T1 Rate1 Export Active Current Month 32 bit float 486 T1 Rate1 Export Active Previous Month 32 bit float T1 Rate1 Inductive Reactive Index VArh 32 bit float 504 T1 1 Cap React Curr Hour T1 Ratel Capacitive Reactive Current Hour kVArh 32 bit float 506 T1 1 Cap React Prev Hour kVArh 32 bit float 508 T1 1 Cap React Curr Day kVArh 32 bit float 510 T1 1 Cap React Prev Day kVArh 32 bit float 512 T1 1 Cap React Curr Month kVArh 32 bit float 514 T1 1 Cap React Prev Month kVArh 32 bit float Tariff 1 Inductive Reactive Current Hour Tariff 1 Inductive Reactive Previous Hour A E 2 2 r 2 SE 2 2 SERBERE 2 EDA gt ka 2 Ps 2 SY T1 Rate1 Capacitive Reactive Previous Hour T1 Rate1 Capacitive Reactive Current Day T1 Rate1 Capacitive Reactive Previous Day T1 Rate1 Capacitive Reactive Current Month T1 Rate1 Capacitive Reactive Previous Month E KI FA ENT 7 uu Energy Analyzer SECTION 4 MODBUS PROTOCOL R W Unit Data Type k
81. key of Klea to insert the decimal point Following the point enter the decimal part of the desired value To enter a negative value enter the number move inside the virtual keyboard point to the negative sign box and press OK KI FA ENT 7 mu Energy Analyzer SECTION 3 MENUS 3 1 5 Voltage Transformer Ratio VTR In this tab voltage transformer ratio is entered For Virtual Keyboard Refer to 3 1 4 Example The voltage transformer ratio can be adjusted between 1 5000 To enter a decimal value enter the integer part of the decimal number first Then scroll inside virtual keyboard till ed box is highlighted Press OK key of Klea to insert the decimal point Following the point enter the decimal part of the desired value Startup Settings Language Date Time CTR Connection Start Figure 3 7 Voltage Transformer Ratio In order for KLEA to perform accurate measurements current transformer ratio should be entered correctly 5 3 1 6 Connection This menu contains information about how to connect KLEA to the panel electrical network There are 3 connection types 3 phase 4 wire connection 3 phase 3 wire connection e Aron connection Startup Settings Language Engli ar Date 07 Jal3phase 3wire Time 17 45 Aron CTR 1 VTR 1 0 onnection 3phase 4wire Start Initializing Figure 3 8 Connection Types e P KI FA ENT 7 mu Energy Analyzer SECTION 3 MENUS E 3
82. llowing submenus Input mode e Output conn e Min Value e Max Value e Multiplier Settings 5 Setup 5 Analog output 5 Output 1 Input mode V1 LN Output conn 5V Min value Max value Multiplier Figure 3 38 Output1 KI FA AV ma AYA Energy Analyzer SECTION 3 MENUS 3 2 1 1 6 1 1 Input mode Analog output will generate a signal in accordance with the parameter selected in Input mode tab Analog output examples will clarify the application of settings Input mode options are as follows VLL12 VLL23 VLL31 tot P tot Q tot S tot Settings gt Setup gt Analog output gt Output1 Input mode IF z Output conn amy Min value Max value Multiplier Figure 3 39 Input mode e P KI FA AV ma AYA Energy Analyzer SECTION 3 MENUS 3 2 1 1 6 1 2 Output connection Inside Output1 menu press up and down keys to select highlight Output connection menu item When Output connection is selected press OK key and the options in Figure 3 40 will appear on the screen Press up and down keys to select the desired option and press OK key to complete the setting Settings gt Setup gt Analog output gt Output1 Input mode Min value Max value Multiplier Figure 3 40 Output connection Assume that for analog output 1 output connection was selected as 0 5V refer to Figure 3 40 Then operator should adjust the analog output 1 dip switch as seen in Figur
83. ms Analysis Gt 5 0 A 220 0 v 5 9 0 y Figure 3 85 T1 Rate1 Menu 3 2 3 3 T1 Rate2 Menu T1 rate2 meter counts between T1 2 start time and T1_3 start time Refer to 3 2 1 1 3 2 and 3 2 1 1 3 3 for T1_2 start time and T1 3 start time settings T1 rate2 menu items are the same as 3 1 3 1 Tariff 1 menu items Alarms Analysis da Exp active Ind reactive Cap reactive Figure 3 86 T1 Rate2 Menu KI FA AV ma AYA Energy Analyzer SECTION 3 MENUS 3 2 3 4 T1 Rate3 Menu T1 rate3 meter counts between T1 3 start time and T1 1 start time Refer to 3 2 1 1 3 3 and 3 2 1 1 3 1 for T1 3 start time and T1 1 start time settings T1 rate3 menu items are the same as 3 2 3 1 Tariff 1 menu items ay Alarms Analysis Gt 5 0 A 220 0 v 5 9 0 y Figure 3 87 T1 Rate3 Menu 3 2 3 5 Tariff 2 Menu T2 meter consists of import active export active inductive reactive and capacitive reactive energy values Refer to 3 2 1 1 4 1 Mode Setting in order to activate Tariff 2 meter aay Alarms Analysis Gt Exp active D 0 A Ind reactive Cap reactive 5 0 A 5 0 A Figure 3 88 Tariff 2 Menu Tariff 2 menu items are the same as Tariff 1 menu items While Tariff 2 meter is active Tariff 1 T1 rate1 T1 rate2 T1 rate3 meters are not active mutually exclusive KI FA AV ma AYA Energy Analyzer SECTION 3 MENUS In order for Tariff 2 to
84. mstatus 5 Alarm ON Nam OFF status 1000 6 Alarm time 1004 6 Alarm ON Alarm OFF status 1006 6 Value of related alarm parameter 1008 7 Alarm time 1010 7 Alarm ID 1012 7 Alarm ON Alarm OFF status 7 Value of related alarm parameter 1016 S Mammesamp 8 Mam me 1024 9 Alarm time 1028 9 Alarm ON Alarm OFF status 1030 9 Value of related alarm parameter 1032 10 Alarm time 1034 10 Alarm ID 1036 10 Alarm ON Alarm OFF status 10 Value of related alarm parameter 1048 12 Alarm Timestamp 12 Alarm time 1050 12 Alarm ID 12 Alarm ID 1052 12 Alarm Status 12 Alarm ON Alarm OFF status 1054 12 Alarm Value 12 Value of related alarm parameter 1056 13 Alarm Timestamp 13 Alarm time 1058 13 Alarm ID 13 Alarm ID 1060 13 Alarm Status 13 Alarm ON Alarm OFF status 1062 13 Value of related alarm parameter 1064 13 Alarm Value 14 Alarm Timestamp 14 Alarm time KI FA ENT 7 uu Energy Analyzer SECTION 4 MODBUS PROTOCOL R W Unit Data Type 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32 bit unix time 32 bit int 32 bit int 32 bit float 32
85. n be adjusted between 1 5000 When this tab is highlighted if the operator presses OK key KLEA Virtual Keyboard will appear on the screen Startup Settings Language Date Time VTR Connection Start o fo Low limit 1 5000 Figure 3 5 Current Transformer Ratio Use arrow keys left right up and down of Klea to navigate inside the virtual keyboard In order to enter any number in the virtual keyboard as a value when that number is highlighted press OK key of Klea When ok box of virtual keyboard is highlighted press OK key of Klea to complete current transformer setting In case an incorrect digit is entered scroll inside the virtual keyboard to select dr box Then pres OK key of Klea to erase erroneous entered digit s In order for KLEA to perform accurate measurements current transformer ratio should be entered correctly Example KI FA AV ma AYA Energy Analyzer CM 988 8680 OORE SS Low limit 1 High limit 5000 po gann 8998 ose ok ote Low limit 1 SECTION 3 MENUS R o OO 2 3 4 5 e 7 8 m ok ote Low limit High limit Startup Settings Language English 07 January 2013 17 45 28 1 0 Connection 3phase 4wire Start Figure 3 6 Entering Values to the Virtual Keyboard To enter a decimal value enter the integer part of the decimal number first Then scroll inside virtual keyboard till n box is highlighted Press OK
86. n the daily data memory can be accessed from 1362 Modbus addressed parameter Refer to Table 4 4 e The last saved file number in the monthly data memory can be accessed from 1364 Modbus addressed parameter Refer to Table 4 4 Table 4 7 Archive History Record Table Item No History Records Variable Type s Li minimumcurentvalueti min sf L1 maximum current value I1 max 32 bit float DEM S L1 average active power value P1 ave 32 bit float DEED L1 minimum active power value P1 min 32 bit float KI FA ENT 7 uu Energy Analyzer SECTION 4 MODBUS PROTOCOL Item No History Records Variable Type L1 maximum reactive power value Q1 max a KI FA Maa ma AYA Energy Analyzer SECTION 4 MODBUS PROTOCOL Item No History Records Variable Type e vatvoltage minimum value V31 min azioa 66 Ti meters generated exp active energy value WEL 32bioat TTT H ET at 4 5 3 1 Hourly archive data The smallest and largest instantaneous values measured during one hour period are saved as minimum and maximum values Likewise average values of measurements which were taken in one hour period are saved as average values 14h function operates with file numbers File numbers between 1 1920 are used for HOURLY data KLEA keeps a total of 1920 hourly files in its specifically reserved memory for hourly data When 1920 files of data are filled compl
87. nergy Analyzer SECTION 3 MENUS 3 2 5 1 1 4 Other VLL12 phase1 phase2 voltage VLL23 phase2 phase3 voltage VLL31 phase3 phase voltage m 3 2 5 1 2 Daily Menu This menu displays the minimum instantaneous values measured calculated from start of day Refer to 3 2 1 1 3 4 up to present time Its submenus are the same as Hourly menu 3 3 2 5 1 3 Monthly Menu 23 3 2 5 2 iJ 3 2 5 3 3 2 5 4 This menu displays the minimum instantaneous values measured calculated from start of month Refer to 3 2 1 1 3 5 and start of day Refer to 3 2 1 1 3 4 up to present time Its submenus are the same as Hourly menu Maximum Menu Submenus and explanations of Maximum menu are the same as Minimum menu The values measured in the Maximum menu are also instantaneous maximum values Average Menu Submenus and explanations of Maximum menu are the same as Minimum menu In Average menu hourly daily and monthly average values are displayed Energy Menu In this menu daily and monthly meter values which are measured when Tariff 1 is active are displayed Minimum Hourly Daily Monthly 220 0 v 2 220 0 Vv 8 KI FA ENT 7 mu Energy Analyzer SECTION 3 MENUS E 3 2 5 4 1 Hourly Menu This menu consists of index values measured from the beginning of current hour up to present time kWh import active kWh E export active kVArh I inductive reactive
88. nic L2 V Harmonics49 Phase2 voltage 49th harmonic L2 V Harmonics51 Phase2 voltage 51st harmonic Phase2 voltage first harmonic Phase2 voltage third harmonic Phase2 voltage 5th harmonic Phase2 voltage 7th harmonic 200 202 204 Phase2 current first harmonic Phase2 current third harmonic 2 Phase2 current 5th harmonic Phase2 current 7th harmonic 220 222 224 226 28 L2 Harmonics17 Phase2 current 17th harmonic 06 32 bit float 242 L2 Harmonics19 Phase2 current 19th harmonic 32 bit float 244 L2 Harmonics21 Phase2 current 21st harmonic 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 246 Phase2 current 23rd harmonic 248 250 252 254 256 L2 Harmonics33 L2 Harmonics23 L2 Harmonics25 L2 Harmonics27 L2 Harmonics29 L2 Harmonics31 Phase2 current 25th harmonic Phase2 current 27th harmonic Phase2 current 29th harmonic p Phase2 current 31st harmonic Phase2 current 33rd harmonic KI FA ENT 7 uu Energy Analyzer SECTION 4 MODBUS PROTOCOL R W Unit Data Type 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float O D Vn e E Le et e Address Parameter 258 L2 Harmonics35 260 L2 Harmonics37 Phase2 current 35th harmonic Phase2 current 37th harmonic 262 Phase2 current 39th harmonic 264 266 268 270 272 274
89. o S tot time 1 Month Ago Total Apparent Power Timestamp 762 764 766 768 770 772 VAr 32 bit unix time gt 32 bit float 32 bit unix time 32 bit float 32 bit unix time 32 bit float 32 bit unix time 32 bit float VAr 1 month ago L2 Q time 32 bit unix time gt 32 bit float 32 bit unix time 7 7 7 7 32 bit float 32 bit unix time 32 bit float 32 bit unix time 32 bit float 788 90 92 94 96 98 32 bit unix time 32 bit float 32 bit unix time 32 bit float 32 bit unix time 32 bit float 32 bit unix time 32 bit float 32 bit unix time 32 bit float Ar gt 32 bit unix time 32 bit float 32 bit unix time 32 bit float 2 months ago L1 time 2 Months Ago Phase 1 Current Timestamp 32 bit unix time 836 2 months ago L1Q 2 Months Ago Phase 1 Reactive Power VAr 32 bit float e P KI FA ENT 7 mu Energy Analyzer SECTION 4 MODBUS PROTOCOL ipti R W Unit Data Type J D Uu A Le et je 3 Address Parameter 2 months ago L1 Q time 2 Months Ago Phase 1 Reactive Power Timestamp 32 bit unix time gt 2 months ago L1 S 2 Months Ago Phase 1 Apparent Power 32 bit float 2 months ago L1 S time 2 Months Ago Phase 1 Apparent Power Timestamp 2 months ago L2 P 2 Months Ago Phase 2 Active Power 2 Months Ago Phase 2 Active Power Timestamp 2 months ago L2 I 2 Months Ago Phase 2 Current 2 months ago L2 I time 2 Months Ago Phase 2 Current T
90. o the ends of lines belonging to the same phase Thus it will be easy to follow currents and voltages of a phase Meters Alarms Analysis ds Measure gt Phasor diagram Instantaneous Demand Signals Harmonics Figure 3 75 Phasor Diagram Menu 3 2 2 4 Signals Menu In this menu current and voltage waveforms are shown At the right hand side of the waveforms following information is listed Voltage and current values of phases e Instantaneous frequency value Phase difference between current and voltage Current signal is in gray and voltage is in black color Operator can scroll inside signals menu by pressing left and right keys Meters Alarms Analysis ds Measure gt Signals gt V2 12 v BA v5 Figure 3 76 Signals Menu e P KI FA ev S AYA Energy Analyzer SECTION 3 MENUS 3 2 2 5 Harmonics Menu KLEA measures calculates current and voltage harmonics up to 51st harmonic Current and voltage harmonics can be monitored in table and in graph format Meters Alarms Analysis Figure 3 77 Harmonics Menu 3 2 2 5 1 Table Menu Current and voltage harmonics of each phase are displayed in a table format See Figure 3 78 Operator can scroll inside table menu by pressing right and left keys There are 6 table pages V1 V2 V3 11 12 B3 Measure gt Harmonics gt V1 96 99 01 0 00 1 02 0 00 5 70 0 00 0 75 0 00 0 00 0 00 0 00 0 00 0 00 0 00 0 00 0 00 0 00 0 00 0 00 0 00
91. oat 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float O D Uu A c Le et o Address Parameter 84 L1 V Harmonics37 L1 V Harmonics39 L1 V Harmonics41 L1 V Harmonics43 92 L1 V Harmonics45 94 L1 V Harmonics47 Phase1 voltage 47th harmonic 96 L1VHarmonics49 Phasel voltage 49th harmonic 98 LVHamones PhaelvotageShithamenc 106 Phasel current 7th harmonic Phasel current 9th harmonic Phase current 11th harmonic 112 Phasel current 13th harmonic 114 L1 Harmonics15 Phase1 current 15th harmonic 116 L1 Harmonics17 Phase1 current 17th harmonic Phase1 current 19th harmonic Phase1 current 21st harmonic 130 Phase1 current 31st harmonic Phase1 current 33rd harmonic 134 Phase current 35th harmonic 136 Phase1 current 37th harmonic Phase voltage 37th harmonic Phase1 voltage 39th harmonic 88 Phase voltage 41st harmonic Phase voltage 43rd harmonic Phase voltage 45th harmonic 138 Phase1 current 39th harmonic 140 Phase1 current 41st harmonic 142 Phase1 current 43rd harmonic Phase current 45th harmonic 32 bit float PHASE 2 Phase2 Cost Ro 32bitfloat LN Ro RO
92. ocess is completed Meters gt Tariff 1 gt Imp Active value will be 2000kWh See Figure 3 61 Meters gt T1 gt Imp active Index 2000 0 Curr hour 0 0 Prev hour 0 0 Curr day 0 0 Prev day 0 0 Curr month 0 0 Prev month 0 0 Figure 3 61 Initial Value After Clear Process e P KI FA ENT 7 mu Energy Analyzer SECTION 3 MENUS 3 2 1 2 Date Time Menu In the following menu Date Time setting is made For date time setting Refer to 3 1 2 Example BANA Measure Meters Alarms Analysis Settings gt Date Time ime 17 22 17 5 0 A Date 07 January 2013 5 0 A 5 0 A Figure 3 62 Date Time Menu Em 3 2 1 3 System Info Menu This menu is for information no setting is accomplished EE Measure Meters Alarms Analysis xum KLEMSAN Date Time KOA KLEA Network Analyzer Model 606100 Password Restart 5 0 A Serial number 2555953 Language English Firmware version 1 00 5 0 A PCB version 1 1 60 Build date 29 October 2012 Temperature 26 5 C Battery voltage 3 30 V Default settings Figure 3 63 System Info Temperature and battery voltage values can be reached via RS485 KI FA ENT 7 mu Energy Analyzer SECTION 3 MENUS 3 2 1 4 Password Menu If operator have not entered password only Date Time System Info and Password tabs are active inside settings menu In order for the remaining tabs to be activated operator should login via Password tab
93. oltage for three phases 32 bit float THDI tot Total har distortion of voltage for three phases 32 bit float PHASE 1 Phase1 voltage 40 L1 PF Phase1 power factor VAr VA 0 e 0 4 6 8 0 2 4 6 96 8 1 1 2 2 2 2 2 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float VAr VA Z L1 THDV Phase total har distortion of voltage Phase total har distortion of current Phase1 voltage first harmonic Phase1 voltage third harmonic Phase voltage 5th harmonic 60 LiVHamonksii Phase voltage 13thharmonic 62 Phase1 voltage 15th harmonic Phasel voltage 17th harmonic Phase voltage 19th harmonic Phasel voltage 21st harmonic 70 Phase voltage 23rd harmonic 72 Phase1 voltage 25th harmonic 74 Phase voltage 27th harmonic Phase voltage 29th harmonic 30 uvHamonies33 Phasel voltage 33rd harmoni e P 4 4 42 4 6 48 50 52 KI FA ENT 7 uu Energy Analyzer SECTION 4 MODBUS PROTOCOL R W Unit Data Type 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit fl
94. onal QQ Q Q Q Q Z Z S25 22 DOZ UO aoc QUA Quo AYU eL ar Figure 2 6 KLEA Star WYE Connection Diagram L1 L2 L3 Tr IT GN bw Voltage Measurement Inputs Digital Outputs Optional 1 TE NN mm NN OO OO OO AA AA AA ah ab Els KI FA ENT 7 mu Energy Analyzer SECTION 2 INSTALLATION 2 3 2 Three Phase Connection No Neutral 3P3W P P Ha WN Current Measurement Voltage Measurement Inputs Inputs Figure 2 7 KLEA 3 Phase Delta Connection Diagram E 2 3 3 Three Phase No Neutral Aron Connection iu An AA n Mr FT WwW YN por a Ww N 2 Current Measurement Voltage Measurement Inputs Inputs Figure 2 8 KLEA Aron Connection Diagram a P KI FA ENT 7 mu Energy Analyzer SECTION 2 INSTALLATION 2 4 Dimensions Dimensions are in millimeters 96 8 89 6 65 0 Figure 2 9 Dimensions KI FA AV ma AYA Energy Analyzer SECTION 3 MENUS SECTION 3 MENUS 3 1 First Power on Settings After its receipt when KLEA is switched on for the first time the following page appears 3 1 1 Dil Language Startup Settings Date 07 January 2013 Time 17 45 28 CTR 1 VTR 1 0 Connection 3phase 4wire Start Figure 3 1 First Power on Settings When OK key is pressed on this tab T rk e English and Pycckun options appear on the screen as seen below Operator can scroll inside the options by pressing
95. r Timestamp 1 Month Ago Phase 1 Current 1 Month Ago Phase 1 Current Timestamp 1 Month Ago Phase 1 Reactive Power 774 1 month ago L1 Q time 1 Month Ago Phase 1 Reactive Power Timestamp 1 month ago LI S 1 Month Ago Phase 1 Apparent Power 1 month ago L1 S time 1 Month Ago Phase 1 Apparent Power Timestamp 784 1 Month Ago Phase 2 Current Value 786 1 Month Ago Phase 2 Current Timestamp 1 Month Ago Phase 2 Reactive Power 1 Month Ago Phase 2 Reactive Power Timestamp 1 month ago L2 S 1 Month Ago Phase 2 Apparent Power 1 month ago L2 S time 1 Month Ago Phase 2 Apparent Power Timestamp 1 Month Ago Phase 3 Active Power 7 1 Month Ago Phase 3 Active Power Timestamp 802 Tmonthagolil me 1 Month Ago Phase 3 Current Timestamp RO 804 Tmonthagol3 DD 1 Month Ag Phase3 Reactive Power RO War 1 month ago L3 Q time 1 Month Ago Phase 3 Reactive Power m Timestamp 1 month ago L3 S 1 Month Ago Phase 3 Apparent Power 808 1 month ago L3 S time 1 Month Ago Phase 3 Apparent Power ru Timestamp 2 Months Ago Total Active Power Timestamp 2 Months Ago Total Current 2 Months Ago Total Current Timestamp 2 Months Ago Total Reactive Power 2 Months Ago Total Reactive Power Timestamp 2 months ago Total S time 2 Months Ago Total Apparent Power Timestamp 2 months ago LI P 2 Months Ago Phase 1 Active Power 2 months ago L1 P time 2 Months Ago Phase 1 Active Power Timestamp 2 months ago L1 I 2 Months Ago Phase 1 Current 1 month ag
96. red in permanent memory If X key is pressed the changes will not be accepted and will not be stored in permanent memory Settings changed Save L Figure 3 12 KLEA Save Query D 3 2 1 1 1 Network Menu Electrical network related settings are accomplished in this menu SS Measure Meters Alarms Analysis Settings gt Setup gt Network VTR 1 0 Connection 3phase 4wire Demand period 15 Power unit Kilo Communication Alarm Clear Figure 3 13 Network Menu E 3 2 1 1 1 1 Current Transformer Ratio In this submenu current transformer ratio is entered Inside Network menu press up and down keys to select CTR Press OK key and KLEA virtual keyboard will appear on the screen The current transformer ratio CTR can be adjusted between 1 5000 For Virtual Keyboard Refer to 3 1 4 Example Settings gt Setup gt Network 1 0 Connection 3phas Powerunit Kio 5 6 7 8 efo f Low limit 1 High limit 5000 Figure 3 14 Setting Current Transformer Ratio In order for KLEA to perform accurate measurements current transformer ratio should be entered correctly KI FA AV ma AYA Energy Analyzer SECTION 3 MENUS 3 2 1 1 1 2 Voltage Transformer Ratio In this submenu voltage transformer ratio is entered Inside Network menu press up and down keys to select VTR Press OK key and KLEA virtual keyboard will appear on the screen The voltage transformer ratio VTR can be adjusted between 1 5000 For
97. ritten on the first alarm An alarm status consists of the below information Alarm Time Stamp Alarm time 32 bit integer Alarm Definition Alarm flag bit number Refer to the example below Alarm State Alarm ON or alarm OFF state Alarm ON and alarm OFF conditions are both considered as records As a result both conditions are saved in MODBUS table as different alarm statuses 1 gt Alarm ON 0 gt Alarm OFF Alarm Value Value of the related alarm parameter Example Assume that 100 VAC is assigned as low limit for V L N for phase1 phase2 and phase3 V L N voltages and again assume that phase3 voltage falls below 100VAC in the system In such a case Alarm Definition is the bitwise index number inside the alarm flags 4 5 1 1 Alarm flags variable That is for the above situation alarm definition value will be 3 Shortly alarm definition value can be used as an index in alarm flag variable to reach the explanation for that alarm Besides this way operator will have the opportunity to match the alarm with the alarm flag Analysis 4 Phase1 Phase2 V i Phase3 U Other v2 220 0 v 2 220 0 v 33 Figure 3 90 Alarms Menu a P 3 2 4 1 3 2 4 2 3 2 4 3 KI FA AV ma AYA Energy Analyzer SECTION 3 MENUS Phase1 Menu In Phase1 menu phase alarm statuses are displayed No alarm Alarm Normal Alarm Alarms 5Phase1 Normal Normal Normal Normal Normal
98. s in leftward direction that phase generates power The above phenomenon also applies for total P active power value When Klea is mounted on a panel which consumes power arrow signs in Measure Instantaneous P page should be in rightward direction When Klea is mounted on a panel which generates power arrow signs in Measure Instantaneous P page should be in leftward direction Otherwise K L leads of the current transformer should be cross connected KI Energy Analyzer EA SECTION 3 MENUS Measure gt Instantaneous gt P Meters gt T1 gt Imp active 267500 1 Index P1 1 1 00 0 Curr hour 0 5 Prev hour 0 6 p 1 1 00 0 Curr day 21 3 P3 1 1 00 0 Prev day 22 6 Curr month 598 4 Pt 3300 0 Prev month 439 5 c R Figure 3 69 Connecting the K L ends of Current Correctly 3 2 2 2 Demand Menu During demand period Klea calculates averages for current active reactive and apparent powers for three phases Maximum of these averages are stored as the demand value with a corresponding time stamp Meters Alarms Analysis Figure 3 70 Demand Menu Example The following graph shows the averages of current signals that are calculated measured during the 15 minutes demand period 15 and demand value Amplitude Waveform 15 minutes 15 minutes 15 minutes Time min average value 3 amps average value 5 amps average value 4 amps demand 3A demand 5A demand 5A deman
99. sor diagram e Signals e Harmonics Meters Alarms Analysis nstantaneous Demand Figure 3 67 Measure Menu a P 3 2 2 1 KI EA AV AYA Energy Analyzer SECTION 3 MENUS Instantaneous Menu This menu includes instantaneous values If OK is pressed on this tab the following page appears on the screen Operator can scroll inside Instantaneous values by pressing right and left keys Measure gt Instantaneous gt V L N v1 220 0 vz 220 0 220 0 220 0 Powers VLL Figure 3 68 Instantaneous Menu e Line to neutral V L N voltage for each phase and their average e Line to line V L L voltage for each phase and their average e Phase currents I and their sum Neutral current IN Cos for each phase and Cos of system Power factor PF for each phase and power factor PF of system Active power P for each phase and their sum Reactive power Q for each phase and their sum e Apparent power S for each phase and their sum e Frequency F for each phase e THDV values for each phase and their sum e THDI values for each phase and their sum Total powers If 3phase 3 wire is selected as connection type VL N title in instantaneous menu will be replaced with V In Measure Instantaneous P active power page if arrow beside active power value of any phase is in rightward direction that phase consumes power if the arrows beside active power value of any phase i
100. t 0 5 Phase Neutral Voltage lt 0 3 Cos 0 390 Frequency 0 390 Relay Outputs 2 pcs Max switching current 5A Max switching voltage 250 VAC Max switching power 1250 VA Digital Input Output Digital IO 2 pcs 5 30V DC 50MA Protection 3750VRMS Insulation Analog Output 2 pcs 2 pcs analog output optional model 4 pcs 4 pcs analog output optional model 0 5V 0 10V 5 5V 10 10V 0 20MA 4 20mA Current Transformer Ratio CTR 1 5000 adjustable Voltage Transformer Ratio VTR 1 5000 adjustable Connection Type 3phase 4 wire 3phase 3 wire KI FA ENT 7 mu Eny Da EE TECHNICAL SPECIFICATIONS Aron Demand Period 1 60 minutes adjustable Operating Temperature 20 C 70 C Storage Temperature 30 C 80 C Relative Humidity Max 95 Sizes W96 x H96 x D72 Protection Class IP40 front IP20 back Power Consumption lt 3VA Klemsan www klemsan com tr
101. t float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float Yo Yo Phase3 voltage third harmonic Phase3 voltage 5th harmonic Phase3 voltage 7th harmonic Phase3 voltage 9th harmonic Phase3 voltage 11th harmonic Phase3 voltage 13th harmonic Phase3 voltage 19th harmonic Phase3 voltage 21st harmonic Phase3 voltage 23rd harmonic Phase3 voltage 25th harmonic Phase3 voltage 27th harmonic JI Phase3 voltage 29th harmonic KI FA ENT 7 mu Energy Analyzer SECTION 4 MODBUS PROTOCOL Address Parameter Description R W Unit Data Type 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float 32 bit float Phase3 voltage 49th harmonic Phase3 voltage 51st harmonic Phase3 current first harmonic Phase3 current third harmonic Phase3 current 5th harmonic Phase3 current 7th harmonic Phase3 current 9th harmonic 366 Phase3 current 19th harmonic Phase3 current 21st harmonic Phase3 current 23rd harmonic Phase3 current 25th harmonic 344 346 348 350 352 354 Phase3 current 27th harmonic
102. t int Output5 Connection 32 bit int 1 10000000000 2500 10000 20 10000000000 Output5 Energy Output5 Width Output5 Multiplier Output6 Mode S 2316 Output6 Energy 2318 Output6 Width RW msec 2500 mum output7Mode TT ss mw 0 20 12324 Output7Energy pns RW 10000000000 e P DD e N N N SL3 SL3 SL3 L3 IE 1 50 2 22 KI FA ENT 7 mu Energy Analyzer SECTION 4 MODBUS PROTOCOL Address Parameter Data Type Descript R W Unit Low Limit High Limit 2326 Output7 Width 32 bit int 5 2500 2328 Output7 Multiplier 10000 DIGITAL INPUT SETTINGS OPTIONAL Input3 Mode RW Input3 Delay RW msec Input4 Mode RW Input4 Delay RW msec Input5 Mode RW O 5 z 3 7 2330 2332 2334 2336 2338 2340 IE 2000 2000 2 msec NN NN mec LEE mec S 2342 Input6 Mode ENSE ESSEN 2344 Input6 Delay RW ms am VW msee ANALOG OUTPUT SETTINGS OPTIONAL SLIO w SLI EN EET RW 100000 2356 AO1 Min Value Rw 100000 CEA EE o NEN CENE BE E EE CREME CENE NN oe BES EM 2 2000 2 2000 SL4 SL4 SL4 SL4 SL4 2000 100000 100000 2 2358 AO1 Multiplier SL12 RW 2360 AO2 Input Mode SL10 RW 2362 AO2 Output Conn SL11 RW 2364 AO2 Max Value 2366 AO2 Min Value RW 2368 AO2 Multiplier SL12 R
103. t is as follows Table4 1 Message Format Address Function 0 252 byte 2 byte There should be a time gap which is atleast 3 5 characters wide between RTU messages For instance when client device requests any information server device should reply after at least a 3 5 character wide time gap Following the response of the server client device should wait 3 5 characters long period before requesting information again Data types used in KLEA are as follows Table 4 2 int 32 bit data type b31 Bit 31 bO Bit 0 MSB Most Significant Bit LSB Least Significant Bit 32 bit integer value Byte order starts from the lowest byte address as bO b1 b2 and so on It is a 32 bit floating point number in IEEE 754 standard Character array in ASCII standard It is only used for Klea device name and Klea configuration name variables 4 4 Implemented functions for MODBUS RTU Protocol Table 4 3 Implemented functions for MODBUS RTU Protocol Function Name Function Code Read Holding Registers 03H decimal value 3 Write Single Register 06H decimal value 6 Write Multiple Registers 10H decimal value 16 Read file record 14H decimal value 20 KI FA AV AYA Energy Analyzer 4 5 Data and Setting Parameters for KLEA 4 5 1 Measured and Calculated Data SECTION 4 MODBUS PROTOCOL Calculated and measured data are read only values Operator programmer can reach all measured and calculated data via
104. time 32 bit float J D L A D et e gt Address Parameter Curr Month tot time Curr Month Q tot Current Month Total Current Timestamp 692 Current Month Total Reactive Power VAr Current Month Total Reactive Power 32 bit unix time Timestamp 694 Curr Month Q tot time Curr Month S tot A 32 bit float Current Month Total Apparent Power Current Month Total Apparent Power 32 bit unix time Timestamp 698 Curr Month S tot time 700 Curr Month L1 P Current Month Phase 1 Active Power W 32 bit float 702 Gar Month time Current Month Phase 1 Active Power Timestamp Curr Month L1 Current Month Phase 1 Current Curr Month L1 I time Current Month Phase 1 Current Timestamp RO Curr Month L1 Q Current Month Phase 1 Reactive Power RO VAr 710 Curr Month L1 O time Current Month Phase 1 Reactive Power Timestamp Curr Month L1 S Current Month Phase 1 Apparent Power Cur Month me Current Month Phase 1 Apparent Power Timestamp Curr Month L2 P Current Month Phase 2 Active Power Cun Month MP ime Current Month Phase 2 Active Power Timestamp Curr Month L2 Current Month Phase 2 Current Curr Month L2 I time Current Month Phase 2 Current Timestamp 72 Curr Month L2 Q Current Month Phase 2 Reactive Power 726 Curr Month L2 Q time Current Month Phase 2 Reactive Power Timestamp Curr Month L2 S Current Month Phase 2 Apparent Power Gur Months Current Month Phase 2 Apparent Power ro Timestamp
105. to present time Current hour active energy value consumed from the beginning of current hour up to present time Previous hour is the active energy value consumed during the previous hour Current time the moment when operator reads the measurement Previous hour Current hour pp i L A amp 13 00 14 00 14 26 Starting time of Starting time of previous hour current hour Figure 3 82 Example for Start of Hour Current day is the active energy value consumed from start of day up to present time Previous day is the active energy value consumed during the previous day Current time the moment when operator reads the measurement Previous day Current day pp A NM er A amp June 18 June 19 June 19 08 00 08 00 16 47 Start of day 8 Figure 3 83 Example for Start of Day e P KI FA AV ma AYA Energy Analyzer SECTION 3 MENUS Current month is the active energy value consumed from start of month up to present time Previous month is the active energy value consumed during the previous month Current time the moment when operator reads the measurement Previous month Current month i A amp April 3 May 3 May 17 07 00 07 00 17 47 Start of day 7 Start of month 3 Figure 3 84 Example for Start of Month Start of day and start of month parameters can be adjusted in Settings gt Setup gt Energy menu Example Assume that start of day is adj
106. tput3 Menu Analog output 3 settings are the same as Output1 Analog output2 gives output from AO3 GND pins 3 2 1 1 6 4 Output4 Menu Analog output 4 settings are the same as Output1 Analog output2 gives output from AO4 GND pins 3 2 1 1 7 Communication Menu KLEA implements MODBUS over serial line with RTU mode In this menu settings related with Modbus RTU are accomplished ETES Measure Meters Alarms Analysis 5 0 A 5 0 A 5 0 A Figure 3 44 Communication Menu 3 2 1 1 7 1 Baud Rate Menu Inside Communication menu press up and down keys to select highlight Baud rate menu item Press OK key and baud rate options will appear on the screen as seen in Figure 3 45 Scroll inside options by pressing up and down keys press OK key to select the desired value Available baud rates are 2400 4800 9600 19200 38400 and 57600 bit sec Settings gt Setup gt Communication Baud rate Slave Id Figure 3 45 Setting Baud Rate a P KI FA ENT 7 mu Energy Analyzer SECTION 3 MENUS 3 2 1 1 7 2 Slave Id In this tab operator can adjust the slave ID For Virtual Keyboard Refer to 3 1 4 Example Slave Id 1 Figure 3 46 Slave Id KLEA can operate in an RS 485 network having a maximum quantity of 247 units As a result Slave Id can be adjusted between 1 and 247 E 3 2 1 1 8 Alarm Menu Inside Setup menu when Alarm is selected press OK key and the options in Figure 3 47 will app
107. ttings are as below Digital output Output Mode T1 kWh Energy 2 Width 100msec When the Tariff 1 import energy T1 kWh reaches 2 kWh a pulse of 100msec will be generated at the output pins DO1 and DO1 Example Digital output Output Mode Digital input Energy When connection type is digital input the Energy tab is not used Width 100msec Multiplier 100 Assume also that Digital input1 mode had been adjusted as counter In this case when Counter1 reaches 100 or multiples of 100 a pulse of 100 msec will be will be generated at the output pins DO1 and DO1 Assume that the digital input 1 counter value was 35 before multiplier adjustment Assume also that operator adjusts Multiplier as 100 Under these conditions Output 1 generates a pulse when digital input 1 counter reaches the values 135 235 335 435 and so On a P KI FA ENT 7 mu Energy Analyzer SECTION 3 MENUS S 3 2 1 1 5 2 Output2 Menu Output 2 applications and settings are the same as Output1 Output2 generates pulse from DO2 and DO2 pins 2 3 2 1 1 5 3 Output3 Menu optional Output 3 applications and settings are the same as Output Output3 generates pulse from DO3 and DO3 pins 3 2 1 1 5 4 Output4 Menu optional Output 4 applications and settings are the same as Output1 Output4 generates pulse from DO4 and DO4 pins E 3 2 1 1 5 5 Output5 Menu optional Output 5 applications and settings are the same as
108. usted as 0 In this case when the system clock is 00 00 value in the Current day will be assigned to previous day Current day resets and starts to count from zero Example Assume that start of month is adjusted as 1 and start of day is adjusted as 0 In this case when system time is 00 00 and day of month is 1 Current month will be assigned to previous month Current month resets and starts to count from zero g Hn 3 2 3 1 2 Exp Active Menu The Consumed Active Energy Menu Exp active menu consists of the same items as Imp active menu Please refer to 3 2 3 1 1 Meters Tariff 1 gt Imp active energy menu for details 3 2 3 1 3 Ind Reactive Menu Inductive Reactive Energy Menu Ind reactive menu consists of the same items as Imp active menu Please refer to 3 2 3 1 1 Meters Tariff 1 gt Imp active energy menu for details 3 2 3 1 4 Cap Reactive Menu Capacitive Reactive Energy Menu Cap reactive menu consists of the same items as Imp active menu Please refer to 3 2 3 1 1 Meters Tariff 1 gt Imp active energy menu for details e P KI FA ENT 7 mu Energy Analyzer SECTION 3 MENUS 3 2 3 2 T1 Rate1 Menu T1 rate1 meter counts between T1 1 start time and T1_2 start time Refer to 3 2 1 1 3 1 and 3 2 1 1 3 2 for T1_1 start time and T1_2 start time settings T1 rate1 menu items are the same as 3 1 3 1 Tariff 1 menu items WE Alar
109. utput6 and output7 this symbol shall be displayed RS485 communication symbol Klea system time X Key in order to cancel any change or to return to the upper menu Left key Up key Down key Right key OK key pressed in order to save any change or to access submenus e P KI FA AV ma AYA Energy Analyzer SECTION 2 INSTALLATION e SECTION 2 INSTALLATION This section provides the information about installation mounting cable routing and connections of Klea 2 1 Preparing for Installation The purchased KLEA may not include all hardware options referred in this document This situation does not constitute an impediment to the electrical installation Assembly and related connections of KLEA must be implemented by authorized persons in accordance with the instructions of user manual The device must not be put into service if the operator is not sure that all connections are correctly accomplished ES 2 2 MOUNTING KLEA is placed vertically into the gap located in the panel Figure 2 1 Mounting KLEA into the Panel After the KLEA is placed into the panel fixing brackets should be installed on Klea and Klea should be fixed to the panel wall with the screws e P KI FA ENT 7 mu Energy Analyzer SECTION 2 INSTALLATION Figure 2 2 Fixing KLEA to the panel There are 2 5mm2 and 1 5mm2 screwed female terminal blocks connected to fixed male terminal blocks on KLEA Remove female
110. value for inductive reactive energy of T2 can be entered in this tab e P KI FA Energy Analyzer SECTION 3 MENUS N 3 2 1 1 3 25 T2 kVArh C Initial value for capacitive reactive energy of T2 can be entered in this tab 3 2 1 1 4 Digital Input Menu Digital input menu consists of Input1 and Input2 menus KLEA digital inputs are used in order to activate Tariff 2 meter and or to count a digital signal ETES Measure Meters Alarms Analysis Network Input1 Device Input2 Energy Digital input Digital output Communication D U A 5 0 A Rate Measure Meters Alarms Analysis Network Device Energy Digital output Communication Figure 3 29 Digital Input Menu With IO option KI FA ev S AYA Energy Analyzer SECTION 3 MENUS 3 2 1 1 4 1 Input Menu Input1 operates when DI1 and GND pins of KLEA are short circuited Input1 menu has two settings e Mode Delay 3 2 1 1 4 1 1 Mode Mode options are as seen below Figure 3 30 Press up and down keys to scroll inside options Press OK key to select the desired option Settings 5 Setup 5 Digital input gt Input1 ode Off Off Delay 100 5nd tariff Counter Figure 3 30 Mode Selection e Assume that for digital input 1 2nd tariff is selected as the mode setting Under this condition when digital input 1 is short circuited activated tariff 1 meter will stop and tariff 2 meter will start to count e Assume that for dig
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