Capacitor Bank Controller - Mid
Contents
1. CLR aan SHLD siin o Powermonitor 3000 Device S eS o ee el SF D D E a oo ow 88 iS amp 2 SHLD RS 485 A LU AIC Powermonitor 3000 Meter A n B SHLD SHLD 3 Connect any additional optional Powermonitor meters RS 485 ports in a daisy chain fashion to to Shld to Shld In certain cases terminating resistors may improve communications robustness Refer to publication 1404 IN007 for more information 4 Connect the Powermonitor meter to the power circuit control power and earth ground See the instructions found in publication 1404 IN007 Publication 1413 UM001C EN P May 2006 16 Installation Publication 1413 UM001C EN P May 2006 PanelView 550 Serial Terminal Serial HMI options 1 Mount the PanelView 550 HMI terminal in a suitable cutout within 5 m 16 ft of the MicroLogix controller Refer to publication 2711 IN009 for detailed installation instructions Mounting Studs 8 3 Top 3 Bottom Protective Installation Label Q lt Self locking Nuts 6 used 8 provided Retainer Base Memory Card awe Retainer ae r e Sote 9 S9 Base Mounting Screws Installation 17 3 Connect 120V ac control power and earth ground2. Power Terminal Block fixed 120 240V ac 120 240V ac 3 Wire 3 Wire European U S Color Code Harmonized Color Code Li L2 GND L1 L2 GND i Green Green Yellow Black Line Earth Ground Brown Line Protective Earth White Blue Neutral Neutral To Power Source To Power Source 4 Connect the communications cable between the MicroLogix 1500 controller Channel 0 and the PanelView 550 terminal serial port 00 D OM F 1 l oo0000b0 zj Ie Printer Port Comm Port 2711 NC21 Publication 1413 UM001C EN P May 2006 18 Installation Publication 1413 UM001C EN P May 2006 PanelView 550 Ethernet Terminal Ethernet HMI Option 1 Mount the PanelView 550 HMI terminal in a suitable cutout within 100 m 328 ft of the MicroLogix controller Refer to publication 2711 IN009 for detailed installation instructions Mounting Studs 8 3 Top 3 Bottom Protective Installation Label Q lt Self locking Nuts 6 used 8 provided
3. Screen Navigation Tree Overview Summary F1 Navigation Menu F2 Operation ALLEN BRADLEY Numeric CIS LY Keypad 5 Jz a ____ Enter Key LEJ Ce Cs Cd Cs aoa Les L77 Lre Lro Go J N Navigation Keys ae ae eee Step Status F3 Power Factor Summary F4 Extended Status F3 Step Control F3 PM3K 1 Data F5 PM3K 2 Data F5 PM3K 3 Data F5 PM3K 4 Data F5 Alarm Summary F9 Configuration F10 Extended Configuration F10 Extended Configuration 2 F10 43 Publication 1413 UM001C EN P May 2006 44 Operation Overview Summary Screen Dyer ien Summars KH HHHH 1 B z Y KUARE HHH a bs 4 J FF HHHH J 16 This is the home screen and displays after you apply power Press the F1 function key to navigate to the Menu screen Navigation Menu Screen Navigation Menu F5 PM3K Data F9 Alarm Summary F3 Step Status F4 PF Summary Bank Status Screen F10 Configuration Bank Status oooaa m an Auto Manual Mode Manual Command Status Step Status Discharge Status Alarm Status CLE Alarm FE Over a aU DRHE ee a DD ee EC DORR eno o R o ALL 22 EEEE z rt Cge 3 Lt tu et Ee La DD eae ee
4. Symbol Datapoint Description Datatype Units Access Privilege Open_8 B3 07 This flag indicates that Contactor 8 has been activated 0 Bit Read Open 1 Active Open_9 B3 08 This flag indicates that Contactor 9 has been activated 0 Bit Read Open 1 Active Open_10 B3 09 This flag indicates that Contactor 10 has been activated 0 Bit Read Open 1 Active Step_Available_1 B64 50 This flag indicates that the step is available to participate in Bit Read automatic control 1 Available Step_Available_2 B64 51 This flag indicates that the step is available to participate in Bit Read automatic control 1 Available Step_Available_3 B64 52 This flag indicates that the step is available to participate in Bit Read automatic control 1 Available Step_Available_4 B64 53 This flag indicates that the step is available to participate in Bit Read automatic control 1 Available Step_Available_5 B64 54 This flag indicates that the step is available to participate in Bit Read automatic control 1 Available Step_Available_6 B64 55 This flag indicates that the step is available to participate in Bit Read automatic control 1 Available Step_Available_7 B64 56 This flag indicates that the step is available to participate in Bit Read automatic control 1 Available Step_Available_8 B64 57 This flag indicates that the step is available to participate in Bit Read auto
5. 2 Install the memory card 7b packed with the Powermonitor meter and retainer Retainer Base Memory Card Eee Retainer s ae TN Base Mounting Screws Installation 19 3 Connect 120V ac control power and earth ground 4 x Power Terminal Block fixed 120 240V ac 120 240V ac 3 Wire 3 Wire European U S Color Code Harmonized Color Code L1 L2 GND L1 L2 GND Black Line Green Brown Line pcreen Yellow Egrth Ground Protective Earth White Blue Neutral Neutral To Power Source To Power Source Install the Ethernet interface module 9 within 45 cm 18 in of the Channel 0 connector on the MicroLogix 1500 controller 1 To Ethernet LAN a gt augm L RSP Ar CABLE 4 EXTERNAL O Verify that the DC Source switch on the Ethernet interface module is in the Cable position Connect the cable 11 between Channel 0 of the MicroLogix 1500 controller and the Ethernet interface module Connect the PanelView 550 terminal to the Ethernet interface module using the Ethernet crossover cable 12 if the system will not be connected to a local area network Connect both the PanelView 550 terminal and the Ethernet interface module to the Ethernet local area network
6. Instance An instance of an object represents a complete iteration of an object and all of its attributes and methods For example the vacuum switch describes a typical vacuum switch Each physical switch would result in one instance of a vacuum switch object Each instance of an object must be managed independently in the software PM See Powermonitor meter Powermonitor meter The power measuring device located at the plant mains There may be more than one Powermonitor meter in a system depending on the number of electrical feeds into the plant Step A single switched circuit in a capacitor or filter bank There are up to ten steps in a bank Others in the industry may also refer to these as stages Publication 1413 UM001C EN P May 2006 66 Glossary Publication 1413 UM001C EN P May 2006 A AIC 14 alarm summary screen 47 alarms 39 assemble controller 11 MicroLogix 1500 11 bank status screen 44 C catalog number explanation 61 communications configuration 20 additional Powermonitors option 22 base unit 20 Ethernet HMI option 21 serial HMI option 21 configuration 20 connect controller 11 AIC 14 MicroLogix 1500 11 PanelView 550 Ethernet 18 PanelView 550 serial 16 Powermonitor 14 controller configuration 26 PanelView 550 HMI 42 use DAT 31 with PanelView 550 33 D description 5 E extended status screen 45 G general information 5 installation 7 mount controller 11 Index AIC
7. Allen Bradley Capacitor Bank Controller 1413 CAP User Manual i Apel il met a rc E i ne int a i 3 i oe Rockwell Jin ma e ea Automation T et er a Important User Information Solid state equipment has operational characteristics differing from those of electromechanical equipment Safety Guidelines for the Application Installation and Maintenance of Solid State Controls publication SGI 1 1 available from your local Rockwell Automation sales office or online at http literature rockwellautomation com describes some important differences between solid state equipment and hard wired electromechanical devices Because of this difference and also because of the wide variety of uses for solid state equipment all persons responsible for applying this equipment must satisfy themselves that each intended application of this equipment is acceptable In no event will Rockwell Automation Inc be responsible or liable for indirect or consequential damages resulting from the use or application of this equipment The examples and diagrams in this manual are included solely for illustrative purposes Because of the many variables and requirements associated with any particular installation Rockwell Automation Inc cannot assume responsibility or liability for actual use based on the examples and diagrams No patent liability is assumed by Rockwell Automation Inc with respect to use of information circui
8. Ground Isolated Alarm Output 10 Capacitor Step 2 8 Control Power Capacitor Step Contractors or Interposing Relays Publication 1413 UM001C EN P May 2006 14 Installation AIC Interface Converter All Configurations 1 Mount the AIC communications converter 4 within 45 cm 18 in of the left edge of the MicroLogix 1500 controller 2 Connect the DB9 to DB9Y cable 5 between Port 1 of the AIC 4 and Channel 1 of the MicroLogix 1500 controller 1 3 Connect a source of 24V dc to the control power terminals on the bottom of the AIC The 24V dc power may be obtained from the DC Power Out terminals on the MicroLogix 1500 controller 4 Verify that the DC Source switch is in the External position and that the Baud Rate selector is set to Auto Powermonitor Meter All Configurations 1 Mount the Powermonitor meter 7 within 1200 m 4000 ft of the AIC communications converter 4 2 Use a 2 conductor shielded cable that you provide to connect the AIC RS 485 port to the Powermonitor RS 485 port Publication 1413 UM001C EN P May 2006 Installation 15 Blue Blue
9. There are three basic sections to PFMGR4 e Power factor alarm The power factor alarming section specifies whether your system KVAR is within its specified range and how long to wait before alarming when it is out of range e Step control The step control section specifies when to actuate or trip a step e Step routine The step routine section specifies what step should be actuated or tripped Publication 1413 UM001C EN P May 2006 52 Add Special Functionality Publication 1413 UM001C EN P May 2006 Power Factor Alarm The ladder logic code for this section has already been written The following is an explanation of the ladder logic code for lines one through four If BUS_NET_KVAR F8 2 falls outside of the limits defined by KVAR_Lag_DB N7 35 and PFMGR4_LEAD_DB_NEG N94 0 then the timer PF_INRANGE__TIMER_4 T93 0 will be started The default time for this timer is 60 seconds When this timer is done timing it will latch KVAR_NOT_ACHEIVED B56 2 and reset the timer If BUS_NET_KVAR F8 2 is within the limits defined by KVAR_Lag_DB N7 35 and PFMGR4_LEAD_DB_NEG N94 0 then reset PF_INRANGE__TIMER_4 T93 0 and unlatch KVAR_NOT_ACHEIVED B56 2 The above process sets the flag KVAR_ NOT_ACHEIVED B56 2 which indicates when the system KVAR is out of your specified limits This flag is used for HMI alarming Step Control The step control consists of three parts Part 1 specifies under what conditions to tell
10. JE F F IF F F Bank Status F3 Ooooc me AO AO AAO AAO AO The steps are listed in vertical columns from 1 10 The first row within the AUTO row commands whether to allow manual or automatic control of each individual step Use the arrow keys to navigate to each individual command The second row within the AUTO row gives the status of each individual step A Automatic M Manual The first row within the MANL row commands the step to be turned on 0 Off 1 On The step must be in Manual mode to allow for manual command of that particular step The second row within the MANL row gives the state status of each individual step ON or OFF The STAT row gives the final status of each individual step Power Factor Summary Screen Power Factor Summary FHH L FHHZ FHES FH 4 Het EH HHHH H HHHH H HHHH H HHHH H HHHH H KUAR HHH HHHH H HHHH H HHH H HHHH H FF HHHH H HHHH H HHHH EOE H HHHH H a diets oooo ad There are no user configurable fields on this screen Press the F1 function key to return to the Overview Summary Screen Publication 1413 UM001C EN P May 2006 Operation 47 Alarm Summary Screen ep Alarm 1 ep Alarm Alarms are listed in the center of the screen Alarms can be cleared and acknowledged by moving the curser over the appropriate field and pressing the Enter key Use the up down keys to change the state and the Enter key to record or save the change Press the Backspace ke
11. 0 PM 4 L1 Current A Read PM_4 12 F14 1 PM 4 L2 Current A Read PM_4 13 F14 2 PM 4 L3 Current A Read PM_4 L12 F14 3 PM 4 L1 L2 Voltage V Read PM_4 123 F14 4 PM 4 L2 L3 Voltage V Read PM_4 L31 F14 5 PM 4 L3 L1 Voltage V Read PM_4 Freq F14 6 PM 4 Frequency Hz Read PM_4 P1 F14 7 PM 4 L1 Real Power W Read PM_4 P2 F14 8 PM 4 L2 Real Power W Read PM_4 P3 F14 9 PM 4 L3 Real Power W Read PM_4 PT F14 10 PM 4 Total Real Power W Read Publication 1413 UM001C EN P May 2006 Add Special Functionality 59 User defined Variables Symbol Datapoint Description Datatype Units Access Privilege PM_4 01 F14 11 PM 4 L1 Reactive Power VAR Read PM_4 02 F14 12 PM 4 L2 Reactive Power VAR Read PM_4 03 F14 13 PM 4 L3 Reactive Power VAR Read PM_4 QT F14 14 PM 4 Total Reactive Power VAR Read PM_4 PF1 F14 15 PM 4 L1 Power Factor Read PM_4 PF2 F14 16 PM 4 L2 Power Factor Read PM_4 PF3 F14 17 PM 4 L3 Power Factor Read PM_4_ PFT F14 18 PM 4 Total Power Factor Read PM_4_ THD F14 19 PM 4 measured Total Harmonic Distortion percentage Read Publication 1413 UM001C EN P May 2006 60 Add Special Functionality Publication 1413 UM001C EN P May 2006 Appendix A Base Unit Catalog Number Explanation 1413 CAP MS PS A Bulletin Number 1413 Power and Energy Controllers Type of Device CAP Capacitor
12. Bank Controller Base Unit Type MS Base controller with standard HMI communicating with one Powermonitor 3000 M5 via RS 485 serial ME Base controller with standard HMI communicating with one Ethernet Powermonitor 3000 M5 via RS 485 serial Series A Series A Additional HMI None Standard DAT HMI only PS Serial PanelView 550 PE Ethernet PanelView 550 The base unit can have serial meter communications or Ethernet meter communications With Serial Powermonitor 1413 CAP MS A Includes base controller and one Powermonitor PM3000 M5 meter on RS 485 Note that MS serial meter communications Communications between the MicroLogix controller and the Powermonitor meter are RS 485 serial Publication 1413 UM001C EN P May 2006 62 Catalog Number Explanation Additional HMI Publication 1413 UM001C EN P May 2006 With Ethernet Powermonitor 1413 CAP ME A Includes base controller and one Powermonitor PM3000 M5 meter on the Ethernet network Note that ME Ethernet meter communications Communications between the MicroLogix controller and the Powermonitor meter are RS 485 serial To add a serial PanelView 550 HMI to the system add PS or PE to the catalog number A PS indicates HMI with serial communications A PE indicates HMI with Ethernet communications When PS or PE is omitted only the DAT is supplied Serial Base Unit with Serial HMI 1413 CAP MS PS A Uses the standard HMI on
13. Current F1x 3 L1 L2 Voltage F1x 4 L2 L3 Voltage F1x 5 L3 L1 Voltage F1x 6 Frequency F1x 7 L1 Real Power F1x 8 L2 Real Power F1x 9 L3 Real Power F1x 10 Total Real Power F1x 11 L1 Reactive Power F1x 12 L2 Reactive Power F1x 13 L3 Reactive Power F1x 14 Total Reactive Power F1x 15 L1 Power Factor F1x 16 L2 Power Factor F1x 17 L3 Power Factor F1x 18 Total Power Factor F1x 19 Measured Total THD Voltage Additional data is available in systems with the Ethernet Powermonitor meter option Publication 1413 UM001C EN P May 2006 50 SCADA Interface Publication 1413 UM001C EN P May 2006 In these systems all Powermonitor meter data may be accessed using the Ethernet communications port integral to the Powermonitor meter Please refer to the Powermonitor 3000 User Manual publication 1404 UM001 for further information PFMGR4 Logic Chapter 5 Add Special Functionality For added functionality custom ladder logic programming and hardware integration are permitted however strict guidelines must be followed to comply with warranty contracts e Altering of existing ladder logic code is prohibited and will void all warranty contracts e Additional functionality can only be implemented by adding additional ladder logic code to subroutine PFMGR4 e Additional subroutines may be written but must be called through PFMGR4 The following sections provide details of PFMGR4 ladder logic programming Overview
14. Er DD a a ET Meeme Tu Publication 1413 UM001C EN P May 2006 Operation 45 The status for the steps is listed in vertical columns from 1 10 There are no configurations on this screen It displays status data only Mode A Automatic which means the step is controlled based on the operation mode selected M Manual which means you can force the step on or off via the keypad Step Status 1 On 0 Off Discharge Status Not Discharging D Discharging Alarm No Alarm In Alarm You can press the F3 function key to navigate to the Extended Status Screen Press the F1 function key to return to the Overview Summary Screen Extended Status Screen bxtended Status Measured KUAR of Opperations 1 HHH E HHHE F i HHHH amp HHH gt HHH HE 7 HHHH zZ HHHHH Y HHH 3 HHH amp HHH 3 HHH amp HHHH 4 HHH 5 HHE H 4 HHHH 5 FHHHH 3 HHH 16 HHH a HHHH 16 HHH Owery ie E Reset Step Contro o o00 0 Press the F6 function key to reset the step counters There are no other user configurable fields on this screen Press the F1 function key to return to the Overview Summary Screen Publication 1413 UM001C EN P May 2006 46 Operation Step Control Screen TENANE a a i Oi i a a o pe D ERD EN D En D EN EN o EN D E o E D E o E A 0 jo jo fo fo jo Jlo fo Jo M F JEI JEN OEI Je Je Je Je E L F Fhe TRE EC PES Re Ia IE S T A T F o fo fo o F E
15. Esc or INT Bit keys discard the new value Publication 1413 UM001C EN P May 2006 32 Installation Publication 1413 UM001C EN P May 2006 The auto configure process begins During this process the controller energizes each capacitor bank step for a short time measures the steps kVARs and records the value This process repeats several times and the results of each trial are averaged When the process is complete the averaged values are copied to the Effinal_StepSize_Sn parameters and the Auto_Detect_Cap_Size flag is reset You must manually configure any parameters that need to change from the default values listed in the table Input Interlock Mode The Input Interlock mode allows fault protection for each capacitor step through the use of fault protection relays Wire normally closed fault protection relays to each input from 0 10 of the controller Wire a normally open momentary pushbutton to Input 11 This pushbutton serves as a reset button During a fault occurrence the controller discharges and locks out the respective capacitor step associated with the fault relay that tripped The fault protection relay wired to Input 0 discharges and locks out all capacitor steps The remaining fault protection relays discharge and lock out their respective capacitor step that is Input 1 discharges and locks out capacitor step 1 In order to place a capacitor step back into the sequence a fault must not be present for that st
16. HMI options Default communications settings are factory configured Publication 1413 UM001C EN P May 2006 22 Installation PanelView 550 Ethernet Configuration Settings Device Parameter MicroLogix 1500 Controller PanelView 550 Operator Powermonitor Meter 1 via NET ENI Terminal IP Address 192 168 0 100 192 168 0 105 192 168 0 101 Subnet Mask 255 255 255 0 255 255 255 0 255 255 255 0 Default Gateway 192 168 0 1 192 168 0 1 192 168 0 1 Publication 1413 UM001C EN P May 2006 To change from the default Ethernet addresses additional software is required The ENI Utility is a free download used to configure the Ethernet interface module The ENI Utility can be found at http www ab com micrologix Follow the links to Get Software and EtherNet IP and DeviceNet Interface Configuration Utilities For information on using the ENI utility please refer to Rockwell Automation Knowledgebase article A19540 Quick Start Getting started with using the ENI Utility You need to supply 24V dc power to the Ethernet Interface while using the ENI utility since the cable to the MicroLogix 1500 controller is disconnected After reconfiguring the Ethernet address cycle power to the Ethernet interface module Changing from the default addresses in the Powermonitor meters must be done using the Powermonitor display module Refer to Powermonitor Meter Configuration on page 23 Changing the PanelView 550 communi
17. Level 14 Core F Cyberport 3 100 Cyberport Road Hong Kong Tel 852 2887 4788 Fax 852 2508 1846 Publication 1413 UM001C EN P May 2006 Supersedes Publication 1413 UM001B EN P January 2006 PN 40055 228 01 3 Copyright 2006 Rockwell Automation Inc All rights reserved Printed in the U S A
18. Manual 1 Auto 24 Step Control B3 25 Capacitor Step 6 Mode 25 B3 26 Capacitor Step 7 Mode 26 B3 27 Capacitor Step 8 Mode 27 B3 28 Capacitor Step 9 Mode 28 B3 29 Capacitor Step 10 Mode 29 B3 30 Capacitor Step 1 Manual Command 0 Command Off 1 30 B3 31 Capacitor Step 2 Manual Command command gn 31 B3 32 Capacitor Step 3 Manual Command 32 B3 33 Capacitor Step 4 Manual Command 33 B3 34 Capacitor Step 5 Manual Command 34 B3 35 Capacitor Step 6 Manual Command 35 B3 36 Capacitor Step 7 Manual Command 36 B3 37 Capacitor Step 8 Manual Command 37 B3 38 Capacitor Step 9 Manual Command 38 B3 39 Capacitor Step 10 Manual Command 39 B3 40 Auto Configure Capacitor Step Sizes Set to 1 to initiate 40 Configuration B3 41 System Alarm 0 No Alarm 1 In 41 Alarm Summary B3 42 Bad Step Alarm mlar 42 B3 43 Power Factor Not Achieved Alarm 43 B3 44 Voltage Alarm 44 B3 45 Voltage THD High Alarm 45 B3 46 Current Unbalance Alarm 46 EXAMPLE Step 4 Alarm status is found at bit address 13 Publication 1413 UM001C EN P May 2006 42 Operation Publication 1413 UM001C EN P May 2006 Use the DAT ai Allen Bradley 01 OFF 0 DE ds C BIT qc INT C enter The data access terminal DAT enters the Bit mode automatically after you apply power Bit mode can also be selected by pressing the BIT key If Bit mode was already active the DAT displays th
19. capacitor steps during a fault occurrence low state condition Inputs 1 10 are wired to normally closed fault protection relays and discharges its respective capacitor step during a fault occurrence Cow state condition If fault protection is not being used for a specific capacitor step then that respective input is wired closed using the controller supplied 24V dc power A normally open momentary pushbutton is wired to Input 11 This pushbutton is used to reset the controller after a fault occurrence Publication 1413 UM001C EN P May 2006 Installation 13 Output 0 is used as an alarm relay and is wired normally open to an external alarm indicator Output 1 10 is wired to normally open contactors for each respective capacitor step Controller Wiring Diagram Capacitor Step Contractors or Interposing Relays Fault Relay Power E rr N oO t iro o N co oa 2 E ig EY ig EY Z amp F o oO Oo Cee foe oee Be esd D 5 5 5 5 5 53 5 5 5 A 2 2 amp E E amp amp amp c 24V dc to AIC Vv RS N sk 1 O O N Q O fo D 4 Dc o 2 colli o 1 1 1 3 1 4 1 6 COM 2 1 9 1 11 Inputs POWER DC o OUT com 1 0 1 2 coma 1 5 1 7 1 8 1 10 248WA 1764 24BWA ze _ 85205 L2 vDC 0 veer VDC 2 vibes vot one 24BWA VAC Outputs L1 0 0 0 4 0 11 D 9 o Spare Output 120V ac Control Power
20. on the screen Number of Samples CTPT Mode Powermonitor Heartbeat Step Tolerance Low Limit Input Mode Disable Enable Step Tolerance Time Restore Defaults Powermonitor Password Kvar Tolerance Disable Enable Publication 1413 UM001C EN P May 2006 Introduction Operating Modes Chapter 3 Operation The capacitor bank controller gathers real and reactive power data using one or more Powermonitor meters The processor manipulates data in engineering units of KVAR and kW The unit does not directly control power factor but rather works to actively minimize imported and exported kVAR The net result of this philosophy indirectly controls power factor and minimizes voltage excursions associated with excessive kVAR export The capacitor bank controller can accommodate up to four different utility feeds and or generators Each feed requires an individual Powermonitor meter The unit sums the kW and kVAR readings from each of the Powermonitor meters to arrive at an aggregate kVAR so that a single capacitor bank could be used to compensate several feeds simultaneously The traditional C k ratio is not required for the capacitor bank controller since we are working in engineering units within the processor Aggregate Power Factor is calculated and displayed using the following formula PF fe KW 3 ggregate Aggregate 7 dw evregate KVAR 2 Aggregate The Powermonitor meter data is gathered with RS
21. the system that a step is waiting to be actuated or tripped Part 2 specifies under what conditions to tell the system that a step should be actuated Part 3 specifies under what conditions to tell the system that a step should be tripped The following ladder logic examples are recommended formats for your custom coding Part 1 If PF_LINRANGE__TIMER_4 T93 0 is done timing e If PF_LEADING B3 6 6 is high and under any user defined conditions latch KVAR_LAG_WAIT_2_ADD B56 0 8 e If PF_LAGGING B3 6 7 is high and under any other user defined conditions latch KVAR_LEAD_WAIT_2_TRIP B56 0 7 Part 1 should be implemented at line three in parallel with the outputs of that rung See Part 1 Example Add Special Functionality 53 Part 1 Example T93 0 0003 rason p Part 2 If KVAR_LAG_WAIT_2_ADD B56 0 8 is high and TOTALSTEP_AVAL_AUTO N70 31 is greater than 0 then output energize KVAR_LAG_ADD_STEP B56 0 4 and unlatch KVAR_LAG_WAIT_2_ADD B56 0 8 This will actuate the required step defined by the step routine See Part 2 Example Publication 1413 UM001C EN P May 2006 54 Add Special Functionality Part 2 Example RT Greater Than A gt B Source A N70 31 10 lt Source B 0 O lt Part 3 If KVAR_LEAD_WAIT_2_TRIP B56 0 7 is high and STEPS_REQUIRED N7 58 is greater than 0 then Output Energize KVAR_LAG_TRIP_STEP B56 0 3 and unlatch KVAR_LAG_WAI
22. treated as a momentary state Bit 5 is used to initiate the step size buffer This bit should also be treated as a momentary state Bit 6 is used for disabling step tolerance The BCD value for each bit is available for easy setup Examples CTPT Mode 2 and Disable Step Tolerance 68 CTPT Mode 0 and Restore Factory Defaults 17 to initiate a restore then 1 CTPT Mode 1 and Initiate Step Buffer 34 to initiate step buffer then 2 N7 44 Unbalance seco The amount of time before alarming and resetting 44 Ext Alarm Time nds the Unbalance Alarm flag Configuration 1 N7 45 Number of The number of Powermonitor meters to include in 45 Configuration Powermonit the aggregate kW and kVAR calculations or meters N7 46 Number of The number of capacitor steps to be controlled 46 Configuration Capacitor Steps N7 47 Operating The operating mode 47 Configuration Mode 0 Manual 1 Linear 2 Balanced 3 Best Fit 4 User Defined 5 Voltage THD N7 59 Number of The number of kVAR samples to average together 1 10 5 Ext Samples when auto configuring capacitor step sizes Configuration 1 1 Please see the Control Word table Control Word Bit Parameter BCD Value 0 CTPT Mode 0 Normal 1 1 CTPT Mode 1 Neutral 2 2 CTPT Mode 2 Retro 4 3 8 Publication 1413 UM001C EN P May 2006 Installation 31 Control Word Bit Parameter BCDVale 4 Restore Factory Defauts Te 5 Initialize Step Buffer 32 6 Disab
23. turned off before a capacitor step is considered fully discharged 60 30 Configuration N7 31 Publication 1413 UM001C EN P May 2006 Nominal Voltage volts The nominal bus voltage of the system 480 Ext Configuration 1 Installation 29 Control and Status Parameters Address Parameter Unit Description Range Default DAT PanelView INT Screen N7 32 Voltage The voltage percentage from nominal that will 1 10 5 32 Ext Threshold determine high and low limits for alarming Configuration High amp Low 1 N7 33 THD The THD at which the controller acts to reduce 0 100 3 33 Ext Voltage voltage THD Configuration Setpoint 1 N7 34 Lead kVAR The leading KVAR limit allowed for the system 20 34 Configuration Deadband before the controller acts to correct lead typically 33 of smallest capacitor step N7 35 Lag KVAR The lagging KVAR limit allowed for the system 35 35 Configuration Deadband before the controller acts to correct lag typically 66 of largest capacitor step N7 36 Step The kVAR percentage of effective that will 0 10 5 36 Ext Tolerance determine low limits for each capacitor step Configuration Low Limit 2 N7 37 Power seco The amount of time the system kVAR must be out 60 37 Ext Factor nds of the range of the lead or lag deadband before Configuration Out of Rang the controller acts to correct 1 e Time N7 38 THD seco The amount of t
24. via a suitable hub or switch using user provided CAT5 Ethernet cables if the system will be connected to a local area network Publication 1413 UM001C EN P May 2006 20 Installation Configuration Communications Configuration Publication 1413 UM001C EN P May 2006 The capacitor bank controller base unit has been set up to require minimal out of box configuration The base system has default communications settings Certain circumstances and options require additional configuration of communications which may include the use of programming software not included with the controller You are required to configure the Powermonitor meters to coordinate them to the power circuit in the base unit and all options Configuration of the Powermonitor meter is performed using the display module The controller requires configuration to coordinate it to the number and size of steps that exist in the capacitor bank being controlled as well as the desired operating mode and other selections Use the data access terminal DAT or the optional PanelView 550 operator terminal to configure the controller Do not operate the capacitor bank controller without first configuring it to suit the controlled capacitor bank and system options Unpredictable operation including undesirable power system effects may result The following sections provide information on configuring communications for the components Base Unit Communic
25. 14 MicroLogix 1500 11 PanelView 550 Ethernet 18 PanelView 550 serial 16 Powermonitor 14 navigation menu screen 44 0 operating modes 37 operation 37 operator interface 39 DAT 40 overview summary screen 44 P PanelView 550 Ethernet 18 PanelView 550 Serial 16 PFMGR4 logic 51 overview 51 power factor alarming 52 step control 52 user variables 55 power factor summary screen 46 Powermonitor 14 configuration 23 parameter descriptions 24 screen 48 set parameters with display module 24 S SCADA interface 49 screen navigation tree 43 special functionality 51 step control screen 46 system architecture 9 ethernet options 10 serial options 9 system components 7 U use DAT 31 use display module 24 Publication 1413 UM001C EN P May 2006 68 Index Publication 1413 UM001C EN P May 2006 Rockwell Automation Support www rockwellautomation com Rockwell Automation provides technical information on the Web to assist you in using its products At http support rockwellautomation com you can find technical manuals a knowledge base of FAQs technical and application notes sample code and links to software service packs and a MySupport feature that you can customize to make the best use of these tools For an additional level of technical phone support for installation configuration and troubleshooting we offer TechConnect Support programs For more information contact your local distributor or Rockw
26. 485 ports using the DF 1 half duplex protocol at a data rate of 19 2 Kbps Each capacitor step can be individually selected to on off or auto status The capacitor discharge timer interlock is in effect in Manual mode to prevent capacitor bank damage In Auto mode a step is available to any of the automatic sequences described below In the On or Off mode a step is unavailable to any automatic operating mode e Manual mode 0 This mode disables all automatic operating modes Manual mode is the default configuration All capacitor steps have a default configuration of auto Publication 1413 UM001C EN P May 2006 38 CTPT Modes Publication 1413 UM001C EN P May 2006 Operation e Linear mode 1 This mode of operation switches the capacitor steps on and off in first in last out FILO order That is the first step on is the last step turned off This is most useful when all the capacitor steps are of similar sized Balanced mode 2 This mode counts the number of opening operations on each capacitor step and switch capacitor steps to balance the number of opening operations equally across all of the employed capacitor steps This mode is also most useful when all of the steps are of similar size Best Fit mode 3 This mode selects capacitor steps to be switched on and off to most closely achieve the target power factor and KVAR needs of the system When the system s kVAR needs increase the a
27. F3 F12 17 PM 2 L3 Power Factor Read Publication 1413 UM001C EN P May 2006 58 Add Special Functionality User defined Variables Symbol Datapoint Description Datatype Units Access Privilege PM_2_PFT F12 18 PM 2 Total Power Factor Read PM_2_ THD F12 19 PM 2 measured Total Harmonic Distortion percentage Read PM3 Data PM_3_11 F13 0 PM 3 L1 Current A Read PM_3_12 F13 1 PM 3 L2 Current A Read PM_3_13 F13 2 PM 3 L3 Current A Read PM_3 112 F13 3 PM 3 L1 L2 Voltage V Read PM_3 123 F13 4 PM 3 L2 L3 Voltage V Read PM_3_L31 F13 5 PM 3 L3 L1 Voltage V Read PM_3_Freq F13 6 PM 3 Frequency Hz Read PM_3_P1 F13 7 PM 3 L1 Real Power W Read PM_3_P2 F13 8 PM 3 L2 Real Power W Read PM_3_P3 F13 9 PM 3 L3 Real Power W Read PM_3_PT F13 10 PM 3 Total Real Power W Read PM_3_01 F13 11 PM 3 L1 Reactive Power VAR Read PM_3_02 F13 12 PM 3 L2 Reactive Power VAR Read PM_3_03 F13 13 PM 3 L3 Reactive Power VAR Read PM_3_0T F13 14 PM 3 Total Reactive Power VAR Read PM_3_PF1 F13 15 PM 3 L1 Power Factor Read PM_3_PF2 F13 16 PM 3 L2 Power Factor Read PM_3_PF3 F13 17 PM 3 L3 Power Factor Read PM_3_ PFT F13 18 PM 3 Total Power Factor Read PM_3_ THD F13 19 PM 3 measured Total Harmonic Distortion percentage Read PM4 Data PM_4 1 F14
28. HAA 8 Ha Lag OB Lead OB 4 HAHHA 9 HHHH HHHH GHBHHE 5 GH 16 FY Operating Mode FE Auto Config KVAR Fo Init KURR Buffer FiA Extended Config The controller tags available on the Configuration screen are shown below in their relative location on the screen Num_Steps StepsActive Eff_StepSize_S1 Eff_StepSize_S6 Eff_StepSize_S2 Eff_StepSize_S7 Num_PMs DischgTimerPreset Eff_StepSize_S3 Eff_StepSize_S8 Eff_StepSize_S4 Eff_StepSize_S9 kVAR_Lead_DB kVAR_Lag_DB Eff_StepSize_S5 Eff_StepSize_S10 Mode Auto_Detect_Cap_Size Initialize_Step_Buffer 3 Press the Direction keys to move the cursor over the desired field and press the Enter key 4 Enter the desired value using the keypad and press Enter to store the new value Pressing the Backspace key cancels a change Publication 1413 UM001C EN P May 2006 5 10 11 samples Taken Installation 35 Press F6 to navigate to the Auto Configure Effective KVAR process TIP The number of measurements to average for each step is entered on the Extended Configuration Screen 2 F10 HH HH Config Step H oooo00 Hit Press F6 to initiate the auto configuration process When done press F10 to return to the Configuration screen Select the desired operating mode by entering the number or by selecting the description in the list box The new value is displayed in both formats To select the mode m
29. L31 F11 5 PM 1 L3 L1 Voltage Read PM_1_Freq F11 6 PM 1 Frequency Hz Read PM_1_P1 F11 7 PM 1 L1 Real Power W Read PM_1_P2 F11 8 PM 1 L2 Real Power W Read PM_1_P3 F11 9 PM 1 L3 Real Power W Read PM_1_PT F11 10 PM 1 Total Real Power W Read PM_1_01 F11 11 PM 1 L1 Reactive Power VAR Read PM_1_02 F11 12 PM 1 L2 Reactive Power VAR Read PM_1_03 F11 13 PM 1 L3 Reactive Power VAR Read PM_1_QT F11 14 PM 1 Total Reactive Power VAR Read PM_1_PF1 F11 15 PM 1 L1 Power Factor Read PM_1_PF2 F11 16 PM 1 L2 Power Factor Read PM_1_PF3 F11 17 PM 1 L3 Power Factor Read PM_1_PFT F11 18 PM 1 Total Power Factor Read PM_1_ THD F11 19 PM 1 measured Total Harmonic Distortion percentage Read PM2 Data PM_2_11 F12 0 PM 2 L1 Current A Read PM_2_ 12 F12 1 PM 2 L2 Current A Read PM_2_13 F12 2 PM 2 L3 Current A Read PM_2_L12 F12 3 PM 2 L1 L2 Voltage V Read PM_2_123 F12 4 PM 2 L2 L3 Voltage V Read PM_2_L31 F12 5 PM 2 L3 L1 Voltage V Read PM_2_Freq F12 6 PM 2 Frequency Hz Read PM_2_P1 F12 7 PM 2 L1 Real Power W Read PM_2_P2 F12 8 PM 2 L2 Real Power W Read PM_2_P3 F12 9 PM 2 L3 Real Power W Read PM_2_PT F12 10 PM 2 Total Real Power W Read PM_2_01 F12 11 PM 2 L1 Reactive Power VAR Read PM_2_02 F12 12 PM 2 L2 Reactive Power VAR Read PM_2_03 F12 13 PM 2 L3 Reactive Power VAR Read PM_2_0T F12 14 PM 2 Total Reactive Power VAR Read PM_2_PF1 F12 15 PM 2 L1 Power Factor Read PM_2_PF2 F12 16 PM 2 L2 Power Factor Read PM_2_P
30. PS A 62 Serial Base Unit with Ethernet HMI 1413 CAP MS PE A 62 Ethernet Base Unit with Ethernet HMI 1413 CAP ME PE A 62 Glossary Index Who Should Use This Manual Additional Resources Preface Read this to familiarize yourself with the rest of the manual It provides information concerning e who should use this manual e where to go for more information Use this manual if you are responsible for designing installing programming or troubleshooting the Capacitor Bank Controller system You should have a basic understanding of electrical circuitry and familiarity with relay logic If you do not obtain the proper training before using this product Please refer to the following publications for additional information on how to assemble install connect operate and maintain your capacitor bank controller Additional Resources For This Information Refer to Publication MicroLogix 1500 Technical Data 1764 TD001 MicroLogix 1500 User Manual 1764 UM001 Powermonitor 3000 Installation Manual 1404 INO07 Powermonitor 3000 User Manual 1404 UM001 Powermonitor 3000 Display Module 1404 INO05 Installation Manual PanelView 550 Installation Guide 2711 INO09 PanelView Standard Operator Terminals 2711 UM014 User Manual Publication 1413 UM001C EN P May 2006 4 Preface Publication 1413 UM001C EN P May 2006 Introduction Description of the Capacitor Bank Controller Chapter 1 Gener
31. R needs Special customer defined THD Linear mode with a voltage THD setpoint Publication 1413 UM001C EN P May 2006 6 General Information e Alarms Bad step indicates blown fuse capacitor failure Target power factor not achieved High Low voltage THD High Current unbalance Metering e Powermonitor data concentrated into the MicroLogix 1500 controller e Phase current line voltage frequency real and reactive power power factor and THD Options e Up to three additional Powermonitor meters to aggregate up to four total feeds e PanelView 550 keypad HMI terminal with serial or Ethernet communications e Ethernet Powermonitor meters to produce power and energy data via your local area network Publication 1413 UM001C EN P May 2006 Chapter 2 Installation The capacitor bank controller system is supplied as a number of components that you assemble install and connect in a suitable enclosure System Components The key number in the component lists are referenced in the illustrations that follow All Configurations Key Quantity Part Number Description 1 1 1764 24BWA MicroLogix 1500 base unit with 120 240V ac control power 12 24V dc inputs and 12 relay outputs 2 1764 LRP MicroLogix 1500 enhanced processor 3 1764 DAT MicroLogix 1500 data access tool 4 1761 NET AIC Advanced interface converter used for PM comms 5 1761 CBL AC00 MicroLogix
32. T_2_ADD B56 0 7 This will trip the required step defined by the step routine See Part 3 Example Part 3 Example Publication 1413 UM001C EN P May 2006 RT Greater Than A gt B Source A Step Routine This section defines what step to use or trip The outputs for the Step Routine are USE_LSTEP_NUM N58 1 and TRIP_STEP_NUM N58 0 When a step is controlled to be used the step equal to the value in USE_STEP_NUM N58 1 will be actuated When a step is controlled to be tripped the step equal to the value in TRIP_STEP_NUM N58 1 will be tripped Add Special Functionality 55 User defined Variables User Variables This chart displays a list of data points and their access rights for use in your custom code Symbol Datapoint Description Datatype Units Access Privilege System Status PF_leading B3 102 This flag indicates the power factor is leading Bit Read PF_lagging B3 103 This flag indicates the power factor is lagging Bit Read Bus_Net_PF F8 00 This register holds the total power factor on the monitored Float Read bus Bus_Net_KW F8 01 This register holds the total real power on the monitored Float W Read bus Bus_Net_KVAR F8 02 This register holds the total reactive power on the Float kVAR Read monitored bus Bus_Volts F8 15 This register holds the three phase average line to line Float V Read voltage as measured by the first P
33. al Information The capacitor bank controller is a replacement for standard fixed function capacitor controllers currently on the market The controller consists of standard off the shelf Allen Bradley hardware with the application ladder code necessary to perform power factor correction The controller is designed to provide the same base functionality as a fixed function capacitor bank controller Also you may add additional code to the controller to fit its functionality to special circumstances The capacitor bank controller is a pre engineered control system containing a MicroLogix 1500 controller a standard data access terminal DAT one or more Powermonitor 3000 modules and an optional additional human machine interface HMD Pre engineered ladder logic code in the controller gathers real and reactive power data from up to four power feeds Cutility feeds and or generators The logic operates on the data in standard engineering units of kVAR and kW and acts to minimize imported and exported reactive power by switching up to 10 steps of capacitance This strategy controls power factor while reducing the likelihood of voltage surge caused by excessive KVAR export Functions e Auto configure e Manual configure e Discharge timer on each step e Selectable operating modes Manual operation Linear last in first out Balanced level out usage of capacitor steps Optimal finds best match of capacitor step to system kVA
34. ations settings are factory configured The MicroLogix 1500 controller settings are contained in the EEPROM memory module Powermonitor meter settings are stored in onboard non volatile memory NVRAM Configuration settings are listed below Installation 21 Communications Settings Device Parameter MicroLogix 1500 Controller MicroLogix 1500 Controller Powermonitor Meter 1 Chan 0 Chan 1 Protocol DF1 Full Duplex DF1 Half duplex Master DF1 Half duplex Slave Baud 19 200 19 2001 19 200 Source ID Node Address 1 0 101 Parity Stop Bits None 1 None 1 None 1 Handshaking None None None Error Checking CRC crcl crcl 0 Default or out of box settings Serial HMI Option Communications settings for the PanelView 550 are factory configured and stored on the flash memory card PanelView 550 Configuration Settings Device Parameter PanelView 550 Operator Terminal Protocol DF1 Full Duplex Baud 19 200 Source ID Node Address 2 Parity Stop Bits None 1 Handshaking None Error Checking CRC Ethernet HMI Option This option allows the PanelView 550 terminal to connect to your Ethernet network It obtains data from the MicroLogix 1500 controller through an Ethernet interface module and your local area network The MicroLogix 1500 controller obtains data from the Powermonitor meters through its Channel 1 serial port in the identical way as the base unit and serial
35. cations settings requires the use of PanelBuilder32 software which is purchased from your local Allen Bradley representative or distributor Additional Powermonitor Meters Option The capacitor bank controller base system and HMI options provide for the addition of up to three more Powermonitor meters The MicroLogix 1500 controller logic is designed to communicate with Powermonitor meters that have the following communications settings If Ethernet Powermonitor meters are added to the system their Ethernet addressing should be configured per your networking requirements Installation 23 Powermonitor Ethernet Communication Settings Device Parameter Powermonitor Meter 2 Powermonitor Meter 3 Powermonitor Meter 4 Node Address 102 103 104 IP Address 192 168 0 UnitID 192 168 0 UnitID 192 168 0 UnitID Subnet Mask 255 255 255 0 255 255 255 0 255 255 255 0 Default Gateway 192 168 0 1 192 168 0 1 192 168 0 1 The Unit ID is listed on the Powermonitor nameplate Powermonitor meter communications settings are changed using the Powermonitor display module Please refer to Powermonitor Meter Configuration Parameters table Powermonitor Meter The table below lists the configuration parameters that must be set up Configuration for correct operation of the capacitor bank controller For additional information regarding Powermonitor meter configuration please refer to the Powermonitor 3000 User Manual publicat
36. controller to AIC cable 9 pin D shell to 9 pin D shell 45 cm 17 1 in long 6 1 1404 DM Powermonitor 3000 display unit with 3 m 9 84 ft cable Base Unit with Serial Meter 1413 CAP MSA 7 1 1413 M5000 A Powermonitor 3000 M5 meter with RS 485 communications port including programmed MicroLogix 1500 8 k memory module with real time clock 1764 MM1RTC Base Unit with Ethernet Meter 1413 CAP MEA 7 1 1413 M5ENT A Powermonitor 3000 M5 meter with Ethernet communications port including programmed MicroLogix 1500 8 k memory module with real time clock 1764 MM1RTC Publication 1413 UM001C EN P May 2006 Optional Serial HMI Serial Meter 1413 CAP MS PSA Key Quantity Part Number Description 7 1 1413 M5000NM A Powermonitor 3000 M5 meter with RS 485 communications port including programmed memory module with real time clock 1764 MM1RTC and programmed 2 MB flash memory card 2711 NM13 8 1 2711 NC21 PanelView terminal to MicroLogix communication cable 9 1 2711 K5A16 PanelView 550 operator terminal with RS 232 DF1 serial Optional Serial HMI Ethernet Meter 1413 CAP ME PSA communications Key Quantity Part Number Description 7 1 1413 M5ENTNM A Powermonitor 3000 M5 meter with RS 485 and Ethernet communications ports including programmed memory module with real time clock 1764 MM1RTC and programmed 2 MB flash memory card 2711 NM13 8 1 2711 NC21 PanelView terminal to MicroLogix control
37. d Status Parameters on page 27 for the Integer Word Elements Address Parameter Value DAT BIT PanelView Screen B3 0 Capacitor Step 1 Status 0 Off 1 On 0 Bank Status B3 1 Capacitor Step 2 Status 1 B3 2 Capacitor Step 3 Status 2 B3 3 Capacitor Step 4 Status 3 B3 4 Capacitor Step 5 Status 4 B3 5 Capacitor Step 6 Status 5 B3 6 Capacitor Step 7 Status 6 B3 7 Capacitor Step 8 Status 7 B3 8 Capacitor Step 9 Status 8 B3 9 Capacitor Step 10 Status 9 B3 10 Capacitor Step 1 Alarm 0 No Alarm 1 In 10 B3 11 Capacitor Step 2 Alarm Alam 11 B3 12 Capacitor Step 3 Alarm 12 B3 13 Capacitor Step 4 Alarm 13 B3 14 Capacitor Step 5 Alarm 14 B3 15 Capacitor Step 6 Alarm 15 B3 16 Capacitor Step 7 Alarm 16 B3 17 Capacitor Step 8 Alarm 17 B3 18 Capacitor Step 9 Alarm 18 B3 19 Capacitor Step 10 Alarm 19 Publication 1413 UM001C EN P May 2006 Operation 41 Binary bit Elements Address Parameter Value DAT BIT PanelView Screen B3 20 Capacitor Step 1 Mode 0 Manual 1 Auto 20 Step Control B3 21 Capacitor Step 2 Mode 21 B3 22 Capacitor Step 3 Mode 22 B3 23 Capacitor Step 4 Mode 23 B3 24 Capacitor Step 5 Mode 0
38. e 14 primary current reflects the current rating on the high side of the neutral current transformer Range and defaults are the same as CT primary current setting e RS 485 node number sets the communications address on the RS 485 network to the MicroLogix 1500 controller Factory set at 101 for PM 1 must be user configured for optional PMs 2 4 Range 1 247 default is the Unit ID e IP address subnet mask default gateway Ethernet port settings required for communications with the user s local area network Set Parameters with the Powermonitor Display Module The Basic Configuration table contains the configuration parameters needed for initial setup of the Powermonitor meter in the base system The table and diagram below describe the basic functionality of the Powermonitor display module Display mode Display Module Key Function Installation 25 Escape Key Returns to parent menu Up Arrow Key Steps back to the previous parameter menu in the list Down Arrow Key Steps forward to the next parameter menu in the list Enter Key Steps into a sub menu or sets as default screen Program mode Returns to parent menu Steps back to the previous parameter menu in the list Steps forward to the next parameter menu in the list Steps into a sub menu selects the parameter to be modified or changes to Edit mode Edit mode Cancels changes to the parameter restores the e
39. e last bit element monitored If Integer mode was active the DAT displays the first bit element after a brief delay during which a working message appears Press the INT key to select Integer mode If Integer mode was already active the DAT displays the last integer element monitored If Bit mode had been active the DAT displays the first integer element after a brief delay during which a working message appears To view controller data select the desired mode Bit or Integer Use the up down keys to scroll to the word or bit address The address and value of the selected parameter is displayed If the parameter is read only the protected indicator will light The DAT checks for controller faults every 10 seconds When the DAT detects a controller fault the display shows FL in the element number field and the value of the controller s major fault word S2 6 is displayed in the value field Please refer to the section on configuration for information on using the DAT to edit configuration parameters Optional PanelView 550 HMI The optional PanelView HMI provides you with a more robust user interface The following screens are provided e Overview Summary Function Keys e Navigation Menu e Bank Status e Extended Status e Step Control e Power Factor Summary e Powermonitoring Data x4 e Alarm Summary e System Configuration
40. ell Automation representative or visit http support rockwellautomation com Installation Assistance If you experience a problem with a hardware module within the first 24 hours of installation please review the information that s contained in this manual You can also contact a special Customer Support number for initial help in getting your module up and running United States 1 440 646 3223 Monday Friday 8am 5pm EST Outside United Please contact your local Rockwell Automation representative for any States technical support issues New Product Satisfaction Return Rockwell tests all of its products to ensure that they are fully operational when shipped from the manufacturing facility However if your product is not functioning it may need to be returned United States Contact your distributor You must provide a Customer Support case number see phone number above to obtain one to your distributor in order to complete the return process Outside United Please contact your local Rockwell Automation representative for States return procedure Power Control and Information Solutions Headquarters Americas Rockwell Automation 1201 South Second Street Milwaukee WI 53204 2496 USA Tel 1 414 382 2000 Fax 1 414 382 4444 Europe Middle East Africa Rockwell Automation Vorstlaan Boulevard du Souverain 36 1170 Brussels Belgium Tel 32 2 663 0600 Fax 32 2 663 0640 Asia Pacific Rockwell Automation
41. ep and a reset must be initiated by pushing the Reset pushbutton Manually Set Configuration Parameters Use the DAT to manually change the controller configuration parameters 1 Select Integer mode 2 Scroll to and select the desired configuration parameter Refer to the Control and Status Parameters table on page 27 3 Press the Enter key to edit the parameter 4 Use the up down keys to change the value of the parameter If the data is protected or undefined pressing the TIP up down key scrolls to the next data element Installation 33 5 Press the Enter key to store the new value Esc or INT Bit keys will discard the new value 6 Repeat steps 2 5 as needed Configuration with the PanelView 550 Terminal Optional HMI Only The optional PanelView 550 terminal provides you with a more user friendly interface to the capacitor bank controller Use the function keys to navigate through the screens and enter data as needed using the keypad PanelView 550 A Allen Bradley Kl HEH KWAR Ha PF HHH Configure the capacitor bank controller using the optional PanelView terminal 1 Press the F2 key to view the Menu from the Overview screen Publication 1413 UM001C EN P May 2006 34 Installation 2 Press F10 to view the Configuration screen from the Menu Configuration Mum Steps Active Effective KWAR HH 1 HABER 6 HHHH Num PM s Disch Tmr HHH HHHH COo 2
42. figurable time delay an alarm will be generated and the system alarm contact closes The alarm is reset when the THD_Y falls below setpoint for the same period of time Unbalance This alarm is set when the average neutral current exceeds a preset maximum for a configurable period of time It is reset using the same timer Operator Interface The capacitor bank controller offers three types of operator interface Data access terminal DAT A simplistic operator terminal physically attached to the controller that provides read write access to configuration and operating data The DAT is provided with the base unit and all optional configurations Serial PanelView 550 A comparatively robust operator interface terminal that provides selectable configuration and operating screens and a keypad for navigation and data entry Communications with the controller is through a serial point to point connection The serial PanelView is offered in the Serial HMI option only Publication 1413 UM001C EN P May 2006 40 Operation Binary bit Elements e Ethernet PanelView 550 A similar HMI to the serial PanelView but using Ethernet communications offered with the Ethernet HMI option only Data Access Terminal DAT The data access terminal DAT provides access to 48 integer and 48 binary data registers The Binary bit Elements and Integer Word Elements tables define how these register assignments are made See Control an
43. ime after all capacitor steps are 38 Ext Alarm Time nds actuated and THD is still above the setpoint Configuration limit before setting the THD High Alarm 1 N7 39 Step seco The amount of time after a capacitor step is 39 Ext Tolerance nds actuated before taking a sample reading of the Configuration Time system kVAR difference to determine if the 2 capacitor step is above the step tolerance low limit N7 40 Voltage seco The amount of time the bus voltage must be 40 Ext High nds below the high limit before resetting the Voltage Configuration In Range High Alarm 1 Time N7 41 Voltage Low seco The amount of time the bus voltage must be above 41 Ext In Range nds the low limit before resetting the Voltage Low Configuration Time Alarm 1 N7 42 Voltage seco The amount of time after the Voltage High and 42 Ext In Range nds Voltage Low alarms have been reset before Configuration Time signifying that the voltage is in an acceptable 1 range Publication 1413 UM001C EN P May 2006 30 Installation Control and Status Parameters Address Parameter Unit Description Range Default DAT PanelView INT Screen N7 43 Control This is the control word for the capacitor bank 43 Ext Word controller The first three 3 bits of the control Configuration word is used to set the CTPT Mode Bit 4 is used 2 to initiate a restore of factory defaults This should be
44. ion 1404 UMO001 Powermonitor Meter Configuration Parameters Parameter PM 1 PM 214 PM 314 pm al Wiring model PT VT primary voltage PT VT secondary voltage CT primary current 14 primary current RS 485 node number 10113 102 103 104 IP address 192 168 0 101 Subnet maskl 255 255 255 0 Default gateway address 192 168 0 1 1 Wiring mode must be Wye when using NEU or Retro CTPT mode Applies only to Ethernet Powermonitor meter options Default factory setting for base unit Optional additional Powermonitor meters Publication 1413 UM001C EN P May 2006 24 Installation Publication 1413 UM001C EN P May 2006 Parameter Descriptions e Wiring mode selected to match the physical connections to the power system Delta 3 CT Delta 2 CT Direct delta 3 CT Direct delta 2 CT Open delta 3 CT Open delta 2 CT Wye default Single phase e PT VT primary voltage reflects the voltage rating on the high side of the potential voltage transformers Range 1 10 000 000 V default 480 e PT VT secondary voltage reflects the voltage rating on the low side of the potential voltage transformers Range 1 600 V default 480 e CT primary current reflects the current rating on the high side of the phase current transformers Range 1 10 000 000 A default 5 The CT secondary current is also adjustable but the default value of 5 A is standard
45. le Step Tolerance 0 False 1 True 64 7 Enable Input Mode 0 False 1 True 128 Use the DAT for Configuration The data access terminal DAT provides a basic configuration interface for the capacitor bank controller In Integer mode the DAT provides read write access to the configuration parameters listed in the Control and Status Parameters table You may also use the DAT in Bit mode to automatically detect and configure the capacitor bank step sizes The DAT enters the Bit mode automatically after applying power Bit mode can also be selected by pressing the BIT key If Bit mode was already active the DAT displays the last bit element monitored If Integer mode was active the DAT displays the first bit element after a brief delay during which a working message appears To select Integer mode press the INT key If Integer mode was already active the DAT displays the last integer element monitored If Bit mode had been active the DAT displays the first integer element after a brief delay during which a working message appears Auto contigure Capacitor Step Sizes Use the DAT to automatically configure the step sizes 1 Select Bit mode 2 Scroll to and select bit 40 3 Press the Enter key to edit the bit 4 Use the up down key to change the value of the bit to 1 TIP If the data is protected or undefined pressing the up down key scrolls to the next data element 5 Press the Enter key to store the new value
46. ler communication cable 9 1 2711 K5A16 PanelView 550 operator terminal with RS 232 DF1 serial Optional Ethernet HMI 1413 CAP ME PEA communications Key Quantity Part Number Description 7 1 1413 M5ENTNM A Powermonitor 3000 M5 meter with RS 485 and Ethernet communications ports including programmed memory module with real time clock 1764 MM1RTC and programmed 2 MB flash memory card 2711 NM13 10 1 1761 NET ENIW MicroLogix Ethernet interface module with Web interface 11 1 1761 CBL AM00 MicroLogix controller to AIC cable 8 pin DIN to 8 Pin DIN 45 cm 17 1 in long 12 1 3 05 m 10 ft CAT5 Ethernet crossover cable 13 1 2711 K5A20 PanelView 550 operator terminal with Ethernet IP communications Publication 1413 UM001C EN P May 2006 Optional Additional Powermonitor Meters The controller is designed to operate with up to three additional Powermonitor meters Additional Powermonitor meters must be ordered separately Please contact your local Allen Bradley distributor for information Installation 9 System Architecture This section illustrates the base system with the serial and Ethernet options Base System with Serial Options ron 3 jj Optional Serial HMI Optional Additional Powermonitor Meters Publication 1413 UM001C EN P May 2006 10 Installation Base System with Ethernet Options gt lt lt N H i d ET oa Bea ae _ a ae
47. matic control 1 Available Step_Available_9 B64 58 This flag indicates that the step is available to participate in Bit Read automatic control 1 Available Step_Available_10 B64 59 This flag indicates that the step is available to participate in Bit Read automatic control 1 Available Power Factor Control KVAR_Lead_Wait_2_T B56 0 7 This flag indicates that a step is waiting to be tripped Bit Read Write rip KVAR_Lag_Wait_2_Ad B56 0 8 This flag indicates that a step is waiting to be added Bit Read Write d KVAR_Lead_Trip_Step B56 0 3 This flag commands the system to trip the selected step Bit Read Write KVAR_Lag_Add_Step Bd6 0 4 This flag commands the system to add the selected step Bit Read Write Trip_Step_Num N58 0 This register holds the number of the step to release Int Read Write Use_Step_Num N58 1 This register holds the number of the step to activate Int Read Write PM1 Data PM_1_11 F11 0 PM 1 L1 Current A Read PM_1_12 F11 1 PM 1 L2 Current A Read PM_1_13 F11 2 PM 1 L3 Current A Read PM_1_L12 F11 3 PM 1 L1 L2 Voltage V Read Publication 1413 UM001C EN P May 2006 Add Special Functionality 57 User defined Variables Symbol Datapoint Description Datatype Units Access Privilege PM_1_L23 F11 4 PM 1 L2 L3 Voltage Read PM_1_
48. monitor Display Module 24 Controller Configuration o oo ates es aa 26 Use the DAT for Configuration nasasa aaaea 31 Configuration with the PanelView 550 Terminal Optional HMI Only scouts eth aaa 33 Chapter 3 Introd c oi e ses ras tear Re 68 ana SIEES FSS PETERS SS 37 Operating Modes jig te head kG de oe Seg Ane Gee he dee 9 37 CTET MOE S iou sci ke eee poke kph E E Aamo 24a 38 PIAL 3 Ae gate tan De Gee DEY LO Oe OI EEE a DLS Heed 39 Operator WMC ACE apa doth aaa a a Forse cn bor ga Reged abcess er hate A 39 Data Access Terminal DAT 5 12 te8o5 oa Ges ce hans 40 Optional PanelView 550 HMMs naaa aana 42 Publication 1413 UM001C EN P May 2006 2 Table of Contents SCADA Interface Add Special Functionality Catalog Number Explanation Publication 1413 UM001C EN P May 2006 Chapter 4 Power circuit Parameters o hie tase ved BS Aas 49 Chapter 5 PEMGRE LOGIC ig ce chu haters oh 4 bai a od eet a tty Weeden 51 OVELVICW aea aa E e PM ale ee E a WEP DOM a A ele d 51 Power Factor Alarm gig BEG CERES BERTH 52 Step Contool Geis eae eel ONs Pee AS ee ees 52 Step Routine n aaau aaa eae tale ade Reo 54 Uset Vana les ens aonn u ce Ges a a Gaa 55 Appendix A Base Unitra nAn le alin a E AN E EN E N Ms 61 With Serial Powermonitor 1413 CAP MS A 61 With Ethernet Powermonitor 1413 CAP ME A 62 Additonal HMI uA of ec noia aA BE oO e a ee 62 Serial Base Unit with Serial HMI 1413 CAP MS
49. monitors by 3 Operation 39 Alarms 2 Retro mode One CT wired on the A phase and one PT wired from phases B to C are installed on a three phase circuit The power monitors must be set up in Wye wiring mode The controller swaps the values of the real and reactive power data produced by the power monitors and multiplies them by 3 This mode is particularly useful in retrofit applications Bad Step This alarm indicates a blown fuse and or loss of capacitor condition The controller measures actual VAR output from a capacitor step averages and compares this value with the original effective capacitor value When actual VAR is more than the user configurable StepKvarTolerance default 5 below the effective step size for a user configurable delay default 30 seconds the alarm is activated The alarm is reset when actual VAR output is greater than or equal to the setpoint for the same delay The step will be latched as tripped offline if the VAR output falls below 90 of nominal Target power factor not achieved If actual power is less than setpoint for a user adjustable number of seconds then set the alarm flag High and Low Voltage If BusVolts is outside either limit this alarm is activated immediately After the voltage returns to the proper range for a configurable amount of time this alarm is reset THD_V above setpoint If all available steps are added and THD_V remains above the setpoint longer than the con
50. n Operation Table of Contents Who Should Use This Manual 0 00000 3 Additional Resources naaa aaa aaa 3 Chapter 1 Introduchon naoa n i A nce a NA E os E NEE E 5 Description of the Capacitor Bank Controller 5 PUNCUONS etaura Gin OO nde Sse Ce A eee tte Cae hae a Ge aad 5 OOS si ss Ao atin a tg We E ua Domes Poche woe Oe ee ae 6 Chapter 2 System Components nu EELER AN 7 Optional Additional Powermonitor Meters 8 System Architecture iv ita eae eee Dale Me dehy 9 Base System with Serial Options 4 9 Base System with Ethernet Options 10 Assemble Mount and Connect Your Controller 11 MicroLogix 1500 Controller All Configurations 11 AIC Interface Converter All Configurations 14 Powermonitor Meter All Configurations 14 PanelView 550 Serial Terminal Serial HMI options 16 PanelView 550 Ethernet Terminal Ethernet HMI Option 18 Configuration 5 655 5 ob Lage sos 4 Nek oe Asses a G89 Be Ao aeee lah sas pasey Heke dosed 4s 20 Communications Configuration 000 20 Base UMIA E eee ae ea ee aa ee ee eg 20 Serial HMI Option 25 pooh 4 o 0 SS os PS Pete Sees 21 Ethernet HMI ODO 4nd a ee oF Rates Leek eRe Ks 21 Additional Powermonitor Meters Option 22 Powermonitor Meter Configuration 23 Parameter Descriptions n osana 24 Set Parameters with the Power
51. ndary 14 Primary 14 Secondary Dee 3 Ethernet Options 1 Base Unit And All Options 2 Additional Power Monitor Options Default Gateway Controller Configuration You may view and edit the first 48 of the CAP Bank Controller parameters using the data access terminal DAT The optional PanelView 550 terminal in either of the HMI options provides configuration screens for viewing and editing the parameters as indicated in the Control and Status Parameter table Screens 1 Configuration X1 Extended Configuration 1 X2 Extended Configuration 2 The range of each integer parameter is 0 32 768 unless otherwise specified The parameters are stored in contiguous locations in a data file N7 0 47 in the controller Publication 1413 UM001C EN P May 2006 Installation 27 Control and Status Parameters Address N7 0 Parameter Capacitor Step 1 Measured Size Unit kVAR N7 1 Capacitor Step 2 Measured Size kVAR N7 2 Capacitor Step 3 Measured Size kVAR N7 3 Capacitor Step 4 Measured Size kVAR N7 4 Capacitor Step 5 Measured Size kVAR N7 5 Capacitor Step 6 Measured Size kVAR N7 6 Capacitor Step 7 Measured Size kVAR N7 7 Capacitor Step 8 Measured Size kVAR N7 8 Capacitor Step 9 Measured Size kVAR N7 9 Capacitor Step 10 Measured Size kVAR Descripti
52. on Measured and averaged capacitor size for each step Default DAT INT PanelView Screen Configuration Configuration Configuration Configuration Configuration Configuration Configuration Configuration Configuration Configuration Publication 1413 UM001C EN P May 2006 28 Installation Control and Status Parameters Address N7 10 Parameter Capacitor Step 1 Effective Size Unit kVAR N7 11 Capacitor Step 2 Effective Size kVAR N7 12 Capacitor Step 3 Effective Size kVAR N7 13 Capacitor Step 4 Effective Size kVAR N7 14 Capacitor Step 5 Effective Size kVAR N7 15 Capacitor Step 6 Effective Size kVAR N7 16 Capacitor Step 7 Effective Size kVAR N7 17 Capacitor Step 8 Effective Size kVAR N7 18 Capacitor Step 9 Effective Size kVAR N7 19 Capacitor Step 10 Effective Size kVAR Description Nameplate capacitor size for each step Default 50 DAT INT PanelView Screen Configuration 50 Configuration 50 Configuration 50 Configuration 50 Configuration 50 Configuration 50 Configuration 50 Configuration 50 Configuration 50 Configuration N7 30 Capacitor Discharge Time seco nds The amount of time after a capacitor step is
53. ove the curser over the list box and press Enter Press the Direction keys to scroll through the selections Press Enter again to select the displayed mode F1 returns to the Overview screen Publication 1413 UM001C EN P May 2006 36 Installation F10 navigates to the first Extended Configuration screen This screen operates in the same way as the initial configuration screen E k ci 2 Mominal YT VT Seale Meas Buss YT PFT imer D a o UT Ranges UTInrangeT imer Meutrallim Lee aaa o HiLimit TimerPreset 4THOSetPt NetNeutral HHHHHH GHHHE HHEH LoLimit TimerPreset THOT imer T imerPreset THHHHHHE HHHH CHH HH The controller tags available on the Configuration screen are shown below in their relative location on the screen NominalVoltage Nominal_Voltage_Scale Bus_Volts PF_inRange_Timer_Preset VoltageRange InRangeTimerPreset Unbalanced_Limit HighLimit HighLimitTimerPreset THD_V_SetPoint Net_Current LowLimit LowLimitTimerPreset THD_Timer_Preset Unbalance_Timer_Preset 12 Press F10 to navigate to the Extended Configuration 2 screen from the Extended Configuration 1 screen E Conti Samples to Awg FE FH Read CTPT Mode Interwal aes Standard tmsec KUVAR Tol x HH HH im Input Mode KVAR Tol Timer Fret CE Toi PM Password R Enabled F16 Config ooo The controller tags available on the Configuration screen are shown below in their relative location
54. owermonitor meter Net_Current F8 16 This register holds the net current obtained from the Float A Read Powermonitor meter THD_V F8 17 This register holds the total harmonic distortion voltage Float Read as measured by the first Powermonitor meter KVAR_Lead_DB N7 34 Leading kVAR dead band limit typically 33 of smallest Int Read step KVAR_Lag_DB N7 35 Lagging KVAR dead band limit typically 66 of largest Int Read step PF_inRange_Timer_4 T93 0 Time to wait for PF to come into acceptable range before Timer Read alarming Step Status Open_1 B3 00 This flag indicates that Contactor 1 has been activated 0 Bit Read Open 1 Active Open_2 B3 01 This flag indicates that Contactor 2 has been activated 0 Bit Read Open 1 Active Open_3 B3 02 This flag indicates that Contactor 3 has been activated 0 Bit Read Open 1 Active Open_4 B3 03 This flag indicates that Contactor 4 has been activated 0 Bit Read Open 1 Active Open_5 B3 04 This flag indicates that Contactor 5 has been activated 0 Bit Read Open 1 Active Open_6 B3 05 This flag indicates that Contactor 6 has been activated 0 Bit Read Open 1 Active Open_7 B3 06 This flag indicates that Contactor 7 has been activated 0 Bit Read Open 1 Active Publication 1413 UM001C EN P May 2006 56 Add Special Functionality User defined Variables
55. s JE a CT oe a Da aaa a al see eee PO le i Optional Etherhet HMI 1 I 1 Ethernet Local Area Network by Customer 1 1 TIP Publication 1413 UM001C EN P May 2006 Optional Additional Powermonitor Meters Ethernet crossover cable 12 is used if there is no connection to a local area network Installation 11 Assemble Mount and This section describes how to mount the MicroLogix 1500 controller and connect it to an AIC interface and PanelView module for use Connect Your Controller with the capacitor bank controller MicroLogix 1500 Controller All Configurations TIP Please refer to Publication 1746 UM001 Chapter 2 for information on performing these tasks 1 Mount the MicroLogix 1500 base unit 1 Mounting Template Publication 1413 UM001C EN P May 2006 12 Installation 3 Install the MicroLogix memory module 7a This module may be found packaged with the Powermonitor meter 7 4 Install the data access terminal 3 5 Connect the MicroLogix 1500 controller to 120V ac control power earth ground capacitor step contactors or interposing relays as required and an alarm circuit as shown in the wiring diagram Wire the Controller Fault protection relays can be used to immediately discharge all or specific capacitor steps during a fault occurrence Input 0 is wired to a normally closed fault protection relay and discharges all
56. the front of the MicroLogix controller and includes a small serial PanelView 550 HMI in addition Serial Base Unit with Ethernet HMI 1413 CAP MS PE A Uses the standard HMI on the front of the MicroLogix controller and includes a small Ethernet PanelView 550 HMI in addition Ethernet Base Unit with Ethernet HMI 1413 CAP ME PE A Uses the standard HMI on the front of the MicroLogix controller and includes a small Ethernet PanelView 550 HMI in addition This option includes Ethernet communications from HMI to both the MicroLogix controller and the Powermonitor PM 3000 M5 meter The controller still uses RS 485 to gather control data from the PM directly Catalog Number Explanation 63 Summary Catalog Number Powermonitor PanelView MicroLogix MicroLogix MicroLogix Meters Terminals Controller to PM Controller to Controller to Communications PanelView SCADA Terminal Communications Communications 1413 CAP ME A Enet None Serial None Serial 1413 CAP ME PEA Enet Enet Serial Enet Enet 1413 CAP ME PS A Enet Serial Serial Serial None 1413 CAP MS A Serial None Serial None Serial 1413 CAP MS PS A Serial Serial Serial Serial None Publication 1413 UM001C EN P May 2006 64 Catalog Number Explanation Publication 1413 UM001C EN P May 2006 Glossary Bank An overall capacitor or tuned filter assembly This controller is designed to manage and control one bank consisting of 10 steps
57. ts equipment or software described in this manual Reproduction of the contents of this manual in whole or in part without written permission of Rockwell Automation Inc is prohibited Throughout this manual when necessary we use notes to make you aware of safety considerations Identifies information about practices or circumstances that can cause an explosion in a hazardous environment which may lead to personal injury or death property damage or economic loss IMPORTANT Identifies information that is critical for successful application and understanding of the product Identifies information about practices or circumstances that can lead to personal injury or death property damage or economic loss Attentions help you identify a hazard avoid a hazard and recognize the consequence ATTENTION SIMA a vaGi Labels may be located on or inside the equipment for example a drive or motor to alert people that dangerous voltage may be present ETETEA Labels may be located on or inside the equipment for example a drive or motor to alert people that surfaces may be dangerous temperatures gt gt eiie Allen Bradley Rockwell Automation ControlLogix Powermonitor 3000 MicroLogix PanelView 550 PanelBuilder32 and RSLinx are trademarks of Rockwell Automation Inc Trademarks not belonging to Rockwell Automation are property of their respective companies Preface General Information Installatio
58. vailable step or steps with the closest aggregated KVAR rating is added On decreasing KVAR demand steps are switched off in similar fashion Special mode 4 This mode is reserved for customer defined switching sequences not described above including voltage current and time of day type functions Special switching mode might include switching on parameters such as PF current voltage time of day weekends weekdays or seasonal adjustments Refer to Add Special Functionality on page 51 THD mode 5 This mode selects capacitor steps to be added in a linear fashion for example step 1 step 2 until the THD_V is below the setpoint for a user configurable time delay default 60 seconds The system will start to remove capacitor steps when the THD_YV is 1 below the setpoint for the user configurable delay The CTPT mode configures the capacitor bank controller to be connected to current transformers CTs and potential transformers PTs in one of three ways e 0 Normal mode CTs and PTs are installed in a typical three phase configuration The controller uses the real and reactive power data produced by the power monitor s without further processing e 1 NEU mode One CT wired on the A phase and one PT wired from phase A to neutral are installed on a three phase circuit The power monitors must be set up in Wye wiring mode The controller multiplies the real and reactive power data produced by the power
59. xisting value and returns to Program mode Increments the parameter menu value Decrements the parameter value Saves the parameter change to Master Module and returns to Program mode The following flow chart shows the menu structure of the Powermonitor meter parameters to be configured for the base unit and various options Use the Enter and Escape keys to move between levels and the arrow keys to select options within a level Once the parameter you wish to configure is selected press the Enter key to edit the parameter In Edit mode the parameter s displayed value will blink Use the arrow keys to change the value of the displayed parameter Press the Enter key to save the displayed value in the Powermonitor meter The display momentarily displays the previous value then the new value In the chart the configuration items for the capacitor bank controller are highlighted with a grey background Publication 1413 UM001C EN P May 2006 26 Installation Menu Flowchart Nact heri Wetvin Curreet Level Within Currant Laval Subnet mask f Chart Key PET Display Ate Program Am amp P ICSE Password i j B Salect J y Basic HO Not Used For Cap Bank Advanced gt Controller Setup Level 2 Native Comm 2 Optional Comm Wiring Mode Protocol IP Address PT Prima Dela Level 3 uy J PT Secondary Baud CT Primary Address CT Seco
60. y to cancel the change Press the F1 function key to return to the Overview Summary Screen Publication 1413 UM001C EN P May 2006 48 Operation Powermonitor Meter Screen There are four instances of this screen one for each of the Powermonitor meters Amps U L L KEH KEJAR FF Freq CHz Power Monitor 1 Dats Fh A Fh B Fh C HHHH H HHHH HO HHHH H THEE HHH HEHE THEE HHHHHH HEHE JHE HHHHHH EHH HHHH H HHHH H HHHH H Total HHH HEE HHHHH HHH H HHHH FS Cycle Through Meters 00 000 There are no user configurable fields on this screen Press the F5 function key to cycle to the next Powermonitor Data Screen Press the F1 function key to return to the Overview Summary Screen Publication 1413 UM001C EN P May 2006 Power circuit Parameters SCADA Interface Chapter 4 The capacitor bank controller reads power circuit parameters from the Powermonitor meters and makes that data available in its data table for use by other applications such as SCADA or HMI systems The following table lists the Powermonitor meter data available in the controller The symbol x indicates the Powermonitor meter number Addresses related to Powermonitor meter no 1 begin with F11 0 addresses related to Powermonitor meter no 2 begin with F12 0 Available Powermonitor Meter Data Address Parameter F1x 0 L1 Current F1x 1 L2 Current F1x 2 L3
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