UG-1056 NPC eCAP-9040 User's Guide€¦ · NPC eCAP-9040 User's Guide ALL RIGHTS RESERVED NOTICE The information in this document has been carefully checked and is believed to be

UG-1056 NPC eCAP-9040

User's Guide

December 2018

NPC eCAP-9040 User's Guide UG-1056

Copyright © 2017 by QEI

NPC eCAP-9040 User's Guide ALL RIGHTS RESERVED

NOTICE

The information in this document has been carefully checked and is believed to be accurate. However, no responsibility is assumed or implied for inaccuracies. Further-more, QEI, reserves the right to make changes to any products herein described to improve reliability, function or design. QEI does not assume liability arising the application or use of any product or circuit described herein; neither does it convey any license under its patent rights nor the rights of others.

This manual and all data contained constitutes proprietary information of QEI and shall not be reproduced, copied or disclosed to others, or used as the basis for manufacture without written consent of QEI.

45 Fadem Road Springfield, NJ 07081 Phone: (973) 379-7400 Fax: (973) 379-2138 Web Site: wwwqeiinc.com

http://www.cgautomationusa.com/

UG-1056 NPC eCAP-9040 User's Guide

Copyright © 2017 QEI Revisions i

Revisions

Revision Description Date

A Release July 2007

B Updated Formatting October 2012

C

D

Updated Formatting

Updated QEI Address

May 2017

December 2018


Copyright © 2017 QEI Introduction 3

Contents

1. Introduction ..............................................................................4 1.1 Specifications ......................................................................... 5

1.1.1 Size ......................................................................... 5 1.1.2 Temperature Sensor ............................................... 5 1.1.3 Operation Counter .................................................. 5 1.1.4 Current Sensor ....................................................... 5 1.1.5 Capacitor Switch Relays ......................................... 5 1.1.6 Supply Voltage ........................................................ 5 1.1.7 Line Frequency ....................................................... 5 1.1.8 Local Switching Strategy ........................................ 5 1.1.9 Power Consumption ............................................... 5 1.1.10 Environment ............................................................ 5 1.1.11 Case ........................................................................ 5 1.1.12 Radio: ...................................................................... 6 1.1.13 Radio Power Supply ............................................... 6

2. Installation ................................................................................7 2.1 Making Connections .............................................................. 7 2.2 Grounding .............................................................................. 7 2.3 4-Wire System Installation ..................................................... 8 2.4 Line Current Measurement .................................................. 10 2.5 Meter Socket Mounting ........................................................ 11

3. Hardware Description ............................................................12 3.1 Front Panel Layout ............................................................... 12

3.1.1 Fuses and Fuseholders ........................................ 15 3.1.2 Battery ................................................................... 15 3.1.3 Clock ..................................................................... 15

4. Operation ................................................................................17 4.1 Navigating the LCD Display – an Example: ......................... 17 4.2 Live Values ........................................................................... 19 4.3 Local Switching Strategy Configuration ............................... 20 4.4 Other Configuration Settings ............................................... 22 Other Configuration Settings (contd.) ........................................... 23 Other Configuration Settings (contd.) ........................................... 24

5. Misc Technical Data ...............................................................25 5.1 Communications Board........................................................ 27

5.1.1 Jumpers - Factory Configuration .......................... 27 5.1.2 TX / RX LEDs ...................................................... 28 5.1.3 Setting the Baud Rate .......................................... 29

5.2 Radio Interface Board .......................................................... 29 5.2.1 DB9 RS-232 Cable: .............................................. 31

5.3 Local/Remote Front Panel Switch ....................................... 32

6. DNP3 Device Profile w/Point List ..........................................33 Version 1.0 .................................................................................... 33


4 Introduction Copyright © 2017 QEI

1. Introduction

The NPC eCAP-9040 is part of QEI’s family of Capacitor Bank Controllers. The eCAP contains a Telemetric DNP-RTM (Remote Telemetry Module). The SCADA analog, status, and control points are remotely accessible through this module.

The eCAP is designed to monitor the AC line voltage and current. Measurement data and controls are accessed via the Telemetric DNP-RTM and website. A local switching strategy is available via auto failover, should SCADA communications be interrupted. The local switching strategy includes a time schedule to switch the bank on or off-line, based on temperature, with high/low voltage overrides.

The eCAP can be commanded to switch the cap bank on or offline via the remote SCADA operation. The remote operation allows monitoring of many measured and calculated values. See the DNP profile document for further information.

eCAP contains a real-time clock/calendar, and a temperature sensor as standard equipment.

The eCAP keeps historical information in non-volatile memory. It maintains an operations log and a history of the measurements taken of the monitored circuit. The measurement history is optionally saved as 1, 2, 5, or 15 minute averages. Enough information is saved so that a complete operating history is available.

eCAP can be set up and operated via a serial link to a typical laptop computer (or other PC), running QEI=s ANPC SmartWare@ program.

The eCAP front panel has an AAuto/Manual@ switch and an AOpen/Close@ switch.

Five LED indicators are included. A yellow LED indicates Local Auto Mode (LED is on) or Remote Mode (LED is blinking) or Manual Mode (LED is off). A red LED indicates that the last Cap Bank operation was CLOSE (red LED is on), or OPEN (green LED is on). A flashing OPEN or CLOSE LED indicates a pending operation.

A panel mounted 9 pin female RS232 connector allows the eCAP to be connected to a laptop (or any PC with a standard 9-pin serial port) using a standard one-to-one 9-pin serial port cable. A switch labeled “Remote/Local” is used to place the eCAP under control of a laptop PC (Local) or under SCADA control (Remote). Two red LEDs indicate data transmit/receive (Tx/Rx) when the switch is in the “Remote” state.

Internal timers and logic in the eCAP protect user and equipment from undesired and non-secure operations. Using timers and logic, the controls can prevent unsafe operations. Internal timers also allow the user to initiate local operations and leave the vicinity of the control before the switching operation occurs. Emergency voltage overrides provides bypass of long timers.


Copyright © 2017 QEI Introduction 5

1.1 Specifications

1.1.1 Size

Height 12", Width 10", Depth 7.5"

1.1.2 Temperature Sensor

0 to 140F (-15 to 60C)

1.1.3 Operation Counter

Internal software counter

1.1.4 Current Sensor

Line Post Sensors: Fisher Pierce 1301-x1A, x7A, Lindsey TrueCT, Multicore (sensors not included with the control)

1.1.5 Capacitor Switch Relays

Electro-mechanical relays rated at 20 amps continuous duty at 240 VAC.

1.1.6 Supply Voltage

120 VAC. The supply voltage is also used to sense the line voltage.

1.1.7 Line Frequency

60 Hz

1.1.8 Local Switching Strategy

Time, Temperature, Voltage: defaults are as follows:

Between the hours of 9AM and 9PM, the control will operate the bank based on temperature (close at 95 degrees, open at 80 degrees) with voltage overrides of 116.0 volts and 126.0 volts.

1.1.9 Power Consumption

3 VA, not including communications transceiver.

1.1.10 Environment

-40F to 149F (-40C to 65C) Temperature; 95% Humidity (non-condensing)

1.1.11 Case

NEMA 4 rated, weatherproof outdoor type.


6 Introduction Copyright © 2017 QEI

1.1.12 Radio:

Telemetric DNP-RTM.

1.1.13 Radio Power Supply

Input: 90-264VAC 50/60Hz.

Output: +12Vdc @ 2.5 Amps.


Copyright © 2017 QEI Installation 7

2. Installation

2.1 Making Connections

The diagram below shows how to connect the eCAP to the capacitor bank switches, the 120VAC transformer, the line post current sensor, and Neutral Current CT. The 120VAC transformer furnishes the power to the eCAP and also serves as the voltage sensor for the control.

2.2 Grounding

Proper grounding is critical when wiring a QEI eCAP. The neutral of all elements (the capacitor switches, the 120VAC transformer, the Line Post Sensor, should be connected to a common point in a junction box on the near the top of the pole. A separate ground wire should run down the pole to a ground rod driven into the soil at

the base of the pole. The earth ground must not be connected at or through the

eCAP. The diagram on the next page illustrates the correct method of connecting the eCAP and grounding.


8 Installation Copyright © 2017 QEI

2.3 4-Wire System Installation

The installation block diagram for a 4-Wire system is shown below. Please note the following installation guidelines for proper installation of the eCAP units on a 4-Wire system.

The placement of the LPCS (Line Post Current Sensor) must be located in between the Source and Capacitor Bank for proper electrical VAR sensing.

All components must be star grounded at the Neutral Support Point shown in the 4-Wire System Installation Pictorial Diagram below.

Voltage and Current signals should come from the same phase on a 4-Wire System in order for the eCAP to indicate correct electrical value readings. If this is an inconvenience, please consult the factory for recommendations.

4-Wire System Block Diagram



4-Wire Installation Pictorial


10 Installation Copyright © 2017 QEI

2.4 Line Current Measurement

The eCAP current measurement input accepts a line post current sensor (LPCS). The following types are supported: Fisher-Pierce Series 1301-x1A, x7A, Lindsey “TrueCT” or Lindsey “Multicore” (or any LPCS with a 60 amps/volt input to output ratio). The outputs from these devices are monitored directly by the eCAP control unit.

WARNING: Do not connect a CT to the eCAP-9040. Connecting a CT may result in unit damage.



2.5 Meter Socket Mounting

Verify that the eCAP unit matches the available socket on the utility pole. The sticker on the inside of the unit cover shows the required socket connections. The view on the sticker is looking into the meter socket on the pole.

Units should be secured in place with a locking collar (not provided) to prevent the eCAP from being removed from its socket by unauthorized personnel.


12 Hardware Description Copyright © 2017 QEI

3. Hardware Description

3.1 Front Panel Layout

The following two pages show the location of all front panel switches, indicators, and controls. A description of each item appears on the following pages.


Copyright © 2017 QEI Hardware Description 13

# ITEM DESCRIPTION

1 Display Contrast This control is used to adjust the contrast on the LCD Display. Turning the control clockwise makes the display contrast darker.

2 Two Line LCD

Display

This 2 line x 16-character display is used for a number of functions. It is used to enter switching algorithms, review and set configuration items and parameters, and to view actual operating conditions. The function of the display depends on the menu item selected. For more detailed information, consult the description of menu item functions.

3 UP / DOWN Switch This switch has several uses: When on a non-numeric item, it is used to select the desired setting. When on a numeric item, it increments or decrements the highlighted value.

4 x10 / ÷10 Switch This switch is used to multiply or divide a numeric value by 10 thereby shifting the value one digit to the left or right. This switch in conjunction with the Modify Up/Down switch is used to enter numeric values.

5 RIGHT/ LEFT Switch This switch has two uses: When the main menus are displayed, this switch moves forward and backward through the main menus. When a sub-menu item is displayed, this switch moves the cursor to the right or left on the display.

6 MENU/ ITEM Switch This switch is used to navigate around the eCAP displays. Use ITEM to navigate from any main menu selection to its’ associated sub-menus. Use MENU to navigate back to the main menu selection from the sub-menus. A main menu selection is any screen numbered “01>” through “23>”.

8 Operating Mode

LED (Yellow)

A yellow LED to the left of the AUTO switch indicates if the control is in auto or manual mode as follows:

ON (Continuous): Auto Mode (Local) ON (blinking): Remote Mode OFF: Manual mode

9 AUTO / MANUAL

Switch

This switch sets the local operating mode to AUTO or MANUAL. When in AUTO mode, the eCAP operates via SCADA control (Remote Mode) or via a settable local switching strategy if communications fails.

10 CLOSE / OPEN

Switch

This switch is used in local Manual mode to switch the capacitor bank on-line or off-line. Timers delay manual operation to allow the user to walk away from the bank after initiating a manual mode operation. The timer is 10 seconds for an OPEN operation, and 45 seconds for a CLOSE operation. A re-close block timer for cap discharge will delay the manual CLOSE operation for up to 5 minutes, immediately following an OPEN operation.


14 Hardware Description Copyright © 2017 QEI

# ITEM DESCRIPTION

11 Capacitor Bank

Switch State LEDs

These Red and Green LEDs adjacent to the Close/Open switch indicate the state of the capacitor bank switch:

Red LED On - The last operation performed was a CLOSE operation.

Red LED Blinking – A CLOSE operation is pending. The capacitor bank will be CLOSED after any delay timers have expired.

Green LED On - The last operation performed was an OPEN (Trip) operation.

Green LED Blinking – An OPEN operation is pending. The capacitor bank will be OPENED (tripped) after any delay timers have expired.

12 RS232 Port This 9-pin female D-sub connector is used to connect the eCAP to a laptop computer. Using Smartware, the user can change many of the eCAP settings, and view real-time data.

13 Line, Neutral,

Current, +12VDC,

Common

Test Jacks

These terminals are used connect the control to a meter that is used in checking the control. A multimeter set to 200VAC scale between the NEUTRAL and VOLTAGE test points measures the actual AC line voltage. A multimeter set to 20 VAC scale between NEUTRAL and CURRENT measures the actual output of the line post sensor into the eCAP (1Vrms in = 60 Amps of primary phase current).

14 Temperature Sensor An external temperature sensor is mounted at the bottom of the eCAP. The sensor allows for the unit to switch the Cap Bank OPEN or CLOSED based on environmental temperature. Range = 0 to 140F.

15 Local/Remote

Switch LOCAL - When the switch is in this position, a laptop

PC can be connected to the front panel RS232 port to configure, monitor, or control the eCAP (Using QEI’s “SmartWare” software.)

REMOTE – When the switch is in this position, the eCAP is monitored and controlled via SCADA communications (through the Telemetric DNP-RTM.) The front panel RS232 port should not be used when the switch is in this position.

16 TX/RX LEDs These LEDS indicated SCADA communication status. TX= data transmitted from the eCAP. RX= data received by the eCAP.


Copyright © 2017 QEI Hardware Description 15

3.1.1 Fuses and Fuseholders

There are three fuses associated with the eCAP. A 10 Amp Slo-Blo type 1-1/4 inch cylinder fuse (QEI No. 10-003669-028) is located in the front panel fuseholder (item 17 in the front panel pictorial). Another fuse is a ¼ Amp 5 x 20mm slo-blo type fuse (QEI No. 10-003669-044, Littlefuse 218.250) on the lower (larger) printed circuit board located underneath the front panel. If the control were inoperative, one of the first steps would be to verify that either of these fuses is not blown. A third fuse is a 2 Amp 5 x 20mm located on AC input of the internal +12VDC radio power supply. Both of the 5 x 20mm fuses are accessed by opening the hinged front panel of the eCAP.

3.1.2 Battery

Each of the two eCAP circuit boards has a +3 VDC lithium battery installed. The batteries maintain the clock, and trending (historical data) memory, when power is removed from the eCAP. The circuit boards are accessed by opening the hinged front panel of the eCAP, so that the rear of the front panel is viewed. On the lower (larger) circuit board , there is one battery labeled B1, and it is installed in the upper left corner of the board. The second battery is located on the upper (smaller) printed circuit board. This battery is labeled BH1 and is located in the upper right corner. The maximum life expectancy of the lithiums in-circuit is 4 years, when the eCAP is in a non-powered state, and 10 years in a powered state. Customer may request for replacement from the factory. The manufacturer and model of the batteries is:

Manufacturer: Renata

Model Number: CR1225

3.1.3 Clock

The eCAP has a battery backed internal clock/calendar, which can automatically adjust for daylight savings time. The battery keeps the clock running when the unit is in a non-powered state.


16 Copyright © 2017 QEI

The eCAP has a front panel RS-232 port, which can be connected to a laptop PC (with QEI’s “SmartWare” software installed and running on the PC) for configuration of the eCAP-9040, and for viewing measurements, etc. in real-time.

Additionally, the eCAP has a Hardware Interface, which is a set of four toggle switches and an LCD Display. The Hardware Interface can be used to set up many of the operating parameters directly from the front panel, without the use of a computer. This may allow for easier setup in the field.

The toggle switches are used to navigate the various configuration menus, and to view the measured/calculated values (i.e., Volts, current, kVAr, kW, etc.) in real time.


Copyright © 2017 QEI Operation 17

4. Operation

4.1 Navigating the LCD Display – an Example:

1) Making sure that the eCAP AUTO/MANUAL switch is set to MANUAL, apply power to the eCAP.

2) Two self tests run (visible on display): one for Flash Memory, another for RAM. The Auto/Manual (Yellow) and the Open/Close (Green/Red) Leds will turn on and off (lamp test) during the self-tests. After the self tests complete, the startup banner appears on the eCAP-9040 display. After the self-tests complete, a start up banner will appear, indicating the firmware version, current sensor type, and maximum line current.

QEI ECap NPC:1.0

FLPS 0-180 Amps

3) Press the MENU switch once to go the main menus (numbered “01>” thru “23>”.

01>Live Values

Voltage, Current

4) Press the RIGHT switch 8 times to navigate to the following main menu selection:

09>Hrdwre Config

Line Volts/Freq

5) Press the ITEM switch to navigate to the Line Volts/Freq sub-menu: V Sec. Freq 120 60


18 Operation Copyright © 2017 QEI

6) Notice that the cursor is now flashing over “120”. This indicates that the value can be changed. In any sub-menu, if the cursor is not blinking, the value is fixed, and cannot be changed.

7) Press the RIGHT switch to move the cursor to the right.

8) Notice that the cursor has moved over to “60”, and is blinking. This indicates the value can be changed.

9) Use the LEFT and RIGHT switches to move the cursor back and forth between “120” and 60”. Stop back at “60”

9) Use the UP switch to change the frequency from 60Hz to 50 Hz.

10) Use the DOWN switch to set the frequency back to 60 Hz (The UP switch would also work to change the value back, since there are only two choices (50 or 60Hz).

11) Use the LEFT switch to move back to “120”.

12) Use the DOWN switch twice to set the voltage to “240”, then back to “120” (the UP switch, would work here to change the value back, since there are only two choices (120 or 240Volts).

13) Use the MENU switch to navigate back to the main menus.

14) Press the RIGHT switch 11 times (or the LEFT switch 12 times to go to the following main menu selection:

20>Misc. Config

Unit ID

15) Press the ITEM switch to navigate to the Unit ID sub-menu: Unit ID Number 1 16) Press the UP switch 3 times to change the ID number from 1 to 4. 17) Press the X10 switch twice to increase the unit ID from 4 to 400. 17) Press the ÷10 switch twice to change the number from 400 to 4. 18) Press the DOWN switch 3 times to change the number from 4 to 1. 19) Press the MENU switch to go back to the main menus, then use the RIGHT or LEFT switch to browse the various main menu selections (numbered “01>” through “”23>”). The example above gives a general idea of navigation. Some main menu selections contain multiple sub-menus. In that case, a sub-menu may contain a “>>” symbol. This indicates that another sub-menu is located below the present sub-menu. Use the ITEM switch to go from the present sub-menu display, down to the next sub-menu display.



4.2 Live Values

The eCAP-9040 monitors the line voltage, phase current, phase angle and ambient temperature. Using the voltage, current, and phase angle, it computes kW, kVAr, PF (power factor) etc. Many of the monitored and computed values are visible through the front panel LCD display, accessible from menus labeled “01>” through “08>”, and called “Live Values”. The table below list the displays, and gives an explanation of each.

Menu Item Submenu Item Format Comments

QEI ECap NPC:1.0

FLPS 0 - 180 Amps

Startup Banner, appears at power up.

01>Live Values

Voltage, Current Volts VCor Cur 124.5 125.5 50

Real-time voltage and current. The VCor value (Voltage Corrected) is the predicted voltage rise (or drop) with a 25% margin used by the eCAP for voltage override purposes.

02>Live Values

kW, kVAr, PF kW kVAr PF 2485 514 98

Real-time kilowatts, kVAr, and power factor .

03>Live Values

Temperature Ambient Temp 82 F

Real-time measured temperature from sensor at bottom of enclosure.

04>Live Values

Switch Status Status Pending Closed Open

“Status” shows last operation performed. “Pending” shows any operation that is in progress, but hasn’t yet occurred.

05>Live Values

Operating Mode Comm Local Auto Manual

“Comm” shows the SCADA set operating mode (Auto or Remote). Local shows the state of the front panel Auto/Manual toggle switch.

06>Live Values

Operations Count Today Op Count 4 122

“Today” shows the daily count (resets at midnight). “Op count” is total count since installation (can be reset via SCADA.

07>Live Values

Reason Last Op Last Operation Temp Lo Open

Shows the operation performed (Close or Open) and the reason.



4.3 Local Switching Strategy Configuration

A local switching strategy is entered into the eCAP. The strategy is in effect whenever the eCAP has no SCADA communications. If the eCAP has SCADA communications, it can be set via SCADA to operate in Remote Mode (eCAP under SCADA control), or in Auto mode (use the local switching strategy). Additionally, if in Remote Mode and SCADA communications fails, the eCAP can be set to automatically failover to the local switching strategy.


08>Switch Mode

Switching Setup

Switch On Volts, Tmp, Time >>

Selects the desired switching strategy. Can be set to “Volts, Tmp Time”, “Tmp, Time”, or “Volts, Time”.

Volt Lo Volt Hi 116.0 126.0 >>

Sets the low (close) and high (open) voltage limits used in the switching strategy.

Volt Lo Volt Hi Yes Yes >>

Separate enables for low and high voltage limits.

EOVR Lo EOVR Hi 115.0 129.0 >>

Emergency low and high voltage overrides . These limits bypass the long interval timer that would normally be in effect for the voltage limits in Auto Mode (10-60 minutes, configurable). If enabled these limits are in effect regardless of the time schedule or other switching strategy settings.

Emer. Voltage OR Enabled >>

Enable for emergency voltage override feature.

Time1 Time2 09:00 21:00

Defines the start time and end times for the time schedule.

Not Time Period Stay: Open >>

“Stay:” indicates the cap bank position that will be set when the switching strategy time schedule is not active (i.e., when the present time is outside of the scheduled time period).

The voltage limits (if enabled) will prevent switching when entering or leaving the scheduled time period, if opening the bank would cause the voltage to fall too low, or closing would cause the voltage to rise too high.

Temp: Open Close 80 95

Sets the low (open) and high (close) temperature limts used in the switching strategy.



Three local switching strategies are available:

1) Volts, Temperature, Time – When the present time is within the scheduled time period, switch the bank based on low/high temperature limits, with low/high voltage override.

2) Volts, Time -- When the present time is within the scheduled time period, switch the bank based on low/high voltage limits.

3) Temp, Time -- When the present time is within the scheduled time period, switch the bank based on temperature.

For all three switching strategies, the EOVR (emergency voltage overrides) are in effect (if enabled). The emergency overrides bypass the 60 minute Anti-Hunt timer (see main menu selection “19>Misc. Config, Max Ops per Day” ).

The local switching strategy voltage limits (if enabled) also function when in SCADA remote mode. In this case, the limits will override SCADA commands, and prevent the bank from being switched remotely, if closing the bank would cause the voltage to rise above the high limit, or opening the bank would cause the voltage to fall below the low limit.



4.4 Other Configuration Settings


09>Hrdwre Config

Line Volts/Freq

VSec. Freq 120 60

Sets the line voltage (120/240V) and line frequency (50/60Hz).

10>Hrdwre Config

Power Direction

Power Direction Always Positive

Sets the sign associated with forward and reverse power flow. Can be “Always Positive” or “Normal” (reverse power flow will be indicated with a negative sign).

11>Hrdwre Config

Current Sensor

Curr Sensor Type FP 1301 x7A >>

Selects LPS (Line Post Sensor) mfgr and model. Can be set to: Lindsey TrueCT/ Multicore. Fisher Pierce: 1301 x7A (-17A, -47A, -27A) 1301 x1A (-11A, -41A, -21A). Generic LPS or CT. Note: Do NOT use a CT with this eCAP model, or damage may result.

Amps/V Phase 60 90 >>

Amps/V and phase shift settings. These are fixed, and depend on the sensor model. These settings can be changed if “Generic LPS” is chosen for the sensor model above.

Harmonic Comp Enabled

LPS harmonic compensation circuit status (enabled/disabled) This is fixed, depending on the sensor model. Can be changed if “Generic LPS” is selected.

12> Hrdwre Config

Maximum Current

Maximum Current 180 Amps

Sets the maximum measurable current in the eCAP. Settable in sixteen steps from 180 to 1530 Amps. Lower settings help resolution at lower currents. Choose a number that is 20% higher than the maximum expected phase current.



Other Configuration Settings (contd.)


13>Hrdwre Config

Switching DeltaV

Learn ClsV OpnV Yes 2.0 2.0

Values used to provide the predicted VCor deadbands (hysteresis) for the voltage limits. ClsV is rise in voltage after closing. OpnV is drop in voltage after opening. Values can be set manually (Learn = No) or the eCAP will learn them as it switches the bank (Leran=Yes). The DeltaV values are added to, or subtracted from the measured voltage (depending on the operation) to arrive at the VCor value. The VCor value also includes a 25% margin for hysteresis.

14>Hrdwre Config

Config Constants

Volts Amps Deg 7200 60 152

Volts = Settable Primary Phase-Neutral Voltage. Amps, Deg = fixed settings, depending on the LPS sensor settings.

15> Misc. Config

Sw Error Check

Delta Err. Check Disabled

If enabled, the measured line voltage rise (or drop) after a bank operation, must be 25% or more of the ClsV (or OpnV) values. If the 25% minimum change is not observed for three consecutive operations, a “Switching Voltage Delta Error” is returned via SCADA.

16> Misc. Config

Tracking Delays

Delay Emer Volt Secs 120 120

“Emer” = emergency voltage tracking delay, “Volt” = voltage limit tracking delay. Both are settable from 1 to 300 seconds. These delays prevent short transient voltage spikes from triggering a cap bank operation.

17> Misc. Config

Sw. Oper. Time

Opn Operate Time 7 Secs >>

“Open” output relay energization time. Settable from 1 to 100 secs.

Cls Operate Time 7 Secs

“Close” output relay energization time. Settable from 1 to 300 secs.

18> Misc. Config

Discharge Time

Discharge Time 300 Secs (5 Min)

Re-close block of 5 minutes to allow the cap bank to discharge after an open operation. Settable to 300 (5 Min) or 600 Secs (10 Min).



Other Configuration Settings (contd.)


19> Misc. Config

Max Ops Per Day

Max Ops Enable Enabled >>

Maximum number of open/close cycles allowed during a single day (24 hours). Can be enabled or disabled. When the count is exceeded, no further operations are allowed until the following day (beginning after midnight).

Time Count 60 Mins 10

“Time” = Anti-Hunt delay time between consecutive auto operations. Settable from 10 to 60 Minutes. “Count” = number of open/close cycles allowed per day. Settable from 4 to 25 counts, or No Limit. The cycle count resets at midnight of each day.

20> Misc. Config

Unit ID

Unit ID Number 1

Unit ID number. Settable from 1 to 32767.

21> Misc. Config

Date

Date: Yr/Mo/Dy is 07/05/24

Sets/displays the date. To set the date, see the time setting instructions below.

22> Misc. Config

Time

Time: Hr:Mn DOW is: 06:25 5Fr

Sets/displays the time of day (Format: HH:MM) and DOW (day-of-week) To set time, make sure the cursor is over the word “is”. Press the UP switch until “is” says “Ent”. Next use the RIGHT switch to move the cursor to the right until it is over the hour. Use the UP/DN switch to set the hour, then use the RIGHT switch again to move the cursor over the minutes. Use the UP/DN switch to set the minutes. Use the RIGHT switch again to move the cursor over the day-of-week. Use the UP/DN switch to set the Day (1 = Monday thru 7 = Sunday). Now use the LEFT switch multiple times to move the cursor back to “Ent”. Press the UP switch once, and verify that “Ent” changes to “Set”, then to “is”.

23> Misc. Config

DST Config

DST Hemisph * Enabled North >>

Daylight Savings Time compensation. When enabled, clock is advanced one hour in the spring (Month1), and set back one hour in the fall (Month2). Settable for North (US) or South Hemispheres. If South Hemisph is selected, the time will be set back in the spring, and advanced in the fall. Asterisk = in DST period.

Month1 Month2 3 11

Month1 = Beginning of DST (the time will be advanced by 1 hour) Month2 = end of DST (the time will be set back by 1 hour).


Copyright © 2017 QEI Misc Technical Data 25

5. Misc Technical Data

DB9

Pin

To Radio

Intf Board

Description

Pin 2 RX Data received by the radio and sent to the eCAP.

Pin 3 TX Data transmitted out by the eCAP.

Pin 5 GND Signal ground.


26 Misc Technical Data Copyright © 2017 QEI

Cable DB9M QEI No. 40-057808-001



5.1 Communications Board

The eCAP is designed for communications in a SCADA system, and the communications board is designed as the eCAP interface to the SCADA Master Station via a data-radio or modem. The communications board talks to the eCAP microprocessor board on PORT 1 (connector P3). It talks to the data radio through the Radio Interface Board that is mounted on the communications board on PORT 2 (connector P4). Communications protocol is DNP3. Communications parameters to the radio are No parity, 8 data bits, one stop bit. Baud rate is jumper configurable on the communications board.

5.1.1 Jumpers - Factory Configuration

The eCAP communications board contains pluggable configuration jumpers. Certain jumpers are relevant to the communications configuration. Other jumpers were preset at the factory before shipment. The factory configuration for all jumpers is as follows:

OS3-CD = IN OS7-ROM60 = IN

OS4-AB = IN 0S7-ROM80 = IN

OS6-AC = IN OS7-ROMA0 = IN

OS6-BD = IN OS7-ROMC0 = IN

OS7-RAM20 = IN 0S9-CD = IN

OS7-RAM40 = IN

Any jumpers not listed in the table above were not installed at the factory (the jumper would be considered OUT). The factory configuration listed in the table above configures the communications board for 9600 bps. An illustration of the jumper locations for the communications board appears on the following page.

Changing any other jumpers on the board is not recommended, and may result in

rendering the board inoperative. If a jumper is accidentally changed, refer to the table above to restore the factory settings. The drawing that follows shows the location of jumpers (and LEDs) on the communications board.



Pictorial of Jumper locations for eCAP communications board.

5.1.2 TX / RX LEDs

Two LEDs on the communications board indicate data transfer to/from the eCAP microprocessor board. The red LED (TX1) indicates data is being sent TO the eCAP microprocessor board. The green LED (RX1) indicates data is being received FROM the eCAP microprocessor board.

Two LEDs on the eCAP front panel indicate data transfer between the communications board and the data radio. TX indicates data is being sent TO the radio, and RX indicates data received FROM the radio.



5.1.3 Setting the Baud Rate

Use jumper OS3 to change the baud rate.

The communications board is configurable for the following baud rates: 1200, 2400, 4800, 9600, 19200. Baud rate is configured via pluggable jumpers. For all baud rates, insure that jumper OS4-AB is IN, while jumper OS4-BC is OUT. Otherwise, none of the baud rates will function correctly.

Factory default for the jumper OS3 is CD = IN = 9600 baud. Refer to the following table to configure jumper OS3 for the required baud rate:

BAUD RATE JUMPERS

1200 2400 4800 9600 19200

OS3-JK IN OUT OUT OUT OUT

OS3-GH OUT IN OUT OUT OUT

OS3-EF OUT OUT IN OUT OUT

OS3-CD OUT OUT OUT IN OUT

OS3-AB OUT OUT OUT OUT IN

5.2 Radio Interface Board

The RS-232 Radio Interface Board provides an isolated RS-232 interface between the SCADA Communications Board and the data radio:

eCAP CPU

BOARD

SCADA COMM

BOARD

RS-232 RADIO

INTFACE BDDATA RADIO

FIBER

OPTICAL

RS-232

ANTENNA

(CUSTOMER SUPPLIED)



The Radio Interface Board contains a 4 position terminal block (J1) for connection of the above RS-232 data cables. The board is marked next to the terminal block with the legends “RX”, “TX”, “+12V”, and “GND”:

RADIO INTERFACE

BOARD, J1

TERMINAL BLOCK

CONNECTED

WIRE COLOR

DESCRIPTION

RX BLUE Incoming data from the radio

TX ORANGE Outgoing data transmitted by the eCAP

+12V RED Power (from radio power supply)

GND BLACK Power supply return, and data common.

The drawing below shows a closeup view of the Radio Interface Board:

The jumpers for JP1 must always be oriented as shown in the Radio Interface Board drawing above (the jumpers are parallel to the “long” side of this board as shown). The Radio Interface Board part number is 40-057807-001.



The Radio Interface Board is “piggy-backed” onto the SCADA Communications Board, and has plastic optical fiber (1000 micron) running from it’s two fiber connectors to the fiber connectors on the SCADA Board.

The illustration above (right) shows the wiring of the RS-232 cable to the Radio Interface Board Terminal Block (J1). Two RS-232 cables are supplied with the eCAP: a 9-pin and 25-pin cable. Use the appropriate cable based on the type of radio.

5.2.1 DB9 RS-232 Cable:

Orange wire: Connected to “TX” on the Radio Interface Board terminal block, goes to pin 3 of the DB9 connector. This is data to be sent from the eCAP to the radio.

Blue wire: Connected to “RX” on the Radio Interface Board terminal

block, goes to pin 2 of the DB9 connector. This is data received from the radio to the eCAP.

Black wire: Connected to “GND” on the Radio Interface Board terminal

block (GND) goes to pin 5 of the DB9 connector. This is the data common connection, and also goes to the radio power supply common.



5.3 Local/Remote Front Panel Switch

In order to use SCADA communications, the front panel LOCAL/REMOTE switch must be in the REMOTE position. When in the REMOTE position, the eCAP communicates with a SCADA system using a data radio or modem, etc. When the switch is in the LOCAL position, the eCAP communicates with a Laptop PC through the RS-232 port on the front panel. The PC must be running QEI’s “SmartWare” software. Note that when the switch is in REMOTE position, the front panel RS-232 port is disabled, and when it is in LOCAL position, SCADA communications via data radio is disabled.


Copyright © 2017 QEI DNP3 Device Profile w/Point List 33

6. DNP3 Device Profile w/Point List

Version 1.0

Date: 06/21/2007

DNP V3.00 DEVICE PROFILE DOCUMENT

This document must be accompanied by a table having the following headings: Object Group Request Function Codes Response Function Codes Object Variation Request Qualifiers Response Qualifiers Object Name (optional)

Vendor Name: QEI

Device Name: NPC eCAP Capacitor Controller

Highest DNP Level Supported: For Requests 2 For Responses 2

Device Function: Master Slave

Notable objects, functions, and/or qualifiers supported in addition to the Highest DNP Levels Supported (the complete list is described in the attached table): The read function code for Object 50 (Time and Date), variation 1, is supported.

Maximum Data Link Frame Size (octets): Transmitted 292 Received 292

Maximum Application Fragment Size (octets): Transmitted 2048 Received 2048

Maximum Data Link Re-tries: None Fixed at Configurable, range None to 10

Maximum Application Layer Re-tries: None Configurable, range None to 10 (Fixed is not permitted)


34 DNP3 Device Profile w/Point List Copyright © 2017 QEI

Requires Data Link Layer Confirmation: Never Always Sometimes: For multi-frame messages. Configurable

Requires Application Layer Confirmation: Never Always (not recommended) When reporting Event Data (Slave devices only) When sending multi-fragment responses (Slave devices only) Sometimes Configurable

Time-outs while waiting for: Data Link Confirm None Fixed at Variable Configurable Complete Appl. Fragment None Fixed at Variable Configurable Application Confirm None Fixed at 5 sec Variable Configurable Complete Appl. Response None Fixed at Variable Configurable Others: Transmit Enable (Time to 1st char after CTS) configurable by A/O (see Table) CTS Override Tim to 1st char after RTS if no CTS) configurable by A/O (see Table) Transmit Disable(Hold time: RTS after last char) configurable by A/O (see Table)

Executes Control Operations: WRITE Binary Outputs Never Always Sometimes Configurable SELECT/OPERATE Never Always Sometimes Configurable DIRECT OPERATE Never Always Sometimes Configurable DIRECT OPERATE - NO ACK Never Always Sometimes Configurable Count > 1 Never Always Sometimes Configurable Pulse On Never Always Sometimes Configurable Pulse Off Never Always Sometimes Configurable Latch On Never Always Sometimes Configurable Latch Off Never Always Sometimes Configurable Queue Never Always Sometimes Configurable Clear Queue Never Always Sometimes Configurable Latch On, Latch Off operate all CROBs except Cap Bank Trip/Close when not in Local.

In addition, unit must be in Remote mode to operate Cap Bank Trip/Close.



FILL OUT THE FOLLOWING ITEM FOR MASTER DEVICES ONLY:

Expects Binary Input Change Events: Either time-tagged or non-time-tagged for a single event Both time-tagged and non-time-tagged for a single event Configurable (attach explanation)

FILL OUT THE FOLLOWING ITEMS FOR SLAVE DEVICES ONLY:

Reports Binary Input Change Events when no specific variation requested: Never Only time-tagged Only non-time-tagged Configurable

Reports time-tagged Binary Input Change Events when no specific variation requested: Never Binary Input Change With Time Binary Input Change With Relative Time Configurable (attach explanation)

Sends Unsolicited Responses: Never Configurable (attach explanation) Only certain objects Sometimes (attach explanation)

Sends Static Data in Unsolicited Responses: Never When Device Restarts When Status Flags Change No other options are permitted.

Default Counter Object/Variation: No Counters Reported Configurable (attach explanation) Default Object 20 Default Variation 04

Point-by-point list attached

Counters Roll Over at: No Counters Reported Configurable (attach explanation) 16 Bits 32 Bits Other Value _____________ Point-by-point list attached

Sends Multi-Fragment Responses: Yes No



DNP 3.0 Implementation Table for eCAP

OBJECT

REQUEST

(slave must parse)

RESPONSE

(master must parse) Obj

Var

Description

Func

Codes

(dec)

Qual

Codes

(hex)

Func

Codes

Qual

Codes

(hex)

1

0

Binary Input - All Variations

1

06

1

1

Binary Input

129

00, 01

1

2

Binary Input with Status

129

00, 01

2

0

Binary Input Change - All Variations

1

06,07,08

2

1

Binary Input Change without Time

1

06,07,08

129

17, 28

2

2

Binary Input Change with Time

1

06,07,08

129

17, 28

2

3

Binary Input Change with Relative Time

1

06,07,08

129

17, 28

10

0

Binary Output - All Variations

1

06

10

1

Binary Output

10

2

Binary Output Status

129

00, 01

12

0

Control Block - All Variations

12

1

Control Relay Output Block

3, 4, 5, 6

17, 28

129

echo of

request

12

2

Pattern Control Block

12

3

Pattern Mask

20

0

Binary Counter - All Variations

1, 7, 8, 9, 10

06

20

1

32-Bit Binary Counter

129

00, 01

20

2


129

00, 01

20

3

32-Bit Delta Counter

129

00, 01

20

4


129

00, 01

20

5

32-Bit Binary Counter without Flag

129

00, 01

20

6

16-Bit Binary Counter without Flag

129

00, 01

20

7

32-Bit Delta Counter without Flag

129

00 ,01

20

8

16-Bit Delta Counter without Flag

129

00 ,01

21

0

Frozen Counter - All Variations

1

06

21

1

32-Bit Frozen Counter

129

00, 01

21

2

16-Bit Frozen Counter

129

00, 01

21

3

32-Bit Frozen Delta Counter



OBJECT

REQUEST

(slave must parse)

RESPONSE


Var

Description

Func

Codes

(dec)

Qual

Codes

(hex)

Func

Codes

Qual

Codes

(hex)

21

4

16-Bit Frozen Delta Counter

21

5

32-Bit Frozen Counter with Time of Freeze

21

6

16-Bit Frozen Counter with Time of Freeze

21

7

32-Bit Frozen Delta Counter with Time of Freeze

21

8

16-Bit Frozen Delta Counter with Time of Freeze

21

9

32-Bit Frozen Counter without Flag

129

00, 01

21

10

16-Bit Frozen Counter without Flag

129

00, 01

21

11

32-Bit Frozen Delta Counter without Flag

21

12

16-Bit Frozen Delta Counter without Flag

22

0

Counter Change Event - All Variations

1

06,07,08

22

1

32-Bit Counter Change Event without Time

129

17, 28

22

2

16-Bit Counter Change Event without Time

129

17, 28

22

3

32-Bit Delta Counter Change Event without Time

22

4

16-Bit Delta Counter Change Event without Time

22

5

32-Bit Counter Change Event with Time

22

6

16-Bit Counter Change Event with Time

22

7

32-Bit Delta Counter Change Event with Time

22

8

16-Bit Delta Counter Change Event with Time

23

0

Frozen Counter Event - All Variations

23

1

32-Bit Frozen Counter Event without Time

23

2

16-Bit Frozen Counter Event without Time

23

3

32-Bit Frozen Delta Counter Event without Time

23

4

16-Bit Frozen Delta Counter Event without Time

23

5

32-Bit Frozen Counter Event with Time

23

6

16-Bit Frozen Counter Event with Time

23

7

32-Bit Frozen Delta Counter Event with Time

23

8

16-Bit Frozen Delta Counter Event with Time

30

0

Analog Input - All Variations

1

06

30

1

32-Bit Analog Input

129

00, 01

30

2

16-Bit Analog Input

129

00, 01

30

3

32-Bit Analog Input without Flag

129

00, 01



OBJECT

REQUEST

(slave must parse)

RESPONSE


Var

Description

Func

Codes

(dec)

Qual

Codes

(hex)

Func

Codes

Qual

Codes

(hex)

30

4

16-Bit Analog Input without Flag

129

00, 01

31

0

Frozen Analog Input - All Variations

31

1

32-Bit Frozen Analog Input

31

2

16-Bit Frozen Analog Input

31

3

32-Bit Frozen Analog Input with Time of Freeze

31

4

16-Bit Frozen Analog Input with Time of Freeze

31

5

32-Bit Frozen Analog Input without Flag

31

6

16-Bit Frozen Analog Input without Flag

32

0

Analog Change Event - All Variations

1

06,07,08

32

1

32-Bit Analog Change Event without Time

129

17,28

32

2

16-Bit Analog Change Event without Time

129

17,28

32

3

32-Bit Analog Change Event with Time

32

4

16-Bit Analog Change Event with Time

33

0

Frozen Analog Event - All Variations

33

1

32-Bit Frozen Analog Event without Time

33

2

16-Bit Frozen Analog Event without Time

33

3

32-Bit Frozen Analog Event with Time

33

4

16-Bit Frozen Analog Event with Time

40

0

Analog Output Status - All Variations

1

06

40

1

32-Bit Analog Output Status

40

2

16-Bit Analog Output Status

129

00, 01

41

0

Analog Output Block - All Variations

41

1

32-Bit Analog Output Block

41

2

16-Bit Analog Output Block

3, 4, 5, 6

17, 28

129

echo of request

50

0

Time and Date - All Variations

50

1

Time and Date

1,2

07 where quantity = 1

50

2

Time and Date with Interval

51

0

Time and Date CTO - All Variations

51

1

Time and Date CTO

129

07, quantity=1



OBJECT

REQUEST

(slave must parse)

RESPONSE


Var

Description

Func

Codes

(dec)

Qual

Codes

(hex)

Func

Codes

Qual

Codes

(hex)

51 2 Unsynchronized Time and Date CTO 129 07, quantity=1

52

0

Time Delay - All Variations

52

1

Time Delay Coarse

129

07, quantity=1

52

2

Time Delay Fine

129

07, quantity=1

60

0

60

1

Class 0 Data

1

06

60

2

Class 1 Data

1

06,07,08

60

3

Class 2 Data

1

06,07,08

60

4

Class 3 Data

1

06,07,08

70

1

File Identifier

80

1

Internal Indications

2

00

index=7

81

1

Storage Object

82

1

Device Profile

83

1

Private Registration Object

83

2

Private Registration Object Descriptor

90

1

Application Identifier

100

1

Short Floating Point

100

2

Long Floating Point

100

3

Extended Floating Point

101

1

Small Packed Binary-Coded Decimal

101

2

Medium Packed Binary-Coded Decimal

101

3

Large Packed Binary-Coded Decimal

No Object

13

No Object

23 (see 4.14)



Basic Input Data Registers – Analog Points

Object /

Variation

/ Class Parameter

Point

Address Units Range

30/4/0 OR 32/2/2 Secondary Voltage (1 phase) 0 0.1 Volts

30/4/0 OR 32/2/2 Voltage w/ Correction (1 phase) 1 0.1 Volts

30/4/0 OR 32/2/2 Current (1 phase) 2 Amps

30/4/0 OR 32/2/2 KW (1 phase x3) 3 KW

30/4/0 OR 32/2/2 kVAr (1 phase x3) 4 kVAr

30/4/0 OR 32/2/2 kVA (1 phase x3) 5 kVA

30/4/0 OR 32/2/2 Power Factor 6 0.1 %

30/4/0 OR 32/2/2 Phase Angle 7 Degrees

30/4/0 OR 32/2/2 Spare1 8 Always 0

30/4/0 OR 32/2/2 Ambient Temperature 9 Degrees F

30/4/0 OR 32/2/2 Operations Counter 10 # of Operations 0 to 32767

30/4/0 OR 32/2/3 Operations Counter Today 11

# of Operations

Since Midnight

30/4/0 OR 32/2/3 Reason for Last Switch Operation 12 See Note 1.

30/4/0 OR 32/2/3 ECap Firmware Version 13 100 = Ver:1.00

30/4/0 OR 32/2/3 NPC Identification Serial number 14 ECap Unit ID 0 to 32767

30/4/0 OR 32/2/2 Last SCADA Command Received 15 See Note 2.

30/4 Last SCADA Point Number 16 SCADA Point #

30/4 Last SCADA Set Point Value 17 Set Point Value

Note 1: Reason for the Last Switch Operation Value Description

0 No Operation 1 Manual Operation 2 Remote (SCADA) Operation 3 Out of Time Period 4 Temperature High 5 Temperature Low 6 Under-Voltage 7 Over-Voltage 8 Emergency Under-Voltage 9 Emergency Over Voltage



Note 2: Last SCADA Command Received Value Description

0 No Command Received 1 Open/Trip 2 Close 3 Set Point



Basic Input Data Registers – Status Points

Object/

Variation/

Class Point Name

Point

Address Description

01/1/0 OR 02/2/1 Cap Bank Switch – Open / Close 0 0 = Open, 1 = Closed

01/1/0 OR 02/2/1 Remote Mode 1 0 = Auto, 1 = Remote

01/1/0 OR 02/2/1 Delta Voltage Learn 2 0 = Disabled, 1 = Enabled

01/1/0 OR 02/2/1 Spare1 3 Always 0

01/1/0 OR 02/2/1 Max Number Operations Daily 4 0 = Disable, 1 = Enabled

01/1/0 OR 02/2/1 Auto-Manual Switch 5

Sets IIN Local bit.

0 = Auto, 1 = Manual

01/1/0 OR 02/2/1 Spare2 6 Always 0

01/1/0 OR 02/2/3 Spare3 7 Always 0

01/1/0 OR 02/2/3 Auto-Remote Timeout Timer Enable 8 0 = Disabled, 1 = Enabled

01/1/0 OR 02/2/3

Under/Over-Voltage SCADA Override Enable 9 0 = Disabled, 1 = Enabled

01/1/0 OR 02/2/3 SCADA Override Active 10 0 = Inactive, 1 = Active

01/1/0 OR 02/2/3 Open Operation is Pending 11 0 = No Open Pending, 1 = Open

01/1/0 OR 02/2/3 Close Operation is Pending 12 0 = No Close Pending, 1 = Close

01/1/0 OR 02/2/3 Switch State (Open/Closed) Unknown 13 0 = OK, 1 = State is Unknown

01/1/0 OR 02/2/3 Under-Voltage Override 14 0 = Disabled, 1 = Enabled

01/1/0 OR 02/2/3 Under-Voltage Override Active 15 0 = Inactive, 1 = Active

01/1/0 OR 02/2/3 Over-Voltage Override 16 0 = Disabled, 1 = Enabled

01/1/0 OR 02/2/3 Over-Voltage Override Active 17 0 = Inactive, 1 = Active

01/1/0 OR 02/2/3 Emergency UV Override 18 0 = Inactive, 1 = Active

01/1/0 OR 02/2/3 Emergency OV Override 19 0 = Inactive, 1 = Active

01/1/0 OR 02/2/3 Under/Over-Voltage Control 20 0 = Disabled, 1 = Active

01/1/0 OR 02/2/3 Emergency Under/Over Voltage Control 21 0 = Disabled, 1 = Active

01/1/0 OR 02/2/3 Switching Delta Voltage Error 22 0 = No Error, 1 = Error Occurred



Basic Output Data Registers – Control Points

Object /

Variation Point Name

Point

Address

Operation

Type Description

Operation

Conditions

12/1 Cap Bank Switch Trip/Close 0 Latched Off = Trip

On = Close

Auto-Remote mode (Status Input 1) must be 1 (Remote). Auto-Manual (Status Input 5) must be 0 (Auto)

12/1 Remote Mode / Auto Mode 1 Latched Off = Auto

On = Remote

None.

12/1 Delta Voltage Learn 2 Latched Off = Disable

On = Enable

None.

12/1 IEEE Cap Discharge Delay – 10/5 minutes

3 Latched Off = 10 minutes

On = 5 minutes

None.

12/1 Maximum Daily Operations 4 Latched Off = Disable

On = Enable

None.

12/1 Auto-Remote Timeout Enable 5 Latched Off = Disable

On = Enable

None.

12/1 Under/Over-Voltage SCADA Override

6 Latched Off = Disable

On = Enable

None.

12/1

Under-Voltage Override 7 Latched Off = Disable

On = Enable

None.

12/1

Over-Voltage Override 8 Latched Off = Disable

On = Enable

None.

12/1

Voltage Control 9 Latched Off = Disable

On = Enable

None.

12/1

Emergency Voltage Control 10 Latched Off = Disable

On = Enable

None.

12/1

Clear Operations Counter 11 Latched Off = Clear

On = Clear

None.



Analog Outputs

Object /

Variation Parameter

Point

Address Units Default Range

41 / 2 Auto/Remote Timeout Time 0 Seconds 300

41 / 2 Under-Voltage Close/Override Value 1

1201 = 120.1 Volts 1160

41 / 2 Over-Voltage Close/Override Value 2

1201 = 120.1

Volts 1260

41 / 2 UV/OV Tracking Time 3 Seconds 120

41 / 2 Emergency Under-Voltage Close Value 4

1201 = 120.1 Volts 1150

41 / 2 Emergency Over-Voltage Open Value 5

1201 = 120.1 Volts 1290

41 / 2 Emergency UV/OV Tracking Time 6 Seconds 120

41 / 2 Time Period Start Time 7 See Note 1. 2304

41 / 2 Time Period End Time 8 See Note 1. 5376

41 / 2 Outside Time Period Remain 9

0 = Open, 1 = Closed 0 0 to 1

41 / 2 Low Temperature (Trip) 10 Degrees F 80

41 / 2 High Temperature (Open) 11 Degree F 95

41 / 2 Open Delta Voltage 12 201 = 2.01 Volts 200

41 / 2 Close Delta Voltage 13 201 = 2.01 Volts 200

41 / 2 Max Daily Operations 14 1 10



Analog Output Status

Object /

Variation Parameter

Point

Address Units Default Range

40 / 2 Auto/Remote Timeout Time 0 Seconds 300

40 / 2 Under-Voltage Close/Override Value 1

1201 = 120.1 Volts 1160

40 / 2 Over-Voltage Close/Override Value 2

1201 = 120.1

Volts 1260

40 / 2 UV/OV Tracking Time 3 Seconds 120

40 / 2 Emergency Under-Voltage Close Value 4

1201 = 120.1 Volts 1150

40 / 2 Emergency Over-Voltage Open Value 5

1201 = 120.1 Volts 12900

40 / 2 Emergency UV/OV Tracking Time 6 Seconds 120

40 / 2 Time Period Start Time 7 See Note 1. 2304

40 / 2 Time Period End Time 8 See Note 1. 5376

40 / 2 Outside Time Period Remain 9

0 = Open, 1 = Closed 0 0 to 1

40 / 2 High Temperature (Close) 10 Degrees F 95

40 / 2 Low Temperature (Open) 11 Degree F 80

40 / 2 Open Delta Voltage 12 201 = 2.01 Volts 200

40 / 2 Close Delta Voltage 13 201 = 2.01 Volts 200

40 / 2 Max Daily Operations 14 1 10

Note 1: Time Values

Time = (Hour X 256) + Minutes

Example: 14:30 = (14 X 256) + 30 = 3614

Documents

UG-1056 NPC eCAP-9040 User's Guide€¦ · NPC eCAP-9040 User's Guide ALL RIGHTS RESERVED NOTICE The information in this document has been carefully checked and is believed to be