PowerLogic™ Series 800 Power Meter
PM810, PM820, PM850, & PM870
User Guide
63230-500-225A2
03/2011
Download from Www.Somanuals.com. All Manuals Search And Download.
TM
63230-500-225A2
3/2011
PowerLogic Series 800 Power Meter
HAZARD CATEGORIES AND SPECIAL SYMBOLS
Read these instructions carefully and look at the equipment to become familiar with the
device before trying to install, operate, service, or maintain it. The following special
messages may appear throughout this bulletin or on the equipment to warn of potential
hazards or to call attention to information that clarifies or simplifies a procedure.
The addition of either symbol to a “Danger” or “Warning” safety label indicates that an
electrical hazard exists which will result in personal injury if the instructions are not
followed.
This is the safety alert symbol. It is used to alert you to potential personal injury hazards.
Obey all safety messages that follow this symbol to avoid possible injury or death.
DANGER
DANGER indicates an imminently hazardous situation which, if not
avoided, will result in death or serious injury.
WARNING
WARNING indicates a potentially hazardous situation which, if not
avoided, can result in death or serious injury.
CAUTION
CAUTION indicates a potentially hazardous situation which, if not
avoided, can result in minor or moderate injury.
CAUTION
CAUTION, used without the safety alert symbol, indicates a potentially
hazardous situation which, if not avoided, can result in property
damage.
NOTE: Provides additional information to clarify or simplify a procedure.
PLEASE NOTE
Electrical equipment should be installed, operated, serviced, and maintained only by
qualified personnel. No responsibility is assumed by Schneider Electric for any
consequences arising out of the use of this material.
CLASS A FCC STATEMENT
This equipment has been tested and found to comply with the limits for a Class A digital
device, pursuant to part 15 of the FCC Rules. These limits are designed to provide
reasonable protection against harmful interference when the equipment is operated in a
commercial environment. This equipment generates, uses, and can radiate radio frequency
energy and, if not installed and used in accordance with the instruction manual, may cause
harmful interference to radio communications. Operation of this equipment in a residential
area is likely to cause harmful interference in which case the user will be required to correct
the interference at his own expense. This Class A digital apparatus complies with Canadian
ICES-003.
© 2011 Schneider Electric. All Rights Reserved.
iii
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TM
PowerLogic Series 800 Power Meter
63230-500-225A2
3/2011
© 2011 Schneider Electric. All Rights Reserved.
iv
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63230-500-225A2
3/2011
PowerLogicTM Series 800 Power Meter
Contents
Contents
Topics Not Covered In This Manual - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 1
What is a Power Meter? - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 1
Power Meter Hardware - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 2
Box Contents - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 6
Features - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 7
Firmware - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 7
Chapter 3—Operation - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 11
Power Meter Display - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 11
How the Buttons Work - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 11
Changing Values - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 11
Menu Overview - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 11
Power Meter Setup - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 13
Power Meter Resets - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 23
Power Meter Diagnostics - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 25
Chapter 4—Metering Capabilities - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 27
Real-Time Readings - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 27
Power Factor Min/Max Conventions - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 28
Power Factor Sign Conventions - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 29
Demand Readings - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 30
Energy Readings - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 35
Power Analysis Values - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 37
Chapter 5—Input/Output Capabilities - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 39
Digital Inputs - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 39
Demand Synch Pulse Input - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 40
Relay Output Operating Modes - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 40
Solid-state KY Pulse Output - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 42
Fixed Pulse Output - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 43
Calculating the Kilowatthour-Per-Pulse Value - - - - - - - - - - - - - - - - - - - - - - - - - - - 43
Analog Inputs - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 44
Analog Outputs - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 44
Chapter 6—Alarms - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 45
Basic Alarms - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 45
Basic Alarm Groups - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 45
Setpoint-driven Alarms - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 46
Priorities - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 47
Viewing Alarm Activity and History - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 47
Types of Setpoint-controlled Functions - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 47
Scale Factors - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 49
Scaling Alarm Setpoints - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 50
Alarm Conditions and Alarm Numbers - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 50
Advanced Alarms- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 53
Advanced Alarm Groups - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 53
Alarm Levels - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 54
Viewing Alarm Activity and History - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 54
Alarm Conditions and Alarm Numbers - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 55
Chapter 7—Logging - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 57
Introduction - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 57
Memory Allocation for Log Files - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 58
Alarm Log - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 58
Maintenance Log - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 58
Data Logs - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 60
Billing Log - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 61
v
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PowerLogicTM Series 800 Power Meter
Contents
63230-500-225A2
3/2011
Chapter 8—Waveform Capture - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -63
Introduction - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -63
Waveform Capture - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -63
Waveform Storage - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -64
How the Power Meter Captures an Event - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -64
Channel Selection in PowerLogic Software - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -64
Chapter 9—Disturbance Monitoring (PM870) - - - - - - - - - - - - - - - - - - - - - - - - - - - - -65
About Disturbance Monitoring - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -65
Capabilities of the PM870 During an Event - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -67
Introduction - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -69
Power Meter Memory - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -69
Viewing the Display in Different Languages - - - - - - - - - - - - - - - - - - - - - - - - - - - - -70
Technical Support - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -70
Troubleshooting - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -71
Using This Appendix - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -73
Section II: 3-Wire System Troubleshooting - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -75
Section III: 4-Wire System Troubleshooting - - - - - - - - - - - - - - - - - - - - - - - - - - - - -76
Field Example - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -78
Appendix B—Register List - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 79
Register List Access - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -79
About Registers - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -79
How Date and Time are Stored in Registers - - - - - - - - - - - - - - - - - - - - - - - - - - - - -80
Supported Modbus Commands - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -81
Resetting Registers - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -81
Overview of the Command Interface - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -83
Conditional Energy - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -87
Incremental Energy - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -88
Setting Up Individual Harmonic Calculations - - - - - - - - - - - - - - - - - - - - - - - - - - - - -89
Changing Scale Factors - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -90
Enabling Floating-point Registers - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -91
Power Quality Standards - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -93
SEMI-F47/ITI (CBEMA) Specification - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -93
EN50160:2000 Specification - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -95
How Evaluation Results Are Reported - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -95
Evaluation During Normal Operation - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -96
Operation with PQ Advanced Enabled - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -99
Advanced Power Quality Evaluation System Configuration
and Status Registers [EN50160 and SEMI-F47/ITI (CBEMA)] - - - - - - - - - - - - - - - -99
Glossary - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -105
Terms - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -105
Abbreviations and Symbols - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -107
Index - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -109
vi
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63230-500-225A2
3/2011
PowerLogicTM Series 800 Power Meter
Chapter 1—Introduction
Chapter 1—Introduction
™
This user guide explains how to operate and configure a PowerLogic Series 800 Power
Meter. Unless otherwise noted, the information contained in this manual refers to the
following power meters:
•
•
•
Power meter with integrated display
Power meter without a display
Power meter with a remote display
Refer to “Power Meter Parts and Accessories” on page 5 for all models and model
numbers. For a list of supported features, see “Features” on page 7.
NOTE: The power meter units on the PM810, PM810U, and the PM810RD are functionally
equivalent.
Topics Not Covered In This Manual
Some of the power meter’s advanced features, such as on-board data logs and alarm log
files, can only be set up via the communications link using PowerLogic software. This
power meter user guide describes these advanced features but does not explain how to set
them up. For information on using these features, refer to your software’s online help or
user guide.
What is a Power Meter?
A power meter is a multifunction, digital instrumentation, data acquisition and control
device. It can replace a variety of meters, relays, transducers, and other components. This
power meter is equipped with RS485 communications for integration into any power
monitoring/control system and can be installed at multiple locations within a facility.
These are true rms meters, capable of exceptionally accurate measurement of highly
non-linear loads. A sophisticated sampling technique enables accurate measurements
➀
through the 63rd harmonic . You can view over 50 metered values, plus minimum and
the readings available from the power meter.
Table 1–1: Summary of power meter instrumentation
Real-time Readings
Power Analysis
•
•
•
•
•
•
•
•
Current (per phase, residual, 3-Phase)
Voltage (L–L, L–N, 3-Phase)
Real Power (per phase, 3-Phase
Reactive Power (per phase, 3-Phase
Apparent Power (per phase, 3-Phase
Power Factor (per phase, 3-Phase
Frequency
•
•
•
•
•
•
•
•
Displacement Power Factor (per phase, 3-Phase
Fundamental Voltages (per phase)
Fundamental Currents (per phase)
Fundamental Real Power (per phase)
Fundamental Reactive Power (per phase)
Unbalance (current and voltage)
Phase Rotation
THD (current and voltage)
Current and Voltage Harmonic Magnitudes and
➀
Angles (per phase)
•
Sequence Components
Energy Readings
Demand Readings
•
•
•
•
•
•
•
Accumulated Energy, Real
Accumulated Energy, Reactive
Accumulated Energy, Apparent
Bidirectional Readings
Reactive Energy by Quadrant
Incremental Energy
•
Demand Current (per phase present, 3-Phase
avg.)
Average Power Factor (3-Phase total)
Demand Real Power (per phase present, peak)
Demand Reactive Power (per phase present,
peak)
•
•
•
Conditional Energy
•
Demand Apparent Power (per phase present,
peak)
•
•
Coincident Readings
Predicted Power Demands
➀ Individual harmonics are not calculated in the PM810. The PM810 with PM810LOG, and the PM820,
calculate distortion to the 31st harmonic. The PM850 and PM870 calculate distortion to the 63rd harmonic.
1
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TM
PowerLogic Series 800 Power Meter
63230-500-225A2
3/2011
Chapter 1—Introduction
Power Meter Hardware
Power Meter With Integrated Display
Figure 1–1: Parts of the Series 800 Power Meter with integrated display
Bottom View
2
4
3
8
1
5
6
7
Back View
Table 1–2: Parts of the Series 800 Power Meter with integrated display
No. Part
Description
1
2
3
4
Control power supply connector
Connection for control power to the power meter.
Voltage metering connections.
Voltage inputs
I/O connector
Heartbeat LED
KY pulse output/digital input connections.
A green flashing LED indicates the power meter is ON.
The RS-485 port is used for communications with a monitoring and
control system. This port can be daisy-chained to multiple devices.
5
RS-485 port (COM1)
6
7
8
Option module connector
Current inputs
Used to connect an option module to the power meter.
Current metering connections.
Integrated display
Visual interface to configure and operate the power meter.
2
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63230-500-225A2
3/2011
PowerLogicTM Series 800 Power Meter
Chapter 1—Introduction
Power Meter Without Display
Figure 1–2: Parts of the Series 800 Power Meter without display
Bottom View
3
4
2
1
5
6
7
Back View
Table 1–3: Parts of the Series 800 Power Meter without display
No. Part Description
1
2
3
4
Control power supply connector
Connection for control power to the power meter.
Voltage metering connections.
Voltage inputs
I/O connector
Heartbeat LED
KY pulse output/digital input connections.
A green flashing LED indicates the power meter is ON.
The RS-485 port is used for communications with a monitoring and
control system. This port can be daisy-chained to multiple devices.
5
RS-485 port (COM1)
6
7
Option module connector
Current inputs
Used to connect an option module to the power meter.
Current metering connections.
3
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TM
PowerLogic Series 800 Power Meter
63230-500-225A2
3/2011
Chapter 1—Introduction
Power Meter With Remote Display
NOTE: The remote display kit (PM8RD) is used with a power meter without a display. See
“Power Meter Without Display” on page 3 for the parts of the power meter without a display.
Figure 1–3: Parts of the remote display and the remote display adapter
1
2
4 5 6 7 8
3
TX/RX
PM8RDA Top View
Table 1–4: Parts of the remote display
No. Part
Description
Provides the connection between the remote display and the
1
Remote display adapter (PM8RDA) power meter. Also provides an additional RS232/RS485
connection (2- or 4-wire).
2
3
4
Cable CAB12
Connects the remote display to the remote display adapter.
Visual interface to configure and operate the power meter.
Use to select the communications mode (RS232 or RS485).
Remote display (PM8D)
Communications mode button
When lit, the LED indicates the communications port is in RS232
mode.
5
Communications mode LED
This port is used for communications with a monitoring and control
system. This port can be daisy-chained to multiple devices.
6
7
8
RS232/RS485 port
Tx/Rx Activity LED
CAB12 port
The LED flashes to indicate communications activity.
Port for the CAB12 cable used to connect the remote display to
the remote display adapter.
4
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63230-500-225A2
3/2011
PowerLogicTM Series 800 Power Meter
Chapter 1—Introduction
Power Meter Parts and Accessories
Table 1–5: Power Meter Parts and Accessories
Model Number
Description
Schneider
Square D
Electric
Power meters
➀
➁
➂
➃
➀
➁
➂
➃
PM810
PM820
PM850
PM870
PM810MG
PM820MG
PM850MG
PM870MG
Power meter with integrated display
➀
➀
PM810U
PM820U
PM850U
PM870U
PM810UMG
PM820UMG
PM850UMG
PM870UMG
➁
➂
➃
➁
➂
➃
Power meter without display
➀
➁
➂
➃
➀
➁
➂
➃
PM810RD
PM820RD
PM850RD
PM870RD
PM810RDMG
PM820RDMG
PM850RDMG
PM870RDMG
Power meter with remote display
Accessories
Remote display with remote display
adapter
PM8RD
PM8RDMG
Remote display adapter
PM8RDA
Input/Output modules
PM810 logging module
PM8M22, PM8M26, PM8M2222
PM810LOG
Cable (12 feet) extender kit for
displays
RJ11EXT
Retrofit gasket (for 4 in. round hole
mounting)
PM8G
CM2000 retrofit mounting adapter
PM8MA
➀ The power meter units for these models are identical and support the
➁ The power meter units for these models are identical and support the
➂ The power meter units for these models are identical and support the
➃ The power meter units for these models are identical and support the
5
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TM
PowerLogic Series 800 Power Meter
63230-500-225A2
3/2011
Chapter 1—Introduction
Box Contents
Table 1–6: Box contents based on model
Model Description
Box Contents
•
•
Power Meter with integrated display
Hardware kit (63230-500-16) containing:
— Two retainer clips
— Template
Power Meter with Integrated Display
— Plug set
— Terminator MCT2W
Power Meter installation guides (EN, FR, ES, DE)
•
•
Power Meter specification guide
•
•
Power Meter without display
Hardware kit (63230-500-16) containing:
— Two retainer clips
— Template
— DIN Slide (installed at factory)
— Plug set
Power Meter without Display
— Terminator MCT2W
Power Meter installation guides (EN, FR, ES, DE)
•
•
Power Meter specification guide
•
•
•
•
Power Meter without display
Remote display (PM8D)
Remote display adapter (PM8RDA)
Hardware kit (63230-500-16) containing:
— Two retainer clips
— Template
— DIN Slide (installed at factory)
— Plug set
— Terminator MCT2W
Power Meter with Remote Display
•
•
Hardware kit (63230-500-96) containing:
— Communication cable (CAB12)
— Mounting screws
Hardware kit (63230-500-163) containing:
— Com 2 RS-485 4-wire plug
— Crimp connector
•
•
Power Meter installation guides (EN, FR, ES, DE)
Power Meter specification guide
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PowerLogicTM Series 800 Power Meter
Chapter 1—Introduction
Features
Table 1–7: Series 800 Power Meter Features
PM810 PM820 PM850 PM870
True rms metering to the 63rd harmonic
Accepts standard CT and PT inputs
(3)
(3)
600 volt direct connection on voltage inputs
High accuracy — 0.075% current and voltage (typical conditions)
Min/max readings of metered data
Input metering (five channels) with PM8M22, PM8M26, or PM8M2222
installed
Power quality readings — THD
Downloadable firmware
Easy setup through the integrated or remote display (password protected)
Setpoint-controlled alarm and relay functions
On-board alarm logging
Wide operating temperature range: –25° to +70°C for the power meter
unit
Communications:
On-board: one Modbus RS485 (2-wire)
PM8RD: one configurable Modbus RS232/RS485 (2- or 4-wire)
Active energy accuracy: ANSI C12.20 Class 0.2S and IEC 62053-22
Class 0.5S
Non-volatile clock
(1)
(2)
On-board data logging
80 KB 800 KB 800 KB
Real-time harmonic magnitudes and angles (I and V):
To the 31st harmonic
(3)
—
—
To the 63rd harmonic
—
Waveform capture
Standard
—
—
—
—
Advanced
—
EN50160 evaluations
NOTE: The PM850 performs EN50160 evaluations based on
standard alarms, while the PM870 performs EN50160 evaluations
based on disturbance alarms.
—
—
ITI (CBEMA) and SEMI-F47 evaluations
—
—
—
—
—
—
NOTE: The PM870 performs ITI (CBEMA) and SEMI-F47
evaluations based on disturbance alarms.
Current and voltage sag/swell detection and logging
(1) The Time Clock in the PM810 with PM810LOG is non-volatile. However, it is volatile in the PM810.
(2) The on-board data logging memory in the PM810 with PM810LOG is 80 KB, but it is not available in the PM810.
(3) The PM810 with PM810LOG and the PM820 monitor distortion to the 31st harmonic. Harmonic distortion is not
monitored in the PM810.
Firmware
This user guide is written to be used with firmware version 11.xx and above. See
on how to determine the firmware version. To download the latest firmware version, follow
the steps below:
1. Using a web browser, go to http://www.Schneider-Electric.com.
2. Locate the Search box in the upper right corner of the home page.
3. In the Search box enter “PM8”.
4. In the drop-down box click on the selection “PM800 series”.
5. Locate the downloads area on the right side of the page and click on
“Software/Firmware”.
6. Click on the applicable firmware version title (i.e. “PowerLogic Series 800 Power Meter
Firmware version 12.100”).
7. Download and run the “xxx.exe” firmware upgrade file provided.
7
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TM
PowerLogic Series 800 Power Meter
63230-500-225A2
3/2011
Chapter 1—Introduction
8
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PowerLogicTM Series 800 Power Meter
Chapter 2—Safety Precautions
Chapter 2—Safety Precautions
DANGER
HAZARD OF ELECTRIC SHOCK, EXPLOSION OR ARC FLASH
• Apply appropriate personal protective equipment (PPE) and follow safe electrical
practices. For example, in the United States, see NFPA 70E.
• This equipment must only be installed and serviced by qualified electrical
personnel.
• NEVER work alone.
• Before performing visual inspections, tests, or maintenance on this equipment,
disconnect all sources of electric power. Assume that all circuits are live until they
have been completely de-energized, tested, and tagged. Pay particular attention to
the design of the power system. Consider all sources of power, including the
possibility of backfeeding.
• Turn off all power supplying this equipment before working on or inside equipment.
• Always use a properly rated voltage sensing device to confirm that all power is off.
• Beware of potential hazards and carefully inspect the work area for tools and
objects that may have been left inside the equipment.
• Use caution while removing or installing panels so that they do not extend into the
energized bus; avoid handling the panels, which could cause personal injury.
• The successful operation of this equipment depends upon proper handling,
installation, and operation. Neglecting fundamental installation requirements may
lead to personal injury as well as damage to electrical equipment or other property.
• Before performing Dielectric (Hi-Pot) or Megger testing on any equipment in which
the power meter is installed, disconnect all input and output wires to the power
meter. High voltage testing may damage electronic components contained in the
power meter.
• Always use grounded external CTs for current inputs.
Failure to follow these instructions will result in death or serious injury.
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Chapter 2—Safety Precautions
63230-500-225A2
3/2011
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PowerLogicTM Series 800 Power Meter
Chapter 3—Operation
Chapter 3—Operation
This section explains the features of the power meter display and the power meter setup
procedures using this display. For a list of all power meter models containing an integrated
Power Meter Display
The power meter is equipped with a large, back-lit liquid crystal display (LCD). It can
the different parts of the power meter display.
Figure 3–1: Power Meter Display
A. Type of measurement
A
B
C
D
B. Screen title
C. Alarm indicator
D. Maintenance icon
E. Bar chart (%)
F. Units (A, V, etc.)
G. Display more menu items
H. Menu item
ꢑꢆꢒ
ꢂꢅꢀꢃꢆꢀꢄꢇꢆꢀꢁꢂꢃꢄ
ꢊ
ꢏꢏꢏꢏꢏꢐꢐꢐꢐꢐꢐ
E
F
ꢈꢖꢆꢆꢆꢆꢗꢖꢆꢆꢆꢈꢖꢖ
ꢀꢁꢂ
ꢀꢃꢂ
ꢀꢁꢄ
ꢂ
ꢓ
ꢔ
ꢂꢆ
M
L
ꢏꢏꢏꢏꢏꢐꢐꢐꢐꢐꢐ
ꢈꢖꢆꢆꢆꢆꢗꢖꢆꢆꢆꢈꢖꢖ
ꢂꢆ
ꢏꢏꢏꢏꢏꢐꢐꢐꢐꢐꢐ
ꢈꢖꢆꢆꢆꢆꢗꢖꢆꢆꢆꢈꢖꢖ
ꢂ
ꢘ
I. Selected menu indicator
J. Button
ꢀꢅꢃ
ꢕ
ꢂ
ꢆꢈꢉ
ꢀꢁꢂꢃꢄ ꢊꢆꢋꢅꢋꢌ ꢍꢍꢍꢎ
K. Return to previous menu
L. Values
G
M. Phase
K
J
I
H
How the Buttons Work
The buttons are used to select menu items, display more menu items in a menu list, and
return to previous menus. A menu item appears over one of the four buttons. Pressing a
button selects the menu item and displays the menu item’s screen. When you have
reached the highest menu level, a black triangle appears beneath the selected menu item.
To return to the previous menu level, press the button below 1;. To scroll through the menu
NOTE: Each time you read “press” in this manual, press and release the appropriate button
beneath the menu item. For example, if you are asked to “Press PHASE,” you would press
the button below the PHASE menu item.
Changing Values
When a value is selected, it flashes to indicate that it can be modified. A value is changed
by doing the following:
•
Press +(plus) or -(minus) to change numbers or scroll through available options.
•
If you are entering more than a single-digit number, press <--to move to the next
higher numeric position.
•
To save your changes and move to the next field, press OK.
Menu Overview
Figure 3–2 on page 12, shows the first two levels of the power meter menu. Level 1
contains all of the top level menu items. Selecting a Level 1 menu item takes you to the
corresponding Level 2 menu items. Additional menu levels may be provided, depending on
the specific meter features and options.
NOTE: Press ###:to scroll through all menu items on a given level.
11
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PowerLogicTM Series 800 Power Meter
Chapter 3—Operation
63230-500-225A2
3/2011
Figure 3–2: Abbreviated List of PM800 Menu Items in IEEE (IEC) Mode
LEVEL 1
LEVEL 2
AMPS (I)
PHASE
I - DMD
UNBAL
V L-L (U)
V L-N (V)
VOLTS (U-V)
PWR (PQS)
ENERG (E)
PF
PWR (PQS)
PHASE
VARh
P - DMD
1
Wh
VAh
INC
TRUE
DISPL
HZ (F)
THD
V L-L (U)
V L-N (V)
I
MINMX
MINMX
AMPS (I)
V L-N (V)
VOLTS (U-V)
I
UNBAL
PWR (PQS)
PF
HZ (F)
THD V
THD I
1
HARM
V L-L (U)
ALARM
I/O
ACTIV
D OUT
HIST
D IN
A OUT
A IN
PM8M2222
TIMER
2
CONTR
3
MAINT
RESET
SETUP
DIAG
METER
ENERG (E)
DMD
MINMX
MODE
TIMER
4
4
DATE
TIME
LANG
COMMS (COM)
METER
ALARM
I/O
PASSW
TIMER
ADVAN
COMM1
4
METER
REG
CLOCK
D OUT [Digital KY Out]
D IN [Digital In]
PM8RD
COMM2
PM8M2222, PM8M26, and PM8M22
PM8M2222
A OUT [Analog Out]
A IN
[Analog In]
➀ Available on the PM810 only when an optional Power Meter Logging Module (PM810LOG) is installed. Available on all other PM800 Series models.
➁ Available with some models.
➂ Both IEC and IEEE modes are available. Depending on the mode selected, menu labels will be different. See “Display Mode Change” on page 24 to select the
desired mode.
➃ The PM810 has a volatile clock. The PM810 with an optional Power Meter Logging Module (PM810LOG), and all other PM800 Series models, have a non-volatile
clock.
12
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PowerLogicTM Series 800 Power Meter
Chapter 3—Operation
Power Meter Setup
Power meter setup is typically performed by using the meter’s front panel display. To
configure a power meter without a display, you will need a means of communication
between the power meter and your computer. Additionally, you will need to install
PowerLogic Meter Configuration Software or PowerLogic ION Setup Software on your
computer. These can be downloaded from the Schneider’s www.Schneider-Electric.com
website.
Power meter setup is performed through the meter’s maintenance (MAINT) option. Refer to
Figure 3–2 on page 12. Setup features may be programmed individually or in any order. To
access the Setup features, follow these steps:
SETUP MODE Access
1. Press ###:to scroll through the Level 1 menu until you see MAINT.
2. Press MAINT.
3. Press SETUP.
4. Enter your password, then press OK. The SETUP MODE screen will be displayed.
NOTE: The default password is 0000.
5. Press ###:to scroll through the setup features and select the one to be programmed.
After programming a feature, you may continue through the remaining features by returning
to the SETUP MODE screen and pressing ###:to scroll to additional features.
Once you have selected the correct options for each setup parameter, press 1;until the
SAVE CHANGES? prompt appears, then press YES. The meter will reset, briefly display
the meter info screen, then automatically return to the main screen.
the following topics:
DATE Setup
1. Perform steps 1 through 5 of the SETUP MODE
Access procedure on page 11.
ꢋꢂꢚꢄꢆꢃꢄꢚꢛꢀ
2. Press ###:until DATE is visible.
3. Press DATE.
ꢆꢃ
ꢀꢁ
ꢅꢝꢕꢚꢁ
ꢋꢂꢟ
4. Enter the MONTH number.
5. Press OK.
6. Enter the DAY number.
7. Press OK.
ꢀꢆꢆꢄ
ꢆꢃꢇꢀꢁꢇꢆꢄ ꢅꢠꢋꢠꢟ
ꢟꢄꢂꢇ
8. Enter the YEAR number.
9. Press OK.
ꢈꢉ
ꢙꢍ
ꢜ
ꢝꢞ
10. Select how the date is displayed: M/D/Y,
Y/M/D, or D/M/Y).
11. Press OK to return to the SETUP MODE
screen.
12. Press1;to return to the main screen.
13. To verify the new settings, press MAINT >
DIAG > CLOCK.
NOTE: The clock in the PM810 is volatile. Each time the meter resets, the PM810 returns
page 69 for more information. All other PM800 Series meters have a non-volatile clock
which maintains the current date and time when the meter is reset.
13
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PowerLogicTM Series 800 Power Meter
Chapter 3—Operation
63230-500-225A2
3/2011
TIME Setup
1. Perform steps 1 through 5 of the SETUP MODE
Access procedure on page 11.
ꢚꢊꢅꢄꢆꢃꢄꢚꢛꢀ
2. Press ###:until TIME is visible.
3. Press TIME.
ꢀꢁ
ꢁꢃ
ꢂꢈ
ꢁꢥꢦꢧ
ꢅꢊꢕ
4. Enter the HOUR.
5. Press OK.
6. Enter the MIN (minutes).
7. Press OK.
ꢃꢡꢢ
ꢣꢤꢁ
ꢝꢞ
8. Enter the SEC (seconds).
9. Press OK.
ꢈꢉ
ꢙꢍ
ꢜ
10. Select how the time is displayed: 24H or
AM/PM.
11. Press OK to return to the SETUP MODE
screen.
12. Press 1;to return to the main screen.
13. To verify the new settings, press MAINT >
DIAG > CLOCK.
NOTE: The clock in the PM810 is volatile. Each time the meter resets, the PM810 returns
to the default clock date/time of 12:00 AM 01-01-1980. See “Date and Time Settings” on
page 69 for more information. All other PM800 Series meters have a non-volatile clock,
which maintains the current date and time when the meter is reset.
LANG (Language) Setup
1. Perform steps 1 through 5 of the SETUP MODE
Access procedure on page 11.
2. Press ###:until LANG is visible.
3. Press LANG.
ꢨꢂꢕꢩꢛꢂꢩꢄ
ꢄꢕꢩꢨꢌ
4. Select the language: ENGL (English), FREN
(French), SPAN (Spanish), GERMN (German),
or RUSSN (Russian).
5. Press OK.
6. At the SETUP MODE screen, continue
programming additional setup features or
press1;until you are asked to save changes.
ꢈꢉ
ꢙꢍ
ꢜ
ꢝꢞ
7. Press YES to save the changes.
14
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PowerLogicTM Series 800 Power Meter
Chapter 3—Operation
COMMS (Communications) Setup
NOTE: If you are using PowerLogic software to set up the power meter, it is recommended
you set up the communications features first.
Refer to Table 3-1 for the meter’s default settings.
Table 3–1: Communications Default Settings
Communications Setting
Default
Protocol
MB.RTU (Modbus RTU)
Address
Baud Rate
Parity
1
9600
Even
The same procedure is used to program the settings for the COMMS, COMM 1, and
COMM 2 options.
1. Perform steps 1 through 5 of the SETUP MODE
Access procedure on page 11.
ꢔꢝꢅꢅꢃꢆꢃꢄꢚꢛꢀ
2. Press ###:until COMMS (communications)
is visible.
ꢅꢓꢌꢇꢚꢛ
3. Press COMMS (communications).
4. Select the required protocol: MB.RTU (Modbus
RTU), Jbus, MB. A.8 (Modbus ASCII 8 bits),
MB. A.7 (Modbus ASCII 7 bits).
ꢂꢋꢋꢇꢌ
ꢪꢫꢦꢋ
ꢆꢆꢉ
ꢊꢄꢆꢆ
5. Press OK.
ꢄꢬꢄꢕ
ꢝꢞ
6. Enter the ADDR (power meter address).
7. Press OK.
ꢈꢉ
ꢙꢍ
ꢜ
8. Select the BAUD (baud rate).
9. Press OK.
10. Select the parity: EVEN, ODD, or NONE.
11. Press OK.
12. At the SETUP MODE screen, continue
programming additional setup features or
press1;until you are asked to save changes.
13. Press YES to save the changes.
METER Setup
This feature allows the user to configure the CTs, PTs, system frequency, and system
wiring method.
CTs Setup
1. Perform steps 1 through 5 of the SETUP MODE
Access procedure on page 11.
ꢔꢚꢆꢇꢂꢚꢊꢝ
2. Press ###:until METER is visible.
3. Press METER.
4. Press CT.
ꢈꢆꢆ
ꢂ
ꢔꢆꢚ
ꢔꢆꢚ
ꢀꢇꢊꢅ
ꢃꢄꢔꢌ
5. Enter the PRIM (CT primary) number.
6. Press OK.
7. Enter the SEC. (CT secondary) number.
8. Press OK.
ꢈꢉ
ꢙꢍ
ꢜ
ꢝꢞ
9. At the SETUP MODE screen, continue
programming additional setup features or
press1;until you are asked to save changes.
10. Press YES to save the changes.
15
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PowerLogicTM Series 800 Power Meter
Chapter 3—Operation
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3/2011
PTs Setup
1. Perform steps 1 through 5 of the SETUP MODE
Access procedure on page 11.
ꢀꢚꢆꢇꢂꢚꢊꢝ
2. Press ###:until METER is visible.
3. Press METER.
ꢭ
ꢉ
ꢉꢀꢆ
ꢉꢀꢆ
ꢃꢔꢂꢨꢄ
ꢀꢇꢊꢅ
4. Press PT.
5. Enter the SCALE value: x1, x10, x100, NO PT
(for direct connect).
ꢃꢄꢔꢌ
ꢝꢞ
6. Press OK.
7. Enter the PRIM (primary) value.
8. Press OK.
ꢈꢉ
ꢙꢍ
ꢜ
9. Enter the SEC. (secondary) value.
10. Press OK.
11. At the SETUP MODE screen, continue
programming additional setup features or
press1;until you are asked to save changes.
12. Press YES to save the changes.
HZ (System Frequency) Setup
1. Perform steps 1 through 5 of the SETUP MODE
Access procedure on page 11.
ꢆꢆꢆꢒ
ꢃꢟꢃꢚꢄꢅꢆꢮꢧꢡꢯꢦꢡꢕꢢꢰ
2. Press ###:until METER is visible.
3. Press METER.
4. Press ###:until HZ is visible.
5. Press HZ.
ꢄꢆ
ꢄꢆ
ꢁꢱ
6. Select the frequency.
7. Press OK.
ꢮꢇꢄꢲꢌ
ꢝꢞ
8. At the SETUP MODE screen, continue
programming additional setup features or
press1;until you are asked to save changes.
ꢈꢉ
ꢙꢍ
ꢜ
9. Press YES to save the changes.
SYS (System Type) Setup
1. Perform steps 1 through 5 of the SETUP MODE
Access procedure on page 11.
ꢆꢆꢆꢒ
ꢳꢆꢀꢁꢂꢃꢄꢆꢃꢟꢃꢚꢄꢅ
2. Press ###:until METER is visible.
3. Press METER.
A
ꢃ
ꢁ
ꢁ
ꢴꢊꢇꢄ
ꢔꢚ
4. Press ###:until SYS is visible.
5. Press SYS.
B
C
6. Select your system (SYS) type (D) based on
the number of wires (A), the number of CTs (B),
and the number of voltage connections (either
direct connect or with PT) (C).
ꢀꢚ
D
ꢃꢆ
ꢍ
ꢃꢟꢃꢌ
ꢝꢞ
ꢈꢉ
ꢜ
7. Press OK.
8. At the SETUP MODE screen, continue
programming additional setup features or
press1;until you are asked to save changes.
9. Press YES to save the changes.
16
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PowerLogicTM Series 800 Power Meter
Chapter 3—Operation
ALARM (Alarms) Setup
There is an extensive list of meter error conditions
which can be monitored and cause an alarm.
ꢆꢆꢆꢒ
ꢝꢬꢄꢇꢆꢬꢂꢕ
1. Perform steps 1 through 5 of the SETUP MODE
Access procedure on page 11.
ꢄꢕꢂꢓꢨꢌ
ꢁꢊꢩꢁ
2. Press ###:until ALARM is visible.
ꢀꢆꢇ
ꢈꢉ
3. Press ALARM.
4. Press <-or ->to select the alarm option you
ꢂꢓꢃꢝꢨ
want to edit.
5. Press EDIT.
ꢙꢍ
ꢜ
ꢝꢞ
6. Select to ENABL (enable) or DISAB (disable)
the alarm.
7. Press OK.
8. Select the PR (priority): NONE, HIGH, MED, or
LOW.
9. Press OK.
10. Select how the alarm values are displayed:
ABSOL (absolute value) or RELAT (percentage
relative to the running average).
ꢆꢆꢆꢒ
ꢝꢬꢄꢇꢆꢬꢂꢕ
11. Enter the PU VALUE (pick-up value).
12. Press OK.
ꢀꢆꢛ
ꢅꢂꢩꢌ
ꢉꢆꢆ
ꢉ
ꢀꢆꢛ
ꢋꢆꢝ
ꢋꢆꢝ
ꢈꢉ
ꢋꢄꢨꢂꢟ
13. Enter the PU DELAY (pick-up delay).
14. Press OK.
ꢃ
ꢅꢂꢩꢌ
ꢋꢄꢨꢂꢟ
ꢝꢞ
15. Enter the DO VALUE (drop-out value).
16. Press OK.
ꢃ
ꢜ
ꢙꢍꢍꢍꢍ
17. Enter the DO DELAY (drop-out delay).
18. Press OK.
19. Press 1;to return to the alarm summary
screen.
20. Press 1;to return to the SETUP MODE screen.
21. At the SETUP MODE screen, continue
programming additional setup features or
press1;until you are asked to save changes.
22. Press YES to save the changes.
17
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PowerLogicTM Series 800 Power Meter
Chapter 3—Operation
63230-500-225A2
3/2011
I/O (Input/Output) Setup
1. Perform steps 1 through 5 of the SETUP MODE
Access procedure on page 11.
2. Press ###:until I/O is visible.
3. Press I/O.
ꢆꢆꢆꢒ
ꢞꢟ
ꢕꢝꢇꢅ
4. Press D OUT for digital output or D IN for digital
input, or press A OUT for analog output or A IN
for analog input. Use the ###:button to scroll
through these selections.
ꢆ
ꢆ
ꢀꢛꢨꢃꢄ
ꢚꢊꢅꢄꢇ
ꢄꢭꢚꢌ
NOTE: Analog inputs and outputs are available
only with the PM8222 option module.
ꢈꢉ
ꢙꢍ
ꢜ
ꢝꢞ
5. Press EDIT.
6. Select the I/O mode based on the I/O type and
the user selected mode: NORM., LATCH,
TIMED, PULSE, or END OF.
7. Depending on the mode selected, the power
meter will prompt you to enter the pulse weight,
timer, and control.
8. Press OK.
9. Select EXT. (externally controlled via
communications) or ALARM (controlled by an
alarm).
10. Press 1;to return to the SETUP MODE screen.
11. At the SETUP MODE screen, continue
programming additional setup features or
press1;until you are asked to save changes.
12. Press YES to save the changes.
PASSW (Password) Setup
1. Perform steps 1 through 5 of the SETUP MODE
Access procedure on page 11.
ꢆꢆꢆꢒ
ꢀꢂꢃꢃꢴꢝꢇꢋꢆꢃꢄꢚꢛꢀ
ꢆꢆꢆꢆ
ꢆꢆꢆꢆ
2. Press ###:until PASSW (password) is visible.
3. Press PASSW.
ꢃꢄꢚꢛꢀ
ꢋꢊꢂꢩꢌ
4. Enter the SETUP password.
5. Press OK.
6. Enter the DIAG (diagnostics) password.
7. Press OK.
ꢆꢆꢆꢆ
ꢄꢕꢄꢇꢩ
ꢆꢆꢆꢆ
ꢜ
ꢅꢕꢠꢅꢭ
ꢝꢞ
8. Enter the ENERG (energy reset) password.
9. Press OK.
ꢈꢉ
ꢙꢍ
10. Enter the MN/MX (minimum/maximum reset)
password.
11. Press OK.
12. At the SETUP MODE screen, continue
programming additional setup features or
press1;until you are asked to save changes.
13. Press YES to save the changes.
18
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PowerLogicTM Series 800 Power Meter
Chapter 3—Operation
TIMER (Operating Time Threshold) Setup
1. Perform steps 1 through 5 of the SETUP MODE
Access procedure on page 11.
2. Press ###:until TIMER is visible.
3. Press TIMER.
ꢝꢀꢄꢇꢆꢚꢊꢅꢄꢆꢃꢄꢚꢛꢀ
ꢀ
ꢳꢍꢀ
ꢊꢌꢆꢂꢬꢩ
ꢂ
4. Enter the 3-phase current average.
ꢉ
NOTE: The power meter begins counting the
operating time whenever the readings are equal
to or above the average.
5. Press OK.
ꢈꢉ
ꢙꢍꢍꢍꢍ
ꢜ
ꢝꢞ
6. At the SETUP MODE screen, continue
programming additional setup features or
press1;until you are asked to save changes.
7. Press YES to save the changes.
ADVAN (Advanced) Power Meter Setup Features
The Advanced Feature set contains several items which need to be programmed. To
access these features, follow these steps:
After programming a feature, you may continue through the remaining features by returning
to the SETUP MODE screen and pressing ###:to scroll to additional features.
Once you have selected the correct options for each setup parameter, press 1;until the
SAVE CHANGES? prompt appears, then press YES. The meter will reset, briefly display
the meter info screen, then automatically return to the main screen.
ROT (Phase Rotation) Setup
1. Perform steps 1 through 5 of the SETUP MODE
Access procedure on page 11.
ꢀꢁꢂꢃꢄꢆꢇꢥꢵꢫꢵꢶꢥꢕ
2. Press ###:until ADVAN (advanced setup) is
visible.
ꢂꢓꢔ
3. Press ADVAN.
4. Press ###:until ROT (phase rotation) is visible.
5. Press ROT.
6. Select the phase rotation: ABC or CBA.
7. Press OK.
ꢈꢉ
ꢙꢍ
ꢜ
8. At the SETUP MODE screen, continue
programming additional setup features or
press1;until you are asked to save changes.
9. Press YES to save the changes.
19
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PowerLogicTM Series 800 Power Meter
Chapter 3—Operation
63230-500-225A2
3/2011
E-INC (Incremental Energy Interval) Setup
1. Perform steps 1 through 5 of the SETUP MODE
Access procedure on page 11.
ꢊꢕꢔꢇꢆꢄꢕꢄꢇꢩꢟ
2. Press ###:until ADVAN (advanced setup) is
visible.
3. Press ADVAN.
ꢄꢆ
ꢊꢕꢚꢬꢨ
4. Press ###:until E-INC (incremental energy) is
visible.
5. Press E-INC.
6. Enter the INTVL (interval). Range is 00 to 1440.
7. Press OK.
ꢈꢉ
ꢙꢍ
ꢜ
ꢝꢞ
8. At the SETUP MODE screen, continue
programming additional setup features or
press1;until you are asked to save changes.
9. Press YES to save the changes.
THD Calculation Setup
1. Perform steps 1 through 5 of the SETUP MODE
Access procedure on page 11.
ꢚꢁꢋꢆꢔꢫꢷꢢꢦꢷꢫꢵꢶꢥꢕ
2. Press ###:until ADVAN (advanced setup) is
visible.
3. Press ADVAN.
ꢸꢦꢕꢋ
4. Press ###:until THD is visible.
5. Press THD.
6. Select the THD calculation: FUND or RMS.
7. Press OK.
ꢈꢉ
ꢙꢍ
ꢜ
8. At the SETUP MODE screen, continue
programming additional setup features or
press1;until you are asked to save changes.
9. Press YES to save the changes.
VAR/PF Convention Setup
1. Perform steps 1 through 5 of the SETUP MODE
Access procedure on page 11.
ꢀꢮꢆꢔꢥꢕꢹꢡꢕꢵꢶꢥꢕ
2. Press ###:until ADVAN (advanced setup) is
visible.
3. Press ADVAN.
ꢶꢡꢡꢡ
4. Press ###:until PF is visible.
5. Press PF.
6. Select the Var/PF convention: IEEE or IEC.
7. Press OK.
ꢈꢉ
ꢙꢍ
ꢜ
8. At the SETUP MODE screen, continue
programming additional setup features or
press1;until you are asked to save changes.
9. Press YES to save the changes.
20
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PowerLogicTM Series 800 Power Meter
Chapter 3—Operation
Lock Resets Setup
1. Perform steps 1 through 5 of the SETUP MODE
Access procedure on page 11.
ꢷꢥꢢꢺꢆꢇꢡꢻꢡꢵꢻꢼ
2. Press ###:until ADVAN (advanced setup) is
visible.
ꢕ
ꢟ
ꢀꢞꢌꢋꢅꢋ
ꢄꢕꢄꢇꢩ
3. Press ADVAN.
4. Press ###:until LOCK is visible.
5. Press LOCK.
ꢕ
ꢕ
ꢅꢽꢠꢾꢿ
ꢘ
6. Select Y (yes) or N (no) to enable or disable
resets for PK.DMD, ENERG, MN/MX, and
METER.
ꢅꢡꢵꢡꢧ
ꢝꢞ
ꢈꢉ
ꢙꢍꢍ
ꢜ
7. Press OK.
8. At the SETUP MODE screen, continue
programming additional setup features or
press1;until you are asked to save changes.
9. Press YES to save the changes.
Alarm Backlight Setup
1. Perform steps 1 through 5 of the SETUP MODE
Access procedure on page 11.
ꢂꢨꢂꢇꢅꢆꢓꢂꢔꢞꢨꢊꢩꢁꢚꢼ
2. Press ###:until ADVAN (advanced setup) is
visible.
3. Press ADVAN.
ꢝꢕ
4. Press ###:until BLINK is visible.
5. Press BLINK.
6. Enter ON or OFF.
7. Press OK.
ꢈꢉ
ꢙꢍ
ꢜ
ꢝꢞ
8. At the SETUP MODE screen, continue
programming additional setup features or
press1;until you are asked to save changes.
9. Press YES to save the changes.
Bar Graph Setup
1. Perform steps 1 through 5 of the SETUP MODE
Access procedure on page 11.
ꢓꢫꢧꢆꣀꢧꢫꣁꢁꢆꢻꢢꢫꢷꢡ
2. Press ###:until ADVAN (advanced setup) is
visible.
3. Press ADVAN.
4. Press ###:until BARGR is visible.
5. Press BARGR.
6. Press AMPS or PWR.
7. Select AUTO or MAN. If MAN is selected, press
OK and enter the %CT*PT and KW (for PWR)
or the %CT and A (for AMPS).
ꢈꢉ
ꢂꢅꢀꢃ
ꢀꢴꢇ
8. Press OK.
9. At the SETUP MODE screen, continue
programming additional setup features or
press1;until you are asked to save changes.
10. Press YES to save the changes.
21
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PowerLogicTM Series 800 Power Meter
Chapter 3—Operation
63230-500-225A2
3/2011
PQ Advanced Evaluation Setup
1. Perform steps 1 through 5 of the SETUP MODE
Access procedure on page 11.
ꢀꢲꢆꢂꢋꢹꢫꢕꢆꢃꢄꢚꢛꢀ
2. Press ###:until ADVAN (advanced setup) is
visible.
ꢝꢕ
3. Press ADVAN.
4. Press ###:until PQADV is visible.
5. Press PQADV.
ꢕꢝꢅꢆꢬ
ꢀꢁꢆ
6. Select ON.
7. Press OK.
ꢈꢉ
ꢙꢍꢍꢍꢍ
ꢜ
ꢝꢞ
8. Change the nominal voltage (NOM V) value if
desired (the default is 230).
9. Press OK to return to the SETUP MODE
screen.
10. At the SETUP MODE screen, continue
programming additional setup features or
press1;until you are asked to save changes.
11. Press YES to save your changes and reset the
power meter.
Power Demand Configuration Setup
1. Perform steps 1 through 5 of the SETUP MODE
Access procedure on page 11.
ꢀꢥꣂꢡꢧꢆꢋꢅꢋꢆꢔꢝꢕꢮꢊꢩ
ꢀ
2. Press ###:until ADVAN (advanced setup) is
visible.
ꢇꢔꢨꢔꢞ
ꢊꢕꢚꢬꢨ
ꢃꢛꢓꢍꢊ
3. Press ADVAN.
ꢉꢂ
ꢉ
4. Press ###:until DMD is visible.
5. Press DMD (P-DMD, I-DMD).
6. Select the demand configuration. Choices are
COMMS, RCOMM, CLOCK, RCLCK, IENGY,
THERM, SLIDE, BLOCK, RBLCK, INPUT, and
RINPUT.
ꢈꢉ
ꢙꢍ
ꢜ
ꢝꢞ
7. Press OK.
8. Enter the INTVL (interval) and press OK.
9. Enter the SUB-I (sub-interval) and press OK.
10. At the SETUP MODE screen, continue
programming additional setup features or
press1;until you are asked to save changes.
11. Press YES to save the changes.
22
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PowerLogicTM Series 800 Power Meter
Chapter 3—Operation
Power Meter Resets
The Power Meter Resets Feature set contains several items. After resetting a feature, you
may continue through the remaining features by returning to the RESET MODE screen and
pressing ###:to scroll to additional features. Once you have reset the specific features,
press 1;until the display returns to the main screen.
Initialize the Power Meter
Initializing the power meter resets the energy
readings, minimum/maximum values, and
operating times. To initialize the power meter,
follow these steps:
ꢊꢕꢊꢚꢌꢆꢅꢄꢚꢄꢇꢆꢼ
1. Press ###:to scroll through the Level 1 menu
until you see MAINT.
2. Press MAINT.
3. Press RESET.
4. Press ###:until METER is visible.
5. Press METER.
ꢕꢝ
ꢟꢄꢃ
6. Enter the password (the default is 0000).
7. Press YES to initialize the power meter and to
return to the RESET MODE screen.
8. At the RESET MODE screen, continue
resetting additional features or press1;until
you return to the main screen.
NOTE: We recommend initializing the power meter
after you make changes to any of the following:
CTs, PTs, frequency, or system type.
Accumulated Energy Readings Reset
1. Press ###:to scroll through the Level 1 menu
until you see MAINT.
ꢇꢄꢃꢄꢚꢆꢄꢕꢄꢇꢩꢟꢆꢼ
2. Press MAINT.
3. Press RESET.
ꢂꢁꢃꢅꢉꢀ
ꢀꢂꢊꢅꢊꢆ
ꢋꢀꢃꢅꢄꢄ
ꢺꢴꣃ
4. Press ###:until ENERG is visible.
5. Press ENERG.
ꢺꢬꢂꢇꣃ
ꢺꢬꢂꣃ
6. Enter the password (the default is 0000).
7. Press YES to reset the accumulated energy
readings and to return to the RESET MODE
screen.
ꢆꢄꢇꢉꢆꢇꢆꢄ
ꢈꢖꢌꢗꢖꢂ
ꢟꢄꢃ
ꢕꢝ
23
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PowerLogicTM Series 800 Power Meter
Chapter 3—Operation
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3/2011
Accumulated Demand Readings Reset
1. Press ###:to scroll through the Level 1 menu
until you see MAINT.
ꢇꢄꢃꢄꢚꢆꢋꢄꢅꢂꢕꢋꢆꢼ
2. Press MAINT.
3. Press RESET.
ꢈ
ꢁ
ꢀꢺ
ꢀꢺ
ꢀꢺ
ꢺꢴ꣄
4. Press ###:until DMD is visible.
5. Press DMD.
ꢺꢬꢂꢇ꣄
ꢂꢅꢀꢆꢋ
6. Enter the password (the default is 0000).
ꢃꢀ
ꢆꢈꢇꢉꢆꢇꢆꢄ
7. Press YES to reset the accumulated demand
readings and to return to the RESET MODE
screen.
ꢈꢖꢌꢗꢖ
ꢟꢄꢃ
ꢕꢝ
Minimum/Maximum Values Reset
1. Press ###:to scroll through the Level 1 menu
until you see MAINT.
ꢇꢄꢃꢄꢚꢆꢅꢊꢕꢠꢅꢂꢭꢆꢼ
2. Press MAINT.
3. Press RESET.
4. Press ###:until MINMX is visible.
5. Press MINMX.
6. Enter the password (the default is 0000).
7. Press YES to reset the minimum/maximum
values and to return to the RESET MODE
screen.
ꢆꢈꢇꢉꢆꢇꢆꢄ
ꢈꢖꢌꢗꢖꢂ
ꢟꢄꢃ
ꢕꢝ
Display Mode Change
1. Press ###:to scroll through the Level 1 menu
until you see MAINT.
ꢇꢄꢃꢄꢚꢆꢋꢄꢮꢂꢛꢨꢚꢆꢼ
2. Press MAINT.
3. Press RESET.
4. Press ###:until MODE is visible.
5. Press MODE.
6. Press IEEE (default for Square D branded
power meters) or IEC (default for Schneider
Electric branded power meters) depending on
the operating mode you want to use.
ꢲꢛꢊꢚ
ꢊꢄꢄꢄ
ꢊꢄꢔ
NOTE: Resetting the mode changes the menu
labels, power factor conventions, and THD
calculations to match the standard mode selected.
To customize the mode changes, see the register
list.
24
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PowerLogicTM Series 800 Power Meter
Chapter 3—Operation
Accumulated Operating Time Reset
1. Press ###:to scroll through the Level 1 menu
until you see MAINT.
ꢇꢄꢃꢄꢚꢆꢝꢀꢄꢇꢆꢚꢊꢅꢄꢆꢼ
2. Press MAINT.
3. Press RESET.
ꢉꢀꢆ
ꢉꢉ
ꢋꢂꢟꢃ
4. Press ###:until TIMER is visible.
5. Press TIMER.
ꢁꢝꢛꢇꢃ
6. Enter the password (the default is 0000).
ꢃꢀ
ꢅꢊꢕꢃ
7. Press YES to reset the accumulated operating
time and to return to the RESET MODE screen.
ꢕꢝ
ꢟꢄꢃ
NOTE: The accumulated days, hours, and
minutes of operation are reset to zero when you
press YES.
Power Meter Diagnostics
To view the power meter’s model, firmware version, serial number, read and write registers,
or check the health status, you must access the HEALTH STATUS screen.
After viewing a feature, you may continue through the remaining features by returning to
the HEALTH STATUS screen and selecting one of the other options.
Once you have viewed the specific features, press 1;until the display returns to the main
screen.
HEALTH STATUS screen
ꢁꢄꢂꢨꢚꢁꢆꢃꢚꢂꢚꢛꢃ
NOTE: The wrench icon and the health status code
display when a health problem is detected. For
code 1, set up the Date/Time (see “DATE Setup”
codes, contact technical support.
ꢝꢞ
ꢈꢉ
ꢅꢄꢚꢄꢇ
ꢇꢄꢩꢌ
ꢔꢨꢝꢔꢞ
25
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PowerLogicTM Series 800 Power Meter
Chapter 3—Operation
63230-500-225A2
3/2011
View the Meter Information
1. Press ###:to scroll through the Level 1 menu
until you see MAINT.
ꢅꢄꢚꢄꢇꢆꢊꢕꢮꢝ
2. Press MAINT.
3. Press DIAG (diagnostics) to open the HEALTH
STATUS screen.
ꢈꢂꢆ
ꢉꢀꢅꢉꢆꢆ
ꢉꢆꢅꢋꢆꢆ
ꢀꢂꢆꢆꢆꢉꢊꢁ
ꢀꢆꢅ
ꢆꢆꢬ
ꢅꢝꢋꢄꢨ
ꢖꢌꢗꢌ
4. On the HEALTH STATUS screen, press
METER (meter information).
ꢆꢆꢬ
ꢈꢉ
ꢇꢄꢃꢄꢚ
ꢃꢌꢕꢌ
5. View the meter information.
6. Press ###:to view more meter information.
ꢙꢍ
ꢍꣅ
7. Press 1;to return to the HEALTH STATUS
screen.
NOTE: The wrench icon and the health status code
display when a health problem is detected. For
code 1, set up the Date/Time (see “DATE Setup”
codes, contact technical support.
Read and Write Registers
1. Press ###:to scroll through the Level 1 menu
until you see MAINT.
ꢇꢠꢴꢆꢇꢄꢩꢊꢃꢚꢄꢇ
ꢉꢆꢆꢆ
ꢆꢆꢆꢆꢆ
ꢆ
2. Press MAINT.
3. Press DIAG (diagnostics) to open the HEALTH
STATUS screen.
ꢇꢄꢩꢌ
ꢁꢄꢭ
ꢋꢄꢔ
4. On the HEALTH STATUS screen, Press REG
(register).
5. Enter the password (the default is 0000).
6. Enter the REG. (register) number that contains
the data you want to monitor.
ꢝꢞ
ꢈꢉ
ꢙꢍ
ꢜ
The register content will be displayed in both
HEX (hexadecimal) and DEC (decimal) values.
7. Press 1;to return to the HEALTH STATUS
screen.
NOTE: For more information about using registers,
View the Meter Date and TIme
1. Press ###:to scroll through the Level 1 menu
until you see MAINT.
ꢀꢅꢆꢋꢂꢚꢄꢍꢚꢊꢅꢄ
ꢉꢉ
ꢃꢀ
ꢋ
ꢆꢀꢇꢀꢈꢇꢆꢄ
2. Press MAINT.
3. Press DIAG (diagnostics) to open the HEALTH
STATUS screen.
ꢀꢆꢅ
ꢆꢆꢬ
ꢁꢝꢛꢇ
ꢅꢊꢕ
4. On the HEALTH STATUS screen, press
CLOCK (current date and time).
ꢆꢆꢬ
ꢈꢉ
ꢃꢄꢔ
5. View the date and time.
ꢚꢛꢄꢃ
6. Press 1;to return to the HEALTH STATUS
screen.
ꢙꢍ
ꢍꣅ
26
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PowerLogicTM Series 800 Power Meter
Chapter 4—Metering Capabilities
Chapter 4—Metering Capabilities
Real-Time Readings
The power meter measures currents and voltages, and reports in real time the rms values
for all three phases and neutral. In addition, the power meter calculates power factor, real
power, reactive power, and more.
Table 4–1 lists some of the real-time readings that are updated every second along with
their reportable ranges.
Table 4–1: One-second, Real-time Readings
Real-time Readings
Current
Reportable Range
Per-Phase
0 to 32,767 A
0 to 32,767 A
0 to 32,767 A
0 to 100.0%
Neutral
3-Phase Average
% Unbalance
Voltage
Line-to-Line, Per-Phase
Line-to-Line, 3-Phase Average
Line-to-Neutral, Per-Phase
Line-to-Neutral, 3-Phase Average
% Unbalance
0 to 1,200 kV
0 to 1,200 kV
0 to 1,200 kV
0 to 1,200 kV
0 to 100.0%
Real Power
Per-Phase
0 to ± 3,276.70 MW
0 to ± 3,276.70 MW
3-Phase Total
Reactive Power
Per-Phase
0 to ± 3,276.70 MVAR
0 to ± 3,276.70 MVAR
3-Phase Total
Apparent Power
Per-Phase
0 to ± 3,276.70 MVA
0 to ± 3,276.70 MVA
3-Phase Total
Power Factor (True)
Per-Phase
–0.002 to 1.000 to +0.002
–0.002 to 1.000 to +0.002
3-Phase Total
Power Factor (Displacement)
Per-Phase
–0.002 to 1.000 to +0.002
–0.002 to 1.000 to +0.002
3-Phase Total
Frequency
45–65 Hz
23.00 to 67.00 Hz
350–450 Hz
350.00 to 450.00 Hz
27
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PowerLogicTM Series 800 Power Meter
Chapter 4—Metering Capabilities
63230-500-225A2
3/2011
Min/Max Values for Real-time Readings
When certain one-second real-time readings reach their highest or lowest value, the power
meter saves the values in its non-volatile memory. These values are called the minimum
and maximum (min/max) values.
The power meter stores the min/max values for the current month and previous month.
After the end of each month, the power meter moves the current month’s min/max values
into the previous month’s register space and resets the current month’s min/max values.
The current month’s min/max values can be reset manually at any time using the power
meter display or PowerLogic software. After the min/max values are reset, the power meter
records the date and time. The real-time readings evaluated are:
•
•
•
•
•
•
•
Min/Max Voltage L-L
Min/Max Voltage L-N
Min/Max Current
Min/Max Voltage L-L, Unbalance
Min/Max Voltage L-N, Unbalance
Min/Max Total True Power Factor
Min/Max Total Displacement Power
Factor
•
•
•
•
•
•
•
Min/Max Reactive Power Total
Min/Max Apparent Power Total
Min/Max THD/thd Voltage L-L
Min/Max THD/thd Voltage L-N
Min/Max THD/thd Current
Min/Max Frequency
Min/Max Voltage N-ground
(see the note below)
•
Min/Max Real Power Total
•
Min/Max Current, Neutral
(see the note below)
NOTE: Min/Max values for Vng and In are not available from the display. Use the display to
For each min/max value listed above, the power meter records the following attributes:
•
•
•
Date/Time of minimum value
Minimum value
Phase of recorded minimum value
•
•
•
Date/Time of maximum value
Maximum value
Phase of recorded maximum value
NOTE: Phase of recorded min/max only applies to multi-phase quantities.
NOTE: There are two ways to view the min/max values. 1- Use the power meter display to
view the min/max values since the meter was last reset. 2- Use PowerLogic software to
view a table with the instantaneous min/max values for the current and previous months.
Power Factor Min/Max Conventions
All running min/max values, except for power factor, are arithmetic minimum and maximum
values. For example, the minimum phase A-B voltage is the lowest value in the range 0 to
1200 kV that has occurred since the min/max values were last reset. In contrast, because
the power factor’s midpoint is unity (equal to one), the power factor min/max values are not
true arithmetic minimums and maximums. Instead, the minimum value represents the
measurement closest to -0 on a continuous scale for all real-time readings -0 to 1.00 to +0.
The maximum value is the measurement closest to +0 on the same scale.
Figure 4–1 shows the min/max values in a typical environment in which a positive power
flow is assumed. In the figure, the minimum power factor is -0.7 (lagging) and the maximum
is 0.8 (leading). Note that the minimum power factor need not be lagging, and the maximum
power factor need not be leading. For example, if the power factor values ranged from
-0.75 to -0.95, then the minimum power factor would be -0.75 (lagging) and the maximum
power factor would be -0.95 (lagging). Both would be negative. Likewise, if the power factor
ranged from +0.9 to +0.95, the minimum would be +0.95 (leading) and the maximum would
be +0.90 (leading). Both would be positive in this case.
28
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PowerLogicTM Series 800 Power Meter
Chapter 4—Metering Capabilities
Figure 4–1: Power factor min/max example
Minimum
Power Factor
-.7 (lagging)
Maximum
Power Factor
.8 (leading)
Range of Power
Factor Value
Unity
1.00
.8
.8
.6
.6
Lead
(+)
Lag
(–)
.4
.4
.2
.2
-0
+0
NOTE: Assumes a positive power flow
An alternate power factor storage method is also available for use with analog outputs and
Power Factor Sign Conventions
The power meter can be set to one of two power factor sign conventions: IEEE or IEC. The
Series 800 Power Meter defaults to the IEEE power factor sign convention. Figure 4–2
illustrates the two sign conventions. For instructions on changing the power factor sign
Figure 4–2: Power factor sign convention
Reactive
Power In
Reactive
Power In
Quadrant
2
Quadrant
1
Quadrant
2
Quadrant
1
watts negative (–)
vars positive (+)
power factor (–)
watts positive (+)
vars positive (+)
power factor (+)
watts negative (–)
vars positive (+)
power factor (+)
watts positive (+)
vars positive (+)
power factor (–)
Reverse
Power Flow
Normal
Power Flow
Reverse
Power Flow
Normal
Power Flow
Real
Power
In
Real
Power
In
watts negative (–)
vars negative (–)
power factor (–)
watts positive (+)
vars negative (–)
power factor (+)
watts negative (–)
vars negative (–)
power factor (–)
watts positive (+)
vars negative (–)
power factor (+)
Quadrant
3
Quadrant
4
Quadrant
3
Quadrant
4
IEC Power Factor Sign Convention
IEEE Power Factor Sign Convention
Figure 4–3: Power Factor Display Example
ꢆꢆꢆꢁ
ꢚꢧꢦꢡꢆꢀꢮ
The power
ꢆꢅꢋꢂꢋ
ꢆꢅꢋꢆꢃ
ꢆꢅꢋꢃꢃ
ꢂ
ꢓ
ꢔ
factor sign is
visible next to
the power
factor reading.
ꢆꢅꢋꢁꢄ
ꢚꢝꢚꢂꢨ
ꢈꢉ
ꢚꢇꢛꢄ
ꢋꢀꢃꢀꢨ
29
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Demand Readings
The power meter provides a variety of demand readings, including coincident readings and
ranges.
Table 4–2: Demand Readings
Demand Readings
Reportable Range
Demand Current, Per-Phase, 3Ø Average, Neutral
Last Complete Interval
Peak
0 to 32,767 A
0 to 32,767 A
Average Power Factor (True), 3Ø Total
Last Complete Interval
Coincident with kW Peak
Coincident with kVAR Peak
Coincident with kVA Peak
Demand Real Power, 3Ø Total
Last Complete Interval
Predicted
–0.002 to 1.000 to +0.002
–0.002 to 1.000 to +0.002
–0.002 to 1.000 to +0.002
–0.002 to 1.000 to +0.002
0 to ± 3276.70 MW
0 to ± 3276.70 MW
0 to ± 3276.70 MW
0 to ± 3276.70 MVA
0 to ± 3276.70 MVAR
Peak
Coincident kVA Demand
Coincident kVAR Demand
Demand Reactive Power, 3Ø Total
Last Complete Interval
Predicted
0 to ± 3276.70 MVAR
0 to ± 3276.70 MVAR
0 to ± 3276.70 MVAR
0 to ± 3276.70 MVA
0 to ± 3276.70 MW
Peak
Coincident kVA Demand
Coincident kW Demand
Demand Apparent Power, 3Ø Total
Last Complete Interval
Predicted
0 to ± 3276.70 MVA
0 to ± 3276.70 MVA
0 to ± 3276.70 MVA
0 to ± 3276.70 MW
0 to ± 3276.70 MVAR
Peak
Coincident kW Demand
Coincident kVAR Demand
Demand Power Calculation Methods
Demand power is the energy accumulated during a specified period divided by the length of
that period. How the power meter performs this calculation depends on the method you
select. To be compatible with electric utility billing practices, the power meter provides the
following types of demand power calculations:
•
•
•
Block Interval Demand
Synchronized Demand
Thermal Demand
The default demand calculation is set to sliding block with a 15 minute interval. You can set
up any of the demand power calculation methods using PowerLogic software.
30
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Chapter 4—Metering Capabilities
Block Interval Demand
In the block interval demand method, you select a “block” of time that the power meter uses
for the demand calculation. You choose how the power meter handles that block of time
(interval). Three different modes are possible:
•
Sliding Block. In the sliding block interval, you select an interval from 1 to 60 minutes
(in 1-minute increments). If the interval is between 1 and 15 minutes, the demand
calculation updates every 15 seconds. If the interval is between 16 and 60 minutes, the
demand calculation updates every 60 seconds. The power meter displays the demand
value for the last completed interval.
•
•
Fixed Block. In the fixed block interval, you select an interval from 1 to 60 minutes (in
1-minute increments). The power meter calculates and updates the demand at the end
of each interval.
Rolling Block. In the rolling block interval, you select an interval and a sub-interval.
The sub-interval must divide evenly into the interval. For example, you might set three
5-minute sub-intervals for a 15-minute interval. Demand is updated at each sub-
interval. The power meter displays the demand value for the last completed interval.
Figure 4–4 below illustrates the three ways to calculate demand power using the block
method. For illustration purposes, the interval is set to 15 minutes.
Figure 4–4: Block Interval Demand Examples
Demand value is the
average for the last
completed interval
Calculation updates
every 15 or 60
seconds
15-minute interval
Time
(sec)
15 30 45 60 . . .
Sliding Block
Demand value is
the average for
the last
completed
interval
Calculation updates at
the end of the interval
15-minute interval
15-minute interval
15-min
Time
(min)
15
30
45
Fixed Block
Demand value is
the average for
the last
Calculation updates at the end of
the sub-interval (5 minutes)
completed
interval
15-minute interval
Time
(min)
20
25
35
40
30
45
15
Rolling Block
31
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Synchronized Demand
The demand calculations can be synchronized by accepting an external pulse input, a
command sent over communications, or by synchronizing to the internal real-time clock.
•
Input Synchronized Demand. You can set up the power meter to accept an input such
as a demand synch pulse from an external source. The power meter then uses the
same time interval as the other meter for each demand calculation. You can use the
standard digital input installed on the meter to receive the synch pulse. When setting up
this type of demand, you select whether it will be input-synchronized block or input-
synchronized rolling block demand. The rolling block demand requires that you choose
a sub-interval.
•
Command Synchronized Demand. Using command synchronized demand, you can
synchronize the demand intervals of multiple meters on a communications network. For
example, if a PLC input is monitoring a pulse at the end of a demand interval on a utility
revenue meter, you could program the PLC to issue a command to multiple meters
whenever the utility meter starts a new demand interval. Each time the command is
issued, the demand readings of each meter are calculated for the same interval. When
setting up this type of demand, you select whether it will be command-synchronized
block or command-synchronized rolling block demand. The rolling block demand
requires that you choose a sub-interval. See Appendix C—Using the Command
•
Clock Synchronized Demand (Requires PM810LOG). You can synchronize the
demand interval to the internal real-time clock in the power meter. This enables you to
synchronize the demand to a particular time, typically on the hour. The default time is
12:00 am. If you select another time of day when the demand intervals are to be
synchronized, the time must be in minutes from midnight. For example, to synchronize
at 8:00 am, select 480 minutes. When setting up this type of demand, you select
whether it will be clock-synchronized block or clock-synchronized rolling block demand.
The rolling block demand requires that you choose a sub-interval.
Thermal Demand
The thermal demand method calculates the demand based on a thermal response, which
mimics thermal demand meters. The demand calculation updates at the end of each
interval. You select the demand interval from 1 to 60 minutes (in 1-minute increments). In
Figure 4–5 the interval is set to 15 minutes for illustration purposes.
Figure 4–5: Thermal Demand Example
The interval is a window of time that moves across the timeline.
99%
90%
Last completed
demand interval
0%
Time
(minutes)
15-minute
interval
next
15-minute
interval
Calculation updates at the end of each interval
Demand Current
The power meter calculates demand current using the thermal demand method. The
default interval is 15 minutes, but you can set the demand current interval between 1 and
60 minutes in 1-minute increments.
32
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Predicted Demand
The power meter calculates predicted demand for the end of the present interval for kW,
kVAR, and kVA demand. This prediction takes into account the energy consumption thus
far within the present (partial) interval and the present rate of consumption. The prediction
is updated every second.
Figure 4–6 illustrates how a change in load can affect predicted demand for the interval.
Figure 4–6: Predicted Demand Example
Predicted demand is updated every second.
Beginning
of interval
15-minute interval
Demand
for last
completed
interval
Predicted demand if load is
added during interval;
predicted demand increases
to reflect increase demand
Partial Interval
Demand
Predicted demand if no load
is added.
Time
1:00
1:06
1:15
Change in Load
Peak Demand
In non-volatile memory, the power meter maintains a running maximum for the kWD,
kVARD, and kVAD power values, called “peak demand.” The peak for each value is the
highest average reading since the meter was last reset. The power meter also stores the
date and time when the peak demand occurred. In addition to the peak demand, the power
meter also stores the coinciding average 3-phase power factor. The average 3-phase
power factor is defined as “demand kW/demand kVA” for the peak demand interval.
Table 4–2 on page 30 lists the available peak demand readings from the power meter.
You can reset peak demand values from the power meter display. From the Main Menu,
select MAINT > RESET > DMD. You can also reset the values over the communications
link by using software.
NOTE: You should reset peak demand after changes to basic meter setup, such as CT
ratio or system type.
The power meter also stores the peak demand during the last incremental energy interval.
See “Energy Readings” on page 35 for more about incremental energy readings.
Generic Demand
The power meter can perform any of the demand calculation methods, described earlier in
this chapter, on up to 10 quantities that you choose using PowerLogic software. For generic
demand, do the following:
•
•
Select the demand calculation method (thermal, block interval, or synchronized).
Select the demand interval (from 5–60 minutes in 1–minute increments) and select
the demand sub-interval (if applicable).
•
Select the quantities on which to perform the demand calculation. You must also
select the units and scale factor for each quantity.
For each quantity in the demand profile, the power meter stores four values:
•
•
•
•
Partial interval demand value
Last completed demand interval value
Minimum values (date and time for each is also stored)
Peak demand value (date and time for each is also stored)
33
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You can reset the minimum and peak values of the quantities in a generic demand profile
by using one of two methods:
•
•
Use PowerLogic software, or
Use the command interface.
Command 5115 resets the generic demand profile. See Appendix C—Using the
Input Metering Demand
The power meter has five input pulse metering channels, but only one digital input. Digital
inputs can be added by installing one or more option modules (PM8M22, PM8M26, or
PM8M2222). The input pulse metering channels count pulses received from one or more
digital inputs assigned to that channel. Each channel requires a consumption pulse weight,
consumption scale factor, demand pulse weight, and demand scale factor. The
consumption pulse weight is the number of watt-hours or kilowatt-hours per pulse. The
consumption scale factor is a factor of 10 multiplier that determines the format of the value.
For example, if each incoming pulse represents 125 Wh, and you want consumption data in
watt-hours, the consumption pulse weight is 125 and the consumption scale factor is zero.
0
The resulting calculation is 125 x 10 , which equals 125 watt-hours per pulse. If you want
-3
the consumption data in kilowatt-hours, the calculation is 125 x 10 , which equals 0.125
kilowatt-hours per pulse.Time must be taken into account for demand data; so you begin by
calculating demand pulse weight using the following formula:
watt-hours 3600 seconds
pulse
second
--------------------------- ------------------------------------ ------------------
watts =
pulse
hour
If each incoming pulse represents 125 Wh, using the formula above you get 450,000 watts.
If you want demand data in watts, the demand pulse weight is 450 and the demand scale
3
factor is three. The calculation is 450 x 10 , which equals 450,000 watts. If you want the
0
demand data in kilowatts, the calculation is 450 x 10 , which equals 450 kilowatts.
NOTE: The power meter counts each input transition as a pulse. Therefore, an input
transition of OFF-to-ON and ON-to-OFF will be counted as two pulses. For each channel,
the power meter maintains the following information:
•
•
•
•
Total consumption
Last completed interval demand—calculated demand for the last completed interval.
Partial interval demand—demand calculation up to the present point during the interval.
Peak demand—highest demand value since the last reset of the input pulse demand.
The date and time of the peak demand is also saved.
•
Minimum demand—lowest demand value since the last reset of the input pulse
demand. The date and time of the minimum demand is also saved.
To use the channels feature, first use the display to set up the digital inputs (see “I/O
(Input/Output) Setup” on page 18). Then using PowerLogic software, you must set the I/O
operating mode to Normal and set up the channels. The demand method and interval that
you select applies to all channels.
34
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Chapter 4—Metering Capabilities
Energy Readings
The power meter calculates and stores accumulated energy values for real and reactive
energy (kWh and kVARh) both into and out of the load, and also accumulates absolute
Table 4–3: Energy Readings
Energy Reading, 3-Phase
Reportable Range
Shown on the Display
Accumulated Energy
Real (Signed/Absolute)
-9,999,999,999,999,999 to
9,999,999,999,999,999 Wh
Reactive (Signed/Absolute)
-9,999,999,999,999,999 to
9,999,999,999,999,999 VARh
0000.000 kWh to 99,999.99 MWh
and
Real (In)
0 to 9,999,999,999,999,999 Wh
0 to 9,999,999,999,999,999 Wh
0 to 9,999,999,999,999,999 VARh
0 to 9,999,999,999,999,999 VARh
0 to 9,999,999,999,999,999 VAh
Real (Out)
0000.000 to 99,999.99 MVARh
Reactive (In)
Reactive (Out)
Apparent
Accumulated Energy, Conditional
Real (In)
0 to 9,999,999,999,999,999 Wh
0 to 9,999,999,999,999,999 Wh
0 to 9,999,999,999,999,999 VARh
0 to 9,999,999,999,999,999 VARh
0 to 9,999,999,999,999,999 VAh
These values not shown on the
display. Readings are obtained
only through the communications
link.
Real (Out)
Reactive (In)
Reactive (Out)
Apparent
Accumulated Energy, Incremental
Real (In)
0 to 999,999,999,999 Wh
0 to 999,999,999,999 Wh
0 to 999,999,999,999 VARh
0 to 999,999,999,999 VARh
0 to 999,999,999,999 VAh
These values not shown on the
display. Readings are obtained
only through the communications
link.
Real (Out)
Reactive (In)
Reactive (Out)
Apparent
Reactive Energy
Quadrant 1
0 to 999,999,999,999 VARh
0 to 999,999,999,999 VARh
0 to 999,999,999,999 VARh
0 to 999,999,999,999 VARh
These values not shown on the
display. Readings are obtained
only through the communications
link.
Quadrant 2
Quadrant 3
Quadrant 4
➀ Not shown on the power meter display.
modes: signed or unsigned (absolute). In signed mode, the power meter considers the
direction of power flow, allowing the magnitude of accumulated energy to increase and
decrease. In unsigned mode, the power meter accumulates energy as a positive value,
regardless of the direction of power flow. In other words, the energy value increases, even
during reverse power flow. The default accumulation mode is unsigned.
You can view accumulated energy from the display. The resolution of the energy value will
automatically change through the range of 000.000 kWh to 000,000 MWh (000.000 kVAh
to 000,000 MVARh), or it can be fixed. See Appendix C—Using the Command Interface
on page 83 for the contents of the registers.
For conditional accumulated energy readings, you can set the real, reactive, and apparent
energy accumulation to OFF or ON when a particular condition occurs. You can do this over
the communications link using a command, or from a digital input change. For example,
you may want to track accumulated energy values during a particular process that is
controlled by a PLC. The power meter stores the date and time of the last reset of
conditional energy in non-volatile memory.
35
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The power meter also provides an additional energy reading that is only available over the
communications link:
•
Four-quadrant reactive accumulated energy readings. The power meter
registers operate in unsigned (absolute) mode in which the power meter accumulates
energy as positive.
Figure 4–7: Reactive energy accumulates in four quadrants
Reactive
Power In
Quadrant
2
Quadrant
1
watts negative (–)
vars positive (+)
watts positive (+)
vars positive (+)
Reverse
Normal
Power Flow
Real
Power
In
Power Flow
watts negative (–)
vars negative (–)
watts positive (+)
vars negative (–)
Quadrant
3
Quadrant
4
Energy-Per-Shift (PM810 with PM810LOG)
The energy-per-shift feature allows the power meter to group energy usage based on three
groups: 1st shift, 2nd shift, and 3rd shift. These groups provide a quick, historical view of
energy usage and energy cost during each shift. All data is stored in non-volatile memory.
Table 4–4: Energy-per-shift recorded values
Category
Recorded Values
•
•
•
•
•
•
Today
Yesterday
This Week
Last Week
This Month
Last Month
Time Scales
•
•
Real
Apparent
Energy
•
•
•
•
•
•
Today
Yesterday
This Week
Last Week
This Month
Last Month
Energy Cost
•
•
•
Meter Reading Date
Meter Reading Time of Day
1st Day of the Week
User Configuration
Configuration
The start time of each shift is configured by setting registers using the display or by using
PowerLogic software. Table 4-5 summarizes the quantities needed to configure energy-
per-shift using register numbers.
36
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Chapter 4—Metering Capabilities
Table 4–5: Energy-per-shift recorded values
Quantity
Register Number(s)
Description
For each shift, enter the minutes from
midnight at which the shift starts.
•
•
•
1st shift: 16171
2nd shift: 16172
3rd shift: 16173
Defaults:
Shift Start Time
1st shift = 420 minutes (7:00 am)
2nd shift = 900 minutes (3:00 pm)
3rd shift = 1380 minutes (11:00 pm)
•
•
•
1st shift: 16174
2nd shift: 16175
3rd shift: 16176
Cost per kWHr
Enter the cost per kWHr for each shift.
The scale factor multiplied by the
monetary units to determine the
energy cost.
Monetary Scale Factor
16177
Values: -3 to 3
Default: 0
Power Analysis Values
The power meter provides a number of power analysis values that can be used to detect
power quality problems, diagnose wiring problems, and more. Table 4–6 on page 38
summarizes the power analysis values.
•
THD. Total Harmonic Distortion (THD) is a quick measure of the total distortion present
in a waveform and is the ratio of harmonic content to the fundamental. It provides a
general indication of the “quality” of a waveform. THD is calculated for both voltage and
current. The power meter uses the following equation to calculate THD, where H is the
harmonic distortion:
2
2
2
3
2
H
4
+
+
+
H
H
x
THD =
100%
H
1
•
thd. An alternate method for calculating Total Harmonic Distortion, used widely in
Europe. It considers the total harmonic current and the total rms content rather than
fundamental content in the calculation. The power meter calculates thd for both voltage
and current. The power meter uses the following equation to calculate THD, where H is
the harmonic distortion:
2
2
2
+
+
+
H
H
H
2
3
4
x
100%
thd =
Total rms
•
•
Displacement Power Factor. Power factor (PF) represents the degree to which
voltage and current coming into a load are out of phase. Displacement power factor is
based on the angle between the fundamental components of current and voltage.
Harmonic Values. Harmonics can reduce the capacity of the power system. The power
meter determines the individual per-phase harmonic magnitudes and angles for all
currents and voltages through the:
— 31st harmonic (PM810 with PM810Log, and PM820) or
— 63rd harmonic (PM850, PM870)
The harmonic magnitudes can be formatted as either a percentage of the fundamental
(default), a percentage of the rms value, or the actual rms value. Refer to “Operation
with PQ Advanced Enabled” on page 99 for information on how to configure harmonic
calculations.
37
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Table 4–6: Power Analysis Values
Value
Reportable Range
THD—Voltage, Current
3-phase, per-phase, neutral
thd—Voltage, Current
0 to 3,276.7%
3-phase, per-phase, neutral
Fundamental Voltages (per phase)
Magnitude
0 to 3,276.7%
0 to 1,200 kV
0.0 to 359.9°
Angle
Fundamental Currents (per phase)
Magnitude
0 to 32,767 A
0.0 to 359.9°
Angle
Miscellaneous
Displacement P.F. (per phase, 3-phase)
Phase Rotation
–0.002 to 1.000 to +0.002
ABC or CBA
Unbalance (current and voltage) ➀
Individual Current and Voltage Harmonic Magnitudes ➁
Individual Current and Voltage Harmonic Angles ➁
➀ Readings are obtained only through communications.
0.0 to 100.0%
0 to 327.67%
0.0° to 359.9°
➁ Current and Voltage Harmonic Magnitude and Angles 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, and 13 are shown on the
display.
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Chapter 5—Input/Output Capabilities
Chapter 5—Input/Output Capabilities
Digital Inputs
The power meter includes one solid-state digital input. A digital input is used to detect
digital signals. For example, the digital input can be used to determine circuit breaker
status, count pulses, or count motor starts. The digital input can also be associated with an
external relay. You can log digital input transitions as events in the power meter’s on-board
alarm log. The event is date and time stamped with resolution to the second. The power
meter counts OFF-to-ON transitions for each input. You can view the count for each input
using the Digital Inputs screen, and you can reset this value using the command interface.
Figure 5–1 is an example of the Digital Inputs screen.
Figure 5–1: Digital Inputs Screen
A. Lit bargraph indicates that the input is
ON. For analog inputs or outputs, the
bargraph indicates the output
percentage.
A
B. SI is common to all meters and
represents standard digital input.
C. A-S1 and A-S2 represent I/O point
numbers on the first (A) module.
D. Use the arrow buttons to scroll through
B
the remaining I/O points. Point numbers
beginning with “B” are on the second
module.
C
D
The digital input has three operating modes:
•
Normal—Use the normal mode for simple on/off digital inputs. In normal mode, digital
inputs can be used to count KY pulses for demand and energy calculation.
•
Demand Interval Synch Pulse—you can configure any digital input to accept a
demand synch pulse from a utility demand meter (see “Demand Synch Pulse Input” on
page 40 of this chapter for more about this topic). For each demand profile, you can
designate only one input as a demand synch input.
•
Conditional Energy Control—you can configure one digital input to control conditional
4—Metering Capabilities for more about conditional energy).
NOTE: By default, the digital input is named DIG IN S02 and is set up for normal mode.
For custom setup, use PowerLogic software to define the name and operating mode of the
digital input. The name is a 16-character label that identifies the digital input. The operating
mode is one of those listed above.
39
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Demand Synch Pulse Input
You can configure the power meter to accept a demand synch pulse from an external
source, such as another demand meter. By accepting demand synch pulses through a
digital input, the power meter can make its demand interval “window” match the other
meter’s demand interval “window.” The power meter does this by “watching” the digital
input for a pulse from the other demand meter. When it sees a pulse, it starts a new
demand interval and calculates the demand for the preceding interval. The power meter
then uses the same time interval as the other meter for each demand calculation. Figure
Capabilities for more about demand calculations.
When in demand synch pulse operating mode, the power meter will not start or stop a
demand interval without a pulse. The maximum allowable time between pulses is 60
minutes. If 66 minutes (110% of the demand interval) pass before a synch pulse is
received, the power meter throws out the demand calculations and begins a new
calculation when the next pulse is received. Once in synch with the billing meter, the power
meter can be used to verify peak demand charges.
Important facts about the power meter’s demand synch feature are listed below:
•
•
Any installed digital input can be set to accept a demand synch pulse.
Each system can choose whether to use an external synch pulse, but only one demand
synch pulse can be brought into the meter for each demand system. One input can be
used to synchronize any combination of the demand systems.
•
The demand synch feature can be set up using PowerLogic software.
Figure 5–2: Demand synch pulse timing
Normal Demand Mode
External Synch Pulse Demand Timing
Billing Meter
Billing Meter
Demand Timing
Demand Timing
Utility Meter
Synch Pulse
Power Meter
Demand Timing
(Slave to Master)
Power Meter
Demand Timing
Relay Output Operating Modes
The relay output defaults to external control, but you can choose whether the relay is set to
external or internal control:
•
External (remote) control—the relay is controlled either from a PC using PowerLogic
software or a programmable logic controller using commands via communications.
•
Power meter alarm (internal) control—the relay is controlled by the power meter in
response to a set-point controlled alarm condition, or as a pulse initiator output. Once
you’ve set up a relay for power meter control, you can no longer operate the relay
remotely. However, you can temporarily override the relay, using PowerLogic software.
NOTE: If any basic setup parameters or I/O setup parameters are modified, all relay
outputs will be de-energized.
The 11 relay operating modes are as follows:
•
Normal
— Externally Controlled: Energize the relay by issuing a command from a remote PC
or programmable controller. The relay remains energized until a command to de-
energize is issued from the remote PC or programmable controller, or until the
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PowerLogicTM Series 800 Power Meter
Chapter 5—Input/Output Capabilities
power meter loses control power. When control power is restored, the relay is not
automatically re-energized.
— Power Meter Alarm: When an alarm condition assigned to the relay occurs, the
relay is energized. The relay is not de-energized until all alarm conditions assigned
to the relay have dropped out, the power meter loses control power, or the alarms
are over-ridden using PowerLogic software. If the alarm condition is still true when
the power meter regains control power, the relay will be re-energized.
•
Latched
— Remotely Controlled: Energize the relay by issuing a command from a remote PC
or programmable controller. The relay remains energized until a command to de-
energize is issued from a remote PC or programmable controller, or until the power
meter loses control power. When control power is restored, the relay will not be re-
energized.
— Power Meter Controlled: When an alarm condition assigned to the relay occurs,
the relay is energized. The relay remains energized—even after all alarm conditions
assigned to the relay have dropped out—until a command to de-energize is issued
from a remote PC or programmable controller, until the high priority alarm log is
cleared from the display, or until the power meter loses control power. When control
power is restored, the relay will not be re-energized if the alarm condition is not
TRUE.
•
Timed
— Remotely Controlled: Energize the relay by issuing a command from a remote PC
or programmable controller. The relay remains energized until the timer expires, or
until the power meter loses control power. If a new command to energize the relay is
issued before the timer expires, the timer restarts. If the power meter loses control
power, the relay will not be re-energized when control power is restored and the
timer will reset to zero.
— Power Meter Controlled: When an alarm condition assigned to the relay occurs, the
relay is energized. The relay remains energized for the duration of the timer. When
the timer expires, the relay will de-energize and remain de-energized. If the relay is
on and the power meter loses control power, the relay will not be re-energized when
control power is restored and the timer will reset to zero.
•
•
•
End Of Power Demand Interval
This mode assigns the relay to operate as a synch pulse to another device. The output
operates in timed mode using the timer setting and turns on at the end of a power
demand interval. It turns off when the timer expires.
Absolute kWh Pulse
This mode assigns the relay to operate as a pulse initiator with a user-defined number
of kWh per pulse. In this mode, both forward and reverse real energy are treated as
additive (as in a tie circuit breaker).
Absolute kVARh Pulse
This mode assigns the relay to operate as a pulse initiator with a user-defined number
of kVARh per pulse. In this mode, both forward and reverse reactive energy are treated
as additive (as in a tie circuit breaker).
•
•
•
kVAh Pulse
This mode assigns the relay to operate as a pulse initiator with a user-defined number
of kVAh per pulse. Since kVA has no sign, the kVAh pulse has only one mode.
kWh In Pulse
This mode assigns the relay to operate as a pulse initiator with a user-defined number
of kWh per pulse. In this mode, only the kWh flowing into the load is considered.
kVARh In Pulse
This mode assigns the relay to operate as a pulse initiator with a user-defined number
of kVARh per pulse. In this mode, only the kVARh flowing into the load is considered.
41
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•
•
kWh Out Pulse
This mode assigns the relay to operate as a pulse initiator with a user-defined number
of kWh per pulse. In this mode, only the kWh flowing out of the load is considered.
kVARh Out Pulse
This mode assigns the relay to operate as a pulse initiator with a user-defined number
of kVARh per pulse. In this mode, only the kVARh flowing out of the load is considered.
The last seven modes in the list above are for pulse initiator applications. All Series 800
Power Meters are equipped with one solid-state KY pulse output rated at 100 mA. The
solid-state KY output provides the long life—billions of operations—required for pulse
initiator applications.
The KY output is factory configured with Name = KY, Mode = Normal, and Control =
(Input/Output) Setup” on page 18. Then using PowerLogic software, you must define the
following values for each mechanical relay output:
•
•
•
Name—A 16-character label used to identify the digital output.
Mode—Select one of the operating modes listed above.
Pulse Weight—You must set the pulse weight, the multiplier of the unit being
measured, if you select any of the pulse modes (last 7 listed above).
•
•
Timer—You must set the timer if you select the timed mode or end of power demand
interval mode (in seconds).
Control—You must set the relay to be controlled either remotely or internally (from the
power meter) if you select the normal, latched, or timed mode.
For instructions on setting up digital I/Os using software, see your software documentation
or help file.
Solid-state KY Pulse Output
This section describes the pulse output capabilities of the power meter. For instructions on
wiring the KY pulse output, see “Wiring the Solid-State KY Output” in the installation guide.
The power meter’s digital output is generated by a solid-state device that can be used as a
KY pulse output. This solid-state relay provides the extremely long life—billions of
operations—required for pulse initiator applications.
The KY output is a Form-A contact with a maximum rating of 100 mA. Because most pulse
initiator applications feed solid-state receivers with low burdens, this 100 mA rating is
adequate for most applications.
When setting the kWh/pulse value, set the value based on a 2-wire pulse output. For
instructions on calculating the correct value, see “Calculating the Kilowatthour-Per-Pulse
Value” on page 43 in this chapter.
The KY pulse output can be configured to operate in one of 11 operating modes. See
“Relay Output Operating Modes” on page 40 for a description of the modes.
2-wire Pulse Initiator
Figure 5–3 shows a pulse train from a 2-wire pulse initiator application.
Figure 5–3: Two-wire pulse train
Y
K
3
1
2
KY
ΔT
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PowerLogicTM Series 800 Power Meter
Chapter 5—Input/Output Capabilities
when the relay contact closes. Each time the relay transitions, the receiver counts a pulse.
The power meter can deliver up to 12 pulses per second in a 2-wire application.
Fixed Pulse Output
Fixed pulse output mode generates a fixed duration pulse output that can be associated
either TRANS mode or PULSE mode is selected. This mode selection is configured on the
MAINT > IO > ADVAN menu.
Figure 5–4: Fixed-pulse output
TRANS & PULSE mode
Pulse Weight = 0.02kWHr/pulse
TRANS mode:
Counts = 4
Setting in ADV mode:
10, 25, 50, 100, 150,
200, 300, 500, 1000
100 msec
PULSE mode (100ms):
Counts = 8
0.02kW
0.04kW
0.06kW
0.08kW
0.1kW
0.12kW
0.14kW
0.16kW
Calculating the Kilowatthour-Per-Pulse Value
The following example illustrates how to calculate kilowatthours per pulse (pulse weight).
To calculate this value, first determine the highest kW value you can expect and the
required pulse rate. Remember the maximum number of pulses is 8 per second.
In this example, the following conditions are set:
•
•
The metered load should not exceed 1600 kW.
About two KY pulses per second should normally occur. (If a higher load is reached, the
number of pulses per second can increase and still stay within the set limits.)
Step 1: Convert 1600 kW load into kWh/second.
(1600 kW)(1 Hr) = 1600 kWh
(1600 kWh)
1 hour
X kWh
1 second
------------------------------ = -----------------------
(1600 kWh)
3600 seconds
X kWh
1 second
------------------------------------ = -----------------------
X = 1600/3600 = 0.444 kWh/second
Step 2: Calculate the kWh required per pulse.
0.444 kWh/second
------------------------------------------------- = 0 . 2 2 2 kW h / p u l s e
2 pulses/second
Step 3: Adjust for the KY initiator (KY will give one pulse per two transitions of the relay).
43
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0.222 kWh/second
------------------------------------------------- = 0 . 1 1 1 1 kW h / p u ls e
2
Step 4: Round to nearest hundredth, since the power meter only accepts 0.01 kWh
increments.
Pulse Weight (Ke) = 0.11 kWh/pulse
Analog Inputs
With a PM8M2222 option module installed, a power meter can accept either voltage or
current signals through the analog inputs on the option module. The power meter stores a
minimum and a maximum value for each analog input.
For technical specifications and instructions on installing and configuring the analog inputs
on the PM8M2222, refer to the instruction bulletin (63230-502-200) that ships with the
option module. To set up an analog input, you must first set it up from the display. From the
SUMMARY screen, select MAINT > SETUP > I/O, then select the appropriate analog input
option. Then, in PowerLogic software, define the following values for each analog input:
•
•
•
•
Name—a 16-character label used to identify the analog input.
Units—the units of the monitored analog value (for example, “psi”).
Scale factor—multiplies the units by this value (such as tenths or hundredths).
Report Range Lower Limit—the value the Power Meter reports when the input
reaches a minimum value. When the input current is below the lowest valid reading, the
Power Meter reports the lower limit.
•
Report Range Upper Limit—the value the power meter reports when the input
reaches the maximum value. When the input current is above highest valid reading, the
Power Meter reports the upper limit.
For instructions on setting up analog inputs using software, see your software
documentation or Help file.
Analog Outputs
This section describes the analog output capabilities when a PM8M2222 is installed on the
Power Meter. For technical specifications and instructions on installing and configuring the
analog outputs on the PM8M2222, refer to the instruction bulletin (63230-502-200) that
ships with the option module.
To set up an analog output, you must first set it up from the display. From the SUMMARY
screen, select MAINT > SETUP > I/O, then select the appropriate analog output option.
Then, in PowerLogic software, define the following values for each analog input
•
Name—a 16-character label used to identify the output. Default names are assigned,
but can be customized
•
•
Output register—the Power Meter register assigned to the analog output.
Lower Limit—the value equivalent to the minimum output current. When the register
value is below the lower limit, the Power Meter outputs the minimum output current.
•
Upper Limit—the value equivalent to the maximum output current. When the register
value is above the upper limit, the Power Meter outputs the maximum output current.
For instructions on setting up an analog output using software, see your software
documentation or Help file.
44
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PowerLogicTM Series 800 Power Meter
Chapter 6—Alarms
Chapter 6—Alarms
This section describes the alarm features on all Series 800 Power Meters. For information
Basic Alarms
The power meter can detect over 50 alarm conditions, including over or under conditions,
digital input changes, phase unbalance conditions, and more. It also maintains a counter
for each alarm to keep track of the total number of occurrences. A complete list of default
up your own custom alarms after installing an input/output module (PM8M22, PM8M26, or
PM8M2222).
When one or more alarm conditions are true, the power meter will execute a task
automatically. When an alarm is active, the !alarm icon appears in the upper-right corner
of the power meter display. If a PM810LOG is installed on a PM810, PowerLogic software
can be used to set up each alarm condition to force data log entries in a single data log file.
For the PM820, PM850, and PM870 PowerLogic software can be used to set up each
alarm condition to force data log entries in up to three user-defined data log files. See
NOTE: PM820 only supports one data log.
Table 6–1: Basic alarm features by model
PM810 with
Basic Alarm Feature
PM810
PM820
PM850
PM870
PM810LOG
Standard alarms
33
33
33
7
33
7
33
7
Open slots for additional
standard alarms
➀
➀
7
7
➁
➁
➁
➁
➁
Digital
12
12
12
12
12
Custom alarms
No
No
Yes
Yes
Yes
➀ Available when an I/O module with analog IN/OUT is installed.
➁ Requires an input/output option module (PM8M22, PM8M26, or the PM8M2222).
Basic Alarm Groups
When using a default alarm, you first choose the alarm group that is appropriate for the
application. Each alarm condition is assigned to one of these alarm groups:
Whether you are using a default alarm or creating a custom alarm, you first choose the
alarm group that is appropriate for the application. Each alarm condition is assigned to one
of these alarm groups:
•
•
•
Standard—Standard alarms have a detection rate of 1 second and are useful for
detecting conditions such as over current and under voltage. Up to 40 alarms can be
set up in this alarm group.
Digital—Digital alarms are triggered by an exception such as the transition of a digital
input or the end of an incremental energy interval. Up to 12 alarms can be set up in this
group.
Custom—The power meter has many pre-defined alarms, but you can also set up your
own custom alarms using PowerLogic software. For example, you may need to alarm
on the ON-to-OFF transition of a digital input. To create this type of custom alarm:
1. Select the appropriate alarm group (digital in this case).
3. Give the alarm a name.
4. Save the custom alarm.
After creating a custom alarm, you can configure it by applying priorities, setting pickups
and dropouts (if applicable), and so forth.
Both the power meter display and PowerLogic software can be used to set up standard,
digital, and custom alarm types.
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Chapter 6—Alarms
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Setpoint-driven Alarms
Many of the alarm conditions require that you define setpoints. This includes all alarms for
over, under, and phase unbalance alarm conditions. Other alarm conditions such as digital
input transitions and phase reversals do not require setpoints. For those alarm conditions
that require setpoints, you must define the following information:
•
•
•
•
Pickup Setpoint
Pickup Delay
Dropout Setpoint
Dropout Delay
NOTE: Alarms with both Pickup and Dropout setpoints set to zero are invalid.
The following two figures will help you understand how the power meter handles setpoint-
look like, as displayed by PowerLogic software.
NOTE: The software does not actually display the codes in parentheses—EV1, EV2, Max1,
Figure 6–1: Sample alarm log entry
(EV2)
(Max2)
(EV1)
(Max1)
Figure 6–2: How the power meter handles setpoint-driven alarms
Max2
Max1
Pickup
Setpoint
Dropout
Setpoint
Pickup Delay
Dropout Delay
EV2
EV1
Alarm Period
EV1—The power meter records the date and time that the pickup setpoint and time delay
were satisfied, and the maximum value reached (Max1) during the pickup delay period
(T). Also, the power meter performs any tasks assigned to the event such as waveform
captures or forced data log entries.
EV2—The power meter records the date and time that the dropout setpoint and time delay
were satisfied, and the maximum value reached (Max2) during the alarm period.
The power meter also stores a correlation sequence number (CSN) for each event (such as
Under Voltage Phase A Pickup, Under Voltage Phase A Dropout). The CSN lets you relate
pickups and dropouts in the alarm log. You can sort pickups and dropouts by CSN to
correlate the pickups and dropouts of a particular alarm. The pickup and dropout entries of
an alarm will have the same CSN. You can also calculate the duration of an event by
looking at pickups and dropouts with the same CSN.
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Chapter 6—Alarms
Priorities
Each alarm also has a priority level. Use the priorities to distinguish between events that
require immediate action and those that do not require action.
•
High priority—if a high priority alarm occurs, the display informs you in two ways: the
LED backlight on the display flashes until you acknowledge the alarm and the alarm
icon blinks while the alarm is active.
•
Medium priority—if a medium priority alarm occurs, the alarm icon blinks only while
the alarm is active. Once the alarm becomes inactive, the alarm icon stops blinking and
remains on the display.
•
•
Low priority—if a low priority alarm occurs, the alarm icon blinks only while the alarm is
active. Once the alarm becomes inactive, the alarm icon disappears from the display.
No priority—if an alarm is set up with no priority, no visible representation will appear
on the display. Alarms with no priority are not entered in the Alarm Log. See Chapter
7—Logging for alarm logging information.
If multiple alarms with different priorities are active at the same time, the display shows the
alarm message for the last alarm that occurred. For instructions on setting up alarms from
Viewing Alarm Activity and History
1. Press ###:until ALARM is visible.
2. Press ALARM.
ꢝꢬꢄꢇꢆꢬꢔꢕ
ꢌꢍꢇꢆꢉ
ꢉꢀꢁ
ꢂꢅꢆ
ꢆꢄꢇꢀꢁꢇꢆꢄ
ꢑꢆ
3. View the active alarm listed on the power
meter display. If there are no active
alarms, the screen reads, “NO ACTIVE
ALARM.”
ꢁꢊꢃꢚꢌ
ꢹ
4. If there are active alarms, press
ꢋꢫꢰꢻ
<--or -->to view a different alarm.
5. Press HIST.
ꢖꢌꢳꢖ
6. Press <--or -->to view a different
ꢈꢉ
ꢙꢍꢍ
ꢍꢍꣅ
ꢂꢔꢚꢊꢬ
alarm’s history.
7. Press 1;to return to the SUMMARY
screen.
Types of Setpoint-controlled Functions
This section describes some common alarm functions to which the following information
applies:
•
•
•
Values that are too large to fit into the display may require scale factors. For more
Relays can be configured as normal, latched, or timed. See “Relay Output Operating
When the alarm occurs, the power meter operates any specified relays. There are two
ways to release relays that are in latched mode:
— Acknowledge the alarm in the high priority log to release the relays from latched
mode. From the main menu of the display, press ALARM to view and acknowledge
unacknowledged alarms.
The list that follows shows the types of alarms available for some common alarm functions:
NOTE: Voltage based alarm setpoints depend on your system configuration. Alarm
setpoints for 3-wire systems are V values while 4-wire systems are V
values.
L-L
L-N
47
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Chapter 6—Alarms
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Under-voltage: Pickup and dropout setpoints are entered in volts. The per-phase under-
voltage alarm occurs when the per-phase voltage is equal to or below the pickup setpoint
long enough to satisfy the specified pickup delay (in seconds). The under-voltage alarm
clears when the phase voltage remains above the dropout setpoint for the specified dropout
delay period.
Over-voltage: Pickup and dropout setpoints are entered in volts. The per-phase over-
voltage alarm occurs when the per-phase voltage is equal to or above the pickup setpoint
long enough to satisfy the specified pickup delay (in seconds). The over-voltage alarm
clears when the phase voltage remains below the dropout setpoint for the specified dropout
delay period.
Unbalance Current: Pickup and dropout setpoints are entered in tenths of percent, based
on the percentage difference between each phase current with respect to the average of all
phase currents. For example, enter an unbalance of 7% as 70. The unbalance current
alarm occurs when the phase current deviates from the average of the phase currents, by
the percentage pickup setpoint, for the specified pickup delay. The alarm clears when the
percentage difference between the phase current and the average of all phases remains
below the dropout setpoint for the specified dropout delay period.
Unbalance Voltage: Pickup and dropout setpoints are entered in tenths of percent, based
on the percentage difference between each phase voltage with respect to the average of all
phase voltages. For example, enter an unbalance of 7% as 70. The unbalance voltage
alarm occurs when the phase voltage deviates from the average of the phase voltages, by
the percentage pickup setpoint, for the specified pickup delay. The alarm clears when the
percentage difference between the phase voltage and the average of all phases remains
below the dropout setpoint for the specified dropout delay (in seconds).
Phase Loss—Current: Pickup and dropout setpoints are entered in amperes. The phase
loss current alarm occurs when any current value (but not all current values) is equal to or
below the pickup setpoint for the specified pickup delay (in seconds). The alarm clears
when one of the following is true:
•
•
All of the phases remain above the dropout setpoint for the specified dropout delay, or
All of the phases drop below the phase loss pickup setpoint.
If all of the phase currents are equal to or below the pickup setpoint, during the pickup
delay, the phase loss alarm will not activate. This is considered an under current condition.
It should be handled by configuring the under current alarm functions.
Phase Loss—Voltage: Pickup and dropout setpoints are entered in volts. The phase loss
voltage alarm occurs when any voltage value (but not all voltage values) is equal to or
below the pickup setpoint for the specified pickup delay (in seconds). The alarm clears
when one of the following is true:
•
•
All of the phases remain above the dropout setpoint for the specified dropout delay (in
seconds), OR
All of the phases drop below the phase loss pickup setpoint.
If all of the phase voltages are equal to or below the pickup setpoint, during the pickup
delay, the phase loss alarm will not activate. This is considered an under voltage condition.
It should be handled by configuring the under voltage alarm functions.
Reverse Power: Pickup and dropout setpoints are entered in kilowatts or kVARs. The
reverse power alarm occurs when the power flows in a negative direction and remains at or
below the negative pickup value for the specified pickup delay (in seconds). The alarm
clears when the power reading remains above the dropout setpoint for the specified
dropout delay (in seconds).
Phase Reversal: Pickup and dropout setpoints do not apply to phase reversal. The phase
reversal alarm occurs when the phase voltage rotation differs from the default phase
rotation. The power meter assumes that an ABC phase rotation is normal. If a CBA phase
rotation is normal, the user must change the power meter’s phase rotation from ABC
(default) to CBA. To change the phase rotation from the display, from the main menu select
Setup > Meter > Advanced. For more information about changing the phase rotation setting
48
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Chapter 6—Alarms
Scale Factors
A scale factor is the multiplier expressed as a power of 10. For example, a multiplier of 10 is
1
represented as a scale factor of 1, since 10 =10; a multiplier of 100 is represented as a
2
scale factor of 2, since 10 =100. This allows you to make larger values fit into the register.
Normally, you do not need to change scale factors. If you are creating custom alarms, you
need to understand how scale factors work so that you do not overflow the register with a
number larger than what the register can hold. When PowerLogic software is used to set up
alarms, it automatically handles the scaling of pickup and dropout setpoints. When creating
a custom alarm using the power meter’s display, do the following:
•
•
Determine how the corresponding metering value is scaled, and
Take the scale factor into account when entering alarm pickup and dropout settings.
Pickup and dropout settings must be integer values in the range of -32,767 to +32,767. For
example, to set up an under voltage alarm for a 138 kV nominal system, decide upon a
setpoint value and then convert it into an integer between -32,767 and +32,767. If the under
voltage setpoint were 125,000 V, this would typically be converted to 12500 x 10 and
entered as a setpoint of 12500.
Six scale groups are defined (A through F). The scale factor is preset for all factory-
configured alarms. Table 6–2 lists the available scale factors for each of the scale groups.
If you need either an extended range or more resolution, select any of the available scale
Appendix C—Using the Command Interface.
Table 6–2: Scale Groups
Scale Group
Measurement Range
Scale Factor
Amperes
0–327.67 A
–2
Scale Group A—Phase Current
0–3,276.7 A
–1
0–32,767 A
0 (default)
1
0–327.67 kA
Amperes
0–327.67 A
–2
Scale Group B—Neutral Current
0–3,276.7 A
–1
0–32,767 A
0 (default)
1
0–327.67 kA
Voltage
0–3,276.7 V
–1
Scale Group D—Voltage
0–32,767 V
0 (default)
0–327.67 kV
1
2
0–3,276.7 kV
Power
0–32.767 kW, kVAR, kVA
0–327.67 kW, kVAR, kVA
0–3,276.7 kW, kVAR, kVA
0–32,767 kW, kVAR, kVA
0–327.67 MW, MVAR, MVA
0–3,276.7 MW, MVAR, MVA
0–32,767 MW, MVAR, MVA
–3
–2
–1
Scale Group F—Power kW, kVAR, kVA
0 (default)
1
2
3
49
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Chapter 6—Alarms
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3/2011
Scaling Alarm Setpoints
This section is for users who do not have PowerLogic software and need to set up alarms
from the power meter display. It explains how to scale alarm setpoints.
When the power meter is equipped with a display, most metered quantities are limited to
five characters (plus a positive or negative sign). The display will also show the engineering
units applied to that quantity.
To determine the proper scaling of an alarm setpoint, view the register number for the
associated scale group. The scale factor is the number in the Dec column for that register.
For example, the register number for Scale D to Phase Volts is 3212. If the number in the
1
Dec column is 1, the scale factor is 10 (10 =10). Remember that scale factor 1 in
setpoint of 125 kV, enter 12.5 because 12.5 multiplied by 10 is 125. Below is a table listing
the scale groups and their register numbers.
Table 6–3: Scale Group Register Numbers
Scale Group
Register Number
Scale Group A—Phase Current
3209
3210
3211
3212
3214
Scale Group B—Neutral Current
Scale Group C—Ground Current
Scale Group D—Voltage
Scale Group F—Power kW, kVAR, kVA
Alarm Conditions and Alarm Numbers
This section lists the power meter’s predefined alarm conditions. For each alarm condition,
the following information is provided.
•
•
•
Alarm No.—a position number indicating where an alarm falls in the list.
Alarm Description—a brief description of the alarm condition
Abbreviated Display Name—an abbreviated name that describes the alarm condition
but is limited to 15 characters that fit in the window of the power meter’s display.
•
Test Register—the register number that contains the value (where applicable) that is
used as the basis for a comparison to alarm pickup and dropout settings.
•
•
Units—the unit that applies to the pickup and dropout settings.
Scale Group—the scale group that applies to the test register’s metering value (A–F).
•
Alarm Type—a reference to a definition that provides details on the operation and
configuration of the alarm. For a description of alarm types, refer to Table 6–6 on page
Table 6– 4 lists the default alarm configuration - factory-enabled alarms.
Table 6– 5 lists the default basic alarms by alarm number.
Table 6– 6 lists the alarm types.
Table 6–4: Default Alarm Configuration - Factory-enabled Alarms
Pickup
Dropout
Limit Time
Delay
Alarm
No.
Pickup
Limit
Dropout
Limit
Standard Alarm
Limit Time
Delay
19
20
53
55
Voltage Unbalance L-N
20 (2.0%)
300
300
0
20 (2.0%)
300
300
0
Max. Voltage Unbalance L-L
End of Incremental Energy Interval
Power-up Reset
20 (2.0%)
20 (2.0%)
0
0
0
0
0
0
50
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PowerLogicTM Series 800 Power Meter
Chapter 6—Alarms
Table 6–5: List of Default Basic Alarms by Alarm Number
Alarm
Number
Abbreviated
Display Name Register
Test
Scale Alarm
Group Type
Alarm Description
Units
➀
➁
Standard Speed Alarms (1 Second)
01
02
03
04
05
06
07
08
09
10
11
12
13
14
15
16
17
18
19
20
Over Current Phase A
Over Current Phase B
Over Current Phase C
Over Current Neutral
Over Ia
1100
1101
1102
1103
1110
3262
1124
1125
1126
1120
1121
1122
1124
1125
1126
1120
1121
1122
1136
1132
Amperes
Amperes
Amperes
Amperes
Tenths %
Amperes
Volts
A
A
010
010
010
010
010
053
010
010
010
010
010
010
020
020
020
020
020
020
010
010
Over Ib
Over Ic
A
Over In
B
Current Unbalance, Max
Current Loss
I Unbal Max
Current Loss
Over Van
—
A
Over Voltage Phase A–N
Over Voltage Phase B–N
Over Voltage Phase C–N
Over Voltage Phase A–B
Over Voltage Phase B–C
Over Voltage Phase C–A
Under Voltage Phase A
Under Voltage Phase B
Under Voltage Phase C
Under Voltage Phase A–B
Under Voltage Phase B–C
Under Voltage Phase C–A
Voltage Unbalance L–N, Max
Voltage Unbalance L–L, Max
D
D
D
D
D
D
D
D
D
D
D
D
—
—
Over Vbn
Volts
Over Vcn
Volts
Over Vab
Over Vbc
Volts
Volts
Over Vca
Volts
Under Van
Under Vbn
Under Vcn
Under Vab
Under Vbc
Under Vca
V Unbal L-N Max
V Unbal L-L Max
Volts
Volts
Volts
Volts
Volts
Volts
Tenths %
Tenths %
Voltage Loss (loss of A,B,C, but
not all)
21
Voltage Loss
3262
Volts
D
052
22
23
24
25
26
27
28
29
30
31
32
33
Phase Reversal
Phase Rev
3228
2151
1163
1207
1208
1209
1211
1212
1213
2181
1143
1151
—
kW
—
F
051
011
055
010
010
010
010
010
010
011
011
011
Over kW Demand
Over kW Dmd
Lag True PF
Lagging true power factor
Thousandths
Tenths %
Tenths %
Tenths %
Tenths %
Tenths %
Tenths %
kVA
—
—
—
—
—
—
—
F
Over THD of Voltage Phase A–N Over THD Van
Over THD of Voltage Phase B–N Over THD Vbn
Over THD of Voltage Phase C–N Over THD Vcn
Over THD of Voltage Phase A–B Over THD Vab
Over THD of Voltage Phase B–C Over THD Vbc
Over THD of Voltage Phase C–A Over THD Vca
Over kVA Demand
Over kW Total
Over kVA Dmd
Over kW Total
Over kVA Total
kW
F
Over kVA Total
kVA
F
Reserved for additional analog
alarms ➂
34-40
34-40
—
—
—
—
—
—
—
—
—
—
Reserved for custom alarms.
Digital
End of incremental energy
interval
01
End Inc Enr Int
N/A
—
—
070
02
03
04
End of power demand interval
Power up/Reset
End Dmd Int
Pwr Up/Reset
DIG IN S02
N/A
N/A
2
—
—
—
—
—
—
070
070
060
Digital Input OFF/ON
Reserved for additional digital
alarms ➂
05-12
05-12
—
—
—
—
—
—
—
—
—
—
Reserved for custom alarms
➂ Additional analog and digital alarms require a corresponding I/O module to be installed.
51
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Chapter 6—Alarms
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Table 6–6: Alarm Types
Type Description
Operation
Standard Speed
If the test register value exceeds the setpoint long enough to satisfy the pickup
delay period, the alarm condition will be true. When the value in the test register
falls below the dropout setpoint long enough to satisfy the dropout delay period,
the alarm will drop out. Pickup and dropout setpoints are positive, delays are in
seconds.
010 Over Value Alarm
If the absolute value in the test register exceeds the setpoint long enough to
satisfy the pickup delay period, the alarm condition will be true. When absolute the
value in the test register falls below the dropout setpoint long enough to satisfy the
dropout delay period, the alarm will drop out. Pickup and dropout setpoints are
positive, delays are in seconds.
011 Over Power Alarm
If the absolute value in the test register exceeds the setpoint long enough to
satisfy the pickup delay period, the alarm condition will be true. When absolute the
value in the test register falls below the dropout setpoint long enough to satisfy the
dropout delay period, the alarm will drop out. This alarm will only hold true for
reverse power conditions. Positive power values will not cause the alarm to occur.
Pickup and dropout setpoints are positive, delays are in seconds.
Over Reverse
012
Power Alarm
If the test register value is below the setpoint long enough to satisfy the pickup
delay period, the alarm condition will be true. When the value in the test register
rises above the dropout setpoint long enough to satisfy the dropout delay period,
the alarm will drop out. Pickup and dropout setpoints are positive, delays are in
seconds.
020 Under Value Alarm
021 Under Power Alarm
051 Phase Reversal
If the absolute value in the test register is below the setpoint long enough to
satisfy the pickup delay period, the alarm condition will be true. When the absolute
value in the test register rises above the dropout setpoint long enough to satisfy
the dropout delay period, the alarm will drop out. Pickup and dropout setpoints are
positive, delays are in seconds.
The phase reversal alarm will occur whenever the phase voltage waveform
rotation differs from the default phase rotation. The ABC phase rotation is
assumed to be normal. If a CBA phase rotation is normal, the user should
reprogram the power meter’s phase rotation ABC to CBA phase rotation. The
pickup and dropout setpoints for phase reversal do not apply.
The phase loss voltage alarm will occur when any one or two phase voltages (but
not all) fall to the pickup value and remain at or below the pickup value long
enough to satisfy the specified pickup delay. When all of the phases remain at or
above the dropout value for the dropout delay period, or when all of the phases
drop below the specified phase loss pickup value, the alarm will drop out. Pickup
and dropout setpoints are positive, delays are in seconds.
052 Phase Loss, Voltage
053 Phase Loss, Current
The phase loss current alarm will occur when any one or two phase currents (but
not all) fall to the pickup value and remain at or below the pickup value long
enough to satisfy the specified pickup delay. When all of the phases remain at or
above the dropout value for the dropout delay period, or when all of the phases
drop below the specified phase loss pickup value, the alarm will drop out. Pickup
and dropout setpoints are positive, delays are in seconds.
The leading power factor alarm will occur when the test register value becomes
more leading than the pickup setpoint (such as closer to 0.010) and remains more
leading long enough to satisfy the pickup delay period. When the value becomes
equal to or less leading than the dropout setpoint, that is 1.000, and remains less
054 Leading Power Factor leading for the dropout delay period, the alarm will drop out. Both the pickup
setpoint and the dropout setpoint must be positive values representing leading
power factor. Enter setpoints as integer values representing power factor in
thousandths. For example, to define a dropout setpoint of 0.5, enter 500. Delays
are in seconds.
The lagging power factor alarm will occur when the test register value becomes
more lagging than the pickup setpoint (such as closer to –0.010) and remains
more lagging long enough to satisfy the pickup delay period. When the value
becomes equal to or less lagging than the dropout setpoint and remains less
055 Lagging Power Factor lagging for the dropout delay period, the alarm will drop out. Both the pickup
setpoint and the dropout setpoint must be positive values representing lagging
power factor. Enter setpoints as integer values representing power factor in
thousandths. For example, to define a dropout setpoint of –0.5, enter 500. Delays
are in seconds.
Digital
The digital input transition alarms will occur whenever the digital input changes
from off to on. The alarm will dropout when the digital input changes back to on
from off. The pickup and dropout setpoints and delays do not apply.
060 Digital Input On
061 Digital Input Off
070 Unary
The digital input transition alarms will occur whenever the digital input changes
from on to off.The alarm will dropout when the digital input changes back to off
from on. The pickup and dropout setpoints and delays do not apply.
This is a internal signal from the power meter and can be used, for example, to
alarm at the end of an interval or when the power meter is reset. Neither the
pickup and dropout delays nor the setpoints apply.
52
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PowerLogicTM Series 800 Power Meter
Chapter 6—Alarms
Advanced Alarms
This section describes the advanced alarm features found on the PM850 and the PM870.
Table 6 – 7: Advanced alarm features by model
Advanced Alarm Feature
PM850
PM870
Boolean alarms
Disturbance alarms
Alarm levels
10
—
10
12
Yes
Yes
Yes
Yes
Custom alarms
Advanced Alarm Groups
following advanced alarm groups are available.
•
•
Boolean—Boolean alarms use Boolean logic to combine up to four enabled alarms.
You can choose from the Boolean logic operands: AND, NAND, OR, NOR, or XOR to
combine your alarms. Up to 10 alarms can be set up in this group.
Disturbance (PM870)—Disturbance alarms have a detection rate of half a cycle and
are useful for detecting voltage sags and swells. The Power Meter comes configured
with 12 default voltage sag and swell alarms; current sag and swell alarms are available
by configuring custom alarms. Up to 12 disturbance alarms can be set up in this group.
For more information about disturbance monitoring, see Chapter 9—Disturbance
•
Custom—The power meter has many pre-defined alarms, but you can also set up your
own custom alarms using PowerLogic software. For example, you may need to alarm
on a sag condition for current A. To create this type of custom alarm:
1. Select the appropriate alarm group (Disturbance in this case).
2. Delete any of the default alarms you are not using from the disturbance alarms
group (for example, Sag Vbc). The Add button should be available now.
3. Click Add, then select Disturbance, Sag, and Current A.
4. Give the alarm a name.
5. Save the custom alarm.
After creating a custom alarm, you can configure it by applying priorities, setting pickups
and dropouts (if applicable), and so forth.
PowerLogic software can be used to configure any of the advanced alarm types, but the
power meter display cannot be used. Also, use PowerLogic software to delete an alarm
and create a new alarm for evaluating other metered quantities.
53
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Chapter 6—Alarms
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Alarm Levels
Using PowerLogic software with a PM850 or PM870, multiple alarms can be set up for one
particular quantity (parameter) to create alarm “levels”. You can take different actions
depending on the severity of the alarm.
For example, you could set up two alarms for kW Demand. A default alarm already exists
for kW Demand, but you could create another custom alarm for kW Demand, selecting
different pickup points for it. The custom kW Demand alarm, once created, will appear in
the standard alarm list. For illustration purposes, let’s set the default kW Demand alarm to
120 kW and the new custom alarm to 150 kW. One alarm named kW Demand ; the other
same quantity, use slightly different names to distinguish which alarm is active. The display
can hold up to 15 characters for each name. You can create up to 10 alarm levels for each
quantity.
Figure 6–3:Two alarms set up for the same quantity with different pickup and dropout set
points
kW Demand
Alarm #43 Pick Up
150
140
130
120
100
Alarm #43 Drop Out
Alarm #26 Pick Up
Alarm #26 Drop Out
Time
Demand OK Approaching
Peak Demand
Below Peak Demand OK
Demand
Peak Demand Exceeded
kW Demand (default)
Alarm #26 kW Demand with pickup
of 120 kWd, medium priority
kW Demand 150 kW (custom)
Alarm #43 kW Demand with pickup
of 150 kWd, high priority
Viewing Alarm Activity and History
1. Press ###:until ALARM is visible.
2. Press ALARM.
ꢝꢬꢄꢇꢆꢬꢔꢕ
ꢌꢍꢇꢆꢉ
ꢉꢀꢁ
ꢂꢅꢆ
ꢆꢄꢇꢀꢁꢇꢆꢄ
ꢑꢆ
3. View the active alarm listed on the power
meter display. If there are no active
alarms, the screen reads, “NO ACTIVE
ALARMS.”
ꢁꢊꢃꢚꢌ
ꢹ
4. If there are active alarms, press <--or --
ꢋꢫꢰꢻ
>to view a different alarm.
5. Press HIST.
ꢖꢌꢳꢖ
6. Press <--or -->to view a different
ꢈꢉ
ꢙꢍꢍ
ꢍꢍꣅ
ꢂꢔꢚꢊꢬ
alarm’s history.
7. Press 1;to return to the SUMMARY
screen.
54
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PowerLogicTM Series 800 Power Meter
Chapter 6—Alarms
Alarm Conditions and Alarm Numbers
This section lists the power meter’s predefined alarm conditions. For each alarm condition,
the following information is provided.
•
•
•
Alarm No.—a position number indicating where an alarm falls in the list.
Alarm Description—a brief description of the alarm condition
Abbreviated Display Name—an abbreviated name that describes the alarm condition,
but is limited to 15 characters that fit in the window of the power meter’s display.
•
Test Register—the register number that contains the value (where applicable) that is
used as the basis for a comparison to alarm pickup and dropout settings.
•
•
Units—the unit that applies to the pickup and dropout settings.
Scale Group—the scale group that applies to the test register’s metering value (A–F).
•
Alarm Type—a reference to a definition that provides details on the operation and
configuration of the alarm. For a description of advanced alarm types, refer to
Table 6–8 lists the preconfigured alarms by alarm number.
Table 6–8: List of Default Disturbance Alarms by Alarm Number
Alarm
Number
Abbreviated
Display Name Register
Test
Scale Alarm
Alarm Description
Units
➀
➁
Group
Type
Disturbance Monitoring (1/2 Cycle) (PM870)
41
42
43
44
45
46
47
48
49
50
51
52
Voltage Swell A
Voltage Swell B
Voltage Swell C
Voltage Swell A–B
Voltage Swell B–C
Voltage Swell C–A
Voltage Sag A–N
Voltage Sag B–N
Voltage Sag C–N
Voltage Sag A–B
Voltage Sag B–C
Voltage Sag C–A
Swell Van
Swell Vbn
Swell Vcn
Swell Vab
Swell Vbc
Swell Vca
Sag Van
Sag Vbn
Sag Vcn
Sag Vab
Sag Vbc
Sag Vca
Volts
Volts
Volts
Volts
Volts
Volts
Volts
Volts
Volts
Volts
Volts
Volts
D
D
D
D
D
D
D
D
D
D
D
D
080
080
080
080
080
080
080
080
080
080
080
080
NOTE: Current sag and swell alarms are enabled using PowerLogic software or by setting
up custom alarms. To do this, delete any of the above default disturbance alarms, and then
create a new current sag or swell alarm (see the example under the “Advanced Alarm
55
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Chapter 6—Alarms
63230-500-225A2
3/2011
Table 6–9: Advanced Alarm Types
Type
Description
Operation
Boolean
Logic
AND
The AND alarm will occur when all of the combined enabled alarms are
true (up to 4). The alarm will drop out when any of the enabled alarms
drops out.
100
101
102
103
104
Logic
NAND
The NAND alarm will occur when any, but not all, or none of the
combined enabled alarms are true. The alarm will drop out when all of
the enabled alarms drop out, or all are true.
Logic
OR
The OR alarm will occur when any of the combined enabled alarms are
true (up to 4). The alarm will drop out when all of the enabled alarms
are false.
Logic
NOR
The NOR alarm will occur when none of the combined enabled alarms
are true (up to 4). The alarm will drop out when any of the enabled
alarms are true.
Logic
XOR
The XOR alarm will occur when only one of the combined enabled
alarms is true (up to 4). The alarm will drop out when the enabled alarm
drops out or when more than one alarm becomes true.
Disturbance (PM870)
The voltage swell alarms will occur whenever the continuous rms
calculation is above the pickup setpoint and remains above the pickup
setpoint for the specified number of cycles. When the continuous rms
calculations fall below the dropout setpoint and remain below the
setpoint for the specified number of cycles, the alarm will drop out.
Pickup and dropout setpoints are positive and delays are in cycles.
080
080
Voltage Swell
Voltage Sag
The voltage sag alarms will occur whenever the continuous rms
calculation is below the pickup setpoint and remains below the pickup
setpoint for the specified number of cycles. When the continuous rms
calculations rise above the dropout setpoint and remain above the
setpoint for the specified number of cycles, the alarm will drop out.
Pickup and dropout setpoints are positive and delays are in cycles.
56
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PowerLogicTM Series 800 Power Meter
Chapter 7—Logging
Chapter 7—Logging
Introduction
This chapter briefly describes the following logs of the power meter:
•
•
•
•
Alarm log
Maintenance log
Billing log
User-defined data logs
See the table below for a summary of logs supported by each power meter model.
Table 7–1: Number of Logs Supported by Model
Number of Logs per Model
Log Type
PM810 with
PM810LOG
PM810
PM820
PM850
PM870
Alarm Log
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
Maintenance Log
Billing Log
—
—
1
Data Log 1
Data Log 2
Data Log 3
Data Log 4
1
—
—
—
Logs are files stored in the non-volatile memory of the power meter and are referred to as
Data and billing log files are preconfigured at the factory. You can accept the preconfigured
logs or change them to meet your specific needs. Use PowerLogic software to set up and
view all the logs. See your software’s online help or documentation for information about
working with the power meter’s on-board logs.
Table 7–2: Available Memory for On-board Logs
Power Meter Model
Total Memory Available
PM810
PM810 with PM810LOG
PM820
0 KB
80 KB
80 KB
800 KB
800 KB
PM850
PM870
Waveform captures are stored in the power meter’s memory, but they are not considered
Log Files”on the next page for information about memory allocation in the power meter.
57
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Chapter 7—Logging
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3/2011
Memory Allocation for Log Files
Each file in the power meter has a maximum memory size. Memory is not shared between
the different logs, so reducing the number of values recorded in one log will not allow more
values to be stored in a different log. The following table lists the memory allocated to each
log:
Table 7–3: Memory Allocation for Each Log
Max. Records
Stored
Max. Register
Values Recorded
Storage
(Bytes)
Power Meter
Model
Log Type
Alarm Log
100
40
11
4
2,200
320
All models
Maintenance Log
All models
PM810 with
PM810LOGPM820
Billing Log
5000
1851
96 + 3 D/T
96 + 3 D/T
65,536
14,808
PM850
PM870
PM810 with
PM810LOGPM820
Data Log 1
PM850
PM870
PM850
PM870
PM850
PM870
PM850
PM870
Data Log 2
Data Log 3
Data Log 4
5000
5000
96 + 3 D/T
96 + 3 D/T
96 + 3 D/T
393,216
393,216
393,216
32,000
Alarm Log
By default, the power meter can log the occurrence of any alarm condition. Each time an
alarm occurs it is entered into the alarm log. The alarm log in the power meter stores the
pickup and dropout points of alarms along with the date and time associated with these
alarms. You select whether the alarm log saves data as first-in-first-out (FIFO) or fill and
hold. With PowerLogic software, you can view and save the alarm log to disk, and reset the
alarm log to clear the data out of the power meter’s memory.
Alarm Log Storage
Maintenance Log
The power meter stores alarm log data in non-volatile memory. The size of the alarm log is
fixed at 100 records.
The power meter stores a maintenance log in non-volatile memory. The file has a fixed
record length of four registers and a total of 40 records. The first register is a cumulative
counter over the life of the power meter. The last three registers contain the date/time of
These values are cumulative over the life of the power meter and cannot be reset.
NOTE: Use PowerLogic software to view the maintenance log.
58
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PowerLogicTM Series 800 Power Meter
Chapter 7—Logging
Table 7–4: Values Stored in the Maintenance Log
Record
Value Stored
Number
1
2
3
4
Time stamp of the last change
Date and time of the last power failure
Date and time of the last firmware download
Date and time of the last option module change
Date and time of the latest LVC update due to configuration errors
detected during meter initialization
5
6–11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
Reserved
Date and time the Present Month Min/Max was last reset
Date and time the Previous Month Min/Max was last reset
Date and time the Energy Pulse Output was overdriven
Date and time the Power Demand Min/Max was last reset
Date and time the Current Demand Min/Max was last reset
Date and time the Generic Demand Min/Max was last reset
Date and time the Input Demand Min/Max was last reset
Reserved
Date and time the Accumulated Energy value was last reset
Date and time the Conditional Energy value was last reset
Date and time the Incremental Energy value was last reset
Reserved
Date and time of the last Standard KY Output operation
Date and time of the last Discrete Output @A01 operation➀
Date and time of the last Discrete Output @A02 operation➀
Date and time of the last Discrete Output @A03 operation➀
Date and time of the last Discrete Output @A04 operation➀
Date and time of the last Discrete Output @A05 operation➀
Date and time of the last Discrete Output @A06 operation➀
Date and time of the last Discrete Output @A07 operation➀
Date and time of the last Discrete Output @A08 operation➀
Date and time of the last Discrete Output @B01 operation➀
Date and time of the last Discrete Output @B02 operation➀
Date and time of the last Discrete Output @B03 operation➀
Date and time of the last Discrete Output @B04 operation➀
Date and time of the last Discrete Output @B05 operation➀
Date and time of the last Discrete Output @B06 operation➀
Date and time of the last Discrete Output @B07 operation➀
Date and time of the last Discrete Output @B08 operation➀
➀ Additional outputs require option modules and are based on the I/O
configuration of that particular module.
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Chapter 7—Logging
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Data Logs
The PM810 with a PM810LOG records and stores readings at regularly scheduled intervals
in one independent data log. This log is preconfigured at the factory. You can accept the
preconfigured data log or change it to meet your specific needs. You can set up the data
log to store the following information:
The PM820 records and stores readings at regularly scheduled intervals in one
independent data log. The PM850 and PM870 record and store meter readings at regularly
scheduled intervals in up to three independent data logs. Some data log files are
preconfigured at the factory. You can accept the preconfigured data logs or change them to
meet your specific needs. You can set up each data log to store the following information:
•
•
Timed Interval—1 second to 24 hours for Data Log 1
Timed Interval—1 second to 24 hours for Data Log 1, and 1 minute to 24 hours for Data
Logs 2, 3 and 4 (how often the values are logged)
•
•
•
First-In-First-Out (FIFO) or Fill and Hold
Values to be logged—up to 96 registers along with the date and time of each log entry
START/STOP Time—each log has the ability to start and stop at a certain time during
the day
Table 7–5: Default Data Log 1 Register List
Number of
Description
Data Type➀ Register Number
Registers
Start Date/Time
3
1
1
1
1
1
1
1
1
1
1
1
1
1
1
D/T
integer
Current D/T
1100
1101
1102
1103
1120
1121
1122
1124
1125
1126
1160
1161
1162
1163
Current, Phase A
Current, Phase B
Current, Phase C
Current, Neutral
integer
integer
integer
Voltage A-B
integer
Voltage B-C
integer
Voltage C-A
integer
Voltage A-N
integer
Voltage B-N
integer
Voltage C-N
integer
True Power Factor, Phase A
True Power Factor, Phase B
True Power Factor, Phase C
True Power Factor, Total
signed integer
signed integer
signed integer
signed integer
Last Demand, Current,
3-Phase Average
1
1
1
1
integer
integer
integer
integer
2000
2150
2165
2180
Last Demand, Real Power,
3-Phase Total
Last Demand, Reactive
Power, 3-Phase Total
Last Demand, Apparent
Power 3-Phase Total
➀ Refer to Appendix A for more information about data types.
Use PowerLogic software to clear each data log file, independently of the others, from the
power meter’s memory. For instructions on setting up and clearing data log files, refer to
the PowerLogic software online help or documentation.
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PowerLogicTM Series 800 Power Meter
Chapter 7—Logging
Alarm-driven Data Log Entries
The PM810 with a PM810LOG can detect over 50 alarm conditions, including over/under
conditions, digital input changes, phase unbalance conditions, and more. (See Chapter
alarm condition one or more tasks, including forcing data log entries into Data Log 1.
The PM820, PM850, and PM870 can detect over 50 alarm conditions, including over/under
conditions, digital input changes, phase unbalance conditions, and more. (See Chapter
alarm condition one or more tasks, including forcing data log entries into one or more data
log files.
For example, assume you have defined three data log files. Using PowerLogic software,
you could select an alarm condition such as “Overcurrent Phase A” and set up the power
meter to force data log entries into any of the three log files each time the alarm condition
occurs.
Organizing Data Log Files (PM850, PM870)
You can organize data log files in many ways. One possible way is to organize log files
according to the logging interval. You might also define a log file for entries forced by alarm
conditions. For example, you could set up three data log files as follows:
Data Log 1:
Data Log 2:
Data Log 3:
Log voltage every minute. Make the file large
enough to hold 60 entries so that you could look
back over the last hour’s voltage readings.
Log energy once every day. Make the file large
enough to hold 31 entries so that you could look
back over the last month and see daily energy use.
Report by exception. The report by exception file
contains data log entries that are forced by the
occurrence of an alarm condition. See the topic
information.
NOTE: The same data log file can support both scheduled and alarm-driven entries.
Billing Log
The PM810 with a PM810LOG, PM820, PM850 and PM870 Power Meters store a
configurable billing log that updates every 10 to 1,440 minutes (the default interval 60
minutes). Data is stored by month, day, and the specified interval in minutes. The log
contains 24 months of monthly data and 32 days of daily data, but because the maximum
amount of memory for the billing log is 64 KB, the number of recorded intervals varies
based on the number of registers recorded in the billing log. For example, using all of the
registers listed in Table 7–6, the billing log holds 12 days of data at 60-minute intervals.
This value is calculated by doing the following:
of registers). In this example, all 26 registers are used.
2. Calculate the number of bytes used for the 24 monthly records.
24 records (26 registers x 2 bytes/register) = 1,248
3. Calculate the number of bytes used for the 32 daily records.
32 (26 x 2) = 1,664
4. Calculate the number of bytes used each day (based on 15 minute intervals).
96 (26 x 2) = 4,992
5. Calculate the number of days of 60-minute interval data recorded by subtracting the
values from steps 2 and 3 from the total log file size of 65,536 bytes and then dividing
by the value in step 4.
(65,536 – 1,248 – 1,664) 4,992 = 12 days
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Chapter 7—Logging
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Chapter 7—Logging
Table 7–6: Billing Log Register List
Number of
Description
Data Type➀ Register Number
Registers
Start Date/Time
3
4
4
4
4
4
1
1
1
D/T
Current D/T
1700
Real Energy In
MOD10L4
MOD10L4
MOD10L4
MOD10L4
MOD10L4
INT16
Reactive Energy In
Real Energy Out
1704
1708
Reactive Energy Out
Apparent Energy Total
Total PF
1712
1724
1163
3P Real Power Demand
3P Apparent Power Demand
INT16
2151
INT16
2181
➀ Refer to Appendix A for more information about data types.
Configure the Billing Log Logging Interval
The billing log can be configured to update every 10 to 1,440 minutes. The default logging
interval is 60 minutes. To set the logging interval you can use PowerLogic software, or you
can use the power meter to write the logging interval to register 3085 (see “Read and
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Chapter 7—Logging
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PowerLogicTM Series 800 Power Meter
Chapter 8—Waveform Capture
Chapter 8—Waveform Capture
Introduction
This section explains the waveform capture capabilities of the following Power Meter
models:
•
•
PM850
PM870
See Table 8–1 for a summary of waveform capture features.
Table 8–1: Waveform capture summary by model
Waveform Capture Feature
PM850
PM870
Number of waveform captures
Waveform initiated:
Manually
5
5
By alarm
Samples per cycle
Channels (1 to 6)
Cycles
128
Configurable*
Configurable*
Configurable*
Configurable*
Configurable
3
1
Precycles
Waveform Capture
A waveform capture can be initiated manually or by an alarm trigger to analyze steady-
state or disturbance events. This waveform provides information about individual
harmonics, which PowerLogic software calculates through the 63rd harmonic. It also
calculates total harmonic distortion (THD) and other power quality parameters.
NOTE: Disturbance waveform captures are available in the PM870 only.
In the PM850, the waveform capture records five individual three-cycle captures at 128
samples per cycle simultaneously on all six metered channels. In the PM870, there is a
range of one to five waveform captures, but the number of cycles captured varies based on
the number of samples per cycle and the number of channels selected in your software.
Use Figure 8–1 to determine the number of cycles captured.
Figure 8–1: PM870 Number of Cycles Captured
6
5
4
3
2
1
30
35
45
60
90
15
15
20
30
45
7
3
9
4
10
15
20
5
Number
of
Channels
7
10
185
16
90
32
45
64
20
128
Number of Samples per Cycle
NOTE: The number of cycles shown above are the total number of cycles allowed (pre-
event cycles + event cycles = total cycles).
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Chapter 8—Waveform Capture
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Initiating a Waveform
Using PowerLogic software from a remote PC, initiate a waveform capture manually by
selecting the power meter and issuing the acquire command. The software will
automatically retrieve the waveform capture from the power meter. You can display the
waveform for all three phases, or zoom in on a single waveform, which includes a data
block with extensive harmonic data. See your software’s online help or documentation for
instructions.
Waveform Storage
The power meter can store multiple captured waveforms in its non-volatile memory. The
number of waveforms stored is based on the number selected. There are a maximum of
five stored waveforms. All stored waveform data is retained on power loss.
Waveform Storage Modes
There are two ways to store waveform captures: “FIFO” and “Fill and Hold.” FIFO mode
allows the file to fill up the waveform capture file. After the file is full, the oldest waveform
capture is removed, and the most recent waveform capture is added to the file. The Fill and
Hold mode fills the file until the configured number of waveform captures is reached. New
waveform captures cannot be added until the file is cleared.
How the Power Meter Captures an Event
When the power meter senses the trigger—that is, when the digital input transitions from
OFF to ON, or an alarm condition is met—the power meter transfers the cycle data from its
data buffer into the memory allocated for event captures.
Channel Selection in PowerLogic Software
Using PowerLogic software, you can select up to six channels to include in the waveform
capture. See your software’s online help or documentation for instructions.
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PowerLogicTM Series 800 Power Meter
Chapter 9—Disturbance Monitoring (PM870)
Chapter 9—Disturbance Monitoring (PM870)
This chapter provides background information about disturbance monitoring and describes
how to use the PM870 to continuously monitor for disturbances on the current and voltage
inputs.
About Disturbance Monitoring
Momentary voltage disturbances are an increasing concern for industrial plants, hospitals,
data centers, and other commercial facilities because modern equipment used in those
facilities tends to be more sensitive to voltage sags, swells, and momentary interruptions.
The power meter can detect these events by continuously monitoring and recording current
and voltage information on all metered channels. Using this information, you can diagnose
equipment problems resulting from voltage sags or swells and identify areas of
vulnerability, enabling you to take corrective action.
The interruption of an industrial process because of an abnormal voltage condition can
result in substantial costs, which manifest themselves in many ways:
•
•
•
•
labor costs for cleanup and restart
lost productivity
damaged product or reduced product quality
delivery delays and user dissatisfaction
The entire process can depend on the sensitivity of a single piece of equipment. Relays,
contactors, adjustable speed drives, programmable controllers, PCs, and data
communication networks are all susceptible to power quality problems. After the electrical
system is interrupted or shut down, determining the cause may be difficult.
Several types of voltage disturbances are possible, each potentially having a different
origin and requiring a separate solution. A momentary interruption occurs when a protective
device interrupts the circuit that feeds a facility. Swells and over-voltages can damage
equipment or cause motors to overheat. Perhaps the biggest power quality problem is the
momentary voltage sag caused by faults on remote circuits.
A voltage sag is a brief (1/2 cycle to 1 minute) decrease in rms voltage magnitude. A sag is
typically caused by a remote fault somewhere on the power system, often initiated by a
fault not only caused an interruption to plant D, but also resulted in voltage sags to plants A,
B, and C.
NOTE: The PM870 is able to detect sag and swell events less than 1/2 cycle duration.
However, it may be impractical to have setpoints more sensitive than 10% for voltage and
current fluctuations.
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PowerLogicTM Series 800 Power Meter
Chapter 9—Disturbance Monitoring (PM870)
63230-500-225A2
3/2011
Figure 9–1: A fault can cause a voltage sag on the whole system
Utility Circuit
Breakers with
Reclosers
1
Plant A
Plant B
Plant C
Utility
Transformer
2
3
4
Plant D
X
Fault
A fault near plant D, cleared by the utility circuit
breaker, can still affect plants A, B, and C,
resulting in a voltage sag.
System voltage sags are much more numerous than interruptions, since a wider part of the
distribution system is affected. And, if reclosers are operating, they may cause repeated
the magnitude of a voltage sag, which persists until the remote fault is cleared.
Figure 9–2: Waveform showing voltage sag caused by a remote fault and lasting five cycles
With the information obtained from the PM870 during a disturbance, you can solve
disturbance-related problems, including the following:
•
Obtain accurate measurement from your power system
— Identify the number of sags, swells, or interruptions for evaluation
— Accurately distinguish between sags and interruptions, with accurate recording of
the time and date of the occurrence
— Provide accurate data in equipment specification (ride-through, etc.)
Determine equipment sensitivity
•
— Compare equipment sensitivity of different brands (contactor dropout, drive
sensitivity, etc.)
— Diagnose mysterious events such as equipment malfunctions, contactor dropout,
computer glitches, etc.
— Compare actual sensitivity of equipment to published standards
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PowerLogicTM Series 800 Power Meter
Chapter 9—Disturbance Monitoring (PM870)
— Use waveform capture to determine exact disturbance characteristics to compare
with equipment sensitivity
— Justify purchase of power conditioning equipment
— Distinguish between equipment malfunctions and power system related problems
•
•
Develop disturbance prevention methods
— Develop solutions to voltage sensitivity-based problems using actual data
Work with the utility
— Discuss protection practices with the serving utility and negotiate suitable changes
to shorten the duration of potential sags (reduce interruption time delays on
protective devices)
— Work with the utility to provide alternate “stiffer” services (alternate design practices)
Capabilities of the PM870 During an Event
The PM870 calculates rms magnitudes, based on 128 data points per cycle, every 1/2
cycle. This ensures that even sub-cycle duration rms variations are not missed.
The power meter is configured with 12 default voltage disturbance alarms for all voltage
channels. Current sag and swell alarms are available by configuring custom alarms. A
maximum of 12 disturbance alarms are available. When the PM870 detects a sag or swell,
it can perform the following actions:
•
Perform a waveform capture with a resolution from 185 cycles at 16 samples per
cycle on one channel down to 3 cycles at 128 samples per cycle on all six channels of
software to set up the event capture and retrieve the waveform.
•
Record the event in the alarm log. When an event occurs, the PM870 updates the
alarm log with an event date and time stamp with 1 millisecond resolution for a sag or
swell pickup, and an rms magnitude corresponding to the most extreme value of the
sag or swell during the event pickup delay. Also, the PM870 can record the sag or swell
dropout in the alarm log at the end of the disturbance. Information stored includes: a
dropout time stamp with 1 millisecond resolution and a second rms magnitude
corresponding to the most extreme value of the sag or swell. Use PowerLogic software
to view the alarm log.
NOTE: The Power Meter display has a 1 second resolution.
•
Force a data log entry in up to 3 independent data logs. Use PowerLogic software to
set up and view the data logs.
•
•
Operate any output relays when the event is detected.
Indicate the alarm on the display by flashing the maintenance icon to show that a sag
or swell event has occurred.
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Chapter 9—Disturbance Monitoring (PM870)
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PowerLogicTM Series 800 Power Meter
Chapter 10—Maintenance and Troubleshooting
Chapter 10—Maintenance and Troubleshooting
Introduction
This chapter describes information related to maintenance of your power meter.
The power meter does not contain any user-serviceable parts. If the power meter requires
service, contact your local sales representative. Do not open the power meter. Opening the
power meter voids the warranty.
DANGER
HAZARD OF ELECTRIC SHOCK, EXPLOSION, OR ARC FLASH
• Do not attempt to service the power meter. CT and PT inputs may contain
hazardous currents and voltages.
• Only authorized service personnel from the manufacturer should service the
power meter.
Failure to follow these instructions will result in death or serious injury.
CAUTION
HAZARD OF EQUIPMENT DAMAGE
• Do not perform a Dielectric (Hi-Pot) or Megger test on the power meter. High
voltage testing of the power meter may damage the unit.
• Before performing Hi-Pot or Megger testing on any equipment in which the power
meter is installed, disconnect all input and output wires to the power meter.
Failure to follow these instructions can result in injury or equipment damage.
Power Meter Memory
The power meter uses its non-volatile memory (RAM) to retain all data and metering
configuration values. Under the operating temperature range specified for the power meter,
this non-volatile memory has an expected life of up to 100 years. The power meter stores
its data logs on a memory chip, which has a life expectancy of up to 20 years under the
operating temperature range specified for the power meter. The life of the internal battery-
backed clock is over 10 years at 25°C.
NOTE: Life expectancy is a function of operating conditions; this does not constitute any
expressed or implied warranty.
Date and Time Settings
The clock in the PM810 is volatile. Therefore, the PM810 returns to the default clock
date/time of 12:00 AM 01-01-1980 each time the meter resets. Reset occurs when the
meter loses control power or you change meter configuration parameters including
selecting the time format (24-hr or AM/PM) or date format. To avoid resetting clock time
more than once, always set the clock date and time last. The PM810LOG (optional module)
provides a non-volatile clock in addition to on-board logging and individual harmonics
readings for the PM810.
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Chapter 10—Maintenance and Troubleshooting
63230-500-225A2
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Identifying the Firmware Version, Model, and Serial Number
1. From the first menu level, press ###:until
MAINT is visible.
ꢅꢄꢚꢄꢇꢆꢊꢕꢮꢝ
ꢈꢂꢆ
ꢉꢀꢅꢉꢆꢆ
ꢉꢆꢅꢋꢆꢆ
ꢀꢂꢆꢆꢆꢉꢊꢁ
2. Press DIAG.
3. Press METER.
ꢀꢆꢅ
ꢅꢝꢋꢄꢨ
ꢖꢌꢗꢌ
4. View the model, firmware (OS) version,
and serial number.
ꢆꢆꢬ
ꢆꢆꢬ
5. Press 1;to return to the MAINTENANCE
screen.
ꢇꢄꢃꢄꢚ
ꢃꢌꢕꢌ
ꢈꢉ
ꢙꢍ
ꢍꣅ
Viewing the Display in Different Languages
The power meter can be set to use one of five different languages: English, French, and
Spanish. Other languages are available. Please contact your local sales representative for
more information about other language options.
The power meter language can be selected by doing the following:
1. From the first menu level, press ###:until
MAINT is visible.
ꢨꢂꢕꢩꢛꢂꢩꢄ
2. Press MAINT.
3. Press SETUP.
ꢄꢕꢩꢨꢌ
4. Enter your password, then press OK.
5. Press ###:until LANG is visible.
6. Press LANG.
7. Select the language: ENGL (English),
FREN (French), SPAN (Spanish), GERMN
(German), or RUSSN (Russian).
ꢈꢉ
ꢙꢍ
ꢜ
ꢝꢞ
8. Press OK.
9. Press1;.
10. Press YES to save your changes.
Technical Support
For assistance with technical issues, contact your local Schneider Electric representative.
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PowerLogicTM Series 800 Power Meter
Chapter 10—Maintenance and Troubleshooting
Troubleshooting
causes. It also describes checks you can perform or possible solutions for each. If you still
cannot resolve the problem after referring to this table, contact the your local Schneider
Electric sales representative for assistance.
DANGER
HAZARD OF ELECTRIC SHOCK, EXPLOSION, OR ARC FLASH
• Apply appropriate personal protective equipment (PPE) and follow safe
electrical practices. For example, in the United States, see NFPA 70E.
• This equipment must be installed and serviced only by qualified personnel.
• Turn off all power supplying this equipment before working on or inside.
• Always use a properly rated voltage sensing device to confirm that all power is
off.
• Carefully inspect the work area for tools and objects that may have been left
inside the equipment.
• Use caution while removing or installing panels so that they do not extend into
the energized bus; avoid handling the panels which could cause personal injury.
Failure to follow these instructions will result in death or serious injury.
Heartbeat LED
The heartbeat LED helps to troubleshoot the power meter. The LED works as follows:
•
•
Normal operation — the LED flashes at a steady rate during normal operation.
Communications — the LED flash rate changes as the communications port transmits
and receives data. If the LED flash rate does not change when data is sent from the
host computer, the power meter is not receiving requests from the host computer.
•
•
Hardware — if the heartbeat LED remains lit and does not flash ON and OFF, there is
a hardware problem. Do a hard reset of the power meter (turn OFF power to the power
meter, then restore power to the power meter). If the heartbeat LED remains lit, contact
your local sales representative.
Control power and display — if the heartbeat LED flashes, but the display is blank,
the display is not functioning properly. If the display is blank and the LED is not lit, verify
that control power is connected to the power meter.
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Chapter 10—Maintenance and Troubleshooting
63230-500-225A2
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Table 10–1: Troubleshooting
Potential Problem
Possible Cause
Possible Solution
Go to DIAGNOSTICS > MAINTENANCE.
Error messages display to indicate the
reason the icon is illuminated. Note these
When the maintenance icon is
illuminated, it indicates a potential
The maintenance icon is
illuminated on the power
meter display.
hardware or firmware problem in the error messages and call Technical
power meter.
Support, or contact your local sales
representative for assistance.
The display shows error
code 3.
Loss of control power or meter
configuration has changed.
Set date and time.
•
•
Verify that the power meter line (L) and
neutral (N) terminals (terminals 25 and
27) are receiving the necessary power.
Verify that the heartbeat LED is
blinking.
The display is blank after
applying control power to
the power meter.
The power meter may not be
receiving the necessary power.
Verify that the power meter is grounded as
Power meter is grounded incorrectly. described in “Grounding the Power Meter”
in the installation manual.
Check that the correct values have been
entered for power meter setup parameters
Incorrect setup values.
Incorrect voltage inputs.
(CT and PT ratings, System Type, Nominal
Frequency, and so on). See “Power Meter
Setup” on page 13 for setup instructions.
The data being displayed is
inaccurate or not what you
expect.
Check power meter voltage input terminals
L (8, 9, 10, 11) to verify that adequate
voltage is present.
Check that all CTs and PTs are connected
correctly (proper polarity is observed) and
that they are energized. Check shorting
terminals. See “Instrument Transformer
page 73. Initiate a wiring check using
PowerLogic software.
Power meter is wired improperly.
Check to see that the power meter is
correctly addressed. See “COMMS
instructions.
Power meter address is incorrect.
Power meter baud rate is incorrect.
Verify that the baud rate of the power
meter matches the baud rate of all other
devices on its communications link. See
page 15 for instructions.
Cannot communicate with
power meter from a remote
personal computer.
Verify the power meter communications
connections. Refer to the PM800-Series
Installation Guide.
Communications lines are improperly
connected.
Check to see that a multipoint
Communications lines are improperly communications terminator is properly
terminated.
installed. Refer to the PM800-Series
Installation Guide.
Check the route statement. Refer to your
software online help or documentation for
instructions on defining route statements.
Incorrect route statement to power
meter.
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PowerLogicTM Series 800 Power Meter
Appendix A—Instrument Transformer Wiring: Troubleshooting Tables
Appendix A—Instrument Transformer Wiring: Troubleshooting Tables
Abnormal readings in an installed meter can sometimes signify improper wiring. This
appendix is provided as an aid in troubleshooting potential wiring problems.
Using This Appendix
The following pages contain “Case” tables arranged in sections. These tables show a
variety of symptoms and probable causes.
Section I: Check these tables first. These are common problems for 3-wire and 4-wire
systems that can occur regardless of system type.
Section II: Check these tables if troubleshooting more complex 3-wire systems.
Section III: Check these tables if troubleshooting more complex 4-wire systems.
The symptoms listed are “ideal,” and some judgment should be exercised when
troubleshooting. For example, if the kW reading is 25, but you know that it should be about
300 kW, go to a table where “kW = 0” is listed as one of the symptoms.
Because it is nearly impossible to address all combinations of multiple wiring mistakes or
other problems that can occur (e.g., blown PT fuses, missing PT neutral ground
connection), this guide generally addresses only one wiring problem at a time.
Before trying to troubleshoot wiring problems, it is imperative that all instantaneous
readings be available for reference. Specifically, those readings should include the
following:
•
•
•
•
•
•
•
line-to-line voltages
line-to-neutral voltages
phase currents
power factor
kW
kVAR
kVA
What is Normal?
Most power systems have a lagging (inductive) power factor. The only time a leading power
factor is expected is if power factor correction capacitors are switched in or over-excited
synchronous motors with enough capacitive kVARS are on-line to overcorrect the power
factor to leading. Some uninterruptable power supplies (UPS) also produce a leading
power factor.
"Normal" lagging power system readings are as follows:
•
•
•
•
Positive kW = 3 VAB I3Avg PF3Avg 1000
Negative kVAR = kVA2 – kW2 1000
kVA (always positive) = 3 VAB I3Avg 1000
PF3Avg = lagging in the range 0.70 to 1.00 (for 4-wire systems, all phase PFs are
about the same)
•
•
Phase currents approximately equal
Phase voltages approximately equal
A quick check for proper readings consists of kW comparisons (calculated using the
previous equation and compared to the meter reading) and a reasonable lagging 3-phase
average power factor reading. If these checks are okay, there is little reason to continue to
check for wiring problems.
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Appendix A—Instrument Transformer Wiring: Troubleshooting Tables
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Section I: Common Problems for 3-Wire and 4-Wire Systems
Section I—Case A
Symptoms: 3-Wire and 4-Wire
Possible Causes
•
•
CT secondaries shorted.
•
•
Zero amps
Less than 2% load on power meter based on CT ratio.
Zero kW, kVAR, kVA
Example: with 100/5 CT's, at least 2A must flow through CT window for power
meter to “wake up.”
Section I—Case B
Symptoms: 3-Wire and 4-Wire
Possible Causes
•
All three CT polarities backwards; could be CTs are physically mounted
with primary polarity mark toward the load instead of toward source or
secondary leads swapped.
•
•
•
Negative kW of expected magnitude
Positive kVAR
•
All three PT polarities backwards; again, could be on primary or secondary.
Normal lagging power factor
NOTE: Experience shows CTs are usually the problem.
Section I—Case C
Symptoms: 3-Wire and 4-Wire
Possible Causes
•
•
PTs primary and/or secondary neutral common not grounded (values as
high as 275 Hz and as low as 10 Hz have been seen).
•
Frequency is an abnormal value; may or may
not be a multiple of 50/60 Hz.
System grounding problem at the power distribution transformer (such as
utility transformer), though this is not likely.
74
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PowerLogicTM Series 800 Power Meter
Appendix A—Instrument Transformer Wiring: Troubleshooting Tables
Section II: 3-Wire System Troubleshooting
Section II—Case A
Symptoms: 3-Wire
Possible Causes
•
•
•
•
Currents and voltages approximately balanced
kW = near 0
•
•
CT secondary leads are swapped (A-phase lead on C-phase terminal and
vice versa).
kVAR = near 0
PT secondary leads are swapped (A-phase lead on C-phase terminal and
vice versa).
PF can be any value, probably fluctuating
Section II—Case B
Symptoms: 3-Wire
Possible Causes
•
Phase B current is 3 higher than A and C
(except in System Type 31).
•
•
kVA = about half of the expected magnitude
•
One CT polarity is backwards.
kW and kVAR can be positive or negative, less
than about half of the expected magnitude.
•
PF can be any value, probably a low leading
value.
Section II—Case C
Symptoms: 3-Wire
Possible Causes
•
•
•
VCA is 3 higher than VAB and VBC
kVA = about half of the expected magnitude
kW and kVAR can be positive or negative, less
than about half of the expected magnitude
•
One PT polarity is backwards.
•
PF can be any value, probably a low leading
value
Section II—Case D
Symptoms: 3-Wire
Possible Causes
•
•
kW = 0 or low, with magnitude less than kVAR
•
•
Either the two voltage leads are swapped OR the two current leads are
swapped AND one instrument transformer has backwards polarity.
kVAR = positive or negative with magnitude of
close to what is expected for kW
(look for VCA
=
3 high or phase B current = 3 high)
•
•
kVA = expected magnitude
The power meter is metering a purely capacitive load (this is unusual); in
this case kW and kVAR will be positive and PF will be near 0 lead.
PF = near 0 up to about 0.7 lead
Section II—Case E
Symptoms: 3-Wire
Possible Causes
•
•
•
One phase current reads 0
•
•
The CT on the phase that reads 0 is short-circuited.
kVA = about 1/2 of the expected value
Less than 2% current (based on CT ratio) flowing through the CT on the
phase that reads 0.
kW, kVAR, and power factor can be positive or
negative of any value
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Appendix A—Instrument Transformer Wiring: Troubleshooting Tables
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Section III: 4-Wire System Troubleshooting
Section III—Case A
Symptoms: 4-Wire
Possible Causes
•
•
•
•
kW = 1/3 of the expected value
kVAR = 1/3 of the expected value
power factor = 1/3 of the expected value
All else is normal
•
One CT polarity is backwards.
NOTE: The only way this problem will usually be detected is by the Quick Check
procedure. It is very important to always calculate kW. In this case, it is the only symptom
and will go unnoticed unless the calculation is done or someone notices backwards CT on
a waveform capture.
Section III—Case B
Symptoms: 4-Wire
Possible Causes
•
One PT polarity is backwards.
•
•
•
•
•
kW = 1/3 of the expected value
kVAR = 1/3 of the expected value
2 of the 3 line-to-line voltages are 3 low
power factor = 1/3 of the expected value
All else is normal
NOTE: The line-to-line voltage reading that does not reference the PT with backwards
polarity will be the only correct reading.
Example: VAB= 277, VBC= 480, VCA= 277
In this case, the A-phase PT polarity is backwards. VBC is correct because it does not
reference VA
.
Section III—Case C
Symptoms: 4-Wire
Possible Causes
•
•
•
•
•
•
One line-to-neutral voltage is zero
2 of the 3 line-to-line voltages are 3 low
kW = 2/3 of the expected value
kVAR = 2/3 of the expected value
kVA = 2/3 of the expected value
Power factor may look abnormal
•
PT metering input missing (blown fuse, open phase disconnect, etc.) on the
phase that reads zero.
NOTE: The line-to-line voltage reading that does not reference the missing PT input will be
the only correct reading.
Example: VAB= 277, VBC= 277, VCA= 480
In this case, the B-phase PT input is missing. VCA is correct because it does not
reference VB
.
Section III—Case D
Symptoms: 4-Wire
Possible Causes
•
•
•
•
•
3-phase kW = 2/3 of the expected value
3-phase kVAR = 2/3 of the expected value
3-phase kVA = 2/3 of the expected value
One phase current reads 0
•
•
The CT on the phase that reads 0 is short-circuited.
Less than 2% current (based on CT ratio) flowing through the CT on the
phase that reads 0.
All else is normal
76
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Appendix A—Instrument Transformer Wiring: Troubleshooting Tables
Section III—Case E
Symptoms: 4-Wire
Possible Causes
•
•
•
kW = near 0
kVA = near 0
•
•
Two CT secondary leads are swapped (A-phase on B-phase terminal, for
example).
Two PT secondary leads are swapped (A-phase on B-phase terminal, for
example).
3-phase average power factor flip-flopping lead
and lag
NOTE: In either case, the phase input that is not swapped will read normal lagging power
factor.
•
Voltages, currents, and kVA are normal
Section III—Case F
Symptoms: 4-Wire
Possible Causes
•
•
kW = negative and less than kVAR
•
•
All three PT lead connections “rotated” counterclockwise: A-phase wire on
C-phase terminal, B-phase wire on A-phase terminal, C-phase wire on B-
phase terminal.
KVAR = negative and close to value expected
for kW
•
•
•
kVA = expected value
All three CT lead connections “rotated” clockwise: A-phase wire on B-phase
terminal, B-phase wire on C-phase terminal, C-phase wire on A-phase
terminal.
Power factor low and leading
Voltages and currents are normal
Section III—Case G
Symptoms: 4-Wire
Possible Causes
•
•
kW = negative and less than kVAR
•
All three PT lead connections “rotated” clockwise: A-phase wire on B-phase
terminal, B-phase wire on C-phase terminal, C-phase wire on A-phase
terminal.
kVAR = positive and close to the value for kW
NOTE: looks like kW and kVAR swapped places
•
All three CT lead connections “rotated” counterclockwise: A-phase wire on
C-phase terminal, B-phase wire on A-phase terminal, C-phase wire on B-
phase terminal.
•
•
•
kVA = expected value
Power factor low and lagging
Voltages and currents are normal
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Appendix A—Instrument Transformer Wiring: Troubleshooting Tables
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Field Example
Readings from a 4-wire system
•
•
•
•
•
•
•
•
•
•
•
•
•
•
kW= 25
kVAR= –15
kVA= 27
IA= 904A
IB= 910A
IC= 931A
I3Avg= 908A
VAB= 495V
VBC= 491V
VCA= 491V
VAN= 287V
VBN= 287V
VCN= 284V
PF3Avg= 0.75 lag to 0.22 lead fluctuating
Troubleshooting Diagnosis
•
•
Power factors cannot be correct .
None of the “Section II” symptoms exist, so proceed to the 4-wire troubleshooting
(“Section IV”).
•
•
Cannot calculate kW because 3-phase power factor cannot be right, so calculate kVA
instead.
Calculated kVA = 3 Vab I3Avg 1000
= 1.732 495 908 1000
= 778 kVA
•
•
•
Power meter reading is essentially zero compared to this value.
4-wire Case E looks similar.
Since the PTs were connected to other power meters which were reading correctly,
suspect two CT leads swapped.
•
•
Since A-phase power factor is the only one that has a normal looking lagging value,
suspect B and C-phase CT leads may be swapped.
After swapping B and C-phase CT leads, all readings went to the expected values;
problem solved.
78
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Appendix B—Register List
Appendix B—Register List
Register List Access
The register list corresponding to the latest firmware version can be found on line at the
Schneider Electric website.
1. Using a web browser, go to: www.Schneider-Electric.com.
2. Locate the Search box in the upper right corner of the home page.
3. In the Search box enter “PM8”.
4. In the drop-down box click on the selection “PM800 series”.
5. Locate the downloads area on the right side of the page and click on
“Software/Firmware”.
6. Click on the applicable register list then download the document file indicated.
In addition you will find the latest firmware files and a firmware history file that describes the
enhancements for each of the different firmware releases.
About Registers
bits are organized in a register.
Figure B–1: Bits in a register
High Byte
Low Byte
0
0
0
0
0
0
1
0
0
0
1
0
0
1
0
0
Bit No.
15 14 13 12 11 10 09 08 07 06 05 04 03 02 01
00
The power meter registers can be used with MODBUS or JBUS protocols. Although the
MODBUS protocol uses a zero-based register addressing convention and JBUS protocol
uses a one-based register addressing convention, the power meter automatically
compensates for the MODBUS offset of one. Regard all registers as holding registers
where a 30,000 or 40,000 offset can be used. For example, Current Phase A will reside in
register 31,100 or 41,100 instead of 1,100.
Floating-point Registers
Floating-point registers are also available. To enable floating-point registers, see “Enabling
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Appendix B—Register List
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How Date and Time are Stored in Registers
The date and time are stored in a three-register compressed format. Each of the three
registers, such as registers 1810 to 1812, contain a high and low byte value to represent
time it represents.
Table B–1: Date and Time Format
Register
Hi Byte
Lo Byte
Register 0
Month (1-12)
Day (1-31)
Register 1
Register 2
Year (0-199)
Minute (0-59)
Hour (0-23)
Second (0-59)
Table B–2 provides an example of the date and time. If the date was 01/25/00 at 11:06:59,
the Hex value would be 0119, 640B, 063B. Breaking it down into bytes we have the
following:
Table B–2: Date and Time Byte Example
Hexadecimal Value
Hi Byte
Lo Byte
0119
01 = month
19 = day
640B
063B
64 = year
0B = hour
06 = minute
3B = seconds
NOTE: Date format is a 3 (6-byte) register compressed format. (Year 2001 is represented
as 101 in the year byte.)
How Signed Power Factor is Stored in the Register
Each power factor value occupies one register. Power factor values are stored using
leading/lagging. A positive value (bit 15=0) always indicates leading. A negative value (bit
15=1) always indicates lagging. Bits 0–9 store a value in the range 0–1,000 decimal. For
example the power meter would return a leading power factor of 0.5 as 500. Divide by
1,000 to get a power factor in the range 0 to 1.000.
Figure B–2: Power Factor Register Format
15 14 13 12 11 10
9
8
7
6
5
4
3
2
1
0
0
0
0
0
0
Unused Bits
Set to 0
Power Factor
in the range 100-1000 (thousandths)
Sign Bit
0=Leading
1=Lagging
When the power factor is lagging, the power meter returns a high negative value—for
example, -31,794. This happens because bit 15=1 (for example, the binary equivalent of -
31,794 is 1000001111001110). To get a value in the range 0 to 1,000, you need to mask bit
15. You do this by adding 32,768 to the value. An example will help clarify.
Assume that you read a power factor value of -31,794. Convert this to a power factor in the
range 0 to 1.000, as follows:
-31,794 + 32,768 = 974
974/1,000 = .974 lagging power factor
80
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PowerLogicTM Series 800 Power Meter
Appendix B—Register List
Supported Modbus Commands
Table B–3 provides the Modbus commands that the PM800 Series meters support. For an
Table B–3: Modbus Commands
Command
Description
0x03
0x04
0x06
0x10
Read holding registers
Read input registers
Preset single registers
Preset multiple registers
Report ID
Return String
byte 1: 0x11
byte 2: number of bytes following without crc
byte 3: ID byte = 250
0x11
byte 4: status = 0xFF
bytes 5+: ID string = PM8xx Power Meter
last 2 bytes: CRC
Read device identification, BASIC implementation (0x00, 0x01, 0x02 data),
conformity level 1,
Object Values
0x01: If register 4128 is 0, then “Schneider Electric. If register 4128 is 1,
then “Square D”
0x2B
0x02: “PM8xx”
0x03: “Vxx.yyy” where xx.yyy is the OS version number. This is the
reformatted version of register 7001. If the value for register 7001 is 11900,
then the 0x03 data would be “V11.900”
Resetting Registers
Table B–4 provides the commands needed to reset many of the power meter features. You
can perform these resets simply by writing the commands into register 4126.
Table B–4: Register Listing—Reset Commands
Reset Commands—Write commands to Register 4126.
Command
666
Parameters
Notes
Restart demand metering
1115
Reset Meter
3211
Reset all alarms to default values
De-energize digital output
Energize digital output
3320
3321
3361
Reset digital output counter
Reset digital input counters
3365
Register Energy value to
7016
7017
7018
7019
7020
7021
4000
4001
4002
4003
4004
4005
6209
Preset Energy Values
10001
14255
21212
30078
Clear the Usage Timers. (Set to 0)
Reset all Min/Max Values. (Sets values to defaults)
Reset Peak Demand values. (Set to 0)
Clear all Energy Accumulators. (Set to 0)
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Appendix B—Register List
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Appendix C—Using the Command Interface
Appendix C—Using the Command Interface
Overview of the Command Interface
The power meter provides a command interface, which can be used to issue commands
that perform various operations such as controlling relays. Table C–1 lists the definitions for
memory at registers 8000–8149.
Table C–1: Location of the command interface
Register
Description
8000
This is the register where you write the commands.
These are the registers where you write the parameters for a
command. Commands can have up to 15 parameters associated with
them.
8001–8015
Command pointer. This register holds the register number where the
most recently entered command is stored.
8017
8018
8019
Results pointer. This register holds the register number where the
results of the most recently entered command are stored.
I/O data pointer. Use this register to point to data buffer registers
where you can send additional data or return data.
These registers are for you (the user) to write information. Depending
on which pointer places the information in the register, the register can
contain status (from pointer 8017), results (from pointer 8018), or data
(from pointer 8019). The registers will contain information such as
whether the function is enabled or disabled, set to fill and hold, start
and stop times, logging intervals, and so forth.
8020–8149
By default, return data will start at 8020 unless you specify otherwise.
When registers 8017 through 8019 are set to zero, no values are returned. When any or all
of these registers contain a value, the value in the register “points” to a target register,
which contains the status, error code, or I/O data (depending on the command) when the
NOTE: You determine the register location where results will be written. Therefore, take
care when assigning register values in the pointer registers; values may be corrupted when
two commands use the same register.
Figure C–1: Command interface pointer registers
Register 8017 8020
(status of the
last command)
1
Register 8020
Register 8021
Register 8022
Register 8018 8021
Register 8019 8022
(error code caused by
the last command)
51
0
(data returned by the
last command)
Refer to “Register List Access” on page 79 for instructions on accessing the complete register list.
83
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Appendix C—Using the Command Interface
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Issuing Commands
To issue commands using the command interface, follow these general steps:
1. Write the related parameter(s) to the command parameter registers 8001–15.
2. Write the command code to command interface register 8000.
If no parameters are associated with the command, then you need only to write the
the command interface into register 8000. Some commands have an associated register
where you write parameters for that command. For example, when you write the parameter
9999 to register 8001 and issue command code 3351, all relays will be energized if they are
set up for external control.
Table C–2: Command Codes
Command
Command
Code
Parameter
Register
Parameters
Description
Causes soft reset of the unit (re-initializes the
power meter).
1110
1210
1310
None
None
None
None
Clears the communications counters.
Sets the system date and time. Values for the
registers are:
8001
8002
8003
8004
8005
8006
Month
Day
Month (1–12)
Day (1–31)
Year
Year (4-digit, for example 2000)
Hour (Military time, for example 14 = 2:00pm)
Minute (1–59)
Hour
Minute
Second
Second (1–59)
1410
1411
None
None
None
None
Disables the revenue security switch
Enables the revenue security switch
Relay Outputs
3310
3311
3320
3321
8001
8001
8001
8001
Relay Output Number ➀ Configures relay for external control.
Relay Output Number ➀ Configures relay for internal control.
Relay Output Number ➀ De-energizes designated relay.
Relay Output Number ➀ Energizes designated relay.
Releases specified relay from latched
condition.
3330
8001
Relay Output Number ➀
3340
3341
3350
3351
3361
3362
3363
3364
8001
8001
8001
8001
8001
8001
8001
8001
Relay Output Number ➀ Releases specified relay from override control.
Relay Output Number ➀ Places specified relay under override control.
9999
9999
De-energizes all relays.
Energizes all relays.
Relay Output Number ➀ Resets operation counter for specified relay.
Relay Output Number ➀ Resets the turn-on time for specified relay.
None
None
Resets the operation counter for all relays.
Resets the turn-on time for all relays.
Resets the operation counter for specified
input.
3365
8001
Input Number ➀
3366
3367
3368
3369
3370
3371
3380
3381
8001
8001
8001
8001
8001
8001
8001
8002
Input Number ➀
None
Resets turn-on time for specified input.
Resets the operation counter for all inputs.
Resets turn-on time for all inputs.
None
None
Resets all counters and timers for all I/Os.
Analog Output Number ➀ Disables specified analog output.
Analog Output Number ➀ Enables specified analog output.
9999
9999
Disables all analog outputs.
Enables all analog outputs.
➀ You must write to register 8001 the number that identifies which output you would like to use. To determine
➁ Data buffer location (register 8019) is the pointer to the first register where data will be stored. By default,
return data begins at register 8020, although you can use any of the registers from 8020–8149. Take care when
assigning pointers. Values may be corrupted if two commands are using the same register.
Refer to “Register List Access” on page 79 for instructions on accessing the complete register list.
84
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Appendix C—Using the Command Interface
Table C–2: Command Codes
Command
Command
Parameter
Parameters
Description
Code
Register
Resets
1522
None
8001
None
Resets the alarm history log.
Resets min/max.
0 = Present and previous
months
4110
1 = Present month
2 = Previous month
None
5110
5111
5113
5114
None
None
None
None
Resets all demand registers.
Resets current demand.
Resets power demand.
Resets input demand.
None
None
None
Resets generic demand for first group of 10
quantities.
5115
None
None
5210
5211
5213
5214
5215
None
None
None
None
None
None
None
None
None
None
Resets all min/max demand.
Resets current min/max demand.
Resets power min/max demand.
Resets input min/max demand.
Resets generic 1 min/max demand.
Start new demand interval.
Bit 0 = Power Demand
5910
6209
8001
8019
Bitmap
1 = Current Demand
2 = Input Metering Demand
3 = Generic Demand Profile
Preset Accumulated Energies
Requires the IO Data Pointer to point to
registers where energy preset values are
entered. All Accumulated energy values must
be entered in the order in which they occur in
registers 1700 to 1727.
I/O Data Pointer ➁
6210
6211
6212
6213
6214
None
None
None
None
None
None
None
None
None
None
Clears all energies.
Clears all accumulated energy values.
Clears conditional energy values.
Clears incremental energy values.
Clears input metering accumulation.
Resets the following parameters to IEEE or
IEC defaults:
1. Phase labels
2. Menu labels
3. Harmonic units
4. PF sign
1 = IEEE
2 = IEC
6215
None
5. THD denominator
6. Date Format
6320
6321
6910
None
None
None
None
None
None
Disables conditional energy accumulation.
Enables conditional energy accumulation.
Starts a new incremental energy interval.
Files
Triggers data log entry. Bitmap where Bit 0 =
Data Log 1, Bit 1 = Data Log 2, Bit 2 = Data
Log 3, etc.
7510
7511
8001
8001
1–3
File Number
Triggers single data log entry.
➀ You must write to register 8001 the number that identifies which output you would like to use. To determine
the identifying number, refer to“I/O Point Numbers” on page 86 for instructions.
➁ Data buffer location (register 8019) is the pointer to the first register where data will be stored. By default,
return data begins at register 8020, although you can use any of the registers from 8020–8149. Take care when
assigning pointers. Values may be corrupted if two commands are using the same register.
Refer to “Register List Access” on page 79 for instructions on accessing the complete register list.
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Appendix C—Using the Command Interface
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Table C–2: Command Codes
Command
Parameter
Register
Command
Code
Parameters
Description
Setup
9020
None
8001
None
Enter into setup mode.
Exit setup mode and save all changes.
1 = Save
9021
2 = Do not save
➀ You must write to register 8001 the number that identifies which output you would like to use. To determine
the identifying number, refer to“I/O Point Numbers” on page 86 for instructions.
➁ Data buffer location (register 8019) is the pointer to the first register where data will be stored. By default,
return data begins at register 8020, although you can use any of the registers from 8020–8149. Take care when
assigning pointers. Values may be corrupted if two commands are using the same register.
Refer to “Register List Access” on page 79 for instructions on accessing the complete register list.
I/O Point Numbers
All inputs and outputs of the power meter have a reference number and a label that
correspond to the position of that particular input or output.
•
•
•
The reference number is used to manually control the input or output with the command
interface.
The label is the default identifier that identifies that same input or output. The label
appears on the display, in PowerLogic software, and on the option card.
See Table C–3 for a complete list of I/O Point Numbers
Table C–3: I/O Point Numbers
Module
Standard I/O
PM8M22 PM8M26 PM8M2222
I/O Point Number
KY
S1
1
2
—
—
—
—
A-R1
A-R2
A-S1
A-S2
A-S3
A-S4
A-S5
A-S6
A-R1
A-R2
A-S1
3
4
5
6
7
8
9
10
A-R1
A-R2
A-S1
A-S2
A-S2
A
B
—
—
A-AI1
A-AI2
A-AO1
A-AO2
B-R1
B-R2
B-S1
B-S2
B-S3
B-S4
B-S5
B-S6
B-R1
B-R2
B-S1
11
12
13
14
15
16
17
18
B-R1
B-R2
B-S1
B-S2
B-S2
B-AI1
B-AI2
B-AO1
B-AO2
Operating Outputs from the Command Interface
To operate an output from the command interface, first identify the relay using the I/O point
number. Then, set the output to external control. For example, to energize output 1, write
the commands as follows:
1. Write number 1 to register 8001.
2. Write command code 3310 to register 8000 to set the relay to external control.
3. Write command code 3321 to register 8000.
command code 3310 sets the relay to external control and command code 3321 is listed as
the command used to energize a relay. Command codes 3310–3381 are for use with inputs
and outputs.
Refer to “Register List Access” on page 79 for instructions on accessing the complete register list.
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Appendix C—Using the Command Interface
Using the Command Interface to Change Configuration Registers
You can also use the command interface to change values in selected metering-related
registers, such as setting the time of day of the clock or resetting generic demand.
Two commands, 9020 and 9021, work together as part of the command interface
procedure when you use it to change power meter configuration. You must first issue
command 9020 to enter into setup mode, change the register, and then issue 9021 to save
your changes and exit setup mode.
Only one setup session is allowed at a time. While in this mode, if the power meter detects
more than two minutes of inactivity, that is, if you do not write any register values or press
any buttons on the display, the power meter will time out and restore the original
configuration values. All changes will be lost. Also, if the power meter loses power or
communications while in setup mode, your changes will be lost.
The general procedure for changing configuration registers using the command interface is
as follows:
1. Issue command 9020 in register 8000 to enter into setup mode.
2. Make changes to the appropriate register by writing the new value to that register.
Perform register writes to all registers that you want to change. For instructions on
3. To save the changes, write the value 1 to register 8001.
NOTE: Writing any other value except 1 to register 8001 lets you exit setup mode
without saving your changes.
4. Issue command 9021 in register 8000 to initiate the save and reset the power meter.
For example, the procedure to change the demand interval for current is as follows:
1. Issue command code 9020 in register 8000.
2. Write the new demand interval to register 1801.
3. Write 1 to register 8001.
4. Issue command code 9021 in register 8000.
register list.
Conditional Energy
Power meter registers 1728–1744 are conditional energy registers.
Conditional energy can be controlled in one of two ways:
•
Over the communications link, by writing commands to the power meter’s command
interface, or
•
By a digital input—for example, conditional energy accumulates when the assigned
digital input is on, but does not accumulate when the digital input is off.
The following procedures explain how to set up conditional energy for command interface
control and for digital input control. The procedures refer to register numbers and command
codes. For a listing of command codes, see Table C–2 on page 84.
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Appendix C—Using the Command Interface
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Command Interface Control
•
Set Control—To set control of conditional energy to the command interface:
1. Write command code 9020 to register 8000.
2. In register 3227, set bit 6 to 1 (preserve other bits that are ON).
3. Write 1 to register 8001.
4. Write command code 9021 to register 8000.
•
•
•
•
Start— To start conditional energy accumulation, write command code 6321 to register
8000.
Verify Setup—To verify proper setup, read register 1794. The register should read 1,
indicating conditional energy accumulation is ON.
Stop—To stop conditional energy accumulation, write command code 6320 to register
8000.
Clear—To clear all conditional energy registers (1728-1747), write command code
6212 to register 8000.
Digital Input Control
•
Set Control—To configure conditional energy for digital input control:
1. Write command code 9020 to register 8000.
2. In register 3227, set bit 6 to 0 (preserve other bits that are ON).
3. Configure the digital input that will drive conditional energy accumulation. For the
appropriate digital input, write 3 to the Base +9 register.
4. Write 1 to register 8001.
5. Write command code 9021 to register 8000.
•
•
Clear—To clear all conditional energy registers (1728–1747), write command code
6212 to register 8000.
Verify Setup—To verify proper setup, read register 1794. The register should read 0
when the digital input is off, indicating that conditional energy accumulation is off. The
register should read 1 when conditional energy accumulation is on.
Incremental Energy
The power meter’s incremental energy feature allows you to define a start time, end time,
and time interval for incremental energy accumulation. At the end of each incremental
energy period, the following information is available:
•
•
•
•
•
•
•
•
•
•
•
•
Wh IN during the last completed interval (reg. 1748–1750)
VARh IN during the last completed interval (reg. 1751–1753)
Wh OUT during the last completed interval (reg. 1754–1756)
VARh OUT during the last completed interval (reg. 1757–1759)
VAh during the last completed interval (reg. 1760–1762)
Date/time of the last completed interval (reg. 1763–1765)
Peak kW demand during the last completed interval (reg. 1940)
Date/Time of Peak kW during the last completed interval (reg. 1941–1943)
Peak kVAR demand during the last completed interval (reg. 1945)
Date/Time of Peak kVAR during the last completed interval (reg. 1946–1948)
Peak kVA demand during the last completed interval (reg. 1950)
Date/Time of Peak kVA during the last completed interval (reg. 1951–1953)
The power meter can log the incremental energy data listed above. This logged data
provides all the information needed to analyze energy and power usage against present or
future utility rates. The information is especially useful for comparing different time-of-use
rate structures.
When using the incremental energy feature, remember that peak demands help minimize
the size of the data log in cases of sliding or rolling demand. Shorter incremental energy
periods make it easier to reconstruct a load profile analysis.
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Appendix C—Using the Command Interface
Using Incremental Energy
Incremental energy accumulation begins at the specified start time and ends at the
specified end time. When the start time arrives, a new incremental energy period begins.
The start and end time are specified in minutes from midnight. For example:
Interval: 420 minutes (7 hours)
Start time: 480 minutes (8:00 a.m.)
End time = 1440 minutes (12:00 p.m.)
The first incremental energy calculation will be from 8:00 a.m. to 3:00 p.m. (7 hours) as
third interval will be from 10 p.m. to 12:00 p.m. because 12:00 p.m. is the specified end
time. A new interval will begin on the next day at 8:00 a.m. Incremental energy
accumulation will continue in this manner until the configuration is changed or a new
interval is started by a remote master.
Figure C–2: Incremental energy example
End Time
12
11
1
10
2
4
9
3
8
Start Time
r
7
5
6
1st Interval (7 hours) = 8:00 a.m. to 3:00 p.m
2nd Interval (7 hours) = 3:00 p.m. to 10:00 p.m
3rd Interval (2 hours) = 10:00 p.m. to 12:00 p.m
•
Set up—To set up incremental energy:
1. Write command code 9020 to register 8000.
2. In register 3230, write a start time (in minutes-from-midnight).
3. For example, 8:00 am is 480 minutes.
4. In register 3231, write an end time (in minutes-from-midnight).
5. Write the desired interval length, from 0–1440 minutes, to register 3229.
6. If incremental energy will be controlled from a remote master, such as a
programmable controller, write 0 to the register.
7. Write 1 to register 8001.
8. Write command code 9021 to register 8000.
•
Start—To start a new incremental energy interval from a remote master, write
command code 6910 to register 8000.
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Appendix C—Using the Command Interface
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Setting Up Individual Harmonic Calculations
The PM810 with a PM810LOG can perform up to the 31st harmonic magnitude and angle
calculations for each metered value and for each residual value. The Power Meter can
perform harmonic magnitude and angle calculations for each metered value and for each
residual value. The harmonic magnitude for current and voltage can be formatted as either
a percentage of the fundamental (THD), as a percentage of the rms values (thd), or rms.
The harmonic magnitude and angles are stored in a set of registers: 13,200–14,608. During
the time that the power meter is refreshing harmonic data, the power meter posts a value of
0 in register 3246. When the set of harmonic registers is updated with new data, the power
meter posts a value of 1 in register 3246. The power meter can be configured to hold the
values in these registers for up to 60 metering update cycles once the data processing is
complete.
The power meter has three operating modes for harmonic data processing: disabled,
magnitude only, and magnitude and angles. Because of the extra processing time
necessary to perform these calculations, the factory default operating mode is magnitudes
only.
Table C–4: Registers for Harmonic Calculations
Reg No.
Value
Description
Harmonic processing;
0 = disabled
3240
0, 1, 2
1 = magnitudes only enabled
2 = magnitudes and angles enabled
Harmonic magnitude formatting for voltage;
0 = % of fundamental (default)
1 = % of rms
3241
3242
0, 1, 2
0, 1, 2
2 = rms
Harmonic magnitude formatting for current;
0 = % of fundamental (default)
1 = % of rms
2 = rms
This register shows the harmonics refresh interval
(default is 30 seconds).
3243
3244
10–60 seconds
0–60 seconds
This register shows the time remaining before the
next harmonic data update.
This register indicates whether harmonic data
processing is complete:
3245
0,1
0 = processing incomplete
1 = processing complete
Refer to “Register List Access” on page 79 for instructions on accessing the complete register list.
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Appendix C—Using the Command Interface
Changing Scale Factors
The power meter stores instantaneous metering data in 16-bit single registers. A value held
in each register must be an integer between –32,767 and +32,767. Because some values
for metered current, voltage, and power readings fall outside this range, the power meter
uses multipliers, or scale factors. This enables the power meter to extend the range of
metered values that it can record.
The power meter stores these multipliers as scale factors. A scale factor is the multiplier
expressed as a power of 10. For example, a multiplier of 10 is represented as a scale factor
1
2
of 1, since 10 =10; a multiplier of 100 is represented as a scale factor of 2, since 10 =100.
You can change the default value of 1 to other values such as 10, 100, or 1,000. However,
these scale factors are automatically selected when you set up the power meter, either
from the display or by using PowerLogic software.
If the power meter displays “overflow” for any reading, change the scale factor to bring the
reading back into a range that fits in the register. For example, because the register cannot
store a number as large as 138,000, a 138 kV system requires a multiplier of 10. 138,000 is
converted to 13,800 x 10. The power meter stores this value as 13,800 with a scale factor
1
of 1 (because 10 =10).
Scale factors are arranged in scale groups. You can use the command interface to change
scale factors on a group of metered values. However, be aware of these important points if
you choose to change scale factors:
•
We strongly recommend that you do not change the default scale factors, which are
automatically selected by PowerLogic hardware and software.
•
When using custom software to read power meter data over the communications link,
you must account for these scale factors. To correctly read any metered value with a
scale factor other than 0, multiply the register value read by the appropriate power of 10.
•
As with any change to basic meter setup, when you change a scale factor, all min/max
and peak demand values should be reset.
Enabling Floating-point Registers
For each register in integer format, the power meter includes a duplicate set of registers in
floating-point format. The floating point registers are disabled by default, but they can be
turned ON by doing the following:
write registers.
1. Read register 11700 (Current Phase A in floating-point format). If floating-point registers
are OFF, you will see -32,768.
2. Write command code 9020 to register 8000.
3. Write 1 to register 3248.
4. Write 1 to register 8001.
5. Write command code 9021 to register 8000.
6. Read register 11700. You will see a value of 1, which indicates floating-point registers
are ON.
NOTE: Values such as current phase A are not shown in floating-point format on the
display even though floating-point registers are ON. To view floating-point values, read the
floating-point registers using the display or PowerLogic software.
Refer to “Register List Access” on page 79 for instructions on accessing the complete register list.
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Appendix C—Using the Command Interface
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Appendix D—Advanced Power Quality Evaluations
Appendix D—Advanced Power Quality Evaluations
The information in this appendix applies to the following models:
•
•
PM850—EN50160 (evaluation only)
PM870—EN50160, ITI (CBEMA), and SEMI-F47
Power Quality Standards
The Advanced Power Quality feature includes power quality (PQ) evaluations according to
the European standard EN50160 and the SEMI-F47/ITI (CBEMA) specifications. The
PM870 registers data under both standards. The PM850 can report data under the
EN50160 standard only. For instructions on how to enable these evaluation features, see
SEMI-F47/ITI (CBEMA) Specification
The SEMI-F47-200 Specification for Semiconductor Processing Equipment Voltage Sag
Immunity was approved by the Global Facilities Committee and is the direct responsibility
of the North American Facilities Committee. This standard is very similar to the Information
Technical Industry (ITI) Council standard.
Semiconductor factories require high levels of power quality due to the sensitivity of
equipment and process controls. Semiconductor processing equipment is especially
vulnerable to voltage sags.
The SEMI-F47 standard addresses specifications for semiconductor processing equipment
voltage sag immunity. It does not include over-voltage conditions, voltage sag durations
less than 0.05 seconds (50 milliseconds), or voltage sag duration greater than 1.0 seconds.
If necessary, the ITI CBEMA-curve can be used to specify additional requirements.
Refer to the Schneider Electric POWERLOGIC Web Pages Instruction Bulletin (document
# 63230-304-207) for more information on using the web pages on the ECC to view
SEMI-47 and ITI(CBEMA) data.
Table D–1: Categorized disturbance levels (% of nominal)
Sag levels
Swell levels
80% — 90%
70% — 80%
40% — 70%
0% — 40%
110% — 120%
120% — 140%
140% — 200%
200% — 500%
Table D–2: Duration categories
Duration
< 20 msec
20 msec — 500 msec
500 msec — 10 sec
>10 sec
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Appendix D—Advanced Power Quality Evaluations
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Figure D–1: ITI (CBEMA) Curve
ITI (CBEMA) Curve
500
400
300
Prohibited Region
Voltage Tolerance Envelope
Applicable to 120, 120/208,
and 120/240 Nominal Voltages
200
140
120
100
110
90
No Interruption In Function Region
80
70
40
0
No Damage Region
Steady
State
0.5 s
20 ms
10 s
Duration in Seconds (s)
Table D–3: Categorized disturbance levels (F-47)
Sag levels
80% — 90%
70% — 80%
50% — 70%
0% — 50%
Table D–4: Duration categories
Duration
< 50 msec
50 msec — 200 msec
200 msec — 500 msec
500 msec — 1000 msec
>1000 msec
Figure D–2: Voltage Sag ride-through capability
Duration of Voltage Sag in Seconds
0.05
100
0.10
0.20
0.50
1.00
90
80
70
60
50
40
30
20
10
0
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Appendix D—Advanced Power Quality Evaluations
EN50160:2000 Specification
EN50160:2000 “Voltage characteristics of electricity supplied by public distribution systems”
is a European standard that defines the quality of the voltage a customer can expect from
the electric utility. Although this is a European standard, it can be applied globally.
The PM850 and the PM870 evaluates the following electrical characteristics in accordance
with EN50160:
Table D–5: EN50160 Evaluation for the PM850 and PM870
Feature
PM850
PM870
Evaluation During Normal Operation (Meter-based Data)
Frequency
3
3
3
3
3
3
Supply voltage variations
Supply voltage unbalance
Harmonic voltage
3
3
3
3
Total Harmonic Distortion
➀
Evaluations During Abnormal Operations (Alarm-based Data)
Magnitude of rapid voltage changes
Supply voltage dips
3
3
➁
➁
3
3
3
3
3
➁
➁
➁
➁
Short interruptions of the supply voltage
Long interruptions of the supply voltage
Temporary power frequency over-voltages
3
➁
3
➁
3
➀ The PM850 performs EN50160 evaluations based on standard alarms, while the
PM870 performs EN50160 evaluations on disturbance alarms.
for a list of configuration and status registers.
PM870 can be divided into two categories. The first category performs evaluations during
normal operation utilizing meter data. The second category performs evaluations during
abnormal operation utilizing either standard alarms (PM850) or disturbance alarms (PM870).
The EN50160:2000 Specification sets limits for most of the evaluations. These limits are
built into the PM850 and the PM870 firmware. You can configure registers for other
evaluations and change them from the default values.
How Evaluation Results Are Reported
The PM850 and the PM870 reports evaluation data in register entries and alarm log
Table D–6: Register Entries
Register
Description
Number
Summary bitmap of active evaluations that reports which areas
of evaluation are active in the PM850 and the PM870.
3910
Summary bitmap of evaluation status that reports the pass/fail
status of each area of evaluation.
3911
Detail bitmap of evaluation status that reports the pass/fail status
of the evaluation of each individual data item. Detailed data
summary information is also available for each of the evaluations
Portal registers
for the present interval and for the previous interval. You can
access this data over a communications link using Modbus block
reads of “portal” registers. Refer to “Evaluation During Normal
Log entries for the evaluation data include:
•
On-board alarm log entry for diagnostic alarms: When the status of an area of
evaluation is outside the range of acceptable values, an entry is made in the on-board
alarm log. This entry provides notification of the exception for a specific area of
evaluation. This notification is reported only in PowerLogic software and does not
appear on the local display.
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•
On-board alarm log entry for alarms: PM850 and the PM870 alarms are used to
perform some of the evaluations. If an on-board alarm log is enabled, an entry will be
made in the on-board alarm log when any of these alarms pick up or drop out.
NOTE: Enabling PQ Advanced evaluation does not guarantee that the on-board alarm log
or waveform files are enabled or properly configured to record these events. You should
consider your requirements and configure these files and the event captures triggered by
the various alarms to provide any additional data that would be helpful to diagnose or
document an exception to this standard.
Possible Configurations Through Register Writes
This section describes the changes you can make to configurations for the EN50160
evaluation through register writes in the PM850 and the PM870. Refer to “Advanced
•
Select the first day of the week for evaluations. You can define the first day of the
week to be used for the EN50160 evaluations in register 3905.
•
Define the voltage interruption. The standard defines an interruption as voltage less
than 1% of nominal voltage. Because some locations require a different definition, you
can configure this value in register 3906.
•
Define allowable range of slow voltage variations. The standard defines the allowable
range of slow voltage variations to be ±10% of nominal voltage. Because some locations
require a different definition, you can configure this value in register 3907.
1
Evaluation During Normal Operation
When the EN50160 evaluation is enabled, the PM850 and the PM870 evaluates metered
data under normal operating conditions, “excluding situations arising from faults or voltage
interruptions.” For this evaluation, normal operating conditions are defined as all phase
voltages greater than the definition of interruption. The standard specifies acceptable
ranges of operation for these data items.
This section describes how the EN50160 standard addresses metered data.
Power Frequency
EN50160 states that the nominal frequency of the supply voltage shall be 50 Hz. Under
normal operating conditions, the power meter will perform the valuation based on the
nominal frequency set on the meter.
•
for systems with synchronous connection to an interconnected system:
— 50 Hz 1% during 99.5% of a year
— 50 Hz + 4 to -6% for 100% of the time
•
for systems with no synchronous connection to an interconnected system (for example,
power systems on some islands):
— 50 Hz 2% during 95% of a week
— 50 Hz 15% for 100% of the time
NOTE: The same range of percentages are used for 60 Hz systems.
Supply Voltage Variations
EN50160 states that, under normal operating conditions, excluding situations arising from
faults or voltage interruptions:
•
during each period of one week 95% of the ten minute mean rms values of the supply
voltage shall be within the range of U 10%.
n
•
all ten minute mean rms values of the supply voltage shall be within the range of U
+10% to -15%.
n
1
EN 50160:2000, Voltage characteristics of electricity supplied by public distribution systems.
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Appendix D—Advanced Power Quality Evaluations
Supply Voltage Unbalance
EN50160 states that, under normal operating conditions, during each period of one week,
95% of the ten minute mean rms values of the negative phase sequence component of the
supply voltage shall be within the range 0–2% of the positive phase sequence component.
Harmonic Voltage
EN50160 states that, under normal operating conditions, during each period of one week,
95% of the ten minute mean rms values of each individual harmonic voltage shall be less
shall be less than 8%.
Table D–7: Values of individual harmonic voltages at the supply terminals for orders up
to 25 in % of nominal voltage
Odd Harmonics
Even Harmonics
Not Multiples of 3
Multiples of 3
Relative
Relative
Relative
Voltage
Order h
Order h
Order h
Voltage
6%
Voltage
5%
5
3
9
2
4
2%
1%
7
5%
1.5%
0.5%
0.5%
11
13
17
19
23
25
3.5%
3%
15
21
6...24
0.5%
2%
1.5%
1.5%
NOTE: No values are given for harmonics of order higher than 25, as they are usually small, but largely
unpredictable because of resonance effects.
Evaluations During Abnormal Operation
Count of Magnitude of Rapid Voltage Changes
The standard does not specify the rate of change of the voltage for this evaluation. For this
evaluation, the PM850 and the PM870 counts a change of 5% nominal and 10%
nominal from one one-second meter cycle to the next one-second meter cycle. It counts
rapid voltage decreases and increases separately. The interval for accumulation of these
events is one week.
You can configure the number of allowable events per week in register 3917.
(Default = -32768 = Pass/Fail evaluation disabled.)
Detection and Classification of Supply Voltage Dips
According to EN50160, voltage dips are generally caused by faults in installations or the
electrical utility distribution system. The faults are unpredictable and frequency varies
depending on the type of power system and where events are monitored.
Under normal operating conditions, the number of voltage dips expected may be anywhere
from less than a hundred to nearly a thousand. The majority of voltage dips last less than
one second with a depth less than 60%. However, voltage dips of greater depth and
duration can occasionally occur. In some regions, voltage dips with depths between 10%
and 15% of the nominal voltage are common because of the switching of loads at a
customer’s installation.
Supply voltage dips are under-voltage events that last from 10 ms to 1 minute. Magnitudes
are the minimum rms values during the event. Disturbance alarms are used to detect these
events in the PM870. Standard speed under-voltage alarms are used to detect these
events in the PM850. The standard does not specifically address how to classify supply
detect and classify the dips for each phase voltage.
97
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Appendix D—Advanced Power Quality Evaluations
63230-500-225A2
3/2011
Table D–8: Voltage dip classifications
Duration (t) seconds
1 t < 3
3 t < 10 10 t < 20 20 t < 60 60 t < 180
Total
Depth (D) % Nominal
10 D < 15
15 D < 30
30 D < 45
45 D < 60
60 D < 75
75 D < 90
90 D < 99
Total
You can configure the number of allowable events per week for each range of Depth in
registers 3920 – 3927. (Default = -32768 = Pass/Fail evaluation disabled.)
Detection of Interruptions of the Supply Voltage
The standard defines an interruption as voltage less than 1% of nominal voltage. Because
some locations require a different definition, you can configure this value in register 3906.
Interruptions are classified as “short” if duration 3 minutes or “long” otherwise. The
Table D–9: Voltage interruptions
Duration (t) seconds
5 t < 10 t < 20 t < 60 t < 180 t < 600 t <
t < 1
1 t < 2 2 t < 5
1200 t
10
20
60
180
600
1200
Total
You can configure the number of allowable short interruptions per year in register 3918
(Default = -32768 = Pass/Fail evaluation disabled). You can configure the number of
allowable long interruptions per year in register 3919. (Default = -32768 = Pass/Fail
evaluation disabled.)
Detecting and Classifying Temporary Power Frequency Over-voltages
As stated in EN50160, a temporary power frequency over-voltage generally appears during
a fault in the electrical utility power distribution system or in a customer’s installation, and
disappears when the fault is cleared. Usually, the over-voltage may reach the value of
phase-to-phase voltage because of a shift of the neutral point of the three-phase voltage
system.
Under certain circumstances, a fault occurring upstream from a transformer will produce
temporary over-voltages on the low voltage side for the time during which the fault current
flows. Such over-voltages will generally not exceed 1.5 kV rms.
each phase voltage.
NOTE: Disturbance alarms are used to detect these events in the PM870. In the PM850,
standard speed over-voltage alarms are used to detect these events.
Table D–10: Over-voltages
Duration (t) seconds
Magnitude (M) %
1 t < 3 3 t < 10 10 t < 20 20 t < 60 60 t < 180
Total
Nominal
110 < M 115
115 < M 130
130 < M 145
145 < M 160
160 < M 175
175 < M 200
M > 200
Total
You can configure the number of allowable events per week for each range of magnitude in
registers 3930 – 3937. (Default = -32768 = Pass/Fail evaluation disabled.)
98
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Appendix D—Advanced Power Quality Evaluations
Operation with PQ Advanced Enabled
This section describes how PM850 and PM870 EN50160 evaluation operation is affected
when PQ Advanced evaluation is enabled.
Resetting Statistics
You can reset statistics for the EN50160 evaluations with the command 11100. A
parameter value of 9999 will reset all items. A timestamp is provided in registers for each
item indicating when the last reset was performed. This command is disabled when
revenue security is active.
NOTE: You should reset statistics when you enable EN50160 for the first time and also
whenever you make any changes to the basic meter setup such as changing the nominal
Harmonic Calculations
When PQ Advanced evaluation is enabled, the harmonic calculations will be set to update
every 10 seconds. You can select the format of the harmonic calculations to be %Nominal,
%Fundamental, or %RMS.
Time Intervals
Time intervals are synchronized with the Trending and Forecasting feature. For additional
information, refer to the Schneider Electric POWERLOGIC Web Pages Instruction Bulletin
(document # 63230-304-207). Weekly values will be posted at midnight of the morning of
the “First Day of Week” configured in register 3905. Yearly values will be based on the
calendar year.
All of the EN50160 data is stored in non-volatile memory once per hour or when an event
occurs. In the event of a meter reset, up to one hour of routine meter evaluation data will be
lost.
Advanced Power Quality Evaluation System Configuration
and Status Registers [EN50160 and SEMI-F47/ITI (CBEMA)]
Table D–11 lists registers for system configuration and status evaluation.
Table D–11: PQ Advanced Evaluation System Configuration and Status Registers
Register Number Description
Enable/Disable PQ Advanced Evaluation
3900
3901
3902
3903
3904
1
1
1
1
1
0 = Disable (default)
1 = Enable
Nominal Voltage, (copied from register 3234 for reference)
Default = 230
Voltage Selection for 4-Wire Systems
0 = Line-to-Neutral (default)
1 = Line-to-Line
Nominal Frequency, Hz (copied from register 3208 for reference)
Default = 60
Frequency configuration
0 = system with synchronous connection to interconnected system (default)
1 = system without synchronous connection to interconnected system
First Day of Week (EN50160 only)
1 = Sunday
2 = Monday (default)
3 = Tuesday
3905
1
4 = Wednesday
5 = Thursday
6 = Friday
7 = Saturday
99
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Appendix D—Advanced Power Quality Evaluations
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3/2011
Table D–11: PQ Advanced Evaluation System Configuration and Status Registers
Register Number Description
Definition of Interruption (EN50160 only)
3906
3907
1
1
0 – 10% Nominal (default = 1)
Allowable Range of Slow Voltage Variations (EN50160 only)
1 – 20% Nominal (default = 10)
3908
3909
1
1
Reserved
Reserved
Bitmap of active evaluations
Bit 00 – Summary bit – at least one EN50160 evaluation is active
Bit 01 – Frequency
Bit 02 – Supply voltage variations
Bit 03 – Magnitude of rapid voltage changes
Bit 04 – Not used
Bit 05 – Supply voltage dips
Bit 06 – Short interruptions of the supply voltage
Bit 07 – Long interruptions of the supply voltage
Bit 08 – Temporary power frequency over-voltages
Bit 09 – Not used
3910
1
Bit 10 – Supply voltage unbalance
Bit 11 – Harmonic voltage
Bit 12 – THD
Bit 13 – Not used
Bit 14 – Not used
Bit 15 – Not used
Bitmap of evaluation status summary
Bit 00 – Summary bit – at least one EN50160 evaluation has failed.
Bit 01 – Frequency
Bit 02 – Supply voltage variations
Bit 03 – Magnitude of rapid voltage changes
Bit 04 – Not used
Bit 05 – Supply voltage dips
Bit 06 – Short interruptions of the supply voltage
Bit 07 – Long interruptions of the supply voltage
Bit 08 – Temporary power frequency over-voltages
Bit 09 – Not used
3911
1
Bit 10 – Supply voltage unbalance
Bit 11 – Harmonic voltage
Bit 12 – THD
Bit 13 – Not used
Bit 14 – Not used
Bit 15 – Not used
3912
3914
3916
2
2
1
Count of 10-second intervals present year
Count of 10-second intervals this week
Count of 10-minute intervals this week
Number of allowable rapid voltage changes per week
Default = -32768 = Pass/Fail evaluation disabled
Number of allowable short interruptions per year
Default = -32768 = Pass/Fail evaluation disabled
Number of allowable long interruptions per year
Default = -32768 = Pass/Fail evaluation disabled
Number of allowable voltage dips per week for each range of Depth
Default = -32768 = Pass/Fail evaluation disabled
3917
3918
3919
3920
3930
1
1
1
8
8
Number of allowable over-voltages per week for each range of Magnitude
Default = -32768 = Pass/Fail evaluation disabled
100
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Appendix D—Advanced Power Quality Evaluations
EN50160 Evaluation Data Available Over a Communications Link
Portal Registers
Evaluation data is available over communications via “portal” register reads. Each data
item is assigned a portal register number. A block read of the specified size at that address
will return the data for that item. In general, if the block size is smaller than specified, the
data returned will be 0x8000 (-32768) to indicate the data is invalid. If the block size is
larger than specified, the data for the item will be returned and the remaining registers will
Table D–12: Portal Register Descriptions
Portal
Description Size
Data
Register number of Metered Quantity (can be used to confirm data item
being reported)
Register value (present metered value)
Average value (at end of last completed averaging time period)
Minimum value during the last completed averaging time period
Maximum value during the last completed averaging time period
Minimum value during this interval
Maximum value during this interval
Minimum value during the last interval
Maximum value during the last interval
Summary of
53432 –
53434
Meter Data
Evaluations by
Item
Percent in Evaluation Range 1 this interval
33
Percent in Evaluation Range 2 this interval (when applicable)
Percent in Evaluation Range 1 last interval
Percent in Evaluation Range 2 last interval (when applicable)
Count of average values in Evaluation Range 1 (MOD10L2)
Count of average values in Evaluation Range 2 (MOD10L2)
Count of total valid averages for Evaluation of Range 1 (MOD10L2)
Count of total valid averages for Evaluation of Range 2 (MOD10L2)
Date/Time Last Excursion Range 1 (4-register format)
Date/Time Last Excursion Range 2 (4-register format)
Date/Time Last Reset (4-register format)
Count of rapid voltage increases this week
Count of rapid voltage decreases this week
Summary of
Rapid Voltage
Changes by
Phase
Count of rapid voltage increases last week
53435 –
53437
12
Count of rapid voltage decreases last week
Date/Time last rapid voltage change (4-register format)
Date/Time last reset (4-register format)
Count of dips by magnitude & duration this week (96 values) [See
Summary of
Voltage Dips
by Phase This
Week
53438 –
53440
104
Date/Time last voltage dip (4-register format)
Date/Time last reset (4-register format)
Count of dips by magnitude & duration last week (96 values) [See
Summary of
Voltage Dips
by Phase Last
Week
53441 –
53443
104
Date/Time last voltage dip (4-register format)
Date/Time last reset (4-register format)
Flag indicating interruption is active
Elapsed seconds for interruption in progress
Count of short interruptions this year
Count of long interruption this year
Summary of
Supply
Voltage
Interruptions
3-Phase and
by Phase
Count of short interruptions last year
Count of long interruptions last year
53444 –
53447
34
Count of interruptions by duration this year (10 values) [See “Detection of
Count of interruptions by duration last year (10 values) [See “Detection of
Date/Time of last interruption (4-register format)
Date/Time of last reset (4-register format)
101
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Appendix D—Advanced Power Quality Evaluations
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Table D–12: Portal Register Descriptions
Portal
Description Size
Data
Temporary
Power
Frequency
Over-voltages
by Phase This
Week
Count of over-voltages by magnitude & duration this week (96 values) [See
53448 –
53449
104
Date/Time last over-voltage (4-register format)
Date/Time last reset (4-register format)
Temporary
Power
Frequency
Over-voltages
by Phase Last
Week
Count of over-voltages by magnitude & duration last week (96 values) [See
53450 –
53452
104
Date/Time last over-voltage (4-register format)
Date/Time last reset (4-register format)
Register 2 – Bitmap of evaluation
Register 1 – Bitmap of active
status summary (same as register
evaluations (same as register 3910)
3911)
Bit set when evaluation is active
Bit set when evaluation fails
Bit 00 – Summary bit – at least one
Bit 00 – Summary bit – at least one
EN50160 evaluation is active
EN50160 evaluation has failed
Bit 01 – Frequency
Bit 01 – Frequency
Bit 02 – Supply voltage variations
Bit 02 – Supply voltage variations
Bit 03 – Magnitude of rapid voltage
Bit 03 – Magnitude of rapid voltage
changes
changes
Bit 04 – Not used
Bit 04 – Not used
Bit 05 – Supply voltage dips
Bit 05 – Supply voltage dips
Evaluation
Summary
Bitmap
Bit 06 – Short interruptions of the
Bit 06 – Short interruptions of the
supply voltage
53312
18
supply voltage
Bit 07 – Long interruptions of the
Bit 07 – Long interruptions of the
supply voltage
supply voltage
Bit 08 – Temporary power frequency
Bit 08 – Temporary power frequency
over-voltages
over-voltages
Bit 09 – Not used
Bit 09 – Not used
Bit 10 – Supply voltage unbalance
Bit 10 – Supply voltage unbalance
Bit 11 – Harmonic voltage
Bit 11 – Harmonic voltage
Bit 12 – THD
Bit 12 – THD
Bit 13 – Not used
Bit 13 – Not used
Bit 14 – Not used
Bit 14 – Not used
Bit 15 – Not used
Bit 15 – Not used
Register 3 (Range 1)/Register 11
(Range 2) – Bitmap of evaluation
status of individual evaluations
Register 4 (Range 1)/Register 12
(Range 2) – Bitmap of evaluation
status of individual evaluations
Bit 00 – Frequency
Bit 01 – Va
Bit 00 – Va H7
Bit 01 – Va H8
Bit 02 – Va H9
Bit 03 – Va H10
Bit 04 – Va H11
Bit 05 – Va H12
Bit 06 – Va H13
Bit 07 – Va H14
Bit 08 – Va H15
Bit 09 – Va H16
Bit 10 – Va H17
Bit 11 – Va H18
Bit 12 – Va H19
Bit 13 – Va H20
Bit 14 – Va H21
Bit 15 – Va H22
Bit 02 – Vb
Bit 03 – Vc
Bit 04 – Not used
Bit 05 – Not used
Bit 06 – Not used
Bit 07 – Voltage Unbalance
Bit 08 – THD Va
Bit 09 – THD Vb
Bit 10 – THD Vc
Bit 11 – Va H2
Bit 12 – Va H3
Bit 13 – Va H4
Bit 14 – Va H5
Bit 15 – Va H6
102
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Appendix D—Advanced Power Quality Evaluations
Table D–12: Portal Register Descriptions
Portal Description Size
Data
Register 5 (Range 1)/Register 13
(Range 2) – Bitmap of evaluation
status of individual evaluations
Register 6 (Range 1)/Register 14
(Range 2) – Bitmap of evaluation
status of individual evaluations
Bit 00 – Va H23
Bit 01 – Va H24
Bit 02 – Va H25
Bit 03 – Vb H2
Bit 04 – Vb H3
Bit 05 – Vb H4
Bit 06 – Vb H5
Bit 07 – Vb H6
Bit 08 – Vb H7
Bit 09 – Vb H8
Bit 10 – Vb H9
Bit 11 – Vb H10
Bit 12 – Vb H11
Bit 13 – Vb H12
Bit 14 – Vb H13
Bit 15 – Vb H14
Bit 00 – Vb H15
Bit 01 – Vb H16
Bit 02 – Vb H17
Bit 03 – Vb H18
Bit 04 – Vb H19
Bit 05 – Vb H20
Bit 06 – Vb H21
Bit 07 – Vb H22
Bit 08 – Vb H23
Bit 09 – Vb H24
Bit 10 – Vb H25
Bit 11 – Vc H2
Bit 12 – Vc H3
Bit 13 – Vc H4
Bit 14 – Vc H5
Bit 15 – Vc H6
Register 7 (Range 1)/Register 15
(Range 2) – Bitmap of evaluation
status of individual evaluations
Register 8 (Range 1)/Register 16
(Range 2) – Bitmap of evaluation
status of individual evaluations
Bit 00 – Vc H7
Bit 01 – Vc H8
Bit 02 – Vc H9
Bit 03 – Vc H10
Bit 04 – Vc H11
Bit 05 – Vc H12
Bit 06 – Vc H13
Bit 07 – Vc H14
Bit 08 – Vc H15
Bit 09 – Vc H16
Bit 10 – Vc H17
Bit 11 – Vc H18
Bit 12 – Vc H19
Bit 13 – Vc H20
Bit 14 – Vc H21
Bit 15 – Vc H22
Bit 00 – Vc H23
Bit 01 – Vc H24
Bit 02 – Vc H25
Bit 03 – V 3PH
Bit 04 – KW 3PH
Bit 05 – KVAR 3PH
Bit 06 – Ia
Bit 07 – Ib
Bit 08 – Ic
Bit 09 – Ia H3
Bit 10 – Ib H3
Bit 11 – Ic H3
Bit 12 – Ia H5
Bit 13 – Ib H5
Bit 14 – Ic H5
Bit 15 – Ia H7
Register 9 (Range 1)/Register 17
(Range 2) – Bitmap of evaluation
status of individual evaluations
Register 10 (Range 1)/Register 18
(Range 2) – Bitmap of evaluation
status of individual evaluations
Bit 00 – Ib H7
Bit 00 – Reserved
Bit 01 – Reserved
Bit 02 – Reserved
Bit 03 – Reserved
Bit 04 – Reserved
Bit 05 – Reserved
Bit 06 – Reserved
Bit 07 – Reserved
Bit 08 – Not used
Bit 09 – Not used
Bit 10 – Not used
Bit 11 – Not used
Bit 12 – Not used
Bit 13 – Not used
Bit 14 – Not used
Bit 15 – Not used
Bit 01 – Ic H7
Bit 02 – Ia H9
Bit 03 – Ib H9
Bit 04 – Ic H9
Bit 05 – Ia H11
Bit 06 – Ib H11
Bit 07 – Ic H11
Bit 08 – Ia H13
Bit 09 – Ib H13
Bit 10 – Ic H13
Bit 11 – Reserved
Bit 12 – Reserved
Bit 13 – Reserved
Bit 14 – Reserved
Bit 15 – Reserved
103
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Appendix D—Advanced Power Quality Evaluations
63230-500-225A2
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Alarms Allocated for PQ Advanced Evaluations
To accomplish some of the evaluations required and to provide a record of events in the
on-board alarm log, the PM850 uses standard alarms, and the PM870 uses disturbance
alarms. When the evaluation is enabled, certain alarm positions will be claimed and
automatically configured for use in the evaluation. You cannot use these alarms for other
purposes while the evaluation is enabled. These alarms include:
•
•
•
Over Voltage (PM850): Standard speed alarm positions 35-37
Under Voltage (PM850): Standard speed alarm positions 38-40
Disturbance for Voltage Swells and Sags (PM870): Disturbance alarm positions 1-3 and 7-9
NOTE: The position depends on the system type (register 3902).
“PQ Advanced” is included in the alarm label for alarms being used by this evaluation.
Setting Up PQ Advanced Evaluation from the Display
To set up the PQ Advanced evaluation in the power meter, you need to perform these
steps using the meter set-up procedure:
1. Enable the PQ Advanced evaluation.
By default, the PQ Advanced evaluation is disabled. To enable the evaluation, use the
2. Select the nominal voltage of your system.
NOTE: The EN50160 standard defines nominal voltage for low-voltage systems to be
230V line-to-line for 3-wire systems or 230V line-to-neutral for 4-wire systems.
Therefore, the default value for Nominal Voltage is 230.
If the application is a medium-voltage system, or if you want the evaluations to be
based on some other nominal voltage, you can configure this value using the display
only. PowerLogic software does not allow configuration of nominal voltage
3. Select the nominal frequency of your system.
NOTE: The EN50160 standard defines nominal frequency as 50 Hz, but the PM850 and
the PM870 can also evaluate 60 Hz systems. They cannot evaluate nominal frequency
for 400 Hz systems.
The default nominal frequency in the PM850 and the PM870 is 60 Hz. To change the
default, from the display Main Menu, select Setup > Meter > Frequency. From
PowerLogic software, see the online help file.
4. Reset the PQ Advanced Statistics.
a. Write 9999 in register 8001.
b. Write 11100 in register 8000.
5. Reset the ITI (CBEMA) and SEMI F-47 Statistics.
a. Write 9999 in register 8001.
b. Write 11200 in register 8000.
104
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PowerLogicTM Series 800 Power Meter
Glossary
Glossary
Terms
accumulated energy—energy can
event—the occurrence of an alarm
accumulate in either signed or unsigned condition, such as Under-voltage Phase
(absolute) mode. In signed mode, the
direction of power flow is considered,
and the accumulated energy magnitude
may increase and decrease. In absolute
mode, energy accumulates as a
positive, regardless of the power flow
direction.
A, configured in the power meter.
firmware—operating system within the
power meter.
fixed block—an interval selected from
1 to 60 minutes (in 1-minute
increments). The power meter
calculates and updates the demand at
the end of each interval.
active alarm—an alarm that has been
set up to trigger, when certain
conditions are met, the execution of a
task or notification. An icon in the
upper-right corner of the meter
indicates that an alarm is active (!).
See also enabled alarm and disabled
alarm.
float—a 32-bit floating point value
returned by a register (see Register List
on page 79). The upper 16-bits are in
the lowest-numbered register pair. For
example, in the register 4010/11, 4010
contains the upper 16-bits while 4011
contains the lower 16-bits.
baud rate—specifies how fast data is
transmitted across a network port.
frequency—number of cycles in one
second.
block interval demand— power
demand calculation method for a block line-to-line voltages—measurement of
of time. Includes three ways to apply
calculating to that block of time; sliding
block, fixed block, or rolling block
methods.
the rms line-to-line voltages of the circuit.
line-to-neutral voltages
—measurement of the rms line-to-
neutral voltages of the circuit.
communications link—a chain of
devices connected by a
communications cable to a
communications port.
maximum demand current—highest
demand current measured in amperes
since the last reset of demand.
maximum demand real power
—highest demand real power
measured since the last rest of
current transformer (CT)—current
transformer for current inputs.
demand—average value of a quantity, demand.
such as power, over a specified interval
of time.
maximum demand voltage—highest
demand voltage measured since the
last reset of demand voltage.
device address—defines where the
power meter resides in the power
monitoring system.
maximum demand (peak demand)
—highest average load during a
specific time interval.
disabled alarm—an alarm which has
been configured but which is currently
“turned off”; i.e, the alarm will not
execute its associated task even when
its conditions are met. See also enabled
alarm and active alarm.
maximum value—highest value
recorded of the instantaneous quantity
such as Phase A Current, Phase A
Voltage, etc., since the last reset of the
minimums and maximums.
enabled alarm—an alarm that has
been configured and “turned on” and
will execute its associated task when its
conditions are met. See also disabled
alarm and active alarm.
minimum value—lowest value
recorded of the instantaneous quantity
such as Phase A Current, Phase A
Voltage, etc., since the last reset of the
minimums and maximums.
105
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Glossary
63230-500-225A2
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nominal—typical or average.
sag/swell—fluctuation (decreasing or
increasing) in voltage or current in the
electrical system being monitored. See
also, voltage sag and voltage swell.
parity—refers to binary numbers sent
over the communications link. An extra
bit is added so that the number of ones
in the binary number is either even or
odd, depending on your configuration.
Used to detect errors in the
scale factor—multipliers that the power
meter uses to make values fit into the
register where information is stored.
transmission of data.
safety extra low voltage (SELV)
partial interval demand—calculation
circuit—a SELV circuit is expected to
of energy thus far in a present interval. always be below a hazardous voltage
Equal to energy accumulated thus far in level.
the interval divided by the length of the
short integer—a signed 16-bit integer
complete interval.
phase currents (rms)—measurement
sliding block—an interval selected
in amperes of the rms current for each
from 1 to 60 minutes (in 1-minute
of the three phases of the circuit. See
increments). If the interval is between 1
also maximum value.
and 15 minutes, the demand calculation
phase rotation—phase rotations refers updates every 15 seconds. If the
to the order in which the instantaneous interval is between 16 and 60 minutes,
values of the voltages or currents of the the demand calculation updates every
system reach their maximum positive
values. Two phase rotations are
possible: A-B-C or A-C-B.
60 seconds. The power meter displays
the demand value for the last
completed interval.
potential transformer (PT)—also
known as a voltage transformer
system type—a unique code assigned
to each type of system wiring
configuration of the power meter.
power factor (PF)—true power factor is
the ratio of real power to apparent
power using the complete harmonic
content of real and apparent power.
Calculated by dividing watts by volt
amperes. Power factor is the difference
between the total power your utility
delivers and the portion of total power
that does useful work. Power factor is
the degree to which voltage and current
to a load are out of phase.
thermal demand—demand calculation
based on thermal response.
Total Harmonic Distortion (THD or
thd)—indicates the degree to which the
volt-age or current signal is distorted in
a circuit.
total power factor—see power factor.
true power factor—see power factor.
unsigned integer—an unsigned 16-bit
page 79).
real power—calculation of the real
power (3-phase total and per-phase
real power calculated) to obtain
kilowatts.
unsigned long integer—an unsigned
32-bit value returned by a register
upper 16-bits are in the lowest-
rms—root mean square. Power meters
are true rms sensing devices.
rolling block—a selected interval and
numbered register pair. For example, in
sub-interval that the power meter uses the register pair 4010 and 4011, 4010
for demand calculation. The sub-
interval must divide evenly into the
interval. Demand is updated at each
sub-interval, and the power meter
displays the demand value for the last
completed interval.
contains the upper 16-bits while 4011
contains the lower 16-bits.
VAR—volt ampere reactive.
voltage sag—a brief decrease in
effective voltage for up to one minute in
duration.
voltage swell—increase in effective
voltage for up to one minute in duration.
106
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PowerLogicTM Series 800 Power Meter
Glossary
Abbreviations and Symbols
kVA—Kilovolt-Ampere
A—Ampere
kVAD—Kilovolt-Ampere demand
A IN—Analog Input
kVAR—Kilovolt-Ampere reactive
A OUT—Analog Output
ABSOL—Absolute Value
ACCUM—Accumulated
ACTIV—Active
kVARD—Kilovolt-Ampere reactive
demand
kVARH—Kilovolt-Ampere reactive hour
kW—Kilowatt
ADDR—Power meter address
ADVAN—Advanced screen
AMPS—Amperes
kWD—Kilowatt demand
kWH—Kilowatthours
kWH/P—Kilowatthours per pulse
kWMAX—Kilowatt maximum demand
LANG—Language
BARGR—Bargraph
COINC—Demand values occurring at
the same time as a peak demand value
LOWER—Lower Limit
COMMS—Communications
COND—Conditional Energy Control
CONTR—Contrast
MAG—Magnitude
MAINT—Maintenance screen
MAMP—Milliamperes
CPT—Control Power Transformer
MB A7—MODBUS ASCII 7 Bits
MB A8—MODBUS ASCII 8 Bits
MBRTU—MODBUS RTU
MIN—Minimum
CT—see current transformer on
DEC—Decimal
D IN—Digital Input
DIAG—Diagnostic
DISAB—Disabled
DISPL—Displacement
D OUT—Digital Output
DMD—Demand
MINS—Minutes
MINMX—Minimum and maximum
values
MSEC—Milliseconds
MVAh—Megavolt ampere hour
MVARh—Megavolt ampere reactive
hour
DO—Drop Out Limit
ENABL—Enabled
ENDOF—End of demand interval
ENERG—Energy
F—Frequency
MWh—Megawatt hour
NORM—Normal mode
O.S.—Operating System (firmware
version)
HARM—Harmonics
HEX—Hexadecimal
HIST—History
P—Real power
PAR—Parity
PASSW—Password
Pd—Real power demand
PF—Power factor
Ph—Real energy
PM—Power meter
HZ—Hertz
I—Current
I/O—Input/Output
IMAX—Current maximum demand
107
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PowerLogicTM Series 800 Power Meter
Glossary
63230-500-225A2
3/2011
PQS—Real, reactive, apparent power
PQSd—Real, reactive, apparent power
demand
PR—Alarm Priority
PRIM—Primary
PT—Number of voltage connections
PU—Pick Up Limit
PULSE—Pulse output mode
PWR—Power
Q—Reactive power
Qd—Reactive power demand
Qh—Reactive energy
R.S.—Firmware reset system version
RELAT—Relative value in %
REG—Register Number
S—Apparent power
S.N.—Power meter serial number
Sd—Apparent power demand
SECON—Secondary
SEC—Seconds
Sh—Apparent Energy
SUB-I—Sub-interval
THD—Total Harmonic Distortion
U—Voltage line to line
UNBAL—Unbalance
UPPER—Upper limit
V—Voltage
VAh—Volt amp hour
VARh—Volt amp reactive hour
VMAX—Maximum voltage
VMIN—Minimum voltage
Wh—Watthour
108
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TM
63230-500-225A2
3/2011
PowerLogic Series 800 Power Meter
Index
Index
clock
Numerics
A
command interface
communications
accumulate energy
address
alarm
alarm backlight
alarm levels
alarm log
conditional energy
CT
custom
alarms
D
date
EN50160 Evaluation
demand
demand power
analog input
diagnostic alarms
diagnostics
B
bar graph
C
calculating
changing
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TM
63230-500-225A2
3/2011
PowerLogic Series 800 Power Meter
Index
display
F
disturbance monitoring
floating-point registers
E
G
EN50160 Evaluation
accumulation
H
harmonic
calculations
I
depth
I/O
incremental energy interval
initialize
statistics
system configuration
input
input/output
inputs
K
L
labels
language
lock resets
M
maintenance
energy
equipment sensitivity
event log
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TM
63230-500-225A2
3/2011
PowerLogic Series 800 Power Meter
Index
memory
power meter
metered values
minimum/maximum
minimum/maximum values
with display
mode
monitoring
problems
protocols
PT
N
nominal frequency
nominal voltage
O
Q
quantities
R
readings
recording
operating time
operating time threshold
outputs
register writes
registers
P
password
phase loss
relay operating modes
phase rotation
pickups and dropouts
PLC
power demand configuration
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TM
63230-500-225A2
3/2011
PowerLogic Series 800 Power Meter
Index
relays
reset
T
testing
time
resets
time intervals
S
sag/swell
trending and forecasting
troubleshooting
U
V
set up
VAR
VAR/PF convention
voltage swell
W
watthours
waveform captures
wiring
synchronized demand
synchronizing
system type
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PowerLogic™ Power Meter 800 User Guide
PowerLogic is a trademark of Schneider Electric, Other trademarks are the property of their
respective owners.
Schneider Electric
295 Tech Park Drive, Suite 100
Lavergne, TN 37086 USA
Electrical equipment should be installed, operated, serviced, and maintained only by qualified
personnel. No responsibility is assumed by Schneider Electric for any consequences arising out of
the use of this material.
For technical support:
(00) + 1 250 544 3010
63230-500-225A2
Replaces 63230-500-225A1, dated
© 2006 - 2011 Schneider Electric All Rights Reserved
3/2011
6/2006
Contact your local Schneider Electric sales
representative for assistance or go to
www.schneider-electric.com
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