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L30 LINE CURRENT DIFFERENTIAL SYSTEM – INSTRUCTION MANUAL
SYSTEM SETUP
CHAPTER 5: SETTINGS
5
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GGIO1, which contains 16 digital status indication points and 16 analog points. The Analog GGIO values are selectable
from any FlexAnalog value in the UR.
When the first PMU from any LD is mapped into an aggregator, the aggregator inherits the Sample Rate (SmpRate) and
IEEE C37.118 Class (P or M) of that PMU. The value of the SmpRate DO in the Report Control Block is set based on the value
of the Sample Rate in the PMU. The Class of the Dataset are mapped into the MSVID of the Dataset (see text that follows for
the overall name of the MSVID). If other PMUs are mapped into the same aggregator with different Sample Rates or from
different classes, then a Self-Test error (DatSetErr) is set and dataset transmission is blocked.
A setting value — MSVID — is created with a maximum input range of 56 characters (=64 less 6 for the IDCode less 2 for the
Class).
The value of MSVID in the dataset is a concatenation of the aggregator IDCode and the MSVID setting value in the format:
MSVID-AggregatorIDCode-CLASS where CLASS is P, M, or N (for None) – depending on the Class of the first PMU included in
the Aggregator.
The UR also supports the option to apply no filtering to the synchrophasors. If no filtering is applied (PMU Class = None),
according to the standard, the ClcMth attribute is PRES. The semantic of the ClcMth used is not carried in the individual DO
and so it is recommended that one of letters of the prefix on the instantiated LNs be set to “P” or “M” accordingly in order
to differentiate. For firmware versions 7.0 and later, only FCDA data is supported. The PMU Implementation by UR Device
table earlier
indicates the maximum size of each PMU data set for version 7.2 and later using FCDA data (non-structured
data).
5.5.8.4 Example: Protection synchrophasors data set with reporting rate 60 frames/second
This example gives the protection synchrophasors data set with a reporting rate of 60 frames per second (P60MMXU1). See
the figure earlier, Logical Nodes Supported in Each Logical Device. This data or list of items, as shown in the following
figure, is not available to the UR setup program but is available to be mapped by the user into a selected aggregator or
aggregators dataset. The logical device name (LDName) of each PMU LD is a 64 character user setting. The IEEE C37.118
STN and IDCode is to be mapped as a concatenated value in the (d)escription field of LPL CDC of the NamPlt DO in LLN0.
The mapping is implemented as STN-IDCode (text string).
From each PMU, the user selects the phasor information of interest that is mapped into the selected aggregator datset(s).
For version 7.0 and later, only FCDA data is supported.
The Synchro Logical Nodes in an LD report at the same rate as set in the PMUn Basic Configuration setting. This is
reflected in the instantiation of the Data Object – SmpRate in the msvcb## of LLN0 in the LD1. SmpRate is a Read
Only Integer Status (INS).
Synchrophasor Rectangular Format and Integer data types are NOT supported in IEC 61850-90-5 (only supported
with IEEE C37.118) and not to set — GGIO1 that contains 16 digital status indication points — aggregated as a 16 bit
bitstring and 16 analog points. The Analog GGIO values are selectable from any FlexAnalog value in the UR. For
firmware versions 7.0 and later, the description fields for the phasors, analog, and digital channels are populated
with the 16 character name field provided within the Basic Configuration menu. Additionally, the names of the 16
binary points are implemented as numbered descriptions — d1, d2, d3, and so on. The number of descriptions are
equal to the number of bits configured in the 16 bit digital status word.
All bitstrings less than or equal to 32 bits in length map into a 32 bit bitstring in an IEC 61850-90-5 dataset.
The Value of the Nominal Frequency of the chassis is instantiated as a DO in LPHD of LD1. The value is named
HzNom and is an Integer Status (INS).
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Страница 14: ...1 4 L30 LINE CURRENT DIFFERENTIAL SYSTEM INSTRUCTION MANUAL FOR FURTHER ASSISTANCE CHAPTER 1 INTRODUCTION 1 ...
Страница 126: ...3 68 L30 LINE CURRENT DIFFERENTIAL SYSTEM INSTRUCTION MANUAL CONNECT TO D400 GATEWAY CHAPTER 3 INSTALLATION 3 ...
Страница 214: ...4 88 L30 LINE CURRENT DIFFERENTIAL SYSTEM INSTRUCTION MANUAL FLEXLOGIC DESIGN USING ENGINEER CHAPTER 4 INTERFACES 4 ...
Страница 582: ...7 16 L30 LINE CURRENT DIFFERENTIAL SYSTEM INSTRUCTION MANUAL TARGETS MENU CHAPTER 7 COMMANDS AND TARGETS 7 ...
Страница 598: ...9 6 L30 LINE CURRENT DIFFERENTIAL SYSTEM INSTRUCTION MANUAL TESTING CHAPTER 9 COMMISSIONING 9 ...
Страница 622: ...10 24 L30 LINE CURRENT DIFFERENTIAL SYSTEM INSTRUCTION MANUAL FAULT LOCATOR CHAPTER 10 THEORY OF OPERATION 10 ...
Страница 670: ...A 18 L30 LINE CURRENT DIFFERENTIAL SYSTEM INSTRUCTION MANUAL FLEXANALOG ITEMS APPENDIX A FLEXANALOG OPERANDS A ...
Страница 678: ...C 6 L30 LINE CURRENT DIFFERENTIAL SYSTEM INSTRUCTION MANUAL COMMAND LINE INTERFACE APPENDIX C COMMAND LINE INTERFACE C ...
Страница 682: ...D 4 L30 LINE CURRENT DIFFERENTIAL SYSTEM INSTRUCTION MANUAL REVISION HISTORY APPENDIX D MISCELLANEOUS D ...
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