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BSI PD IEC/TR 62689-100:2016

BSI PD IEC/TR 62689-100:2016

$215.11

Current and voltage sensors or detectors, to be used for fault passage indication purposes – Requirements and proposals for the IEC 61850 series data model extensions to support fault passage indicators applications

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BSI 2016 138
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This part of IEC 62689, which is a Technical Report, was prepared jointly with TC 57 with the scope to prepare requirements and proposals for the IEC 61850 series data model extensions to support fault passage indicators (all classes and extended functions) applications to be introduced in the future IEC 61850906 and that, in turn, will be needed for the preparation of the future IEC 62689-3.

PDF Catalog

PDF Pages PDF Title
4 CONTENTS
8 FOREWORD
10 INTRODUCTION
11 1 Scope
2 Normative references
3 Terms, definitions and abbreviated terms
3.1 Terms and definitions
12 3.2 Abbreviated terms
3.2.1 Generic abbreviated terms
Tables
Table 1 – Generic acronyms and abbreviated terms
13 3.2.2 Proposed specifically for the data model part of this document
Table 2 – Abbreviated terms for data object names
14 3.2.3 Existing abbreviated terms used in IEC 61850 (all parts) data object names model
Table 3 – Abbreviated terms of IEC 61850 (all parts) for data object names
24 3.3 Fault classification definitions
25 4 Requirements and use cases
4.1 General
Table 4 – Fault types
26 4.2 Common actors
27 Figures
Figure 1 – Actors global hierarchy
28 Figure 2 – System Actors SGAM positioning (function)
29 Figure 3 – System Actors SGAM positioning (not function related)
30 Table 5 – List of common actors
35 4.3 Use cases: fault indication and report
4.3.1 Generic use case – Not fault type specific
37 Figure 4 – Fault indication – Main use case
38 Figure 5 – Fault detection and indication – T1
39 Figure 6 – Fault detection and indication– T2
40 Figure 7 – Fault detection and indication for FPI – T3,T4 (with communicationto HV/MV SS) in the context of FLISR as described in 4.4.5
41 Figure 8 – Fault detection and indication for FPI – T3,T4 (without communication to HV/MV SS) in the context of FLISR as described in 4.4.5
53 4.3.2 Overcurrent non directional Fault Localization and Indication (F1C/NC)
54 4.3.3 Phase to earth faults, non directional fault detection (F2)
4.3.4 Overcurrent and phase to earth non directional faults detection (F3)
Figure 9 – Voltage presence/absence
55 4.3.5 Overcurrent, directional and non directional, fault detection (F4)
4.3.6 Overcurrent, non directional, phase to earth faults, directional and non directional fault detection (F5)
4.3.7 Overcurrents and phase to earth faults, directional and non directional fault detection (F6)
4.4 Use cases related to “other functions”
4.4.1 Report on device health
4.4.2 Monitor substation environment
4.4.3 Monitor external communication
4.4.4 Monitor energy flow (energy flow related use cases)
56 Figure 10 – Energy flow related use cases
57 Figure 11 – Sequence diagram for monitoring energy flows use cases
61 4.4.5 Contribute to distributed automatic FLISR
63 Figure 12 – Logical selectivity – FLI along the MV feeder
64 Figure 13 – Logical selectivity – FLI inside the EU plant
65 Figure 14 – Logical selectivity – FLI along the MV feeder and anti-islanding
66 Figure 15 – Use case – fault location indication
67 Figure 16 – For further analysis
77 4.4.6 Contribute to distributed automatic VVC
4.4.7 Contribute to distributed DER management
4.5 Use cases related to “Product life cycle”
4.5.1 IED configuration via CID file
79 Figure 17 – IED configuration process via CID
80 Figure 18 – FieldComp configuration – Main UC
81 Figure 19 – FieldComp asset management
Figure 20 – Grid and topology planning
82 Figure 21 – Communication network planning
83 Figure 22 – First FieldComp connection to communication network
84 Figure 23 – New FieldComp configuration via CID – Remote + local (successful case)
85 Figure 24 – New FieldComp configuration via CID – Remote + local (unsuccessful case – corrupted CID)
86 Figure 25 – Existing FieldComp on-line reconfiguration – (topology – successful case)
102 5 Information Models
5.1 Mapping of requirements on LNs
5.1.1 General
5.1.2 Mapping of the requirements of Fault Identification and report
103 5.1.3 Mapping of the requirements of “other functions”
Figure 26 – Possible arrangement of LNs to support fault passage indication
104 Figure 27 – Possible arrangement of LNs to support “Energy flow related use cases”
105 5.1.4 Mapping of the requirements of “product life cycle” (FieldComp remote configuration)
6 Logical node classes
6.1 General
Figure 28 – Possible arrangement of LNs to support CID Handling
106 6.2 Package LNGroupL
6.2.1 General
Figure 29 – Class diagram LogicalNodesJAHWG51::LogicalNodesJAHWG51
107 Figure 30 – Statechart diagram LNGroupL::LNGroupL
108 6.2.2 LICH LN
Figure 31 – Class diagram LNGroupL::LNGroupL
109 6.2.3 LN: Common LD Settings   Name: LCLD
Table 6 – Data objects of LICH
110 6.3 Package LNGroupM
6.3.1 General
Table 7 – Data objects of LCLD
111 6.3.2 LN: Energy   Name: MMTNExt
Figure 32 – Class diagram LNGroupM::LNGroupM
112 Table 8 – Data objects of MMTNExt
113 6.3.3 LN: Energy   Name: MMTRExt
114 Table 9 – Data objects of MMTRExt
115 6.3.4 LN: Measurement   Name: MMXNExt
116 6.3.5 LN: Measurement   Name: MMXUExt
Table 10 – Data objects of MMXNExt
117 Table 11 – Data objects of MMXUExt
118 6.4 Package LNGroupS
6.4.1 General
119 6.4.2 LN: Current presence monitoring   Name: SCPI
Figure 33 – Class diagram LNGroupS::LNGroupS
Table 12 – Data objects of SCPI
120 6.4.3 LN: Fault Passage Indicator   Name: SFPI
121 Table 13 – Data objects of SFPI
122 6.4.4 LN: Fault indicator statistic calculation   Name: SFST
Table 14 – Data objects of SFST
123 6.4.5 LN: Voltage presence indicator   Name: SVPI
124 Table 15 – Data objects of SVPI
125 7 Data object name semantics and enumerations
7.1 Data semantics
Table 16 – Attributes defined on classes of LogicalNodesJAHWG51 package
128 7.2 Enumerated data attribute types
7.2.1 General
129 7.2.2 CIDHandlingResultKind enumeration
Figure 34 – Class diagram DOEnumsJAHWG51::DOEnumsJAHWG51
Table 17 – Literals of CIDHandlingResultKind
130 7.2.3 CIDHandlingStatusKind enumeration
7.2.4 CurrentTransformersArrangementKind enumeration
7.2.5 FaultConfirmationModeKind enumeration
Table 18 – Literals of CIDHandlingStatusKind
Table 19 – Literals of CurrentTransformersArrangementKind
Table 20 – Literals of FaultConfirmationModeKind
131 7.2.6 FaultPermanenceKind enumeration
7.2.7 PwrFlwSignKind enumeration
8 SCL enumerations (from DOEnumsJAHWG51)
Table 21 – Literals of FaultPermanenceKind
Table 22 – Literals of PwrFlwSignKind
132 9 References
133 Annex A (informative)Interpretation of logical node tables
A.1 General interpretation of logical node tables
A.2 Conditions for element presence
Table A.1 – Interpretation of logical node tables
134 Table A.2 – Conditions for presence of elements within a context
136 Bibliography

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BSI PD IEC/TR 62689-100:2016
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