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PD IEC/TR 62689-100:2016 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, 2016
- 30338164-VOR.pdf [Go to Page]
- CONTENTS
- FOREWORD
- INTRODUCTION
- 1 Scope
- 2 Normative references
- 3 Terms, definitions and abbreviated terms [Go to Page]
- 3.1 Terms and definitions
- 3.2 Abbreviated terms [Go to Page]
- 3.2.1 Generic abbreviated terms
- 3.2.2 Proposed specifically for the data model part of this document
- 3.2.3 Existing abbreviated terms used in IEC 61850 (all parts) data object names model
- 3.3 Fault classification definitions
- 4 Requirements and use cases [Go to Page]
- 4.1 General
- 4.2 Common actors
- 4.3 Use cases: fault indication and report [Go to Page]
- 4.3.1 Generic use case – Not fault type specific
- 4.3.2 Overcurrent non directional Fault Localization and Indication (F1C/NC)
- 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)
- 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” [Go to Page]
- 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)
- 4.4.5 Contribute to distributed automatic FLISR
- 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” [Go to Page]
- 4.5.1 IED configuration via CID file
- 5 Information Models [Go to Page]
- 5.1 Mapping of requirements on LNs [Go to Page]
- 5.1.1 General
- 5.1.2 Mapping of the requirements of Fault Identification and report
- 5.1.3 Mapping of the requirements of “other functions”
- 5.1.4 Mapping of the requirements of “product life cycle” (FieldComp remote configuration)
- 6 Logical node classes [Go to Page]
- 6.1 General
- 6.2 Package LNGroupL [Go to Page]
- 6.2.1 General
- 6.2.2 LICH LN
- 6.2.3 LN: Common LD Settings Name: LCLD
- 6.3 Package LNGroupM [Go to Page]
- 6.3.1 General
- 6.3.2 LN: Energy Name: MMTNExt
- 6.3.3 LN: Energy Name: MMTRExt
- 6.3.4 LN: Measurement Name: MMXNExt
- 6.3.5 LN: Measurement Name: MMXUExt
- 6.4 Package LNGroupS [Go to Page]
- 6.4.1 General
- 6.4.2 LN: Current presence monitoring Name: SCPI
- 6.4.3 LN: Fault Passage Indicator Name: SFPI
- 6.4.4 LN: Fault indicator statistic calculation Name: SFST
- 6.4.5 LN: Voltage presence indicator Name: SVPI
- 7 Data object name semantics and enumerations [Go to Page]
- 7.1 Data semantics
- 7.2 Enumerated data attribute types [Go to Page]
- 7.2.1 General
- 7.2.2 CIDHandlingResultKind enumeration
- 7.2.3 CIDHandlingStatusKind enumeration
- 7.2.4 CurrentTransformersArrangementKind enumeration
- 7.2.5 FaultConfirmationModeKind enumeration
- 7.2.6 FaultPermanenceKind enumeration
- 7.2.7 PwrFlwSignKind enumeration
- 8 SCL enumerations (from DOEnumsJAHWG51)
- 9 References
- Annex A (informative)Interpretation of logical node tables [Go to Page]
- A.1 General interpretation of logical node tables
- A.2 Conditions for element presence
- Bibliography
- Figures [Go to Page]
- Figure 1 – Actors global hierarchy
- Figure 2 – System Actors SGAM positioning (function)
- Figure 3 – System Actors SGAM positioning (not function related)
- Figure 4 – Fault indication – Main use case
- Figure 5 – Fault detection and indication – T1
- Figure 6 – Fault detection and indication– T2
- 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
- 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
- Figure 9 – Voltage presence/absence
- Figure 10 – Energy flow related use cases
- Figure 11 – Sequence diagram for monitoring energy flows use cases
- Figure 12 – Logical selectivity – FLI along the MV feeder
- Figure 13 – Logical selectivity – FLI inside the EU plant
- Figure 14 – Logical selectivity – FLI along the MV feeder and anti-islanding
- Figure 15 – Use case – fault location indication
- Figure 16 – For further analysis
- Figure 17 – IED configuration process via CID
- Figure 18 – FieldComp configuration – Main UC
- Figure 19 – FieldComp asset management
- Figure 20 – Grid and topology planning
- Figure 21 – Communication network planning
- Figure 22 – First FieldComp connection to communication network
- Figure 23 – New FieldComp configuration via CID – Remote + local (successful case)
- Figure 24 – New FieldComp configuration via CID – Remote + local (unsuccessful case – corrupted CID)
- Figure 25 – Existing FieldComp on-line reconfiguration – (topology – successful case)
- Figure 26 – Possible arrangement of LNs to support fault passage indication
- Figure 27 – Possible arrangement of LNs to support "Energy flow related use cases"
- Figure 28 – Possible arrangement of LNs to support CID Handling
- Figure 29 – Class diagram LogicalNodesJAHWG51::LogicalNodesJAHWG51
- Figure 30 – Statechart diagram LNGroupL::LNGroupL
- Figure 31 – Class diagram LNGroupL::LNGroupL
- Figure 32 – Class diagram LNGroupM::LNGroupM
- Figure 33 – Class diagram LNGroupS::LNGroupS
- Figure 34 – Class diagram DOEnumsJAHWG51::DOEnumsJAHWG51
- Tables [Go to Page]
- Table 1 – Generic acronyms and abbreviated terms
- Table 2 – Abbreviated terms for data object names
- Table 3 – Abbreviated terms of IEC 61850 (all parts) for data object names
- Table 4 – Fault types
- Table 5 – List of common actors
- Table 6 – Data objects of LICH
- Table 7 – Data objects of LCLD
- Table 8 – Data objects of MMTNExt
- Table 9 – Data objects of MMTRExt
- Table 10 – Data objects of MMXNExt
- Table 11 – Data objects of MMXUExt
- Table 12 – Data objects of SCPI
- Table 13 – Data objects of SFPI
- Table 14 – Data objects of SFST
- Table 15 – Data objects of SVPI
- Table 16 – Attributes defined on classes of LogicalNodesJAHWG51 package
- Table 17 – Literals of CIDHandlingResultKind
- Table 18 – Literals of CIDHandlingStatusKind
- Table 19 – Literals of CurrentTransformersArrangementKind
- Table 20 – Literals of FaultConfirmationModeKind
- Table 21 – Literals of FaultPermanenceKind
- Table 22 – Literals of PwrFlwSignKind
- Table A.1 – Interpretation of logical node tables
- Table A.2 – Conditions for presence of elements within a context [Go to Page]