BSI PD IEC/TR 61850-90-3:2016
$256.21
Communication networks and systems for power utility automation – Using IEC 61850 for condition monitoring diagnosis and analysis
| Published By | Publication Date | Number of Pages |
| BSI | 2016 | 214 |
IEC TR 61850-90-3:2016(E) addresses communication aspects related to specific sensor networks that are widely used as well as information exchange towards asset management systems. Since the outcome of this work will affect several parts of IEC 61850, in a first step, this technical report has been prepared to address the topic from an application specific viewpoint across all affected parts of IEC 61850. Once this technical report has been approved, the affected parts of the standard will be amended with the results from the report. This approach is similar to what is done as an example with IEC 61850-90-1 for the communication between substations.
PDF Catalog
| PDF Pages | PDF Title |
|---|---|
| 4 | CONTENTS |
| 11 | FOREWORD |
| 13 | INTRODUCTION |
| 14 | 1 Scope |
| 15 | 2 Normative references 3 Terms, definitions, abbreviations, acronyms and conventions 3.1 Terms and definitions |
| 16 | 3.2 Abbreviations, acronyms and conventions Tables Table 1 โ Normative abbreviations for data object names |
| 34 | 4 Use cases 5 GIS (Gas Insulated Switchgear) 5.1 Summary Figures Figure 1 โ CMD Modelling Concept |
| 35 | 5.2 GIS overview |
| 36 | 5.3 GIS use case diagrams Figure 2 โ GIS CMD Overview |
| 37 | Figure 3 โ GIS use case diagram |
| 41 | Figure 4 โ Abrasion monitoring use case |
| 43 | Figure 5 โ Switch monitoring use case |
| 45 | Figure 6 โ Operating mechanism monitoring use case |
| 50 | Figure 7 โ Maintenance planning use case |
| 52 | Figure 8 โ CB operating time monitoring use case |
| 55 | 5.4 Preliminary modelling approach Figure 9 โ GIS internal structure |
| 56 | Figure 10 โ Example of 3 phases compartment modelling Figure 11 โ Example of 3 phases CB modelling |
| 57 | Figure 12 โ Example of 3 phases switch modelling Figure 13 โ Example of PD monitoring modelling |
| 58 | 6 Power transformer 6.1 Summary 6.2 Transformer overview Figure 14 โ Transformer principle |
| 59 | 6.3 Transformer CMD use case diagram Figure 15 โ Typical power transformer |
| 60 | Figure 16 โ Use case for oil supervision |
| 62 | Figure 17 โ Partial discharge (PD) use case |
| 64 | Figure 18 โ Use case for temperature supervision |
| 66 | Figure 19 โ Use case for solid insulation aging supervision |
| 68 | Figure 20 โ Use case for bubbling temperature supervision |
| 70 | Figure 21 โ Use case for bushing supervision |
| 72 | Figure 22 โ Use case for cooling supervision |
| 75 | Figure 23 โ Use case for ancillary sensors supervision |
| 76 | 6.4 Preliminary modelling approach |
| 78 | 7 Load tap changer (LTC) 7.1 Summary |
| 79 | 7.2 Load tap changer overview 7.3 Constraints/assumptions/design considerations Figure 24 โ Structure of load tap changer |
| 80 | Figure 25 โ Configuration of LTC CMD system |
| 81 | 7.4 Data flow Figure 26 โ Data flows for LTC CMD (part 1) |
| 82 | 7.5 Use case diagram Figure 27 โ Data flows for LTC CMD (part 2) Figure 28 โ Data flows for LTC CMD (part 3) |
| 83 | Figure 29 โ Use case for monitoring LTC operation properties |
| 85 | Figure 30 โ Use case for monitoring LTC operation counts |
| 86 | Figure 31 โ Use case for monitoring contact abrasion |
| 88 | Figure 32 โ Use case for monitoring LTC oil temperature and flow |
| 90 | Figure 33 โ Use case for monitoring operation of oil filter unit |
| 91 | 7.6 Data description table |
| 96 | 8 Underground cable (UGC) 8.1 Summary 8.2 Underground cable overview Figure 34 โ An online system monitoring OF (Oil Filled) cable conditions |
| 97 | 8.3 Constraints/assumptions/design considerations 8.4 Data flow Figure 35 โ Cable cross-section drawing |
| 98 | Figure 36 โ Supervisions of UGC and their data flows |
| 99 | 8.5 Use case diagram Figure 37 โ Supervisions of OF cables and their data flows Figure 38 โ Use case for thermal aging supervision |
| 101 | Figure 39 โ A sensor detecting cable positions in 3 dimensions Figure 40 โ Use case for supervision of cable parts cracking |
| 103 | Figure 41 โ Use case for insulation aging supervision |
| 104 | Figure 42 โ Use case for water-tree supervision |
| 106 | Figure 43 โ Use case for supervision of earth fault without circuit breaker trip |
| 108 | Figure 44 โ Use case for oil aging supervision |
| 109 | Figure 45 โ Use case for oil leak supervision |
| 111 | 8.6 Data description table |
| 112 | 9 Transmission line (TL) 9.1 Summary |
| 113 | 9.2 Transmission line overview |
| 114 | Figure 46 โ Example configuration of OHTL tower cluster Figure 47 โ Line sensor unit |
| 115 | 9.3 TL CMD use case diagram Figure 48 โ Use case for line condition supervisor |
| 117 | Figure 49 โ Use case for tower condition supervisor |
| 119 | Figure 50 โ Use case for insulator condition supervisor |
| 121 | Figure 51 โ Use case for surrounding area supervisor |
| 123 | 9.4 Data description table 10 Auxiliary power system 10.1 Summary |
| 124 | 10.2 Auxiliary power system overview Figure 52 โ Legend of diagrams |
| 125 | Figure 53 โ Secured DC system from AC input power Figure 54 โ Secured AC system from DC input with AC backup |
| 126 | 10.3 Data flow 10.4 Use case diagram Figure 55 โ Secured AC system from AC input with AC backup Figure 56 โ Data flow of auxiliary power system |
| 127 | Figure 57 โ Use case for auxiliary power system |
| 128 | 10.5 Data modelling |
| 129 | Figure 58 โ Secured DC system from AC input power Figure 59 โ Secured AC system from DC input with AC backup |
| 130 | 11 Communication Requirements 11.1 General issues Figure 60 โ Secured AC system from AC input with AC backup |
| 131 | 11.2 Response behaviour requirements (6.4 of IECย 61850-5:2013) 11.3 Requirements for data integrity (Clause 14 of IECย 61850-5:2013) 11.4 Communication requirements for the WAN Figure 61 โ Communication architecture for CMD |
| 132 | 11.5 Performance issue 11.6 Plug and Play 12 Asset Management 12.1 Definition 12.2 Comparison of asset management to other systems |
| 133 | 12.3 IECย 61850 services for Asset Management |
| 134 | Figure 62 โ Reporting and logging model (conceptual) from IECย 61850-7-1 |
| 135 | 12.4 CMD 12.5 Conclusion 12.6 Maintenance |
| 136 | Figure 63 โ Use case for maintenance |
| 138 | 12.7 ERP Update |
| 139 | Figure 64 โ Use case for ERP update |
| 141 | 13 Logical node classes 13.1 General |
| 142 | 13.2 Abstract Logical Nodes (AbstractLNs_90_3) Figure 65 โ Class diagram LogicalNodes_90_3::LogicalNodes_90_3 |
| 143 | Figure 66 โ Class diagram AbstractLNs_90_3::AbstractLNs_90_3 |
| 144 | Table 2 โ Data objects of BatteryChargerLN |
| 145 | 13.3 Logical nodes for tanks (LNGroupK) |
| 146 | Figure 67 โ Class diagram LNGroupK::LNGroupK |
| 147 | Table 3 โ Data objects of KTNKExt |
| 148 | Table 4 โ Data objects of KTOW |
| 149 | 13.4 Logical nodes for metering and measurement (LNGroupM) |
| 150 | Figure 68 โ Class diagram LNGroupM::LNGroupM |
| 151 | Table 5 โ Data objects of MMETExt |
| 152 | 13.5 Logical nodes for supervision and monitoring (LNGroupS) |
| 153 | Figure 69 โ Class diagram LNGroupS::LNGroupS1 |
| 154 | Figure 70 โ Class diagram LNGroupS::LNGroupS2 |
| 156 | Table 6 โ Data objects of SBAT |
| 157 | Table 7 โ Data objects of SCBRExt |
| 159 | Table 8 โ Data objects of SCGR |
| 160 | Table 9 โ Data objects of SEAM |
| 162 | Table 10 โ Data objects of SFIR |
| 163 | Table 11 โ Data objects of SIMLExt |
| 168 | Table 12 โ Data objects of SIMS |
| 169 | Table 13 โ Data objects of SLTCExt |
| 172 | Table 14 โ Data objects of SPTRExt |
| 173 | Table 15 โ Data objects of SSTP |
| 174 | 13.6 Logical nodes for instrument transformers and sensors (LNGroupT) |
| 175 | Figure 71 โ Class diagram LNGroupT::LNGroupT |
| 176 | Table 16 โ Data objects of TDEN |
| 177 | Table 17 โ Data objects of TTRQ |
| 178 | 13.7 Logical nodes for power transformers (LNGroupY) Table 18 โ Data objects of TUHF |
| 179 | Figure 72 โ Class diagram LNGroupY::LNGroupY |
| 180 | Table 19 โ Data objects of YPTRExt |
| 181 | 13.8 Logical nodes for further power system equipment (LNGroupZ) |
| 182 | Figure 73 โ Class diagram LNGroupZ::LNGroupZ1 |
| 183 | Figure 74 โ Class diagram LNGroupZ::LNGroupZ2 |
| 184 | Table 20 โ Data objects of ZAXNExt |
| 185 | Table 21 โ Data objects of ZBATExt |
| 187 | Table 22 โ Data objects of ZBSHExt |
| 188 | Table 23 โ Data objects of ZBTC |
| 190 | Table 24 โ Data objects of ZCABExt |
| 192 | Table 25 โ Data objects of ZCONExt |
| 193 | Table 26 โ Data objects of ZGENExt |
| 195 | Table 27 โ Data objects of ZLINExt |
| 197 | Table 28 โ Data objects of ZUPS |
| 198 | 14 Data object name semantics and enumerations 14.1 Data semantics Table 29 โ Attributes defined on classes of LogicalNodes_90_3 package |
| 206 | 14.2 Enumerated data attribute types Figure 75 โ Class diagram DOEnums_90_3::DOEnums_90_3 Table 30 โ Literals of BatteryChargerType90_3Kind |
| 207 | Table 31 โ Literals of BatteryTestResult90-3Kind Table 32 โ Literals of BatteryType90_3Kind |
| 208 | Table 33 โ Literals of ChargerOperationKind Table 34 โ Literals of ExternalDeviceModeKind Table 35 โ Literals of OperationFailureModeKind |
| 209 | 15 SCL enumerations (from DOEnums_90_3) Table 36 โ Literals of SystemOperationModeKind |
| 211 | Annex A (informative) Usage of โTโ logical node and โSโ logical node in CMD application Figure A.1 โ Decomposition of functions into interacting LN on different levels: Examples for generic function with tele control interface, protection function and measuring/metering function (from IECย 61850-5:2003) |
| 212 | Bibliography |
