BS EN IEC 61970-456:2018 – TC:2020 Edition
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Tracked Changes. Energy management system application program interface (EMS-API) – Solved power system state profiles
| Published By | Publication Date | Number of Pages |
| BSI | 2020 | 172 |
IEC 61970-456:2018 rigorously defines the subset of classes, class attributes, and roles from the CIM necessary to describe the result of state estimation, power flow and other similar applications that produce a steady-state solution of a power network, under a set of use cases which are included informatively in this standard. This document is intended for two distinct audiences, data producers and data recipients, and may be read from those two perspectives. This new edition includes the following significant technical changes with respect to the previous edition: – Addition of the Steady State Hypothesis (SSH) profile. – Better description of the relation between different profiles and alignment with the current nomenclature used with profiles, e.g. ‘data set’ and ‘network part’. – Extension of the description of the use cases.
PDF Catalog
| PDF Pages | PDF Title |
|---|---|
| 102 | undefined |
| 106 | English CONTENTS |
| 108 | FOREWORD |
| 110 | INTRODUCTION |
| 111 | 1 Scope 2 Normative references 3 Terms and definitions |
| 112 | 4 Profile information 5 Overview Table 1 – Profiles defined in this document |
| 113 | Figures Figure 1 – Relations between MAS, profile and dataset |
| 115 | Figure 2 – Profile relationships |
| 116 | Figure 3 – Connectivity model example |
| 117 | 6 Use cases 6.1 Overview |
| 118 | Figure 4 – The European power system with regions |
| 119 | 6.2 EMS network analysis integration Figure 5 – Information exchange in power flow and sharing of results |
| 120 | 6.3 Power flow based network analysis Figure 6 – EMS datasets to an external client |
| 121 | Figure 7 – Node-breaker power flow Integration architecture Figure 8 – Bus-branch power flow Integration architecture |
| 122 | Figure 9 – Boundary injection model |
| 123 | Figure 10 – Alternate boundary modelling |
| 124 | Figure 11 – Assembled model alternatives |
| 125 | 7 Data model with CIMXML examples 7.1 Use of the interfaces 7.1.1 Overview 7.1.2 Network model boundaries |
| 126 | Figure 12 – Line boundary dataset example Figure 13 – Substation boundary dataset example |
| 127 | Figure 14 – Power Flow on an assembledd model |
| 128 | 7.1.3 Bus-branch and node-breaker models Figure 15 – Power Flow on a regional network part |
| 129 | Figure 16 – CIM relation between ConnectivityNode and TopologicalNode |
| 130 | Figure 17 – Bus-branch modeling of bus coupler and line transfer |
| 131 | 7.2 Topology (TP) interface Figure 18 – CIM topology model |
| 132 | Figure 19 – Topology solution interface |
| 133 | 7.3 State Variables (SV) interface Figure 20 – CIM state variable solution model |
| 134 | Figure 21 – State solution interface example |
| 135 | 7.4 Steady State Hypothesis (SSH) interface 8 Profiles 8.1 Comments and notes |
| 136 | 8.2 SteadyStateHypothesis profile 8.2.1 General |
| 137 | 8.2.2 Concrete Classes |
| 150 | 8.2.3 Abstract Classes |
| 157 | 8.2.4 Data Types |
| 159 | 8.3 Topology profile 8.3.1 General 8.3.2 Concrete Classes |
| 161 | 8.3.3 Abstract Classes |
| 162 | 8.4 StateVariables profile 8.4.1 General 8.4.2 Concrete Classes |
| 168 | 8.4.3 Abstract Classes |
| 169 | 8.4.4 Data Types |
| 171 | Bibliography |
