BS EN IEC 63376:2023
$215.11
Industrial facility energy management system (FEMS). Functions and information flows
| Published By | Publication Date | Number of Pages |
| BSI | 2023 | 76 |
This document specifies the functions and the information flows of industrial Facility Energy Management System (FEMS). Generic functions are defined for the FEMS, to enable upgrading traditional Energy Management System (EMS) from visualization of the status of energy consumption to automation of energy management defining a closer relation with other management and control systems. A generic method to classify the FEMS functions will be explained. The information exchange between the FEMS and other systems such as Manufacturing Operations Management (MOM), Manufacturing Execution System (MES) and Enterprise Resource Planning (ERP) will be outlined.
PDF Catalog
| PDF Pages | PDF Title |
|---|---|
| 2 | undefined |
| 5 | Annex ZA (normative)Normative references to international publicationswith their corresponding European publications |
| 6 | English CONTENTS |
| 10 | FOREWORD |
| 12 | INTRODUCTION |
| 14 | 1 Scope 2 Normative references 3 Terms, definitions, and abbreviated terms |
| 15 | 3.1 Terms and definitions |
| 16 | 3.2 Abbreviated terms |
| 17 | 4 General 4.1 Energy management activities in Industrial Facilities Figures Figure 1 ā Characteristic feature of HEMS, BEMS, and FEMS |
| 18 | 4.2 Hierarchical structure of enterprise manufacturing system 4.2.1 Levels of manufacturing enterprises and the activities Figure 2 ā Functional hierarchy |
| 19 | 4.3 Energy management system in a manufacturing enterprise Figure 3 ā Extension to the role-based equipment hierarchy model |
| 20 | 4.4 Role of FEMS and its expansion 4.4.1 Role of FEMS 4.4.2 Expansion of the role of FEMS Figure 4 ā System configuration of integration of multiple FEMS |
| 21 | 4.4.3 International standardization Figure 5 ā Expansion of role of FEMS |
| 22 | 4.5 Relation between FEMS and other systems 4.5.1 Relation between FEMS and other systems 4.5.2 FEMS and production system Figure 6 ā Relationship between FEMS and other systems |
| 24 | Figure 7 ā Hierarchical model of production system Figure 8 ā Multiple-input, Multiple-output controller |
| 25 | 4.5.3 Management and optimization 4.6 Information exchange 4.6.1 System boundary |
| 26 | 4.6.2 Inside and outside of the facility Figure 9 ā Hierarchical structure of integrated enterprise-production system |
| 27 | 4.7 Data confidentiality 4.7.1 General Figure 10 ā Example of Information exchange with inside and outside of the facility |
| 28 | 4.7.2 Information security 5 Description of functions of FEMS 5.1 Category of functions of FEMS Figure 11 ā IEC 62443 Security for industrial automation and control systems standards |
| 29 | Figure 12 ā Categories of FEMS functions and improvement cycle of energy performance Tables Table 1 ā Description for FEMS function categories |
| 31 | 5.2 Monitoring Data Flows 5.2.1 General Figure 13 ā Relationship among functions of FEMS and other systems Table 2 ā Data input and output of FEMS functions categorized into āMonitoringā |
| 32 | 5.2.2 Collection of actual and reference data Figure 14 ā Functions categorized under āMonitoringā and FEMS related data flow |
| 33 | 5.2.3 Collection of manufacturing planning information and facility status |
| 34 | 5.3 Analysis Data Flows 5.3.1 General Table 3 ā Data input and output of FEMS functions categorized into āAnalysisā |
| 35 | 5.3.2 Assumption for unmeasured parameters Figure 15 ā Functions categorized under āAnalysisā and FEMS related data flow |
| 36 | 5.3.3 Change detection in energy performance 5.3.4 Estimation of causality |
| 37 | 5.3.5 Analysis of potential energy saving |
| 38 | 5.4 Optimization Data Flows 5.4.1 General Table 4 ā Data input and output of FEMS functions categorized into āOptimizationā |
| 39 | 5.4.2 Validation of operation strategy and constraints Figure 16 ā Functions categorized under āOptimizationā and FEMS related data flow |
| 40 | 5.4.3 Derivation of operation strategy 5.5 Instruction Data Flows 5.5.1 General Table 5 ā Data input and output of FEMS functions categorized into āInstructionā |
| 41 | 5.5.2 Report optimisation results to operator/energy manager Figure 17 ā Functions categorized under āInstructionā and FEMS related data flow |
| 42 | 5.5.3 Output operation strategies to other systems 6 Classification of FEMS |
| 43 | Table 6 ā Description of āAutomation levelsā |
| 44 | Figure 18 ā Three-dimensional map of FEMS |
| 45 | Table 7 ā Relation between the level of automation and function |
| 47 | 7 FEMS Demand Response 7.1 Demand Response |
| 48 | 7.2 FEMS and Incentive-based Demand Response 7.3 FEMS and Price-based Demand Response Figure 19 ā General approach common todayfor grid management of demand response |
| 49 | Figure 20 ā Correspondence relationship among these seven FCs and FEMS functions |
| 50 | Table 8 ā Relationship between the FCs in IEC 62872-2 [2] and the functions of FEMS |
| 51 | Annex A (informative)FEMS Use Cases A.1 FEMS Actors Figure A.1 ā Generic communication diagram between the smart grid and the FEMS Table A.1 ā Actors and roles |
| 53 | A.2 Use cases of FEMS A.2.1 General A.2.2 Selection of Use cases Figure A.2 ā Use Case representation on three-dimensional FEMS model |
| 54 | A.2.3 Measurement and analysis of energy data (Visualization) Figure A.3 ā Relationship between IEC 62264 (ISA 95) model and FEMS use-cases Figure A.4 ā Measurement and analysis of energy data |
| 55 | A.2.4 Optimization of each unit Figure A.5 ā Sequence diagram of measurement and analysis of energy data Table A.2 ā Functions included in a Process (Measurement and analysis of energy data) |
| 56 | Figure A.6 ā Optimization of each unit (invertor control of compressor) |
| 57 | A.2.5 Optimization of each facility Figure A.7 ā Sequence diagram of Optimization of each unit (invertor control of compressor) Table A.3 ā Functions included in a Process (optimization of each unit(invertor control of compressor) |
| 58 | Figure A.8 ā Optimization of each facility (quantity control of compressor) |
| 59 | A.2.6 Optimization of energy supply facility Figure A.9 ā Sequence diagram of optimization of each facility (quantity control of compressor) Table A.4 ā Functions included in a process (optimization of each facility(quantity control of compressor) |
| 60 | Figure A.10 ā Optimization of energy supply facility (supply-side RENKEI) |
| 61 | Figure A.11 ā Sequence diagram of optimization of energy supply facility(supply-side RENKEI) Table A.5 ā Functions included in a process (optimization of energy supply facility (Supply-side RENKEI)) Function |
| 62 | A.2.7 Overall optimization Figure A.12 ā Overall optimization (demand and supply RENKEI) |
| 63 | Figure A.13 ā Sequence diagram of overall optimization(demand and supply RENKEI) |
| 64 | A.2.8 Energy Source optimization ā Economics/renewables Table A.6 ā Functions included in a process (overall optimization (demand and supply RENKEI)) |
| 65 | Figure A.14 ā Alternative energy sources |
| 66 | Figure A.15 ā Sequence diagram for energy source optimization Table A.7 ā Functions included in an energy optimization process |
| 67 | A.2.9 Energy Profile |
| 68 | Figure A.16 ā Alternative energy profiles |
| 69 | Figure A.17 ā Sequence diagram for energy profile optimization Table A.8 ā Functions included in an Energy Profiles Optimization Process |
| 70 | Annex B (informative)Interface to exchange information for FEMS B.1 Energy Storage System (ESS) |
| 71 | B.2 Peak shift Figure B.1 ā Signal exchange diagram of the ESS and FEMS |
| 72 | B.3 Peak shaving Figure B.2 ā Energy flow during peak shift Figure B.3 ā Peak shaving energy flow |
| 73 | B.4 Other Functions B.4.1 General B.4.2 Battery operating time forecast B.4.3 Battery life monitoring B.4.4 Function update |
| 74 | Bibliography |
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