GBZ45388.1-2025 English PDF

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GBZ45388.1-2025: Industrial-process measurement, control and automation - Part 1: System interface between industrial facilities and the smart grid
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Basic data

Standard ID: GB/Z 45388.1-2025 (GB/Z45388.1-2025)
Description (Translated English): Industrial-process measurement, control and automation - Part 1: System interface between industrial facilities and the smart grid
Sector / Industry: National Standard
Classification of Chinese Standard: N10
Classification of International Standard: 25.040
Word Count Estimation: 86,889
Date of Issue: 2025-03-28
Date of Implementation: 10/1/2025
Issuing agency(ies): State Administration for Market Regulation, China National Standardization Administration

GBZ45388.1-2025: Industrial-process measurement, control and automation - Part 1: System interface between industrial facilities and the smart grid

---This is a DRAFT version for illustration, not a final translation. Full copy of true-PDF in English version (including equations, symbols, images, flow-chart, tables, and figures etc.) will be manually/carefully translated upon your order.
GB /Z 45388.1-2025.Industrial process measurement, control and automation Part 1.System interface between industrial facilities and smart grids ICS 25.040 CCSN10 Guiding technical documents of the People's Republic of China on national standardization Industrial process measurement, control and automation Part 1.Interconnection between industrial facilities and smart grids System Interface (IEC TS62872-1.2019,IDT) Released on 2025-03-28 2025-10-01 Implementation State Administration for Market Regulation The National Standardization Administration issued

Table of contents

Preface V Introduction VI 1 Scope 1 2 Normative references 1 3 Terms and Definitions 2 3.1 Overview 2 3.2 Models in Automation 3 3.3 Models in Energy Management Systems and Smart Grids 4 4 Abbreviations 7 5 Requirements 8 5.1 Industrial considerations and approaches 8 5.2 Architecture Requirements 11 5.3 System interface model between industrial facilities and smart grid 15 5.4 Information security requirements 16 5.5 Functional safety requirements 16 5.6 Communication requirements 17 5.7 Audit record requirements 17 5.8 Information requirements17 Appendix A (Normative) User Cases and User Use Cases 34 A.1 Overview 34 A.2 User Case 34 A.3 Use Case 36 Appendix B (Normative) Use Cases Based on Incentive DR Programs 55 B.1 Overview 55 B.2 Incentive-based DR (IBDR) solution use case 55 Appendix C (Informative) Application Examples of Demand Response Energy Management Model 67 C.1 Overview 67 C.2 Main Architecture 67 C.3 Task structure 67 C.4 Energy management methods 68 C.5 Industrial Demand Response Energy Management Model Mapping to Use Cases 69 Appendix D (Normative) Information Security Services 70 Appendix E (Informative) Information Requirement Solutions 71 E.1 Overview 71 E.2 Existing standards71 E.3 Analysis of each use case 72 References 78 Figure 1 Overview of the interface between FEMS and smart grid 9 Figure 2 Common methods currently used for DR grid management10 Figure 3 Example of power distribution in a facility11 Figure 4 Physical enterprise and control system 12 Figure 5 Model element 13 Figure 6 Model architecture 14 Figure 7 Grid architecture model 16 Figure A.1 Use case overview 37 Figure A.2 General communication diagram between smart grid and FEMS38 Figure A.3 Participants in the role hierarchy (IEC 62264-1) 38 Figure A.4 FG-100 sequence diagram 41 Figure A.5 FG-200 sequence diagram 43 Figure A.6 FG-300 sequence diagram 44 Figure A.7 FG-400 sequence diagram 46 Figure A.8 FG-500 sequence diagram 47 Figure A.9 FG-600 sequence diagram 48 Figure A.10 FG-710 sequence diagram 49 Figure A.11 FG-720 sequence diagram 51 Figure A.12 FG-800 52 Figure A.13 FG-820 sequence diagram 54 Figure B.1 The role of incentive-based demand response in power system planning and operation 55 Figure B.2 IBMR-1 (DLC) sequence diagram 57 Figure B.3 3-sequence diagram of IBDR-2 (I/C) 59 Figure B.4 Sequence diagram of IBDR-3 (EDRP) 60 Figure B.5 Sequence diagram of IBDR-4 (DB) 62 Figure B.6 IBMR-5 (CMP) Sequence Diagram 64 Figure B.7 IBMR-6 (ASM) sequence diagram 66 Figure C.1 Application example of demand response energy management model 67 Figure C.2 Water cooling task structure 68 Figure E.1 Interaction of registration report 72 Figure E.2 Interaction requesting a report 72 Figure E.3 Simple setup exchange 73 Table 1 Requirement Information 18 Table 2 Data and data type examples 32 Table A.1 High-level facility-side user case. Facility operation perspective 34 Table A.2 Utility User Case. Utility Operations Perspective35 Table A.3 Dependencies between user stories and use cases 36 Table A.4 Participants and roles 38 Table A.5 FG-100 exchange information 41 Table A.6 Information exchanged by FG-200 43 Table A.7 Information exchanged by FG-300 45 Table A.8 Information exchanged by FG-400 46 Table A.9 Information exchanged by FG-500 47 Table A.10 Information exchanged by FG-600 48 Table A.11 Information exchanged by FG-710 50 Table A.12 Information exchanged by FG-720 51 Table A.13 FG-810 exchange information description 53 Table A.14 Information exchanged by FG-820 54 Table B.1 Dependencies between user stories and use cases 56 Table B.2 Information exchanged in IBDR-1 (DLC) 58 Table B.3 IBDR-2 exchange information (I/C) 59 Table B.4 Information exchanged in IBDR-3 (EDRP) 61 Table B.5 Information exchanged in IBDR-4 (DB) 62 Table B.6 Information exchanged in IBDR-5 (CMP) 64 Table B.7 Information exchanged in IBMR-6 (ASM) 66 Table E.1 Overview of applicability of existing standards 71

Foreword

This document is in accordance with the provisions of GB/T 1.1-2020 "Guidelines for standardization work Part 1.Structure and drafting rules for standardization documents" Drafting. This document is part 1 of GB /Z 45388 "Industrial process measurement, control and automation". GB /Z 45388 has published the following part. --- Part 1.System interface between industrial facilities and smart grids. This document is equivalent to IEC TS62872-1.2019 "Industrial process measurement, control and automation Part 1.Industrial facilities and intelligent System Interfaces Between Grids. The following minimal editorial changes were made to this document. ---The abbreviation "GW" originally means "UtilityGateway", which is the same as the abbreviation "UG". Therefore, the content after the abbreviation "GW" is Change to "Gateway". Please note that some of the contents of this document may involve patents. The issuing organization of this document does not assume the responsibility for identifying patents. This document was proposed by the China Machinery Industry Federation. This document is under the jurisdiction of the National Industrial Process Measurement, Control and Automation Standardization Technical Committee (SAC/TC124). This document was drafted by. Southwest University, Xi'an Youkong Technology Development Co., Ltd., Shanghai Lodinson Industrial Automation Equipment Co., Ltd. Anhui Tiankang (Group) Co., Ltd., Jiangsu Jack Instrument Co., Ltd., Hangzhou Automation Technology Research Institute Co., Ltd., Guoneng Zhishen Control Technology Co., Ltd., Chongqing Jinxin Max Safety Instrument System Co., Ltd., Henan Baoshian Technology Co., Ltd., Jiangyuan (Tianchang) Technology Co., Ltd., Jiangsu Huaxia Instrument Co., Ltd., Jiangsu Shuangmu Measurement and Control Technology Co., Ltd., Zhejiang Zhongkong Automation Instrument Co., Ltd., Xiamen Anton Electronics Co., Ltd., China Academy of Railway Sciences Group Co., Ltd., Institute of Electronic Computing Technology, Shandong Provincial Institute of Quantitative Science, Shenzhen Feistech Technology Co., Ltd., Chongqing Silian Transportation Technology Co., Ltd., Huzhou Normal University, Yangzhou Vocational University, Jiangsu Suyi Group Co., Ltd., Shenzhen Jinkaibo Electronics Co., Ltd., Guangdong Lisheng Electric Power Technology Co., Ltd., China Southern Power Grid Big Data Services Co., Ltd., Anshan Iron and Steel Group Benxi Steel Plate Steelmaking Plant, China Inspection Group Southern Testing Co., Ltd., Wuhan Baomu Testing Co., Ltd. Company, Xi'an Singularity Energy Co., Ltd., Guangzhou Keyi Optoelectronic Technology Co., Ltd., Chongqing Zhongzhilian Instrument Co., Ltd., Southwest Petroleum University. The main drafters of this document are. Yang Yang, Hu Ming, Luo Wenjun, Mao Wenzhang, Min Xinyi, Bu Yan, Tian Yucong, Ge Fengchun, Lang Yunfei, Ma Bin, Huang Dong, Ming Zhendong, Ding Shuhui, Chen Shuang, Chen Qingfeng, Xiao Guozhuan, Li Shuai, Zhang Shuai, Liu Xingguang, Cao Xu, Hu Wenjun, Chen Jiusong, Liu Liang, Zheng Ye, Ma Jinchao, Zhao Yongguo, Zheng Chuanxin, Han Ming, Liu Shengwen, Liu Weizheng, Wu Xiaosong, Zhou Xiang, Liu Feng, Zhang Xinguo, Zhou Xuelian, Zhang Yu, Zhang Geng, Zheng Desheng, Gong Jie, Ren Yue, Zhang Zhongrui, Ren Shiqi, and Zhong Xiongyu.

Introduction

The World Energy Outlook.2017 pointed out that in.2015, global industrial electricity consumption exceeded 40% of the world's total electricity generation. With the increasing implementation of internal power generation, co-generation and storage resources, industry itself has become an important generator of internal power. As a major energy consumer, some industries can minimize the peak demand of the power grid by rationally arranging industrial power consumption. Suppliers, industries with internal generation or storage resources can also assist the grid with load management. Its use and supply of electricity is managed, but wider deployment, especially in small industrial facilities, will depend on industrial automation Availability of readily available standard interfaces between equipment and the “smart grid”. NOTE. In this document, "smart grid" refers to entities external to industry that interact with industry for the purpose of energy management. In other documents, the term may be used for Refers to all elements, including internal industrial energy elements, which work together to optimize the generation and use of energy. Industry is a major consumer of electricity and in many cases this consumption can be arranged to help minimize the impact on the smart grid. In addition, many industrial facilities have internal generation or storage resources that can help with smart grid load and supply management. For example, internal generation can provide energy for smart grids and facilities. Going a step further, storage resources can help smart grid loads While some large industrial facilities already manage their electricity use and supply, wider deployment, particularly in small industrial The deployment of industrial facilities will depend on the availability of readily available standard automation interfaces. Interface standards for home and building automation and smart grids are already being developed. However, industrial interface requirements are not consistent with home and building automation. For industry, the planning of energy resources and production processes is governed by facility energy planning. The responsibility of the facility energy operator and production operator lies with the facility operator and scheduler, and the operation lies with the facility energy operator and production operator. Incorrect operation of resources may affect the functional safety of personnel, facilities and the environment, and even lead to production failures and equipment damage. Large facilities may have internal production planning capabilities that can be coordinated with smart grid planning to enable long-term energy planning. In order to achieve the above objectives and better coordinate with various parties, this series of standards is specially formulated. GB /Z 45388 is intended to consist of the following two parts. --- Part 1.System interface between industrial facilities and smart grids. The purpose is to define the system interface between industrial facilities and "smart grids". interfaces to identify, configure and extend the required standards to exchange the required information, thereby supporting the integration of industrial facilities and smart grids Planning, management and control of power in the environment. --- Part 2.IoT industrial facility demand response energy management application framework. The purpose is to propose industrial The IoT application framework for industrial facility demand response energy management (FDREM) uses IoT-related communication technologies to achieve industrial Efficient information exchange between facilities. Industrial process measurement, control and automation Part 1.Interconnection between industrial facilities and smart grids System Interface

1 Scope

This document defines the interface between industrial facilities and the "Smart Grid" from the perspective of information flow. It identifies, configures and extends the required standards The new standards enable the exchange of required information to support the planning, management and control of power between industrial facilities and smart grids. This document does not include the agreements required for direct control of energy within a facility. Direct control and related responsibilities are delegated by industrial facilities to external parties. Control of distributed energy resources (DER) by entities such as grid operators.

2 Normative references

The contents of the following documents constitute essential clauses of this document through normative references in this document. For referenced documents without a date, only the version corresponding to that date applies to this document; for referenced documents without a date, the latest version (including all amendments) applies to This document. GB/T 20720.1-2019 Enterprise control system integration Part 1.Models and terminology (IEC 62264-1.2013, IDT) GB/T 40211-2021 Industrial communication network network and system security terms, concepts and models (IEC TS62443-1-1. 2009, IDT) Note. GB/T 33007-2016 Industrial communication network network and system security Establishing industrial automation and control system security procedures (IEC 62443-2-1. 2010,IDT); GB/T 35673-2017 Industrial communication network network and system security system security requirements and security levels (IEC 62443-3-3.2013, IDT); GB/T 40682-2021 Security program requirements for industrial automation and control system security IACS service providers (IEC 62443-2-4.2015, IDT); GB/T 42445-2023 Patch management in industrial automation and control system security IACS environment (IEC TR62443-2-3.2015, IDT); GB/T 42456-2023 Security technical requirements for industrial automation and control system information security IACS components (IEC 62443-4-2.2019, IDT); GB/T 42457-2023 Industrial Automation and Control System Information Security Product Security Development Lifecycle Requirements (IEC 62443-4-1.2018, IDT); GB/T 44861-2024 Safety risk assessment for industrial automation and control system safety system design (IEC 62443-3-2.2020, IDT) IEC 62443-2-1 Industrial communication networks Network and system security Part 2-1.Establishing industrial automation and control system security Note. GB/T 33007-2016 Industrial communication network network and system security Establishing industrial automation and control system security procedures (IEC 62443-2-1. 2010, IDT) IEC TR62443-3-1 Industrial communication networks Network and system security Part 3-1.Security of industrial automation and control systems ......

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