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Delivery: <= 9 days. True-PDF full-copy in English will be manually translated and delivered via email. GB/T 36237-2023: Wind energy generation systems - Generic electrical simulation models Status: Valid GB/T 36237: Historical versions
Basic dataStandard ID: GB/T 36237-2023 (GB/T36237-2023)Description (Translated English): Wind energy generation systems - Generic electrical simulation models Sector / Industry: National Standard (Recommended) Classification of Chinese Standard: F11 Classification of International Standard: 27.180 Word Count Estimation: 82,871 Date of Issue: 2023-05-23 Date of Implementation: 2023-05-23 Older Standard (superseded by this standard): GB/T 36237-2018 Issuing agency(ies): State Administration for Market Regulation, China National Standardization Administration GB/T 36237-2023: Wind energy generation systems - Generic electrical simulation models---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.ICS 27:180 CCSF11 National Standards of People's Republic of China Replacing GB/T 36237-2018 General Electric Simulation Model of Wind Power Generation System Released on 2023-05-23 2023-05-23 implementation State Administration for Market Regulation Released by the National Standardization Management Committee table of contentsPreface VII Introduction VIII 1 Scope 1 2 Normative references 1 3 Terms and Definitions, Abbreviations, Subscripts 1 3:1 Terms and Definitions 1 3:2 Abbreviations and subscripts 4 4 Symbols and units6 4:1 Overview 6 4:2 Symbols (units) 7 5 Model Function Specification 9 5:1 General requirements 9 5:2 Wind turbine model 10 5:3 Wind farm model 10 6 The overall structure of the model 11 6:1 General 11 6:2 Wind turbine model 11 6:3 Auxiliary equipment model 21 6:4 Wind farm model 22 7 Submodule structure 25 7:1 General 25 7:2 Pneumatic modules 26 7:3 Mechanical system module 28 7:4 Generator and converter system modules 29 7:5 Electrical Equipment Module 33 7:6 Pitch control module 34 7:7 Generator and converter control modules 36 7:8 Grid interface module 46 7:9 Wind Farm Control Module 48 7:10 Communication Module 51 7:11 Electrical components module 52 Appendix A (Informative) Calculation of Model Parameters of Power Collection System 53 A:1 Overview 53 A:2 Implementation method 53 A:3 Example 54 Appendix B (informative) Two-dimensional aerodynamic model 57 B:1 Overview 57 B:2 Wind speed input model 57 B:3 Power Input Module Parameters 58 Appendix C (Informative) Power Generation System Model Based on External Impedance 59 Appendix D (Normative) Module Symbol Library 62 D:1 Overview 62 D:2 Switch 62 D:3 Time step delay 62 D:4 Rate limiting 62 D:5 First-order filters 63 D:6 Lookup tables 64 D:7 Comparator 64 D:8 Timer 64 D:9 Anti-Water Integrator 65 D:10 Integrator with reset function 66 D:11 Clip detection first-order filter 66 D:12 Rising edge detection 66 D:13 Falling edge detection 67 D:14 Delay flag bit 67 D:15 Variable delay flag bit 68 D:16 Dead zone 69 D:17 Circuit breakers 69 References 70 Figure 1 IEEE/CIGRE Stability Terms and Definitions Joint Working Group's Classification of Power System StabilityⅧ Figure 2 General architecture of wind turbine model11 Fig: 3 Model structure of type 1A wind turbine 12 Fig: 4 Model structure of type 1B wind turbine 13 Fig: 5 Model structure of type 2 wind turbine 14 Fig: 6 Model structure of 3A and 3B wind turbines 15 Fig: 7 3A and 3B model generator control module structure 16 Figure 8 Model structure of type 4A wind turbine 18 Figure 9 Structure of 4A model generator control module 18 Figure 10 Model structure of type 4B wind turbine 19 Figure 11 Structure of 4B model generator control module 20 Figure 12 Static Var Generator model structure 21 Figure 13 Static Var Generator Converter Control Module Structure 21 Figure 14 General structure of wind farm model 22 Figure 15 General architecture of wind farm control and communication model 23 Fig: 16 Simplified single-line diagram of wind farm aggregation model 24 Fig: 17 Single line diagram of wind farm model with reactive power compensation 25 Fig:18 Block diagram of constant aerodynamic torque model 27 Figure 19 One-dimensional aerodynamic model block diagram 27 Figure 20 Block diagram of 2D aerodynamic model 28 Fig: 21 Block diagram of double-mass model 29 Fig: 22 Model block diagram of 3A type power generation system 30 Figure 23 Model block diagram of 3B type power generation system 31 Figure 24 Block diagram of type 4 power generation system model 32 Figure 25 Coordinate transformation model block diagram 33 Figure 26 Electrical equipment γ equivalent model single line diagram 33 Figure 27 Block diagram of pitch control power model 34 Fig: 28 Block diagram of pitch angle control model 35 Fig: 29 Block diagram of rotor resistance control model 36 Figure 30 Type 3 active power control model block diagram 38 Fig: 31 Block diagram of type 3 torque PI control model 39 Figure 32 Block diagram of 4A type active power control model 40 Figure 33 Block Diagram of Type 4B Active Power Control Model 41 Figure 34 Block Diagram of Reactive Power Control Model 43 Figure 35 Block Diagram of Current Limiting Model 45 Figure 36 Block diagram of constant reactive power limiting model 45 Figure 37 QP and QU clipping model block diagram 46 Figure 38 Block Diagram of Grid Protection Model 47 Figure 39 uf measurement model block diagram 48 Fig: 40 Block diagram of wind farm active power/frequency control model 49 Fig: 41 Block diagram of wind farm reactive voltage control model 51 Figure 42 Block Diagram of Communication Delay Model 51 Fig: 43 Block diagram of linear communication model with N communication variables 52 Figure A:1 Example of wind farm power collection system 55 Figure B:1 Fan aerodynamic model proposed in reference [21] 57 Figure C:1 Model Block Diagram of Type 3A Generating System with Parallel Impedance 59 Figure C:2 Model Block Diagram of Type 3B Power Generation System Containing Parallel Impedance 60 Figure C:3 Block Diagram of Type 4 Power Generation System Model with Parallel Impedance 61 Figure D:1 switch symbol 62 Figure D:2 Single integration time step delay symbol 62 Figure D:3 Rate limiting module symbol 62 Figure D:4 Realization block diagram of rate limiting module 63 Figure D:5 First-order filter symbols with clipping, rate-limiting, and freezing flags 63 Figure D:6 Implementation block diagram of a first-order filter with amplitude limiting, rate limiting, and freezing flag bits 63 Figure D:7 Freezing state execution block diagram without filtering function (T=0) 64 Figure D:8 Lookup table symbol 64 Figure D:9 Comparator symbol 64 Figure D:10 Timer symbol 64 Figure D:11 Timer function 65 Figure D:12 Anti-windup integrator symbol 65 Figure D:13 Anti-integral saturator implementation block diagram 65 Figure D:14 Integrator symbol 66 with reset function Figure D:15 Clipping detection first-order filter symbol 66 Figure D:16 Implementation block diagram of the first-order filter for clipping detection 66 Figure D:17 Rising edge detection symbol 67 Figure D:18 Rising edge detection block diagram 67 Figure D:19 Falling edge detection symbol 67 Figure D:20 Falling edge detection block diagram 67 Figure D:21 Delay flag symbol 67 Figure D:22 Implementation block diagram of delay flag bit 68 Figure D:23 Variable delay flag symbol 68 Figure D:24 Implementation block diagram of variable delay flag bit 68 Figure D:25 dead zone symbol 69 Figure D:26 Circuit breaker symbol 69 Table 1 Type 1A model sub-module 13 Table 2 Type 1B model sub-module 13 Table 3 Type 2 model submodule 15 Table 4 Type 3A model sub-module 16 Table 5 Type 3B model sub-module 17 Table 6 Type 4A model sub-module 19 Table 7 Type 4B model sub-module 20 Table 8 Static Var Generator model sub-module 22 Table 9 Wind farm control and communication model sub-module 23 Table 10 Basic model sub-modules of wind farms 24 Table 11 Submodules of wind farm model with reactive power compensation 25 Table 12 Global parameters 26 Table 13 Initialization variables in the block diagram of the module 26 Table 14 Parameters of one-dimensional aerodynamic model Table 27 Table 15 Two-dimensional aerodynamic model parameters Table 27 Table 16 Double-mass model parameters Table 28 Table 17 Model Parameters of Type 3A Power Generation System Table 29 Table 18 Model Parameters of Type 3B Power Generation System Table 30 Table 19 Model Parameters of Type 4 Power Generation System Table 32 Table 20 Reference coordinate system transformation model parameters table 32 Table 21 Electrical Equipment Model Parameters Table 33 Table 22 Pitch Control Power Model Parameters Table 34 Table 23 Parameters of pitch angle control model Table 35 Table 24 Rotor Resistance Control Model Parameters Table 36 Table 25 Type 3 Active Power Control Model Parameters Table 36 Table 26 Type 4A Active Power Control Model Parameters Table 39 Table 27 Parameters of Type 4B Active Power Control Model Table 40 Table 28 Conventional reactive power control mode MqG 41 Table 29 Low voltage ride through reactive power control mode MqFRT 41 Table 30 Reactive power control model parameters Table 42 Table 31 FFRT flag bit description 44 Table 32 Current Limiting Model Parameters Table 44 Table 33 Constant reactive power limiting model parameters Table 45 Table 34 QP and QU clipping model parameters Table 46 Table 35 Grid Protection Model Parameters Table 46 Table 36 Grid Measurement Model Parameters Table 48 Table 37 Parameter list of active power/frequency control model 49 Table 38 Reactive power and voltage control model parameters Table 50 Table 39 Communication delay model parameters Table 51 Table 40 Linear communication model parameter list 52 Table A:1 Line parameters and aggregation calculation (data per unit value uses wind farm-level reference value) 55 Table A:2 Transformer model parameters 55 Table A:3 Collection system model parameters 56 Table B:1 Function ∂pω(ν0) Calculation Table 58 Table B:2 Parameter List of Wind Speed Input Module 58forewordThis 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 replaces GB/T 36237-2018 "Electrical Simulation Model of Wind Turbine Generating Sets": Compared with GB/T 36237-2018, except Apart from structural adjustments and editorial changes, the main technical changes are as follows: a) The terms and definitions of "quasi-steady state of the system", "reaction time", "response time", "stabilization time", "transient interval" and "unbalance degree" are deleted meaning (see 3:1 of the:2018 edition); b) Added "Power Equipment", "Grid Variables", "Generator Symbol Convention", "Auxiliary Equipment", "High Voltage Ride Through", "Fault Ride Through" and "Basic Terms and definitions of "unit", "extensible interface", "access point" and "module" (see 3:1); c) Increased the functional specifications of the wind farm model (see 5:3); d) Added specifications for auxiliary equipment model and wind farm model structure (see 6:3, 6:4); e) Added specifications for grid interface module, wind farm control module, communication module and electrical component module (see 7:8~7:11): This document identically adopts IEC 61400-27-1:2020 "Wind Power Generation System Part 27-1: General Model for Electrical Simulation Model": The following minimal editorial changes have been made to this document: --- In order to coordinate with existing standards, change the name of the standard to "General Electrical Simulation Model of Wind Power Generation System": Please note that some contents of this document may refer to patents: The issuing agency of this document assumes no responsibility for identifying patents: This document is proposed by China Machinery Industry Federation: This document is under the jurisdiction of the National Wind Power Standardization Technical Committee (SAC/TC50): This document was drafted by: China Electric Power Research Institute Co:, Ltd:, Northeast Branch of State Grid Corporation of China, Shanghai Electric Wind Power Group Co:, Ltd: Co:, Ltd:, Zhejiang Yunda Wind Power Co:, Ltd:, State Grid Liaoning Electric Power Co:, Ltd:, China Shipbuilding Industry Corporation Haizhuang Wind Power Co:, Ltd: Co:, Ltd:, Xinjiang Goldwind Technology Co:, Ltd:, CRRC Shandong Wind Power Co:, Ltd:, Siemens Gamesa Renewable Energy Technology (China) Co:, Ltd: Co:, Ltd:, Guodian United Power Technology Co:, Ltd:, Longyuan Power Group Co:, Ltd:, Dongfang Electric Wind Power Co:, Ltd:, State Grid Mountain Western Provincial Electric Power Company Electric Power Research Institute, State Grid Inner Mongolia Eastern Electric Power Co:, Ltd: Electric Power Research Institute, State Grid Zhejiang Electric Power Co:, Ltd: Division Electric Power Research Institute, State Grid Jilin Electric Power Co:, Ltd: Electric Power Research Institute, Sungrow Power Supply Co:, Ltd:, China Quality Certification Center, Mingyang Smart Energy Group Co:, Ltd:, State Grid Sichuan Comprehensive Energy Service Co:, Ltd:, State Grid Shaanxi Electric Power Co:, Ltd: Electric Power Division Research Institute, CRRC Zhuzhou Electric Locomotive Research Institute Co:, Ltd:, Envision Energy Co:, Ltd:, Beijing Huizhi Tianhua New Energy Technology Co:, Ltd:, State Power Investment Group Co:, Ltd:, Zhejiang University, Shenzhen Hopewind Electric Co:, Ltd:, Huize Yuneng Investment New Energy Development Co:, Ltd: company: The main drafters of this document: Qin Shiyao, Li Shaolin, He Jing, Zhang Hongpeng, Zhu Zhiquan, Yang Jing, Sun Mingyi, Du Wei, Yan Hong, Tian Jiabin, Li Yue, Wang Shuaijie, Liu Junqi, Liu Shihong, Zhang Min, Yang Pengwei, Ma Junchao, Li Dexin, Liang Xinxin, Kang Wei, Tang Binwei, Guo Jiangtao, Miao Fenglin, Huang Rui, Deng Jun, Zhao Wei, Qu Chunhui, Zang Xiaodi, Zhang Mei, Yang Yanxia, Zhang Songtao, Shi Junwei, Liu Yixing, An Shaoru, Zhao Bingjie, Yan Liying, Zhang Chong, Wu Lijian, Li Dongpo, Zhu Lin, Liu Xia, Hua Bin, Zhao Dengli, Wei Xiaoyu: This document was first published in:2018, and this is the first revision:IntroductionThis document specifies a standard dynamic electrical simulation model for wind turbines and wind farms: Wind turbine models can be used in wind power farms or independent distributed wind turbines: In addition to the wind turbine model, the wind farm model may contain auxiliary equipment commonly used in wind farms: equipment models, such as static var generators: With the increasing penetration of wind power in the power system, transmission system operators (TSOs) and distribution system operators (DSOs) The dynamic model of wind power system needs to be used for power system stability analysis: Models built by wind turbine manufacturers are capable of simulating However, it is not suitable for the stability analysis of large-scale wind power connected to the power system: Because detailed manufacturer-proprietary models do not It will only increase the complexity of the system, increase the simulation time, and require a large amount of input data: This document specifies a general dynamic model for wind power systems that can be used for power system stability analysis: American Electrical and Electronics Engineer Stability terms and definitions [11] 1) The joint working group of the Association and the International Large Grid Organization (IEEE/CIGRE) analyzed the power system stability: class, as shown in Figure 1: Figure 1 The classification of power system stability by the IEEE/CIGRE Stability Terms and Definitions Joint Working Group[11] Based on the above classification, the model is suitable for the study of large-disturbance short-term stability of wind power generation, such as short-term voltage stability, short-term frequency stability, etc: and the short-term transient power angle stabilization in Figure 1: Therefore, the model is suitable for dynamic simulation of power system events, such as short circuit (low voltage breakdown more), off-line or load shedding [12], system disconnection, etc: The general electrical simulation model should be able to characterize the dynamic characteristics of the wind farm access point (hereinafter referred to as "grid connection point") and the output of the wind turbine: At the same time, it is suitable for the simulation research of large power grids: Therefore, the simplified model should be able to characterize the typical response of the existing technology: Note: The wind farm access point is also called the grid connection point of the wind farm: The electrical simulation model specified in this document is mainly aimed at the wind turbine fundamental frequency positive sequence 2) model, which has the following limitations: 1) Numbers in square brackets cite references: 2) This document covers both symmetrical and asymmetrical faults, but only the positive sequence component of the fundamental frequency is specified for asymmetrical faults: ---The model is not suitable for long-term stability analysis: --- The model is not suitable for studying subsynchronous problems: ---The model is not suitable for studying fluctuations caused by changes in wind speed in time and space, that is, the model does not cover turbulence, tower shadow, wind shear Change, wake: --- The model is not suitable for the study of harmonics, flicker, or other electromagnetic compatibility (EMC) disturbances in the IEC 61400 series standards: ---Wind power generation system is a highly nonlinear system, the simplified model of the system in this document is not suitable for model small signal stability Analysis of eigenvalue calculations: --- This document does not involve short-circuit calculation characteristics: ---The model is not suitable for studying the island operation of wind turbines without synchronous generators: ---The model is not suitable for scenarios where the short-circuit ratio is less than 3: The short-circuit current limit depends on the wind turbine type, control mode and its he set: When the wind turbine manufacturer can specify a lower short-circuit ratio application scenario, the application scenario should be based on IEC 61400- 27-2 for verification: --- The model is limited to the functional specifications in Chapter 5: The following stakeholders are potential users of the models in this document: ---The transmission system operator and the distribution system operator are the end users of the model, which are used to plan and dispatch the power system in operation system stability analysis; ---The wind farm developer is generally obliged to provide the simulation model of the wind farm to the power grid company before the wind farm is connected to the grid for trial operation; ---Wind turbine manufacturers generally provide wind turbine models to wind farm developers; --- The development unit of power system simulation tool software uses this document to establish a standard wind turbine simulation model in the software library; ---A certification body that independently conducts model verification of wind turbines; ---Consulting agencies use the model on behalf of grid companies and/or wind farm developers; --- Due to the confidentiality of the manufacturer's proprietary model, education and research groups can use this document for modeling: General Electric Simulation Model of Wind Power Generation System1 ScopeThis document specifies a standard electrical simulation model for wind turbines and wind farms: The models involved are applied to power system stability The analyzed positive sequence simulation model in time domain is suitable for dynamic simulation of power system short-term stability: This document defines common terms and parameters for electrical simulation models: This document specifies electrical simulation models for common topologies/configurations of wind farms: The wind farm model mainly includes wind turbines, wind farm Control and auxiliary equipment: The wind farm model is described in a modular manner, which can be applied to wind farms and different types of wind turbines: This document specifies electrical simulation models for the general topology/design/configuration of wind turbines: The purpose of the model is to characterize......Tips & Frequently Asked Questions:Question 1: How long will the true-PDF of GB/T 36237-2023_English be delivered?Answer: Upon your order, we will start to translate GB/T 36237-2023_English as soon as possible, and keep you informed of the progress. 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