海上風電接入電網建模與故障穿越技術

海上風能以其資源豐富、發電利用小時數相對較高、靠近負荷中心、不占用土地和適宜大規模開發等特點，成為近年來世界各國爭相開發的新型能源。在此背景下編寫了本書，對海上風電接入電網技術進行研究。

本書共分為8章，分別為概述、雙饋風電機組建模與特性分析、永磁半直驅風電機組建模與特性分析、風電場的等值模型及特性分析、柔性直流輸電在海上風電併網中的套用、柔性直流併網系統建模及特性分析、含高比例海上風電局部電網暫態建模仿真、海上風電併網對電網穩定性的影響。

前言

第1 章 概述 ·················································································· 1

1.1 全球海上風電發展概述 ··························································1

1.2 中國海上風電發展概述 ··························································3

1.3 海上風電技術發展特點 ··························································4

1.4 海上風電場併網導則 ·····························································6

第2 章 雙饋風電機組建模與特性分析 ··············································· 20

2.1 風力渦輪機模組 ································································· 20

2.2 發電機側變流器控制模組 ····················································· 22

2.3 網側變流器控制模組 ··························································· 25

2.4 風速模組 ·········································································· 28

2.5 傳動系統模組 ···································································· 28

2.6 Crowbar 保護電路 ······························································· 29

2.7 超級電容模組 ···································································· 29

2.8 高低電壓穿越模組 ······························································ 31

2.9 高低電壓穿越控制策略 ························································ 33

2.10 整機模型及驗證 ································································ 35

第3 章 永磁半直驅風電機組建模與特性分析 ······································ 43

3.1 永磁同步發電機模組 ··························································· 43

3.2 機側變流器控制模組 ··························································· 44

3.3 網側變流器控制模組 ··························································· 45

3.4 PWM 調製模組 ·································································· 48

3.5 負序控制模組 ····································································· 49

3.6 虛擬阻尼模組 ····································································· 51

3.7 高低電壓穿越模組 ······························································· 52

3.8 Chopper 保護模組 ································································ 55

3.9 高低電壓穿越控制策略 ························································· 56

3.10 整機模型及驗證 ································································ 58

第4 章 風電場的等值模型及特性分析 ··············································· 83

4.1 風電場等值目標及思路 ························································· 83

4.2 基於風速因子的風電場分群方法 ············································· 87

4.3 風電場等值參數計算方法 ······················································ 90

4.4 等值模型仿真驗證 ······························································· 95

第5 章 柔性直流輸電在海上風電併網中的套用 ································· 102

5.1 柔性直流輸電概述 ····························································· 102

5.2 海上風電柔性直流併網特點 ················································· 105

5.3 柔性直流輸電基本工作原理 ················································· 106

5.4 柔性直流輸電併網對風電場的要求 ········································ 119

第6 章 柔性直流併網系統建模及特性分析 ······································· 123

6.1 柔性直流輸電系統及其控制 ················································· 123

6.2 關鍵控制模組及建模 ·························································· 124

6.3 併網柔直故障穿越及其控制策略 ··········································· 132

6.4 併網柔直系統與海上風電場協調控制 ····································· 140

6.5 交直流併網模式仿真對比及特性分析 ····································· 143

第7 章 含高比例海上風電局部電網暫態建模仿真 ······························ 148

7.1 局部電網構建 ··································································· 148

7.2 海上風電場穩態特性仿真 ···················································· 159

7.3 海上風電高、低電壓穿越特性仿真 ········································ 170

7.4 海上風電頻率特性仿真 ······················································· 182

7.5 柔直併網海上風電協調控制特性仿真 ···································· 185

7.6 諧波仿真及治理 ······························································· 191

7.7 工頻過電壓仿真分析 ························································· 202

第8 章 海上風電併網對電網穩定性的影響 ······································· 223

8.1 大規模海上風電脫網風險及對系統安全穩定的影響 ·················· 223

8.2 海上風電場對電能質量的影響 ············································· 234

8.3 海上風電場工頻過電壓問題及對系統的影響 ··························· 242

8.4 海上風電併網對電網規劃發展的影響 ···································· 253

余浩，工學碩士，高級工程師，廣東電網有限責任公司電網規劃研究中心三級助理技術專家，主要從事電網規劃、系統仿真及新能源併網研究。黎燦兵，工學博士，上海交通大學電氣系教授，主要從事新能源併網消納與儲能研究。林勇，工學碩士，高級工程師，廣東電網有限責任公司二級技術專家，主要從事電網規劃、系統分析及新能源併網消納研究。