考慮台灣極端風況 建立離岸風力發電機塔柱易損性曲線

以作者查詢圖書館館藏

、以作者查詢臺灣博碩士

、以作者查詢全國書目

、勘誤回報

、線上人數：36

、訪客IP：3.144.92.54

姓名

張景淳(Ching Chun Zhang) 查詢紙本館藏

畢業系所

土木工程學系

論文名稱

考慮台灣極端風況建立離岸風力發電機塔柱易損性曲線
(Developing the fragility curves for the offshore wind turbine tower under Taiwan′s extreme wind field)

相關論文

★ 台灣地區整合性災害潛勢查詢平台建置之研究

檔案

[Endnote RIS 格式]

[Bibtex 格式]

[相關文章]

[文章引用]

[完整記錄]

[館藏目錄]

[檢視]

[下載]

本電子論文使用權限為同意立即開放。
已達開放權限電子全文僅授權使用者為學術研究之目的，進行個人非營利性質之檢索、閱讀、列印。
請遵守中華民國著作權法之相關規定，切勿任意重製、散佈、改作、轉貼、播送，以免觸法。

摘要(中)

考量國內離岸風電產業發展剛起步，相關保險業者對於離岸風機損率尚無法準確評估，大多數保單皆交由國際再保公司進行再保，導致我國資金外流，為促進我國產業發展，本研究以巨災風險評估角度切入，針對離岸風機易損性模組，建立適用於台灣颱風極端風況塔柱易損性曲線。
本研究選用額定功率 5MW 及 10MW 參考風機，以美國 NREL 開發之 OpenFAST軟體執行模擬，假設三種情境分別為機艙轉向 8 度、機艙轉向 15 度及單支扇葉旋向 70度，分析風速 30m/s 至 100m/s 區間內，離岸風機整體結構受力行為。同時藉由 R 語言以拉丁超立方模擬 200 個相似塔柱斷面，根據歐洲規範 EN 1993-1-6【49】計算塔柱軸向特徵挫曲應力，判斷 200 個塔柱斷面在各種情境下之損壞程度，建立離岸風機塔柱
易損性曲線，藉此推估不同尺寸、不同情境及不同風速作用下，離岸風機塔柱結構發生損壞之機率。
考量台灣地理位置每年約有 3 至 4 個颱風侵襲，我國規範 CNS15176-1【19】除採納國際規範 IEC 61400-1 既已訂定之等級指標，將風力機劃分三級，另外增設 T 級基準，將原本規定承受 10 分鐘基準風速，由最高規格之第 I 級 50m/s 提升至 T 級57m/s。根據本研究最終結果顯示，在機艙轉向錯位 8 度且風速達至 57m/s 以後，離岸風機塔柱結構才開始發生挫曲損壞，說明目前參考風機之設計規格皆滿足 T 級基準風速所規定之要求；在機艙轉向錯位 15 度之情境模擬結果，顯示風速在 40m/s 便開始出現塔柱挫曲損壞；在單支扇葉旋向 70 度之情境模擬結果，顯示風速 35m/s 左右塔柱挫曲損壞已開始發生。三種情境作用下，單支扇葉旋向 70 度造成之損壞情況最為嚴重，且在相對較低風速時損壞率已達至 100%。

摘要(英)

Taiwan’s offshore wind energy industry just begun in past few years. Most of the insurers in Taiwan have difficulty to estimate the failure rate of offshore wind turbines due to wind excitation, as the consequence they cede most of the premium to international reinsurance companies. This situation causes the capital outflow of our country. In this study, we develop the fragility curves of the wind turbines due to strong wind for the fragility
module which is one of the five modules of catastrophe risk model of offshore wind turbines.
Two reference wind turbines (RWT) are selected with rated power of 5MW and 10MW respectively. We choose three scenarios to be simulated using OpenFAST software developed
by NREL to obtain the response of the wind turbines excited by wind. The combinations of conditions are wind speed from 30 m/s to 100 m/s, yaw of nacelle 8 degree and 15 degree and
blade pitch 70 degree. Latin Hypercube Sampling is used to simulate 200 cross section of towers with similar RWT specifications. Based on the European standard EN 1993-1-6
【49】, tower characteristic buckling stress are calculated and compared with strength of cross section of towers. The failure situation was analyzed and the fragility curves of wind turbine tower are built accordingly. Fragility curves can be used to predict the failure rate of tower structure in different conditions which include different power rating of wind turbines, different type of machinery malfunctions, different weather conditions and different wind speeds.
There are three to four typhoons hit Taiwan every year. Our country’s standard CNS 15176-1【19】which is based on international standard IEC 61400-1, divides wind turbines
into three levels and adds T class. The highest level was class I in the past with 10 minutes average wind speed of 50 m/s. The current highest level is class T with average speed of 57 m/s. This study concludes that the buckling of tower occurs always after the wind speed reaches 57 m/s with yaw of nacelle of 8 degree; yaw of nacelle of 15 degree, tower bucking occurs after the wind speed reaches 40 m/s. In the case of one of blade’s pitch is set to 70 degree, tower buckling occurs after wind speed reaches 35 m/s.
The fragility curves of offshore wind turbine are built which can be used in the vulnerability module of catastrophe risk mode of wind turbine for risk management purpose.

關鍵字(中)

★ 離岸風力發電機
★ 易損性曲線
★ NREL
★ OpenFAST
★ 軸向特徵挫曲應力

關鍵字(英)

★ Offshore wind turbine
★ Fragility curve
★ NREL
★ OpenFAST
★ characteristic buckling stress

論文目次

摘要 .........................................................................................i
ABSTRACT ....................................................................................ii
圖目錄 ........................................................................................ x
表目錄 ..................................................................................... xvi
第一章緒論 ................................................................................. 1
1.1 研究背景與動機 ........................................................ 1
1.2 研究目的 ................................................................... 1
1.3 論文內容 ................................................................... 2
第二章文獻回顧 .......................................................................... 3
2.1 離岸風力發電機之組成介紹 ...................................... 3
2.1.1 離岸風力發電機組成樹狀圖 ................................ 4
(1) 離岸風力發電風場 .............................................. 4
(2) 離岸風力發電機 .................................................. 4
(3) 電力基礎建設 ...................................................... 4
2.1.2 轉子及機艙內部介紹 ........................................... 9
(1) 轉子 rotor........................................................... 9
(2) 旋向驅動器 pitch drive ....................................... 9
(3) 機艙 nacelle ....................................................... 9
(4) 煞車器 break ...................................................... 9
(5) 低速轉軸 low speed shaft .................................... 9
(6) 齒輪箱 gearbox ................................................... 9
(7) 高速轉軸 high speed shaft ................................... 9
(8) 發電機 generator .............................................. 10
(9) 熱交換器 heat exchanger ................................... 10
(10)控制器 controller .............................................. 10
(11)風速計 anemometer........................................... 10
(12)風標 wind vane ................................................. 10
(13)轉向驅動器 yaw drive ....................................... 10
(14)塔柱 tower........................................................ 10
2.1.3 基礎結構種類介紹 ............................................ 12
(1) 重力式基礎結構 Gravity Based Foundations ...... 13
(2) 單樁式基礎結構 Monopile Foundations............... 14
(3) 三角套管式/三樁式基礎結構 Tripod / Tripile
Foundations ....................................................... 16
(4) 套管式基礎結構 Jackets Foundations .................. 17
(5) 浮動式基礎結構 Floating Foundations ................ 20
2.2 台灣能源結構概況 ................................................... 22
2.3 台灣離岸風電相關政策 ........................................... 25
2.3.1 風力發電四年推動計畫 ..................................... 25
(1) 示範獎勵計畫 .................................................... 26
(2) 潛力場址要點 .................................................... 27
(3) 區塊開發 ........................................................... 27
2.4 台灣首座離岸風場 -「 Formosa1」介紹 ..................... 28
2.5 台灣離岸風電相關規範 ........................................... 28
2.5.1 風力機等級 ....................................................... 29
2.5.2 正常風剖面模型(NWP) ...................................... 30
2.5.3 極端風速模型 (EWM)與 T 級基準風速條件 ......... 30
2.5.4 極端擾流模型 (ETM) .......................................... 31
2.5.5 設計負載情況 Design Load Case (DLC) .............. 31
2.6 風機模型介紹 .......................................................... 35
2.6.1 NREL 5-MW 參考風機 ...................................... 35
2.6.2 DTU 10-MW 參考風機 ...................................... 38
2.6.3 IEA Wind Task37 ............................................... 41
2.6.4 IEA Wind Task 37 10MW 參考風機 .................... 43
2.6.5 IEA Wind Task 37 15MW 參考風機 .................... 45
2.6.6 參考風機規格比較 ............................................ 47
2.7 巨災風險評估模型介紹 ........................................... 50
2.7.1 巨災事件模組 (Event Module) ............................. 51
2.7.2 危害度模組 (Hazard Module) .............................. 52
2.7.3 易損性模組 (Vulnerability Module) ..................... 52
2.7.4 財務分析模組 (Financial Module)........................ 52
2.7.5 風險暴露模組 (Exposure Module)........................ 52
2.7.6 離岸風機平均損失估算 ..................................... 52
第三章執行分析之軟體介紹 ....................................................... 55
3.1 FAST 軟體架構 ...................................................... 55
3.1.1 ElastoDyn .......................................................... 57
(1) 自由度相關參數設置 ......................................... 58
(2) 初始條件相關參數設置 ..................................... 58
(3) 風機組態相關參數設置 ..................................... 59
(4) 塔柱及扇葉相關參數設置 .................................. 61
3.1.2 AeroDyn ............................................................ 61
3.1.3 InflowWind ....................................................... 64
3.1.4 ServoDyn .......................................................... 65
(1) 扇葉旋向(Blade Pitch)系統相關參數設置 ........... 65
(2) 發電機系統相關參數設置 .................................. 66
(3) 高速運轉軸 (High-Speed Shaft，HHS)相關參數設置 66
(4) 機艙轉向(Nacelle Yaw)系統相關參數設置 ......... 67
3.1.5 HydroDyn .......................................................... 68
3.1.6 SubDyn ............................................................. 69
3.1.7 其他相關輔助程式 ............................................ 76
(1) BeamDyn ........................................................... 76
(2) MAP++.............................................................. 76
(3) MoorDyn ........................................................... 76
(4) FEAMooring ...................................................... 76
(5) OrcaFlex Interface ............................................. 76
(6) IceDyn/IceFloe .................................................. 76
3.2 OpenFAST 軟體架構介紹 ......................................... 76
3.3 程式執行相關設定操作 ........................................... 77
3.3.1 楊氏模數及材料性質之相關設定 ....................... 79
3.3.2 扇葉旋向(Blade Pitch)系統之相關設定 .............. 83
(1) 扇葉旋向(Blade Pitch)系統之角度定義 .............. 84
(2) 扇葉旋向(Blade Pitch)系統之操作測試 .............. 86
3.3.3 機艙轉向(Nacelle Yaw)系統之相關設定 ............. 88
(1) 機艙轉向(Nacelle Yaw)系統之角度定義 ............. 89
(2) 機艙轉向(Nacelle Yaw)系統之操作測試 ............. 90
(3) 機艙轉向(Nacelle Yaw)系統之程式問題 ............. 93
(4) 機艙轉向(Nacelle Yaw)系統之數值不穩定問題 .. 98
3.3.4 TurbSim-模擬分析之風況輸入檔建立 ............... 100
(1) TurbSim 風況檔建立流程 ................................. 105
(2) 以 TurbSim 輸出不同風況之差異測試 .............. 105
第四章易損性曲線建立及分析案例 .......................................... 108
4.1 研究流程概述 ........................................................ 108
4.2 以 FAST 分析風機結構行為 ................................... 109
4.2.1 假設分析情境 .................................................. 109
4.2.2 透過 MATLAB 將 FAST 分析結果彙整 ............. 111
(1) MATLAB 程式介紹 ......................................... 111
(2) FAST 分析結果彙整 ........................................ 111
4.3 根據 EN 1993-1-6 計算薄殼結構軸向挫曲應力 ....... 114
4.3.1 歐洲標準規範 EN 1993-1-6 介紹 ...................... 114
4.3.2 薄殼結構之幾何形狀定義 ................................ 114
4.3.3 薄殼結構之邊界條件 ....................................... 115
4.3.1 軸向彈性臨界挫曲應力計算 ............................ 116
4.3.2 軸向挫曲相關參數計算 ................................... 117
4.3.3 軸向挫曲細長比計算 ....................................... 118
4.3.4 軸向特徵挫曲應力計算 ................................... 119
4.4 以 R 語言模擬不同塔底斷面尺寸 ........................... 119
4.4.1 R 語言介紹 ..................................................... 119
4.4.2 歐洲鋼材 S355 介紹 ......................................... 120
4.4.3 標準差、變異係數及常態分佈相關介紹 ........... 121
4.4.4 對數分佈相關介紹 .......................................... 123
4.4.5 蒙地卡羅法 (Monte Carlo Method)介紹 ............. 124
(1) 蒙地卡羅法命名由來 ....................................... 124
(2) 布豐投針試驗 (Buffon′s Needle Problem)........... 124
(3) 蒙地卡羅法求圓周率 ....................................... 126
4.4.6 拉丁超立方抽樣(Latin Hypercube Sampling)介紹 128
4.4.7 模擬塔底斷面過程之說明 ................................ 128
4.5 考慮 T 級基準風速之研究方法介紹 ....................... 129
4.6 易損性曲線建立說明 ............................................. 131
4.6.1 韋伯 (Weibull)分佈介紹 .................................... 131
4.6.2 易損性曲線擬合 .............................................. 132
4.7 參考風機案例分析結果 ......................................... 133
4.7.1 5MW-機艙轉向 8 度之易損性曲線 ................... 135
4.7.2 5MW-機艙轉向 15 度之易損性曲線 ................. 136
4.7.3 5MW-單支扇葉旋向 70 度之易損性曲線 .......... 138
4.7.4 5MW T 級基準 -機艙轉向 8 度之易損性曲線 ..... 139
4.7.5 5MW T 級基準 -機艙轉向 15 度之易損性曲線 ... 141
4.7.6 5MW T 級基準 -單支扇葉旋向 70 度之易損性曲線 142
4.7.7 10MW-機艙轉向 8 度之易損性曲線 ................. 144
4.7.8 10MW-機艙轉向 15 度之易損性曲線 ................ 145
4.7.9 10MW-單支扇葉旋向 70 度之易損性曲線 ......... 147
4.7.10 10MW T 級基準-機艙轉向 8 度之易損性曲線 ... 148
4.7.11 10MW T 級基準-機艙轉向 15 度之易損性曲線 . 150
4.7.12 10MW T 級基準-單支扇葉旋向 70 度之易損性曲線 151
第五章結論與建議 ................................................................... 153
5.1 研究結論 ............................................................... 153
5.2 建議 ...................................................................... 158
參考文獻 .................................................................................... 159

參考文獻

【1】 Dublin Array Offshore Wind Farm Project. (2021 年 3 月 10 日). 擷取自https://dublinarray.com/.
【2】 R.can Rooij. (October 2001). Terminology, Reference Systems and Conventions.
【3】 M, Keiser; B, Snyder. (2012). Offshore Wind Energy System Components, In Offshore Wind Energy Cost Modelling, Green Energy and Technology. London: Springer-Verlag.
【4】 Tiago João Fazeres Ferradosa. (2015). REVIEW OF DESIGN
PROCEDURES FOR MONOPILE OFFSHORE WIND STRUCTURES. ORLANDO.
【5】 Malhotra Sanjeev. (2007). Design and Construction Considerations for Offshore Wind Turbine Foundations. California.
【6】 N. Dedic. (2014). Offshore Wind Turbine Foundations - State of the Art and Future Challenges. Denmark: Ramboll Offshore Wind.
【7】 Sanjeev Malhotra. (2011). Selection, Design and Construction of Offshore
【8】 Fazeres - Ferradosa T. (無日期). Risk analysis of dynamic scour protection systeams for the optimization of offshore foundations. Porto In Press: Faculdade de Engenharia da Universidade do Porto.
【9】 Offshore Wind Farms in Europe. (2015 年 4 月 18 日). 擷取自http://studentaccess.emporia.edu/~lgerber1/Intro%20to%20GSA%20project.html.
【10】 Tiago João Fazeres Ferradosa. (2015). REVIEW OF DESIGN PROCEDURES FOR MONOPILE OFFSHORE WIND STRUCTURES.
ORLANDO.
【11】 L. Devaney. (2012). Breaking Wave Loads and Stress Analysis of Jacket Structures Supporting Offshore Wind Turbines.
【12】 Z. Saleem. (2011). Alternatives and modifications of Monopile foundation or its installation technique for noise mitigation. Netherlands.
【13】 Pasin Plodpradit , Osoon Kwon, Van Nguyen Dinh , Jimmy Murphy and KiDu Kim. (2020). Suction Bucket Pile–Soil–Structure Interactions of Offshore Wind Turbine Jacket Foundations Using Coupled Dynamic Analysis.
【14】 Renewable Energy Focus. (2015 年 4 月 22 日). 擷取自
http://www.renewableenergyfocus.com/view/8169/hywind-floatingoffshore-wind-turbinefoundation/.
【15】 S. a. W. Energy. (2015 年 4 月 22 日). Offshore Wind Industry. 擷取自
http://www.offshorewindindustry.com/news/multiple-opportunities.
【16】 4COffshore. (2015 年 3 月 2 日). 擷取自 http://www.4coffshore.com/.
【17】經濟部能源局. (2018/10). 經濟部能源局 107 能源統計手冊(修訂版). 台灣: 經濟部.
【18】 (106/08). 風力發電 4 年推動計畫(核定版). 台灣: 經濟部.
【19】中華民國國家標準. (107/10/30). CNS 15176-1 風力機－第 1 部：設計要求. 中華民國.
【20】財團法人國家實驗研究院國家地震工程研究中心. (107.10). 台灣離岸風機支撐結構設計準則. 台灣.
【21】 J. Jonkman, S. Butterfield, W. Musial, and G. Scott. (2009). Definition of a 5-MW Reference Wind Turbine for Offshore System Development. America: National Renewable Energy Laboratory.
【22】 Malcolm, D. J. and Hansen, A. C. (August 2002). WindPACT Turbine RotorDesign Study. National Renewable Energy Laboratory.
【23】 About the Program: WindPACT. (2005 年 anuary 月 4 日). 擷取自National Renewable Energy Laboratory,: http://www.nrel.gov/wind/windpact/
【24】 Smith, K. (June 2001). WindPACT Turbine Design Scaling Studies; Technical Area 2: Turbine, Rotor, and Blade Logistics. National Renewable Energy Laboratory.
【25】 Kooijman, H. J. T., Lindenburg, C., Winkelaar, D., and van der Hooft, E. L. (September 2003). DOWEC 6 MW Pre-Design: Aero-elastic modeling of the DOWEC 6 MW pre-design in PHATAS. Petten, the Netherlands: Energy Research Center of the Netherlands.
【26】 Lindenburg, C. (December 2002). Aeroelastic Modelling of the LMH64-5 Blade. Petten, the Netherlands: Energy Research Center of the Netherlands.
【27】 Goezinne, F. (September 2001). Terms of reference DOWEC. DOWEC Dutch Offshore Wind Energy Converter 1997–2003 Public Reports.
【28】 Technical Data Multibrid M5000. (2004 年 November 月 1 日). 擷取自 Multibrid Technology:
http://www.multibrid.com/download/Datenblatt_M5000_eng.pdf
【29】 The Concept in Detail. (2005 年 January 月 4 日). 擷取自 Multibrid Technology: http://www.multibrid.com/english/concept.htm
【30】 de Vries, E. (2004 年 November 月 1 日). Multibrid: ‘A New Offshore Wind Turbine Contender’. 擷取自 Renewable Energy World: http://www.renewable energyworld.com/articles/article_display.cfm ARTICLE_ID=272695&p=121
【31】 Wind Turbine Blades, Product Overview, Standard Products – Max. Rated Power <=5000 kW. (2005 年 January 月 4 日). 擷取自 LM Glasfiber Group:
http://www.lmglasfiber.dk/UK/Products/Wings/ProductOverView/50000kw.htm
【32】 REpower 5M. (2005 年 January 月 4 日). 擷取自 REpower Systems:
http://www.repower.de/typo3/fileadmin/download/produkte/5m_uk.pdf
【33】 REpower Systems AG — Renewable Energy for the Future. (2005 年January 月 4 日). 擷取自 REpower Systems: http://www.repower.de/
【34】 Christian Bak, Frederik Zahle, Robert Bitsche, Taeseong Kim, Anders Yde, Lars Christian Henriksen, Anand Natarajan,Natarajan,Morten Hartvig Hansen. (July 2013). Description of the DTU 10 MW Reference Wind Turbine. DTU Wind Energy.
【35】 iea wind. (2021 年 4 月 21 日). 擷取自 About IEA Wind:
https://community.ieawind.org/about/about-iea-wind
【36】 Pietro Bortolotti, Helena Canet Tarr′es, Katherine Dykes, Karl Merz, Latha Sethuraman, David Verelst, and Frederik Zahle. (May 23, 2019). IEA Wind Task 37 on Systems Engineering in Wind Energy WP2.1 Reference Wind Turbines. International Energy Agency.
【37】 Evan Gaertner, Jennifer Rinker, Latha Sethuraman,Frederik Zahle, Benjamin Anderson, Garrett Barter,......,Anthony Viselli. (March 2020). IEA
Wind Task 37 Definition of the IEA Wind 15-Megawatt Offshore Reference Wind Turbine. National Renewable Energy Laboratory.
【38】 Key Trends and Statistics. (2019). Offshore Wind in Europe. WindEurope: WindEurope.
【39】黃劭雋. (107/6). 利用側推分析建立風力發電機塔柱易損性曲線. 台灣.
【40】 Bonnie Jonkman and Jason Jonkman. (July 26, 2016). FAST v8.16.00a-bjj. National Renewable Energy Laboratory.
【41】 (Jan 14, 2021). OpenFAST Documentation Release v2.5.0. National Renewable Energy Laboratory.
【42】 Jason M. Jonkman, Marshall L. Buhl Jr. (August 2005). FAST User’s Guide. National Renewable Energy Laboratory.
【43】 Hermann-Josef Wagner & Jyotirmay Mathur. (無日期). Introduction to Wind Energy -Basics, Technology and Operation. Springer.
【44】 J.M. Jonkman, G.J. Hayman, B.J. Jonkman, R.R. Damiani. (無日期). AeroDyn v15 User’s Guide and Theory Manual. National Renewable Energy Laboratory.
【45】 Andy Platt, Bonnie Jonkman, and Jason Jonkman. (July 26, 2016). InflowWind User’s Guide. National Wind Technology Center.
【46】 J.M. Jonkman, A.N. Robertson, G.J. Hayman. (無日期). HydroDyn User’s Guide and Theory Manual. National Renewable Energy Laboratory.
【47】 Rick Damiani, Jason Jonkman, and Greg Hayman. (September 2015). SubDyn User’s Guide and Theory Manual. National Renewable Energy Laboratory.
【48】 B. J. Jonkman. (June 1, 2016). TurbSim User’s Guide v2.00.00. National Renewable Energy Laboratory.
【49】 (February 2007). Eurocode 3 - Design of steel structures - Part 1-6: Strength and. CEN.
【50】 Material S355 Steel Properties, Comparison, Equivalent Grade, EN 10025-2. (2021 年 3 月 31 日). 擷取自 The World Material:
https://www.theworldmaterial.com/material-s355-steel-en-10025/
【51】 NORMALITY TEST. (2021 年 4 月 1 日). 擷取自 ★ ★ 艾比酷統計顧問 ★ ★ EPIC DATA STUDIO: https://epicdatastudio.xyz/normality-test/

指導教授

蔣偉寧許文科(WEI LING CHIANG WEN KO XU)

審核日期

2021-7-30

推文