RESEARCH ON AERODYNAMIC AND STRUCTURAL CHARACTERISTICS OF LARGE-SCALE WIND TURBINE BLADE WITH PITCHL FAULT UNDER THE CUT-OFF WIND SPEED
Wind turbine blade pitch fault is easy to cause unstable ultra-high load, which can lead to structural failure and damage. Firstly, the aerodynamic characteristics of NREL 5 MW wind turbine blades with pitch fault/success were analyzed based on the computational fluid dynamics method. Then, the two-...
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Editorial Office of Journal of Mechanical Strength
2023-12-01
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| Series: | Jixie qiangdu |
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| Online Access: | http://www.jxqd.net.cn/thesisDetails#10.16579/j.issn.1001.9669.2023.06.013 |
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| author | GAO Wei WANG YuanBo LAI RuHui LIU ZhiWen LIU YangGuang |
| author_facet | GAO Wei WANG YuanBo LAI RuHui LIU ZhiWen LIU YangGuang |
| author_sort | GAO Wei |
| collection | DOAJ |
| description | Wind turbine blade pitch fault is easy to cause unstable ultra-high load, which can lead to structural failure and damage. Firstly, the aerodynamic characteristics of NREL 5 MW wind turbine blades with pitch fault/success were analyzed based on the computational fluid dynamics method. Then, the two-way strong fluid-structure coupling and bending analysis were used to study the state of blades with pitch fault under typical azimuths. The results show that average flapwise torque of the blade with pitch fault under the cut-out wind speed is 13. 8 times that of the blade with successful pitch, and the flow field wake of the former is more obvious. The fluctuation range of blade flapwise torque under two-way strong fluid-structure coupling is significantly wider than that without fluid-structure coupling, and the maximum tip displacement of the blade with pitch fault is 14. 1 times that of the blade with successful pitch. For the four typical azimuth angles of 0°, 60°, 120°, and 180°, the bending moment, tip displacement, bending degree, end effect, wake range and strength of the blade with pitch fault gradually decrease with the increase of the angle. Buckling analysis reveals that the buckling factor increases with the enlargement of azimuth angle, and the first-order buckling factor of 180°azimuth is 20.2% higher than that of 0° azimuth. |
| format | Article |
| id | doaj-art-5af7c2c93e25425598d62f3c0ab80917 |
| institution | Kabale University |
| issn | 1001-9669 |
| language | zho |
| publishDate | 2023-12-01 |
| publisher | Editorial Office of Journal of Mechanical Strength |
| record_format | Article |
| series | Jixie qiangdu |
| spelling | doaj-art-5af7c2c93e25425598d62f3c0ab809172025-01-15T02:44:52ZzhoEditorial Office of Journal of Mechanical StrengthJixie qiangdu1001-96692023-12-01451361137055272744RESEARCH ON AERODYNAMIC AND STRUCTURAL CHARACTERISTICS OF LARGE-SCALE WIND TURBINE BLADE WITH PITCHL FAULT UNDER THE CUT-OFF WIND SPEEDGAO WeiWANG YuanBoLAI RuHuiLIU ZhiWenLIU YangGuangWind turbine blade pitch fault is easy to cause unstable ultra-high load, which can lead to structural failure and damage. Firstly, the aerodynamic characteristics of NREL 5 MW wind turbine blades with pitch fault/success were analyzed based on the computational fluid dynamics method. Then, the two-way strong fluid-structure coupling and bending analysis were used to study the state of blades with pitch fault under typical azimuths. The results show that average flapwise torque of the blade with pitch fault under the cut-out wind speed is 13. 8 times that of the blade with successful pitch, and the flow field wake of the former is more obvious. The fluctuation range of blade flapwise torque under two-way strong fluid-structure coupling is significantly wider than that without fluid-structure coupling, and the maximum tip displacement of the blade with pitch fault is 14. 1 times that of the blade with successful pitch. For the four typical azimuth angles of 0°, 60°, 120°, and 180°, the bending moment, tip displacement, bending degree, end effect, wake range and strength of the blade with pitch fault gradually decrease with the increase of the angle. Buckling analysis reveals that the buckling factor increases with the enlargement of azimuth angle, and the first-order buckling factor of 180°azimuth is 20.2% higher than that of 0° azimuth.http://www.jxqd.net.cn/thesisDetails#10.16579/j.issn.1001.9669.2023.06.013Wind turbinePitch faultFluid-structure couplingAerodynamic characteristicStructural responseBuckling analysis |
| spellingShingle | GAO Wei WANG YuanBo LAI RuHui LIU ZhiWen LIU YangGuang RESEARCH ON AERODYNAMIC AND STRUCTURAL CHARACTERISTICS OF LARGE-SCALE WIND TURBINE BLADE WITH PITCHL FAULT UNDER THE CUT-OFF WIND SPEED Jixie qiangdu Wind turbine Pitch fault Fluid-structure coupling Aerodynamic characteristic Structural response Buckling analysis |
| title | RESEARCH ON AERODYNAMIC AND STRUCTURAL CHARACTERISTICS OF LARGE-SCALE WIND TURBINE BLADE WITH PITCHL FAULT UNDER THE CUT-OFF WIND SPEED |
| title_full | RESEARCH ON AERODYNAMIC AND STRUCTURAL CHARACTERISTICS OF LARGE-SCALE WIND TURBINE BLADE WITH PITCHL FAULT UNDER THE CUT-OFF WIND SPEED |
| title_fullStr | RESEARCH ON AERODYNAMIC AND STRUCTURAL CHARACTERISTICS OF LARGE-SCALE WIND TURBINE BLADE WITH PITCHL FAULT UNDER THE CUT-OFF WIND SPEED |
| title_full_unstemmed | RESEARCH ON AERODYNAMIC AND STRUCTURAL CHARACTERISTICS OF LARGE-SCALE WIND TURBINE BLADE WITH PITCHL FAULT UNDER THE CUT-OFF WIND SPEED |
| title_short | RESEARCH ON AERODYNAMIC AND STRUCTURAL CHARACTERISTICS OF LARGE-SCALE WIND TURBINE BLADE WITH PITCHL FAULT UNDER THE CUT-OFF WIND SPEED |
| title_sort | research on aerodynamic and structural characteristics of large scale wind turbine blade with pitchl fault under the cut off wind speed |
| topic | Wind turbine Pitch fault Fluid-structure coupling Aerodynamic characteristic Structural response Buckling analysis |
| url | http://www.jxqd.net.cn/thesisDetails#10.16579/j.issn.1001.9669.2023.06.013 |
| work_keys_str_mv | AT gaowei researchonaerodynamicandstructuralcharacteristicsoflargescalewindturbinebladewithpitchlfaultunderthecutoffwindspeed AT wangyuanbo researchonaerodynamicandstructuralcharacteristicsoflargescalewindturbinebladewithpitchlfaultunderthecutoffwindspeed AT lairuhui researchonaerodynamicandstructuralcharacteristicsoflargescalewindturbinebladewithpitchlfaultunderthecutoffwindspeed AT liuzhiwen researchonaerodynamicandstructuralcharacteristicsoflargescalewindturbinebladewithpitchlfaultunderthecutoffwindspeed AT liuyangguang researchonaerodynamicandstructuralcharacteristicsoflargescalewindturbinebladewithpitchlfaultunderthecutoffwindspeed |