风电机组偏航系统实验平台
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摘要
以主动式偏航系统结构为依据,设计了适用于实验研究和探索的偏航系统实验平台。该实验平台由偏航实训台和偏航操作台构成,依据实验平台设计了相关实验内容。该实验平台丰富了风电机组实验仪器,为学生分析风电机组偏航系统创造了实验条件,促进了学生对偏航系统的学习,并提高了学生的实践能力。
Based on the structure of active yaw system, an experimental platform of the yaw system suitable for experimental research and exploration is designed. This experimental platform consists of the yaw training platform and yaw operation platform, and according to the experimental platform, the relevant experimental contents are designed. This experimental platform enriches the experimental instruments of wind turbines, creates experimental conditions for students to analyze the yaw system of wind turbines, promotes students' learning of yaw system and improves their practical ability.
Based on the structure of active yaw system, an experimental platform of the yaw system suitable for experimental research and exploration is designed. This experimental platform consists of the yaw training platform and yaw operation platform, and according to the experimental platform, the relevant experimental contents are designed. This experimental platform enriches the experimental instruments of wind turbines, creates experimental conditions for students to analyze the yaw system of wind turbines, promotes students' learning of yaw system and improves their practical ability.
引文
[1] 刘超.基于KHC算法的风力发电机组偏航控制系统设计[D].长春:长春工业大学,2018.
[2] 褚金.兆瓦级风电机组智能偏航液压系统虚拟设计[D].兰州:兰州理工大学,2008.
[3] 张皓,刘万久,黎俞琳,等.风力发电偏航控制系统研究及技术展望[J].四川水泥,2018(6):358.
[4] 张宇.风力发电智能偏航系统的设计与研究[D].北京:北方工业大学,2015.
[5] 陈实.MW级风力发电系统单机电气控制技术研究:无功补偿和偏航控制系统[D].南京:南京航空航天大学,2004.
[6] 田骥骜,陈子顺,王哲,等.基于TRIZ的工艺创新技术预测过程模型研究[J].机械工程师,2017(9):5-8.
[7] 王克让,戎瑞雪,白国义,等.有机化学课程中的诺贝尔化学奖与创新人才培养[J].高等理科教育,2017(2):79-83.
[8] TAO Z,ZHU K D.Discussion on advanced mathematics teaching and cultivation on innovative and practical ability[J].Journal of Shenyang Institute of Engineering,2012(4):538-540.
[9] 鄂加强,陈燕,李振强,等.兆瓦级风力发电机组偏航系统主动偏航特性分析[J].湖南大学学报(自然科学版),2014,41(1):57-62.
[10] 沈小军,杜万里.大型风力发电机偏航系统控制策略研究现状及展望[J].电工技术学报,2015,30(10):196-203.
[11] TEKIN G I.Design and simulation of an integrated active yaw control system for road vehicles[J].International Journal of Vehicle Design,2010,52(1):5-19.
[2] 褚金.兆瓦级风电机组智能偏航液压系统虚拟设计[D].兰州:兰州理工大学,2008.
[3] 张皓,刘万久,黎俞琳,等.风力发电偏航控制系统研究及技术展望[J].四川水泥,2018(6):358.
[4] 张宇.风力发电智能偏航系统的设计与研究[D].北京:北方工业大学,2015.
[5] 陈实.MW级风力发电系统单机电气控制技术研究:无功补偿和偏航控制系统[D].南京:南京航空航天大学,2004.
[6] 田骥骜,陈子顺,王哲,等.基于TRIZ的工艺创新技术预测过程模型研究[J].机械工程师,2017(9):5-8.
[7] 王克让,戎瑞雪,白国义,等.有机化学课程中的诺贝尔化学奖与创新人才培养[J].高等理科教育,2017(2):79-83.
[8] TAO Z,ZHU K D.Discussion on advanced mathematics teaching and cultivation on innovative and practical ability[J].Journal of Shenyang Institute of Engineering,2012(4):538-540.
[9] 鄂加强,陈燕,李振强,等.兆瓦级风力发电机组偏航系统主动偏航特性分析[J].湖南大学学报(自然科学版),2014,41(1):57-62.
[10] 沈小军,杜万里.大型风力发电机偏航系统控制策略研究现状及展望[J].电工技术学报,2015,30(10):196-203.
[11] TEKIN G I.Design and simulation of an integrated active yaw control system for road vehicles[J].International Journal of Vehicle Design,2010,52(1):5-19.