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基于载荷优化的大型风电机组μ-synthesis鲁棒控制 被引量:2

ROBUST μ-SYNTHESIS CONTROL FOR LOAD REDUCTION ON WIND TURBINE
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摘要 基于结构奇异值μ理论,针对大型风电机组柔性结构不确定性,提出动态载荷控制系统的鲁棒控制器设计方法。考虑结构的模态参数不确定性和高阶未建模动态,通过选取适当加权函数分离出系统的不确定部分,设计独立变桨距鲁棒μ控制器,用DK迭代算法求解控制器,以使闭环系统同时满足鲁棒性和稳定性要求,利用Matlab/S4WT软件进行仿真试验验证,仿真结果表明对载荷振动有很好的抑制效果。 Based on the structured singular value theory a generalized synthesis framework for the uncertain vibration control system and the robust controller design method are presented in order to damp the vibration of flexible structure of large scales wind turbine. Modal parameter perturbations and unmodeled high frequency dynamics of the structure are analyzed. A robust individual pitch controller is designed. The uncertainties of wind turbine structural system that fit the synthesis framework is separated by choosing weighted transfer functions. The controller is solved by DK iteration technique, and the resulting closed system has both robust stability and robust performance. The simulation results by Matlab and S4WT software showed that the method proposed is effective and the vibration of the fatigue load is damped rapidly.
出处 《太阳能学报》 EI CAS CSCD 北大核心 2017年第5期1369-1374,共6页 Acta Energiae Solaris Sinica
基金 国家自然科学基金(51207095) 辽宁省科技创新重大专项(201303005) 辽宁省自然科学基金(201202170) 沈阳市科技计划(F13-074-2-00) 辽宁省高等学校优秀人才支持计划 辽宁省科技攻关计划(2011220017 2012220042)
关键词 载荷控制 结构奇异值理论 独立变桨距控制 鲁棒性能 不确定性 load reduction μ-synthesis theory individual pitch control robust performance uncertain
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