风力发电叶片主梁弯扭耦合设计研究

    同时在叶片整体性能上，也进行了检验，如表3所示。表中数据表明，碳纤维替代玻璃纤维，主梁利用弯扭耦合进行设计，在铺层平均厚度减小11.33%的情况下，叶片在结构性能上仍有全面的提高。

 
3 小结
    弯扭耦合运用到叶片设计将是大势所趋，其技术将会逐渐成熟。本文主要对弯扭耦合设计在叶片主梁上的运用做了初步探讨对弯扭耦合控制参数进行了研究，推导出了单向层合板最简洁的耦合控制参数的表达式，并从理论上对弯扭耦合控制参数的变化范围进行了计算。计算表明，在一定铺层角度范围内，弯扭耦合程度对材料十分敏感。主梁上碳纤维替代玻璃纤维，并引入弯扭耦合设计将会使叶片在整体性能有较大提高。
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