风电叶片芯隙制造缺陷的表征与修复

IF 3.5 3区材料科学 Q1 ENGINEERING, MECHANICAL

Journal of Sandwich Structures & Materials Pub Date : 2022-08-14 DOI:10.1177/10996362221122046

Paul Murdy, Scott Hughes, D. Barnes

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引用次数: 3

摘要

各种风力涡轮机叶片部件，如抗剪腹板和蒙皮，通常使用纤维增强复合材料夹层结构，其核心材料为轻木或泡沫。在制造过程中，型芯间隙缺陷可能由叶片模具中相邻的泡沫或轻木型芯板的错位引起。了解堆芯间隙对风力涡轮机叶片结构完整性的影响以及如何减轻其影响非常重要。这项研究表征了环氧树脂和下一代热塑性复合材料在制造和机械层面上的芯隙缺陷的影响。对常见的修复方法进行了评估和比较。使用在制造过程中嵌入热电偶收集的温度数据，与使用图像映射技术、光学显微镜和长梁弯曲的机械表征获得的芯间隙缺陷特征，对多种缺陷尺寸进行比较。结果表明，固化过程中的峰值放热温度与芯间隙大小密切相关。长梁弯曲试验确定，在纯弯曲载荷下，横向芯间隙会对环氧树脂和热塑性复合材料夹层结构的极限面板强度产生实质性影响（强度降低高达25%），尽管缺陷本身的大小对强度降低的幅度影响较小。支持图像映射技术表明，复合材料面板因芯部间隙而变形是导致过早失效的原因之一。本研究中使用的修复方法对提高之前存在核心间隙缺陷的夹芯板的极限强度几乎没有作用。热塑性面板的修复导致最终面板强度的进一步损失。这项研究表明，迫切需要开发一种兼容的热塑性聚合物修复树脂系统，并为下一代可回收热塑性风叶片开发适当的树脂专用修复程序。

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Characterization and repair of core gap manufacturing defects for wind turbine blades

Various wind turbine blade components, such as shear webs and skins, commonly use fiber-reinforced composite sandwich structures with a core material like balsa or foam. During manufacturing, core gap defects may result from the misalignment of adjacent foam or balsa core sheets in the blade mold. It is important to understand the influence that core gaps have on the structural integrity of wind turbine blades and how to mitigate their influence. This research characterized the effects of core gap defects at the manufacturing and mechanical levels for both epoxy and next-generation thermoplastic composites. Common repair methods were assessed and compared. Multiple defect sizes were compared using temperature data gathered with thermocouples embedded during manufacturing to core gap defect characteristics obtained using image-mapping techniques, optical microscopy, and mechanical characterization by long beam flexure. Results showed that peak exothermic temperatures during curing were closely related to core gap size. The long beam flexure tests determined that transverse core gaps under pure bending loads can have a substantial effect on the ultimate facesheet strength of both epoxy and thermoplastic composite sandwich structures (up to 25% strength reduction), although the size of the defect itself had less of an influence on the magnitude of the strength reduction. The supporting image-mapping techniques indicated that the distortion of the composite facesheets by the core gaps contributed to the premature failures. The repair methods used in this study did very little to improve the ultimate strength of the sandwich panels that previously had core gap defects. The repair of the thermoplastic panel resulted in a further loss in ultimate facesheet strength. This research demonstrated that there is a vital need for the development of a compatible thermoplastic polymer repair resin system and appropriate resin specific repair procedures for the next generation of recyclable thermoplastic wind blades.

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来源期刊

Journal of Sandwich Structures & Materials 工程技术-材料科学：表征与测试

CiteScore

9.60

自引率

2.60%

发文量

审稿时长

7 months

期刊介绍： The Journal of Sandwich Structures and Materials is an international peer reviewed journal that provides a means of communication to fellow engineers and scientists by providing an archival record of developments in the science, technology, and professional practices of sandwich construction throughout the world. This journal is a member of the Committee on Publication Ethics (COPE).