储能复合材料飞轮力学研究进展

doi:10.12028/j.issn.2095-4239.2017.0059

摘要/Abstract

摘要： 简要分析了飞轮储能的特点、应用领域及其关键技术，其中复合材料飞轮结构力学研究是提高飞轮能量密度的基础。在研究中，一般利用分析力学和有限元方法获得复合材料飞轮的应力、应变信息，运用强度准则判断其极限转速，确定工作转速下的应力状态。采用多环过盈装配、混杂纤维材料组合结构、纤维多向排布、缠绕以及机织叠层新结构设计，充分利用复合材料的可设计性来适应旋转结构的应力特征，从而提高储能密度。复合材料飞轮的储能量从早期的0.3～5 kW•h，发展到当今的30～130 kW•h，储能密度达到30～100 W•h/kg。合金钢飞轮材料费用估计700 $/kW•h，飞轮复合材料费用估计为3000 $/kW•h，复合材料飞轮的性价比离大规模储能应用还有相当的距离。

关键词: 飞轮储能, 复合材料, 结构设计, 力学研究

Abstract: The technical characteristics, application fields and key technologies of flywheel energy storage system were reviewed briefly, in which the mechanical and structural design of composite flywheel was the fundamental study for improving energy density. In particular analysis, both theoretical analysis and finite element calculation provided stress and strain information of composite flywheel at rated speed, and the ultimate speed was determined according to strength criterion. Some operations, such as multi-rings interference fitting, commingled fiber reinforced structures, multidirectional fiber alignment, winded and woven plies, were selected to enhance the energy density, making full use of the design feasibility of composite to adapt to the stress features in rotating condition. The energy capacity of composite flywheel had increased from 0.3—5 kW•h to 30—130 kW•h, and the energy density had realized 30～100 W•h/kg correspondingly. As contrast, alloy steel flywheel cost 700 $/kW•h and the cost of composite material in flywheel estimated at 3000 $/kW•h. Therefore, the low performance-price ratio restricted composite flywheels from large-scale applications.

Key words: flywheel energy storage, composite, structural design, mechanics research

王超1，戴兴建2，汪勇2，李玺1，钟国彬1. 储能复合材料飞轮力学研究进展[J]. 储能科学与技术, 2017, 6(5): 1076-1083.

WANG Chao1, DAI Xingjian2, WANG Yong2, LI Xi1, ZHONG Guobin1. Research progress of energy storage composite flywheel[J]. Energy Storage Science and Technology, 2017, 6(5): 1076-1083.

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