超导磁悬浮复合材料储能飞轮转子优化设计

doi:10.3969/j.issn.2095-4239.2013.03.002

储能科学与技术 ›› 2013, Vol. 2 ›› Issue (3): 185-188.doi: 10.3969/j.issn.2095-4239.2013.03.002

超导磁悬浮复合材料储能飞轮转子优化设计

汤继强, 张永斌, 刘刚

北京航空航天大学"惯性技术"重点实验室; 北京航空航天大学"新型惯性仪表与导航技术"国防重点学科实验室,北京100191

收稿日期:2013-04-12 出版日期:2013-06-19 发布日期:2013-06-19
通讯作者: 刘刚,博士,教授,博士生导师,主要研究领域为磁悬浮姿控/储能飞轮的控制,电机与磁轴承建模,先进控制等.
作者简介:张永斌(1987--),男,硕士研究生,研究领域为磁悬浮控制力矩陀螺和磁悬浮飞轮的结构设计优化,E-mail:zhang6350668@foxmail.com

Analysis and optimization of an interference fitted composite material rotor of a superconducting energy storage flywheel

TANG Jiqiang, ZHANG Yongbin, LIU Gang

Science and Technology on Initial Laboratory,Beijing 100191,China; Fundamental Science on Novel Instrument & Navigation System Technology Laboratory,Beijing 100191,China

Received:2013-04-12 Online:2013-06-19 Published:2013-06-19

摘要/Abstract

摘要： 为了提高储能飞轮的储能密度,设计了一种金属轮毂和3个复合材料圆环过盈装配的磁悬浮外转子飞轮;采用平面应力方法建立了转子的应力模型,以复合材料圆环的厚度和环间过盈量为优化变量,以储能量为优化目标,在强度约束条件下,通过序列二次规划法对转子进行优化设计,将转子的极限转速从50000 r/min提高到57797 r/min,储能密度由40 W∙h/kg升高到53.8 W∙h/kg,储能量升高34.5%.该研究方法和结果可以为复合材料储能飞轮的设计,制造和优化提供依据.

关键词: 储能飞轮, 复合材料转子, 多学科优化设计, 过盈配合

Abstract: To achieve a high specific energy density, a metal rotor without a shaft is designed to consists of a hollow hub and three composite cylindrical rings fitted in interference. A mathematical model is formulated for the stress distribution using a simplified two dimensional stress model. Optimization is carried out by using the total storage energy density as the objective function and the thickness of the composite rings and the interference value between rings as the variables. It is found that the optimization increases the upper limit of the rotor speed from 50000 r/min to 57797 r/min, and the corresponding total storage energy capacity increases by 34.5%, from 1147 W·h to 1543 W·h.

Key words: energy storage flywheel, composite material rotor, multidisciplinary design, interference fit

中图分类号:

V249.1

汤继强, 张永斌, 刘刚. 超导磁悬浮复合材料储能飞轮转子优化设计[J]. 储能科学与技术, 2013, 2(3): 185-188.

TANG Jiqiang, ZHANG Yongbin, LIU Gang. Analysis and optimization of an interference fitted composite material rotor of a superconducting energy storage flywheel[J]. Energy Storage Science and Technology, 2013, 2(3): 185-188.

参考文献

[1] Wu Gang(吴刚),Liu Kun(刘昆),Zhang Yulin(张育林). Application and study of magnetic bearing flywheel technology[J]. Journal of Astronautics (宇航学报),2005,26(3):389-390.
[2] Bitterly J G. Flywheel technology: Past, present, and 21st century projections[J]. IEEE Aerospace and Electronic Systems Magazine ,1998,13:13-16.
[3] Portnov G,Uthe A N,Cruz I,Fiffe R P,Arias F. Design of steel-composite multirim cylindrical flywheels manufactured by winding with high tension and in situ curing[J]. Mechanics of Composite Materials ,2005,41(3):241-254.
[4] Ma Li(马立),Wang Cunbin(王存斌),Bai Yue(白越), Wu Yihui(吴一辉). Design and manufacture of composites integrated energy storage and attitude control flywheel for satellites[J]. Journal of Astronautics (宇航学报),2009,30(1):290-292.
[5] Ha S K,Kim S J,Nasir S U,Han S C. Design optimization and fabrication of a hybrid composite flywheel rotor[J]. Compos . Struct .,2012,94(11):3290-3299.
[6] Arvin A C,Bakis C E. Optimal design of press-fitted filament wound composite flywheel rotors[J]. Composite Structures ,2006,72(1):47-57.
[7] Naki Tutuncu. Effect of anisotropy on stress in rotating discs[J]. Int. J. Mech. Sci ,1995,37(8):873-881.
[8] Ha S K,Kim S J,Nasir S U,Han S C. Effects of rotor size and epoxy system on the process-induced residual strains within multi-rings composite rotors[J]. Journal of Composite Materials ,2004,38(10):871-885.
[9] Ha S K,Kim H T,Sung T H. Measurement and prediction of process-induced residual strains in thick wound composite rings[J]. Journal of Composite Materials ,2003,37(14):1223-1237.
[10] Ha S K,Jeong J Y. Effects of winding angles on through-thickness properties and residual strains of thick filament wound composite rings[J]. Composite Science and Technology ,2005,65(1):27-35.
[11] Callioglu H,Topcu M,Altan G. Stress analysis of curvilinearly orthotropic rotating discs under mechanical and thermal loading[J]. Journal of Reinforced Plastics and Composites ,2005,24(8):831-838.
[12] Wen Shaobo,Jiang Shuyun. Optimum design of hybrid composite multi-ring flywheel rotor based on displacement method[J]. Composite Science and Technology ,2012,72(9):982-988.
[13] Qin Yong(秦勇),Xia Yuanming(夏源明),Mao Tianxiang(毛天祥). Simplified and fine analyses of the full deformation and stress of press fit of the hollow multi-ring composite flywheel[J]. Acta . Materiae Compositae Sinica (复合材料学报),2003,20(5):95-99.
[14] Tang Jiqiang,Fang Jiancheng,Ge S K. Roles of superconducting magnetic bearings and active magnetic bearings in attitude control and energy storage flywheel[J]. Physica C: Superconductivity ,2012,483:178-185.

超导磁悬浮复合材料储能飞轮转子优化设计

Analysis and optimization of an interference fitted composite material rotor of a superconducting energy storage flywheel

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