Experimental and Stowing/Deploying Dynamical Simulation of Lenticular Carbon Fiber Reinforced Polymer Thin-Walled  Tubular Space Boom

doi:10.1007/s12204-012-1230-z

上海交通大学学报（英文版） ›› 2012, Vol. 17 ›› Issue (1): 58-064.doi: 10.1007/s12204-012-1230-z

Experimental and Stowing/Deploying Dynamical Simulation of Lenticular Carbon Fiber Reinforced Polymer Thin-Walled Tubular Space Boom

LI Rui-xiong (李瑞雄), CHEN Wu-jun (陈务军), FU Gong-yi (付功义)

(Space Structures Research Center, Shanghai Jiaotong University, Shanghai 200030, China)

收稿日期:2011-07-13 出版日期:2012-02-29 发布日期:2012-03-21
通讯作者: LI Rui-xiong (李瑞雄), E-mail:ruixiong_li@126.com

Experimental and Stowing/Deploying Dynamical Simulation of Lenticular Carbon Fiber Reinforced Polymer Thin-Walled Tubular Space Boom

LI Rui-xiong (李瑞雄), CHEN Wu-jun (陈务军), FU Gong-yi (付功义)

(Space Structures Research Center, Shanghai Jiaotong University, Shanghai 200030, China)

Received:2011-07-13 Online:2012-02-29 Published:2012-03-21
Contact: LI Rui-xiong (李瑞雄), E-mail:ruixiong_li@126.com

摘要/Abstract

摘要： Abstract: The stowing and deploying experiment was conducted for three 700 mm long thin-walled tubes, and the structural behavior characteristics parameters were measured clearly, including strain, deformation and wrapping moment. 3D finite element models (FEM) were built subsequently and explicit dynamic method was used to simulate the stowing and deploying of the lenticular carbon fiber reinforced polymer (CFRP) thin-walled tubular space boom, which was designed as four-ply (45/-45/45/-45) lay-up. The stress and energy during the wrapping process were got and compared with different wrapping angular velocity, the reasonable wrapping angular velocity and effective method were conformed, and structural behavior characteristics were obtained. The results were compared and discussed as well, and the results show that the numerical results by 0.628 rad/s velocity agree well with the measured values. In this paper, the numerical procedure and experimental results are valuable to the optimization design of CFRP thin-walled tubular space boom and future research.

关键词: lenticular carbon fiber reinforced polymer thin-walled tube, space boom, explicit method, stowing and deploying, wrapping moment

Abstract: Abstract: The stowing and deploying experiment was conducted for three 700 mm long thin-walled tubes, and the structural behavior characteristics parameters were measured clearly, including strain, deformation and wrapping moment. 3D finite element models (FEM) were built subsequently and explicit dynamic method was used to simulate the stowing and deploying of the lenticular carbon fiber reinforced polymer (CFRP) thin-walled tubular space boom, which was designed as four-ply (45/-45/45/-45) lay-up. The stress and energy during the wrapping process were got and compared with different wrapping angular velocity, the reasonable wrapping angular velocity and effective method were conformed, and structural behavior characteristics were obtained. The results were compared and discussed as well, and the results show that the numerical results by 0.628 rad/s velocity agree well with the measured values. In this paper, the numerical procedure and experimental results are valuable to the optimization design of CFRP thin-walled tubular space boom and future research.

Key words: lenticular carbon fiber reinforced polymer thin-walled tube, space boom, explicit method, stowing and deploying, wrapping moment

中图分类号:

V214

LI Rui-xiong (李瑞雄), CHEN Wu-jun (陈务军), FU Gong-yi (付功义). Experimental and Stowing/Deploying Dynamical Simulation of Lenticular Carbon Fiber Reinforced Polymer Thin-Walled Tubular Space Boom[J]. 上海交通大学学报（英文版）, 2012, 17(1): 58-064.

LI Rui-xiong (李瑞雄), CHEN Wu-jun (陈务军), FU Gong-yi (付功义). Experimental and Stowing/Deploying Dynamical Simulation of Lenticular Carbon Fiber Reinforced Polymer Thin-Walled Tubular Space Boom[J]. Journal of shanghai Jiaotong University (Science), 2012, 17(1): 58-064.

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Experimental and Stowing/Deploying Dynamical Simulation of Lenticular Carbon Fiber Reinforced Polymer Thin-Walled Tubular Space Boom

Experimental and Stowing/Deploying Dynamical Simulation of Lenticular Carbon Fiber Reinforced Polymer Thin-Walled Tubular Space Boom

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