Co-Simulation Research of the Mechanical-Hydraulic-Control Coupling System of ITER Tractor 被引量：1

Co-Simulation Research of the Mechanical-Hydraulic-Control Coupling System of ITER Tractor

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摘要 The virtual prototyping models of the mechanical, hydraulic and control system of the ITER tractor were built with CATIA, ADAMS and MATLAB/Simulink respectively according to its heavy load and high precision characteristics, and the data transfer between the different models was accomplished by the integration interface between different software. Consequently the virtual experimental platform for the multi-disciplinary co-simulation was established. A co-simulation study of the mechanical-hydraulic-control coupling system of the ITER tractor was carried out. The synchronization servo control of parallel hydraulic cylinders was implemented, and the tracking control of the preconcerted trajectory of the hydraulic cylinders was realized on the established experimental platform. This paper presents the optimization design and technology rebuilding for the complicated coupling system with its theoretic foundation and co-simulation virtual experimental platform. The virtual prototyping models of the mechanical, hydraulic and control system of the ITER tractor were built with CATIA, ADAMS and MATLAB/Simulink respectively according to its heavy load and high precision characteristics, and the data transfer between the different models was accomplished by the integration interface between different software. Consequently the virtual experimental platform for the multi-disciplinary co-simulation was established. A co-simulation study of the mechanical-hydraulic-control coupling system of the ITER tractor was carried out. The synchronization servo control of parallel hydraulic cylinders was implemented, and the tracking control of the preconcerted trajectory of the hydraulic cylinders was realized on the established experimental platform. This paper presents the optimization design and technology rebuilding for the complicated coupling system with its theoretic foundation and co-simulation virtual experimental platform.

作者杨秀清骆敏舟梅涛姚达毛

机构地区 Institute of Intelligent Machines(IIM) University of Science and Technology of China Institute of Plasma Physics

出处《Plasma Science and Technology》 SCIE EI CAS CSCD 2009年第3期334-340,共7页 等离子体科学和技术（英文版）

基金 supported by design of the ITER transfer casks system (ITER International Team) ITA 23-01-CN the Key Laboratory of Biomimetic Sensing and Advanced Robot Technology,Anhui Province,China

关键词 CO-SIMULATION mechanical-hydraulic coupling PID control of integral separation hydraulic synchronization servo system co-simulation, mechanical-hydraulic coupling, PID control of integral separation, hydraulic synchronization servo system

分类号 TL625 [核科学技术—核技术及应用]

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