曳引电梯磁流变制动装置的多物理场耦合分析与试验

中国机械工程

曳引电梯磁流变制动装置的多物理场耦合分析与试验

郑祥盘1,3;郭源帆2;唐晓腾1;陈淑梅3

1.闽江学院物理与电子信息工程学院,福州，350108
2.湖南大学机械与运载工程学院，长沙，410012
3.福州大学机械工程及自动化学院,福州，350108

出版日期:2019-08-10 发布日期:2019-08-14
基金资助:
福建省引导性项目（2019H0028）;
福州市科技计划资助项目（2018G85）;
原质检总局科技项目（2016QK015）;
闽江学院校级项目（MYK18025）

Multi-physics Coupling Analysis and Experiment of Elevator MRB

ZHENG Xiangpan1,3;GUO Yuanfan2;TANG Xiaoteng1;CHEN Shumei3

1.College of Physics and Electronic Information Engineering，Minjiang University，Fuzhou，350108
2.College of Mechanical and Vehicle Engineering,Hunan University,Changsha，410012
3.College of Mechanical Engineering and Automation,Fuzhou University,Fuzhou，350108

Online:2019-08-10 Published:2019-08-14

摘要/Abstract

摘要： 设计了一种具有双线圈结构的磁流变制动装置，该结构满足曳引电梯较大制动力矩和良好散热功能的要求。基于数学物理方法，在COMSOL Multi-physic有限元软件中建立了曳引电梯磁流变制动装置多物理场模型，即静磁场、流场与转子动力学方程相互耦合的数学模型，利用该模型进行动态仿真研究分析，揭示不同电流、转速下磁流变制动装置的制动力矩、制动时间、温度的变化规律和动态性能。最后进行了实验验证，仿真分析结果与试验结果相吻合。

关键词: 曳引电梯, 磁流变制动装置, 多物理场耦合, 制动力矩, 温度

Abstract: A MRB with dual-coil structures was designed. The requirements of elevators with large braking torques and good heat dissipation were met by the structures. Based on the mathematical physics method, the multi-physics model of elevator MRB was established in COMSOL Multi-physic finite element software, namely the static magnetic field, flow field and rotor dynamics equation, the mathematical model of coupled to each other. The model was used to research dynamic simulation, the braking torque, braking time, temperature changes and dynamic performance of the magneto-rheological braking device under different current and rotational speed were revealed. Finally, experimental verification was carried out, the simulation results were consistent with the experimental ones.

Key words: elevator, magneto-rheological brake(MRB), multi-physics coupling, braking torque, temperature

中图分类号:

TH39

郑祥盘1,3;郭源帆2;唐晓腾1;陈淑梅3. 曳引电梯磁流变制动装置的多物理场耦合分析与试验[J]. 中国机械工程.

ZHENG Xiangpan1,3;GUO Yuanfan2;TANG Xiaoteng1;CHEN Shumei3. Multi-physics Coupling Analysis and Experiment of Elevator MRB[J]. China Mechanical Engineering.

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链接本文: http://www.cmemo.org.cn/CN/

http://www.cmemo.org.cn/CN/Y2019/V30/I15/1821

参考文献

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