电磁力驱动可变间隙磁流变传动装置的分析与实验

IF 2.4 3区材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY

Journal of Intelligent Material Systems and Structures Pub Date : 2024-02-19 DOI:10.1177/1045389x241227339

Hang Gong, Jin Huang

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引用次数: 0

摘要

为解决传统磁共振装置传动性能差、扭矩调节范围小等问题，提出了一种电磁力驱动的可变工作间隙磁共振传动装置。该装置利用电磁力驱动挤压盘轴向移动挤压磁共振元件，从而改变磁共振元件的工作间隙数和有效工作厚度，提高磁共振装置的传动性能。根据线圈磁化效应，建立了电流、磁场强度和电磁力之间的关系。根据电磁力的驱动特性和 MRF 的流变特性，得出了电磁力与 MRF 工作间隙厚度和工作体积之间的非线性函数关系。利用有限元方法，对不同电流下 MRF 装置不同部位的磁路设计、磁场分布和温度变化曲线进行了理论分析，推导并计算了 MRF 扭矩传递方程，并通过实验验证了理论方程的正确性。最后，通过已建立的测试系统测试了可变工作间隙 MRF 传动装置的传动性能。结果表明，当 MRF 厚度达到 1 mm 时，两个工作间隙所需的挤压力均为 6.65 kN。当电流从 0.5 A 增加到 3.0 A 时，电磁力从 0.65 kN 增加到 6.77 kN，增加了 972.3%，工作间隙 I 中 MRF 的平均温度从 25.2°C 增加到 71.2°C，工作间隙 II 中 MRF 的平均温度从 23.5°C 增加到 48.3°C。当电流为 1.5 A 时，工作间隙 I 中的 MRF 达到磁饱和，继续增大电流至 3.0 A，两个工作间隙中的 MRF 厚度均为 1 mm，磁共振装置传递的扭矩达到 376.6 N-m，比传统磁共振装置高 72.3%。

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Analysis and experimentation of variable gap magnetorheological transmission device driven by electromagnetic force

To solve the problems of poor transmission performance and small torque regulation range of traditional MR device, a variable working gap MRF transmission device driven by electromagnetic force is proposed. The device uses electromagnetic force driving the squeeze disk to move axially to squeeze the MRF, thereby changing the number of working gaps and effective working thickness of the MRF to improve the transmission performance of the MR device. Based on the coil magnetization effect, the relationship between current, magnetic field intensity, and electromagnetic force is established. According to the driving characteristics of electromagnetic force and the rheological characteristics of MRF, a nonlinear function relationship between electromagnetic force and MRF working gap thickness and working volume is derived. Using the finite element method, a theoretical analysis of the magnetic circuit design, magnetic field distribution and temperature change profile in different parts of MRF device with different currents was conducted, the MRF torque transfer equations were deduced and calculated, and experimentally verified the correctness of the theoretical equations. Finally, the transmission performance of the variable working gap MRF transmission device is tested through the established testing system. Results show that, the required squeeze force is 6.65 kN when the MRF thickness reaches 1 mm in both working gaps. As the current increases from 0.5 to 3.0 A, the electromagnetic force increases from 0.65 to 6.77 kN, with an increase of 972.3%, the average temperature of the MRF in working gap I increases from 25.2°C to 71.2°C and the MRF in working gap II increases from 23.5°C to 48.3°C. When the current is 1.5 A, the MRF in the working gap I reaches magnetic saturation, continue to increase the current to 3.0 A, the MRF thickness in both working gaps is 1 mm, and the MR device transmits torque reach 376.6 N·m, which is 72.3% higher than that of the traditional MR device.

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来源期刊

Journal of Intelligent Material Systems and Structures 工程技术-材料科学：综合

CiteScore

5.40

自引率

11.10%

发文量

126

审稿时长

4.7 months

期刊介绍： The Journal of Intelligent Materials Systems and Structures is an international peer-reviewed journal that publishes the highest quality original research reporting the results of experimental or theoretical work on any aspect of intelligent materials systems and/or structures research also called smart structure, smart materials, active materials, adaptive structures and adaptive materials.