An Active Magnetic Saddle Based on Electro-Permanent Magnetic Adhesion Mechanism

Volume 2: Computer Technology and Bolted Joints; Design and Analysis Pub Date : 2022-07-17 DOI:10.1115/pvp2022-84528

Hongsheng Zhang, Yanbin Li, K. Guo, Jian Jiang

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Abstract

In this paper, a novel transport technique for pressure vessels based on electro-permanent magnet (EPM) technology is proposed. The magnetic force and the resulting transport gripping force (TGF) are applied by controllable permanent magnets rather than conventional electromagnet or permanent magnet technology, and the current is only required at the moment of loading or unloading the TGF. The EPM system is convenient in control, and low in energy consumption. The experimental device including magnetic chuck, web of foundation girder and other components is constructed based on the EPM characteristics and requirements of transported equipment. The EPM units are used to generate magnetic force to realize loading and unloading of TGF. The principles and advantages of EPM transport technique are first elaborated with theoretical derivation and magnetic field simulation. Then, a series of experiments such as electrical circuit, magnetic field and tensile test were performed for the EPM chuck and magnetic saddle. It is demonstrated that the TGF applied by the designed system is large enough for the transportation of the pressure vessel. Also, the energy saving is significant using the EPM transportation system.

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一种基于电永磁吸附机理的主动磁鞍

本文提出了一种基于电永磁(EPM)技术的新型压力容器传输技术。磁力和由此产生的输运夹持力(TGF)是由可控永磁体施加的，而不是传统的电磁铁或永磁体技术，并且仅在加载或卸载TGF时需要电流。EPM系统控制方便，能耗低。根据EPM的特点和运输设备的要求，构建了包括磁性吸盘、基础梁腹板等部件的实验装置。EPM单元产生磁力，实现TGF的加载和卸载。本文首先通过理论推导和磁场模拟阐述了EPM输运技术的原理和优点。然后，对EPM卡盘和磁鞍进行了电路、磁场和拉伸等一系列实验。结果表明，所设计的系统所施加的TGF对于压力容器的输送是足够大的。此外，使用EPM运输系统节能效果显著。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Volume 2: Computer Technology and Bolted Joints; Design and Analysis

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