Numerical Simulation for the Multi-Point Incremental Forming Process

Multi-point forming process has been developed to shape the sheet metal with bidirectional curvature. However, the forming force usually climbs too high so that the dimension of the forming machine should be designed to meet it. To solve this problem, the multi-point incremental forming (MPIF) proce...

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Veröffentlicht in:	Applied Mechanics and Materials 2015-07, Vol.775 (Engineering Solutions for Industrial Production), p.219-223
Hauptverfasser:	Du, Ru Xu, Yang, Wan Mian, Luo, Yuan Xin, Liu, Zhi Fang
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Sprache:	eng
Schlagworte:	Computer simulation Curvature Devices Forming Mathematical analysis Mathematical models Sheet metal Stability
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container_issue	Engineering Solutions for Industrial Production
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container_title	Applied Mechanics and Materials
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creator	Du, Ru Xu Yang, Wan Mian Luo, Yuan Xin Liu, Zhi Fang
description	Multi-point forming process has been developed to shape the sheet metal with bidirectional curvature. However, the forming force usually climbs too high so that the dimension of the forming machine should be designed to meet it. To solve this problem, the multi-point incremental forming (MPIF) process was proposed in this paper. First, the principle of this new forming process was introduced. Then, the experimental device was designed. Next, the MPIF process was simulated by a finite element model. The forming effects including displacements, thickness, and curvatures were visualized and discussed in detail. It was found that there is no obvious thickness change during the forming process. The advantage of this forming process is that the shape of the sheet metals adaptable and controllable with small forming force.
doi_str_mv	10.4028/www.scientific.net/AMM.775.219
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subjects	Computer simulation Curvature Devices Forming Mathematical analysis Mathematical models Sheet metal Stability
title	Numerical Simulation for the Multi-Point Incremental Forming Process
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