Global-cumulative incremental hole-flanging by tools with complementary-shape cross section

A novel method using special featured tools is proposed for double-sided incremental hole-flanging (DSIHF), which can perform successful hole-flanging in one-step due to the globally cumulated deformation mode. Tools with complementary-shape section curves are used to constrain the material flow for...

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Veröffentlicht in:	International journal of material forming 2019-09, Vol.12 (5), p.899-906
Hauptverfasser:	Zhang, Huan, Ren, Huaqing, Chen, Jun, Cao, Jian
Format:	Artikel
Sprache:	eng
Schlagworte:	CAE) and Design Computational Intelligence Computer simulation Computer-Aided Engineering (CAD Curvature Curves Deformation Engineering Geometric accuracy Hole flanging Machines Manufacturing Materials Science Mechanical Engineering Original Research Processes
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container_title	International journal of material forming
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creator	Zhang, Huan Ren, Huaqing Chen, Jun Cao, Jian
description	A novel method using special featured tools is proposed for double-sided incremental hole-flanging (DSIHF), which can perform successful hole-flanging in one-step due to the globally cumulated deformation mode. Tools with complementary-shape section curves are used to constrain the material flow for better part geometry. The proposed method has been verified by two cases: an axisymmetric circular flanging and an asymmetric clover flanging. Experimental results demonstrate that the new method is feasible for flanging of complex shapes with simplified tools, reduces processing time and improves geometric accuracy. Moreover, numerical simulations were conducted to show that the proposed method has a different deformation mode compared with the conventional incremental forming. Specifically, the circumferential strain becomes the dominant strain, and its value depends on the in-plane curvature and the distance from the part edge.
doi_str_mv	10.1007/s12289-018-01460-5
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Tools with complementary-shape section curves are used to constrain the material flow for better part geometry. The proposed method has been verified by two cases: an axisymmetric circular flanging and an asymmetric clover flanging. Experimental results demonstrate that the new method is feasible for flanging of complex shapes with simplified tools, reduces processing time and improves geometric accuracy. Moreover, numerical simulations were conducted to show that the proposed method has a different deformation mode compared with the conventional incremental forming. 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subjects	CAE) and Design Computational Intelligence Computer simulation Computer-Aided Engineering (CAD Curvature Curves Deformation Engineering Geometric accuracy Hole flanging Machines Manufacturing Materials Science Mechanical Engineering Original Research Processes
title	Global-cumulative incremental hole-flanging by tools with complementary-shape cross section
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