Formability Improvement Technique for Heated Sheet Metal Forming by Partial Cooling

A forming process for heated sheet metal, such as hot-stamping, has limited use in deformable shapes. Higher temperature areas which have not yet come into contact with dies are more easily deformed; therefore, local deformation occurs at these areas which leads to breakage. To improve the formabili...

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Veröffentlicht in:	Key engineering materials 2014-09, Vol.622-623, p.279-283
Hauptverfasser:	Iwata, Noritoshi, Yogo, Yasuhiro, Ishida, Kenjiro, Iwata, Takamichi, Takeda, Kenichi, Ota, Eiichi
Format:	Artikel
Sprache:	eng
Schlagworte:	Cooling Deep drawing Deformation Dies Formability Forming Sheet metal Temperature dependence Temperature distribution
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creator	Iwata, Noritoshi Yogo, Yasuhiro Ishida, Kenjiro Iwata, Takamichi Takeda, Kenichi Ota, Eiichi
description	A forming process for heated sheet metal, such as hot-stamping, has limited use in deformable shapes. Higher temperature areas which have not yet come into contact with dies are more easily deformed; therefore, local deformation occurs at these areas which leads to breakage. To improve the formability of heated sheet metal, a deformation control technique utilizing the temperature dependence of flow stress is proposed. This technique can suppress local deformation by partial cooling around potential cracking areas to harden them before forming. In order to apply this technique to a variety of product shapes, a procedure to determine a suitable initial temperature distribution for deep drawing and biaxial stretching was developed with a coupled thermal structural simulation. In this procedure, finite elements exceeding forming limit strain are highlighted, and an initial temperature distribution is defined with areas of decreased temperature around the elements to increase their resistance to deformation. Subsequently, the partial cooling technique was applied to a deep drawing test with a heated steel sheet. The results of the experiment showed that the proposed technique improved 71% in the forming limit depth compared with results obtained using a uniform initial temperature distribution.
doi_str_mv	10.4028/www.scientific.net/KEM.622-623.279
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subjects	Cooling Deep drawing Deformation Dies Formability Forming Sheet metal Temperature dependence Temperature distribution
title	Formability Improvement Technique for Heated Sheet Metal Forming by Partial Cooling
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