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Christiansen, Peter
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Topics
Publications (13/13 displayed)
- 2019Revisiting Veerman’s interpolation method
- 2019A sheet metal necking formability diagram for nonlinear strain paths
- 2018A Study on DLC Tool Coating for Deep Drawing and Ironing of Stainless Steelcitations
- 2018A Study on DLC Tool Coating for Deep Drawing and Ironing of Stainless Steelcitations
- 2018Friction coefficients in cold forging: A global perspectivecitations
- 2017Acoustic emission monitoring of the bending under tension test
- 2017Pre-treatment of Biomass By Rolling - A Combined Experimental and Numerical Analysis
- 2014Physical modeling and numerical simulation of V-die forging ingot with central voidcitations
- 2013Open die forging of large shafts with porosity defects – physical and numerical modellingcitations
- 2012Analysis of fluid lubrication mechanisms in metal forming at mesoscopic scalecitations
- 2012Modelling the void deformation and closure by hot forging of ingot castings
- 2012Liquid lubrication in sheet metal forming at mesoscopic scale
- 2011Numerical simulation of lubrication mechanisms at mesoscopic scale
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article
A sheet metal necking formability diagram for nonlinear strain paths
Abstract
A new procedure for drawing forming limit curves is suggested. The theoretical basis for computing the forming limit curve due to diffuse necking, for nonlinear strain paths, is derived. The theoretically determined forming limit curve is compared with experimentally determined forming limits for both linear and bilinear strain paths. Reasonable agreement is observed. The procedure can also be utilized for nonlinear strain paths in general.