Achieving High Strains in Sheet Metal Characterization Using the In-Plane Torsion Test-Reference-Cited by-同舟云学术

Achieving High Strains in Sheet Metal Characterization Using the In-Plane Torsion Test

Published:2013-06 Issue: Volume:554-557 Page:77-85
ISSN:1662-9795
Container-title:Key Engineering Materials
language:
Short-container-title:KEM

Author:

Yin Qing¹,Kolbe Jörg¹,Haupt Marco¹,Tekkaya A. Erman¹

Affiliation:

1. TU Dortmund University

Abstract

The in-plane torsion test is used to determine plastic flow curves for sheet metals. Very high strains of up to an equivalent strain of 1.0 can be measured since there are no edge effects in a plane torsion specimen. In combination with optical strain measurement, an efficient evaluation method for this test was developed. However, the achievable strain varies for each material. The slippage between the inner clamps and the specimen was found to be one main limiting effect. In order to improve the clamping capability, different surface corrugations are applied at the inner clamping tool. Four sheet materials, DC06, DP600, AA6016, and AA5182 are selected for testing this new clamping setup. While the flow curve of DC06 is determined until a strain of 1.0 and above, such high values cannot be achieved for the other materials. It can be shown that the measurable strain can be increased by the choice of the surface corrugation features at the inner clamping. For the DP steel and the aluminum alloys, the flow curve can be determined until equivalent plastic strains of 0.5 to 0.6, which is also a significant improvement compared to many other sheet metal testing methods.

Publisher

Trans Tech Publications, Ltd.

Subject

Mechanical Engineering,Mechanics of Materials,General Materials Science

Link

https://www.scientific.net/KEM.554-557.77.pdf

Reference13 articles.

1. W. Panknin, Der hydraulische Tiefungsversuch und die Ermittlung von Fließkurven. PhD thesis, University Stuttgart, (1959).

2. A. Hannon, P. Tiernan, A review of planar biaxial tensile test systems for sheet metal. J. Mater. Process. Technol. 198: 1-3 (2008) 1-13.

3. N. Kanetake, Y. Tozawa, T. Kato, S. Aiba, Effect of texture on deformation behavior of aluminum sheets. Journal of Japan Institute of Light Metals. 31: 5 (1981) 307-312.

4. B. Zillmann, M. Härtel, T. Halle, T. Lampke, M. F. -X. Wagner, Flow Behavior of Automotive Aluminium Sheets During in-Plane Uniaxial and Biaxial Compression Loading. Steel research international, Special edition: 10th International Conference on Technology of Plasticity (ICTP 2011), Aachen, Vol. 1 (2011).

5. S. Bouvier, H. Haddadi, P. Levee,C. Teodosiu. Simple shear tests: experimental techniques and characterization of the plastic anisotropy of rolled sheets at large strains. J. Mater. Process. Technol. 172 (2006) 96-103.

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