Springback of Aluminum Alloy Sheet Metal and its Modeling

Takeshi Uemori; Satoshi Sumikawa; Syohei Tamura; Tetsuo Naka; Fusahito Yoshida

doi:10.4028/www.scientific.net/AMR.939.361

Paper Titles

Influence of Wire Reinforcement on the Forming Behaviour of Adhesive Bonded Steel Sheets
p.336

Influences of Process Conditions on Stretching Characteristics of Crystalline Polymer Film
p.342

Precision Glass Molding of High Filling Factor Micro Lens Arrays
p.349

Research on Formability of Aluminum Alloy Automotive Panels by Using Viscous Pressure Forming
p.355

Springback of Aluminum Alloy Sheet Metal and its Modeling
p.361

Theoretical and Experimental Studies on the Influence of Process Parameters on Strains and Forces of Single Point Incremental Forming
p.367

Verification of Numerical Roll Forming Loads with the Aid of Measurement Equipment
p.373

On Flow Layer Uniformity in the Co-Extrusion of Polymer Multilayer Film
p.381

Development of Looper Shape Meter and Verification Test Results in Hot Rolling
p.391

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 939Springback of Aluminum Alloy Sheet Metal and its...

Springback of Aluminum Alloy Sheet Metal and its Modeling

Abstract:

Aluminum alloy sheet metals have been widely utilized for a light weight construction of automobile. However, Aluminum sheet metals still remain one of the difficult materials to predict the accurate final shapes after press forming processes, because of several mechanical weak features such as lower Youngs modulus, strong plastic anisotropy of yield stress, Lankford values, and so on. In order to solve the problems, the present author has developed a new constitutive model called Modified Yoshida-Uemori model. The present model can describe accurate non-proportional hardening behaviors of Aluminum alloy sheet metals. In the present research, several experimental procedures were carried out to reveal the mechanical properties of Aluminum alloy sheet metals. From the comparison between experimental data and the corresponding calculated results by our constitutive model, the performance of our model was evaluated. In addition to the above mentioned research, the evaluation of some springback analyses were also carried out. The calculated results show good agreements with the corresponding experimental data.

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Periodical:

Advanced Materials Research (Volume 939)

Pages:

361-366

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.939.361

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Online since:

May 2014

Authors:

Takeshi Uemori*, Satoshi Sumikawa, Syohei Tamura, Tetsuo Naka, Fusahito Yoshida

Keywords:

Aluminum Alloy Sheet, Bauschinger Effect, Constitutive Model, Springback

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* - Corresponding Author

References

[1] F. Yoshida and T. Uemori, International Journal of Mechanical Sciences 45 (2003), 1687-1702.

Google Scholar

[2] F. Yoshida and T. Uemori, International Journal of Plasticity 18 (2002), 661-686.

Google Scholar

[3] F. Yoshida and T. Uemori, Key Engineering materials Vols 233-236 (2003), 47-58.

Google Scholar

[4] F. Yoshida, T. Uemori and S. Abe, Key Engineering materials Vols 340-341 (2007), 811-816.

Google Scholar

[5] T. Uemori, S. Sumikawa, S. Tamura, H. Akagi, T. Naka and F. Yoshida, Steel Research International, 81-9 (2010) 825-828.

Google Scholar

[6] T. Uemori, T. Kuramitsu, Y. Mito, R. Hino, T. Naka and F. Yoshida, Materials Transactions, 51-10 (2010) 1814-1818.

DOI: 10.2320/matertrans.p-m2010817

Google Scholar

[7] T. Uemori, Y. Mito, S. Sumikawa, R. Hino, F. Yoshida and T. Naka: International Journal of Modern Physics B, 22-31/32 (2008), pp.5394-539.

Google Scholar

[8] R. Hill, Proceedings of Royal Society of London, A193 (1948), 281-297.

Google Scholar

[9] R. Hill, Journal of the Mechanics and Physics of Solids (1990), 405-417.

Google Scholar