Tool shape design in the sheet bending process by inverse analysis of springback

Abstract

Elastic recovery of formed parts in unloading, known as springback, causes shape error in the final product of sheet metal forming processes. The final product shape deviates from the target geometry owing to the springback. In the present paper, an analytical approach is proposed for springback analysis in the sheet bending process. By development of this approach for inverse springback analysis, an inverse algorithm for compensation of the springback error is proposed. In the inverse algorithm, the modified die geometry is obtained from the target geometry by inverse springback modelling. The proposed compensation algorithm is adapted to apply the finite element (FE) method for the inverse analysis of springback. The capability of the proposed algorithms is verified in the asymmetric bending process. The optimum die shape for producing the target geometry is obtained in a few trials. Both algorithms present high accuracy and convergence rate. The results of the analytical approach are in accordance with the FE approach with high precision. The accuracy of the presented algorithms is investigated by performing an experimental asymmetric bending test. The optimum shape obtained from the compensation algorithm is applied to produce the bending die. The obtained product matches to the target geometry with high precision. The analytical algorithm is fast and accurate for springback compensation in the bending processes. The FE algorithm is not as fast as the analytical approach, but it enables more complicated three-dimensional processes to be analysed.

Keywords

tool design inverse analysis springback sheet bending process optimization

References

Cho

J. R.

Moon

S. J.

Kang

S. S.

, ‘Finite element investigation on springback characteristics in sheet metal U-bending process’ J. Mater. Process. Technol. 141 (2003): 109–116.

Schmoeckel

Beth

, ‘Springback reduction in draw-bending process of sheet metals’ Ann. CIRP 42 (1993): 339–342.

Sunseri

Cao

Karafllis

A. P.

Boyce

M. C.

, ‘Accommodation of springback error in channel forming using active binder force control: Numerical simulations and experiments’ Trans. ASME 118 (1996): 426–435.

Liu

Y. C.

, ‘The effect of restraining force on shape deviations in flanged channel’ J. Engng Mater. Technol. 110 (1988): 389–394.

Gan

Wagoner

R. H.

, ‘Die design method for sheet springback’ Int. J. Mech. Sci. 46 (2004): 1097–1113.

Gan

Wagoner

R. H.

Mao

Price

Rasouli

, ‘Practical methods for the design of sheet formed components’ J. Engng Mater. Technol. 126 (2004): 360–367.

Karafillis

A. P.

Boyce

M. C.

, ‘Tooling and binder design for sheet metal forming processes compensating springback error’ Int. J. Machine Tools Mfg 36 (1996): 503–526.

Zhang

, ‘Iterative FEM die surface design to compensate for springback in sheet metal stampings’ In Proceedings of NUMIFORM 95, Ithaca, New York, June 1995, pp. 637–641.

Anagnostou

E. L.

, ‘Optimized tooling design algorithm for sheet metal forming over reconfigurable compliant tooling’ In Proceedings of the 8th Conference on Numerical methods in industrial forming processes (NUMIFORM 2004), Colombus, Ohio, 13–17 June 2004, AIP Conference Proceedings Vol. 712, pp. 741–748 (American Institute of Physics, New York).

10.

Lingbeek

Huetink

Ohnimus

Petzoldt

Weiher

, ‘The development of a finite elements based springback compensation tool for sheet metal products’ J. Mater. Process. Technol. 169 (2005): 115–125.

11.

Cheng

H. S.

Cao

Xia

Z. C.

, ‘An accelerated springback compensation method’ Int. J. Mech. Sci. 49 (2007): 267–279.

12.

Behrouzi

Mollaei

Shakeri

, ‘A new approach for inverse analysis of springback in a sheet-bending process’ Proc. IMechE, Part B: J. Engineering Manufacture 222 (2008): 1363–1374 DOI: 10.1243/09544054JEM1191.

13.

Panthi

S. K.

Ramakrishnan

Pathak

K. K.

Chouhan

J. S.

, ‘An analysis of springback in sheet metal bending using finite element method (FEM)’ J. Mater. Process. Technol. 186 (2007): 120–124.

14.

Ling

Y. E.

Lee

H. P.

Cheok

B. T.

, ‘Finite element analysis of springback in L-bending of sheet metal’ J. Mater. Process. Technol. 168 (2005): 296–302.

15.

Firat

Kaftanoglu

Eser

, ‘Sheet metal forming analyses with an emphasis on the springback deformation’ J. Mater. Process. Technol. 196 (2008): 135–148.

16.

Vin

L. J.

Streppel

A. H.

Singh

U. P.

Kals

H. J. J.

, ‘A process model for air bending’ J. Mater. Process. Technol. 57 (1996): 48–54.

17.

Dongjuan

Zhenshan

Xueyu

Yuqiang

, ‘An analytical model for predicting springback and side wall curl of sheet after U-bending’ Comput. Mater. Sci. 38 (2007): 707–715.

18.

Kim

Nargundkar

Altan

, ‘Prediction of bend allowance and springback in air bending’ J. Mfg Sci. Engng 129 (2007): 342–351.

19.

Leu

D. K.

Hsieh

C. M.

, ‘The influence of coining force on spring-back reduction in V-die bending process’ J. Mater. Process. Technol. 196 (2008): 230–235.