Contact modelling of large radius air bending with geometrically exact contact algorithm

Usage of high-strength steels in conventional air bending is restricted due to limited bendability of these metals. Large-radius punches provide a typical approach for decreasing deformations during the bending process. However, as deflection progresses the loading scheme changes gradually. Therefore, modelling of the contact interaction is essential for an accurate description of the loading scheme. In the current contribution, the authors implemented a plane frictional contact element based on the penalty method. The geometrically exact contact algorithm is used for the penetration determination. The implementation is done using the OOFEM – open source finite element solver. In order to verify the simulation results, experiments have been conducted on a bending press brake for 4 mm Weldox 1300 with a punch radius of 30 mm and a die opening of 80 mm. The maximum error for the springback calculation is 0.87° for the bending angle of 144°. The contact interaction is a crucial part of large radius bending simulation and the implementation leads to a reliable solution for the springback angle

Regression data for large radius bending

Regression prediction of large radius air bending.edition: 3status: Published onlin

Complete experimental data for large radius bending

Complete experimental data for large radius bending conducted in KU Leuven in 2016. Die openings 40, 50, 60, and 80 mm. Punch radii 10, 20, 30, and 40 mm. Used materials: AlMg3, St-37, AISI 304, AISI 316L, Domex 700 MC, and Weldox 1300. Bending was performed up to approximately 90°, 110°, 130° and 150°.edition: 1.1status: publishe

Variability data for large radius bending

Variability data of the main dataset "Complete experimental data for large radius bending". Available at https://doi.org/10.7910/DVN/P7XKVV.edition: 1.1status: Published onlin