Abstract
Abstract Incremental sheet forming (ISF) is a highly versatile and flexible process for producing low batches of sheet metal parts. Although finite element (FE) method is a key approach in the study of material deformation in metal forming processes, the application of FE in ISF process is still limited. This is due to the enormous simulation time required for ISF processes. Focusing on this problem, this paper presents a new selective element fission (SEF) approach for simulation of ISF process based on LS-DYNA. In the approach, the computational efficiency is improved by reducing the unnecessary calculations of elements outside the localized deformation zone in the ISF process. The introduction of a background mesh for simulation data storage and a separate simulation mesh with varied mesh density for simulation ensures both the efficiency of computation and accuracy of results. To verify the proposed SEF method, two ISF case problems including a hyperbolic cone part and a pyramid part are studied by comparing to the conventional FE approach and the H-adaptive approach in terms of the CPU time, the forming load, the final part profile, and thickness distribution. The influence of two key factors: element size ratio and toolpath segment length is also studied. The results suggested that the developed SEF approach can save the CPU time by up to 74 % with satisfactory accuracy as compared to conventional FE method, which demonstrates both the effectiveness and robustness of the developed SEF approach.
Highlights
Incremental sheet forming (ISF) is a flexible sheet forming method, which is commonly used for rapid prototyping of sheet metal parts in small batch manufacturing and for customized products
The developed fast simulation method is based on selective element fission approach, which enables the reduction of the number of elements involved in simulation by representing the localized deformation nature in the ISF process
This inaccuracy may be attributed to the unstable element thickness: the variation of sheet thickness may affect the plastic work and the load required for deformation
Summary
Incremental sheet forming (ISF) is a flexible sheet forming method, which is commonly used for rapid prototyping of sheet metal parts in small batch manufacturing and for customized products. Due to the incremental deformation nature, ISF process has obvious advantages over conventional forming processes including greater formability, reduced forming load and lower cost of tooling and forming equipment [1] These advantages have attracted increased attention in the metal forming research community, and this process was considered to have the potential to revolutionize sheet metal forming industry [2]. Progress has been made in many aspects of ISF technology, including in-depth understanding in deformation mechanism [3], development of new toolpath generation strategies [4], improved the geometric accuracy [5], new method for thickness prediction [6], and new material processing methods [7]. These advances have helped to make the ISF technology closer for practical applications in different industrial sectors
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