Abstract
Herein, two-dimensional (2D) single-action die compaction process of copper (Cu) powder was simulated by the multiparticle finite element method (MPFEM) at particulate scale. The initial packing structure, generated by the discrete element method (DEM), was used as an input for the FEM model, where the mesh division of each particle was discretized. The evolution of macro- and microscopic properties, such as relative density, stress distribution, particle deformation, void filling behavior, and force transmission, during compaction and pressure release processes have been systematically studied. The results revealed that the force is mainly concentrated on largely deformed regions of the particles during compaction and formed a contact force network, which hindered the densification process. In the compact, the shorter side of the large void edges rendered higher stress than the longer side. On the other hand, the stress distribution of small void edges remained uniform. After pressure release, large residual stress was observed at the contact area of the adjacent particles and the maximum stress was observed at the particles’ edges. Moreover, the residual stress did not proceed to the interior of the particles. Meanwhile, the stress of large void edges has been completely released but exhibited a nonuniform distribution. The smaller fraction of void filling resulted in a larger reduction of the released stress after pressure removal. Also, the particles closer to the upper die exhibited higher average equivalent von Mises stress inside the particles during compaction and pressure release processes.
Highlights
Copper- (Cu-) based materials are widely employed in different industrial areas, such as metallurgy, mechanics, aeronautics, and aerospace
The compression pressure exceeds the critical stress of the powder and the particles induce significant plastic deformation to fill the pores. ird, at a relative density of ∼0.95, the change in relative density with respect to compaction pressure became insignificant, and the densification of the compact has transmitted from deformation of individual particles to bulk behavior
Conclusions e dynamic process of Cu powder die compaction has been modeled by the multiple-particle finite element method (MPFEM) coupled with the discrete element method (DEM)
Summary
Copper- (Cu-) based materials are widely employed in different industrial areas, such as metallurgy, mechanics, aeronautics, and aerospace. Powder metallurgy (PM) technology has gained significant industrial focus for the fabrication of complex structural components. We aimed to utilize powder metallurgy technology to prepare nozzle-twisted lance with a complex structure. It’s difficult to realize the characterization of the micromechanical properties of the forming process, it is really hard to quantitatively characterize the local density and distribution, stress distribution, and particle flow behavior in the compact during and after compaction [1,2,3,4,5,6,7]. As well known that in addition to the relative density, other properties such as local relative density and distribution and stress and distribution, as well as powder flow behavior, cannot be characterized in experiments. Geometric nonlinearity, Mathematical Problems in Engineering material nonlinearity, and contact nonlinearity of the forming process raise difficulties in the physical experiments [8,9,10,11]
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