Metals | |
Forming Process and Simulation Analysis of Helical Carbon Fiber Reinforced Aluminum Matrix Composite | |
Chunjing Wu1  Weizhong Tang1  Jun Liang1  Zihang Zhao1  | |
[1] Institute for Advanced Materials and Technology, University of Science and Technology Beijing, Beijing 100083, China; | |
关键词: helical carbon fiber; aluminum matrix composite; plastic forming; drawing; finite element simulation; | |
DOI : 10.3390/met11122024 | |
来源: DOAJ |
【 摘 要 】
In order to promote the industrialization of the large deformation technology of carbon fiber composites, this paper studies a new method of forming of helical carbon fiber reinforced aluminum matrix composite. The purpose is to solve the problem of large deformation of carbon fiber with low elongation and metal matrix with high elongation. By introducing carbon fiber with helical space structure into the aluminum matrix, the helical carbon fiber reinforced aluminum matrix composites were prepared and the subsequent drawing deformation was carried out. Here we systematically studied the large plastic deformation behavior of helical carbon fiber reinforced aluminum matrix composite via a combination of numerical simulations and experiments, and analyzed the deformation law and stress of helical carbon fiber in the deformation process. We found that the plastic deformation of the composite causes local stress concentration around the helical carbon fiber, and the helical carbon fiber will move synchronously with the aluminum matrix during the deformation, and receive the pressure from the aluminum matrix. Second, the best process parameters obtained from the simulation, that is, the drawing die angle α = 7°, when five-pass drawing experiments were carried out, the total deformation reached 58%, and the average elongation of a single pass was 18.9%. The experimental show carbon fiber reinforced aluminum matrix composite with helical space structure can achieve large deformation and high strength. The experimental and simulation are in general agreement, which verifies the correctness of the carbon fiber helical structure model.
【 授权许可】
Unknown