Finite element modeling on micro-machining of graphene-reinforced aluminum matrix composites

The International Journal of Advanced Manufacturing Technology - Tập 124 - Trang 97-110 - 2022
Hao Yu1, Zhenpeng He1, Jinbo Li2, Baichun Li1, Jia Xin1, Lianzheng Yao1, Fangchao Yan3
1College of Aeronautical Engineering, Civil Aviation University of China, Tianjin, China
2School of Mechanical Engineering, Shenyang University of Technology, Shenyang, China
3Tianjin Bu Er Technology Co, Ltd, Tianjin, China

Tóm tắt

Graphene-reinforced metal matrix composites have received a lot of attention from academia and industry due to their excellent mechanical properties. In this paper, the machinability of graphene-reinforced aluminum metal matrix composites (Gr/Al MMCs) during micro-machining is investigated by finite element method. A three-dimensional modeling program based on the Python language is developed independently; this program can generate graphene with random distribution of orientation and position. A three-dimensional two-phase finite element model considering the cutting edge radius is established to simulate the micro-machining process of Gr/Al MMCs. Embedded element method is used in the model to more efficiently simulate the interaction behavior between graphene and aluminum matrix during micro-machining. The accuracy of the model is verified by indirect experiments. Stress distribution, tool-graphene interaction, chip formation, cutting force, and specific cutting energy during micro-machining are investigated with different uncut chip thickness. The simulation results show that graphene inhibits stress propagation, resulting in the formation of a stress field with irregular contours within the matrix. Continuous serrated chips are generated during the cutting process. The addition of graphene increases the magnitude and fluctuation of cutting forces.

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Thông tin
Thông tin xuất bản

The International Journal of Advanced Manufacturing Technology

Tập 124

97-110

Thông tin tác giả