Research on the Drilling Temperature Field Model of the Unidirectional Carbon Fiber Epoxy Composites

Guo Ping Zhu; Yong Jie Bao; Hang Gao

doi:10.4028/www.scientific.net/AMR.565.478

Paper Titles

Cutting Forces and Tool Wear in Dry Milling of Ti6Al4V
p.454

Development of Al₂O₃/TiCN Ceramic Composite Cutting Tool and Research on its Milling Performance
p.460

Ball-End Milling of Cr12MoV Die Steel Using Ceramic Tool and Cements Carbide Tool
p.466

An End-Milling Condition Decision Support System Using Data-Mining for Difficult-to-Cut Materials
p.472

Research on the Drilling Temperature Field Model of the Unidirectional Carbon Fiber Epoxy Composites
p.478

Chip Formation Characteristics in High-Speed Machining of Hardened AISI1045 Steel
p.484

Mechanical Behavior of Single Crystal Copper for Different Shearing Directions
p.490

Machinability Study on Hard Milling of Ultra-High Strength Steel 30Cr3SiNiMoVA
p.496

Review of Microelectrode Fabrication
p.503

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 565Research on the Drilling Temperature Field Model...

Research on the Drilling Temperature Field Model of the Unidirectional Carbon Fiber Epoxy Composites

Abstract:

Heat is easy to aggregate during drilling carbon fiber epoxy (C/E) composites because of the materials’ anisotropy and the low thermal conductivity. It can result in a high temperature gradient which has a significant effect on the quality of the workpiece and the tool wear. In this paper, a drilling temperature field model of the unidirectional composites is developed. Based on the finite difference method (FDM) the temperature distribution and changes are simulated. Experiments of measuring the drilling temperature at the exit of the hole are carried out, and the results show that the temperature distribution is in agreement with the temperature field model.