用多晶金刚石钻头干钻厚 CFRP 层压板时的热分区评估

IF 1.9 Q3 ENGINEERING, MANUFACTURING
Fahim Shariar , Umut Karagüzel , Yiğit Karpat
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引用次数: 0

摘要

由于碳纤维增强聚合物(CFRP)的各种材料特性与温度有关,因此碳纤维增强聚合物的干式钻孔是一个微妙的过程。在钻孔过程中,由于大量热量传入材料,温度升高会造成热损伤。热分区用于量化这种情况,它表示在加工操作过程中散失到组成物体中的热量占总热量的百分比。钻孔余量和刀具-工件界面的接触条件对 CFRP 材料的钻孔有很大影响。钻孔实验测量了五组不同进给率和转速下的推力、扭矩和温度。本研究通过开发基于有限元的热模型,提出了一种计算 CFRP 钻孔过程中热分区值的方法。该有限元模型采用高斯分布环型热通量,它是钻头与材料表面界面等效接触长度和工件几何形状的函数,可作为移动热源,模拟钻头穿过 CFRP 层压板的过程。该工具使用基于时间点的特征阶跃函数实现热通量,以表示钻头在加工过程中穿过工件时的温度。从 FE 分析和实验中获得的工件和刀具的温度曲线随后进行迭代匹配,以确定相应的热分区值。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Heat partition evaluation during dry drilling of thick CFRP laminates with polycrystalline diamond drills
Since various material properties of carbon fiber-reinforced polymer (CFRP) are temperature dependent, dry drilling of CFRP is a delicate process. Thermal damage can be caused by a rise in temperature during drilling due to a large portion of heat being transferred into the material. Heat partition is used to quantify this, which represents the percentage of total heat being dissipated into the constituent objects during a machining operation. Drill margin and contact conditions at the tool-workpiece interface significantly affect the drilling of CFRP material. Drilling experiments were performed to measure thrust force, torque, and temperatures for five different sets of feed rates and rotational speeds. This study proposes a method for calculating heat partition values during CFRP drilling by developing a finite element-based thermal model. The FE model employs a Gaussian distributed ring-type heat flux that is a function of the equivalent contact length at the interface between the drill and the material surface and the geometry of the workpiece which operates as a moving heat source, emulating the progress of the drill through the CFRP laminate. The tool implements heat fluxes that use characteristic time-point-based step functions to represent the temperature on the drill as it advances through the workpiece during machining. The temperature profiles obtained from the FE analysis and the experiments for the workpiece and tool were subsequently matched iteratively to determine the corresponding heat partition value.
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来源期刊
Manufacturing Letters
Manufacturing Letters Engineering-Industrial and Manufacturing Engineering
CiteScore
4.20
自引率
5.10%
发文量
192
审稿时长
60 days
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