材料科学
陶瓷
机械加工
微尺度化学
表面粗糙度
刀具
表面光洁度
刀具磨损
摩擦学
机械工程
过程(计算)
工程制图
复合材料
冶金
计算机科学
工程类
数学教育
数学
操作系统
作者
Sergey N. Grigoriev,Thet Naing Soe,Khaled Hamdy,Yuri Pristinskiy,Alexander P. Malakhinsky,Islamutdin Makhadilov,V. A. Romanov,Ekaterina Kuznetsova,Pavel Podrabinnik,Alexandra Yu. Kurmysheva,Antón Smirnov,Nestor Washington Solís Pinargote
出处
期刊:Materials
[MDPI AG]
日期:2022-10-06
卷期号:15 (19): 6945-6945
被引量:1
摘要
Machining is an indispensable manufacturing process for a wide range of engineering materials, such as metals, ceramics, and composite materials, in which the tool wear is a serious problem, which affects not only the costs and productivity but also the quality of the machined components. Thus, the modification of the cutting tool surface by application of textures on their surfaces is proposed as a very promising method for improving tool life. Surface texturing is a relatively new surface engineering technology, where microscale or nanoscale surface textures are generated on the cutting tool through a variety of techniques in order to improve tribological properties of cutting tool surfaces by reducing the coefficient of friction and increasing wear resistance. In this paper, the studies carried out to date on the texturing of ceramic and superhard cutting tools have been reviewed. Furthermore, the most common methods for creating textures on the surfaces of different materials have been summarized. Moreover, the parameters that are generally used in surface texturing, which should be indicated in all future studies of textured cutting tools in order to have a better understanding of its effects in the cutting process, are described. In addition, this paper proposes a way in which to classify the texture surfaces used in the cutting tools according to their geometric parameters. This paper highlights the effect of ceramic and superhard textured cutting tools in improving the machining performance of difficult-to-cut materials, such as coefficient of friction, tool wear, cutting forces, cutting temperature, and machined workpiece roughness. Finally, a conclusion of the analyzed papers is given.
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