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Wang H, Cong W, Ning F, Hu Y (2018) A study on the effects of machining variables in surface grinding of CFRP composites using rotary ultrasonic machining.
The conclusions of this study are beneficial to facilitate the development of high-quality and high-efficiency machining technologies of CFRP.
According to this, preliminary optimization methods of machining CFRP are proposed.
#Design concepts laminator yj 3071 crack#
From the results, it is found that there are four evolution types in all and when “burrs and cracks” exist, the crack depth increases obviously, and both the evolution types and depth are mainly determined by the fiber cutting angle. Specifically, orthogonal cutting experiments are conducted for analyzing the fiber-matrix interface crack’s types and depth, and upon these characteristics predictive models based on machine learning are established for acquiring sufficient data so that reliable evolution laws can be obtained. In order to accurately and conveniently obtain the evolution laws determined by numerous coupled factors, the study is conducted through a combined method of experiments and machine-learning predictions. For effectively suppressing various machining damages, this study aims to reveal the evolution laws of the fiber-matrix interface crack, which can be regarded as the origin of majority of the machining damages. Undesirable machining damages exist frequently in the conventional machining processes of CFRP, causing significant decline in the performance of CFRP components.
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