Karbon Fiber Takviyeli Polimer Kompozitlerin Kenar Budama Değişkenlerinin Yüzey Kalitesine Etkisi

Abstract

The main focus of this paper is to investigate the surface quality and machinability of the edge trimming process of carbon fiber reinforced polymer (CFRP) material. Measurement of transverse and longitudinal surface roughness and deformation behavior are carried out for different combinations of cutting speed, feed per tooth, tool type and milling type to evaluate the machined surface quality. Three different flutes (2,4,6) micro grain carbide end mill tools were used for vertical and inclined peripheral milling. Edge trimming experiments were conducted under different experimental parameters and their levels according to the Taguchi design of experiment method. The contribution ratio of parameters on machinability outputs has statistically analyzed by Analysis of Variance (ANOVA). According to machinability outputs such as surface roughness and deformation types, the inclined peripheral milling is more suitable than vertical peripheral milling. Edge trimming by vertical peripheral milling generates Type II delamination which consists of long uncut fibers protruding from the trimmed edges. Edge trimming by inclined milling generates Type I-II delamination which consists of short uncut fibers protruding from the trimmed edges and where plies have broken inwards in the same time. The transverse and longitudinal surface roughness and deformation decreased with increased number of teeth, cutting speed and decreased feed per tooth. The best machining quality was obtained when cutting at the highest level of cutting speed, lowest feed rate and 6 number of flute in inclined milling.