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Optimization of cryogenic milling parameters for AFRP

This paper is aimed to restrain the defects such as fluff and ablation, which were often found in machining of the aramid fiber-reinforced composites (AFRP). The cooling method of spray liquid nitrogen was adopted in the orthogonal milling process. The processing parameters including cutting depth,...

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Published in:International journal of advanced manufacturing technology 2017-08, Vol.91 (9-12), p.3243-3252
Main Authors: Wang, Fengbiao, Liu, Jingkai, Shu, Qilin
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Language:English
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container_title International journal of advanced manufacturing technology
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creator Wang, Fengbiao
Liu, Jingkai
Shu, Qilin
description This paper is aimed to restrain the defects such as fluff and ablation, which were often found in machining of the aramid fiber-reinforced composites (AFRP). The cooling method of spray liquid nitrogen was adopted in the orthogonal milling process. The processing parameters including cutting depth, cutting speed, cooling temperature, feed speed, and liquid nitrogen flow were considered in details, and their effects on the processing quality were researched and analyzed. The analysis optimization methods of processing parameter were employed for the influence on the machining surface quality. Meanwhile, the optimal machining surface quality was predicted and verified. The results show that the cryogenic way realizes a bigger improved role on machining quality than the conventional one for AFRP. As well as the influence order of processing parameters on the roughness is cutting depth, cutting speed, cooling temperature, feed speed, and liquid nitrogen flow. And the predicted result Ra = 0.557 μm of minimum surface roughness value is similar with the actual one Ra = 0.572 μm and verifies the feasibility of optimization method. For processing of AFRP, the cooling way of spray liquid nitrogen has a positive role with high quality and efficiency.
doi_str_mv 10.1007/s00170-017-0003-0
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The cooling method of spray liquid nitrogen was adopted in the orthogonal milling process. The processing parameters including cutting depth, cutting speed, cooling temperature, feed speed, and liquid nitrogen flow were considered in details, and their effects on the processing quality were researched and analyzed. The analysis optimization methods of processing parameter were employed for the influence on the machining surface quality. Meanwhile, the optimal machining surface quality was predicted and verified. The results show that the cryogenic way realizes a bigger improved role on machining quality than the conventional one for AFRP. As well as the influence order of processing parameters on the roughness is cutting depth, cutting speed, cooling temperature, feed speed, and liquid nitrogen flow. And the predicted result Ra = 0.557 μm of minimum surface roughness value is similar with the actual one Ra = 0.572 μm and verifies the feasibility of optimization method. 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subjects Ablation
Aramid fiber reinforced plastics
CAE) and Design
Computer-Aided Engineering (CAD
Cooling
Cooling rate
Cryogenic engineering
Cutting parameters
Cutting speed
Defects
Engineering
Fiber composites
Industrial and Production Engineering
Liquid nitrogen
Machine tools
Machining
Mechanical Engineering
Media Management
Milling (machining)
Nitrogen
Optimization
Order parameters
Original Article
Process parameters
Quality
Surface properties
Surface roughness
title Optimization of cryogenic milling parameters for AFRP
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