Abstract
Glass fiber-reinforced polymer (GFRP) composites find wide applications in automobile, aerospace, aircraft and marine industries due to their attractive properties such as lightness of weight, high strength-to-weight ratio, high stiffness, good dimensional stability and corrosion resistance. Although these materials are required in a wide range of applications, their non-homogeneous and anisotropic properties make their machining troublesome and consequently restrict their use. It is thus important to study not only the machinability of these materials but also to determine optimum cutting parameters to achieve optimum machining performance. The present work focuses on turning of the GFRP composites with an aim to determine the optimal cutting parameters that yield the optimum output responses. The effect of three cutting parameters, i.e., spindle rotational speed (N), feed rate (f) and depth of cut (d) in conjunction with their interactions on three output responses, viz., Material Removal Rate (MRR), Tool Wear Rate (TWR), and Surface roughness (Ra), is studied using full factorial design of experiments (FFDE). The statistical significance of the cutting parameters and their interactions is determined using analysis of variance (ANOVA). To relate the output response and cutting parameters, empirical models are also developed. Artificial Neural Network (ANN) combined with Genetic Algorithm (GA) is employed for multi-response optimization to simultaneously optimize the MRR, TWR and Ra.
Highlights
Composite materials are manufactured by combining two or more different materials having specific chemical and physical properties
analysis of variance (ANOVA) at 95% confidence level was used to study the relative influence of the cutting parameters and their interactions [30]
ANOVA for Material Removal Rate (MRR), Tool Wear Rate (TWR) and Ra are presented in Tables 6–8, respectively
Summary
Composite materials are manufactured by combining two or more different materials having specific chemical and physical properties. Composite materials are normally lighter than metals and their specific strength and hardness are usually better than metals due to presence of strong fibers. They possess better conductivity, excellent corrosion and fatigue resistance and good thermal and acoustic insulation than the metals. Due to these notable properties, they are taking over the market and being used in various engineering and non-engineering applications. Composites find wide applications in a large number of areas including aerospace, aircrafts, marine, and transportation, domestic, medical, etc
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