Investigation and optimization on ultrasonic vibration assisted wire cut electrical discharge machining parameters of titanium cored metal fibre laminate and ni cr 625 space alloy with rsm ccd

Abstract

The powerful but environment-friendly Metal Fibre Laminates newline(MFL) are primarily employed in numerous engineering applications for basic newlineand upgraded constructions. Compared to monolithic materials, it has newlinelightweight, high specific strength, corrosion resistance, and impact-resistant newlinecapabilities. MFLs are frequently employed in the structural components of newlineaerospace, ships, and automobiles. Recent research focuses on MFLs in a newlinechallenging vibration/shock environment that continually occurs with high newlineintensity. Rather than the present MFLs, high strength and enough energy newlinestorage should be the fundamental criterion. The construction of MFLs is newlinedetermined by the configurations of interleaving fibers and metal sheets newlineexpected to improve performance. newlineTherefore, this research aims to examine the tensile, flexural, and newlineimpact strengths of a skin-like titanium sheet laminated with basalt and flax newlinefibre called Titanium Metal Fiber Laminate (TMFL). It is achieved using newlinebasalt fibre made from natural rock that works well as glass fiber. It exhibits newlinestrong chemical stability, ambient reaction defence, non-combustibility newlinebehaviour, adequate resistivity to temperature, and mechanical strength. Due newlineto its superior strength and stress absorption qualities, natural flax fiber was newlineselected to provide structural damping. A well-known structural material, newlinetitanium alloy has an excellent strength-to-weight ratio and high flexural newlinestrength. Titanium metal fiber laminate provides a rigidity layer made of newlinetitanium metal. newline