Abstract
Abstract
A recent advancement in composite materials involves integrating wire mesh with glass and carbon fibers, with the goal of significantly enhancing mechanical characteristics and machining efficiency. The article offers a comprehensive review of recent developments in material performance, surface treatments, and machining parameters, while examining the synergistic impacts of incorporating wire mesh into carbon and glass fiber-reinforced composites. Significant attention is given to the effects of wire mesh on tensile strength and flexural characteristics, as well as optimizing surface treatments to improve interfacial bonding and durability. Moreover, the paper discusses challenges and advancements in drilling and machining these hybrid composites, focusing specifically on parameters such as feed rate, cutting speed, and tool wear. Machining performance is evaluated using metrics such as surface roughness, delamination, and tool lifespan, accompanied by a detailed analysis of how wire mesh architecture influences composite behavior under various machining conditions. The ultimate objective of this synthesis is to establish a stage for the development of next-generation composites with improved mechanical characteristics and machining capabilities, which can successfully satisfy changing needs in structural, automotive, and aerospace applications.