Abstract
Fiber reinforced composite (FRC) requires a process of grinding, mixing and compounding natural fibers from cellulosic waste streams into a polymer matrix that creates a high-strength fiber composite. In this situation, the specified waste or base raw materials used are the waste thermoplastics and different types of cellulosic waste including rice husk and saw dust. FRC is a high-performance fiber composite achieved and made possible through a proprietary molecular re-engineering process by interlinking cellulosic fiber molecules with resins in the FRC material matrix, resulting in a product of exceptional structural properties. In this feat of molecular re-engineering, selected physical and structural properties of wood are effectively cloned and obtained in the FRC component, in addition to other essential qualities in order to produce superior performance properties to conventional wood. The dynamic characteristics of composite structures are largely extracted from the reinforcing of fibres. The fiber, held in place by the matrix resin, contributes to tensile strength in a composite, enhancing the performance properties in the final part, such as strength and rigidity, while minimizing weight. The advantages of composite materials always beat down their disadvantages. In this analysis, we tried to find out FRC advance manufacturing, recycling technology and future perspective for mankind and next generation development. This research will bring a new horizon for future science with FRC technology and every aspect of modern science which will bring a stable dimensional stability by recycling process with minimizing waste for environment and next generation science.
Highlights
Fiber reinforced composite materials assume a significant job in the technology today through the structure and assembling of cutting edge materials equipped for accomplishing higher solidness/thickness and quality/thickness proportions
Piezoelectric composite materials are thought to be homogenous with successful electro-flexible properties which are subject to their constituent properties and microstructural geometry
The greater part of dental fiber-strengthened composite (FRC) materials are manufactured utilizing hand lay-up forms, wherein the expert may decide the mechanical properties of the conclusive reclamation by the manner in which the composite constituents are organized in the last structure [7]
Summary
Fiber reinforced composite materials assume a significant job in the technology today through the structure and assembling of cutting edge materials equipped for accomplishing higher solidness/thickness and quality/thickness proportions. Likewise the viscoelastic character of composites renders them appropriate for superior basic applications like aviation, marine, vehicle, and so forth Be that as it may, these materials are very particular from metals in light of the fact that the previous display a few unconventional methods of disappointment (grid crazing, delamination, fiber disappointment and interfacial bond disappointment because of de-holding) and collaboration at micromechanical, for example constituent level. The fiber strengthened polymers (FRP) comprise of filaments of high quality and modulus installed in or clung to a grid with unmistakable interface between them In this structure, the two strands and framework hold their physical and substance characters. For the advanced fiber reinforced composite (FRC) materials with the combination of advanced manufacturing method (AMM) the additive method for carbon is one of them
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