Surface Roughness Simulation During Rotational-Magnetorheological Finishing of Poppet Valve Profiles

Surface finishing is essential for various applications in the aerospace industry.One of the applications is the poppet valve,which is used for leak-proof sealing of high-pressure gases in aerospace gas propulsion engines.The combustion engine also typically employs a poppet valve as an intake and exhaust valve.Nano-finishing a poppet valve is difficult because of its complex narrow profile.The precise nano-finished poppet valve perfectly fits on its seat and reduces hydrocarbon emissions.The rotational-magnetorheological fluid-based finishing process can be used effectively for these complicated surfaces.The polishing agent in this process is magnetorheological fluid,and rheological properties are controlled by a permanent magnet.This article presents the uniform finishing of the poppet valve's narrow ridge profile,which is analyzed through finite element analysis(FEA),wherein the outcomes are uniform shear stress,normal stress,and magnetic flux density distributions along the poppet ridge profile.The study of forces exerting on abrasive grains and surface roughness simulation is also conducted using FEA findings.The experiment is subsequently performed to verify the simulation results for poppet profile polishing.The obtained experimental and simulated surface roughness values are comparable.After the finishing process,the maximum percentage improvement of surface roughness is obtained as 93.71%.The rotational-magnetorheological fluid-based finishing process has high accuracy and reliability for specific applications.