Frontiers in Ultra-Precision Machining, Volume II

doi:10.3390/books978-3-7258-1565-4

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Frontiers in Ultra-Precision Machining, Volume II

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July 2024

340 pages

ISBN978-3-7258-1566-1 (Hardback)
ISBN978-3-7258-1565-4 (PDF)

https://doi.org/10.3390/books978-3-7258-1565-4 (registering)

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This book is a reprint of the Special Issue Frontiers in Ultra-Precision Machining, Volume II that was published in

Chemistry & Materials Science

Engineering

Physical Sciences

Summary

Ultra-precision machining is a multi-disciplinary research area that is an important branch of manufacturing technology. With continuous advancements in science and technology and the diversification of industrial needs, ultra-precision machining has become an indispensable component of modern industry. It is widely used in aerospace, semiconductors, optics, microelectronics, automotive manufacturing, biomedical, energy, and other fields with the goal of realizing ultra-precision shape machining or improving surface roughness. The increasing demand for components with ultra-precision accuracy has stimulated the development of ultra-precision machining technology in recent decades. Therefore, this reprint brings together research papers on the frontiers of ultra-precision machining in the hope of advancing the development of related industrial technologies and providing a theoretical basis for subsequent research by relevant scholars.

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Hardback

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Keywords

milling force; milling temperature; multiple linear regression; range analysis; chip morphology; tool wear; surface quality; surface texture; high carbon chromium bearing steel (GCr15); ethylene propylene diene monomer (EPDM); friction; wear morphology; coupling; picosecond laser; glass cutting; characteristic strength; surface roughness; hatch; fixed abrasive pad; friction and wear; quartz glass; material removal rate; surface quality; wavelet packet energy coefficient; magnetic field assisted finishing; polishing; material removal; surface shape; ultra-precision machining; sliding contact; fused silica; densification; finite element analysis; cracks; Ti-6Al-4V alloy; 3D EVC; cutting force; residual stress; finite element method; TC4 titanium alloy; longitudinal-torsional ultrasonic grinding; grinding force; grinding temperature; grinding wheel wear; high-speed rail grinding; passive grinding; grinding time; grinding pass; grinding wheel; non-contact ultrasonic abrasive machining (NUAM); optical polishing; material removal distributions; surface morphology; femtosecond pulses; cutting; roughness; chipping; characteristic strength; borosilicate glass; filament; traditional micromilling; simulation; burr; ultrasonic vibration-assisted micromilling; size effect; cutting performance; radial error; ultra-precision spindle; nanometer-scale measurement; three-point method; Donaldson reversal method; molecular dynamics; nano-cutting; fluid medium; cutting angle; silicon carbide; aspheric mirror; ultra-precision shaping; deterministic polishing; precision testing; micromanipulation platform; systematic error; image stitching; error compensation model; NdFeB; laser processing; simulation; microstructure formation mechanism; melt pool flow evolution; fixed abrasive pad; abrasive water jet; friction; Hilbert marginal spectrum; friction coefficient; plasma temperature; silicon carbide; plasma etching; removal function