Precision Machining of Advanced MaterialsLiangchi Zhang Precision machining is an essential manufacturing process to achieve high dimensional accuracy and high surface integrity of functional components for various technological applications, such as those in aeronautical, biomedical, mechanical, metrological, mechatronic, nano-technological and microscopy industries. To achieve a satisfactory operation of precision machining, however, one must have a deep understanding of the setting and control of machining conditions, mechanisms of material removal and effectiveness of the cutting tools. As a result, a quality precision machining requires a comprehensive integration of the development of machine tools, the improvement of machining methods and the wise application of materials science and engineering and mechanics of solids. recent research, development and applications on the precision machining of advanced materials. It covers three major aspects of precision machining, i.e., mechanisms of machining and material removal, friction and wear problems associated with cutting tools and development of new methods and new tools for more cost-effective processes. machining methods and conditions to achieve high surface integrity and accuracy. For example, silicon monocrystalls are brittle in nature and are chemically sensitive to machining environment. Composites have at least two phases with different mechanical properties. These need to be considered carefully in machining as otherwise unacceptable damage will take place in either the workpiece or the cutting tool or in both. The papers included in this volume deal with a wide range of difficult-to-machine materials, such as silicon, glass, carbon-fibre reinforced composites, CVD-SiC film and ceramics. The methodologies presented address both industrial production problems and fundamental issues, including polishing, grinding, electrochemical discharge machining, abrasive jet machining, laser sintering, chemo- mechanical machining, drilling, fractal analysis, molecular dynamics analysis and finite element simulation. The volume should therefore be of interest to production and research engineers, research students and academics in the area. |
Contents
Preface V | 1 |
A Novel ChemicalMechanical Planarization Technology Using PreThinSurface | 25 |
Assessment of the Exit Defects in Carbon FibreReinforced Plastic Plates Caused | 43 |
Copyright | |
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abrasive Al2O3 coated inserts analysis borosilicate glass carbide tools ceramics CFRP chemical Chemical-Mechanical Polishing chip coated carbide conventional grinding cutting edge cutting force cutting speed CVD-SiC films decreases depth of cut diameter diamond film diamond tool discharge drilling effect Electrode electrolyte ELID ELID-grinding etching experimental feed rate Fibre-Reinforced Plastic Figure fractal dimension free-machining grain graphite greentape grinding burn grinding conditions grinding direction grinding force grinding machine grinding wheel GTLS increases iron Key Engineering Materials laser m/min machining material removal rate measured metal removed micro holes microelectrode Micron Technology mm³/mm molecular dynamics monitoring nonuniformity oxide parameters partial pressure planarization polishing powder formation pyramids relative frequency distribution rotating shown in Fig shows silicon silicon dioxide simulation sintering slurry spalling stress substrate surface integrity surface profile surface roughness table speed thermal threading TiN coated inserts Trans Tech Publications Tribology velocity voltage Volume of metal wear mechanism