Urbicain, Gorka||López de Lacalle, Luis Norberto
Machining—Recent Advances, Applications and Challenges
English[eng]
in situ estimation||modeling||simulation||variable pitch||X-ray diffraction||cutting edge preparation||plastic zone||flank milling||surface roughness||power consumption||cutting tool||fatigue||additive manufacturing||optimization||trochoidal step||surface topography||sinusoidal grid||milling||desirability approach||electrochemical discharge machining||fast simulation||Inconel 718||secondary adhesion wear||machinability||hybrid stacks drilling||cooling rate||shape memory alloy||residual stress||diameter variation||turning||computer vision||workholding||on-machine monitoring||chip morphology||dry-cutting||turning machine tools||SACE-drilled hole depth||residual stresses||cryogenic machining||prime machining costs||PVD Ti0.41Al0.59N/Ti0.55Al0.45N coating||single point incremental sheet forming||butt weld joint||dish angle||machining characteristic||DSC test||segmented diamond blade||cutting tool wear||ultra-precision machining||ceramics||shape memory effect||current density||fractal dimension||crack growth rate||drilling||force–temperature correlation through analytical modeling||finite element model||analytic solution||aluminium||taguchi method||multi-objective optimization||real-time prediction||Gamma-TiAl||cutting temperature||EN 31 steel||superalloys||material-removal rate||glass machining||corner radius||thin-wall machining||vibration||GPU||titanium aluminides||minimum quantity lubrication||machining temperatures at two deformation zones||finite element method||roughness||slight materials||high computational efficiency||dynamic||adhesive||heat transfer analysis||connections||stability||vibrations||trochoidal milling||magnesium alloys||specific cutting energy||laser-assisted machining||artificial neutral network||microscopic analysis||Milling stability||topography||weight loss||modal testing||sustainable machining||dry||damping||ductile machining||Inconel® 718||modelling||cutting edge microgeometry||electropulsing||PCD||cutting geometry||fixture||artificial neural networks||spark-assisted chemical engraving||machining||specific energy consumption||heat transfer search algorithm||material removal rate||prediction||CFRP/UNS A92024||tool wear||titanium alloy||multi-beam laser||chip compression ratio||design of experiments||concrete||ANN||titanium||chatter||response surface methodology||machine tool||superelastic nitinol||optimal machining conditions||machine vision||steel sheet||cutting process||fracture mechanism||self-excitation||tool insert condition||induction assisted milling||hole quality||GA||titanium alloys||microlens array||parameter identification||Taguchi method||weld reinforcement||slow tool servo||cutting parameters||flank super abrasive machining (SAM)||stiffness properties||grey relational analysis||deflection||computer numerical control||grain density||surface grinding||the cutting force components||Huber–Mises stress||WEDM