Kinematic fields measurement during Ti-6Al-4V chip formation using new high-speed imaging system
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[1] Xiaoming Zhang,et al. A Comprehensive Experiment-Based Approach to Generate Stress Field and Slip Lines in Cutting Process , 2021 .
[2] Gilles Dessein,et al. Kinematic Fields Measurement during Orthogonal Cutting Using Digital Images Correlation: A Review , 2021 .
[3] Y. Landon,et al. A coupled in-situ measurement of temperature and kinematic fields in Ti-6Al-4V serrated chip formation at micro-scale , 2018, International Journal of Machine Tools and Manufacture.
[4] K. Lee,et al. An improved material constitutive model considering temperature-dependent dynamic recrystallization for numerical analysis of Ti-6Al-4V alloy machining , 2018, The International Journal of Advanced Manufacturing Technology.
[5] S. Liang,et al. Study of the Shear Strain and Shear Strain Rate Progression During Titanium Machining , 2018 .
[6] G. Dessein,et al. Thermal and microstructure study of the chip formation during turning of Ti64 β lamellar titanium Structure , 2018 .
[7] Jun Zhao,et al. FEM-simulation of machining induced surface plastic deformation and microstructural texture evolution of Ti-6Al-4V alloy , 2017 .
[8] Han Ding,et al. Stress Field Analysis in Orthogonal Cutting Process Using Digital Image Correlation Technique , 2017 .
[9] G. Fromentin,et al. Kinematic Field Measurements During Orthogonal Cutting Tests via DIC with Double-frame Camera and Pulsed Laser Lighting , 2017 .
[10] Zhanqiang Liu,et al. Evolutions of grain size and micro-hardness during chip formation and machined surface generation for Ti-6Al-4V in high-speed machining , 2016 .
[11] Justin A. Blaber,et al. Ncorr: Open-Source 2D Digital Image Correlation Matlab Software , 2015, Experimental Mechanics.
[12] Mohammed Nouari,et al. Analysis of the heat transfer at the tool–workpiece interface in machining: determination of heat generation and heat transfer coefficients , 2015 .
[13] Rajiv Shivpuri,et al. Role of phase transformation in chip segmentation during high speed machining of dual phase titanium alloys , 2014 .
[14] D. Umbrello,et al. Finite element simulation of machining Inconel 718 alloy including microstructure changes , 2014 .
[15] Mohammed Nouari,et al. Thermomechanical modelling of the tool–workmaterial interface in machining and its implementation using the \ABAQUS\ \VUINTER\ subroutine , 2014 .
[16] D. Coupard,et al. Sub-Millimeter Measurement of Finite Strains at Cutting Tool Tip Vicinity , 2014 .
[17] Franck Girot,et al. NUMERICAL SIMULATION OF TITANIUM ALLOY DRY MACHINING WITH A STRAIN SOFTENING CONSTITUTIVE LAW , 2010 .
[18] Anand Asundi,et al. Two-dimensional digital image correlation for in-plane displacement and strain measurement: a review , 2009 .
[19] Ala Hijazi,et al. A novel ultra-high speed camera for digital image processing applications , 2008 .
[20] Pedro J. Arrazola,et al. In-process high-speed photography applied to orthogonal turning , 2008 .
[21] Christophe Pinna,et al. Determination of micro-scale plastic strain caused by orthogonal cutting , 2008 .
[22] Olivier Cahuc,et al. Mechanical and Thermal Experiments in Cutting Process for New Behaviour Law , 2007 .
[23] Jean-Luc Battaglia,et al. ESTIMATED TEMPERATURE ON A MACHINED SURFACE USING AN INVERSE APPROACH , 2005 .
[24] P Vacher,et al. Bidimensional strain measurement using digital images , 1999 .
[25] R. Komanduri,et al. New observations on the mechanism of chip formation when machining titanium alloys , 1981 .
[26] R. H. Brown,et al. An investigation of the deformation in orthogonal cutting , 1965 .
[27] T. Bergs,et al. Development of a Methodology for Strain Field Analysis during Orthogonal Cutting , 2020 .
[28] H. Christ,et al. Using Digital Image Correlation Measurements for the Inverse Identification of Constitutive Material Parameters applied in Metal Cutting Simulations , 2019, Procedia CIRP.
[29] S. Melkote,et al. A physically based constitutive model for simulation of segmented chip formation in orthogonal cutting of commercially pure titanium , 2015 .
[30] L. Settineri,et al. Finite element modeling of microstructural changes in turning of AA7075-T651 Alloy , 2013 .
[31] T. Vorm,et al. Development of a quick-stop device and an analysis of the “frozen-chip” technique , 1976 .