Wear behavior of alumina abrasive belt and its effect on surface integrity of titanium alloy during conventional and creep-feed grinding
暂无分享,去创建一个
Guijian Xiao | Yun Huang | Youdong Zhang | Kun Zhou | Hui Gao | B. Zhu
[1] Y. Geng,et al. Molecular dynamics simulation of laser assisted grinding of GaN crystals , 2022, International Journal of Mechanical Sciences.
[2] Guijian Xiao,et al. Wear evolution of electroplated diamond abrasive belt and corresponding surface integrity of Inconel 718 during grinding , 2022, Tribology International.
[3] Guijian Xiao,et al. A new one-step approach for the fabrication of microgrooves on Inconel 718 surface with microporous structure and nanoparticles having ultrahigh adhesion and anisotropic wettability: Laser belt processing , 2022, Applied Surface Science.
[4] Guijian Xiao,et al. A novel low-damage and low-abrasive wear processing method of Cf/SiC ceramic matrix composites: Laser-induced ablation-assisted grinding , 2022, Journal of Materials Processing Technology.
[5] Guijian Xiao,et al. Tip vortex cavitation of propeller bionic noise reduction surface based on precision abrasive belt grinding , 2022, Journal of Advanced Manufacturing Science and Technology.
[6] Guijian Xiao,et al. Material removal behavior of Cf/SiC ceramic matrix composites as a function of abrasive wear during diamond abrasive belt grinding , 2021, Wear.
[7] Guijian Xiao,et al. Analysis of abrasive belt wear effect on residual stress distribution on a grinding surface , 2021, Wear.
[8] Yucan Fu,et al. Coolant condition and spindle power in high-efficiency-deep-grinding of nickel-based superalloy profile part , 2021, Materials and Manufacturing Processes.
[9] He Zhe,et al. Investigation of conditions leading to critical transitions between abrasive belt wear modes for rail grinding , 2021 .
[10] W. Ding,et al. Fretting wear behaviour of machined layer of nickel-based superalloy produced by creep-feed profile grinding , 2021, Chinese Journal of Aeronautics.
[11] Guijian Xiao,et al. Fatigue Life Analysis of Aero-engine Blades for Abrasive Belt Grinding Considering Residual Stress , 2021, Engineering Failure Analysis.
[12] Zhi Huang,et al. Collision detection algorithm on abrasive belt grinding blisk based on improved octree segmentation , 2021, The International Journal of Advanced Manufacturing Technology.
[13] Jiu-hua Xu,et al. Creep feed grinding induced gradient microstructures in the superficial layer of turbine blade root of single crystal nickel-based superalloy , 2021, International Journal of Extreme Manufacturing.
[14] Ze Chai,et al. A study of dynamic energy partition in belt grinding based on grinding effects and temperature dependent mechanical properties , 2021 .
[15] Guijian Xiao,et al. A measurement method of the belt grinding allowance of hollow blades based on blue light scanning , 2021, The International Journal of Advanced Manufacturing Technology.
[16] Y. Liu,et al. The Method and Experiment Research on Down-stroke Abrasive Belt Grinding under Micro Feeding for Noise Reduction Surface , 2021, Journal of Bionic Engineering.
[17] Guijian Xiao,et al. A multi-particle abrasive model for investigation of residual stress in belt grinding of titanium alloys , 2021, Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture.
[18] Chunya Wu,et al. Wear characteristics of small ball-end fine diamond grinding pins dressed by on-machine electrical discharge , 2021, Wear.
[19] T. Beno,et al. Surface integrity investigations for prediction of fatigue properties after machining of alloy 718 , 2021 .
[20] M. Jackson,et al. Creep-Feed Grinding Wheel Development for Safely Grinding Aerospace Alloys , 2021, Journal of Materials Engineering and Performance.
[21] Guijian Xiao,et al. Comprehensive investigation into the effects of relative grinding direction on abrasive belt grinding process , 2021 .
[22] Cezhi Du,et al. Surface quality and residual stress variation of ceramics after abrasive grinding under pre-compressive stress , 2021 .
[23] T. Chen,et al. Surface burn behavior in creep-feed deep grinding of gamma titanium aluminide intermetallics: characterization, mechanism, and effects , 2021, The International Journal of Advanced Manufacturing Technology.
[24] Jiu-hua Xu,et al. Alumina abrasive wheel wear in ultrasonic vibration-assisted creep-feed grinding of Inconel 718 nickel-based superalloy , 2021 .
[25] S. Paul,et al. Wear mechanism in high-speed superabrasive grinding of titanium alloy and its effect on surface integrity , 2020 .
[26] Yun Huang,et al. Investigation on secondary self-sharpness performance of hollow-sphere abrasive grains in belt grinding of titanium alloy , 2020 .
[27] Guijian Xiao,et al. Optimization of belt grinding stepover for biomimetic micro-riblets surface on titanium alloy blades , 2020, The International Journal of Advanced Manufacturing Technology.
[28] Qi-yue Liu,et al. Effects of abrasive material and hardness of grinding wheel on rail grinding behaviors , 2020, Wear.
[29] Steven Y. Liang,et al. Effect of phase transition on micro-grinding-induced residual stress , 2020 .
[30] Wenxi Wang,et al. Experimental and simulation research on residual stress for abrasive belt rail grinding , 2020, The International Journal of Advanced Manufacturing Technology.
[31] Yun Huang,et al. Investigation of robotic abrasive belt grinding methods used for precision machining of aluminum blades , 2020 .
[32] W. Ding,et al. An investigation on machined surface quality and tool wear during creep feed grinding of powder metallurgy nickel-based superalloy FGH96 with alumina abrasive wheels , 2020 .
[33] Minhao Zhu,et al. Probing the effect of abrasive grit size on rail grinding behaviors , 2020 .
[34] Wen-jian Wang,et al. Experimental investigation on material removal mechanism during rail grinding at different forward speeds , 2020, Tribology International.
[35] P. Mallet,et al. Numerical evaluation of surface welding residual stress behavior under multiaxial mechanical loading and experimental validations , 2020 .
[36] Z. Yue,et al. Effect mechanism and equivalent model of surface roughness on fatigue behavior of nickel-based single crystal superalloy , 2019, International Journal of Fatigue.
[37] Jiu-hua Xu,et al. Comparative investigation on wear behavior of brown alumina and microcrystalline alumina abrasive wheels during creep feed grinding of different nickel-based superalloys , 2019, Wear.
[38] Steven Y. Liang,et al. High-speed grinding of HIP-SiC ceramics on transformation of microscopic features , 2019, The International Journal of Advanced Manufacturing Technology.
[39] S. Paul,et al. Effect of different grinding fluids applied in minimum quantity cooling-lubrication mode on surface integrity in cBN grinding of Inconel 718 , 2018, Journal of Manufacturing Processes.
[40] Yidu Zhang,et al. Investigation on influences of initial residual stress on thin-walled part machining deformation based on a semi-analytical model , 2018, Journal of Materials Processing Technology.
[41] J. Rech,et al. Investigating adhesion wear on belt and its effects on dry belt finishing , 2018, Journal of the Brazilian Society of Mechanical Sciences and Engineering.
[42] XiaoQi Chen,et al. A novel sound-based belt condition monitoring method for robotic grinding using optimally pruned extreme learning machine , 2018, Journal of Materials Processing Technology.
[43] Yulong Gu,et al. Towards the understanding of creep-feed deep grinding of DD6 nickel-based single-crystal superalloy , 2018, The International Journal of Advanced Manufacturing Technology.
[44] Guijian Xiao,et al. Micro-stiffener surface characteristics with belt polishing processing for titanium alloys , 2018, The International Journal of Advanced Manufacturing Technology.
[45] Wenfeng Ding,et al. Grinding performance and surface integrity of particulate-reinforced titanium matrix composites in creep-feed grinding , 2018 .
[46] Dongzhou Jia,et al. Maximum undeformed equivalent chip thickness for ductile-brittle transition of zirconia ceramics under different lubrication conditions , 2017 .
[47] C. Bolfarini,et al. Prediction of the surface finishing roughness effect on the fatigue resistance of Ti-6Al-4V ELI for implants applications , 2017 .
[48] Jun Zhao,et al. SURFACE INTEGRITY OF HIGH-SPEED FACE MILLED Ti-6Al-4V ALLOY WITH PCD TOOLS , 2013 .
[49] Jan-Eric Ståhl,et al. An investigation of surface damage in the high speed turning of Inconel 718 with use of whisker reinforced ceramic tools , 2012 .
[50] H. Zahouani,et al. The effect of abrasive grain's wear and contact conditions on surface texture in belt finishing , 2007 .