Volume 1 Issue 1
Jan.  2021
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Guijian XIAO, Youdong ZHANG, Yun HUANG, Shayu SONG, Benqiang CHEN. Grinding mechanism of titanium alloy: Research status and prospect[J]. Journal of Advanced Manufacturing Science and Technology , 2021, 1(1): 2020001. doi: 10.51393/j.jamst.2020001
Citation: Guijian XIAO, Youdong ZHANG, Yun HUANG, Shayu SONG, Benqiang CHEN. Grinding mechanism of titanium alloy: Research status and prospect[J]. Journal of Advanced Manufacturing Science and Technology , 2021, 1(1): 2020001. doi: 10.51393/j.jamst.2020001

Grinding mechanism of titanium alloy: Research status and prospect

doi: 10.51393/j.jamst.2020001
Funds:

This study was co-supported by the State Key La-boratory of Mechanical Transmissions (No.174, Sha-zhengjie, Shapingba, Chongqing) and the National Natural Science Foundation of China (U1908232), National Science and Technology Major Project (2017-VII-0002-0095) and Graduate Scientific Re-search and Innovation Foundation of Chongqing (CYB20009).

  • Publish Date: 2021-01-11
  • Titanium alloy material has excellent properties such as low density, high strength, good oxidation resistance, creep resistance, etc. It has a broad application prospect in various fields. However, these characteristics also make it dif-ficult to process. Grinding is an essential method for high efficiency and precision machining of titanium alloy, ob-taining good machining precision and surface quality. The removal mechanism of titanium alloy is helpful to im-prove the surface quality of titanium alloy grinding. The recent research results in this field are reviewed. Firstly, the grinding technology types of titanium alloy were summarized, and the machining characteristics were systematically analyzed from two aspects of abrasive wear and material removal behavior of titanium alloy. Finally, the development trend of titanium alloy grinding technology in the prospect.

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  • [1]
    . He H. Influences of ω-assisted nucleation on mi-crostructures and properties of titanium alloy[dis-sertation]. Jinzhou:Liaoning University of Tech-nology, 2015.
    [2]
    . Chen X, Yang BY, Lei Y. The effect son of aging treatment on the organization and performance of titanium alloy rods. World Nonferrous Metal 2020; 544(4):180-181.
    [3]
    . Klocke F, Soo SL, Karpuschewski B, et al. Abrasive machining of advanced aerospace alloys and composites. CIRP Annals-Manufacturing Technol-ogy 2015; 64 (2):581-604.
    [4]
    . Xi XX, Yu TY, Ding WF, et al. Grinding of Ti2AlNb intermetallics using silicon carbide and alumina abrasive wheels:Tool surface topology effect on grinding force and ground surface quality. Precision Engineering 2018; 53:134-145.
    [5]
    . Zhang Y, Zhu D, Xu ZY. Basic research on micro-hole EDM-Electrolytic composite machining. Journal of Mechanical Engineering 2018, 54(1):26.
    [6]
    . Shi XJ, Wang LQ, Gu L, et al. Thermal elastohy-drodynamic lubrication analysis of aero-engine mainshaft ball bearing based on quasi-dynamic. Journal of Aerospace Power 2016; 31(1):233-240.
    [7]
    . Xu JH, Ding WF, Fu YC, et al. Dimension accuracy and surface integrity of creep feed ground titanium alloy with monolayer brazed CBN shaped wheels. Chinese Journal of Aeronautics 2010; 23(5):585-590.
    [8]
    . Manjaiah M, Narendranath S, Basavarajappa S, et al. Wire electric discharge machining characteris-tics of titanium nickel shape memory alloy. The Chinese Journal of Nonferrous Metals 2014; 24(10):3201-3209.
    [9]
    . Xie BC, Wang YK, Wang ZL, et al. Numerical simulation of titanium alloy machining in electric discharge machining process. Transactions of Nonferrous Metals Society of China 2011; 21(S2):434-439.
    [10]
    . Wang YG, Zhao FL, Wang JN. Wear-resist elec-trodes for micro-EDM. Chinese Journal of Aero-nautics 2009; 22(3):339-342.
    [11]
    . Zhai DJ, Feng KQ. Preparation of mi-cro/nano-structured ceramic coatings on Ti6Al4V alloy by plasma electrolytic oxidation process. Transactions of Nonferrous Metals Society of Chi-na 2019; 29(12):2546-2555.
    [12]
    . Yurii S, Ekaterina K, Maria S, et al. Structure and properties of micro-arc calcium phosphate coatings on pure titanium and Ti-40Nb alloy. Transactions of Nonferrous Metals Society of China 2017; 27(1):125-133.
    [13]
    . Javad K, Farshad Barazandeh, Seyed Mehdi Re-zaei, Hamed Adibi Ahmed.Sarhan. Surface integ-rity and flexural strength improvement in grinding partially stabilized zirconia. Journal of Central South University 2019; 26(12):3261-3278.
    [14]
    . Wang NS, Yuan X. Intelligent precision control in CNC grinding. Transactions of Nanjing University of Aeronautics & Astronau 2000; (1):95-99.
    [15]
    . Guo DM, Kang RK, Feng G. Nanogrinding of SiC wafers with high flatness and low subsurface damage. Trans. Nonferrous Met. Soc. China 2012; 22(12):3027-3033.
    [16]
    . Ren JX, Kang RK, Wu XL, et al. Grinding burn and crack of Titanium alloy. Manufacturing Tech-nology & Machine Tool 2000; 10:40-42.
    [17]
    . Kang RK, Yuan JT. Effect of grinding fluid on grindingproperties of vitrified bonded CBN wheel. Journal of North-western Polytechnical University 2000; 4:527-530.
    [18]
    . Xiao GJ, He Y, Huang Y, et al. Shark-skin-inspired micro-riblets forming mechanism of TC17 titanium alloy with belt grinding. IEEE Access 2019; 7(1):107636-107648.
    [19]
    . Huang Y, Xiao GJ, Liu Y, et al. Interactive strategy for adaptive belt grinding heterogeneous data for an aero-engine blade. IEEE Access 2019; 7(1):84637-84648.
    [20]
    . Xiao GJ, Huang Y. Two-level static floatation tool used in belt grinding for root fillet of titanium alloy blade. IEEE Access 2019; 7(1):28663-28671.
    [21]
    . Xiao GJ, Zhang YD, He Y, et al. Optimization of belt grinding stepover for biomimetic micro-riblets surface on titanium alloy blades. International Journal of Advanced Manufacturing Technology 2020; DOI: 10.1007/s00170-020-05935-1.
    [22]
    . Xiao GJ, He Y, Huang Y, et al. Bionic micro-structure on titanium alloy blade with belt grinding and its drug reduction performance. Proceedings of the Institution of Mechanical Engineers, Part B:Journal of Engineering Manufacture 2020;DOI: 10.1177/0954405420949744.
    [23]
    . Huang Y, Liu S, Huang T, et al. Model of residual stress formation on belt grinding surface of titani-um alloy and experimental research. Surface Tech-nology 2020; 49(4):30-37.
    [24]
    . Bhushan B. Mordern tribology handbook. 2001.
    [25]
    . Zha HT, Feng PF, Zhang JF, et al. Wear charac-teristics of cutting tools in ultrasonic vibration as-sisted scratching high volume fraction SiC particle reinforced aluminum matrix composites. Jilin University Journal(liberal arts ed.) 2019; 49(2):458-465.
    [26]
    . Deng H. Nanosecond laser dressing of coarse-grained diamond grinding wheels and its grinding performance. Ordnance Material Science and Engineering 2017; 40(3):21-25.
    [27]
    . Choudhary A, Paul S. The wear mechanisms of diamond grits in grinding of alumina and yt-tria-stabilized zirconia under different cooling -lubrication schemes. Wear 2020; DOI: https://doi.org/10.1016/j.wear.2020.203315.
    [28]
    . Wang WS, Shan RL, Zhang SY. Experimental study on grinding Titanium alloy with abrasive belt. Abrasives and Grinding 1990; 5(59):8-10.
    [29]
    . Ren JX, Hua DA, Huang Q, et al. Study on grinding wheel wear mechanism during grinding Titanium alloy. Chinese Journal of Aeronautics. 1991; (1):266-272.
    [30]
    . Huang W, Su HH, Zhang K, et al. Wear experi-ment of single brazed diamond abrasive. Diamond Abrasives Engineering 2016; 36(2):15-18.
    [31]
    . Mao C, Zhang YC, Peng XX, et al. Wear mecha-nism of single CBN-WC-10Co fiber cutter in ma-chining of Ti-6Al-4V alloy. Journal of Materials Processing Technology 2018; 259:45-57.
    [32]
    . Pandiyan V,Caesarendra W, Tjahjowidodo T, et al. In-process tool condition monitoring in com-pliant abrasive belt grinding process using support vector machine and genetic algorithm. Journal of Manufacturing Processes 2018; 31:199-213.
    [33]
    . Gao H, Liu GX, Zhang XL, et al. Research on abrasive wear characteristics of electroplated dia-mond tool during drilling carbon fiber reinforced plastics. Journal of Dalian University of Technol-ogy 2011; 51(5):675-680.
    [34]
    . Huo WG, Xu JH, Fu YC, et al. Dry grinding of Ti6Ai4V alloy with flap wheel. Transactions of Nanjing University of Aeronautics & Astronautics 2010; 27(2):131-137.
    [35]
    . Heart R, Hua DA. Grinding principle. Beijing:Electronic Industry Press, 2011:105-338.
    [36]
    . Deng H. Nanosecond laser dressing of coarse-grained diamond grinding wheels and its grinding performance. Ordnance Material Science and Engineering 2017; 40(3):21-25.
    [37]
    . Zhan YJ, Xu XP. Characteristics of brazed dia-mond wear in grinding of granite. Tribology 2007; (3):279-283.
    [38]
    . Xu XP, Yu YQ, Huang H. Mechanisms of abra-sive wear in the grinding of titanium (TC4) and nickel (K417) alloys. Wear 2003; 255(7):1421-1426.
    [39]
    . Turley DM. Factors affecting surface finish when grinding titanium and a titanium alloy (Ti-6Al-4V). Wear 1985; 104(4):323-335.
    [40]
    . Yu HY, Zhang HC, Guo YY, et al. Thermody-namic analysis of shark skin texture surfaces for microchannel flow. Continuum Mechanics and Thermodynamics 2015; 28:1361-1371.
    [41]
    . Zhang JH. Effects of tangential ultrasonic vibra-tion on grinding force of single abrasive grit. Acta Armamentarii 2011; 32(4):487-492.
    [42]
    . Zhang JG. Research on mechanism and surface integrity of precision abrasive belt grinding of TiAl-based alloy thin-walled compo-nent[dissertation]. Chongqing:Chongqing Univer-sity,2018.
    [43]
    . Qi JD, Chen B. Mechanism model of belt grinding considering single abrasive action. Diamond Abrasives Engineering 2020; 40(3):13-20.
    [44]
    . Xiao GJ, He Y, Huang Y, et al. Single particle removal model and experimental study on micro bionic zigzag surface of aeronautical blade using belt grinding. Chinese Journal of Aeronautics 2020; 33(7):33-42.
    [45]
    . Wang WX, Ferdinando S, Joel R. Characteristic assessment and analysis of residual stresses gener-ated by dry belt finishing on hard turned AI-SI52100. J Manuf Process 2020; 59:11-18.
    [46]
    . Brinksmeier E, Sch Nemann L. Generation of discontinuous microstructures by diamond micro chiseling. CIRP Annals-Manufacturing Technology 2014; 63(1):49-52.
    [47]
    . Zou L, Li H, Yang YG, et al. Feasibility study of minimum quantity lubrication assisted belt grinding of titanium alloys. Material and manufacturing processes 2020; 35:961-968.
    [48]
    . Luo GS, Zou L, Huang Y, et al. Study on material removal and surface quality in titanium alloy. Chi-na Mechanical Engineering 2020; DOI: 42.1294.TH.20200618.1051.004.
    [49]
    . Liu Y, Li Q, Xiao GJ, et al. Study of the vibration mechanism and process optimization for abrasive belt grinding for a blisk-blade. IEEE Access 2019; 7(1):24829-24842.
    [50]
    . Xiao GJ, Zhang YD, He Y, et al. Bionic structure on complex surface with belt grinding for electron beam welding seam of titanium alloy. Applied Sci-ences 2020; 10(7):237001-237012.
    [51]
    . Huang Y, He S, Xiao GJ, et al. Effects research on theoretical-modelling based suppression of the contact flutter in blisk belt grinding. Journal of Manufacturing Processes 2020; 54:309-317.
    [52]
    . Zhao B, Ding WF, Zhou Y, et al. Effect of grain wear on material removal behaviour during grind-ing of Ti-6Al-4V titanium alloy with single aggre-gated CBN grain. Ceramics international 2019; 45:14842-14850.
    [53]
    . Cheng Z, Xu JH, Ding WF, et al. Simulation of chip formation in grinding titanium alloy TC4 with single abrasive grit. Diamond & Abrasives Engi-neering 2011; 31(2):17-21.
    [54]
    . Liang QY, Shan K, Li ZR, et al. Investigation of grain wear in diamond abrasive belt grinding tita-nium alloy blade for aeroengine. Diamond & Abrasives Engineering 2020; 40(4):59-64.
    [55]
    . Fu DK, Ding WF, Miao Q, et al. Simulation re-search on the grinding forces and stresses distribu-tion in single-grain surface grinding of Ti-6Al-4V alloy when considering the actual cutting-depth variation. International Journal of Advanced Man-ufacturing Technology 2017; 91(9-12):3591-3602.
    [56]
    . Liu CJ, Ding WF, Li Z, et al. Prediction of high-speed grinding temperature of titanium matrix composites using BP neural network based on PSO algorithm. International Journal of Advanced Manufacturing Technology 2016; 89(5-8):1-9.
    [57]
    . Fan WG, Cheng JF, Lu HB, et al. Prediction of high-speed grinding temperature of titanium matrix composites using BP neural network based on PSO algorithm. Chinese Journal of Mechanical Engi-neering 2018; 54(4):87-92
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