Volume 3 Issue 1
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Weisen ZHAO, Qiang GUO, Changlin SHU, Zhixi ZHEN, Wenbo WANG. Methods on error-modeling, detection and compensation in gear hobbing process: A short review[J]. Journal of Advanced Manufacturing Science and Technology , 2023, 3(1): 2022019. doi: 10.51393/j.jamst.2022019
Citation: Weisen ZHAO, Qiang GUO, Changlin SHU, Zhixi ZHEN, Wenbo WANG. Methods on error-modeling, detection and compensation in gear hobbing process: A short review[J]. Journal of Advanced Manufacturing Science and Technology , 2023, 3(1): 2022019. doi: 10.51393/j.jamst.2022019

Methods on error-modeling, detection and compensation in gear hobbing process: A short review

doi: 10.51393/j.jamst.2022019

The authors gratefully acknowledge the support of the Fundamental Research Funds for Key Science and Technology Program of Henan Province (No.212102210055)

  • Received Date: 2022-07-01
  • Accepted Date: 2022-09-15
  • Rev Recd Date: 2022-08-12
  • Available Online: 2022-09-30
  • Publish Date: 2022-10-09
  • Gear is one of important transmission components in mechanical devices.How to correctly produce gears that meets the transmission requirements has always been the research focus in the mechanical industry.Among processing methods of gears,gear hobbing is the one of the most important processing methods because of its high production efficiency and strong universality.However,due to the influence of machining process,various errors will inevitably appear in the gear hobbing process.Therefore,the analysis of hobbing error modeling,detection and compensation are very vital to improve gear accuracy.This paper summarizes researches and developments of the above three aspects,and puts forward the direction and content that need to be further studied:constructing a closed-loop hobbing machining system of "tooth surface error modeling-tooth surface error tracing-error compensation".

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  • [1]
    . Ueda Y, Sakurai N, Takagi T, et al. Exploratory investigation of chip formation and surface integrity in ultra-high-speed gear hobbing. CIRP Ann 2022;71(1):89– 92.
    . Yagishita H. Method for measuring the dynamic transmission error in large gear hobbing machines. Precis Eng 1990;12(3):144–150.
    . Khusainov RM, Khaziev RR. Mathematical model for assessing the accuracy of processed gears on gear shaping machines. Procedia Eng 2017;206: 1087–1092.
    . Xia CJ, Wang SL, Wang SB, et al. Geometric error identification and compensation for rotary worktable of gear profile grinding machines based on single-axis motion measurement and actual inverse kinematic model. Mech Mach Theory 2021;155: 104042.
    . Mallipeddi D, Norell M, Sosa M, et al. The effect of manufacturing method and running-in load on the surface integrity of efficiency tested ground, honed and superfinished gears. Tribol Int 2019;131: 277–287.
    . Cheng YN, Ma CJ, Zhang JY, et al. Research progress on technology parameter optimization of high-speed dry gearhobbing. Journal of Harbin University of Science and Technology 2022; 2: 10-20 [Chinese].
    . Troß N, Löpenhaus C, Klocke F. Analysis of the cutting conditions for radial-axial infeed strategies in gear hobbing. Procedia CIRP 2019;79: 68–73.
    . Liu X, Mei XS, Tao T, et al. A null-coupling error model in gear hobbing and error prediction. Journal of Xi’an Jiao Tong University 2016;50 (10): 42-48,85 [Chinese].
    . Wang XL. Error Analysis on gear production. Machinery Management and Development 2014;29 (6): 35-37 [Chinese].
    . Zhang WL, Yan JC. Research on dynamic compensation system of hobbing machining error. Digital Technology and Application 2011 [Chinese].
    . Zhang L. Research on structural analysis and error compensation technology of YK3150E CNC hobbing machine [dissertation]. Lanzhou: Lanzhou University of Technology; 2019.
    . Jiang XF. The research on thermal error compensation of CNC hobbing machine tools [dissertation]. Hefei: Hefei University of Technology; 2013.
    . Liu ZT. Research on thermal error modeling and compensation of high-speed dry-cutting CNC gear hobbing machine [dissertation]. Chongqing: Chongqing University; 2018.
    . Shen JH, Guo YJ. Application of partial least squares neural network in thermal error modeling for CNC machine tool. Key Eng Mater 2009;392–394:30–34.
    . Lei CL, Rui ZY, Liu J, et al. Thermal error robust modeling for high-speed motorized spindle. Adv Mater Res 2012;1669(466–467):961–965.
    . Vyroubal J. Compensation of machine tool thermal deformation in spindle axis direction based on decomposition method. Precis Eng 2012;36(1):121–127.
    . Liu H, Miao EM, Zhuang XD, et al. Thermal error robust modeling method for CNC machine tools based on a split unbiased estimation algorithm. Precis Eng 2018;51: 169– 175.
    . Mize CD, Ziegert JC. Neural network thermal error compensation of a machining center. Precis Eng 2000;24(4):338–346.
    . Yan W. Research on real-time detection and compensation method for thermal error of dry-cut hobbing machine [dissertation]. Chongqing: Chongqing University of Technology; 2020.
    . Li YX. New methods of thermal reeor modeling for NC machine tools and the2ir researchment and application [dissertation]. Shanghai: Shanghai Jiao Tong University; 2007.
    . Guo QJ. Research on real-time compensation technology of geometric and thermal errors for gear hobbing machine [dissertation]. Shanghai: Shanghai Jiao Tong University; 2008.
    . Leete DL. Automatic compensation of alignment errors in machine tools. Int J Mach Tool Des Res 1961;1(4):293– 324.
    . French D, Humphries SH. Compensation for the backlash and alignment errors in a numerically controlled machine tool by a digital computer programme. Advances in Machine Tool Design and Research 1967. Amsterdam: Elsevier, 1968:707–726.
    . Reshetov DN, Portman VT, Dunaevsky VV. Accuracy of machine tools. New York: ASME Press, 1988.
    . Pennock GR, Oncu BA. Application of screw theory to rigid body dynamics. J Dyne Sys Meas Control, 1992;114(2):262-269.
    . Denavit J, Hartenberg RS. A kinematic notation for lowerpair mechanisms based on metrics. Transactions of the ASME. Journal of Applied Mechanics 1955; 22: 215-221.
    . Liu YW, Liu LB, Zhao XS, et al. Research on error compensation technology of NC machine tool. China Mechanical Engineering 1998; 9(12): 48-52 [Chinese].
    . Xia HS. Geometric error modeling and compensation research for CNC gear hobbing machine [dissertation]. Hefei: Hefei University of Technology; 2013.
    . Liu RA. Research and application of key technologies of direct-drive gear hobbing machine [dissertation]. Chongqing: Chongqing University; 2006.
    . Huang Q. Study on the technologies of controlling precision and supperssing chatter vibration for “zerotransmission” hobber [dissertation]. Chongqing: Chongqing University; 2008.
    . Huang Q, Zhang GB, Zhang XY. Building and application of direct error model for gear hobbing. Journal of System Simulation 2009;21 (17): 5589-5593 [Chinese].
    . Jin J, Chen P, Li PW. Application of laser interferometer in rapid indication error measurement of large scale three coordinate measuring machine. Shanghai Metrology and Testing 2017;44 (1): 20-23 [Chinese].
    . Sun SL. Research on multi-source error modeling and compensation method for CNC hobbing process [dissertation]. Chongqing: Chongqing University; 2018.
    . Liu YW. Research on total error model and error compensation of CNC machine tools. Manufacturing Technology & Machine Tool 2003;(7):46-50,74 [Chinese].
    . Li YM, Yang XZ, Shen XQ, et al. Study on measurement and identification of geometric error for the NC machine tools based on the twelve-line method. Journal of Henan Polytechnic University (Natural Science) 2009;28(5): 592- 595 [Chinese].
    . Chen GQ, Yuan JX, Ni J. A displacement measurement approach for machine geometric error assessment. Int J Mach Tools Manuf 2001;41(1):149–161.
    . Zhang G, Ouyang R, Lu B, et al. A displacement method for machine geometry calibration. CIRP Ann 1988;37(1):515–518.
    . He ZY, Fu JZ, Zhang LC, et al. A new error measurement method to identify all six error parameters of a rotational axis of a machine tool. Int J Mach Tools Manuf 2015;88: 1–8.
    . Lv B, Li DX. Error identification and compensation of NC machine tool based on ball instrument. Defense Manufacturing Technology 2017;1: 61-63 [Chinese].
    . Zargarbashi SHH, Mayer JRR. Assessment of machine tool trunnion axis motion error, using magnetic double ball bar. Int J Mach Tools Manuf 2006;46(14):1823–34.
    . Lei WT, Sung MP, Liu WL, et al. Double ballbar test for the rotary axes of five-axis CNC machine tools. Int J Mach Tools Manuf 2007;47(2):273–285.
    . Flynn J, Vichare P, Chaharsooghi A, et al. Single setup ballbar testing of 5-axis machine tools to identify positionindependent geometric errors. FAIM 2015: The International Conference on Flexible Automation and Intelligent Manufacturing (FAIM), 2015.
    . Xiang ST, Altintas Y. Modeling and compensation of volumetric errors for five-axis machine tools. Int J Mach Tools Manuf 2016;101: 65–78.
    . Liang YY, Liang RJ, Wang QL, et al. Research on geometrical error identification of machine tool rotary table base on DBB position. Machinery & Electronics 2017; 2: 45-50 [Chinese].
    . Chen ZW, Ding S, Song ZY, et al. Review of research on tooth surface error control of large CNC gear forming grinding. Journal of Mechanical Transmission 2022.
    . Ren YQ , Yang JG. Research on decoupling of comprehensive error compensation for five-axis CNC machine tools. Chinese Journal of Mechanical Engineering, 2004, 40 (2) :55-59.
    . Hsu YY, Wang SS. A new compensation method for geometry errors of five-axis machine tools. Int J Mach Tools Manuf 2007;47(2):352–360.
    . Chen JX, Lin SW, He BW. Geometric error compensation for multi-axis CNC machines based on differential transformation. Int J Adv Manuf Technol 2014;71(1– 4):635–642.
    . Liao L. Study on decoupling and compensation of volumetric error of CNC gear grinding machine tool [dissertation]. Chongqing: Chongqing University; 2017.
    . Ding S, Huang XD, Yu CJ, et al. Actual inverse kinematics for position-independent and position-dependent geometric error compensation of five-axis machine tools. Int J Mach Tools Manuf 2016;111: 55–62.
    . Yang JG. Comprehensive error compensation technology and application of NC machine tool [dissertation]. Shanghai: Shanghai Jiao Tong University; 1998.
    . Yee KW, Gavin RJ. Implementing fast part probing and error compensation on machine tools. Technical Report NISITIR-4447, 1990.
    . Kim KD, Kim MS, Chung SC. Real-time compensatory control of thermal errors for high-speed machine tools. Proc Inst Mech Eng B J Eng Manuf 2004;218(8):913–924.
    . Yang S, Yuan J, Ni J. Accuracy enhancement of a horizontal machining center by real-time error compensation. J Manuf Syst 1996;15(2):113–124.
    . Jiang H, Sun HY, Fan JZ, et al. Research on error compensation of NC machine tool based on the offset function of external coordinate origin of FANUC 0I system. Machinery 2009;47 (7): 73-76.
    . Yang JG, Zhang HT, Tong HC, et al. The application of real-time thermal error compensation on NC machine tools. J Shanghai Jiao Tong University 2005; 39 (9): 1389-1392 [Chinese].
    . Wang SL, Qi P, Zhou J, et al. Thermal deformation error analysis and compensation method for NC gear hobbing machine tools. Journal of Shanghai Jiao Tong University 2011; 34 (3): 13-17 [Chinese].
    . Jing YG, Wang W. Diagnosis and compensation of hobbing error. Journal of Shenyang Polytechnic University 1986;8 (2): 21-35 [Chinese].
    . Chiu H, Umezaki Y, Arura Y. An improvement of the tooth profile accuracy of a hobbed gear by adjusting the hob eccentricity. JSME International Journal. Ser. 3, Vibration, Control Engineering, Engineering for Industry 1989,32(1):131-135.
    . Zheng Y, Zheng FY, Gao ZH, et al. Refinement practical technology testing system of machine transmission chain and gear hobbing machine. Manufacturing Technology & Machine Tools 2010; 9: 102-106 [Chinese].
    . Zhang CR. Real time compensation and controlling transmission of gear hobbing machines. Manufacturing Technology & Machine tool 1993 (9): 16-18 [Chinese].
    . Shang XD, Jing YG, Deng LJ. On the application of hobbing radial error compensation technology in hobbing machining. Journal of Shenyang University of Technology 1996;18(1): 1–7,12 [Chinese].
    . Shang XD, Jing YG. Hobbing error diagnosis. Mechanical Design & Manufacturing 1995; (6): 40-42 [Chinese].
    . Du JM, Wu XT, Wu H, et al. Modeling, simulation and application for compensation of movement error in NC gear hobbing. Journal of System Simulation 2002; 14 (12): 1680-1682 [Chinese].
    . Gao XL, Lu KJ, Zhao YX. The diagnosis analysis of gearhobbing machining error and the study of the compensation system. New Technology & New Process 2002;12: 19-21 [Chinese].
    . Wang FL. Research on generating method and error compensation for digital gear tooth surfaces [dissertation]. Wuhan: Huazhong University of Science and Technology; 2005.
    . Ma SZ. CNC gear hobbing machining error compensation research [dissertation]. Shenyang: Shenyang Ligong University; 2013.
    . Yu Y, Wang RQ, Wang YP, et al. Contact force controlled robotic polishing for complex PMMA parts with an active end-effector. J Adv Manuf Sci Technol 2021;1(4): 2021012.
    . Geng TY, Xu ZY. Electrochemical discharge machining for fabricating holes in conductive materials: a review. J Adv Manuf Sci Technol 2021;1(3):2021006.
    . Niu JB, Xu JT, Ren F, et al. A short review on milling dynamics in low-stiffness cutting conditions: modeling and analysis. J Adv Manuf Sci Technol 2021;1(1):2020004.
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