锻压技术

金属体积成形中摩擦描述与评估研究进展

英文标题：Research progresses of description and evaluation for friction during bulk metal forming

分类号：TG306

出版年,卷(期):页码：2021,46(10):1-11

摘要：

采用合理的摩擦模型、测定准确的摩擦参数与恰当的评估体积成形摩擦条件对体积成形工艺路径的制定和优化十分重要。由于金属体积成形过程中的高压、高温、工艺参数多样性及其之间复杂的非线性关系，使得体积成形中工件和模具之间接触面上的摩擦描述与评估较为困难。为了适用不同工艺条件，不断发展和改进多种形式的摩擦模型与摩擦测试试验，从摩擦模型、摩擦评估测试方法、不同模型中摩擦参数的对应关系等方面评述了金属体积成形摩擦的描述与评估研究进展，详细阐述了几种适用性强、具有应用前景的摩擦模型结构形式、数值化特征、适用范围与摩擦参数测定方法。

Adopting a reasonable friction model, measuring accurate friction parameters and properly evaluating the friction conditions of bulk forming are very important for the formulation and optimization of metal bulk forming process path, and due to the high pressure, high temperature, diversity of process parameters and the complex non-linear relationships among them in the metal bulk forming process, it is difficult to describe and evaluate the friction on the contact surface between workpiece and mold in the bulk forming process. Therefore, in order to adapt to different process conditions, continuously develop and improve various forms of friction models and friction test testing, the research progresses of description and evaluation for friction during the metal bulk forming was reviewed from some aspects such as friction model, friction evaluation test method and the corresponding relationship of friction parameters in different models, and the structure type, numerical characteristics, application scope and friction parameters measurement methods of several friction models with strong applicability and application prospects were elaborated in detail.

基金项目：

基金项目:国家自然科学基金资助项目（51675415，51305334）

作者简介：张大伟（1982-），男，博士，副教授，博士生导师 E-mail：zhangdawei2000@mail.xjtu.edu.cn

参考文献：

[1]Kalpakjiana S. Recent progress in metal forming tribology [J]. Annals of the CIRP, 1985, 34(2): 585-592.

[2]武建国，安红萍，刘俐利，等. 基于摩擦修正的SA508-3钢高温本构方程 [J]. 锻压技术，2020,45(12):178-182.

Wu J G，An H P，Liu L L，et al. High-temperature constitutive equation of SA508-3 steel based on friction correction [J]. Forging & Stamping Technology，2020,45(12): 178-182.

[3]Tan X. Comparisons of friction models in bulk metal forming [J]. Tribology International, 2002, 35: 385-393.

[4]Joun M S, Moon H G, Choi I S, et al. Effects of friction laws on metal forming processes [J]. Tribology International, 2009, 42: 311-319.

[5]Zhang D W, Yang H, Li H W, et al. Friction factor evaluation by FEM and experiment for TA15 titanium alloy in isothermal forming process [J]. The International Journal of Advanced Manufacturing Technology, 2012, 60: 527-53.

[6]Zhang D W, Yang G C, Zhao S D. Frictional behavior during cold ring compression process of aluminum alloy 5052 [J]. Chinese Journal of Aeronautics, 2021, 34(5): 47-64.

[7]秦敏，刘建生，李景丹. 镦粗过程中摩擦对空洞演变行为的影响 [J]. 锻压技术，2020,45(2):24-28.

Qin M，Liu J S，Li J D. Influence of friction on void evolution behavior during upsetting [J]. Forging & Stamping Technology，2020,45(2): 24-28.

[8]刘郁丽, 杨合, 詹梅. 摩擦对叶片预成形毛坯放置位置影响规律的研究[J]. 机械工程学报, 2003, 39(1): 97-100.

Liu Y L, Yang H, Zhan M. Research on influence of friction on setting position of preform billet in precision forging process of blade[J]. Chinese Journal of Mechanical Engineering, 2003, 39(1): 97-100.

[9]Zhang D W, Yang H. Numerical study of the friction effects on the metal flow under local loading way [J]. The International Journal of Advanced Manufacturing Technology, 2013, 68:1339-1350.

[10]张大伟. 钛合金筋板类构件局部加载成形有限元仿真分析中的摩擦及其影响[J]. 航空制造技术, 2017, (4): 34-41.

Zhang D W. Friction and influence in FEM simulation of local loading process for titanium alloy rib-web component [J]. Aeronautical Manufacturing Technology, 2017, (4): 34-41.

[11]Altan T, Oh S I, Gegel H L. Metal Forming: Fundamentals and Application [M]. Metal Park OH: American Society for Metals, 1983.

[12]Lange K. Handbook of Metal Forming [M]. New York: McGraw-Hill, 1985.

[13]Petersen S B, Martins P A F, Bay N. Friction in bulk metal forming:A general friction model vs. the law of constant friction [J]. Journal of Materials Processing Technology, 1997, 66: 186-194.

[14]Ghassemali E, Tan M J, Jarfors A E W, et al. Progressive microforming process: Towards the mass production of micro-parts using sheet metal [J]. The International Journal of Advanced Manufacturing Technology, 2013, 66: 611-621.

[15]Groche P, Müller C, Stahlmann J, et al. Mechanical conditions in bulk metal forming tribometers-Part one [J]. Tribology International, 2013, 62: 223-231.

[16]孟丽芬, 胡成亮, 赵震. 金属塑性成形中摩擦模型的研究进展[J]. 模具工业, 2014, 40(4): 1-7.

Meng L F, Hu C L, Zhao Z. Research progress of friction model in metal plastic forming [J]. Die & Mould Industry, 2014, 40(4): 1-7.

[17]Zhang D W, Yang H. Analytical and numerical analyses of local loading forming process of T-shape component by using Coulomb, shear and hybrid friction models [J]. Tribology International, 2015, 92: 259-271.

[18]Shaw M C, Ber A, Mamin P A. Friction characteristics of sliding surfaces undergoing subsurface plastic flow [J]. Journal of Fluids Engineering, 1960, 82(2):342-345.

[19]Wanheim T. Friction at high normal pressures [J]. Wear, 1973, 25: 255-244.

[20]Wanheim T, Bay N, Petersen A S. A theoretically determined model for friction in metal working processes [J]. Wear, 1974, 28:251-258.

[21]Male A T, Cockcroft M G. A method for the determination of the coefficient of friction of metals under conditions of bulk plastic deformation [J]. Journal of the Institute of Metals, 1964, 93(2): 38-46.

[22]Buschhausen A, Weinmann K, Lee Y L, et al. Evaluation of lubrication and friction in cold forging using a double backward-extrusion process [J]. Journal of Materials Processing Technology, 1992, 33: 95-108.

[23]Schrader T, Shirgaokar M, Altan T. A critical evaluation of the double cup extrusion test for selection of cold forging lubricants [J]. Journal of Materials Processing Technology, 2007, 189: 36-44.

[24]Ebrahimi R, Najafizadeh A. A new method for evaluation of friction in bulk metal forming [J]. Journal of Materials Processing Technology, 2004, 152: 136-143.

[25]Fan X G, Dong Y D, Yang H, et al. Friction assessment in uniaxial compression test: A new evaluation method based local bulge profile [J]. Journal of Materials Processing Technology, 2017, 243: 282-290.

[26]Zhang Q, Felder E, Bruschi S. Evaluation of friction condition in cold forging by using T-shape compression test [J]. Journal of Materials Processing Technology, 2009，209:5720-5729.

[27]Wang L, Yang H. Friction in aluminium extrusion-Part 2: A review of friction models for aluminum extrusion [J]. Tribology International, 2012, 56: 99-106.

[28]Han X, Hua L. Friction behaviors in cold rotary forging of 20CrMnTi alloy [J]. Tribology International, 2012, 55: 29-39.

[29]Zhang D W, Li F, Li S P, et al. Finite element modeling of counter-roller spinning for large-sized aluminum alloy cylindrical parts [J]. Frontiers of Mechanical Engineering, 2019, 14(3): 351-357.

[30]Zhang D W, Li Y T, Fu J H, et al. Mechanics analysis on precise forming process of external spline cold rolling [J]. Chinese Journal of Mechanical Engineering，2007, 20(3):54-58.

[31]Gavrus A, Francillette H, Pham D T. An optimal forward extrusion device proposed for numerical and experiment analysis of materials tribological properties corresponding to bulk forming processes [J]. Tribology International, 2012, 47: 105-121.

[32]Orowan E. The calculation of roll pressure in hot and cold flat rolling [J]. Proceedings of the Institution of Mechanical Engineers, 1943, 150(1):140-167.

[33]Freshwater I J. Simplified theories of flat rolling-I. the calculation of roll pressure, roll force and roll torque [J]. International Journal of Mechanical Sciences, 1996, 38(6): 633-648.

[34]Huang M N, Tzou G Y. Study on compression forming of a rotating disk considering hybrid friction [J]. Journal of Materials Processing Technology, 2002, 125-126: 421-426.

[35]Kobayashi S, Oh S I, Altan T. Metal Forming and the Finite-element Method [M]. New York: Oxford University Press Inc., 1989.

[36]张大伟, 赵升吨, 朱骏, 等. 大型钛合金模锻件模锻成形过程建模仿真[J]. 重型机械, 2014, (5):10-14.

Zhang D W, Zhao S D, Zhu J, et al. Modeling and simulation of die forging process for large-scale titanium alloy forging [J]. Heavy Machinery, 2014, (5):10-14.

[37]Bowden F P, Tabor D. The area of contact between stationary and between moving surfaces [J]. Proceedings of the Royal Society of London. Series A, Mathematical and Physical Sciences, 1939, 169 (938): 391-413.

[38]Fereshteh-Saniee F, Pillinger I, Hartley P. Friction modelling for the physical simulation of the bulk metal forming processes [J]. Journal of Materials Processing Technology, 2004, 153-154: 151-156.

[39]Behrens B A, Bouguecha A, Hadifi T, et al. Advanced friction modeling for bulk metal forming processes [J]. Production Engineering Research Development, 2011, 5(6): 621-627.

[40]Behrens B A, Alasti M, Bouguecha A, et al. Numerical and experimental investigations on the extension of friction and heat transfer models for an improved simulation of hot forging processes [J]. International Journal of Material Forming, 2009, 2(S1): 121-124.

[41]久能木真人. 軸方向圧縮荷重を受ける中空円筒の塑性変形に就いて[J]. 科学研究所報告, 1954, 30(2):63-92.

Kunogi M. On plastic deformation of hollow cylinders under axial compressive loading [J]. Journal of the Science Research Institute (Tokyo), 1954, 30(2):63-92.

[42]张大伟. 螺纹花键同步滚轧理论与技术[M]. 北京:科学出版社, 2020.

Zhang D W. Theory and Technology of Thread and Spline Synchronous Rolling [M]. Beijing: Science Press, 2020.

[43]Petersen S B, Martins P A F, Bay N. An alternative ring-test geometry for the evaluation of friction under low normal pressure [J]. Journal of Materials Processing Technology, 1998, 79: 14-24.

[44]Tan T, Martins P A F, Bay N, et al. Friciton studies at different normal pressures with alternative ring-compression tests[J]. Journal of Materials Processing Technology, 1998, 80-81: 292-297.

[45]Hu C L, Ou H A, Zhao Z. An alternative evaluation method for friction condition in cold forging by ring with boss compression test [J]. Journal of Materials Processing Technology, 2015, 224: 18-25.

[46]Hu C L, Yin Q, Zhao Z, et al. A new measuring method for friction factor by using ring inner boss compression test [J]. International Journal of Mechanical Sciences, 2017, 123: 133-140.

[47]Burgdorf M. ber die ermittlung des reibwertes für verfahren der massivumformung durch den ringstauchversuch[J]. Industrie-Anzeiger, 1967, 89(39): 15-20.

Burgdorf M. The determination of friction value for bulk forming process by the ring compression test [J]. Industrie-Anzeiger, 1967, 89(39): 15-20.

[48]Hawkyard J B, Johnson W. An analysis of the changes in geometry of a short hollow cylinder during axial compression[J]. International Journal of Mechanical Science, 1967, 9(4): 163-182.

[49]Lee C H, Altan T. Influence of flow stress and friction upon metal flow in upset forging of rings and cylinders [J]. Transactions of the ASME Series B: Journal of Engineering for Industry, 1972, 94(3): 775-782.

[50]张大伟, 赵升吨, 王利民. 复杂型面滚轧成形设备现状分析[J]. 精密成形工程, 2019, 11(1): 1-10.

Zhang D W, Zhao S D, Wang L M. Current status of rolling forming machine for complex profile [J]. Journal of Netshape Forming Engineering, 2019, 11(1): 1-10.

[51]Zhang D W, Cui M C, Cao M, et al. Determination of friction conditions in cold-rolling process of shaft part by using incremental ring compression test [J]. The International Journal of Advanced Manufacturing Technology, 2017, 91: 3823-3831.

[52]Yao Z, Mei D, Shen H, et al. A friction evaluation method based on barrel compression test [J]. Tribology Letter, 2013, 51:525-535.

[53]俞汉清, 陈金德. 金属塑性成形原理[M]. 北京: 机械工业出版社, 1999.

Yu H Q, Chen J D. Principle of Metal Plastic Forming [M]. Beijing: China Machine Press, 1999.

[54]Leu D K. A simple dry friction model for metal forming process [J]. Journal of Materials Processing Technology, 2009, 209: 2361-2368.

[55]Zhang D W, Ou H A. Relationship between friction parameters in Coulomb-Tresca friction model for bulk metal forming [J]. Tribology International, 2016, 95: 13-18.

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