Research on Friction during Hot Deformation of Al-Alloys at High Strain Rate

被引:0
|
作者
P. Petrov
M. Petrov
E. Vasileva
A. Dubinchin
机构
[1] Moscow State Technical University “MAMI”,
来源
International Journal of Material Forming | 2008年 / 1卷
关键词
interfacial friction; friction factor; aluminium alloy; non-ferrous alloy; isothermal hot forging; lubricant; massive hot forming;
D O I
暂无
中图分类号
学科分类号
摘要
The paper is linked to the investigation of lubricants for massive hot forging. It was observed temperature range of 200-470°C and screw press was used for tests. The research on friction has been done for Al-Mg and Al-Cu-Mg-Fe-Ni aluminium alloys. In this connection, physical and numerical investigation of friction are performed. On the basis of the ring upsetting technique, the effect of temperature on the friction factor value has been investigated. The regressions for the relationship between friction factor and temperature for all lubricants under study have been obtained. Moreover, the sets of calibration curves were drawn. Each set of calibration curves corresponds to the definite type of aluminium alloy as well as definite conditions of deformation. Some practical recommendations were given.
引用
收藏
页码:1255 / 1258
页数:3
相关论文
共 50 条
  • [31] Strain rate effect on the cyclic deformation response of UFG Al alloys
    Malekjani, Shokoufeh
    Hodgson, Peter D.
    Cizek, Pavel
    Hilditch, Timothy B.
    MATERIALS SCIENCE AND ENGINEERING A-STRUCTURAL MATERIALS PROPERTIES MICROSTRUCTURE AND PROCESSING, 2012, 548 : 69 - 74
  • [32] Dynamic Recrystallization Mechanism of Inconel 690 Superalloy During Hot deformation at High Strain Rate
    Wang, Bin
    Zhang, Shi-Hong
    Cheng, Ming
    Song, Hong-Wu
    JOURNAL OF MATERIALS ENGINEERING AND PERFORMANCE, 2013, 22 (08) : 2382 - 2388
  • [33] Dynamic Recrystallization Mechanism of Inconel 690 Superalloy During Hot deformation at High Strain Rate
    Bin Wang
    Shi-Hong Zhang
    Ming Cheng
    Hong-Wu Song
    Journal of Materials Engineering and Performance, 2013, 22 : 2382 - 2388
  • [34] Thermomechanical modelling of hot extrusion of Al-alloys, followed by cooling on the press
    Bontcheva, N.
    Petzov, G.
    Parashkevova, L.
    COMPUTATIONAL MATERIALS SCIENCE, 2006, 38 (01) : 83 - 89
  • [35] Research progress in hot deformation behavior of high entropy alloys
    Yu, Qiuying
    Xie, Xiaochang
    Lan, Bo
    Zhang, Liwei
    Li, Neng
    Xiong, Huaping
    CAILIAO GONGCHENG-JOURNAL OF MATERIALS ENGINEERING, 2024, 52 (01): : 45 - 56
  • [36] Research progress on microstructure evolution and hot processing maps of high strength β titanium alloys during hot deformation
    Huang, Liang
    Li, Chang-min
    Li, Cheng-lin
    Hui, Song-xiao
    Yu, Yang
    Zhao, Ming-jie
    Guo, Shi-qi
    Li, Jian-jun
    TRANSACTIONS OF NONFERROUS METALS SOCIETY OF CHINA, 2022, 32 (12) : 3835 - 3859
  • [37] Quasicrystalline Al-alloys with high strength and good ductility
    Schurack, F
    Eckert, J
    Schultz, L
    MATERIALS SCIENCE AND ENGINEERING A-STRUCTURAL MATERIALS PROPERTIES MICROSTRUCTURE AND PROCESSING, 2000, 294 : 164 - 167
  • [38] THE CLASSIFICATION AND DETERMINATION OF RESTORATION MECHANISMS IN THE HOT-WORKING OF AL-ALLOYS
    MCQUEEN, HJ
    EVANGELISTA, E
    KASSNER, ME
    ZEITSCHRIFT FUR METALLKUNDE, 1991, 82 (05): : 336 - 345
  • [39] Effect of Strain and Strain Rate on the Evolution of Dispersoid Particles in Al-Mn-Fe-Si Alloy During Hot Deformation
    Hill, T.
    Robson, J.
    Kamp, N.
    LIGHT METALS TECHNOLOGY 2013, 2013, 765 : 398 - +
  • [40] Evolution of microstructure and strength during high-strain, high-strain-rate deformation of tantalum and tantalum based alloys
    Marquis, FDS
    FUNDAMENTAL ISSUES AND APPLICATIONS OF SHOCK-WAVE AND HIGH-STRAIN-RATE PHENOMENA, PROCEEDINGS, 2001, : 87 - 97
12345