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In this paper the new metal forming technologies developed at Lublin University of Technology are presented. The team of Metal Forming and Numerical Modeling Department focus on finding new solutions for different parts manufacturing. Among them, the researchers were interested in rotational forming processes for full and hollow parts: cross wedge rolling, helical wedge rolling, rotary compression and rolling extrusion. Short descriptions of the chosen processes and realized research of them are shown.
Czasopismo
Rocznik
Tom
Strony
5--17
Opis fizyczny
Bibliogr. 28 poz., rys., fot.
Twórcy
autor
- Lublin University of Technology, Department of Computer Modelling and Metal Forming Technologies, Lublin
autor
- Lublin University of Technology, Department of Computer Modelling and Metal Forming Technologies, Lublin
autor
- Lublin University of Technology, Department of Computer Modelling and Metal Forming Technologies, Lublin
autor
- Lublin University of Technology, Department of Computer Modelling and Metal Forming Technologies, Lublin
Bibliografia
- [1] FU X.P., DEAN T.A., 1993, Past developments, current applications and trends in the cross wedge rolling process, International Journal of Machinery Tools Manufacture Design, Research and Application, 33/3 367-400.
- [2] URANKAR S., LOVELL M., MORROW C., LI Q., KAWADA K., 2006, Establishment of failure conditions for the cross-wedge rolling of hollow shafts, Journal of Materials Processing Technology, 177, 545-549.
- [3] PATER Z., BARTNICKI J., 2006, Finished cross-wedge rolling of hollowed cutters, Archives of Metallurgy and Materials, 51/2, 205-211.
- [4] PATER Z., 2011, Cross-wedge rolling of shafts with an eccentric step, Journal of Iron and Steel Research, International, 18/6, 26-30.
- [5] PATER Z., GONTARZ A., TOFIL A., 2011, Analysis of the cross-wedge rolling process of toothed shafts made from 2618 aluminium alloy, Journal of Shanghai Jiaotong University (Science), 16/2, 62-166.
- [6] PATER Z., GONTARZ A., WEROŃSKI W., 2008, Cross rolling of parts with non-circular cross section, Archives of Civil and Mechanical Engineering, 8/2, 139-147.
- [7] TOMCZAK J., PATER Z., BULZAK T., 2013, Effect of technological parameters on the rotary compression process, Eksploatacja i Niezawodnosc – Maintenance and Reliability, 15, 279–283.
- [8] ZHAO J., SHU X., HU Z., 2007, Computer aided design for cross wedge rolling tools of automobile semi-axes, Journal of Materials Processing Technology, 187-188, 41-45.
- [9] CELIKOV A. I. et al., 1971, Special rolling machines, Metallurgija, Moscow.
- [10] BARTNICKI J., 2009, The theoretical and experimental research of rolling – extrusion process, Ed. Politechnika Lubelska, Lublin, 1-118.
- [11] NEUGEBAUER R., GLASS R., KOLBE M., HOFFMANN M., 2002, Optimisation of processing routes for cross rolling and spin extrusion, Journal Material Processing Technology, 125-126, 856-862.
- [12] PATER Z., TOMCZAK J., BARTNICKI J., LOVELL M.R. AND MENEZES P.L., 2013, Experimental and numerical analysis of helical-wedge rolling process for producing steel balls, International Journal of Machine Tools & Manufacture, 67, 1–7.
- [13] TOMCZAK J., PATER Z., 2012, Analysis of metal forming process of a hollowed gear shaft, Metalurgija, 51/4, 497-500.
- [14] KAZANECKI J., 2003, Production of seamless pipes, Ed. AGH, Krakow, (in Polish).
- [15] WANG Q., HE F., 2004, A review of developments in the forging of connecting rods in China, Journal of Materials Processing Technology, 151, 192-195.
- [16] YIN F., WANG G.X., HONG S.Z., ZENG Z.P., 2003, Technological study of liquid die forging for the aluminum alloy connecting rod of an air compressor, Journal of Materials Processing Technology, 139, 462-464.
- [17] GRASS H., KREMPASZKY C., WERNER E., 2006, 3-D FEM-simulation of hot forming processes for the production of a connecting rod, Computational Materials Science, 36, 480-489.
- [18] HATZENBICHLER T., BUCHMAYR B., 2008, Vorformoptimierung für das Gesenkschmieden mittels numerischer Simulation, Berg- und hüttenmännische Monatshefte, BHM, 153, 413-417.
- [19] TAKEMASU T., VAZQUEZ V., PAINTER B., ALTAN T., 1996, Investigation of metal flow and preform optimization in flashless forging of a connecting rod, Journal of Materials Processing Technology, 59, 95-105.
- [20] VAZQUEZ V., ALTAN T., 2000, Die design for flashless forging of complex parts, Journal of Materials Processing Technology, 98, 81-89.
- [21] VAZQUEZ V., ALTAN T., 2000, New concepts in die design - physical and computer modeling applications, Journal of Materials Processing Technology, 98, 212-223.
- [22] DOEGE E., BOHNSACK R., 2000, Closed die technologies for hot forging, Journal of Materials Processing Technology, 98, 165-170.
- [23] BEHRENS B. A., DOEGE E., REINSCH S., TELKAMP K., DAEHNDEL H., SPECKER A., 2007, Precision forging processes for high-duty automotive components, Journal of Materials Processing Technology, 185, 139-146.
- [24] BELLET M., 1999, Finite Element Analysis of compressible viscoplasticity using a three-field formulation. Application to metal powder hot compaction, Computer Methods in Applied Mechanics and Engineering, 175, 19-40.
- [25] DALE J.R., 2005, Powder forged or C-70 steel? Now the MPIF strikes back, Metal Powder Report, 60, 14-17.
- [26] GONTARZ A., 2005, Effective forming processes on three slide forging press, Edited by Lublin University of Technology, Lublin, (in Polish).
- [27] WEROŃSKI W., GONTARZ A., PATER Z., 2006, The research of forging process of eccentric part on three slide forging press, Journal of Materials Processing Technology, 177, 214-217.
- [28] GONTARZ A., 2006, Forming process of valve drop forging with three cavities, Journal of Materials Processing Technology, 177, 228-232.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-ac977f15-b45b-4f44-8c0a-93baa99da18b