Abstract
Change in the temperature of band over its length, associated with the stock being non-uniformly heated in the furnace, influences the variations in the magnitudes of energy-force parameters. Using the FEM (Finite Element Model) programs for the computation of the values of the energy-force parameters can take into account the distribution of temperature over the band length. The mathematical model of the computer program Forge2008 was used to theoretically examine the energy-force parameters and plastic metal flow in the roughing stands of the continuous rolling mill. The results of experimental investigation of influence of the non-uniform temperature distribution were presented on the metallic charge length on the energy and force parameters and dimensions of the band during round bars rolling. Thermovision monitoring energy and force parameters monitoring were carried out in continuous rolling mill D350 in one of the Polish industrial plants. On the basis of obtained results, it could be stated that non-uniform distribution of temperatures along the charge length causes local increase of energy and force parameters values and also such distribution affects the local increase of the width of rolled band. The rolling process of charge with non-uniform distribution of temperature could lead to exceeding required dimensional tolerances of the final products.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Szota P. Numerical Analysis of the 45 mm Reinforcement Bar Rolling Process [J]. Journal of Achievements in Materials and Manufacturing Engineering, 2008, 28(1): 67.
Milenin A, Dyja H, Mróz S. Simulation of Metal Forming During Multi-Pass Rolling of Shape Bars [J]. Journal of Materials Processing Technology, 2004, 153–154: 108.
Chekmariev A P, Niefiedov A A, Nikolajev B A. Theory of Longitudinal Rolling [M]. Moscow: Metallurgija, 1965 (in Russian).
Brovman M. Application of the Theory of Plasticity During Rolling [M]. Moscow: Metallurgija, 1991 (in Russian).
Zhuchyn B N, Nikitin G C, Shvarcbart J C, et al. Calculation of Energy and Force Parameters During Continuous Hot Rolling Process [M]. Moscow: Metallurgija, 1986 (in Russian).
Głowacki M, Mróz S, Lesik L. Analysis of Application the Empirical Equations to the Calculation of Groove Rolling Power Parameters [J]. Hutnik-Wiadomosci Hutnicze, 1999, 11: 523.
Labuda E, Dyja H, Lesik L. Effectiveness and Directions to Improve the Accuracy Products Mills [J]. Hutnik-Wiadomosci Hutnicze, 1992, 8: 265.
Chenot J L, Bay F. An Overview of Numerical Modeling Techniques [J]. Journal of Materials Processing Technology, 1998, 80–81: 8.
Norton F H. Creep of Steel at High Temperature [M]. New York: McGraw Hill, 1929.
Hoff N J. Approximate Analysis of Structures in the Presence of Moderately Large Steps Deformation [J]. Quart, Appl Mech, 1954 (2): 49.
Hansel A, Spittel T. Calculation of Energy and Force Parameters in Metal Working Processes [M]. Lipsk: VEB Deutscher Verlang fur Grundstof f industrie, 1979 (in German).
Mróz S, Jagiela K, Dyja H. Determination of the Energy and Power Parameters During Groove-Rolling [J]. Journal of Achievements in Materials and Manufacturing Engineering, 2007, 22(2): 59.
Mróz S. Influence of Change in the Temperature of Band Over Its Length on Energy-Power Parameters [J]. Obrabotka Materialov Davlenijem, Sbornik Nauchnykh Trudov, 2008, 1: 272.
Mróz S, Sygut P, Dyja H. Influence of the Temperature Changes on the Band Length on the Metal Plastic Flow [J]. Hutnik-Wiadomosci Hutnicze, 2009, 8: 632.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Sebastian, M. Influence of Non-Uniform Temperature Distribution on Metallic Charge Length on Energy and Force Parameters During Groove-Rolling. J. Iron Steel Res. Int. 19, 17–24 (2012). https://doi.org/10.1016/S1006-706X(12)60134-4
Received:
Published:
Issue Date:
DOI: https://doi.org/10.1016/S1006-706X(12)60134-4