Development of Finite Element Analysis Model for Plug Mill Rolling

T. Katsumura; Kazutoshi Ishikawa; Atsushi Matsumoto; Shunsuke Sasaki; Yasushi Kato; Jun Yanagimoto

doi:10.4028/www.scientific.net/KEM.622-623.899

Paper Titles

Metal Powder Injection Molding Process for Manufacturing Adapter Component
p.868

A New Rolling Model for Three-Roll Rolling Mills
p.879

A Study on the Rolling of a Multilayer Plate Composed of Teflon-Cu-SPCC Steel
p.887

Analysis of the Helical-Wedge Rolling Process for Producing a Long Stepped Shaft
p.893

Development of Finite Element Analysis Model for Plug Mill Rolling
p.899

Effect of Grain Size on Cross Wedge Rolling of Micro Copper Rod
p.905

Finite Element Modeling of Shear Strain in Rolling with Velocity Asymmetry in Multi-Roll Calibers
p.912

Hot Rolled Coil Property Heterogeneities due to Coil Cooling: Impact and Prediction
p.919

Influence of Process Parameters on Distribution of Shear Strain through Sheet Thickness in Asymmetric Rolling
p.929

HomeKey Engineering MaterialsKey Engineering Materials Vols. 622-623Development of Finite Element Analysis Model for...

Development of Finite Element Analysis Model for Plug Mill Rolling

Abstract:

In the seamless pipe rolling process, the pipe wall thickness is largely determined at the mandrel mill or plug mill. It is possible to obtain the target thickness at these mills by defining the gap of a grooved roll and an inside tool such as a plug. However, the thickness of the free deformation part, which is not in contact with the roll and tool, had generally been estimated by experimental techniques. Although a number of analytical studies of mandrel mill rolling had been reported, few reports had examined plug mill rolling. Therefore, in this research, a finite element analysis model for plug mill rolling was developed by extending the rigid plasticity finite element model "Computational Rolling Mill (CORMILL)." Good agreement between the calculated results and experimental results was obtained for the wall thickness, and it was found that the thickness of the flange part decreases with reduction of the wall thickness at the grooved bottom. These results suggested that the wall thickness distribution of rolled pipes can be controlled by using a suitable inside tool and roll shape in each rolling pass, and the necessary shapes can be obtained by using the newly-developed model.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Key Engineering Materials (Volumes 622-623)

Pages:

899-904

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.622-623.899

Citation:

Cite this paper

Online since:

September 2014

Authors:

T. Katsumura*, Kazutoshi Ishikawa, Atsushi Matsumoto, Shunsuke Sasaki, Yasushi Kato, Jun Yanagimoto

Keywords:

Rolling , Finite Element Analysis (FEA), Flow Stress, Grooved Roll, Plug Mill, Rigid Plasticity, Seamless Pipe, Wall Thickness

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] A. Ghiotti, S. Fanini, S. Bruschi, P.F. Bariani, Modelling of the Mannesmann effect, CIRP Ann. Manuf. Technol., 58 (2009), 255-258.

DOI: 10.1016/j.cirp.2009.03.099

Google Scholar

[2] A. Krux, M. Zemko, FEM-modelling of Barrel-type Cross-roll Piercing and Analysis of the Rotational Motion of the Plug Bar, Steel Res. Int., ICTP2011 Special Edition(2011).

Google Scholar

[3] T. Hirakawa, Y. Mihara, M. Kamata, S. Akita, M. Numano, Theoretical Analysis on Mandrel Rolling, The 3rd Int. Conf. on Steel Rolling, 231-238(1985).

Google Scholar

[4] S. Yamamoto, S. Tamura, Y. Wada, K. Hamauzu, Modeling of cross-sectional shape of rolled tube and forward slip ratio for single stand rolling of Mandrel Mill, Simul. Mater. Proc. Theory Method Appl. 1998(Int. Conf. Num. Industrial Form. Proc. (6th), 707-713 (1998).

Google Scholar

[5] V. Palma, S. Bandini, J. H. Pehle, P. Thieven, The PQF Mill (Premium Quality Finishing Mill)-The Ultimate Process for High Quality Seamless Tube Production, Mech. Work Steel Proc., 37(1999), 585-595.

Google Scholar

[6] K. Hori, M. Yamada, Comparison of rolling characteristic between 2-roll mandrel mill and 3-roll mandrel mill, CAMP-ISIJ, 11-2(1998), 344. (in Japanese).

Google Scholar

[7] Yan Zesheng, Zhuang Gang, Sun Qiang, New Manufacuturing Technique on Seamless Tube Rolling, The 10th Int. Conf. on Steel Rolling, 1405-1409(2010).

Google Scholar

[8] J. Yanagimoto, Y. Kadomura, T. Muto and K. Inoue, Strategic CAE System for the Design of Calibers in the Rolling of Complex Sections, Steel Research, 73-12(2002), 526-530.

DOI: 10.1002/srin.200200023

Google Scholar

[9] Edited by The Iron and Steel Institute of Japan, Handbook of Iron and Steel 3rd edition Chap. 11, Maruzen (1980), Tokyo, 958. (in Japanese).

Google Scholar

[10] H. Abe, K. Nakagawa, T. Imae, A. Ejima, Material deformation and characteristics of rolling load in plug mill rolling for seamless pipe, Proc. the 1981 Jap. Spring Conf. Technol. of Plasticity (1981), 233-236 (in Japanese).

Google Scholar

[11] T. Okui, M. Yamada, T. Yamada, Deformation Analysis of a Three-Roll Reducing Mill, J. Jap. Soc. Technol. Plasticity, 38-432(1997-1), 76-80. (in Japanese).

Google Scholar