Load Prediction for the Extrusion from Circular Billet to Symmetric and Asymmetric Polygons Using Linearly Converging Die Profiles

J.S. Ajiboye; S.T. Oyinbo

doi:10.4028/www.scientific.net/KEM.622-623.119

Paper Titles

Bridge Design Influences on the Pressure Conditions in the Welding Chamber for Porthole Die Extrusion
p.87

Effects of Temperature and Cross Section Variations on the Vibrational Behavior of Finished Wire Blocks
p.95

Environmental Comparison between a Hot Extrusion Process and Conventional Machining Processes through a Life Cycle Assessment Approach
p.103

Investigation of the Mandrel’s Stress States and Wear Conditions during Tube Hot Extrusion of IN690 Superalloy
p.111

Load Prediction for the Extrusion from Circular Billet to Symmetric and Asymmetric Polygons Using Linearly Converging Die Profiles
p.119

Method for Producing Twist Drills by Extrusion Using a Three-Slide Forging Press
p.129

Numerical Simulation of the Crystallographic Texture Evolution during Hot Extrusion of Oxides Dispersed Strengthened Steels
p.136

Effect of ECAE on Structure and Strength of Porous A6061 Alloy with Aligned Unidirectional Pores
p.148

The Effects of Non-Metallic Inclusion on Ductile Damage of High Carbon Steel Wire in Multi-Pass Dry Drawing Process
p.155

HomeKey Engineering MaterialsKey Engineering Materials Vols. 622-623Load Prediction for the Extrusion from Circular...

Load Prediction for the Extrusion from Circular Billet to Symmetric and Asymmetric Polygons Using Linearly Converging Die Profiles

Abstract:

The deformation load is the most important parameter in the press design as it affects the structure and the general integrity of the final product. Therefore, every other parameter such as die shape, friction, type of process (hot or cold), and speed considered in modeling is optimized to cut back on the metal forming load. The flow of metal is largely influenced by the geometry of the die and hence the geometric shape of the tools is the main factor by which an optimum load can be evaluated. In extrusion process the strain distribution, resulting from deformation load, and other important variables that influence material structure, such as a hydrostatic stress, are strongly dependent on the geometry of the die. In the present investigation using linearly converging die profiles, the extrusion of symmetric and asymmetric polygons such as circular, square, triangular, hexagonal, heptagonal, octagonal, and L-, T-and H-, respectively sections from round billet have been numerically simulated. Mathematical equations describing the die profiles were derived, and then using MATLAB R2009b the co-ordinate of the die profiles was evaluated. A solid CAD model for the linearly converging die profile was made using Autodesk Inventor 2013 software and numerical analysis using DEFORM software for extrusion of the above sections from round billet was then performed to predict, for dry and lubricated condition, the extrusion load during deformation. It is found that the predictive loads for asymmetric shapes are found to be higher than that of the symmetric shapes. While there is no marked difference between the predictive loads for symmetric shapes that of the asymmetric shapes is significant where L-section has the highest extrusion load, followed by T-section and the H-section given the least pressure.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Key Engineering Materials (Volumes 622-623)

Pages:

119-128

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.622-623.119

Citation:

Cite this paper

Online since:

September 2014

Authors:

J.S. Ajiboye*, S.T. Oyinbo

Keywords:

Asymmetric, Extrusion, FEM Modeling, Linearly Converging Dies, Polygons, Symmetric

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] T. Sheppard, Extrusion of AA2024 Alloy, Materials Science Technology 9 (1993) 430-440.

Google Scholar

[2] N. Solomon and I. Solomon, Effect of die shape on the metal flow pattern during direct extrusion process, Revista de Metalurgia, 46 (5), 2010, 396-404.

DOI: 10.3989/revmetalm.0928

Google Scholar

[3] I. Flitta, T. Sheppard and Z. Peng, FEM analysis to predict development of structure during extrusion and subsequent solution soak cycle, Materials Science and Technology, 23 (5) 2007, 582-592.

DOI: 10.1179/174328407x158668

Google Scholar

[4] Libura, W. & Zasadzinski, J., The influence of strain gradient on material structure during extrusion of the AlCu4Mg alloy, Journal of Material Processing Technology, vol. 34, 1992, pp.517-524.

DOI: 10.1016/0924-0136(92)90149-m

Google Scholar

[5] M. Jolgaf, S.B. Sulaiman, M.K.A. Ariffin, and A.A. Faieza, Billet Shape Optimization for Minimum Forging Load , European Journal of Scientific Research, 24 (3) (2008), 420-427.

Google Scholar

[6] R. Narayanasamy, R. Ponalagusamy, R. Venkatesan, P. Srinivasan, An upper boundary solution to extrusion of circular billet to circular shape through cosine dies, Materials and Design 27 (2006) 411–415.

DOI: 10.1016/j.matdes.2004.11.026

Google Scholar

[7] W.A. Gordon, C.J. Van Tyne, Y.H. Moon, Overview of adaptable die design for extrusions, Journal of Materials Processing Technology 187–188 (2007) 662–667.

DOI: 10.1016/j.jmatprotec.2006.11.158

Google Scholar

[12] K. P. Maity, A. K. Rout, Kalu Majhi, computer-aided simulation of metal flow through curved die for extrusion of square section from square billet , Presented in International Conference on Extrusion and Benchmark, Dortmund, Germany, 16-17 September, (2009).

DOI: 10.4028/www.scientific.net/kem.424.181

Google Scholar

[14] T. Chanda, J. Zhou, J. Duszczyk, FEM analysis of aluminium extrusion through square and round dies , Materials and Design 21 (2000) 323-335.

DOI: 10.1016/s0261-3069(99)00073-4

Google Scholar

[15] Zhi Peng, Terry Sheppard, Simulation of multi-hole die extrusion, Materials Science and Engineering A 367 (2004) 329–342.

DOI: 10.1016/j.msea.2003.10.294

Google Scholar

[16] OO. Onawola and MB. Adeyemi, Warm compression and extrusion tests of Aluminium, Journal of Materials Processing Technology, 2005, 136, 7-11.

DOI: 10.1016/s0924-0136(02)00462-4

Google Scholar