Access the full text.
Sign up today, get DeepDyve free for 14 days.
E. Hinton, John Campbell (1974)
Local and global smoothing of discontinuous finite element functions using a least squares methodInternational Journal for Numerical Methods in Engineering, 8
S. Oh, J. Park, Shiro Kobayashi, T. Altan (1983)
Application of FEM Modeling to Simulate Metal Flow in Forging a Titanium Alloy Engine DiskJournal of Engineering for Industry, 105
T. Liszka, J. Orkisz (1980)
The finite difference method at arbitrary irregular grids and its application in applied mechanicsComputers & Structures, 11
G. Cantin, G. Loubignac, G. Touzot (1978)
An iterative algorithm to build continuous stress and displacement solutionsInternational Journal for Numerical Methods in Engineering, 12
O. Zienkiewicz, P. Godbole (1974)
Flow of plastic and visco‐plastic solids with special reference to extrusion and forming processesInternational Journal for Numerical Methods in Engineering, 8
N. Rebelo, Shiro Kobayashi (1980)
A coupled analysis of viscoplastic deformation and heat transfer—I: Theoretical considerationsInternational Journal of Mechanical Sciences, 22
O. Zienkiewicz, D. Owen, K. Lee (1974)
Least square-finite element for elasto-static problems. Use of `reduced' integrationInternational Journal for Numerical Methods in Engineering, 8
C. Lee, Shiro Kobayashi (1973)
New Solutions to Rigid-Plastic Deformation Problems Using a Matrix MethodJournal of Engineering for Industry, 95
Nathalie Soyris, J. Cescutti, T. Coupez, G. Brachotte, J. Chenot (1988)
Three Dimensional Finite Element Calculation of the Forging of a Connecting Rod
J. Park, Shiro Kobayashi (1984)
Three-dimensional finite element analysis of block compressionInternational Journal of Mechanical Sciences, 26
J. Marcelin, M. Abouaf, J. Chenot (1986)
Analysis of residual stresses in hot-rolled complex beamsApplied Mechanics and Engineering, 56
J. Argyris, J. Doltsinis (1981)
On the natural formulation and analysis of large deformation coupled thermomechanical problemsComputer Methods in Applied Mechanics and Engineering, 25
J. Price, J. Alexander (1979)
Specimen geometries predicted by computer model of high deformation forgingInternational Journal of Mechanical Sciences, 21
G. Comini, S. Guidice, R. Lewis, O. Zienkiewicz (1974)
Finite element solution of non‐linear heat conduction problems with special reference to phase changeInternational Journal for Numerical Methods in Engineering, 8
G. Surdon, J. Chenot (1987)
Finite element calculation of three‐dimensional hot forgingInternational Journal for Numerical Methods in Engineering, 24
T. Hughes, Wing Liu, A. Brooks (1979)
Finite Element Analysis of Incompressible Viscous Flows by the Penalty Function FormulationJournal of Computational Physics, 30
O. Zienkiewicz, Li Xi-kui, S. Nakazawa (1985)
Iterative solution of mixed problems and the stress recovery proceduresCommunications in Applied Numerical Methods, 1
Shiro Kobayashi (1982)
A review on the finite-element method and metal forming process modelingJournal of Applied Metalworking, 2
This paper presents the results of the simulation of the forging of a connecting rod. The calculation has been carried out by the code FORGE3 developed at the CEMEF laboratory. FORGE3 is a threedimensional finite element computer program that can simulate hot forging of industrial parts. The flow problem is solved using a thermomechanical analysis. The mechanical resolution and the thermal one are coupled by the way of the consistency K which is thermodependent, the plastic deformation in the volume of the material and the friction heat flux on the surface. The material behaviour is assumed to be incompressible and viscoplastic NortonHoff law with the associated friction law. The thermal resolution includes the case of nonlinear physical properties and boundary conditions. An explicit Euler scheme is used for the mechanical resolution and twostep schemes for the thermal one. For the computation of other parameters, it is necessary to have a good approximation for the strain rate tensor. The Orkisz method has been used to determine the deviatoric stress tensor and p is calculated by an original smoothing method. The results show that it is possible to get good information on the flow and on the physical properties during forging of automotive parts. Comparisons have been made with experimental measurements with a reasonably good agreement.
Engineering Computations: International Journal for Computer-Aided Engineering and Software – Emerald Publishing
Published: Jan 1, 1992
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.