Numerical simulation of friction extrusion: process characteristics and material deformation due to friction
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In: International Journal of Material Forming, Vol. 17, No. 3, 26, 05.2024.
Research output: Journal contributions › Journal articles › Research › peer-review
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TY - JOUR
T1 - Numerical simulation of friction extrusion
T2 - process characteristics and material deformation due to friction
AU - Diyoke, George
AU - Rath, Lars
AU - Chafle, Rupesh
AU - Ben Khalifa, Noomane
AU - Klusemann, Benjamin
N1 - Publisher Copyright: © The Author(s) 2024.
PY - 2024/5
Y1 - 2024/5
N2 - This study employs a finite element thermo-mechanical model, using a Lagrangian incremental setting to investigate friction extrusion (FE) under varying process conditions. The incorporation of rotation in FE generates substantial frictional heat, leading to significantly reduced process forces in comparison to conventional extrusion (CE). The model reveals the interplay between temperature, strain, and strain rate across different microstructural zones of the resulting wire. Specifically, the sticking friction condition in FE enhances initial shear deformation, aligning with a homogeneous spatial strain distribution and predicting complete grain refinement in the extruded wire, as per Zener-Hollomon calculations. On the other hand, under the sliding friction condition in FE, the shear deformation is reduced which results in an inhomogeneous microstructure in the extruded wire. The analysis of material flow in the workpiece reveals distinct transitions from the base material to the thermo-mechanically affected zones. The simulated process force, thermal history, and microstructure during sliding friction conditions align well with the findings from performed friction extrusion experiments.
AB - This study employs a finite element thermo-mechanical model, using a Lagrangian incremental setting to investigate friction extrusion (FE) under varying process conditions. The incorporation of rotation in FE generates substantial frictional heat, leading to significantly reduced process forces in comparison to conventional extrusion (CE). The model reveals the interplay between temperature, strain, and strain rate across different microstructural zones of the resulting wire. Specifically, the sticking friction condition in FE enhances initial shear deformation, aligning with a homogeneous spatial strain distribution and predicting complete grain refinement in the extruded wire, as per Zener-Hollomon calculations. On the other hand, under the sliding friction condition in FE, the shear deformation is reduced which results in an inhomogeneous microstructure in the extruded wire. The analysis of material flow in the workpiece reveals distinct transitions from the base material to the thermo-mechanically affected zones. The simulated process force, thermal history, and microstructure during sliding friction conditions align well with the findings from performed friction extrusion experiments.
KW - Dynamic recrystallization
KW - Friction condition
KW - Material flow behavior
KW - Microstructure zones
KW - Process simulation
KW - Thermo-mechanical condition
KW - Engineering
UR - http://www.scopus.com/inward/record.url?scp=85189855053&partnerID=8YFLogxK
UR - https://www.mendeley.com/catalogue/aca61616-239e-341e-8de4-a715af89b428/
U2 - 10.1007/s12289-024-01825-z
DO - 10.1007/s12289-024-01825-z
M3 - Journal articles
AN - SCOPUS:85189855053
VL - 17
JO - International Journal of Material Forming
JF - International Journal of Material Forming
SN - 1960-6206
IS - 3
M1 - 26
ER -