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Verification of sheet metal forming simulation of advanced thin plate parts using a first order friction model

Gabrielson, Per LU ; Ekdahl, Lars ; Hafsäter, Viktor and Löfgren, Hans (2013) Towards Zero Failure Production Methods by Advanced Modeling Techniques and a Process Integrated Virtual Control, IDDRG 2013 International Conference
Abstract
There is today a need of better prediction of part geometry regarding industrial products by simulations. There is a need for better prediction of material inflow, stresses and strains and final geometry. One way to solve this could be by using a more advanced friction model. Today a zero order friction model (Coulomb friction) is normally used. By using a friction model of higher order the friction is not constant and can be changed depending on both different input parameters set from start in friction equation such as surface roughness, hardness, dynamic viscosity and numerous parameters that are automatic inputs to the friction equation during the forming process and taken from the actual FEM simulation such as sliding ve-locity and... (More)
There is today a need of better prediction of part geometry regarding industrial products by simulations. There is a need for better prediction of material inflow, stresses and strains and final geometry. One way to solve this could be by using a more advanced friction model. Today a zero order friction model (Coulomb friction) is normally used. By using a friction model of higher order the friction is not constant and can be changed depending on both different input parameters set from start in friction equation such as surface roughness, hardness, dynamic viscosity and numerous parameters that are automatic inputs to the friction equation during the forming process and taken from the actual FEM simulation such as sliding ve-locity and load. In this paper a first order friction model regarding effects and changes when simulating the forming of advanced thin plate parts has been evaluated. The evaluation has been performed in several steps. First an analysis of variance was made to see how different input parameters, and variation of these, affect the output regarding material inflow, formability and calculated friction at a specific position. Of course also the actual setup of the forming simulation influences the output and can be even more important to adjust when using a higher order friction model. Because of this different ways of meshing were evaluated. A final verification has been made in a special demonstrator tool. In this tool it is possible to evaluate the effects in a scientific way and the tool is verified against real part production. (Less)
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author
; ; and
organization
publishing date
type
Chapter in Book/Report/Conference proceeding
publication status
published
subject
keywords
Friction model, stainless steel, formability, forming simulation, sheet metal forming
host publication
Towards Zero Failure Production Methods by Advanced Modeling Techniques and a Process Integrated Virtual Control: IDDRG 2013 Conference Proceedings
publisher
ETH, Zürich
conference name
Towards Zero Failure Production Methods by Advanced Modeling Techniques and a Process Integrated Virtual Control, IDDRG 2013 International Conference
conference location
Zurich, Switzerland
conference dates
2013-06-02 - 2013-06-05
ISBN
978-3-906031-34-7
language
English
LU publication?
yes
additional info
IDDRG International Conference IDDRG Conference International Deep Drawing Research Group Conference
id
afc17d64-33fa-4ddd-91a2-412320025df1 (old id 4378553)
date added to LUP
2016-04-04 11:55:47
date last changed
2018-11-21 21:08:02
@inproceedings{afc17d64-33fa-4ddd-91a2-412320025df1,
  abstract     = {{There is today a need of better prediction of part geometry regarding industrial products by simulations. There is a need for better prediction of material inflow, stresses and strains and final geometry. One way to solve this could be by using a more advanced friction model. Today a zero order friction model (Coulomb friction) is normally used. By using a friction model of higher order the friction is not constant and can be changed depending on both different input parameters set from start in friction equation such as surface roughness, hardness, dynamic viscosity and numerous parameters that are automatic inputs to the friction equation during the forming process and taken from the actual FEM simulation such as sliding ve-locity and load. In this paper a first order friction model regarding effects and changes when simulating the forming of advanced thin plate parts has been evaluated. The evaluation has been performed in several steps. First an analysis of variance was made to see how different input parameters, and variation of these, affect the output regarding material inflow, formability and calculated friction at a specific position. Of course also the actual setup of the forming simulation influences the output and can be even more important to adjust when using a higher order friction model. Because of this different ways of meshing were evaluated. A final verification has been made in a special demonstrator tool. In this tool it is possible to evaluate the effects in a scientific way and the tool is verified against real part production.}},
  author       = {{Gabrielson, Per and Ekdahl, Lars and Hafsäter, Viktor and Löfgren, Hans}},
  booktitle    = {{Towards Zero Failure Production Methods by Advanced Modeling Techniques and a Process Integrated Virtual Control: IDDRG 2013 Conference Proceedings}},
  isbn         = {{978-3-906031-34-7}},
  keywords     = {{Friction model; stainless steel; formability; forming simulation; sheet metal forming}},
  language     = {{eng}},
  publisher    = {{ETH, Zürich}},
  title        = {{Verification of sheet metal forming simulation of advanced thin plate parts using a first order friction model}},
  year         = {{2013}},
}