Coupled Simulation of Forming and Welding
Transcript of Coupled Simulation of Forming and Welding
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Dr.-Ing. Tobias Loose07.10.2014, BambergLS-DYNA Forum
Coupled Simulation of Forming and Welding with LS-DYNA for the design of
Distortion-Compensation
Herdweg 13, D-75045 Wössingen Lkr. KarlsruheCourriel: [email protected] Web: www.tl-ing.de, www.loose.at
Mobil: +49 (0) 176 6126 8671 Tel: +49 (0) 7203 329 023 Fax: +49 (0) 7203 329 025
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Numerical Simulation forWelding and Heat Treatment since 2004
Consulting - Training - SupportDistribution of software for
Welding and Heat Treatment Simulation
Herdweg 13, D-75045 Wössingen Lkr. KarlsruheE-Post: [email protected] Web: www.tl-ing.eu www.loose.at
Mobil: +49 (0) 176 6126 8671 Tel: +49 (0) 7203 329 023 Fax: +49 (0) 7203 329 025
Internet:DEeutsch: www.loose.atENglisch: www.tl-ing.euESpanol: www.loose.es
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Introduction
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Simulation of Process Chain
FormingHeat
Treatment
Assembly
Welding Post WeldHeat Treatment
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Specific Features of Welding and Heat Treatment Simulation
Material Properties– material properties depend on temperature– material properties change in thermal loading cycles
→ change of microstructure / phase transformation
History Variables– stress, strain, strain hardening– phase proportion
Material Modell– reset of material history– phase transformation– phase transformation effects
MaterialSimulation
Process Simulation
Structure Simulation
Welding & HTSimulation
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Simulation of Process Chain
MaterialSimulation
Process Simulation
Structure Simulation
Welding & HTSimulation
Forming
CrashClamping and Predeformation
Cutting andGrinding
Assembly
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Simulation of Process Chain
Method A:• Each simulation task with a
special simulation tool• Each simulation task with a
specific material modell• Transfer of informations between
two tasks via special interfaces• Mapping of results
Consequence:• Information loss from one step to
the next step by mapping • Problem of interface compatibility• Multiple license costs
Method B:• As many simulation task as
possible in one simulation tool• Each simulation task with the same
material modell• Continous transfer of information
within the same code and the same data structure
• Avoid mapping of results.Consequence:• No information loss between single
simulation steps• No trouble with interface
compatibility• Save of license costs
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Benefit of a Continous Simulation of Process Chain
• Precalcualtion of the final state of the assembly:– geometry– residual stresses– microstructure
• Complete simulation of the entire manufacturing process• Take into account the two way impact of single manufacturing tasks
• Enables the design of the manufacturing process• Enables the desing of compensation methods for requested conditions
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Process Chain Manufacturing
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Manufacturing of a BoxTask and Model
Forming:• The roof geometry is made by forming a 3 mm thick sheet (1.4301)Assembly:• Add the sidewallWelding:• Weld the sidewall to the roofClamp and predeformation:• press the sidewall on measureAssembly:• Add the bottom plateWelding:• Weld the bottom plate to the sidewallUnclampingModel:• Solid-element model• Material model (*MAT_270) is used in all steps• History variables and deformations are kept from one step to an other• Implicit analysis in all steps
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Welded AssemblysDeep-Drawing of a CupProcess Chain Welding - FormingProcess Chain Welding - Crash
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Deep-Drawing of a Cup from a Laser Welded SheetTask and Model
Welding:• Two sheets (S355) with 1 mm wall thickness are laser weldedForming:• The welded and distorted sheet is clamped• a globular die is pressed slow in the sheet.
Crash:• The welded and distorted sheet is free• a bullet impacts the sheet with a speed of
5000 m/s
Model:• Shell-elements are used for the sheet, solid elements are used for the clamps and the die• Same material model (*MAT_244) is used in all steps• History variables, phase proportions and deformations are kept from one step to an other• Welding: implicit analysis, Forming / Crash: explicit analysis
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Weldingz-displacement 10-times scaled
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Vertical Distortion
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Stresses and Strains in Midsurface of Shell
After welding and coolingtop left: Longitudinal stresstop right: Effectiv stress (v. Mises)bottom right: plastic strain
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Microstructure
After welding and coolingtop left: Ferrit proportiontop right: Bainit proportionbottom right: Martensit proportion
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Deep drawing – effectiv stress
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Stresses and Strains in Midsurface of Shell
top left: effectiv stress bevor unclamping 200 .. 1100 N/mm²
bottom left: effectiv stess after unclamping 0 .. 200 N/mm²
bottom right: plastic strain after unclamping 0 .. 0.65 m/m
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Microstructure during Deep-Drawing
top left: Ferrit proportiontop right: Bainit proportionbottom right: Martensit proportion
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Effective Stress during FormingInfluence of Material Property Change from Welding
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Thinning of the SheetInfluence of Material Property Change from Welding
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Crash – Effective StressImpact Velocity 5000 m/s
Skala: 0 .. 200 N/mm²
Skala: 0 .. 1000 N/mm²
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Effective Stress During CrashInfluence of Material Property Change from Welding
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Thinning of the sheetInfluence of Material Property Change from Welding
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Comparison between Forming and Crasheffective Stress at same Penetration Depth
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Distortion CompensationPredeformation
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Rolling and Welding of a thin Walled BeamTask and Model
Rolling:• A 1500 mm long sheet (S355) with 1 mm wall thickness is rolled to a groove
Welding:• A ground plate is longitudinal welded to the grooveModel:• Shell-elements are used for the sheet and the ground plate• Solid-elements are used for the filler material and the clamps• Same material model (*MAT_244) is used in all steps for shells and for solids• History variables, and deformations are kept from one step to an other
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Distortion Evolution during WeldingMetatransient Method
Temperature
Distortion
Max vertical distortion during welding:22 mm down
Max vertical distortion after cooling:2,7 mm up
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Compensation of distortion
Method A: • Stamping of the groove with the inverted final distortion from welding.Method B: • Predeformation in vertical direction during welding as shown below:
no vertical distortion after welding
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Summary
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Summary
• The manufacturing process comprises several different steps.• These several steps interact and may influence each other.• For a realistic simulation of the manufacturing process results of previous
simulation steps has to be taken as initial conditions.• The finite element code LS-DYNA provides the feasability to simulate the
manufacturing steps:forming, assembly, welding, post-weld-heat-treatment, grinding, crash– in one code– with continuous data structure– with continuous material modell and continuous history variables– take into account material property change– without loss of information by mapping
• Shell-, solid- and mixed shell-solid models can be used • Thus LS-DYNA is a suitable solution for the simulation of the process chain
to simulate complex manufacturing prosesses.
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Thanks for your Attention!