v6.07.108 COMP008 — Thermo-mechanical validation of elasto-plastic laws

Summary

This test makes it possible to validate the consideration of temperature variation in the laws of elastoplastic behavior. These tests make it possible to verify the following two points:

• Thermal expansion is well calculated (taking into account the variation of thermal expansion with temperature)

• The variation of the material coefficients with temperature is correct, especially in the incremental resolution of the behavior,

The validated laws of behavior are as follows:

• Modeling \(A\): this modeling makes it possible to validate the ELAS model with an isotropic material

• Modeling \(B\): this modeling makes it possible to validate the ELAS model with orthotropic material,

• Modeling \(C\): this modeling makes it possible to validate the model VMIS_ISOT_LINE,

• Modeling \(D\): this modeling makes it possible to validate the model VMIS_CINE_LINE,

• Modeling \(E\): this modeling makes it possible to validate the model VENDOCHAB,

• Modeling \(F\): this modeling makes it possible to validate the model VMIS_ECMI_LINE,

• Modeling \(G\): this modeling makes it possible to validate the model VMIS_CIN1_CHAB,

• Modeling \(H\): this modeling makes it possible to validate the model VMIS_CIN2_CHAB,

• Modeling \(I\): this modeling makes it possible to validate the model VMIS_CIN2_MEMO,

• Modeling \(J\): this modeling makes it possible to validate the model VISC_CIN1_CHAB,

• Modeling \(K\): this modeling makes it possible to validate the model VISC_CIN2_CHAB,

• Modeling \(L\): this modeling makes it possible to validate the model VISC_CIN2_MEMO,

• Modeling \(M\): this modeling makes it possible to validate the transverse isotropic elasticity,

• Modeling \(N\): this modeling makes it possible to validate the model ROUSS_PR.

• Modeling \(O\): this modeling makes it possible to validate the model VMIS_JOHN_COOK.

• 1. Methodology
  • 1.1. Simulation 1
  • 1.2. Simulation 2
• 2. Interpreting the results
• 3. Modeling A
  • 3.1. Characteristics of modeling
  • 3.2. Tested sizes and results
• 4. B modeling
  • 4.1. Characteristics of modeling
  • 4.2. Tested sizes and results
• 5. C modeling
  • 5.1. Characteristics of modeling
  • 5.2. Tested sizes and results
• 6. D modeling
  • 6.1. Characteristics of modeling
  • 6.2. Tested sizes and results
• 7. Modeling E
  • 7.1. Characteristics of modeling
  • 7.2. Tested sizes and results
• 8. F modeling
  • 8.1. Characteristics of modeling
  • 8.2. Tested sizes and results
• 9. G modeling
  • 9.1. Characteristics of modeling
  • 9.2. Tested sizes and results
• 10. H modeling
  • 10.1. Characteristics of modeling
  • 10.2. Tested sizes and results
• 11. Modeling I
  • 11.1. Characteristics of modeling
  • 11.2. Tested sizes and results
• 12. J modeling
  • 12.1. Characteristics of modeling
  • 12.2. Tested sizes and results
• 13. K modeling
  • 13.1. Characteristics of modeling
  • 13.2. Tested sizes and results
• 14. L modeling
  • 14.1. Characteristics of modeling
  • 14.2. Tested sizes and results
• 15. M modeling
  • 15.1. Characteristics of modeling
  • 15.2. Tested sizes and results
• 16. N modeling
  • 16.1. Characteristics of modeling
  • 16.2. Tested sizes and results
• 17. O modeling
  • 17.1. Characteristics of modeling
  • 17.2. Tested sizes and results
• 18. General summary of the results