doc:user:elements:volumes:iso_hypo_materials
Differences
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| Both sides previous revisionPrevious revisionNext revision | Previous revision | ||
| doc:user:elements:volumes:iso_hypo_materials [2026/06/12 14:34] – [TmContinuousDamageEvpIsoHHypoMaterial] papeleux | doc:user:elements:volumes:iso_hypo_materials [2026/06/12 14:43] (current) – [TmContinuousDamageEvpIsoHHypoMaterial] papeleux | ||
|---|---|---|---|
| Line 50: | Line 50: | ||
| | Thermal expansion | | Thermal expansion | ||
| | Conductivity | | Conductivity | ||
| - | | Heat capacity | + | | Heat Capacity |
| - | | Heat capacity type : \\- ENTHALPY_CONSISTENT (default) necessary \\ for high variation of the Heat capacity (phase change) \\- POINT_WISE for slow variation of Heat Capacity | '' | + | | Heat Capacity Type : \\ - ENTHALPY_CONSISTENT (default) necessary \\ for high variation of the Heat capacity (phase change) \\ - POINT_WISE for slow variation of Heat Capacity | '' |
| | Dissipated thermoelastic power fraction | | Dissipated thermoelastic power fraction | ||
| | Dissipated (visco)plastic power fraction (Taylor-Quinney factor) | | Dissipated (visco)plastic power fraction (Taylor-Quinney factor) | ||
| Line 202: | Line 202: | ||
| :!: Thermomechanical calculation method : | :!: Thermomechanical calculation method : | ||
| * When the thermal expansion changes, an average value is computed over the time step is estimated to model this thermal expansion properly. | * When the thermal expansion changes, an average value is computed over the time step is estimated to model this thermal expansion properly. | ||
| - | * If the heat capacity changes, | + | * Heat Capacity Type allows to manage varying Heat Capacity : |
| + | * POINT_WISE : compute | ||
| + | * ENTHALPY_CONSISTENT (default) : an average value is computed to estimate properly the energy balance. An equivalent heat capacity can be used to take into account the latent heat (= heat capacity + latent heat). Needed for fast variation of HeatCapacity (ex: solid phase changes). | ||
| ---- | ---- | ||
| Line 217: | Line 219: | ||
| | Conductivity | | Conductivity | ||
| | Heat capacity | | Heat capacity | ||
| - | | Heat capacity type : \\- ENTHALPY_CONSISTENT (default) necessary \\ for high variation of the Heat capacity (phase change) \\- POINT_WISE for slow variation of Heat Capacity | + | | Heat capacity type : \\ - ENTHALPY_CONSISTENT (default) necessary \\ for high variation of the Heat capacity (phase change) \\ - POINT_WISE for slow variation of Heat Capacity |
| | Dissipated thermoelastic power fraction | | Dissipated thermoelastic power fraction | ||
| | Dissipated (visco)plastic power fraction (Taylor-Quinney factor) | | Dissipated (visco)plastic power fraction (Taylor-Quinney factor) | ||
| Line 283: | Line 285: | ||
| :!: Thermomechanical calculation method : | :!: Thermomechanical calculation method : | ||
| * When the thermal expansion changes, an average value is computed over the time step is estimated to model this thermal expansion properly. | * When the thermal expansion changes, an average value is computed over the time step is estimated to model this thermal expansion properly. | ||
| - | * If the heat capacity changes, | + | * Heat Capacity Type allows to manage varying Heat Capacity : |
| + | * POINT_WISE : compute | ||
| + | * ENTHALPY_CONSISTENT (default) : an average value is computed to estimate properly the energy balance. An equivalent heat capacity can be used to take into account the latent heat (= heat capacity + latent heat). Needed for fast variation of HeatCapacity (ex: solid phase changes). | ||
| ---- | ---- | ||
| Line 320: | Line 324: | ||
| | Conductivity | | Conductivity | ||
| | Heat Capacity | | Heat Capacity | ||
| - | | Heat Capacity Type : \\- ENTHALPY_CONSISTENT (default) necessary \\ for high variation of the Heat capacity (phase change) \\- POINT_WISE for slow variation of Heat Capacity | '' | + | | Heat Capacity Type : \\ - ENTHALPY_CONSISTENT (default) necessary \\ for high variation of the Heat capacity (phase change) \\ - POINT_WISE for slow variation of Heat Capacity | '' |
| | Dissipated thermoelastic power fraction | | Dissipated thermoelastic power fraction | ||
| | Dissipated (visco)plastic power fraction (Taylor-Quinney factor) | | Dissipated (visco)plastic power fraction (Taylor-Quinney factor) | ||
| Line 470: | Line 474: | ||
| :!: Thermomechanical calculation method : | :!: Thermomechanical calculation method : | ||
| * When the thermal expansion changes, an average value is computed over the time step is estimated to model this thermal expansion properly. | * When the thermal expansion changes, an average value is computed over the time step is estimated to model this thermal expansion properly. | ||
| - | * If the heat capacity changes, | + | * Heat Capacity Type allows to manage varying Heat Capacity : |
| + | * POINT_WISE : compute | ||
| + | * ENTHALPY_CONSISTENT (default) : an average value is computed to estimate properly the energy balance. An equivalent heat capacity can be used to take into account the latent heat (= heat capacity + latent heat). Needed for fast variation of HeatCapacity (ex: solid phase changes). | ||
| ---- | ---- | ||
| Line 487: | Line 493: | ||
| | Conductivity | | Conductivity | ||
| | Heat Capacity | | Heat Capacity | ||
| - | | Heat Capacity Type : \\- ENTHALPY_CONSISTENT (default) necessary \\ for high variation of the Heat capacity (phase change) \\- POINT_WISE for slow variation of Heat Capacity | '' | + | | Heat Capacity Type \\ - ENTHALPY_CONSISTENT (default) necessary \\ for high variation of the Heat capacity (phase change) \\ - POINT_WISE for slow variation of Heat Capacity | '' |
| | Dissipated thermoelastic power fraction | | Dissipated thermoelastic power fraction | ||
| | Dissipated (visco)plastic power fraction (Taylor-Quinney factor) | | Dissipated (visco)plastic power fraction (Taylor-Quinney factor) | ||
doc/user/elements/volumes/iso_hypo_materials.1781267680.txt.gz · Last modified: by papeleux