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--- doc:user:elements:volumes:iso_hypo_materials [2016/03/30 15:23] – external edit 127.0.0.1
+++ doc:user:elements:volumes:iso_hypo_materials [2022/07/14 12:41] (current) – papeleux
@@ Line 17: / Line 17: @@
 | Young's modulus                                    |  ''ELASTIC_MODULUS''  |              |
 | Poisson Ratio                                      |   ''POISSON_RATIO''   |              |
+| Material Stiffness  \\ (STIFF_ANALYTIC - STIFF_NUMERIC) \\ only if element Stiffness == STIFF_ANALYTIC | ''MATERIALSTIFFMETHOD''  |      -       |
 | Objectivity Method \\ (Jaumann = 0, GreenNaghdi = 1) |    ''OBJECTIVITY''    |      -       |
 | Orthotropic axis                                   |    ''ORTHO_AX1_X''    |      -       |
@@ Line 37: / Line 38: @@
 | Young's modulus                                |  ''ELASTIC_MODULUS''  |             |
 | Poisson ratio                        |   ''POISSON_RATIO''   |             |
+| Material Stiffness  \\ (STIFF_ANALYTIC - STIFF_NUMERIC) \\ only if element Stiffness == STIFF_ANALYTIC | ''MATERIALSTIFFMETHOD''  |      -       |
 | Objectivity method \\ (Jaumann = 0, GreenNaghdi = 1)   |    ''OBJECTIVITY''    |     -       |
 | Orthotropic axis                              |    ''ORTHO_AX1_X''    |     -       |
@@ Line 64: / Line 66: @@
 \begin{cases}
 p^{1}  = p^{0} + 3K {\Delta\epsilon}_{ii} \\
-s^{1}_{ij}  = s^{0}_{ij} + 2G {\Delta\epsilon}_{ij} + \eta \frac{{\Delta\epsilon}_{ij}}{\Delta t}
+s^{1}_{ij}  = s^{0}_{ij} + 2G {\Delta\hat{\epsilon}}_{ij} + \eta \frac{{\Delta\hat{\epsilon}}_{ij}}{\Delta t}
 \end{cases}
 $$
@@ Line 78: / Line 80: @@
 | Young's modulus                                   |  ''ELASTIC_MODULUS''  |    TO/TM     |
 | Poisson Ratio                                     |   ''POISSON_RATIO''   |    TO/TM     |
+| Material Stiffness  \\ (STIFF_ANALYTIC - STIFF_NUMERIC) \\ only if element Stiffness == STIFF_ANALYTIC | ''MATERIALSTIFFMETHOD''  |      -       |
 | Viscosity coefficient                             |   ''VISCO_ETA''       |    TO/TM     |
@@ Line 86: / Line 89: @@
 The GeneralizedMaxwell viscoelastic model result in adding of up to now, maximum 2 visco-elastic Maxwell branches to the elastic material. The similar spring/damper model is shown at the figure below
-{{ :doc:user:elements:volumes:generalizedmaxwell.png?200 |}}
+{{ :doc:user:elements:volumes:generalizedmaxwell.png?400 |}}
 Defining Maxwell viscous parameters from materials data (for each Maxwell branch):
@@ Line 105: / Line 108: @@
 \begin{cases}
 p^{1}      &= p^{0} + 3K {\Delta\epsilon}_{ii} \\
-\underline{s}^{1}  &= s^{0}_{ij} + 2G {\Delta\underline{\epsilon}} +\underline{s}^{1}_{M1} + \underline{s}^{1}_{M2}
+\underline{s}^{1}  &= \underline{s}_{E}^{1} + \underline{s}^{1}_{M1} + \underline{s}^{1}_{M2}
 \end{cases}
 $$
+Stresses in each branch are computed using :
 $$
 \begin{cases}
-\underline{s}^{1}_{M1} &= e^{(\frac{-\Delta t}{\tau_{1}})} \underline{s}^{0}_{M1} + \Gamma_{1} (1-e^{\frac{-\Delta t}{\tau_{1}}}) \frac{\tau_{1}}{\Delta t} 2G {\Delta\underline{\epsilon}} \\
+\underline{s}_{E}^{1}  &= \underline{s}_{E}^{0} + 2G {\Delta\hat{\underline{\epsilon}}} \\
-\underline{s}^{1}_{M2} &= e^{(\frac{-\Delta t}{\tau_{2}})} \underline{s}^{0}_{M2} + \Gamma_{2} (1-e^{\frac{-\Delta t}{\tau_{2}}}) \frac{\tau_{2}}{\Delta t} 2G {\Delta\underline{\epsilon}} \\
+\underline{s}^{1}_{M1} &= e^{(\frac{-\Delta t}{\tau_{1}})} \underline{s}^{0}_{M1} + \Gamma_{1} (1-e^{\frac{-\Delta t}{\tau_{1}}}) \frac{\tau_{1}}{\Delta t} 2G {\Delta\hat{\underline{\epsilon}}} \\
+\underline{s}^{1}_{M2} &= e^{(\frac{-\Delta t}{\tau_{2}})} \underline{s}^{0}_{M2} + \Gamma_{2} (1-e^{\frac{-\Delta t}{\tau_{2}}}) \frac{\tau_{2}}{\Delta t} 2G {\Delta\hat{\underline{\epsilon}}} \\
 \end{cases}
 $$
@@ Line 127: / Line 131: @@
 | Young's modulus                                   |  ''ELASTIC_MODULUS''  |    TO/TM     |
 | Poisson Ratio                                     |   ''POISSON_RATIO''   |    TO/TM     |
+| Material Stiffness  \\ (STIFF_ANALYTIC - STIFF_NUMERIC) \\ only if element Stiffness == STIFF_ANALYTIC | ''MATERIALSTIFFMETHOD''  |      -       |
 | Number of Maxwell branches 1 (default) or 2       |  ''NBMAXWELLBRANCH''  |      -       |
 | Maxwel 1 Stiffness                                |   ''VISCO_MU1''       |      -       |
@@ Line 157: / Line 162: @@
 | Young's Modulus                                      |  ''ELASTIC_MODULUS''     |  ''TM''  |
 | Poisson Ratio                                     |   ''POISSON_RATIO''      |    -     |
+| Material Stiffness  \\ (STIFF_ANALYTIC - STIFF_NUMERIC) \\ only if element Stiffness == STIFF_ANALYTIC | ''MATERIALSTIFFMETHOD''  |      -       |
 | Thermal Expansion                                 |  ''THERM_EXPANSION''     |  ''TM''  |
 | Number of the material law which defines the yield stress  $\sigma_{yield}$     |      ''YIELD_NUM''       |    -     |
@@ Line 202: / Line 208: @@
 | Young's Modulus                                                              |  ''ELASTIC_MODULUS''  |  ''TO/TM''  |
 | Poisson Ratio                                                          |   ''POISSON_RATIO''   |  ''TO/TM''  |
+| Material Stiffness  \\ (STIFF_ANALYTIC - STIFF_NUMERIC) \\ only if element Stiffness == STIFF_ANALYTIC | ''MATERIALSTIFFMETHOD''  |      -       |
 | Thermal expansion                                                         |  ''THERM_EXPANSION''  |  ''TO/TM''  |
 | Number of the material law which defines the yield stress  $\sigma_{yield}$     |      ''YIELD_NUM''    |    -        |
@@ Line 235: / Line 242: @@
 | Young's Modulus                                      |  ''ELASTIC_MODULUS''     |  ''TM''  |
 | Poisson Ratio                                  |   ''POISSON_RATIO''      |    -     |
+| Material Stiffness  \\ (STIFF_ANALYTIC - STIFF_NUMERIC) \\ only if element Stiffness == STIFF_ANALYTIC | ''MATERIALSTIFFMETHOD''  |      -       |
 | Thermal expansion                                 |  ''THERM_EXPANSION''     |  ''TM''  |
 | Number of the material law which defines the yield stress  $\sigma_{yield}$   |      ''YIELD_NUM''       |    -     |
@@ Line 268: / Line 276: @@
 | Young's Modulus                                      |  ''ELASTIC_MODULUS''  |  ''TO/TM''  |
 | Poisson Ratio                                  |   ''POISSON_RATIO''   |  ''TO/TM''  |
+| Material Stiffness  \\ (STIFF_ANALYTIC - STIFF_NUMERIC) \\ only if element Stiffness == STIFF_ANALYTIC | ''MATERIALSTIFFMETHOD''  |      -       |
 | Thermal Expansion                                |  ''THERM_EXPANSION''  |  ''TO/TM''  |
 | Number of the material law which defines the yield stress  $\sigma_{yield}$      |    ''YIELD_NUM''  |  -   |
@@ Line 307: / Line 316: @@
 | Young's Modulus                           |   ''ELASTIC_MODULUS''  | |
 | Poisson Ratio                    |    ''POISSON_RATIO''   | |
+| Material Stiffness  \\ (0 : Ana - 1 : Num) \\ only if element Stiffness == STIFF_ANALYTIC | ''MATERIALSTIFFMETHOD''  |      -       |
 | Number of the material law which defines the yield stress  $\sigma_{yield}$  |      ''YIELD_NUM''       |    -     |
 | Number of the damage evolution law              |     ''DAMAGE_NUM''     | |
@@ Line 349: / Line 359: @@
 $$
-f=\dfrac{\overline{\sigma}}{1-D}-\sigma_{yield}=0
+f=\dfrac{\overline{\sigma}}{1-h\cdot D}-\sigma_{yield}=0
 $$
-where  $\overline{\sigma}$  is the equivalent stress computed as a function of [[doc:user:elements:volumes:plasticity_criterion#vonmisesplasticcriterion|Von Mises plasticy criterion]],  $\sigma_{yield}$  is the yield stress,  $D$  is the damage variable updated as a function of the [[doc:user:elements:volumes:continuousdamage|damage evolution law]].
+where  $\overline{\sigma}$  is the equivalent stress computed as a function of [[doc:user:elements:volumes:plasticity_criterion#vonmisesplasticcriterion|Von Mises plasticy criterion]],  $\sigma_{yield}$  is the yield stress,  $D$  is the damage variable updated as a function of the [[doc:user:elements:volumes:continuousdamage|damage evolution law]]. Moreover,  $h$  is the Micro-Crack Closure Effect parameter that makes the distinction of the weakening effect of damage under compressive and tensile stress states, which is defined as:
+$$
+ h = \left\{
+ \begin{array}{ll}
+  \text{DAMAGE_MCCE} &\mbox{, if } \dfrac{p}{J_2}< 0.0\\
+.0 &\mbox{, if } \dfrac{p}{J_2}\geq 0.0\\
+ \end{array}
+ \right.
+$$
 The evolution law coupled with plasticity can be integrated three ways depending on the parameter ''TYPE_INTEG'':
@@ Line 366: / Line 384: @@
 | Young's Modulus                               |   ''ELASTIC_MODULUS''   |  ''TM''  |
 | Poisson Ratio                           |    ''POISSON_RATIO''    |    -     |
+| Material Stiffness  \\ (0 : Ana - 1 : Num) \\ only if element Stiffness == STIFF_ANALYTIC | ''MATERIALSTIFFMETHOD''  |      -       |
 | Number of the material law which defines the yield stress  $\sigma_{yield}$  |      ''YIELD_NUM''       |    -     |
 | Number of the damage evolution law      |     ''DAMAGE_NUM''      |    -     |
 | Initial damage                         |     ''DAMAGE_INIT''     |    -     |
 | Integration method                         |     ''TYPE_INTEG''      |    -     |
+| Micro-Crack Closure Effect parameter (=1.0 by default)   |    ''DAMAGE_MCCE''     | |
 ===== ContinuousAnisoDamageEvpIsoHHypoMaterial =====
@@ Line 400: / Line 420: @@
 | Young's Modulus                               |   ''ELASTIC_MODULUS''   |  ''TM''  |
 | Poisson Ratio                           |    ''POISSON_RATIO''    |    -     |
+| Material Stiffness  \\ (0 : Ana - 1 : Num) \\ only if element Stiffness == STIFF_ANALYTIC | ''MATERIALSTIFFMETHOD''  |      -       |
 | Number of the material law which defines the yield stress  $\sigma_{yield}$    |      ''YIELD_NUM''       |    -     |
 | Number of the damage evolution law      |     ''DAMAGE_NUM''      |    -     |
@@ Line 426: / Line 447: @@
 | Young's Modulus                                                   |  ''ELASTIC_MODULUS''  |  ''TO/TM''  |
 | Poisson Ratio                                               |    ''POISSON_RATIO''  |    -       |
+| Material Stiffness  \\ (0 : Ana - 1 : Num) \\ only if element Stiffness == STIFF_ANALYTIC | ''MATERIALSTIFFMETHOD''  |      -       |
 | Number of the material law which defines the yield stress  $\sigma_{yield}$    |      ''YIELD_NUM''       |    -     |
 | Number of the damage evolution law                          |     ''DAMAGE_NUM''    |    -       |