Difference between revisions of "Isotropic Plastic Softening Material"
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== Constitutive Law == | == Constitutive Law == | ||
This [[Material Models|MPM | This [[Material Models#Softening Materials|MPM softening material]] is an isotropic, elastic-plastic material that can also develop anisotropic damage. | ||
In the | In the absence of damage, this material is identical to an [[Isotropic, Elastic-Plastic Material]]. In the absence of plasticity, this material is identical to an [[Isotropic Softening Material]]. If conditions allow, the material can develop both plasticity and damage with softening. Note that if plastic yield properties are below damage initiation stress, the material may never reach stress to cause damage. But, if the plastic properties allow hardening, the material can yield first and then start damage after hardening allows stresses to reach stress for initiation of damage. | ||
== Material Properties == | == Material Properties == | ||
For material properties, combine all options available | For material properties, combine all options available for an [[Isotropic, Elastic-Plastic Material]] and for an [[Isotropic Softening Material]]. This material must, however, use large rotation mode (as is also required for an [[Isotropic Softening Material]]). | ||
{| class="wikitable" | {| class="wikitable" | ||
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| ([[Isotropic Material#Material Properties|Isotropic Properties]]) || Enter all properties needed to define the underlying isotropic material response || varies || varies | | ([[Isotropic Material#Material Properties|Isotropic Properties]]) || Enter all properties needed to define the underlying isotropic material response || varies || varies | ||
|- | |- | ||
| ([[Isotropic, Elastic-Plastic Material#Material Properties|Isotropic, | | ([[Isotropic, Elastic-Plastic Material#Material Properties|Isotropic, Plastic Properties]]) || Enter yield properties and a [[Hardening Laws|hardening law]], but cannot use a [[Hardening Laws|hardening law]] that changes shear modulus ([[Steinberg-Cochran-Guinan Hardening]] or [[Steinberg-Lund Hardening]]) || varies || varies | ||
|- | |- | ||
| ([[Isotropic Softening Material#Material Properties|Isotropic Softening | | ([[Isotropic Softening Material#Material Properties|Isotropic Softening Properties]]) || Enter properties for initiation of damage and for two softening laws || varies || varies | ||
|- | |- | ||
| ([[Common Material Properties|other]]) || Properties common to all materials || varies || varies | | ([[Common Material Properties|other]]) || Properties common to all materials and must use the large rotation option || varies || varies | ||
|} | |} | ||
== History Variables == | == History Variables == | ||
The chosen [[Hardening Laws|hardening law]] will have at least one history variable and will start with history variable number 1. After the [[Hardening Laws|hardening law]] history variables, the remaining variables will be for the [[Isotropic Softening Material]] material | The chosen [[Hardening Laws|hardening law]] will have at least one history variable and will start with history variable number 1. After the [[Hardening Laws|hardening law]] history variables, the remaining variables will be the same as for the [[Isotropic Softening Material]] material, but the history variable will be offset by the number of [[Hardening Laws|hardening law]] history variables. Because plastic strain is used for plasticity, three additional history variables (compared to an [[Isotropic Softening Material]]) track the three components of cracking strains in the crack axis system corresponding to normal and shear crack opening displacements. | ||
Let P and S be number of history variables for the plastic law in use and for damage needed by an [[Isotropic Softening Material]], respectively. The history variables for this material are then: | |||
This material also tracks | * 1 to P: Plastic law history variables | ||
* P+1 to P+S: [[Isotropic Softening Material]] history variable <tt>S</tt> | |||
* P+S+1: ε<sub>c,xx</sub> or x direction cracking strain normal to crack in the crack axis system | |||
* P+S+2: γ<sub>c,xy</sub> or x-y direction shear cracking strain in the crack axis system | |||
* P+S+3: γ<sub>c,xz</sub> or x-z direction shear cracking strain in the crack axis system | |||
For example when P=1 and S=13, this material defines 17 history variables. | |||
This material also tracks plastic strain, which can be saved by using the [[MPM Archiving Options|<tt>plasticstrain</tt> archiving option]]. The total plastic strain is archived in the global axis system. | |||
If you also [[MPM Archiving Options|archive the <tt>damagenormal</tt>]], you will be able to plot a vector along the crack-opening displacement vector. | If you also [[MPM Archiving Options|archive the <tt>damagenormal</tt>]], you will be able to plot a vector along the crack-opening displacement vector. | ||
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== Examples == | == Examples == | ||
Material " | Material "isoplastsoft","Isotropic Plastic Softening Material",53 | ||
E 1000 | E 1000 | ||
nu .33 | nu .33 |
Latest revision as of 09:48, 18 November 2023
Constitutive Law
This MPM softening material is an isotropic, elastic-plastic material that can also develop anisotropic damage.
In the absence of damage, this material is identical to an Isotropic, Elastic-Plastic Material. In the absence of plasticity, this material is identical to an Isotropic Softening Material. If conditions allow, the material can develop both plasticity and damage with softening. Note that if plastic yield properties are below damage initiation stress, the material may never reach stress to cause damage. But, if the plastic properties allow hardening, the material can yield first and then start damage after hardening allows stresses to reach stress for initiation of damage.
Material Properties
For material properties, combine all options available for an Isotropic, Elastic-Plastic Material and for an Isotropic Softening Material. This material must, however, use large rotation mode (as is also required for an Isotropic Softening Material).
Property | Description | Units | Default |
---|---|---|---|
(Isotropic Properties) | Enter all properties needed to define the underlying isotropic material response | varies | varies |
(Isotropic, Plastic Properties) | Enter yield properties and a hardening law, but cannot use a hardening law that changes shear modulus (Steinberg-Cochran-Guinan Hardening or Steinberg-Lund Hardening) | varies | varies |
(Isotropic Softening Properties) | Enter properties for initiation of damage and for two softening laws | varies | varies |
(other) | Properties common to all materials and must use the large rotation option | varies | varies |
History Variables
The chosen hardening law will have at least one history variable and will start with history variable number 1. After the hardening law history variables, the remaining variables will be the same as for the Isotropic Softening Material material, but the history variable will be offset by the number of hardening law history variables. Because plastic strain is used for plasticity, three additional history variables (compared to an Isotropic Softening Material) track the three components of cracking strains in the crack axis system corresponding to normal and shear crack opening displacements.
Let P and S be number of history variables for the plastic law in use and for damage needed by an Isotropic Softening Material, respectively. The history variables for this material are then:
- 1 to P: Plastic law history variables
- P+1 to P+S: Isotropic Softening Material history variable S
- P+S+1: εc,xx or x direction cracking strain normal to crack in the crack axis system
- P+S+2: γc,xy or x-y direction shear cracking strain in the crack axis system
- P+S+3: γc,xz or x-z direction shear cracking strain in the crack axis system
For example when P=1 and S=13, this material defines 17 history variables. This material also tracks plastic strain, which can be saved by using the plasticstrain archiving option. The total plastic strain is archived in the global axis system.
If you also archive the damagenormal, you will be able to plot a vector along the crack-opening displacement vector.
Examples
Material "isoplastsoft","Isotropic Plastic Softening Material",53 E 1000 nu .33 a 60 rho 1 largeRotation 1 Initiation MaxPrinciple sigmac 30 tauc 20 SofteningI Linear I-Gc 10000 SofteningII Linear II-Gc 10000 Hardening Linear yield 20 Ep 200 Done