Difference between revisions of "Steinberg-Cochran-Guinan Hardening"
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== Yield Stress == | |||
In the Steinberg-Cochran-Guinan [[Hardening Laws|hardening law]], the yield stress is given by | In the Steinberg-Cochran-Guinan [[Hardening Laws|hardening law]], the yield stress is given by | ||
<math>\sigma_y = \sigma_0\bigl(1 + \beta \ | | ||
<math>\sigma_y = \min\left\{\sigma_0\bigl(1 + \beta \alpha\bigr)^n, \sigma_y^{max}\right\}{G(T,P)\over G_0}</math> | |||
where σ<sub>0</sub> is the initial yield stress, β and n are hardening law properties, | where σ<sub>0</sub> is the initial yield stress, β and n are hardening law properties, α is the cumulative equivalent plastic strain, G(T,P) is the shear modulus (which may depend on temperature and pressure), and G<sub>0</sub> is the initial shear modulus. The shear modulus temperature and pressure dependence are given by: | ||
| |||
<math>{G(T,P)\over G_0} = 1 + {G_P'\over G_0} P J^{1/3} + {G_T'\over G_0}(T-T_0)</math> | <math>{G(T,P)\over G_0} = 1 + {G_P'\over G_0} P J^{1/3} + {G_T'\over G_0}(T-T_0)</math> | ||
where J is the relative volume change (V/V<sub>0</sub>), G<sub>P</sub>' and G<sub>T</sub>' are coefficients for pressure and temperature affects, T is current temperature, and T<sub>0</sub> is a reference temperature. | where J is the relative volume change (V/V<sub>0</sub>), G<sub>P</sub>' and G<sub>T</sub>' are coefficients for pressure and temperature affects, T is current temperature, and T<sub>0</sub> is a reference temperature. For more details, see paper by Steinberg, Cochran, and Guinan.<ref>D. J. Steinberg S. G. Cochran, and M. W. Guinan, "A constitutive model for metals applicable at high strain rates," J. Appl. Phys., 51, 1498-1504 (1979).</ref> | ||
The [[Steinberg-Lund Hardening]] law is similar to this law but adds a a strain rate- and temperature-dependent term. | |||
=== Plasticity Theory === | |||
This law (and the [[Steinberg-Lund Hardening]] law) are implemented use J<sub>2</sub> plasticity theory. In associative, J<sub>2</sub> plasticity theory, the yield function has to depend only on deviatoric stress and cannot depend on pressure, but these laws have yield strengths that depend on pressure. They can, however be used in J<sub>2</sub> plasticity as non-associative laws. The plastic flow is determined by the failure surface defined by: | |||
| |||
<math>\Phi = \|{\bf s}\| - \sqrt{2\over3}\min\left\{\sigma_0\bigl(1 + \beta \alpha\bigr)^n, \sigma_y^{max}\right\}{G(T,P)\over G_0}</math> | |||
where <b>s</b> is the deviatoric stress. The plastic strain and forces, however, are determined by a different plastic potential of: | |||
| |||
<math>\Psi = \|{\bf s}\| - \sqrt{2\over3}\min\left\{\sigma_0\bigl(1 + \beta \alpha\bigr)^n, \sigma_y^{max}\right\}</math> | |||
Because these two functions different, the implementation is formally non-associative plasticity. | |||
== Hardening Law Properties == | == Hardening Law Properties == | ||
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! Property !! Description | ! Property !! Description | ||
|- | |- | ||
| yield || Initial yield stress (& | | yield || Initial yield stress (σ<sub>0</sub> at zero pressure and the reference temperature). Enter in [[ConsistentUnits Command#Legacy and Consistent Units|pressure units]]. | ||
|- | |- | ||
| betahard || Yield stress hardening term &beta. It is dimensionless. | | betahard || Yield stress hardening term β. It is dimensionless. | ||
|- | |- | ||
| nhard || Exponent on cumulative plastic strain in hardening term. It is dimensionless. | | nhard || Exponent on cumulative plastic strain in hardening term. It is dimensionless. | ||
|- | |- | ||
| GPpG0 || The (G<sub>p</sub>'/G<sub>0</sub>) ratio term for pressure dependence of shear modulus. Enter in units | | GPpG0 || The (G<sub>p</sub>'/G<sub>0</sub>) ratio term for pressure dependence of shear modulus. Enter in units [[ConsistentUnits Command#Legacy and Consistent Units|pressure<sup>-1</sup> units]]. Enter 0 to omit pressure dependence in shear modulus. | ||
|- | |- | ||
| GTpG0 || The (G<sub>T</sub>'/G<sub>0</sub>) ratio term for temperature dependence of shear modulus. Enter in units | | GTpG0 || The (G<sub>T</sub>'/G<sub>0</sub>) ratio term for temperature dependence of shear modulus. Enter in units K<sup>-1</sup>. Enter 0 to omit temperature dependence in shear modulus. | ||
|- | |- | ||
| yieldMax || Maximum yield stress. Enter in units | | yieldMax || Maximum yield stress. Enter in [[ConsistentUnits Command#Legacy and Consistent Units|pressure units]]. | ||
|} | |} | ||
The reference temperature, T<sub>0</sub>, is set using the simulations [[Thermal Calculations#Stress Free Temperature|stress free temperature]] and not set using [[Hardening Laws|hardening law]] properties. | |||
== History Data == | |||
This [[Hardening Laws|hardening law]] defines one history variable, which is stored as history variable #1. It stores the the cumulative equivalent plastic strain (absolute) defined as | |||
| |||
<math>\alpha = \sum \sqrt{2\over3}\ ||d\varepsilon_p||</math> | |||
where dε<sub>p</sub> is the incremental plastic strain tensor in one time step. | |||
== References == | |||
<references/> |
Latest revision as of 22:54, 29 October 2019
Yield Stress
In the Steinberg-Cochran-Guinan hardening law, the yield stress is given by
[math]\displaystyle{ \sigma_y = \min\left\{\sigma_0\bigl(1 + \beta \alpha\bigr)^n, \sigma_y^{max}\right\}{G(T,P)\over G_0} }[/math]
where σ0 is the initial yield stress, β and n are hardening law properties, α is the cumulative equivalent plastic strain, G(T,P) is the shear modulus (which may depend on temperature and pressure), and G0 is the initial shear modulus. The shear modulus temperature and pressure dependence are given by:
[math]\displaystyle{ {G(T,P)\over G_0} = 1 + {G_P'\over G_0} P J^{1/3} + {G_T'\over G_0}(T-T_0) }[/math]
where J is the relative volume change (V/V0), GP' and GT' are coefficients for pressure and temperature affects, T is current temperature, and T0 is a reference temperature. For more details, see paper by Steinberg, Cochran, and Guinan.[1]
The Steinberg-Lund Hardening law is similar to this law but adds a a strain rate- and temperature-dependent term.
Plasticity Theory
This law (and the Steinberg-Lund Hardening law) are implemented use J2 plasticity theory. In associative, J2 plasticity theory, the yield function has to depend only on deviatoric stress and cannot depend on pressure, but these laws have yield strengths that depend on pressure. They can, however be used in J2 plasticity as non-associative laws. The plastic flow is determined by the failure surface defined by:
[math]\displaystyle{ \Phi = \|{\bf s}\| - \sqrt{2\over3}\min\left\{\sigma_0\bigl(1 + \beta \alpha\bigr)^n, \sigma_y^{max}\right\}{G(T,P)\over G_0} }[/math]
where s is the deviatoric stress. The plastic strain and forces, however, are determined by a different plastic potential of:
[math]\displaystyle{ \Psi = \|{\bf s}\| - \sqrt{2\over3}\min\left\{\sigma_0\bigl(1 + \beta \alpha\bigr)^n, \sigma_y^{max}\right\} }[/math]
Because these two functions different, the implementation is formally non-associative plasticity.
Hardening Law Properties
This hardening law can set the following properties:
Property | Description |
---|---|
yield | Initial yield stress (σ0 at zero pressure and the reference temperature). Enter in pressure units. |
betahard | Yield stress hardening term β. It is dimensionless. |
nhard | Exponent on cumulative plastic strain in hardening term. It is dimensionless. |
GPpG0 | The (Gp'/G0) ratio term for pressure dependence of shear modulus. Enter in units pressure-1 units. Enter 0 to omit pressure dependence in shear modulus. |
GTpG0 | The (GT'/G0) ratio term for temperature dependence of shear modulus. Enter in units K-1. Enter 0 to omit temperature dependence in shear modulus. |
yieldMax | Maximum yield stress. Enter in pressure units. |
The reference temperature, T0, is set using the simulations stress free temperature and not set using hardening law properties.
History Data
This hardening law defines one history variable, which is stored as history variable #1. It stores the the cumulative equivalent plastic strain (absolute) defined as
[math]\displaystyle{ \alpha = \sum \sqrt{2\over3}\ ||d\varepsilon_p|| }[/math]
where dεp is the incremental plastic strain tensor in one time step.
References
- ↑ D. J. Steinberg S. G. Cochran, and M. W. Guinan, "A constitutive model for metals applicable at high strain rates," J. Appl. Phys., 51, 1498-1504 (1979).