NonlinearGurson

Nonlinear General Gurson Porous Model

Yield Function

An extended yield function is used,

F = q^{2} + 2 q_{1} f σ_{y}^{2} \cosh (\frac{3}{2} \frac{q_{2} p}{σ_{y}}) - σ_{y}^{2} (q_{1}^{2} f^{2} + 1),

where

s = dev σ, p = \frac{tr σ}{3} = \frac{I_{1}}{3}, q = \sqrt{3 J_{2}} = \sqrt{\frac{3}{2} s : s} = \sqrt{\frac{3}{2}} | s | .

Furthermore, $q_{1}$ , $q_{2}$ and $q_{3} = q_{1}^{2}$ are model constants, $f (ε_{m}^{p})$ is the volume fraction, $σ_{y} (ε_{m}^{p})$ is the yield stress, $ε_{m}^{p}$ is the equivalent plastic strain.

$q_{1} = q_{2} = 1$ The original Gurson model is recovered.
$q_{1} = 0$ The von Mises model is recovered.

Evolution of Equivalent Plastic Strain

The evolution of $ε_{m}^{p}$ is assumed to be governed by the equivalent plastic work expression,

(1 - f) σ_{y} Δ ε_{m}^{p} = σ : Δ ε^{p} = 2 Δ γ {(\frac{q^{t r}}{1 + 6 G Δ γ})}^{2} + 3 q_{1} q_{2} p Δ γ f σ_{y} \sinh (\frac{3}{2} \frac{q_{2} p}{σ_{y}}) .

Evolution of Volume Fraction

The evolution of volume fraction consists of two parts.

Δ f = Δ f_{g} + Δ f_{n},

where

Δ f_{g} = (1 - f) Δ ε_{v}, Δ f_{n} = A Δ ε_{m}^{p}

with

A = \frac{f_{N}}{s_{N} \sqrt{2 π}} \exp (- \frac{1}{2} {(\frac{ε_{m}^{p} - ε_{N}}{s_{N}})}^{2}) .

Parameters $f_{N}$ , $s_{N}$ and $ε_{N}$ controls the normal distribution of volume fraction. If ( $f_{N} = 0$ , the nucleation is disabled. In this case, when ( $f_{0} = 0$ , the volume fraction will stay at zero regardless of strain history.

Recording

This model supports the following additional history variables to be recorded.

variable label	physical meaning
VF	volume fraction