Difference between revisions of "Transversely Isotropic Viscoelastic Material"

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n_0 = E_A + 4K_{T0}\nu_A^2, \quad n_k = 4K_{Tk}\nu_A^2, \quad \ell_0 = 2K_{T0}\nu_A, \quad \ell_k = 2K_{Tk}\nu_A
n_0 = E_A + 4K_{T0}\nu_A^2, \quad n_k = 4K_{Tk}\nu_A^2, \quad \ell_0 = 2K_{T0}\nu_A, \quad \ell_k = 2K_{Tk}\nu_A
</math>
</math>
=== Isotropic with Time-Dependent Bulk Modulus ===
The available [[isotropic viscoelastic]] material is limited to materials with time-independent bulk modulus because that is a good approximation for more isotropic, viscoelastic materials. This transversely, isotropic materials, however, does not place any dependence on which properties are time dependent. As result, it can model an isotropic material with a time-dependent bulk modulus as a special case. Image an isotropic material with ''K(t)'' and ''G(t)'' as time dependent moduli, To model using a transversely isotropic material, choose ''G<sub>A</sub>(t) = G<sub>T</sub>(t) = G(t)'' along with:
&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;
<math>K_T(t) = K(t) + \frac{G_T(t)}{3},\quad n(t)= K(t) + \frac{4G_T(t)}{3},\quad {\rm and}\quad
    \ell(t) = K(t) - \frac{2G_T(t)}{3}</math>
Similarly, set any other material properties (such as thermal expansion coefficients) to isotropic material properties.


== Material Properties ==
== Material Properties ==

Revision as of 14:37, 14 January 2021

Constitutive Law

(This material is available only in OSParticulas because it is still in development)

This anisotropic MPM material is a small strain, linear viscoelastic material that extends the Viscoelastic Material to model anisotropic viscoelasticity. The stress (σ) and strain (ε) are related by:

      [math]\displaystyle{ \sigma(t) = \mathbf{C}(t) * \varepsilon(t) }[/math]

Here [math]\displaystyle{ * }[/math] indicates convolution (or Boltzman's superposition) between time-dependent stiffness tensor ([math]\displaystyle{ \mathbf{C}(t) }[/math]) and strain tensor. In Voight-notation with unique axis in the z direction, the time-dependent stiffness tensor is

      [math]\displaystyle{ \mathbf{C}(t) = \left[\begin{array}{cccccc} K_T(t)+G_T(t) & K_T(t)-G_T(t) & \ell(t) & 0 & 0 & 0 \\ K_T(t)-G_T(t) & K_T+G_T & \ell(t) & 0 & 0 & 0 \\ \ell(t) & \ell(t) & n(t) & 0 & 0 & 0 \\ 0 & 0 & 0 & G_A(t) & 0 & 0 \\ 0 & 0 & 0 & 0 & G_A(t) & 0 \\ 0 & 0 & 0 & 0 & 0 & G_T(t) \end{array}\right] }[/math]

Here [math]\displaystyle{ K_T(t) }[/math] is the plane strain, bulk modulus, [math]\displaystyle{ G_T(t) }[/math] is the transverse shear modulus, [math]\displaystyle{ G_A(t) }[/math] is the axial shear modulus, and [math]\displaystyle{ n(t) }[/math] and [math]\displaystyle{ \ell(t) }[/math] give time-dependence of the C33 and C13=C23 elements of the stiffness tensor (as defined here). The time dependence of each property is modeled with a sum of exponentials:

      [math]\displaystyle{ K_T(t) = K_{T0} + \sum_{k=1}^{N_{KT}} K_{Tk} e^{-t/\tau_{KT,k}} \qquad G_T(t) = G_{T0} + \sum_{k=1}^{N_{GT}} G_{Tk} e^{-t/\tau_{GT,k}} \qquad G_A(t) = G_{A0} + \sum_{k=1}^{N_{GA}} G_{Ak} e^{-t/\tau_{GA,k}} }[/math]

      [math]\displaystyle{ n(t) = n_0 + \sum_{k=1}^{N_n} n_k e^{-t/\tau_{n,k}} \qquad\qquad \ell(t) = \ell_0 + \sum_{k=1}^{N_\ell} \ell_k e^{-t/\tau_{\ell,k}} }[/math]

TIViscoelastic 1 and 2

TIViscoelastic 1 and TIViscoelastic 2 give identical materials but with different initial orientations. TIViscoelastic 1 has the unrotated axial direction along the z (or θ if axisymmetric) axis (see above tensors) while TIViscoelastic 2 has unrotated axial direction along the y (or Z if axisymmetric) axis (exchange y and z directions in above tensors). You can change the unrotated direction to any other orientation when defining material points by selecting rotation angles. For 2D analyses, the two options are needed to allo for axial direction in the x-y (or R-Z if axisymmetric) analysis plane (TIViscoelastic 2) or normal to that plane (TIViscoelastic 1). For 3D analyses, only TIViscoelastic 1 is allowed (and it in the only one needed).

Elastic Fiber Direction

Some materials, such as unidirectional composite materials or wood, can be modeled with the fiber direction as the axial direction. Because this direction is typically much stiffer than the isotropic plane direction, it might be expected to have little or no viscoelasticity compared to other directions. If one assumes that axial modulus ([math]\displaystyle{ E_A }[/math]) and Poisson's ratio ([math]\displaystyle{ \nu_A }[/math]) are independent of time, then [math]\displaystyle{ n(t) }[/math] and [math]\displaystyle{ \ell(t) }[/math] are determined by [math]\displaystyle{ K_T(t) }[/math] by setting:

      [math]\displaystyle{ N_n=N_\ell=N_{KT}, \quad \tau_{n,k}=\tau_{\ell,k}=\tau_{KT,k}, \quad n_0 = E_A + 4K_{T0}\nu_A^2, \quad n_k = 4K_{Tk}\nu_A^2, \quad \ell_0 = 2K_{T0}\nu_A, \quad \ell_k = 2K_{Tk}\nu_A }[/math]

Isotropic with Time-Dependent Bulk Modulus

The available isotropic viscoelastic material is limited to materials with time-independent bulk modulus because that is a good approximation for more isotropic, viscoelastic materials. This transversely, isotropic materials, however, does not place any dependence on which properties are time dependent. As result, it can model an isotropic material with a time-dependent bulk modulus as a special case. Image an isotropic material with K(t) and G(t) as time dependent moduli, To model using a transversely isotropic material, choose GA(t) = GT(t) = G(t) along with:

      [math]\displaystyle{ K_T(t) = K(t) + \frac{G_T(t)}{3},\quad n(t)= K(t) + \frac{4G_T(t)}{3},\quad {\rm and}\quad \ell(t) = K(t) - \frac{2G_T(t)}{3} }[/math]

Similarly, set any other material properties (such as thermal expansion coefficients) to isotropic material properties.

Material Properties

The unusual task for this material is to use multiple terms to define the exponential series used for up to five material properties.

Property Description Units Default
GT0 The long term (or fully-relaxed) transverse shear modulus pressure units none
GA0 The long term (or fully-relaxed) axial shear modulus pressure units none
KT0 The long term (or fully-relaxed) plane-strain bulk modulus pressure units none
en0 The long term (or fully-relaxed) C33 element of the stiffness tensor pressure units none
ell0 The long term (or fully-relaxed) C13=C23 elements of the stiffness tensor pressure units none
ntaus The number of relaxation times of the previous long-term property that was entered. This property is only needed in XML files and must come before any subsequent Pk or tauk properties. In scripted files, the number is automatically determined from the number of relaxation times you provide. none none
Pk The next property in the series for the previous long-term property that was entered. Use multiple Pk values for each term on the series. pressure units none
tauk The next relaxation time in the series for the previous long-term property that was entered. Enter multiple tauk values for each term on the series. time units none
fibrous Enter 1 to indicate fiber direction is independent of time (or [math]\displaystyle{ E_A }[/math] and [math]\displaystyle{ \nu_A }[/math] are independent of time). Enter 0 to allow separate time dependence series for [math]\displaystyle{ n(t) }[/math] and [math]\displaystyle{ \ell(t) }[/math]. dimensionless 1
TI Properties Enter thermal expansion, solvent expansion, and poroelasticity properties as usual for transversely isotropic materials. When fibrous is 1, also enter EA (required) and nuA (default 0.33). varies varies
(other) Properties common to all materials varies varies

The material properties need to define the time dependence of 3 properties (when fibrous is 1) or 5 properties (when fibrous is 0). The process for each one is to enter the long-term value first (GT0, GA0, KT0, en0, ell0) and then to follow each one by ntaus (only needed in XML files) and by one Pk and tauk value for each term in the series.

When fibrous is 1, you instead enter time-independent values for EA and nuA. When fibrous is 0, their initial values calculated from:

      [math]\displaystyle{ \nu_A(0) = {\ell(0)\over 2K_T(0)} \qquad {\rm and} \qquad E_A(0) = n(0) - 4K_T(0)\nu_A^2 = n(0) - \frac{\ell(0)^2}{K_T(0)} }[/math]

The remaining, initial transverse properties are:

      [math]\displaystyle{ \frac{1}{E_T(0)} = \frac{1}{4K_T(0)} +\frac{1}{4G_T(0)} + {\nu_A(0)^2\over E_A(0)} \qquad {\rm and} \qquad \nu_T(0) = \frac{E_T(0)}{2G_T(0)}-1 }[/math]

The above initial values, or the properties at time zero, are sums of all Pk terms for that property. For example

      [math]\displaystyle{ G_T(0) = G_{T0} + \sum_{k=1}^{N_{GT}} G_{Tk} }[/math]

For valid modeling, the initial Poisson's ratios must satisfy

      [math]\displaystyle{ -1\lt \nu_T(0)\lt 1 \qquad -\sqrt{E_A(0)\over E_T(0)} \lt \nu_A(0) \lt \sqrt{E_A(0)\over E_T(0)} \qquad {E_T(0)\nu_A(0)^2\over E_A(0)} \lt {1-\nu_T(0)\over 2} }[/math]

These relations must apply for all time, but only the initial values are validated before starting a simulation.

History Variables

This material tracks internal history variables (one for each relaxation time and each component of stress) for implementation of linear viscoelastic properties, but currently none of these internal variables are available for archiving.

Example