FluidSolidPorousMaterial: Difference between revisions

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'''FluidSolidPorousMaterial''' couples the responses of two phases: fluid and solid. The fluid phase response is only volumetric and linear elastic. The solid phase can be any NDMaterial. This material is developed to simulate the response of saturated porous media under fully undrained condition.  
'''FluidSolidPorousMaterial''' couples the responses of two phases: fluid and solid. The fluid phase response is only volumetric and linear elastic. The solid phase can be any NDMaterial. This material is developed to simulate the response of saturated porous media under fully undrained condition.  
'''Please''' [http://quakesim.net/index.php?title=Examples click here] '''for examples.'''




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2. During the application of gravity (elastic) load, the fluid phase does not contribute to the material response.
2. During the application of gravity (elastic) load, the fluid phase does not contribute to the material response.


=='''Pressure Independent Material Examples:'''==
<table border=1 width=800>
    <tr>
    <td colspan=2 align=center ><b>Material in saturated, undrained elastic-plastic state (coupled with FluidSolidPorous Material)</b></td>
  </tr>
  <tr>
    <td>[[PressureDependMultiYield-Example 8|Example 8]]</td>
    <td>Single quadrilateral element, subjected to sinusoidal base shaking</td>
  </tr>
  <tr>
    <td>[[PressureDependMultiYield-Example 9|Example 9]]</td>
    <td>Single quadrilateral element, subjected to monotonic pushover</td>
  </tr>
  <tr>
    <td>[[PressureDependMultiYield-Example 10|Example 10]]</td>
    <td>Single quadrilateral element (inclined by 4 degrees), subjected to msinusoidal base shaking</td>
  </tr>
  <tr>
    <td>[[PressureDependMultiYield-Example 11|Example 11]]</td>
    <td>Single 3D BbarBrick element, subjected to sinusoidal base shaking</td>
  </tr>
  <tr>
    <td>[[PressureDependMultiYield-Example 12|Example 12]]</td>
    <td>Single 3D BbarBrick element (inclined by 4 degrees), subjected to sinusoidal base shaking</td>
  </tr>
  <tr>
    <td>[[PressureDependMultiYield--Example 13|Example 13]]</td>
    <td>A column of quadrilateral element (inclined by 4 degrees), subjected to sinusoidal base shaking</td>
  </tr>
</table>


Code Developed by: <span style="color:blue"> UC San Diego (Dr. Zhaohui Yang)</span>:
Code Developed by: <span style="color:blue"> UC San Diego (Dr. Zhaohui Yang)</span>:

Revision as of 20:46, 10 August 2012




FluidSolidPorousMaterial couples the responses of two phases: fluid and solid. The fluid phase response is only volumetric and linear elastic. The solid phase can be any NDMaterial. This material is developed to simulate the response of saturated porous media under fully undrained condition.


OUTPUT INTERFACE:

The following information may be extracted for this material at given integration point, using the OpenSees Element Recorder facility (McKenna and Fenves 2001): "stress", "strain", "tangent", or "pressure". The "pressure" option records excess pore pressure and excess pore pressure ratio at a given material integration point.


nDMaterial FluidSolidPorousMaterial $tag $nd $soilMatTag $combinedBulkModul <$pa=101>


$Tag A positive integer uniquely identifying the element among all elements
$nd Number of dimensions, 2 for plane-strain, and 3 for general 3D analysis.
$soilMatTag The material number for the solid phase material (previously defined).
$combinBulkModul Combined undrained bulk modulus Bc relating changes in pore pressure and volumetric strain, may be approximated by:

Bc ≈ Bf /n

where Bf is the bulk modulus of fluid phase (2.2x106 kPa (or 3.191x105 psi) for water), and n the initial porosity.

$pa Optional atmospheric pressure for normalization (typically 101 kPa in SI units, or 14.65 psi in English units)


NOTE:

1. Buoyant unit weight (total unit weight - fluid unit weight) should be used in definition of the finite elements composed of a FluidSolidPorousMaterial.

2. During the application of gravity (elastic) load, the fluid phase does not contribute to the material response.

Pressure Independent Material Examples:

Material in saturated, undrained elastic-plastic state (coupled with FluidSolidPorous Material)
Example 8 Single quadrilateral element, subjected to sinusoidal base shaking
Example 9 Single quadrilateral element, subjected to monotonic pushover
Example 10 Single quadrilateral element (inclined by 4 degrees), subjected to msinusoidal base shaking
Example 11 Single 3D BbarBrick element, subjected to sinusoidal base shaking
Example 12 Single 3D BbarBrick element (inclined by 4 degrees), subjected to sinusoidal base shaking
Example 13 A column of quadrilateral element (inclined by 4 degrees), subjected to sinusoidal base shaking

Code Developed by: UC San Diego (Dr. Zhaohui Yang):


UC San Diego Soil Model: