Elastomeric Bearing (Plasticity) Element: Difference between revisions
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1) If the element has zero length and optional orientation vectors are not specified, the local element axes coincide with the global axes. Otherwise the local z-axis is defined by the cross product between the x- and y-vectors specified on the command line. | 1) If the element has zero length and optional orientation vectors are not specified, the local element axes coincide with the global axes. Otherwise the local z-axis is defined by the cross product between the x- and y-vectors specified on the command line. | ||
2) Elastomeric bearings are very stiff in compression, but not rigid. It is not a good idea to specify an extremely large axial stiffness (such as 1E10), because it can lead to problems with numerical sensitivity. Always specify a realistic value for the axial stiffness. | |||
2) The valid queries to an elastomeric bearing element when creating an ElementRecorder object are 'force,' 'localForce,' 'basicForce,' 'localDisplacement,' 'basicDisplacement' and 'material $matNum matArg1 matArg2 ...' Where $matNum is the number associated with the material whose data is to be output. | 2) The valid queries to an elastomeric bearing element when creating an ElementRecorder object are 'force,' 'localForce,' 'basicForce,' 'localDisplacement,' 'basicDisplacement' and 'material $matNum matArg1 matArg2 ...' Where $matNum is the number associated with the material whose data is to be output. |
Revision as of 22:18, 24 August 2012
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This command is used to construct an elastomericBearing element object, which is defined by two nodes. The element can have zero length or the appropriate bearing height. The bearing has unidirectional (2D) or coupled (3D) plasticity properties for the shear deformations, and force-deformation behaviors defined by UniaxialMaterials in the remaining two (2D) or four (3D) directions. By default (sDratio = 0.5) P-Delta moments are equally distributed to the two end-nodes. To avoid the introduction of artificial viscous damping in the isolation system (sometimes referred to as "damping leakage in the isolation system"), the bearing element does not contribute to the Rayleigh damping by default. If the element has non-zero length, the local x-axis is determined from the nodal geometry unless the optional x-axis vector is specified in which case the nodal geometry is ignored and the user-defined orientation is utilized.
For a two-dimensional problem:
element elastomericBearing $eleTag $iNode $jNode $kInit $fy $alpha -P $matTag -Mz $matTag <-orient $x1 $x2 $x3 $y1 $y2 $y3> <-shearDist $sDratio> <-doRayleigh> <-mass $m> |
For a three-dimensional problem:
element elastomericBearing $eleTag $iNode $jNode $kInit $fy $alpha -P $matTag -T $matTag -My $matTag -Mz $matTag <-orient $x1 $x2 $x3 $y1 $y2 $y3> <-shearDist $sDratio> <-doRayleigh> <-mass $m> |
$eleTag | unique element object tag |
$iNode $jNode | end nodes |
$kInit | initial elastic stiffness in local shear direction |
$fy | yield strength |
$alpha | post yield stiffness ratio |
-P $matTag | tag associated with previously-defined UniaxialMaterial in axial direction |
-T $matTag | tag associated with previously-defined UniaxialMaterial in torsional direction |
-My $matTag | tag associated with previously-defined UniaxialMaterial in moment direction around local y-axis |
-Mz $matTag | tag associated with previously-defined UniaxialMaterial in moment direction around local z-axis |
$x1 $x2 $x3 | vector components in global coordinates defining local x-axis (optional) |
$y1 $y2 $y3 | vector components in global coordinates defining local y-axis (optional) |
$sDratio | shear distance from iNode as a fraction of the element length (optional, default = 0.5) |
-doRayleigh | to include Rayleigh damping from the bearing (optional, default = no Rayleigh damping contribution) |
$m | element mass (optional, default = 0.0) |
NOTE:
1) If the element has zero length and optional orientation vectors are not specified, the local element axes coincide with the global axes. Otherwise the local z-axis is defined by the cross product between the x- and y-vectors specified on the command line.
2) Elastomeric bearings are very stiff in compression, but not rigid. It is not a good idea to specify an extremely large axial stiffness (such as 1E10), because it can lead to problems with numerical sensitivity. Always specify a realistic value for the axial stiffness.
2) The valid queries to an elastomeric bearing element when creating an ElementRecorder object are 'force,' 'localForce,' 'basicForce,' 'localDisplacement,' 'basicDisplacement' and 'material $matNum matArg1 matArg2 ...' Where $matNum is the number associated with the material whose data is to be output.
EXAMPLES:
element elastomericBearing 1 1 2 20.0 2.50 0.02 -P 1 -Mz 2; # for a 2D elastomeric bearing
element elastomericBearing 1 1 2 20 2.50 0.02 -P 1 -T 2 -My 3 -Mz 4; # for a 3D elastomeric bearing
Code Developed by: Andreas Schellenberg, University of California, Berkeley.