Stress Density Material: Difference between revisions
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| style="background:yellow; color:black; width: | | style="background:yellow; color:black; width:780px" | '''nDMaterial StressDensityModel $matTag $mDen $eNot $A $n $nu $a1 $b1 $a2 $b2 $a3 $b3 $fd $muNot $muCyc $sc $M $patm <$ssl1 $ssl2 $ssl3 $ssl4 $ssl5 $ssl6 $ssl7 $ssl8 $ssl9 $ssl10 $hsl $p1 $p2 $p3 $p4 $p5 $p6 $p7 $p8 $p9 $p10>''' | ||
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| '''$patm ''' || atmospheric pressure (in appropriate units) | | '''$patm ''' || atmospheric pressure (in appropriate units) | ||
| | |} | ||
| '''<$ssl1> ''' || void ratio of quasi steady state (QSS-line) at pressure $p1 (default = 0.877) | |||
Optional steady state line parameters (default values shown for each, be careful with units) | |||
{| | |||
| style="width:150px" | '''<$ssl1> ''' || void ratio of quasi steady state (QSS-line) at pressure $p1 (default = 0.877) | |||
|- | |- | ||
| '''<$ssl2> ''' || void ratio of quasi steady state (QSS-line) at pressure $p2 (default = 0.877) | | '''<$ssl2> ''' || void ratio of quasi steady state (QSS-line) at pressure $p2 (default = 0.877) | ||
| Line 100: | Line 104: | ||
===Notes === | ===Notes === | ||
===Usage Examples=== | |||
The following usage example provides the input parameters used in the single element examples of Borja et al. (2001). The initial bulk modulus is determined from the initial mean stress desired in the test (in this case p = 100 kPa) divided by the | |||
recompressibilty index kappa = 0.018. The units of this analysis are kN and m, thus the prescribed initial shear modulus of 5.4 MPa is input as 5400 kPa. The hardening parameter $h has the same units as the moduli. | |||
# mass density | |||
set mDen 1.8 | |||
# atmospheric pressure | |||
set patm 98.1 | |||
# stress density model parameters | |||
set eNot 0.730 | |||
set A 250.0 | |||
set n 0.60 | |||
set a1 0.58 | |||
set b1 0.023 | |||
set a2 230.0 | |||
set b2 65.0 | |||
set a3 79.0 | |||
set b3 16.0 | |||
set fd 4.0 | |||
set muNot 0.22 | |||
set muCyc 0.0 | |||
set sc 0.0055 | |||
set M 0.607 | |||
nDMaterial StressDensityModel 1 $mDen $eNot $A $m $nu $a1 $b1 $a2 $b2 $a3 $b3 $fd $muNot $ muCyc $sc $M $patm | |||
===References=== | |||
Cubrinovski, M. and Ishihara K. (1998a) 'Modelling of sand behaviour based on state concept,' ''Soils and Foundations,'' 38(3), 115-127. | |||
Cubrinovski, M. and Ishihara K. (1998b) 'State concept and modified elastoplasticity for sand modelling,' ''Soils and Foundations,'' 38(4), 213-225. | |||
---- | |||
==Example Analysis== | |||
<source lang="tcl"> | |||
</source> | |||
Revision as of 00:46, 28 July 2016
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This command is used to construct a multi-dimensional stress density material object for modeling sand behaviour following the work of Cubrinovski and Ishihara (1998a,b).
| nDMaterial StressDensityModel $matTag $mDen $eNot $A $n $nu $a1 $b1 $a2 $b2 $a3 $b3 $fd $muNot $muCyc $sc $M $patm <$ssl1 $ssl2 $ssl3 $ssl4 $ssl5 $ssl6 $ssl7 $ssl8 $ssl9 $ssl10 $hsl $p1 $p2 $p3 $p4 $p5 $p6 $p7 $p8 $p9 $p10> |
| $matTag | integer tag identifying material |
| $mDen | mass density |
| $eNot | initial void ratio |
| $A | constant for elastic shear modulus |
| $n | pressure dependency exponent for elastic shear modulus |
| $nu | Poisson's ratio |
| $a1 | peak stress ratio coefficient (etaMax = a1 + b1*Is) |
| $b1 | peak stress ratio coefficient (etaMax = a1 + b1*Is) |
| $a2 | max shear modulus coefficient (Gn_max = a2 + b2*Is) |
| $b2 | max shear modulus coefficient (Gn_max = a2 + b2*Is) |
| $a3 | min shear modulus coefficient (Gn_min = a3 + b3*Is) |
| $b3 | min shear modulus coefficient (Gn_min = a3 + b3*Is) |
| $fd | degradation constant |
| $muNot | dilatancy coefficient (monotonic loading) |
| $muCyc | dilatancy coefficient (cyclic loading) |
| $sc | dilatancy strain |
| $M | critical state stress ratio |
| $patm | atmospheric pressure (in appropriate units) |
Optional steady state line parameters (default values shown for each, be careful with units)
| <$ssl1> | void ratio of quasi steady state (QSS-line) at pressure $p1 (default = 0.877) |
| <$ssl2> | void ratio of quasi steady state (QSS-line) at pressure $p2 (default = 0.877) |
| <$ssl3> | void ratio of quasi steady state (QSS-line) at pressure $p3 (default = 0.873) |
| <$ssl4> | void ratio of quasi steady state (QSS-line) at pressure $p4 (default = 0.870) |
| <$ssl5> | void ratio of quasi steady state (QSS-line) at pressure $p5 (default = 0.860) |
| <$ssl6> | void ratio of quasi steady state (QSS-line) at pressure $p6 (default = 0.850) |
| <$ssl7> | void ratio of quasi steady state (QSS-line) at pressure $p7 (default = 0.833) |
| <$ssl8> | void ratio of quasi steady state (QSS-line) at pressure $p8 (default = 0.833) |
| <$ssl9> | void ratio of quasi steady state (QSS-line) at pressure $p9 (default = 0.833) |
| <$ssl10> | void ratio of quasi steady state (QSS-line) at pressure $p10 (default = 0.833) |
| <$hsl> | void ratio of upper reference state (UR-line) for all pressures (default = 0.895) |
| <$p1> | pressure corresponding to $ssl1 (default = 1.0 kPa) |
| <$p2> | pressure corresponding to $ssl1 (default = 10.0 kPa) |
| <$p3> | pressure corresponding to $ssl1 (default = 30.0 kPa) |
| <$p4> | pressure corresponding to $ssl1 (default = 50.0 kPa) |
| <$p5> | pressure corresponding to $ssl1 (default = 100.0 kPa) |
| <$p6> | pressure corresponding to $ssl1 (default = 200.0 kPa) |
| <$p7> | pressure corresponding to $ssl1 (default = 400.0 kPa) |
| <$p8> | pressure corresponding to $ssl1 (default = 400.0 kPa) |
| <$p9> | pressure corresponding to $ssl1 (default = 400.0 kPa) |
| <$p10> | pressure corresponding to $ssl1 (default = 400.0 kPa) |
The material formulations for the StressDensity object are "ThreeDimensional" and "PlaneStrain"
Code Developed by Saumyashuchi Das, University of Canterbury. Maintained by Chris McGann
General Information
This nDMaterial object provides the
Notes
Usage Examples
The following usage example provides the input parameters used in the single element examples of Borja et al. (2001). The initial bulk modulus is determined from the initial mean stress desired in the test (in this case p = 100 kPa) divided by the recompressibilty index kappa = 0.018. The units of this analysis are kN and m, thus the prescribed initial shear modulus of 5.4 MPa is input as 5400 kPa. The hardening parameter $h has the same units as the moduli.
# mass density set mDen 1.8 # atmospheric pressure set patm 98.1 # stress density model parameters set eNot 0.730 set A 250.0 set n 0.60 set a1 0.58 set b1 0.023 set a2 230.0 set b2 65.0 set a3 79.0 set b3 16.0 set fd 4.0 set muNot 0.22 set muCyc 0.0 set sc 0.0055 set M 0.607 nDMaterial StressDensityModel 1 $mDen $eNot $A $m $nu $a1 $b1 $a2 $b2 $a3 $b3 $fd $muNot $ muCyc $sc $M $patm
References
Cubrinovski, M. and Ishihara K. (1998a) 'Modelling of sand behaviour based on state concept,' Soils and Foundations, 38(3), 115-127.
Cubrinovski, M. and Ishihara K. (1998b) 'State concept and modified elastoplasticity for sand modelling,' Soils and Foundations, 38(4), 213-225.