Concrete Wall on Elastic Base Plate
Note
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The concrete wall geometry shown in Figure 1 is used for this example. The wall is based upon a model that was developed by Onken and Rostásy (1995) to compare numerical temperature results to temperature measurements. The model consists of a wall of new concrete (10 × 1 × 40 elements) footed on a base plate of old concrete (10 × 1 × 5 elements). The material parameters and boundary conditions are not available from Onken and Rostásy (1995). Therefore, the material parameters from the example of concrete inclusion are used in addition to typical temperature boundary conditions.
The thermal hydration model (hydration) and the mechanical hydration Drucker-Prager model (hydration-drucker-parger) are prescribed for the concrete wall. The base plate is considered elastic and thermally isotropic.
The model is considered to be under summer temperature conditions. The temperatures at the wall boundary are fixed to air temperature; the temperatures at the base plate are fixed to the initial ground temperature:
initial wall temperature of 293 K
wall boundary temperature fixed at 293 K
initial base plate temperature of 285 K
base plate boundary temperature fixed at 285 K
The numerical results are displayed in Figure 2 to Figure 8: the temperature distribution inside the model after 1 and 3 days (Figure 2 and Figure 3); evolution of gridpoint temperatures (Figure 4); evolution of the hydration grade (Figure 5); evolution of the strength parameters (Figure 6); evolution of the elastic parameters (Figure 7); and evolution of the hydration heat (Figure 8). The results are qualitatively in good agreement with the results given by Onken and Rostásy (1995). (A more detailed comparison is not available due to limited access to material parameters and boundary conditions.)
Reference
Onken, P., and F. Rostásy. Wirksame Betonzugfestigkeit im Bauwerk bei früh einsetzendem Temperaturzwang, DAfStb Heft 449. Berlin: Beuth-Verlag (1995).
Data File
;--------------------------------------
; Concrete wall on elastic base plate
;--------------------------------------
model new
model title ...
"Concrete wall on elastic base plate - summer temperature conditions"
;
zone create brick point 0=(-0.5,0.0,0.0) point 1=(0.5,0.0,0.0) ...
point 2=(-0.5,0.2,0.0) point 3=(-0.5,0.0,10.0) ...
size = 10,1,100
zone create brick point 0=(-2.5,0.0,-1.0) point 1=(2.5,0.0,-1.0) ...
point 2=(-2.5,0.2,-1.0) point 3=(-2.5,0.0,0.0) ...
size = 20,1,5
zone attach by-face range position-z 0
;
zone group 'concrete' range position-z 0 100
zone group 'base_plate' range position-z -100 0
;
; Mechanical
model large-strain off
zone cmodel assign elastic range group 'base_plate'
zone cmodel assign hydration-drucker-prager range group 'concrete'
zone property density=2000
zone property bulk=1e9 shear=0.7e9 range group 'base_plate'
; Hydration-Drucker-Prager
zone property bulk-reference=0.98e9 shear-reference=0.50e9 ...
range group 'concrete'
zone property constant-c=0.4 constant-a=0.6 ...
range group 'concrete'
zone property hydration-minimum=0.20 tension-reference=2.0e6 ...
range group 'concrete'
zone property hydration-difference-minimum=1e-4 ...
range group 'concrete'
zone gridpoint fix velocity range position-z -1.0
zone gridpoint fix velocity-x range union position-x -2.5 position-x 2.5
; Thermal
model configure thermal
zone thermal cmodel assign hydration range group 'concrete'
zone thermal property conductivity=20 expansion=1e-4 specific-heat=0.2
zone thermal property conductivity= 2 expansion=1e-5 range group 'concrete'
zone thermal property conductivity= 2 expansion=1e-5 specific-heat=0.2 ...
range group 'concrete'
zone thermal property density-cement=330 constant-jonasson-b=-1.114 ...
constant-jonasson-t1=7.2e4 ...
range group 'concrete'
zone thermal property constant-gas=8.314 temperature-reference=293 ...
hydration-grade-maximum=1.0 hydration-temperature-maximum=1e4 ...
range group 'concrete'
zone thermal property constant-energy-1=33.5 constant-energy-dt=1.47 ...
constant-energy-halftime=273 flag-law=0 constant-heat-1=0.2 ...
range group 'concrete'
zone thermal property hydration-binding-maximum=1e5 ...
constant-conductivity-1=2.0 ...
range group 'concrete'
;
zone gridpoint initialize temperature 293 range group 'concrete'
zone gridpoint fix temperature 293 range position-x -0.5
zone gridpoint fix temperature 293 range position-x 0.5
zone gridpoint fix temperature 293 range position-z 10.0
zone gridpoint fix temperature 285 range group 'base_plate' ; <-- overwrite whatever
;
zone history temperature position (0,0.1,1)
zone history temperature position (0,0.1,2)
zone history temperature position (0,0.1,3)
zone history temperature position (0,0.1,4)
zone history temperature position (0,0.1,5)
zone history property-thermal name 'hydration-grade' position (0,0,5)
zone history property-thermal name 'hydration-rate' position (0,0,5)
zone history property-thermal name 'age-concrete-effective' position (0,0,5)
zone history property name 'tension' position (0,0,5)
zone history property name 'compression' position (0,0,5)
zone history property name 'young' position (0,0,5)
zone history property name 'bulk' position (0,0,5)
zone history property name 'shear' position (0,0,5)
model history thermal time-total
zone geometry update-interval 10
; The implicit servo does not work with
; The hydration model. So we just set a
; timestep that requires implicit and doesn't
; produce too much error
model thermal timestep fix 100
model solve time-total [24*3600]
model save 'hyd_exp2_1d'
model thermal timestep fix 300
model solve time-total [3*24*3600]
model save 'hyd_exp2_3d'
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