Code_Aster. TPNL301 - Thermohydration of a concrete cylinder

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Titre : TPNL301 - Thermo-hydratation d'un cylindre de béto[...] Date : 01/08/2011 Page : 1/8 TPNL301 - Thermohydration of a concrete cylinder Summary: The purpose of this test is to validate the thermo-hydrating behavior THER_HYDR, consists in imposing two temperatures inside and outside a presumedly infinite hollow roll. It is a question of finding the field of temperature and hydration in the course of time. The reference solution semi-analytical, is obtained by an implicit scheme for the temperature and explicit for the hydration. 4 modelings are carried out: 3D and 3D_DIAG on a mixed grid TETRA4, HEXA8, PENTA6 3D on a mixed grid TETRA10, HEXA20, PENTA15 AXIS and AXIS_DIAG on a mixed grid TRIA3 and QUAD4 AXIS and AXIS_DIAG on a mixed grid TRIA6 and QUAD9

Titre : TPNL301 - Thermo-hydratation d'un cylindre de béto[...] Date : 01/08/2011 Page : 2/8 1 Problem of reference 1.1 Geometry Cylinder infinite length and internal ray Rint=20m and outside Rext=21m. 1.2 Properties of material The material has the following thermal characteristics: thermal conductivity: =6 kj /h/ m/ K voluminal variation of enthalpy: C p =2400kJ /m3 K., and characteristics relating to the behavior hydrating following: heat per degree of hydration: Q 0 =1.4904e 5 kj /m 3 affinity function of the hydration (polynomial evaluation of the function known by points) and of the temperature (tablecloth): QSR A h, T = 1586000h 5 5224000h 4 6432000h 3 353500h 2 730000h 6510 exp K 273,15 T with constant of Arrhenius: QSR K =4000/ K. Note: The constant of Arrhenius is always expressed in Kelvin degree. The temperatures are expressed in C. 1.3 Boundary conditions and loadings T r=r int,t =T int =40 C T r=r ext,t =T ext =15 C 1.4 Initial conditions T r,t=0 = r corresponds to the stationary solution of the cylinder without internal source of heat subjected to constraints of temperature in internal and external skin, T int and T ext. 1.5 Discretization in time The explicit integration of the hydration requires a fine temporal discretization until the end of the phenomenon of hydration:

Titre : TPNL301 - Thermo-hydratation d'un cylindre de béto[...] Date : 01/08/2011 Page : 3/8 Of t=0 with t=300h, t=2 h. Of t=300h with t=730h t=10h. 2 Reference solution 2.1 Method of calculating The stationary solution is obtained analytically: r =T int T T int ext r ln ln R R ext int R int Then, the transitory problem in temperature is solved by using the method of resolution digital of Crank-Nicholson (implicit). The solution in hydration is obtained by a diagram clarifies (not time = 1h ). h r,t t =h r,t dh dt =h r,t A h r, t exp A r T r,t 273,15 2.2 Sizes and results of reference The reference solution in temperature and hydration is known on a grid r, t, with: r vary 20 with 21m with a step r=0,05 and t vary 0 with with a step of t=0,01 h. One will observe the results more particularly in r =20,5 m with t=0, 50h and 730h and the maximum value of the temperature. 27,3475 48,7091 27,7116 48,7557 0,4778 0,9558 2.3 Uncertainties on the solution The method of resolution is semi-analytical. Moreover, the hydration is integrated explicitly: the step of time must thus be sufficiently small. 2.4 Bibliographical references [1] J. HAELEWYN, Assessment of the thermal elements with thermohydration Report AMA 10,021 (2010)

Titre : TPNL301 - Thermo-hydratation d'un cylindre de béto[...] Date : 01/08/2011 Page : 4/8 3 Modeling A 3.1 Characteristics of modeling Two calculations are carried out, one in modeling 3D and the other in modeling 3D_DIAG. 3.2 Characteristics of the grid Many nodes: 798 Many meshs and types: 128 HEXA8, 544 PENTA6, 926 TETRA4. 3.3 Sizes tested and results The node tested is X205 coordinates 20.5; 0.5;0.5 Test Modeling Reference Aster Difference (%) C 3D 27,3475 27,5000 0,56 C 3D_DIAG 27,3475 27,5000 0,56 C 3D 48,7091 49,2586 1,1 C 3D_DIAG 48,7091 49,0701 0,74 C 3D 27,7116 27,8709 0,57 C 3D_DIAG 27,7116 27,8713 0,57 C 3D 48,7557 49,4487 1,4 C 3D_DIAG 48,7557 49,3345 1,2 3D 0,4778 0,4722-1,2 3D_DIAG 0,4778 0,4704-1,5 3D 0,9558 0,9545-0,13 3D_DIAG 0,9558 0,9542-0,17

Titre : TPNL301 - Thermo-hydratation d'un cylindre de béto[...] Date : 01/08/2011 Page : 5/8 4 Modeling B 4.1 Characteristics of modeling Modeling 3D with quadratic elements. 4.2 Characteristics of the grid Many nodes: 3933 Many meshs and types: 128 HEXA20, 544 PENTA15, 926 TETRA10. 4.3 Sizes tested and results The node tested is X205 coordinates 20.5; 0.5;0.5 Modeling Reference Aster Difference (%) C 3D 27,3475 27,5495 0,74 C 3D 48,7091 52,0074 6,8 C 3D 27,7116 27,9624 0,91 C 3D 48,7557 52,8420 8,1 3D 0,4778 0,4868 1,9 3D 0,9558 0,9609 0,54

Titre : TPNL301 - Thermo-hydratation d'un cylindre de béto[...] Date : 01/08/2011 Page : 6/8 5 Modeling C 5.1 Characteristics of modeling Two calculations are carried out, one in modeling AXIS and the other in modeling AXIS_DIAG. 5.2 Characteristics of the grid Many nodes: 25 Many meshs and types: 16 TRIA3, 8 QUAD4. 5.3 Sizes tested and results The node tested is X205 coordinates 20.5; 0.5. Modeling Reference Aster Difference (%) C AXIS 27,3475 27,3475 0 C AXIS_DIAG 27,3475 27,3475 0 C AXIS 48,7091 48,3622-0,71 C AXIS_DIAG 48,7091 47,8223-1,8 C AXIS 27,7116 27,6526-0,21 C AXIS_DIAG 27,7116 27,6524-0,21 C AXIS 48,7557 48,3622-1 C AXIS_DIAG 48,7557 47,9020-2 AXIS 0,4778 0,4917 2,9 AXIS_DIAG 0,4778 0,4852 1,6 AXIS 0,9558 0,9579 0,23 AXIS_DIAG 0,9558 0,9570 0,13

Titre : TPNL301 - Thermo-hydratation d'un cylindre de béto[...] Date : 01/08/2011 Page : 7/8 6 Modeling D 6.1 Characteristics of modeling Two calculations are carried out, one in modeling AXIS and the other in modeling AXIS_DIAG. 6.2 Characteristics of the grid Many nodes: 81 Many meshs and types: 16 TRIA6, 8 QUAD9. 6.3 Sizes tested and results The node tested is X205 coordinates 20.5; 0.5 Modeling Reference Aster Difference (%) C AXIS 27,3475 27,9568 2,2 C AXIS_DIAG 27,3475 27,6960 1,3 C AXIS 48,7091 51,8141 6,4 C AXIS_DIAG 48,7091 51,2837 5,3 C AXIS 27,7116 28,2898 2,1 C AXIS_DIAG 27,7116 28,0643 1,3 C AXIS 48,7557 52,1296 6,7 C AXIS_DIAG 48,7557 52,5950 5,6 AXIS 0,4778 0,5151 7,8 AXIS_DIAG 0,4778 0,4969 4 AXIS 0,9558 0,9611 0,55 AXIS_DIAG 0,9558 0,9651 0,97

Titre : TPNL301 - Thermo-hydratation d'un cylindre de béto[...] Date : 01/08/2011 Page : 8/8 7 Summary of the results The results of modelings with linear elements are rather correct. The maximum error is obtained for the hydration ( 2,9% ). The hydration is integrated explicitly. This error can thus be decreased by decreasing the step of time. The results for the quadratic elements are rather bad. The peak of temperature is overestimated. The tolerances for modelings B and D rather important but are thus supplemented by tests of not-regression. Modeling with diagonalisation of the thermal matrix of mass DIAG seems to improve the results.

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