Bayesian inference with correction of model bias for Thermo-Hydro-Mechanical models of large concrete structures

“…The details of the applied models are provided in the next sections. [34] thermal analysis/thermal property prediction model based on the experiments, hydration kinetics, and composite material equivalence theory Mirković U. et al [35] thermal analysis/FEM/Lusas Academic software (Available online: https://www.lusas.com (accessed on 1 March 2022))/validation Zhang J. et al [12] fully coupled hygro-thermo-mechanical model/FEM/validation Sumarno A. et al [36] thermal analysis/2D model Zhang S. et al [37] thermal fields/numerical simulation/ABAQUS 2021/validation Yu H. et al [38] thermal fields/numerical simulation/validation 2023 Mansour D. et al [13] thermal analysis/3D-finite difference model/MS Excel Van Tran M. et al [39] thermal analysis/numerical simulation/Ansys Fluent software/validation Cai Y. et al [40] thermal field/3D-FEM simulation/ABAQUS/validation Lajimi N. et al [41] hygro-thermal analysis/numerical simulation/DIGITAL Visual FORTRAN 95 Ebid A. M. et al [14] State of the art on heat and mass transfer in self-compacting concrete and geopolymer concrete Wasik M. et al [42] the prototype of the experimental stand for heat and moisture transfer investigation in building materials Zhu J. et al [43] temperature field analysis/mesoscale simulation Prskalo S. et al [44] multi-field model/finite element code PANDAS Yin H. et al [45] multi-field model/3D flow lattice model (FLM) Rossat D. et al [46] thermo-hydro-mechanical model/FE simulation/validation Lyu C. et al [47] thermo-hydro-force coupling model/FE simulation/COMSOL Multiphysics/validation Li X. et al [48] thermal analysis/FEM/Midas FEA software/validation Meghwar S. L. et al [49] moisture diffusion/FE simulation/validation 2022 Yikici A. et al [50] thermal analysis/3D numerical model/finite volume method (FVM)/MATLAB/validation Cheng P. et al [51] coupled thermo-hydro-mechanical-phase field/2D numerical simulation/Fortran/The Intel ® oneAPI Math Kernel Library PARDISO Bondareva et al [52] mathematical model of the unsteady coupled heat and mass transfer in concrete containing PCM/validation Mostafavi S.A. et al [53] thermal model/MATLAB Zhang Z. et al [54] moisture transport/2D computational fluid dynamics (CFDs) model Smolana A. et al …”

“…This method treats concrete as a continuous medium, employing a macroscopic description of thermal and moisture phenomena. Numerous examples of applications of phenomenological models can be found in the literature, including references such as [46,[65][66][67][68][69][70][71][72][73]. Therefore, this review focuses on the phenomenological approach to modeling heat and mass transfer in hardening cement-based materials.…”

Modeling of Heat and Mass Transfer in Cement-Based Materials during Cement Hydration—A Review

“…The details of the applied models are provided in the next sections. [34] thermal analysis/thermal property prediction model based on the experiments, hydration kinetics, and composite material equivalence theory Mirković U. et al [35] thermal analysis/FEM/Lusas Academic software (Available online: https://www.lusas.com (accessed on 1 March 2022))/validation Zhang J. et al [12] fully coupled hygro-thermo-mechanical model/FEM/validation Sumarno A. et al [36] thermal analysis/2D model Zhang S. et al [37] thermal fields/numerical simulation/ABAQUS 2021/validation Yu H. et al [38] thermal fields/numerical simulation/validation 2023 Mansour D. et al [13] thermal analysis/3D-finite difference model/MS Excel Van Tran M. et al [39] thermal analysis/numerical simulation/Ansys Fluent software/validation Cai Y. et al [40] thermal field/3D-FEM simulation/ABAQUS/validation Lajimi N. et al [41] hygro-thermal analysis/numerical simulation/DIGITAL Visual FORTRAN 95 Ebid A. M. et al [14] State of the art on heat and mass transfer in self-compacting concrete and geopolymer concrete Wasik M. et al [42] the prototype of the experimental stand for heat and moisture transfer investigation in building materials Zhu J. et al [43] temperature field analysis/mesoscale simulation Prskalo S. et al [44] multi-field model/finite element code PANDAS Yin H. et al [45] multi-field model/3D flow lattice model (FLM) Rossat D. et al [46] thermo-hydro-mechanical model/FE simulation/validation Lyu C. et al [47] thermo-hydro-force coupling model/FE simulation/COMSOL Multiphysics/validation Li X. et al [48] thermal analysis/FEM/Midas FEA software/validation Meghwar S. L. et al [49] moisture diffusion/FE simulation/validation 2022 Yikici A. et al [50] thermal analysis/3D numerical model/finite volume method (FVM)/MATLAB/validation Cheng P. et al [51] coupled thermo-hydro-mechanical-phase field/2D numerical simulation/Fortran/The Intel ® oneAPI Math Kernel Library PARDISO Bondareva et al [52] mathematical model of the unsteady coupled heat and mass transfer in concrete containing PCM/validation Mostafavi S.A. et al [53] thermal model/MATLAB Zhang Z. et al [54] moisture transport/2D computational fluid dynamics (CFDs) model Smolana A. et al …”

“…This method treats concrete as a continuous medium, employing a macroscopic description of thermal and moisture phenomena. Numerous examples of applications of phenomenological models can be found in the literature, including references such as [46,[65][66][67][68][69][70][71][72][73]. Therefore, this review focuses on the phenomenological approach to modeling heat and mass transfer in hardening cement-based materials.…”

Modeling of Heat and Mass Transfer in Cement-Based Materials during Cement Hydration—A Review

Efficient variational Bayesian model updating by Bayesian active learning

Load Identification of High-Speed Train Crossbeam Based on Bayesian Finite Element Model Updating and Load-Strain Linear Superposition Algorithm