TY - GEN
T1 - Concrete fracture prediction using virtual internal bond model with modified morse functional potential
AU - Park, Kyoungsoo
AU - Paulino, Glaucio H.
AU - Roesler, Jeffery R.
PY - 2008
Y1 - 2008
N2 - Concrete fracture behavior is predicted by one of multi-scaling methods, called the virtual internal bond (VIB) model. The VIB model describes the microscopic interactions between the cement pastes and aggregates using the concept of homogenization. The microscopic behavior is connected to macroscopic behavior by the Cauchy-Born rule, which results in the strain energy function. From the macroscopic strain energy function, the VIB model represents both elastic and fracture behavior within the framework of continuum mechanics. In this study, a modified Morse functional potential is introduced for material particles interactions so that the potential is independent of the length scale lattice parameter. The other parameters in the potential function are determined on the basis of macroscopic fracture parameters, i.e. the fracture energy and the cohesive strength. Moreover, the fracture energy is evaluated in conjunction with the J-integral. Finally, the VIB model with the modified Morse potential is verified by the double cantilever beam test and validated by three-point bending tests.
AB - Concrete fracture behavior is predicted by one of multi-scaling methods, called the virtual internal bond (VIB) model. The VIB model describes the microscopic interactions between the cement pastes and aggregates using the concept of homogenization. The microscopic behavior is connected to macroscopic behavior by the Cauchy-Born rule, which results in the strain energy function. From the macroscopic strain energy function, the VIB model represents both elastic and fracture behavior within the framework of continuum mechanics. In this study, a modified Morse functional potential is introduced for material particles interactions so that the potential is independent of the length scale lattice parameter. The other parameters in the potential function are determined on the basis of macroscopic fracture parameters, i.e. the fracture energy and the cohesive strength. Moreover, the fracture energy is evaluated in conjunction with the J-integral. Finally, the VIB model with the modified Morse potential is verified by the double cantilever beam test and validated by three-point bending tests.
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U2 - 10.1063/1.2896871
DO - 10.1063/1.2896871
M3 - Conference contribution
AN - SCOPUS:40449134591
SN - 9780735404922
T3 - AIP Conference Proceedings
SP - 724
EP - 729
BT - Multiscale and Functionally Graded Materials - Proceedings of the International Conference, FGM IX
T2 - 9th International Conference on Multiscale and Functionally Graded Materials, FGM IX
Y2 - 15 October 2006 through 18 October 2006
ER -