Gradient Nonlocal Enhanced Microprestress-Solidification Theory and Its Finite Element Implementation

Abstract: Time-dependent responses of cracked concrete structures are complex, due to the intertwined effects between creep, shrinkage, and cracking. There still lacks an effective numerical model to accurately predict their nonlinear long-term deflections. To this end, a computational framework is constructed, of which the aforementioned intertwined effects are properly treated. The model inherits merits of gradient-enhanced damage (GED) model and microprestress-solidification (MPS) theory. By incorporating higher orde… Show more

“…where ε e is the instantaneous strain, ε c is the creep strain, ε th is the shrinkage strain, and ε sh is the thermal strain. The microprestress-solidification (MPS) theory has been widely used to calculate the concrete creep and has produced reasonably accurate calculations [44][45][46][47]. The MPS theory consists of the solidification and microprestress theories.…”

Study on Temperature Control and Cracking Risk of Mass Concrete Sidewalls with a Cooling-Pipe System

“…where ε e is the instantaneous strain, ε c is the creep strain, ε th is the shrinkage strain, and ε sh is the thermal strain. The microprestress-solidification (MPS) theory has been widely used to calculate the concrete creep and has produced reasonably accurate calculations [44][45][46][47]. The MPS theory consists of the solidification and microprestress theories.…”

Study on Temperature Control and Cracking Risk of Mass Concrete Sidewalls with a Cooling-Pipe System