Experimental and numerical analysis of early age behavior in non-reinforced concrete

Abstract: An approach combining numerical simulations and experimental techniques is proposed to investigate the early-age properties of non-reinforced concrete. Both thermo-mechanical and fracture behaviors are studied, providing a deep insight into the hydration process. This work makes an important step in understanding the effects of hydration on the performance of cement-based materials. More specifically, in the first part, the shrinkage and fracture properties of a non-reinforced concrete have been experimentally… Show more

“…where A T represents the ratio of the maximum value of the heat production rate to the latent hydration heat for a normalized definition of the hydration function [1,29,32], the damage variable / affects the heat during hydration reaction as assumed in [29]. Moreover, E a is the activation energy characterizing the rate of heat generation and R ¼ 8:314 Â 10 À3 kJ K À1 mol À1 is the ideal gas constant.…”

“…Generally, there are many ways to choose this specific function e.g. a piecewise linear or exponential approximation of the experimental data [1,20,29,33,71]. In the present study, the power form of the evolution function, f ðaÞ, for the normalized heat production rate is considered as presented in [1,29,32]:…”

“…Cement hydration and shrinkage is a phenomenon characterized by inhomogeneous stresses occurring in plain and non-reinforced concrete. Concrete is widely used in infrastructures such as airfields, slabs and dams [1]. A significant disadvantage of concrete is its sensitivity with respect to the early-age cracking in aforementioned structures.…”

“…A significant disadvantage of concrete is its sensitivity with respect to the early-age cracking in aforementioned structures. Hence, a basic understanding of material performance due to early-age cracking is required in the design of concrete structures [1,2]. Due to the fast change of mechanical properties such as strength of the material [3,4], prediction of the behaviour of concrete is still not a trivial task.…”

“…Other numerical approaches such as microplane approach in [27] or lattice approach in [28] are used to investigate the early-age concrete behaviour. Soon afterwards, Neguyen et al [1,29] have proposed a phase field model to investigate complex fracture induced by early-age shrinkage and hydration heat in cement based materials. Other numerical methods in this field can be traced in [30][31][32].…”

Simulation of chemo-thermo-mechanical problems in cement-based materials with Peridynamics

“…where A T represents the ratio of the maximum value of the heat production rate to the latent hydration heat for a normalized definition of the hydration function [1,29,32], the damage variable / affects the heat during hydration reaction as assumed in [29]. Moreover, E a is the activation energy characterizing the rate of heat generation and R ¼ 8:314 Â 10 À3 kJ K À1 mol À1 is the ideal gas constant.…”

“…Generally, there are many ways to choose this specific function e.g. a piecewise linear or exponential approximation of the experimental data [1,20,29,33,71]. In the present study, the power form of the evolution function, f ðaÞ, for the normalized heat production rate is considered as presented in [1,29,32]:…”

“…Cement hydration and shrinkage is a phenomenon characterized by inhomogeneous stresses occurring in plain and non-reinforced concrete. Concrete is widely used in infrastructures such as airfields, slabs and dams [1]. A significant disadvantage of concrete is its sensitivity with respect to the early-age cracking in aforementioned structures.…”

“…A significant disadvantage of concrete is its sensitivity with respect to the early-age cracking in aforementioned structures. Hence, a basic understanding of material performance due to early-age cracking is required in the design of concrete structures [1,2]. Due to the fast change of mechanical properties such as strength of the material [3,4], prediction of the behaviour of concrete is still not a trivial task.…”

“…Other numerical approaches such as microplane approach in [27] or lattice approach in [28] are used to investigate the early-age concrete behaviour. Soon afterwards, Neguyen et al [1,29] have proposed a phase field model to investigate complex fracture induced by early-age shrinkage and hydration heat in cement based materials. Other numerical methods in this field can be traced in [30][31][32].…”

Simulation of chemo-thermo-mechanical problems in cement-based materials with Peridynamics

PD-FEM chemo-thermo-mechanical coupled model for simulation of early-age cracks in cement-based materials

Investigation on the concrete strength performance of underlying tunnel structure subjected to train-induced dynamic loads at an early age