Hygro-thermo-chemo-mechanical modelling of concrete at early ages and beyond. Part I: hydration and hygro-thermal phenomena

Gawin, Dariusz; Pesavento, Francesco; Schrefler, Bernhard A.

doi:10.1002/nme.1615

Cited by 241 publications

(208 citation statements)

References 39 publications

(155 reference statements)

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“…During the salt crystallization the additional crystallization pressure was released. The equation describing crystallization pressure was firstly derived by Correns and Steinborn [34]:…”

Section: Drying Experimentsmentioning

confidence: 99%

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Experimental and numerical investigation of sodium sulphate crystallization in porous materials

Koniorczyk

Konca

2012

Heat Mass Transfer

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The experimental setup was constructed to measure the thermal effect of the salt crystallization/dissolution process in building materials containing sodium sulphate. Additional heat was released/consumed during the salt crystallization/dissolution. The mathematical model of salt, moisture and energy transport concerning the salt phase change kinetics was derived and based on it the computer code was developed. To solve the set of partial differential, governing equations the finite element and finite difference methods were used. By solving the inverse problem the parameters of the rate law for brick saturated with the sodium sulphate solution were determined.

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“…During the salt crystallization the additional crystallization pressure was released. The equation describing crystallization pressure was firstly derived by Correns and Steinborn [34]:…”

Section: Drying Experimentsmentioning

confidence: 99%

“…The pressure, which was exerted on the solid skeleton, was summed over the phases occupying the pores: gas pressure, capillary pressure defined by the Kelvin equation [34], and additional term defining the crystallization pressure [35]:…”

Section: Drying Experimentsmentioning

confidence: 99%

Experimental and numerical investigation of sodium sulphate crystallization in porous materials

Koniorczyk

Konca

2012

Heat Mass Transfer

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“…The corresponding results allow for improved representation of water-to-cement ratio-dependent and hydration-dependent diffusivity of cement paste. This provides a novel, both experimentally and theoretically improved foundation which may support large-scale simulations concerning durability of concrete structures, see, e.g., the approaches presented by Schrefler and Pesavento (2004), Gawin et al (2006).…”

Section: Discussionmentioning

confidence: 95%

Self-Consistent Channel Approach for Upscaling Chloride Diffusivity in Cement Pastes

et al. 2017

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Chloride ingress into concrete is a major cause for material degradation, such as cracking due to corrosion-induced steel reinforcement expansion. Corresponding transport processes encompass diffusion, convection, and migration, and their mathematical quantification as a function of the concrete composition remains an unrevealed enigma. Approaching the problem step by step, we here concentrate on the diffusivity of cement paste, and how it follows from the microstructural features of the material and from the chloride diffusivity in the capillary pore spaces. For this purpose, we employ advanced self-consistent homogenization theory as recently used for permeability upscaling, based on the resolution of the pore space as pore channels being oriented in all space directions, resulting in a quite compact analytical relation between porosity, pore diffusivity, and the overall diffusivity of the cement paste. This relation is supported by experiments and reconfirms the pivotal role that layered water most probably plays for the reduction of the pore diffusivity, with respect to the diffusivity found under the chemical condition of a bulk solution.Keywords Diffusion · Homogenization · Chlorides · Multiscale modeling · Layered water List of Symbols Mathematical operators divDivergence operator, applied to a vector field div Divergence operator, applied to a second-order tensor field grad Gradient operator on the microscopic observation scale of pore space

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“…Cement hydration can be characterized by the hydration degree [74,[81][82][83], α c , that represents the fraction of Portland clinker fully reacted with water. Its evolution law can be formulated aṡ…”

Section: Hygro-thermo-chemical (Htc) Modelmentioning

confidence: 99%

Modeling Time-Dependent Behavior of Concrete Affected by Alkali Silica Reaction in Variable Environmental Conditions

Alnaggar¹,

Luzio²,

Cusatis

2017

Preprint

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Alkali Silica Reaction (ASR) is known to be a serious problem for concrete worldwide, especially in high humidity and high temperature regions. ASR is a slow process that develops over years to decades and it is influenced by changes in environmental and loading conditions of the structure. The problem becomes even more complicated if one recognizes that other phenomena like creep and shrinkage are coupled with ASR. This results in synergistic mechanisms that can not be easily understood without a comprehensive computational model. In this paper, coupling between creep, shrinkage and ASR is modeled within the Lattice Discrete Particle Model (LDPM) framework. In order to achieve this, a multi-physics formulation is used to compute the evolution of temperature, humidity, cement hydration, and ASR in both space and time, which is then used within physics-based formulations of cracking, creep and shrinkage. The overall model is calibrated and validated on the basis of experimental data available in the literature. Results show that even during free expansions (zero macroscopic stress), a significant degree of coupling exists because ASR induced expansions are relaxed by meso-scale creep driven by self-equilibriated stresses at the meso-scale. This explains and highlights the importance of considering ASR and other time dependent aging and deterioration phenomena at an appropriate length scale in coupled modeling approaches.

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Hygro-thermo-chemo-mechanical modelling of concrete at early ages and beyond. Part I: hydration and hygro-thermal phenomena

Cited by 241 publications

References 39 publications

Experimental and numerical investigation of sodium sulphate crystallization in porous materials

Experimental and numerical investigation of sodium sulphate crystallization in porous materials

Self-Consistent Channel Approach for Upscaling Chloride Diffusivity in Cement Pastes

Modeling Time-Dependent Behavior of Concrete Affected by Alkali Silica Reaction in Variable Environmental Conditions

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