Analysis of carbonation behavior in concrete using neural network algorithm and carbonation modeling

Analysis of carbonation behavior in concrete using neural network algorithm and carbonation modeling

Carbonation on concrete structures in underground sites or metropolitan cities is one of the major causes of steel corrosion in RC (Reinforced Concrete) structures. For quantitative evaluation of carbonation, physico-chemo modeling for reaction with dissolved CO 2 and hydrates is necessary. Amount o...

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Bibliographic Details
Published in:Cement and concrete research Vol. 40; no. 1; pp. 119 - 127
Main Authors: Kwon, Seung-Jun, Song, Ha-Won
Format: Journal Article
Language:English
Published: Kidlington Elsevier Ltd 2010
Elsevier
Subjects:
Applied sciences
Building structure
Buildings. Public works
Carbonation
Concrete structure
Construction (buildings and works)
Corrosion
Diffusion coefficient
Durability. Pathology. Repairing. Maintenance
Exact sciences and technology
Modeling
Neural network
Porosity
Carbonation
Neural network
Porosity
Diffusion coefficient
Modeling
Experimental result
Corrosion
Simulation
Concrete construction
Algorithm
Application
Comparative study
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Summary:Carbonation on concrete structures in underground sites or metropolitan cities is one of the major causes of steel corrosion in RC (Reinforced Concrete) structures. For quantitative evaluation of carbonation, physico-chemo modeling for reaction with dissolved CO 2 and hydrates is necessary. Amount of hydrates and CO 2 diffusion coefficient play an important role in evaluation of carbonation behavior, however, it is difficult to obtain a various CO 2 diffusion coefficient from experiments due to limited time and cost. In this paper, a numerical technique for carbonation behavior using neural network algorithm and carbonation modeling is developed. To obtain the comparable data set of CO 2 diffusion coefficient, experimental results which were performed previously are analyzed. Mix design components such as cement content, water to cement ratio, and volume of aggregate including exposure condition of relative humidity are selected as neurons. Training of learning for neural network is carried out using back propagation algorithm. The diffusion coefficient of CO 2 from neural network are in good agreement with experimental data considering various conditions such as water to cement ratios (w/c: 0.42, 0.50, and 0.58) and relative humidities (R.H.: 10%, 45%, 75%, and 90%). Furthermore, mercury intrusion porosimetry (MIP) test is also performed to evaluate the change in porosity under carbonation. Finally, the numerical technique which is based on behavior in early-aged concrete such as hydration and pore structure is developed considering CO 2 diffusion coefficient from neural network and changing effect on porosity under carbonation.
Bibliography:ObjectType-Article-2
SourceType-Scholarly Journals-1
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content type line 23
ISSN:0008-8846
1873-3948
DOI:10.1016/j.cemconres.2009.08.022