Study of Carbonation-depth Prediction of Unsaturated Concrete Considering Carbonation-produced Water

IF 1 Q4 ENGINEERING, CIVIL

Jordan Journal of Civil Engineering Pub Date : 2023-01-01 DOI:10.14525/jjce.v17i1.08

J. Long, Zhigao Peng, Haoxiong Feng, Aocheng Yang

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引用次数: 1

Abstract

Carbon dioxide can react with alkaline carbonate substances in cement-based materials, which harms the durability of the concrete structure. The carbonation reaction is a process of releasing water, resulting in an increase in pore water saturation, which was always neglected by previous studies. In this paper, a transient pore water saturation equation is proposed and introduced into the classical carbonation reaction kinetic model, which is simulated by finite-element software with a typical ordinary Portland cement. The model was verified by two classical empirical equations for carbonation-depth prediction. The simulation results indicated that the increment of pore water saturation originated by carbonation-produced water will weaken the CO2 diffusivity and enhance the carbonation resistance. Besides, the growth rate of carbonation depth is slightly faster without considering the produced water and with higher initial saturation, the difference will be more significant. If the influence of carbonation water is ignored, the predicted carbonation depth of unsaturated concrete may be less accurate. This study can provide some reference for theoretical and experimental studies on concrete carbonation. However, future work is still needed including more realistic effects in the model such as the mesoscale modeling of concrete and the integration of stress states. KEYWORDS: Ordinary Portland concrete, Carbonization reaction, Carbon-dioxide transport, Finite-element method, Pore saturation.

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考虑采出水碳化的非饱和混凝土碳化深度预测研究

二氧化碳会与水泥基材料中的碱性碳酸盐物质发生反应，损害混凝土结构的耐久性。碳酸化反应是一个释放水的过程，导致孔隙水饱和度的增加，这一点在以往的研究中一直被忽略。本文提出了瞬态孔隙水饱和度方程，并将其引入经典碳酸化反应动力学模型中，以典型普通硅酸盐水泥为例，采用有限元软件进行了模拟。用两个经典的碳酸盐岩深度预测经验方程对模型进行了验证。模拟结果表明，碳化产水引起的孔隙水饱和度的增加会减弱CO2的扩散，增强抗碳化能力。在不考虑采出水的情况下，碳酸化深度增长速度略快，初始饱和度越高，差异越显著。如果忽略碳化水的影响，非饱和混凝土的碳化深度预测可能不太准确。本研究可为混凝土碳化的理论和实验研究提供一定的参考。然而，未来的工作仍然需要包括更多的现实效应，如混凝土的中尺度模拟和应力状态的整合。关键词:普通硅酸盐混凝土，碳化反应，二氧化碳输运，有限元法，孔隙饱和度

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来源期刊

Jordan Journal of Civil Engineering ENGINEERING, CIVIL-

CiteScore

2.10

自引率

27.30%

发文量

期刊介绍： I am very pleased and honored to be appointed as an Editor-in-Chief of the Jordan Journal of Civil Engineering which enjoys an excellent reputation, both locally and internationally. Since development is the essence of life, I hope to continue developing this distinguished Journal, building on the effort of all the Editors-in-Chief and Editorial Board Members as well as Advisory Boards of the Journal since its establishment about a decade ago. I will do my best to focus on publishing high quality diverse articles and move forward in the indexing issue of the Journal.