Pseudo-dynamic carbonation for concrete curing and carbon storage

Q4 Engineering International Journal of Materials and Structural Integrity Pub Date : 2015-08-13 DOI:10.1504/IJMSI.2015.071108

Y. Shao, A. Zhou, Mehrdad Mahoutian

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引用次数: 4

Abstract

Concrete demonstrates the capacity to absorb carbon dioxide. The reaction between concrete and carbon dioxide accelerates concrete curing at early age and converts CO2 into calcium carbonate for carbon storage. As-captured flue gas without recovery can be directly used in this application. Because of low CO2 concentration in flue gas, a pseudo-dynamic carbonation process was developed with multiple injection and releasing cycles. The effect of process parameters on carbon uptake and strength gain was examined. It was found that, with a flue gas of 25% CO2 concentration and 2-hour carbonation, cement paste could uptake CO2 of 8-11% based on cement content in immediate carbonation and concrete could absorb CO2 at 7-9% after 18-hour initial curing. The maximum possible carbon uptake from flue gas carbonation was also determined. It was about 15-17% based on cement mass. While immediate carbonation could significantly enhance the early strength, carbonation after initial curing did not improve significantly the late strength.

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混凝土养护与碳储存的拟动态碳化

混凝土具有吸收二氧化碳的能力。混凝土与二氧化碳的反应加速了混凝土的早期养护，并将二氧化碳转化为碳酸钙储存碳。未回收的捕获烟气可直接用于该应用。由于烟气中CO2浓度较低，形成了多注入、多释放循环的准动态碳酸化过程。考察了工艺参数对吸碳量和强度增益的影响。结果表明，当烟气CO2浓度为25%，碳化2小时时，水泥浆体在立即碳化时可吸收8-11%的CO2，混凝土在初始养护18小时后可吸收7-9%的CO2。还确定了最大可能的烟气碳化碳吸收量。按水泥质量计算约为15-17%。初期碳化可以显著提高早期强度，而初期固化后碳化对后期强度的提高不显著。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

International Journal of Materials and Structural Integrity Engineering-Mechanical Engineering

CiteScore

0.40

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0.00%

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