发泡混凝土碱浸试块碳酸化增强固碳特性研究

材料导报

2019, Vol. 33

Issue (Z2): 300-303

无机非金属及其复合材料

发泡混凝土碱浸试块碳酸化增强固碳特性研究

任国宏¹, 廖洪强¹, 程芳琴¹, 闫志华²

1 山西大学资源与环境工程研究所,太原 030006;
2 长治市杨暴热电粉煤灰综合利用有限公司,长治 046000

Study on Carbon Sequestration Characteristics Enhancing by Carbonation Reactionof CO₂ for Foamed Concrete Block with Alkali Leaching

REN Guohong¹, LIAO Hongqiang¹, CHENG Fangqin¹, YAN Zhihua²

1 Institute of Resources and Environment Engineering, Shanxi University, Taiyuan 030006;
2 Changzhi Yangbao, Thermoelectric Fly Ash Comprehensive Utilization Limited, Changzhi 046000

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摘要发泡混凝土与CO₂碳酸化反应不仅可以改善混凝土性能而且可实现CO₂的矿化固定达到减排的效果。本实验分别考察了CO₂反应时间对未浸、水浸和电石渣饱和液浸泡后发泡混凝土试块抗压强度的影响,并采用XRD、TGA 、SEM分析测试手段,分别对试块的矿物组成、热失重特性和微观形貌特性进行了表征。结果表明:发泡混凝土试块的抗压强度随碳酸化反应时间延长出现先增加后降低的变化趋势;碱浸碳酸化反应4 h试块强度最高为6.5 MPa,较未碳酸化反应试块强度上升80.6%。SEM分析结果显示,发泡混凝土试块孔壁结构随碳酸化反应时间延长发生较明显变化,整体上呈现“先片状致密后粒化疏松”的转化历程,这可能是导致试块抗压强度随碳酸化时间延长出现先增加后降低现象的内在原因。TGA曲线结果表明,试块达最高抗压强度时,每吨发泡混凝土可固定37 kg CO₂,在不降低试块强度前提下,每吨发泡混凝土可固定61 kg CO₂。

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	任国宏
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关键词: 发泡混凝土碳酸化反应 CO₂ 电石渣

Abstract: The foaming concrete and CO₂ carbonation reaction can not only improve the concrete performance but also achieve the effect of reducing the mineralization of CO₂. The effects of CO₂ reaction time on the compressive strength of foamed concrete blocks after immersion in unsoaked, water immersed and calcium carbide slag were investigated. XRD, TGA and SEM were used to analyze the mineral composition of the test blocks. The thermogravimetric properties and micromorphology characteristics were characterized. The results show that the compressive strength of the foamed concrete test block increases with the increase of carbonation reaction time, and the strength of the test block of alkali leaching is up to 6.5 MPa, which is lower than that of the uncarbonated reaction test. The block strength increases by 80.6%. The results of SEM analysis show that the pore wall structure of the foamed concrete test block changes significantly with the prolongation of the carbonation reaction time. The whole process shows the transformation process of “grain-like compaction and granulation looseness”, which may lead to the compressive strength of the test block. The intrinsic cause of the phenomenon of “first increase and then decrease” occurs with the prolongation of carbonation time. The TGA curve results show that when the test block reaches the highest compressive strength, the CO₂ can be fixed at 37 kg per ton of foamed concrete. Under the premise of not reducing the strength of the test block, the CO₂ can be fixed at 61 kg per ton of foamed concrete.

Key words: foamed concrete carbonation reaction carbon dioxide carbide slag

出版日期: 2019-11-25 发布日期: 2019-11-25

ZTFLH:

TK09

基金资助: 山西省重点研发(MC2016-02)

通讯作者: 13910766805@139.com

作者简介: 任国宏,2016年9月到2019年7月就读于山西大学,研究方向为固体废弃物资源化。
廖洪强,清华大学博士后,教授级高级工程师。国内节能环保及固废资源化领域的知名专家;后进入北京大学和山西大学从事节能环保与固废资源综合利用新技术开发与产业化推广应用工作10余年;承担过国家科技部支持的“863”课题、国家“十一五”科技支撑课题、国家“十二五”科技支撑课题。

引用本文:

任国宏, 廖洪强, 程芳琴, 闫志华. 发泡混凝土碱浸试块碳酸化增强固碳特性研究[J]. 材料导报, 2019, 33(Z2): 300-303.
REN Guohong, LIAO Hongqiang, CHENG Fangqin, YAN Zhihua. Study on Carbon Sequestration Characteristics Enhancing by Carbonation Reactionof CO₂ for Foamed Concrete Block with Alkali Leaching. Materials Reports, 2019, 33(Z2): 300-303.

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http://www.mater-rep.com/CN/ 或 http://www.mater-rep.com/CN/Y2019/V33/IZ2/300

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