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CO2-工业废渣协同固化渣土多尺度试验研究OA

Multiscale experimental study on waste soil co-solidified by CO2 and industrial waste

中文摘要英文摘要

为实现工程渣土的高效固化并资源化利用,以纯工业废渣—WZ01 为主固化剂,电石渣(CCR)为碱性激发剂,结合CO2 碳化技术,采用微观-单元体-模型多尺度试验研究CO2-CCR-WZ01 协同固化渣土的可行性,通过开展无侧限抗压强度试验与CO2 吸收率测定试验来分析通碳时间(Tc)、碳化温度(Kc)、通碳压强(Pc)、CO2 浓度(Wc)四种因素对碳化效果的影响规律,并结合微观与模型试验探究CO2-WZ01-CCR固化土的微观演变规律,从多尺度角度评价CO2-CCR-WZ01 协同固化技术的固化效果.结果表明:在Tc=6 h、Kc=60 °C,、Pc=600 kPa、Wc=50%时,渣土的碳化效果最佳;在碳化-固化反应的内外协同作用下,生成的方解石、C-A-H、C-S-H等产物可以有效填充孔隙,提高渣土强度;CO2-CCR-WZ01 协同作用下碳化土的贯入指数最低,承载力达到 700 kPa,土体物理力学性质得到显著提升.CO2-CCR-WZ01 协同固化技术具有高效、低碳、环保等特征,可在渣土资源化利用中得到广泛引用.

With the rapid construction and iteration of urban infrastructure in China,substantial amounts of abandoned engineering waste soil have piled up,causing serious environmental pollution and resource waste.To achieve efficient solidification and resource utilization of engineering waste soil,this study examined the use of pure industrial waste residue,WZ01 as the primary solidifying agent and calcium carbide slag(CCR)as the alkaline activator,to reinforce the engineering waste soil.The introduction of carbon capture utilization and storage(CCUS)technology to achieve multiple goals including carbon sequestration and storage of CO2,as well as resource utilization of engineering and industrial waste,was also examined.The feasibility of CO2-CCR-WZ01 synergistic solidification of slag soil was studied using microscale unit cell model multiscale experiments.Unconfined compressive strength tests and CO2 absorption rate tests were conducted to analyze the effects of four factors on the carbonation process:carbonation time(Tc),carbonation temperature(Kc),carbon pressure(Pc),and CO2 concentration(Wc).To determine which of these factors had the best effect on CO2-CCR-WZ01 solidification engineering waste soil,we conducted various micro experiments,such as scanning electron microscopy(SEM),energy dispersive X-ray spectroscopy(EDS),X-ray diffraction(XRD),and thermogravimetric analysis(TGA),to e xplore the micro evolution law of CO2-WZ01-CCR solidified soil and analyze the reaction mechanism of CO2-WZ01-CCR synergistic solidification technology.Finally,indoor model box tests were conducted to analyze the improvement of CO2-WZ01-CCR collaborative solidification technology on slag soil with respect to mechanical and physical properties.The feasibility of on-site construction of the CO2-WZ01-CCR collaborative solidification technology and its application prospects were evaluated from a multiscale perspective.The experimental results show that with an increase in Tc,qu gradually increases and growth rate gradually decreases.As Kc increases,qu gradually increases and the amplification rate gradually becomes faster;As Pc increases,qu shows a trend of first increasing and then decreasing;With an increase in Wc,qu gradually increases and growth rate gradually decreases.The best carbonization effect of engineering slag soil was achieved with Tc=6 h,Kc=60 ℃,Pc=600 kPa,and Wc=50%.The main product generated by carbonization reaction is calcite,which is concentrated on the outer surface of the unit,whereas cementitious products such as C-A-H and C-S-H generated by solidification reaction are distributed in the middle of the unit.Through the synergistic effect of carbonization solidification reaction,the generated products can effectively fill the pores and improve the strength of the slag soil.Under the influence of CO2-CCR-WZ01,the permeability index of the carbonized soil was significantly reduced.The bearing capacity reached 700 kPa,and substantial improvements were observed in the basic physical properties of the soil.The CO2-CCR-WZ01 co-curing technology demonstrates high efficiency,low carbon emissions,and environmental sustainability.This indicates that the technology can significantly reinforce and improve engineering waste soil,making it a promising solution for the resource utilization of engineering residues.Studying CO2 carbonization technology provides research direction and academic support for the low-carbon development of geotechnical engineering,which is of great significance in achieving"Dual Carbon Goals".

朱剑锋;汪正清;陶燕丽;龚晓南;夏亚宁;李挺

浙江科技大学土木与建筑工程学院,杭州 310023浙江科技大学土木与建筑工程学院,杭州 310023||南京水利科学研究院岩土工程研究所,南京 210024浙江科技大学土木与建筑工程学院,杭州 310023浙江大学滨海和城市岩土工程研究中心,杭州 310058浙江科技大学土木与建筑工程学院,杭州 310023浙江科技大学土木与建筑工程学院,杭州 310023

建筑与水利

渣土碳化无侧限抗压强度碳吸附率微观结构模型试验

waste soilcarbonationunconfined compression strengthcarbon adsorption ratemicro-testmodel test

《工程科学学报》 2026 (3)

504-516,13

国家自然科学基金资助项目(52378378)浙江省公益项目(LGG22E090002TGS23E080010)

10.13374/j.issn2095-9389.2025.01.16.003

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