含膨润土和纤维素醚的水泥-硅酸钠浆液的高温流变性

IF 1.3 4区工程技术 Q3 CONSTRUCTION & BUILDING TECHNOLOGY

Advances in Cement Research Pub Date : 2023-04-27 DOI:10.1680/jadcr.22.00200

Rentai Liu, Xiuhao Li, Shucai Li, Chunyu Zhang, Mengjun Chen, Canxun Du, Sanlin Du

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引用次数: 1

摘要

水泥-硅酸钠(C-S)浆液被广泛用于防治突水灾害，其表观粘度对其堵水效果有很大影响。然而，传统的注浆材料和方法不适合高温环境，高温会影响浆液粘度。黏度改性外加剂(vma)用于增稠浆料，提高浆料的表观黏度。在这项研究中，使用两种类型的膨润土(钙膨润土，Ca-B和钠膨润土，Na-B)和羟乙基甲基纤维素(HEMC)对C-S浆液进行改性，并进行了实验室测试，以评估流动性、凝胶时间和流变性。结果表明，膨润土和HEMC均降低了凝胶的流动性，延长了凝胶时间。在不同温度下，HEMC、Ca-B和Na-B分别降低了46.8 ~ 60.4%、12.5 ~ 31.5%和17.7 ~ 39.1%的流动性。HEMC、Ca-B和Na-B分别使凝胶时间延长23.8% ~ 50.1%、23.3 ~ 71.4%和20% ~ 57.1%。此外，膨润土由于吸水能力强，可以部分抵抗高温，提高浆液的表观粘度。相反，HEMC对表观粘度有负面影响，这是由于水泥颗粒与HEMC之间的分子间交联形成了复杂的微观结构，阻止了水玻璃的连接。

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Rheology of cement-sodium silicate grout containing bentonite and cellulose ether at high temperatures

Cement-sodium silicate (C-S) grout is widely used to control water inrush disasters, and its apparent viscosity considerably impacts its water-plugging effect. However, the traditional grouting materials and methods are inappropriate for high-temperature environments, as high temperatures can affect the grout viscosity. Viscosity-modifying admixtures (VMAs) are used to thicken the grout and increase its apparent viscosity. In this study, two types of bentonite (calcium bentonite, Ca-B, and sodium bentonite, Na-B) and hydroxyethyl methyl cellulose (HEMC) were used to modify the C-S grout, and laboratory tests to evaluate fluidity, gelation time, and rheology were performed. The results showed that both bentonite and HEMC decreased fluidity and prolonged gelation time. HEMC, Ca-B, and Na-B decreased fluidity by 46.8–60.4%, 12.5–31.5%, and 17.7–39.1%, respectively, at different temperatures. HEMC, Ca-B, and Na-B increased gelation time by 23.8–50.1%, 23.3–71.4%, and 20%–57.1%, respectively. Additionally, bentonite can partially resist high temperatures and improve the apparent viscosity of grout owing to its water-absorption capacity. Conversely, HEMC has a negative effect on apparent viscosity, which is attributed to the formation of a complex microstructure resulting from intermolecular crosslinking between the cement particles and HEMC, preventing the connection of sodium silicate.

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来源期刊

Advances in Cement Research 工程技术-材料科学：综合

CiteScore

3.70

自引率

5.00%

发文量

审稿时长

3.2 months

期刊介绍： Advances in Cement Research highlights the scientific ideas and innovations within the cutting-edge cement manufacture industry. It is a global journal with a scope encompassing cement manufacture and materials, properties and durability of cementitious materials and systems, hydration, interaction of cement with other materials, analysis and testing, special cements and applications.