碳化物石灰和稻壳碱活化体系用于颗粒土稳定

IF 1.3 Q3 ENGINEERING, GEOLOGICAL

Proceedings of the Institution of Civil Engineers-Ground Improvement Pub Date : 2022-04-07 DOI:10.1680/jgrim.21.00048

Luci Queiroz, Lucas Luciano Sousa Batista, Laura Mendonça Ponte Souza, Max Deluan Lima, Sarah Danieli, G. Bruschi, C. Bergmann

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引用次数: 7

摘要

本研究探讨了利用碱活化体系稳定颗粒土的方法。以稻壳灰为前驱体，电石石灰为活化剂，制备碱活化粘结剂。采用试验程序对砂米壳灰石石灰混合料的强度和刚度进行了分析。对不同粘结剂含量(10%和20%)、干密度(15.5、16.5和17.5kN/m³)、养护时间(7和28天)和Ca/SiO2比(1、1.5和2)进行了评价。此外，还对混合材料进行了显微组织分析。粘结剂含量、干密度和固化时间的增加有利于提高材料的强度和刚度，而Ca/SiO2比的增加则阻碍了材料的力学性能。统计分析表明，所有研究因素都影响了土-粘结剂混合物的力学性能。此外，较高的干重、粘结剂含量、养护时间和较低的摩尔比是获得最高强度和刚度的条件。碱活化体系被证明是一种很有前途的粘结剂，用于土壤的强度和刚度稳定。最后，在土-粘结剂混合物中发现了两种钙铝硅酸盐水合物结构，即钙铝硅酸钙和钙铝硅酸钙，为水泥水合物的组成提供了理想的结构。

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Alkali-activated system of carbide lime and rice husk for granular soil stabilization

This study investigated the utilization of an alkali-activated system to stabilize a granular soil. For the alkali-activated binder, rice husk ash was used as the precursor and carbide lime as the activator. An experimental program was carried out to analyze the strength and stiffness of sand-rice husk ash-carbide lime mixtures. Different binder contents (10 and 20%), dry densities (15.5, 16.5 and 17.5kN/m³), curing periods (7 and 28 days) and Ca/SiO2 ratios (1, 1.5 and 2) were evaluated. In addition, microstructural analyses were conducted on the mixed materials. The increase in binder content, dry density, and curing period led to the improvement of strength and stiffness, while the increase in Ca/SiO2 ratio hindered the mechanical behavior. The statistical analysis revealed that all studied factors influenced the mechanical behavior of soil-binder mixtures. In addition, the condition to obtain the highest strength and stiffness was evidenced in the combination of higher dry unit weight, binder content, curing period, and lower molar ratio. The alkali-activated system was shown to be a promising binder agent for soil stabilization for both strength and stiffness. Finally, two calcium aluminosilicate hydrate structures were identified in the soil-binder mixtures, soulunite and jaffeite, indicating ideal structures for the composition of cement hydrates.

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来源期刊

Proceedings of the Institution of Civil Engineers-Ground Improvement ENGINEERING, GEOLOGICAL-

CiteScore

3.10

自引率

8.30%

发文量

期刊介绍： Ground Improvement provides a fast-track vehicle for the dissemination of news in technological developments, feasibility studies and innovative engineering applications for all aspects of ground improvement, ground reinforcement and grouting. The journal publishes high-quality, practical papers relevant to engineers, specialist contractors and academics involved in the development, design, construction, monitoring and quality control aspects of ground improvement. It covers a wide range of civil and environmental engineering applications, including analytical advances, performance evaluations, pilot and model studies, instrumented case-histories and innovative applications of existing technology.