Applying the Porosity-to-Cement Index for Estimating the Mechanical Strength, Durability, and Microstructure of Artificially Cemented Soil

Q3 Engineering

Open Civil Engineering Journal Pub Date : 2023-05-01 DOI:10.28991/cej-2023-09-05-02

Jair Arrieta-Baldovino, R. Izzo, Carlos Millan-Paramo

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引用次数: 0

Abstract

Fine, expansive, and problematic soils cannot be used in fills or paving layers. Through additions to these soils, they can be converted into technically usable materials in civil construction. One methodology to make them viable for construction is through a stabilization process. Nevertheless, current methodologies regarding dosage based on compaction effort and the volumetric amount of binder used are unclear. Thus, this research describes cement-stabilized sedimentary silt's strength and durability properties from Curitiba (Brazil) for future application in paving. Splitting tensile strength, unconfined compressive strength, and loss of mass against wetting and drying cycles (W-D) were investigated in the laboratory utilizing greenish-gray silt (originating from one of the Guabirotuba Formation layers, Paraná) and high-early strength Portland cement- ARI (CPV). Utilized were cement concentrations (C) of 3, 5, 7, and 9%, molding dry unit weights (d) of 14, 15, and 16 kN/m3, curing periods (t) of 7, 14, and 28 days, and constant moisture content (w) of 23%. With an increase in cement concentration and curing time, the compacted mixes demonstrate an increase in strength, an improvement in microstructure, and a decrease in accumulated mass loss (ALM) and initial porosity (η). Using the porosity/volumetric cement content ratio (η/Civ), the lowest amount of cement required to stabilize the soil in terms of strength and durability was determined. The porosity/cement index provided an appropriate parameter for modeling the mechanical and durability properties, and a unique equation between the strength/accumulated loss of mass and the porosity/binder index was obtained for the curing times studied. Lastly, C = 5% by weight is the minimum acceptable amount for prospective subbase soil application. Doi: 10.28991/CEJ-2023-09-05-02 Full Text: PDF

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应用水泥孔隙率指数估算人工胶结土的机械强度、耐久性和微观结构

细、膨胀和有问题的土壤不能用于填充物或铺装层。通过添加这些土壤，它们可以转化为民用建筑中技术上可用的材料。一种使它们能够施工的方法是通过稳定过程。然而，目前关于基于压实努力和使用粘合剂的体积量的剂量的方法尚不清楚。因此，本研究描述了来自巴西库里蒂巴(Curitiba)的水泥稳定沉积粉土的强度和耐久性特性，以供未来在铺装中的应用。劈裂抗拉强度、无侧限抗压强度和湿、干循环下的质量损失(W-D)在实验室进行了研究，使用的是绿灰色泥沙(来自瓜比罗图巴地层之一，paran)和高早强度波特兰水泥- ARI (CPV)。所使用的水泥浓度(C)分别为3,5,7和9%，成型干重(d)分别为14,15和16 kN/m3，养护时间(t)分别为7,14和28天，恒定含水率(w)为23%。随着水泥浓度的增加和养护时间的延长，压实混合料的强度增加，微观结构改善，累积质量损失(ALM)和初始孔隙率(η)降低。通过孔隙率/体积水泥掺量比(η/Civ)，确定了稳定土体强度和耐久性所需的最低水泥用量。孔隙度/胶结指数为模拟混凝土的力学性能和耐久性提供了合适的参数，并在研究的养护时间内得到了强度/累积质量损失量与孔隙度/胶结指数之间的独特方程。最后，C = 5%的重量是最低可接受的量为潜在的基层土壤应用。Doi: 10.28991/CEJ-2023-09-05-02全文:PDF

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来源期刊

Open Civil Engineering Journal Engineering-Civil and Structural Engineering

CiteScore

1.90

自引率

0.00%

发文量

期刊介绍： The Open Civil Engineering Journal is an Open Access online journal which publishes research, reviews/mini-reviews, letter articles and guest edited single topic issues in all areas of civil engineering. The Open Civil Engineering Journal, a peer-reviewed journal, is an important and reliable source of current information on developments in civil engineering. The topics covered in the journal include (but not limited to) concrete structures, construction materials, structural mechanics, soil mechanics, foundation engineering, offshore geotechnics, water resources, hydraulics, horology, coastal engineering, river engineering, ocean modeling, fluid-solid-structure interactions, offshore engineering, marine structures, constructional management and other civil engineering relevant areas.