Internal Erosion Stabilization of Cohesionless Soil Using Lime

Banu, Shaziya Ahmed; Attom, Mousa F.

doi:10.3390/w15111992

Cited by 6 publications

(10 citation statements)

References 35 publications

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“…Factors include soil water content; unit weight; plasticity index; void ratio; soil swell; and percent passing sieve #200, soil pH, and clay minerals [4]. Other studies [5,6] showed that internal soil erosion is affected by soil type, water and material properties, and soil-piping resistance relationships. Generally, these factors resemble the physical and mineral composition of the soil [4].…”

Section: Introductionmentioning

confidence: 99%

“…Various types of internal erosion are recognized in hydraulic structures, such as piping, suffusion, blowout (heave, uplift), Suffusion, and backward erosion [5][6][7]. Piping involves the formation of a continuous tunnel, and as a result, water will flow between the upstream and downstream of the earth structure.…”

Section: Introductionmentioning

confidence: 99%

“…Studies by Luthi [14] and Banu and Attom [5,6] revealed that approximately 30-50% of embankment failures and are caused by the internal erosion of the soil. These percentages are considered a very high percentage and indicated that the majority of the earth fill dams and embankments are failed due to internal erosion.…”

Section: Introductionmentioning

confidence: 99%

“…Several materials and techniques have been used in soil stabilization such as cement stabilization [15,16], lime stabilization [5,6,17], bituminous stabilization [18,19], electrical stabilization [20,21], grouting [22,23], fly ash stabilization [24,25], burned sludge stabilization [26][27][28], sisal fiber stabilization [29,30], polypropylene stabilization [31,32], and compaction [33]. These materials and techniques were used to increase the shear strength properties, as well as to reduce settlement, compressibility, and expansion of the soils.…”

Section: Introductionmentioning

confidence: 99%

“…Lime is used in stabilizing soils against swelling and to improve the mechanical properties of weak soils [5,6]. Lime stabilizes the soil due to the soil-lime reaction that generates long-term cementitious pozzolanic bonding.…”

Section: Introductionmentioning

confidence: 99%

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Piping Stabilization of Clay Soil Using Lime

Aqel,

Attom,

El-Emam

et al. 2024

Geosciences

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Construction of earth fill dams offers a cost-effective solution for various purposes. However, their susceptibility to internal soil erosion, known as piping, poses a significant risk of structural failure and resultant loss of life and property. Soil stabilization emerges as a practical technique to fortify these dams against such threats. This study investigated the impact of lime on the internal erosion properties of clay soils, focusing on CH and ML soil types. Specimens of different lime content were prepared and remolded at 95% relative compaction and optimum moisture content. Hole Erosion tests at varying lime concentrations and curing durations were adapted to conduct the investigation. This investigation aims to optimize lime content and curing time for cohesive soil stabilization against internal erosion. Findings revealed that 2% and 5% of quicklime, by dry weight of the soil, effectively stabilized CH and ML soils, respectively, against internal erosion, with a two-day curing period proving optimal. Furthermore, the addition of lime significantly enhanced erosion rate index and critical shear strength in clay soil, underscoring its efficacy in soil stabilization efforts.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Piping Stabilization of Clay Soil Using Lime

Aqel,

Attom,

El-Emam

et al. 2024

Geosciences

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Stabilization of Clayey Soils Against Internal Erosion Using Cement-Crushed Glass Mixture

Attom,

Yamin,

Khan

et al. 2024

Lecture Notes in Civil Engineering

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Investigating the internal erosion behavior and microscopic mechanisms of chemically stabilized soil: an experimental study

Zhang,

Zhu,

Tao

et al. 2024

Front. Earth Sci.

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IntroductionInternal erosion triggered by water pipeline leaks seriously threatens the stability of the urban ground. Hangzhou, a city in Zhejiang Province, China, is facing critical challenges due to urban ground collapse (UGC) caused by internal erosion. However, there is a lack of research on the prevention of UGC by improving the internal erodibility of underground soil. Addressing this issue is of utmost importance to ensure the city’s stability and safety. This paper proposes to improve the internal erodibility of typical sandy silt soils with chemical stabilisers.MethodsThe effects of three chemical stabilisers, lignosulphonate (LS), lime (LI), and lignin fibre (LF), on the critical shear stress (τc) and erosion coefficient (kd) of sandy silt soils were investigated, which from Hangzhou, Zhejiang, China, by the hole erosion test (HET) at different mixing amounts and at different conservation times.ResultsThe findings indicate that LF mainly improves the erosion resistance of sandy silt by increasing τc, and the maximum increase is 2.38 times; LI mainly improves the erosion resistance by decreasing kd, and the maximum decrease is 2.18 times. After adding LS, τc and kd did not change significantly. The scanning electron microscope (SEM) test revealed that the inclusion of LF led to the formation of larger agglomerates in the sandy silt soil. The microstructure of sandy silt soil remained dispersed even after adding LS. Various chemical stabilisers used to improve sandy silt soils exhibited distinct erosion mechanisms. Sandy silt soils improved with LF exfoliated into agglomerates, displaying high resistance to erosion. On the other hand, the sandy silt treated with LF still lacks a protective layer and shows minimal improvements in its ability to withstand erosion. In contrast, the LS-amended sandy silt remains stripped with individual soil particles with insignificant changes in erosion resistance.DiscussionThis study can provide a conceptual framework for choosing foundation treatment techniques in future urban development projects.

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Internal Erosion Stabilization of Cohesionless Soil Using Lime

Cited by 6 publications

References 35 publications

Piping Stabilization of Clay Soil Using Lime

Piping Stabilization of Clay Soil Using Lime

Stabilization of Clayey Soils Against Internal Erosion Using Cement-Crushed Glass Mixture

Investigating the internal erosion behavior and microscopic mechanisms of chemically stabilized soil: an experimental study

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