Study on Anti-Uplift Effect of Micro-Steel-Pipe Pile on Red-Bedded Soft Rock Subgrade

Zhang, Rui; Luo, Hui; Liu, Zhengnan; Nie, Rusong

doi:10.3390/su141911923

Cited by 4 publications

(2 citation statements)

References 35 publications

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“…The mechanical properties of micro-steel pipe piles in stations using the PBA method require further study. However, the supporting effect of side piles is also the focus of scholars (Zhang et al, 2022). Generally, with an increase in the row number of side piles, the supporting effect will be greatly enhanced; however, this increases the difficulty and cost of construction.…”

Section: Introductionmentioning

confidence: 99%

Mechanical Difference Analysis of Single-row and Double-row Side Piles in Stations by PBA Method Based on Model Test

Wang

2024

JJCE

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This study employs the pile-beam-arch (PBA) method to investigate the force-evolution law of micro-steel pipe piles during the excavation process, focusing on a Guangzhou metro-station project. Through laboratory model tests, we compared and analyzed the mechanical evolution laws of single-row and double-row side piles. Our findings revealed a significant soil arch effect in both single-row and double-row piles; with similar distribution patterns and peak-stress range. As soil excavation progresses, the soil arching effect shifts downward. Notably, the stress concentration in double-row piles is weaker than that in single-row piles, especially in the soil range of 0–50 mm after the piles. This is attributed to the looser soil between single-row piles, resulting in more evident stress release. The attenuation amplitude of the Y-direction stress of the double-row piles was considerably smaller than that of the single-row piles. The soil arching between the back-row piles in doublerow configurations exhibits shielding effects on the force of front-row piles, significantly weakening the soil pressure on them. This impact alters the force of the front-row piles, even causing the tip of the front-row piles to bend in reverse. The research results provide important insights for similar projects and can serve as a valuable reference.

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Section: Introductionmentioning

confidence: 99%

Mechanical Difference Analysis of Single-row and Double-row Side Piles in Stations by PBA Method Based on Model Test

Wang

2024

JJCE

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“…They have conducted comprehensive analyses of the mechanical behavior of micropile groups subjected to both vertical and lateral loading scenarios, with the aim of offering robust design and construction recommendations [15,16]. Furthermore, in terms of micropile performance, Zhang et al [17] carried out in situ static load tests to evaluate the resistance to uplift of micropiles in soft red clay substrates. Their findings indicate that micropiles can notably enhance pullout resistance and effectively control foundation uplift deformation.…”

Section: Introductionmentioning

confidence: 99%

Horizontal and Uplift Bearing Characteristics of a Cast-In-Place Micropile Group Foundation in a Plateau Mountainous Area

Li,

Ren

2023

Sustainability

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Micropile groups have been progressively more frequently adopted in the construction of transmission tower bases due to their compact size and flexible construction advantages. However, the load-bearing characteristics and deformation mechanisms of micropile groups are complex, and the study of their coupling effects under combined loads remains unclear. Consequently, this paper presents a field static load test of micropile groups in a highland mountainous area. The analysis encompasses the axial force distribution and load-sharing ratio of micropiles. With a focus on micropile groups subjected to both uplift and horizontal combined loads, the coupled effects under different load combination ratios are examined using numerical simulation methods. The key findings are as follows: During the uplift loading process, the load distribution among individual piles is relatively uniform, with lower side friction resistance gradually coming into play to counterbalance the top load. The load–uplift displacement curve exhibits a steep characteristic, making it susceptible to sudden failure in practical engineering applications. Under the simultaneous action of uplift (V) and horizontal (H) loads, the unbalanced lateral frictional resistance on both sides of the pile segment induces additional bending moments, which is an important part affecting the load-coupling mechanisms. The uplift resistance capacity of micropile groups decreases with an increase in horizontal load, while the horizontal load-carrying capacity initially decreases and then increases with an increase in uplift load. The space enclosed by the yield envelope under combined load, and the vertical line of the ultimate load, is divided into a ‘failure zone’ and a ‘safety zone.’ In the design of the pile foundation, the uplift bearing capacity reduced by the ‘failure zone’ should be taken into account.

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Identification and susceptibility assessment of landslide disasters in the red bed formation along the Nanjian-Jingdong Expressway

Cao,

Zhao,

Wen

et al. 2025

Ecological Indicators

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Study on Anti-Uplift Effect of Micro-Steel-Pipe Pile on Red-Bedded Soft Rock Subgrade

Cited by 4 publications

References 35 publications

Mechanical Difference Analysis of Single-row and Double-row Side Piles in Stations by PBA Method Based on Model Test

Mechanical Difference Analysis of Single-row and Double-row Side Piles in Stations by PBA Method Based on Model Test

Horizontal and Uplift Bearing Characteristics of a Cast-In-Place Micropile Group Foundation in a Plateau Mountainous Area

Identification and susceptibility assessment of landslide disasters in the red bed formation along the Nanjian-Jingdong Expressway

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