Research on Stability of Transmission Tower Slopes with Different Slope Ratios Under Rainfall Conditions and Reinforcement Effects of Anti-Slide Piles

Research on Stability of Transmission Tower Slopes with Different Slope Ratios Under Rainfall Conditions and Reinforcement Effects of Anti-Slide Piles

With the extensive construction of high-voltage power grid projects in complex mountainous terrains, rainfall-induced slope instability poses a significant threat to the safety of transmission tower foundations. This study focuses on a power transmission and transformation project in Huizhou City, G...

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Bibliographic Details
Main Authors: Guoliang Huang, Xiaolong Huang, Caiyan Lin, Ji Shi, Xiongwu Tao, Jiaxiang Lin, Bingxiang Yuan
Format: Article
Language:English
Published: MDPI AG 2025-06-01
Series:Buildings
Subjects:
transmission tower foundation
slope stability
rainfall
anti-slide piles
numerical simulation
Online Access:https://www.mdpi.com/2075-5309/15/12/2066
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Summary:With the extensive construction of high-voltage power grid projects in complex mountainous terrains, rainfall-induced slope instability poses a significant threat to the safety of transmission tower foundations. This study focuses on a power transmission and transformation project in Huizhou City, Guangdong Province. Using MIDAS GTS NX 2019 (v1.2), an unsaturated seepage-mechanics coupling model was established to systematically investigate the influence of slope ratios (1:0.75, 1:1, and 1:1.25) on slope stability under rainfall conditions and the reinforcement effects of anti-slide piles. The results demonstrate that slope ratios significantly govern slope responses. For steep slopes (1:0.75), post-rainfall matrix suction loss reached 43.2%, peak displacement attained 74.49 mm, and the safety factor decreased by 12.5%. In contrast, gentle slopes (1:1.25) exhibited superior stability. Anti-slide piles effectively controlled displacement growth (≤9.15%), but pile bending moments increased markedly with steeper slope ratios, accompanied by a notable expansion of the plastic zone at the slope toe. The study reveals a destabilization mechanism characterized by “seepage–strength degradation–displacement synergy” and recommends engineering practices adopting slope ratios of 1:1–1:1.25, combined with anti-slide piles (spacing ≤ 1.5 m) and dynamic drainage measures. These findings provide critical guidance for the design of transmission tower slopes in mountainous regions.
ISSN:2075-5309

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