Soil bioengineering using vegetation has been recognised as an environmentally friendly solution for shallow slope stabilisation. Plant transpiration induces suction in the soil, but its effects to slope stability are often ignored. This study investigates the influences of transpiration-induced suction and mechanical reinforcement of different root geometries (i.e., tap- and heart-shaped) to the slope stability subjected to an intense rainfall with an intensity of 70 mm/h (prototype scale; corresponding to a return period of 1000 years), via centrifuge modelling. New model roots that have scaled mechanical properties close to real roots were used to simulate transpiration-induced suction in the centrifuge. Transient seepage analyses were performed using SEEP/W to back-analyse the suction responses due to transpiration and rainfall. Subsequently, the back-analysed suction was used to assess the factor of safety of the slopes using SLOPE/W. It is revealed that heart-shaped roots provided greater stabilisation effects to a 60o clayey sand slope than tap-shaped roots. The heart-shaped roots induced higher suction, leading to 14% reduction of rainfall infiltration and 6% increase in shear strength. Although transpiration-induced suction in a 45o slope was reduced to zero after the rainfall, mechanical root reinforcement was found to be sufficient to maintain the slope stability.
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机译:使用植被的土壤生物工程已被认为是用于浅层边坡稳定的环保解决方案。植物的蒸腾作用引起土壤中的吸力,但其对边坡稳定性的影响通常被忽略。这项研究调查了蒸腾作用引起的吸力和不同根部几何形状(即拍打形和心形形)的机械加固对强度为70 mm / h(原型规模;对应于回收期为1000年)(通过离心建模)。具有与真实根接近的缩放机械特性的新模型根用于模拟离心机中蒸腾诱导的吸力。使用SEEP / W进行瞬态渗流分析,以对由于蒸腾作用和降雨引起的吸力响应进行反分析。随后,使用SLOPE / W,使用反向分析的吸力评估斜坡的安全系数。结果表明,心形根对60o黏性砂质边坡的稳定作用比轻敲形根大。心形根部引起较高的吸力,导致降雨入渗量减少14%,抗剪强度增加6%。尽管降雨后45o坡上的蒸腾作用引起的吸力降低到零,但发现机械根部加固足以维持坡度的稳定性。
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