Reduction of rainfall infiltration in soil slope using a controllable biocementation method

Xiaohua Pan , Jian Chu , Liang Cheng
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引用次数: 2

Abstract

Reasonable control of rainwater infiltration rate can ensure that soil slope will not fail due to rapid infiltration of rainwater in heavy rainfall, and at the same time, more rainwater can be infiltrated in light rainfall to meet the water demand of animals and plants. In this study, based on microbial-induced calcium carbonate precipitation (MICP) technique, a controllable bio-method for rainfall infiltration of soil slope was proposed. To have a comprehensive understanding the relationship among the rainwater infiltration control capacity, biocement treated soil permeability, slope angle and rainfall intensity, a series of physical modelling experiments of rainfall diversion on slopes with three types of soils and three slope angles were carried out in the presence of various rainfall intensities. Experimental results indicated that the proposed bio-method had the ability of controlling rainwater infiltration in term of varying rounds of biocement spraying treatment. In general, it was found that the rainwater infiltration decreases with the increase in slope angle and rainfall intensity. In the worst case of smallest slope angle (15°) and lightest rainfall intensity (n = 50 mm/h), more than 82.6%, 92.2% and 84.4% of rainwater were prevented from infiltration into the MICP treated natural sand, fine sand and medium sand, respectively, while the untreated soils were not able to prevent the rainwater infiltration at all. The corresponding maximum local uniaxial compressive strength for the MICP treated natural sand, fine sand and medium sand, respectively, were found to be 2.3 MPa, 2.0 MPa, 2.6 MPa, whereas the flexural stresses were 0.46 MPa, 0.33 MPa, 0.67 MPa, which could resist rainfall droplet impact force. Overall, the proposed bio-method showed good rainwater infiltration control capacity and high bearing strength against the impact of heavy rainfalls, suggesting a good potential to mitigate the rainfall-induced landslides.

可控生物胶结法减少土壤坡面降雨入渗
合理控制雨水入渗速率,可以保证土壤边坡在强降雨时不会因雨水快速入渗而失效,同时在弱降雨时可以渗透更多的雨水,满足动植物的用水需求。本研究基于微生物诱导碳酸钙沉淀(MICP)技术,提出了一种可控的土壤坡面降雨入渗生物方法。为了全面了解雨水入渗控制能力、生物水泥处理土壤渗透性、坡角和降雨强度之间的关系,在不同降雨强度的情况下,对三种土壤和三个坡角的坡面进行了一系列降雨导流的物理模拟实验。实验结果表明,在不同轮次的生物水泥喷洒处理中,所提出的生物方法具有控制雨水入渗的能力。总的来说,雨水入渗量随着坡角和降雨强度的增加而减少。在坡度角最小(15°)和降雨强度最轻(n=50mm/h)的最坏情况下,经MICP处理的天然砂、细砂和中砂分别阻止了82.6%、92.2%和84.4%以上的雨水入渗,而未经处理的土壤根本无法阻止雨水入渗。MICP处理的天然砂、细砂和中砂的相应最大局部单轴抗压强度分别为2.3MPa、2.0MPa和2.6MPa,而弯曲应力分别为0.46MPa、0.33MPa和0.67MPa,可以抵抗降雨液滴的冲击力。总体而言,所提出的生物方法显示出良好的雨水渗透控制能力和对暴雨影响的高承载力,表明其在缓解降雨引发的滑坡方面具有良好的潜力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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