降雨作用下斜坡上沟壑形态演变的实验研究

Sustainability Pub Date : 2024-07-23 DOI:10.3390/su16156297
Wenbin Huang, Yongtao Wang, Shuai Shao, Xiangtian Xu, Yong Liu
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引用次数: 0

摘要

准确监测斜坡侵蚀褶皱发展全过程的形态和时空演变特征,对于规避依靠平均流速计算水动力参数的传统方法所固有的局限性至关重要。本研究采用环境试验室和自主研发的边坡侵蚀试验装置,对不同坡度和降雨强度的边坡进行侵蚀试验。通过综合运用结构-运动(SfM)法、固定网格坐标法、连续摄像结合染料示踪技术,精确计算了整个褶皱发育过程的形态指标和水动力参数。主要结论如下坡面褶皱发育的全过程可分为三个不同的阶段。初始阶段的特点是出现轻微侵蚀的微小褶皱。中期阶段包括严重的横向扩展侵蚀和纵向下切,从而形成多种多样的褶皱形态。最后阶段的特点是形态特征趋于稳定。坡面土壤流失的高峰期出现在褶皱发展的中期阶段。从开始到结束,表征坡面土壤流失最有效的参数是雷诺数和流动剪应力、弗劳德数和流动剪应力以及不同时期的弗劳德数。在整个褶皱发展过程中,流速从最初的减小到逐渐增大,直至稳定。形态指标,包括褶皱密度、剖面度、倾斜度和复杂程度,总体上呈上升趋势。然而,在中期阶段,上升速度放缓,随后在某些点急剧上升。在评估不同坡度的径流密度时,发现最佳的水力参数是达西-韦斯巴赫阻力系数和实时流速;在评估径流剖面程度、复杂程度和倾斜度时,发现最佳的水力参数是雷诺数和流量功率。在不同的降雨强度下,对评估辙迹密度、断裂程度和倾斜度最有效的水力和动力学参数是水流切应力和雷诺数;对评估辙迹复杂程度最有效的参数是雷诺数和水流功率。这项研究成果提高了陡坡侵蚀试验中水动力参数计算的准确性,能够精确预测斜坡上陡坡的发展趋势,并为陡坡形态和特征的实时动态监测提供了创新方法。这些进展对水土保持和可持续发展具有重要意义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
An Experimental Study of the Morphological Evolution of Rills on Slopes under Rainfall Action
Accurately monitoring the morphology and spatiotemporal evolution characteristics of the entire process of slope erosion rill development is essential to circumvent the limitations inherent in traditional methods that rely on average flow velocity for hydrodynamic parameter calculations. This study employs an environmental chamber and a self-developed slope erosion test device to perform erosion tests on slopes with varying gradients and rainfall intensities. By integrating the structure-from-motion (SfM) method, fixed grid coordinate method, and continuous camera combined with the dye tracer technique, the morphological indexes and hydrodynamic parameters of the entire rill development process are precisely computed. The main conclusions are as follows: The entire process of slope rill development can be divided into three distinct stages. The initial stage is characterized by the appearance of tiny rills with mild erosion. The middle stage involves severe transverse spreading erosion and longitudinal undercutting, resulting in diverse rill morphologies. The final stage is marked by the stabilization of morphological characteristics. The peak slope soil loss is observed during the middle stage of rill development. The most effective parameters for characterizing slope soil loss from the beginning to the end are the Reynolds number and flow shear stress, the Froude number and flow shear stress, and the Froude number during different periods. Throughout the development of rills, the flow velocity initially decreases and then gradually increases until it stabilizes. The morphological indexes, including rill density, dissected degree, inclination, and complexity, generally show an increasing trend. However, in the middle stage, the rate of increase slows down, followed by a sharp rise at certain points. The optimal hydraulic parameters for evaluating rill density across different slope gradients, which were found to be the Darcy–Weisbach drag coefficient and real-time flow velocity, for assessing rill dissected degree, complexity, and inclination, were the Reynolds number and flow power. Under varying rainfall intensities, the most effective hydraulic and kinetic parameters for evaluating rill density, dissected degree, and inclination were flow shear stress and Reynolds number; for assessing rill complexity, the Reynolds number and flow power were used. The findings of this research enhance the accuracy of hydrodynamic parameter calculations in rill erosion tests, enable precise prediction of rill development trends on slopes, and offer innovative approaches for real-time dynamic monitoring of rill morphology and characteristics. These advancements are of significant importance for soil and water conservation and sustainability.
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