In this research, the effect of the width/depth ratio (W/d) on sediment transport was demonstrated based on statistical analysis on a set of hydraulic variables, using regression analyses. Three sediment transport equations were modified to include a width/depth ratio. Two sediment transport relationships were developed, one for natural channels, and another for the laboratory flumes. The results show that the width/depth ratio has an important role in prediction of sediment transport, but the role is less important than the role of flow velocity, channel slope, and grain size. The trends from five sediment transport relationships show that the sediment transport decreases as W/d increases for natural channels and sediment transport increases as W/d increases for flumes.; A computational procedure was developed to examine the relationship between maximum sediment transport and the channel width/depth ratio. An investigation of the relationship between width/depth ratio and several different sediment transport relationships was then conducted. Examination of Engelund and Hansen (1967), Yang (1973) for sand and gravel, and Shen and Hung (1971) equations showed that the maximum sediment concentration occurred at a width/depth ratio value of 2, which almost never occurs in natural alluvial channel systems. A comparison was made between Duboys (1879) and Meyer-Peter and Müller (1948) with regime charts (USACE, 1994) for the 2-year recurrence interval discharge using a maximum sediment transport method. It was found that both of the sediment transport equations could be used for prediction of the regime (USACE, 1994) width/depth ratio. A range of width/depth ratio at maximum sediment transport was found to be 18 to 35 for channels with gravel.; For Demonstration Erosion Control (DEC) channels using regression Channel Evolution Model (CEM) relationships, the range of width/depth ratio was found to be 9.8 to 15.1 for channels with sand and top widths 50 m. A new method for stable channel design was developed by modifying the Copeland (1999) procedure. This new method uses Brownlie's (1981) sediment transport equation for sand and was compared with those of other investigators. Based on the results, it was found that this method could be used to design the cross-section geometry for non-cohesive alluvial charnels with low and high sediment concentration.
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机译:在这项研究中,使用回归分析,基于一组水力变量的统计分析,论证了宽/深比( W / d )对沉积物迁移的影响。修改了三个输沙方程,以包括宽度/深度比。建立了两种沉积物传输关系,一种是自然通道,另一种是实验室水槽。结果表明,宽深比在预测泥沙输移中起着重要作用,但作用不如流速,河道斜率和晶粒大小重要。五个沉积物输运关系的趋势表明,对于自然通道,沉积物输运随着 W / d 的增加而降低,对于水渠,沉积物输运随着 W / d 的增加而增加。开发了一种计算程序来检查最大输沙量与河道宽度/深度比之间的关系。然后研究了宽深比与几种不同的泥沙输送关系之间的关系。对Engelund和Hansen(1967),Yang(1973)的砂砾和Shen和Hung(1971)方程的检验表明,最大沉积物浓度出现在宽度/深度比值为2的情况下,而在自然冲积层中几乎从未发生过渠道系统。用最大沉积物输运方法比较了两年复发间隔排放的Duboys(1879)和Meyer-Peter andMüller(1948)的状态图(USACE,1994)。发现这两个沉积物迁移方程都可用于预测该政权(USACE,1994)宽深比。对于有砾石的河道,最大输沙量时的宽深比范围为18至35。对于使用回归通道演化模型(CEM)关系的演示侵蚀控制(DEC)通道,发现沙子和顶部宽度<50 m的通道的宽/深比范围为9.8至15.1。通过修改Copeland(1999)程序,开发了一种稳定通道设计的新方法。这种新方法使用了Brownlie(1981)的沙土输沙方程,并与其他研究者进行了比较。根据结果,发现该方法可用于设计低和高沉积物浓度的非粘性冲积通道的横截面几何形状。
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