明渠进水口沉积与流态的数值研究

Rana A. Al-Zubaidy, Ali N. Hilo
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摘要

明渠横向取水结构在水环境工程中应用广泛。侧进水口的通过流主要是包含垂直和水平螺旋流的湍流,造成泥沙问题。在引水过程中,进水口内的水流分离区对泥沙和水的分布至关重要。它表示侧向支流来水的可能宽度大大减小,以及泥沙聚集的地方,阻碍了偏流。本研究利用CFD、ANSYS Fluent软件模拟的三维数值模型,通过改善侧进水口的流态,减少和控制侧进水口的泥沙问题。通过前期的实验研究,验证了三维数值模型的正确性。采用不同的流量比和一系列形状设计来模拟进气通道连接处的流动模式。研究结果表明,随着放电比的增加,分离区测量值最小。根据改变进水口形状的结果,切割运河入口外边界拓宽了分离区域,并且随着切割尺寸的增加增加了额外的分离点。与进气道内倒角模型相比,分离区尺寸减小。在本研究中,减小分离程度的最佳设计为与主通道气流方向夹角为30°、与气流方向法向的倒角侧长度(c值)等于进气宽度的四分之三的倒角圆角内进气边缘模型。因此,在这种情况下,分离区宽度和长度的减小率分别达到90%和72%。
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Numerical Study of Sedimentation and Flow Pattern at the Open Channel Intake
Generally, open channel lateral intake structures are extensively used in the water and environmental projects. The passing flow at side intakes is mostly turbulence containing vertical and horizontal spiral currents causing sediment problems. The flow separation region in the intake channel is critical for sediment and water distribution during the diversion. It denotes a large reduction in the possible breadth of the lateral branch's incoming flow, as well as a place where sediment has collected, obstructing the deviated flow. This study aims to reduce and control sediment problems at the lateral intake by improving the flow pattern at this area using three-dimensional numerical models simulated in CFD, ANSYS Fluent software. The correctness of the three-dimensional numerical model was validated by a previous experimental study that showed good accuracy. Different discharge ratios and a range of shape designs were used to simulate the flow pattern at the intake channel junction. The findings demonstrated that the separation zone measurements minimize as the discharge ratio increases. Based on the changing the intake entrance shape results, cutting the outer boundary of the canal entrance widens the separation area, as well as an additional separation spot as the cutting size grows. In contrast with the internal chamfered angle models of the intake inlet, the separation area dimensions are reduced. The chamfered and rounded inner intake edge model with 30o angle to the main channel flow direction and the length of the chamfered side that normal to the flow direction (c value ) equal to three-quarters of the intake width was noticed to be the best design for lessening separation extent in this study. Thereby, the reduction ratio of the separation area width and length reaches in this case to 90% and 72%, respectively.
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