北戴河西海滩波浪动力与人工养护沙滩侵蚀原位监测研究

以北戴河西海滩为例,测量了养护后的海滩演变和波浪数据,估算了海滩侵蚀量及有效波高对岸滩侵蚀的贡献度。结果表明,养滩后海滩整体呈侵蚀趋势,最大侵蚀高度达到1.7 m。有效波高对海滩侵蚀量的累积影响呈指数分布。重现频数较低的大波浪(有效波高>0.6 m)作用虽能引起更大的海滩侵蚀,但是对岸滩总侵蚀量的累积贡献仅为25%,而波高为0.3~0.6 m的中小波浪贡献度可达75%。该研究可为维护人工海滩质量和养后海滩演变预测提供参考。

大跨度泵站多人字型前池导流墩整流分析

针对浙石化4×10^7t/年炼化取水口北区循环水泵房大跨度前池存在的主流集中、流速大、出现回流区、流道进水不均等问题,提出“多人字型”组合前池导流墩方案,并基于N-S方程、标准κ-ε湍流模型、重力相似准则,对“多人字型”组合导流墩方案进行数值模拟和物理模型试验研究。结果表明,“多人字型”组合导流墩方案起到了分散水流、降低主流流速、减少前池回流区域和回流流速大小的作用,为同类型大跨度直角进水前池的整治提供了依据。

黄河口近60年来潮流特征演化过程

本文利用1962年、1986年以及2015年的三个典型年代的实测资料建立黄河口数学模型,并对河口潮流场和潮流特征进行模拟,借用MATLAB软件进行分潮调和分析,得到黄河口近60年潮流特征以及各个阶段的潮流演化过程,得出以下结论:(1) 1962年河口流场较为平整,有明显切变锋形态,该阶段存在两个较为明显的高流速区并且潮流在河口处呈现为往复流;(2) 1986年黄河三角洲岸线曲折多拐,从湾湾沟到清水沟滋生了多个小型高流速区群,并且潮流在滨海处呈现往复流的形态而在远海处为旋转流;(3) 2015年涨落潮时潮流在河口处形成明显的环流,此时在沿线凸出沙嘴处会形成3个明显的高流速区,并且潮流在大部分区域呈现旋转流而在河口东北向远海处部分区域呈现往复流的特征。

复式航道波浪变形及输沙影响数值模拟研究

复式航道通过在原有深水主航道两侧开挖并行浅水航道,实行大小船舶分道航行,高效缓解进港航道通航压力,具有广泛的应用前景。由于航道断面复式化,波浪穿越航道的演变规律比传统单一断面复杂,影响船舶通航安全及泥沙输运。基于天津港复式航道工况,建立数值波浪水槽,针对正交入射波浪在不同断面型式复式航道中的演变进行数值模拟,研究结果表明:开挖小航道后,开挖处波高增大,主航道内波高基本不变;随着小航道宽度减小和航道过渡段坡度减小,复式航道内波高增大;航道水深比和波浪要素对波高演变存在耦合影响。主航道内床面上的波浪边界层切应力为小航道的68.5%,小航道能够拦蓄部分浮泥和推移质泥沙,减轻主航道淤积。

圆管有压流输沙与泥沙垂向分选特性试验研究

管道输沙是实现黄河水沙资源重分配的有效手段之一,广泛用于水库泄洪排沙、河道疏浚及滩区淤沙等工程。以黄河流域水库高含沙隧洞和管道输沙为工程背景,设计了循环管道输沙试验系统,以d_(50)=107μm的黄河细沙为试验材料,研究有压封闭环境下不同含沙浓度引起的断面流速、泥沙浓度垂向分布等物理量的变化,并采用Malvern3000粒度分析仪对分层泥沙样品进行颗粒分析,探讨泥沙垂向分选特性。试验结果表明:泥沙的存在会改变清水流场分布,小流量工况的水动力较弱,含沙浓度的增加引起断面流速分布不对称,垂向泥沙颗粒出现明显分层;随着流量增大,流速不对称性有所降低,含沙浓度沿垂向趋近均匀分布,泥沙分选效果减弱。

高含沙水流与泥沙异重流之间分界线的确定方法

泥沙淤积影响水库寿命和河口正常运行,而异重流排沙是减少库区淤积与河口淤积的重要措施之一。异重流形成的直观表象之一是泥沙浓度分布特征的转变,即泥沙浑水区与异重流区之间应存在划分两种泥沙浓度分布特征的分界线,研究分界线的分布形式有助于掌握异重流的演进规律。根据泥沙浓度公式及异重流下潜后的泥沙浓度分布特征,导出了泥沙浑水区与异重流区分界线的解析表达式,由连续性条件确定分界线起始点位置,并采用多组实验数据资料对理论模型进行了验证。

海口湾东部海域淤积趋势机制分析

海口湾东部是南渡江西北新三角洲受水受沙盆地,一直以来是典型的淤积海域。通过历史卫星影像分析海口湾东部浅滩的沉积过程,研究不同时间的湾内表层沉积物分布规律,采用遥感和实测悬浮颗粒物数据认知悬移质泥沙运动规律,借助沉积物粒径趋势分析推移质泥沙运动规律,对海口湾东部海域淤积趋势以及机制进行宏观分析。结果表明:海口湾东部浅滩的多个沙坝生成于不同的围海填地阶段;人类活动建造的向湾内伸突的人工构筑物,减弱了海口湾东部浅滩的潮流和波浪作用,进而导致泥沙在“葫芦岛项目”东部和南部海域沉积。了解海口湾东部海域泥沙运动规律以及海域淤积机制,是解决该海域淤积问题的基础。

河岸陡峭度对冲积河流平衡河道形态的影响

河岸抗冲性对河流横断面形态影响显著。以水力半径分割方法为基础,采用等腰梯形过水断面,以河岸陡峭度代表河岸的抗冲性,利用变分方法研究冲积河流达到平衡状态时,河岸抗冲性对河道横断面形态以及输沙能力的影响。研究结果表明:河岸陡峭程度减缓时,平衡河道形态变得宽浅,相反变得窄深;河岸陡峭度变化对水力几何形态关系式中的相关变量指数几乎没有影响,仅仅影响水力几何形态关系式中的系数。随着河岸陡峭度增加,河流达到平衡状态时横断面形态变得窄深,河道最大输沙率增大。

A Novel Wake Oscillator Model for Vortex-Induced Vibrations Prediction of A Cylinder Considering the Influence of Reynolds Number

It is well known that the Reynolds number has a significant effect on the vortex-induced vibrations(VIV) of cylinders. In this paper, a novel in-line(IL) and cross-flow(CF) coupling VIV prediction model for circular cylinders has been proposed, in which the influence of the Reynolds number was comprehensively considered. The Strouhal number linked with the vortex shedding frequency was calculated through a function of the Reynolds number. The coefficient of the mean drag force was fitted as a new piecewise function of the Reynolds number, and its amplification resulted from the CF VIV was also taken into account. The oscillating drag and lift forces were modelled with classical van der Pol wake oscillators and their empirical parameters were determined based on the lock-in boundaries and the peak-amplitude formulas. A new peak-amplitude formula for the IL VIV was developed under the resonance condition with respect to the mass-damping ratio and the Reynolds number. When compared with the results from the experiments and some other prediction models, the present model could give good estimations on the vibration amplitudes and frequencies of the VIV both for elastically-mounted rigid and long flexible cylinders. The present model considering the influence of the Reynolds number could generally provide better results than that neglecting the effect of the Reynolds number.

NUMERICAL SIMULATION OF TWO-DIMENSIONAL DAM-BREAK FLOWS IN CURVED CHANNELS

Two-dimensional transient dam-break flows in a river with bends were theoretically studied. The river was modeled as a curved channel with a constant width and a flat bottom. The water was assumed to be an incompressible and homogeneous fluid. A channel-fitted orthogonal curvilinear coordinate system was established and the corresponding two-dimensional shallow-water equations were derived for this system. The governing equations with well-posed initial and boundary conditions were numerically solved in a rectangular domain by use of the Godunov-type finite-difference scheme, which can capture the hydraulic jump of dam-break flows. The comparison between the obtained numerical results and the experimental data of Miller and Chaudry in a semicircle channel shows the validity of the present numerical scheme. The mathematical model and the numerical method were applied to the dam-break flows in channels with various curvatures. Based on the numerical results, the influence of river curvatures on the dam-break flows was analyzed in details.