Experimental analysis of flow and turbulence in the wake of neighboring emergent vegetation patches with different densities

Environmental Fluid Mechanics - Patches of vegetation in natural water bodies grow close to each other and may affect each other’s wake pattern with significant implications on nutrient...     

Experimental surface flow visualization and numerical investigation of flow structure around an oblong stockpile

Emission factors are largely used to quantify particle emissions from industrial open storage piles. These factors are based on the knowledge of velocity distribution and flow patterns over the stockpile surface which still requires further research. The aim of the present work is to investigate the airflow characteristics over a single typical oblong pile and in its near-ground surroundings for various wind flow directions. Wind tunnel experiments using an oil-film surface coating technique were carried out for near-wall flow visualization. Numerical simulation results, favorably compared to PIV measurements, were used to allow comparison analysis of flow features. For the stockpile oriented 90° to the wind main direction, typical topology of flow around wall-mounted obstacles were observed, notably a wake zone downstream the pile including two main counter-rotating vortices. Further analysis of numerical wall shear stress distribution and streamlines indicates that two complex three-dimensional vortical flow structures develop downstream the pile. For other incoming wind flow directions (30 and 60°), the flow characteristics over the storage pile greatly differ as a single helical main vortex develops from the pile’s crest. Corresponding high values of wall shear stress are noticed downstream the storage pile. For each configuration studied, downwash and upwash zones are induced by the vortical structures developed. This near-wall flow topology combined with areas of high friction levels may be linked to potential dust emission from the ground surface surrounding industrial stockpiles.     

Experimental investigation of channel flow through idealized isolated tree-like vegetation

Environmental Fluid Mechanics - Riparian and floodplain tree-like emergent vegetation alter significantly the flow field and lead to complicated three-dimensional flow patterns, characterized by...     

华南红壤坡面侵蚀水动力学机制试验研究

华南红壤区是我国发生潜在水土流失危害的重点区域之一,红壤坡地的水土流失现象较为严重。华南红壤地区气候温暖,雨量丰沛,降雨特点通常表现为强度大、历时长,暴雨或大暴雨事件频发,因此暴雨驱动因子影响作用更为显著,研究探讨华南红壤坡面侵蚀过程及动力特征有着重要的现实意义。通过室内35场不同雨强（30、60、90、120、180、210、270 mm·h-1）、不同坡度（5°、10°、15°、20°、25°）的人工模拟降雨试验,研究了华南红壤侵蚀的水动力学机制。主要取得以下研究结果：（1）红壤坡面侵蚀水流的流态大部分均处于＂层流—缓流区＂,除平均流速随着模拟雨强的增加而增加外,其他水动力参数（坡面侵蚀水流的阻力、曼宁糙率、径流剪切力、以及水流功）均会受到雨强和坡度改变的影响,但是不呈现特定的函数关系,规律不明显;（2）从水动力学角度解析了红壤坡面水蚀过程,得出了相对水深和曼宁糙率系数两种水动力因子共同组成的复合水动力特征参数,可作为表征不同雨强及坡度下的坡面水蚀侵蚀产沙的特征水动力参数指标。     

农业生态系统能流分析中几个问题的探讨

本文就目前广泛应用的农业生态系统能流分析方法及有关概念作了分析，提出了辅助能替代率的概念。建议用辅助能替代率代替能量产投比对农业生态系统进行能流分析。文中还讨论了工业辅助能的计算及其在不同系统间或同一系统不同时段的可比性。     

Exchange flow between open water and floating vegetation

This study describes the exchange flow between a region with open water and a region with a partial-depth porous obstruction, which represents the thermally-driven exchange that occurs between open water and floating vegetation. The partial-depth porous obstruction represents the root layer, which does not penetrate to the bed. Initially, a vertical wall separates the two regions, with fluid of higher density in the obstructed region and fluid of lower density in the open region. This density difference represents the influence of differential solar heating due to shading by the vegetation. For a range of root density and root depths, the velocity distribution is measured in the lab using PIV. When the vertical wall is removed, the less dense water flows into the obstructed region at the surface. This surface flow bifurcates into two layers, one flowing directly through the root layer and one flowing beneath the root layer. A flow directed out of the vegetated region occurs at the bed. A model is developed that predicts the flow rates within each layer based on energy considerations. The experiments and model together suggest that at time- and length-scales relevant to the field, the flow structure for any root layer porosity approaches that of a fully blocked layer, for which the exchange flow occurs only beneath the root layer.     

Three-dimensional analysis of coherent turbulent flow structure around a single circular bridge pier

The coherent turbulent flow around a single circular bridge pier and its effects on the bed scouring pattern is investigated in this study. The coherent turbulent flow and associated shear stresses play a major role in sediment entrainment from the bed particularly around a bridge pier where complex vortex structures exist. The conventional two-dimensional quadrant analysis of the bursting process is unable to define sediment entrainment, particularly where fully three-dimensional flow structures exist. In this paper, three-dimensional octant analysis was used to improve understanding of the role of bursting events in the process of particle entrainment. In this study, the three-dimensional velocity of flow was measured at 102 points near the bed of an open channel using an Acoustic Doppler Velocity meter (Micro-ADV). The pattern of bed scouring was measured during the experiment. The velocity data were analysed using the Markov process to investigate the sequential occurrence of bursting events and to determine the transition probability of the bursting events. The results showed that external sweep and internal ejection events were an effective mechanism for sediment entrainment around a single circular bridge pier. The results are useful in understanding scour patterns around bridge piers.     

Experimental and numerical analysis of flow instabilities in rectangular shallow basins

Free surface flows in several shallow rectangular basins have been analyzed experimentally, numerically and theoretically. Different geometries, characterized by different widths and lengths, are considered as well as different hydraulic conditions. First, the results of a series of experimental tests are briefly depicted. They reveal that, under clearly identified hydraulic and geometrical conditions, the flow pattern is found to become non-symmetric, in spite of the symmetrical inflow conditions, outflow conditions and geometry of the basin. This non-symmetric motion results from the growth of small disturbances actually present in the experimental initial and boundary conditions. Second, numerical simulations are conducted based on a depth-averaged approach and a finite volume scheme. The simulation results reproduce the global pattern of the flow observed experimentally and succeed in predicting the stability or instability of a symmetric flow pattern for all tested configurations. Finally, an analytical study provides mathematical insights into the conditions under which the symmetric flow pattern becomes unstable and clarifies the governing physical processes.     

Interaction between flow, transport and vegetation spatial structure

This paper summarizes recent advances in vegetation hydrodynamics and uses the new concepts to explore not only how vegetation impacts flow and transport, but also how flow feedbacks can influence vegetation spatial structure. Sparse and dense submerged canopies are defined based on the relative contribution of turbulent stress and canopy drag to the momentum balance. In sparse canopies turbulent stress remains elevated within the canopy and suspended sediment concentration is comparable to that in unvegetated regions. In dense canopies turbulent stress is reduced by canopy drag and suspended sediment concentration is also reduced. Further, for dense canopies, the length-scale of turbulence penetration into the canopy, δ _e , is shown to predict both the roughness height and the displacement height of the overflow profile. In a second case study, the relation between flow speed and spatial structure of a seagrass meadow gives insight into the stability of different spatial structures, defined by the area fraction covered by vegetation. In the last case study, a momentum balance suggests that in natural channels the total resistance is set predominantly by the area fraction occupied by vegetation, called the blockage factor, with little direct dependence on the specific canopy morphology.     

Experimental study of a positive surge. Part 2: comparison with literature theories and unsteady flow field analysis

A positive surge is a unsteady open channel flow resulting from the rapid rise of the free-surface. The phenomenon may be observed in water supply canals and channels as well as in some estuaries during spring tidal conditions. The formation and development of positive surges can be predicted using the method of characteristics and shallow water equations. The paper is the second part of a study presenting the results from new experimental investigations conducted in a large rectangular channel. Detailed unsteady velocity measurements were performed with a high temporal resolution using acoustic Doppler velocimetry and non-intrusive free-surface measurement devices. Several experiments were conducted with the same initial discharge (Q = 0.060 m³/s) and six different gate openings after closure resulting in both non-breaking undular and breaking bores. A comparison between main features of the undular surges with literature theories demonstrated that the experimental data were mostly in agreement with Andersen’s theory. The analysis of unsteady flow field including Reynolds stresses confirmed and extended previous findings about positive surge hydrodynamics.     

Experimental study on the discharge characteristics of viscous debris flow with grid-type dam

Environmental Fluid Mechanics - Experimental tests were conducted on a rectangular flume with different grid-type dam grid sizes, channel slopes and debris flow bulk density. We use the Bernoulli...     

Collection and analysis of baseline vegetation data

Vegetation baseline studies are dependent on the use of an adequate classification of vegetation, which structures all further study. The reliable and careful execution of sampling techniques is as important as choosing a sound sampling scheme. In order for vegetation mapping to represent the vegetation accurately, significant community gradation and anomalous communities should be portrayed. Data analysis should distinguish between precision and accuracy, include an indication of the statistical reliability of estimates, and explain and interpret findings.     

Numerical simulation and optimization study of surface pressure and flow field around a triangular prism behind a porous fence

Environmental Fluid Mechanics - The flow structure around upright porous fences and a triangular prism was numerically investigated by using the RNG k-ε turbulence model. The numerical method...     

垂直潜流人工湿地净化北方微污染水体试验研究

为研究垂直潜流人工湿地对北方微污染水体中COD、氮和磷的去除效果及去除机理,在室内选用混合土(由炉渣与种植土按比例混合而成)、石英砂和陶粒作为填料,以天津当地常见植物黄花鸢尾为植被构建了垂直潜流人工湿地处理微污染景观湖水和雨季的初期雨水;除冬季冰封期暂停运行外,通过对系统不同季节运行数据的分析,考察了不同季节环境条件下垂直潜流人工湿地对我国北方城市微污染水体的净化效果及影响因素。结果表明:不同季节条件下,该系统对污染物均有着良好的去除效果和抗冲击负荷能力。微污染景观水和雨季初期雨水经垂直潜流人工湿地系统处理后,出水COD、NH4+-N及TP的质量浓度可分别优于GB 3838—2002《地表水环境质量标准》的IV类、III类和II类水质标准(研究阶段进水TP≤0.80 mg·L-1),COD、NH4+-N和TP的阶段平均去除率最高可分别达80%、91%和82%;TN的去除效果受季节变化波动较大,阶段平均去除率在32%~78%,温度较低季节或原水水质较差时有待处理水回流或辅加其他技术手段以提高脱氮效果。垂直潜流人工湿地对北方微污染水体有着较好的净化效果,能够有效地预防地表水体富营养化的发生,有利于城市水环境质量的改善和水资源的循环利用,具有良好的发展应用前景。     

草莓在有机与无机种植系统中的能流和经济效益的比较

本文运用了生态经济学的原理，对草莓在有机和无机种植系统内能量流动、物质转化以及经济效益进行了比较研究。结果表明：两处理区施用几乎相同氮量的有机肥（１７５ｋｇ／ｈｍ￣２）和无机肥（１６４ｋｇ／ｈｍ￣２），其有机区草莓的生长发育、产量均明显好于无机处理区；有机草莓的光能利用率和氮素产出／投入分别比无机草莓提高了６４．２４％和５７．７２％；同时证明，优质有机肥可改善草莓的良用品质，并提高经济效益。     

城市化地区植被生态环境效应研究

城市植被具有其它生态环境要素难以替代的多样化生态服务功能,城市化地区的植被生态环境效应研究是一个具有重要理论和实践意义的研究课题。国内外该领域的研究已经形成一系列特色鲜明的研究方向,几个重要研究范畴中,城市化过程对植被影响研究属于传统的理论兼应用研究范畴,从景观生态学视角入手,注重残遗植被保护等是该领域近年来的新研究方向;城市植被生态服务功能研究是目前研究工作积累最为丰富的热点领域,重点研究方向包括负面生态环境效应缓冲与还原、自然环境调控、生物多样性保护以及城市碳氧平衡等;比较而言,城市植被保护与管理研究相对薄弱,亟待加强。总结国内外现有研究工作可以看出,城市化地区的植被生态效应研究存在着一定程度的理论研究与应用研究脱节,专业研究与综合研究脱节,微观研究与宏观研究脱节等不合理现象,应当成为今后研究工作中重点关注并加以克服的问题。     

The role of increasing riverbank vegetation density on flow dynamics across an asymmetrical channel

Environmental Fluid Mechanics - Over the last two decades, the role of vegetation in the environmental and ecological restoration of surface water bodies has received much attention. In this...     

The role of rooted emergent vegetation on periodically thermal-driven flow over a sloping bottom

Thermal-driven flow is generated due to topographic or vegetation-shading effects. Asymptotic solutions by assuming a small bottom slope are derived to discuss effects of rooted emergent vegetation and interactions between emergent vegetation and sloping topography on thermal-driven flow during diurnal heating and cooling cycles. The results show that the zero-order horizontal velocity is significantly reduced by vegetative drag, and the time lag between the change of horizontal velocity and the reversal of pressure gradient is also shortened. The solutions reveal that the viscous effect is dominant in very shallow water, and the drag force becomes important as the water depth increases. The inertial term is only important at the very beginning stage of flow initiation. Different vegetation distributions can significantly change the temperature fields that then affect patterns of thermal-driven circulation and exchange flowrates. For the case of tall vegetation growth in shallow water, and when the deep water side is open, the effects of vegetation shading may interfere with the topographic effects and dramatically alter the flow patterns. The blockage of solar radiation due to vegetation shading can determine the patterns and magnitude of thermal-driven flow. By means of the derived asymptotic horizontal velocity, exchange flow rates can be estimated, which are in good agreement with previous studies. The limitation and valid ranges of asymptotic solutions are finally discussed.