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Journal of hydraulic engineering
American Society of Civil Engineers
Journal of hydraulic engineering

American Society of Civil Engineers

月刊

0733-9429

Journal of hydraulic engineering/Journal Journal of hydraulic engineeringSCI
正式出版
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    Void Fraction Distribution Downstream of Nonlinear Weirs: An Experimental Investigation Using Trapezoidal A-Type Piano Key Weirs, a Labyrinth Weir, and a Linear Weir

    Biruk S. BelayMario Oertel
    1.1-1.14页
    查看更多>>摘要:Abstract This experimental study investigates the behavior of void fraction distribution downstream of nonlinear weirs. Systematic air concentration measurements were performed in a 3D array for two model pairs: (1) a piano key weir and a labyrinth weir, and (2) a piano key weir and a reference linear weir. For the labyrinth and piano key weirs tested herein, the results revealed a significant variation of depth-averaged void fraction within the channel cross-section. Under limited tailwater conditions, interaction of spreading plunging jet shockwaves from the inlet keys remained significant, leading to higher void fractions along the adjacent outlet keys due to the formation of standing waves. However, this cross-sectional variation is moderated as the effect of plunging jets reduces with increasing tailwater depth. Alignment of an inlet key with the sidewall also induced standing waves that further contributed to the lateral variability of air concentrations. The findings further indicated that the labyrinth weir yields higher void fraction compared to the piano key weir under similar hydraulic conditions, highlighting the role of weir type and geometry. Additionally, 3D surfaces and contour profiles of depth-averaged void fraction were derived using high-resolution measurements downstream of the second model pair that showed substantial differences between nonlinear and linear weirs. Furthermore, a simplified relationship was established using the upstream and downstream flow depths to parameterize the behavior of the depth-averaged void fraction. Exponential detrainment trends were observed in all cases along the flow, and classic depth-concentration profiles were found to replicate the observations in these experiments.
      原文链接:
    • NETL
    • NSTL
    • Asce-Amer Soc Civil Engineers

    Effects of Nappe Collision on Piano Key Weir Discharge Efficiency

    Xiaoyang ShenMario Oertel
    1.1-1.6页
    查看更多>>摘要:Abstract The nappe collision within the outlet sections of a piano key weir (PKW) induces localized submergence, causing a decrease in overall weir efficiency. The present study assesses the impact of interactive nappe collision on the hydraulic performance of individual crest segments by testing irregular trapezoidal and rectangular PKW configurations with varying outlet section widths. Results reveal that the nappe over upstream apex is the dominant factor impeding lateral outflow and therefore limiting the overall weir efficiency. Lateral nappe collision between adjacent side walls appear to exert notable impact only when the upstream head reaches a certain threshold correlated with the planform geometry. Notably, the upstream apex itself remains unaffected by submergence for the entire tested range, exhibiting equivalent head-discharge relationship to vertical linear weir featuring the same crest. Therefore, the upstream apex of a PKW can be considered an independent component for which efficiency can be properly estimated using equations derived from similar crested classic linear weirs.
      原文链接:
    • NETL
    • NSTL
    • Asce-Amer Soc Civil Engineers

    Flow Constrictions and Fish Behavior: Unraveling Undulatory Swimming Strategies in Accelerating Flow

    Yuqian XiWenqi LiChendi ZhangShikang Liu...
    1.1-1.14页
    查看更多>>摘要:Abstract Section contractions in rivers often induce accelerated flows in nature, exerting substantial influence on the swimming behaviors of various fish species. This study focuses on the undulatory swimming strategies of fishes and the effects of hydrodynamics on the swimming behavior in a flume with constriction. By using a combination of computational fluid dynamics (CFD) modeling, convolutional neural network (CNN), and observation of fish behavior with kinematic and morpho-kinematic parameters, we investigate how fish select their swimming strategies when encountering complex flow conditions. The results reveal that fish exhibit distinct swimming behaviors in response to accelerating flows, including avoidance behavior, drifting with the flow, and escaping upstream. Fish demonstrate a preference for swimming on one side of the flume, with the side bank of the adaptation region being the most favored location due to the lower flow velocity and thigmotactic behavior. Additionally, we identify three swimming gaits employed by the fish to navigate complex river environments, adjusting their swimming behavior based on environmental cues. This study highlights the significance of both head and tail characteristics in governing fish swimming behavior, with head features crucial for perceiving the environment and tail movements directly influencing swimming speed and maneuverability.
      原文链接:
    • NETL
    • NSTL
    • Asce-Amer Soc Civil Engineers

    Air Demand and Flow Patterns of Low-Level Outlets: Accounting for Wall Roughness

    Simone PagliaraStefan FelderBenjamin HohermuthRobert Michael Boes...
    1.1-1.15页
    查看更多>>摘要:Abstract Low-level outlets (LLOs) are key safety elements of high-head dams, typically consisting of a pressurized inflow controlled by a vertical sluice gate that discharges into a free-surface flow tunnel. The transition from pressurized to free-surface flow generates a high-velocity water jet with considerable air entrainment and transport along the tunnel, resulting in subatmospheric pressures downstream of the gate. These conditions potentially aggravate serious safety issues such as cavitation, gate vibration, and, in combination with sediment transport, hydroabrasion. Sufficient air supply can mitigate these problems. Several empirical equations have been developed to predict the air demand of LLOs, incorporating the effects of flow patterns, air vent loss coefficient, and tunnel geometry. However, reported model and prototype air demand data scatter over one order of magnitude, with tunnel roughness identified as a potential reason for these differences. To date, the influence of wall roughness on the performance of LLOs has not been systematically investigated. In this study, physical model tests were conducted with varying wall roughness, representing finished concrete, abraded concrete, and unlined rock at prototype scale. The results showed a significant increase in the air-water mixture flow depth with increasing wall roughness, where excessive filling of the tunnel may trigger foamy flow, flow choking, and the formation of hydraulic jumps, resulting in severe degradation of LLO performance. Increased wall roughness also led to a higher air demand, suggesting a predominant effect of the invert roughness over the wall and soffit roughness. A novel empirical equation was derived for air demand, incorporating the effects of tunnel roughness. The equation showed good agreement with previous laboratory and prototype data, indicating that other design parameters were not affected by the tunnel roughness. Finally, design recommendations were updated to account for roughness effects in LLO design, thereby contributing toward a safer design of these structures.
      原文链接:
    • NETL
    • NSTL
    • Asce-Amer Soc Civil Engineers

    Review of Fluvial Hydrodynamics: Hydrodynamic and Sediment Transport Phenomena, 2nd Edition by Subhasish Dey

    Michele Palermo
    1.1-1.2页
      原文链接:
    • NETL
    • NSTL
    • Asce-Amer Soc Civil Engineers

    Discussion of “Nikuradse Roughness Height Derived from a Physically Based Model Applied to a River Channel with Dunes”

    Jie QinQiran LiTeng Wu
    1.1-1.3页
      原文链接:
    • NETL
    • NSTL
    • Asce-Amer Soc Civil Engineers

    Variational Mechanics Formulation for Stream Meander Mechanics under Stable State End Conditions

    Ranjan S. MuttiahPeter Allen
    1.1-1.14页
    查看更多>>摘要:Abstract A mechanical analog formulation for distributed vibrating systems is used to derive a relationship between the fundamental meander frequency (cycling/s) and stream flow parameters mass per unit length and stream length. Cycling frequency is estimated from the number of peak–peak lateral migrations divided by the travel time of a bank-full 2-year return flow flood wave and implemented in an arcpy/python routine in the ArcGIS-pro environment. The peak–peak meander cycling of a sample of first- and second-order and higher streams in the Brazos River basin were analyzed for traction force generated by the associated bank-full flows. The bank-full celerity was determined from historical 2-year return flows obtained from the United States Geological Survey gauging points in the Central Texas region. Bed and bank normal and shear stresses due to flow traction force were estimated for submeter depths and compared against measured values from undrained and drained shear tests. Estimated traction forces in the studied first-order streams primarily caused surficial erosion rather than structural failure. On the other hand, traction forces in second-order and higher streams were high enough to contribute to structural failure of stream banks. Pore-water pressures that reduce the shear strength of soils are likely to contribute to added bed and bank failure modes of second- and higher-order streams. It was found that second-order and higher streams had evolved to shallower slopes compared to their initial meander onset stages.
      原文链接:
    • NETL
    • NSTL
    • Asce-Amer Soc Civil Engineers

    Scour Control through Bed Soil Stabilization Using Slag-Based Alkali-Activated Cement

    Abbas Ghaedi HaghighiAmir Reza ZarratiMojtaba Karimaei TabarestaniSeyed Mohammad Fattahi...
    1.1-1.11页
    查看更多>>摘要:Abstract An innovative approach to control scouring by stabilizing bed sediments using slag-based alkali-activated cement is presented. This method is economical, environmentally friendly, and easily implementable. Many experiments were conducted with various percentages of granular-ground-blast-furnace-slag (GGBFS). Results demonstrated that activated GGBFS is very efficient in stabilizing the bed sediment. For example, 9 wt.% GGBFS activated by 12.5 wt.% sodium hydroxide alkaline with a concentration of two molarities, after 7 days of curing, led to 110 times increase in critical shear stress of the stream bed. Furthermore, unconfined compressive strength tests were performed, revealing a linear relationship between the critical shear stress of treated bed sediments and their unconfined compressive strength. Additionally, the permeability of treated bed sediments was measured and was near the original granular sediments. Microstructure analysis experiments such as x-ray diffraction analysis, microscopic imaging, and scanning electron microscopy showed that the dominant product shaping the treated sediments is the calcium–aluminum–silicate–hydrate gel produced by the slag-based alkaline-activated cement.
      原文链接:
    • NETL
    • NSTL
    • Asce-Amer Soc Civil Engineers

    Prevention of Bedload Transport in a Lateral Water Intake by a Guiding Structure in a Mountain River

    Jakob SiederslebenMarco SchusterMarkus AuflegerStefan Achleitner...
    1.1-1.13页
    查看更多>>摘要:Abstract A lateral intake withdraws water from the Lech River, a mountain river characterized by high bedload and coarse substrate, to supply a hydropower plant. The water intake features a flushing channel that experiences sedimentation several times a year. Hydraulic sediment removal from the riverbed upstream of the facility and the flushing channel requires a drawdown of the backwater level, resulting in economic losses for operators and reduced green energy production. Therefore, it is essential to prevent sediment aggradation in the flushing channel and the intake of the hydropower plant. Physical model tests with geometric scales of 1:25 and 1:15, respecting Froude similarity, were conducted to explore different sediment guiding structures with objectives to (1) prevent bedload deposition in the flushing channel and bedload transport in the intake of the hydropower plant, (2) enable efficient hydraulic sediment removal from the flushing channel, and (3) provide general insights into the design of guiding structures. The proposed solution combines a deflector, a guiding wall, and a nonerodible area. The deflector serves as a pivotal element in the design proposed in this study. It connects the guiding wall to various bank geometries and protects the flushing channel from sedimentation. This final design optimizes the structure’s size, with variations in the inclination of the guiding wall showing that the best sediment rejection occurs at minimal inclination relative to the main flow direction. Consequently, sediment can be diverted parallel to the wall and discharged downstream via the sluice gates. Additionally, the intake area’s flushing capacity can be maintained by implementing a notch in the guiding wall, which allows for efficient hydraulic sediment removal. Finally, the area between the guiding wall and water intake is protected against erosion to prevent unwanted sediment mobilization.
      原文链接:
    • NETL
    • NSTL
    • Asce-Amer Soc Civil Engineers

    Review of Fluvial Hydrodynamics - Solutions Manual by Subhasish Dey and Sk Zeeshan Ali

    Michele Palermo
    1.1-1.1页
      原文链接:
    • NETL
    • NSTL
    • Asce-Amer Soc Civil Engineers