Drag Coefficient of Emergent Flexible Vegetation in Steady Nonuniform Flow

Seagrass meadows are essential for protection of coastal erosion by damping wave and stabilizing the seabed. Seagrass are considered as a source of water resistance which modifies strongly the wave dynamics. As a part of EDF R & D seagrass restoration project in the Berre lagoon, we quantify the wave attenuation due to artificial vegetation distributed in a flume. Experiments have been conducted at Saint-Venant Hydraulics Laboratory wave flume (Chatou, France). We measure the wave damping with 13 resistive waves gauges along a distance L = 22.5 m for the “low” density and L = 12.15 m for the “high” density of vegetation mimics. A JONSWAP spectrum is used for the generation of irregular waves with significant wave height Hs ranging from 0.10 to 0.23 m and peak period Tp ranging from 1 to 3 s. Artificial vegetation is a model of Posidonia oceanica seagrass species represented by slightly flexible polypropylene shoots with 8 artificial leaves of 0.28 and 0.16 m height. Different hydrodynamics conditions (Hs, Tp, water depth hw) and geometrical parameters (submergence ratio α, shoot density N) have been tested to see their influence on wave attenuation. For a high submergence ratio (typically 0.7), the wave attenuation can reach 67% of the incident wave height whereas for a low submergence ratio (< 0.2) the wave attenuation is negligible. From each experiment, a bulk drag coefficient has been extracted following the energy dissipation model for irregular non-breaking waves developed by Mendez and Losada (2004). This model, based on the assumption that the energy loss over the species meadow is essentially due to the drag force, takes into account both wave and vegetation parameter. Finally, we found an empirical relationship for Cd depending on 2 dimensionless parameters: the Reynolds and Keulegan-Carpenter numbers. These relationships are compared with other similar studies.

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Numerical Comparison of Drag Coefficient between Nacelle Lip-Skin with and without Bias Acoustic Liner

International Review of Mechanical Engineering (IREME) ◽

10.15866/ireme.v10i6.9427 ◽

2016 ◽

Vol 10 (6) ◽

pp. 390 ◽

Cited By ~ 2

Author(s):

Qummare Azam ◽

Mohd Azmi Ismail ◽

Nurul Musfirah Mazlan ◽

Musavir Bashir

Keyword(s):

Drag Coefficient ◽

Numerical Comparison ◽

Acoustic Liner

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Effect of Stefan flow on drag coefficient of reactive spherical particles in gas flow

Proceeding of THMT-18. Turbulence Heat and Mass Transfer 9 Proceedings of the Ninth International Symposium On Turbulence Heat and Mass Transfer ◽

10.1615/thmt-18.1250 ◽

2018 ◽

Author(s):

T.R. Jayawickrama ◽

N.E.L. Haugen ◽

M.U. Babler ◽

K. Umeki

Keyword(s):

Drag Coefficient ◽

Gas Flow ◽

Spherical Particles ◽

Stefan Flow

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COMPARISON OF DIFFERENT EXPERIMENTAL DESIGNS, SAMPLE SIZES AND TECHNIQUES APPLIED TO METAMODELING THE INDUCED DRAG COEFFICIENT OF A BOX-WING AIRCRAFT

10.26678/abcm.conem2018.con18-1610 ◽

2018 ◽

Author(s):

Luiz Fernando Tibério Fernandez ◽

Guilherme Barufaldi ◽

Adson De Paula ◽

Luiz Carlos Sandoval

Keyword(s):

Drag Coefficient ◽

Experimental Designs ◽

Sample Sizes ◽

Induced Drag

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EFFECT OF THE MACRO-SCALE TOPOLOGY OVER THE EFFECTIVE DRAG COEFFICIENT IN DENSE GAS-SOLID FLUIDIZED FLOWS

10.26678/abcm.encit2018.cit18-0017 ◽

2018 ◽

Author(s):

Seyed Reza Amini Niaki ◽

Joseph Mouallem ◽

Christian Milioli ◽

Fernando Milioli

Keyword(s):

Drag Coefficient ◽

Dense Gas ◽

Macro Scale

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Analytical Model For Stage-Discharge Estimation In Meandering Compound Channels With Submerged Flexible Vegetation

10.31988/scitrends.12808 ◽

2018 ◽

Author(s):

Yuqi Shan ◽

Chao Liu

Keyword(s):

Analytical Model ◽

Compound Channels ◽

Flexible Vegetation ◽

Discharge Estimation

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LATENT AND SENSIBLE HEAT COEFFICIENTS BASED ON DRAG COEFFICIENT AFFECTED BY WAVE AGE AND SEA SPRAY

Journal of Japan Society of Civil Engineers Ser B1 (Hydraulic Engineering) ◽

10.2208/jscejhe.74.5_i_1201 ◽

2018 ◽

Vol 74 (5) ◽

pp. I_1201-I_1206

Author(s):

Hiroki OKACHI ◽

Tomohito J. YAMADA

Keyword(s):

Drag Coefficient ◽

Sea Spray ◽

Wave Age ◽

Sensible Heat

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Numerical Studies on Trapped-Vortex Concepts for Stable Combustion

Journal of Engineering for Gas Turbines and Power ◽

10.1115/1.2818088 ◽

1998 ◽

Vol 120 (1) ◽

pp. 60-68 ◽

Cited By ~ 33

Author(s):

V. R. Katta ◽

W. M. Roquemore

Keyword(s):

Drag Coefficient ◽

Reacting Flow ◽

Flow Conditions ◽

Third Order ◽

Cold Flow ◽

Flow Simulations ◽

Numerical Studies ◽

Dynamic Flows ◽

Experimental Findings ◽

Trapped Vortex

Spatially locked vortices in the cavities of a combustor aid in stabilizing the flames. On the other hand, these stationary vortices also restrict the entrainment of the main air into the cavity. For obtaining good performance characteristics in a trapped-vortex combustor, a sufficient amount of fuel and air must be injected directly into the cavity. This paper describes a numerical investigation performed to understand better the entrainment and residence-time characteristics of cavity flows for different cavity and spindle sizes. A third-order-accurate time-dependent Computational Fluid Dynamics with Chemistry (CFDC) code was used for simulating the dynamic flows associated with forebody-spindle-disk geometry. It was found from the nonreacting flow simulations that the drag coefficient decreases with cavity length and that an optimum size exists for achieving a minimum value. These observations support the earlier experimental findings of Little and Whipkey (1979). At the optimum disk location, the vortices inside the cavity and behind the disk are spatially locked. It was also found that for cavity sizes slightly larger than the optimum, even though the vortices are spatially locked, the drag coefficient increases significantly. Entrainment of the main flow was observed to be greater into the smaller-than-optimum cavities. The reacting-flow calculations indicate that the dynamic vortices developed inside the cavity with the injection of fuel and air do not shed, even though the cavity size was determined based on cold-flow conditions.

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Forced convection heat transfer study of a blunt-headed cylinder in non-Newtonian power-law fluids

International Journal of Chemical Reactor Engineering ◽

10.1515/ijcre-2020-0170 ◽

2021 ◽

Vol 0 (0) ◽

Author(s):

Jaspinder Kaur ◽

Roderick Melnik ◽

Anurag Kumar Tiwari

Keyword(s):

Heat Transfer ◽

Nusselt Number ◽

Drag Coefficient ◽

Power Law ◽

Average Nusselt Number ◽

Convection Heat Transfer ◽

Convection Heat ◽

Total Drag ◽

Shear Thinning Fluids ◽

Power Law Fluids

Abstract In this present work, forced convection heat transfer from a heated blunt-headed cylinder in power-law fluids has been investigated numerically over the range of parameters, namely, Reynolds number (Re): 1–40, Prandtl number (Pr): 10–100 and power-law index (n): 0.3–1.8. The results are expressed in terms of local parameters, like streamline, isotherm, pressure coefficient, and local Nusselt number and global parameters, like wake length, drag coefficient, and average Nusselt number. The length of the recirculation zone on the rear side of the cylinder increases with the increasing value of Re and n. The effect of the total drag coefficient acting on the cylinder is seen to be higher at the low value of Re and its effect significant in shear-thinning fluids (n < 1). On the heat transfer aspect, the rate of heat transfer in fluids is increased by increasing the value of Re and Pr. The effect of heat transfer is enhanced in shear-thinning fluids up to ∼ 40% and it impedes it’s to ∼20% shear-thickening fluids. In the end, the numerical results of the total drag coefficient and average Nusselt number (in terms of J H −factor) have been correlated by simple expression to estimate the intermediate value for the new application.

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