2004
DOI: 10.1017/s0022112004008304
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Particle–fluid interactions in a plane near-wall turbulent flow

Abstract: The role of particles heavier than the fluid (glass spheres in water) in a turbulent open channel flow over a smooth bed is examined at volume concentration about $10^{-3}$. The present work focuses on the dynamical interaction between the solid (particles) and the fluid phases in the near-wall region. Experimental measurements have been performed by means of phase Doppler anemometry to acquire two velocity components, particle size and concentration data simultaneously; the Reynolds number of the flow was clo… Show more

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Cited by 127 publications
(115 citation statements)
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“…For convenience, the velocity lag is non-dimensionalized asû l (=u l /u * ), where u * is the shear velocity. From the experimental results, Rashidi et al [4] and Righetti and Romano [26] proposed a monotonic variation of velocity-lag along the vertical direction in open channel flow. Based on this proposition, it is assumed that the velocity lag increases monotonically from the water surface to the channel bed, having a zero value at the water surface and u l max at the reference level (above the bed) y = a, where a is the vertical distance from the bed to the reference level.…”
Section: Entropy Theory-based Methodologymentioning
confidence: 98%
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“…For convenience, the velocity lag is non-dimensionalized asû l (=u l /u * ), where u * is the shear velocity. From the experimental results, Rashidi et al [4] and Righetti and Romano [26] proposed a monotonic variation of velocity-lag along the vertical direction in open channel flow. Based on this proposition, it is assumed that the velocity lag increases monotonically from the water surface to the channel bed, having a zero value at the water surface and u l max at the reference level (above the bed) y = a, where a is the vertical distance from the bed to the reference level.…”
Section: Entropy Theory-based Methodologymentioning
confidence: 98%
“…To test the validity of this model, i.e., Equation (13) with a wide range of sediment-laden flow conditions and different types of particles, experimental data from Rashidi et al [4] and Kaftori et al [31] for polystyrene particles, Best et al [3] and Righetti and Romano [26] for glass particles and Muste and Patel [2] and Muste et al [32] for natural sand particles were selected. A summary of these data with flow conditions and other flow characteristics is given in Table 1.…”
Section: Comparison With Experimental Data and Other Modelsmentioning
confidence: 99%
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“…The features of these coherent structures in the dense and sparse configurations can presumably differ, as suggested by the third order moments analysis, but after all they are responsible for the vertical transport of momentum and substances, such as nutrients, oxygen and sediment, between the vegetation layer and the outer flow (Ikeda andKanazawa 1996, Ghisalberti andNepf 2005). Focusing our attention on the transport by suspension of fine sediments, it is indeed well known that ejections are responsible for the maintaining into suspension of particles heavier than fluid, supplying the required net turbulent upward momentum flux (see, e.g., Sumer and Deigaard 1981, Kaftori et al 1995, Lu and Willmart 1973, Righetti and Romano 2004. The impact of plants on the suspended sediment transport capacity can be therefore investigated generalizing the approach proposed by Lu and Willmart (1973) …”
Section: P Z H′ ≈mentioning
confidence: 99%