Laser Doppler velocimetry measurement of turbulent bubbly channel flow

So, Seun Seup; Morikita, Hiroshi; Takagi, Shu; Matsumoto, Yoichiro

doi:10.1007/s00348-002-0459-y

Cited by 65 publications

(25 citation statements)

References 12 publications

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“…Image pairs from each camera are cross-correlated separately and the v r -, v z -, and v θ -component velocities are reconstructed using the method described in Soloff et al (1997). A multipass scheme using a robust phase correlation (Eckstein et al 2008;Eckstein and Vlachos 2009a;2009b The convergence of the velocity statistics must be carefully considered (Estrada-Perez and Hassan 2010; So et al 2002). At any given time instant, vapor bubbles can intercede and obscure the view of the liquid from either camera, effectively reducing the liquid velocity data sampling length at a given position …”

Section: Piv Processingmentioning

confidence: 99%

Stereo-PIV measurements of vapor-induced flow modifications in confined jet impingement boiling

Rau

Guo

Vlachos

et al. 2016

International Journal of Multiphase Flow

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Section: Piv Processingmentioning

confidence: 99%

Stereo-PIV measurements of vapor-induced flow modifications in confined jet impingement boiling

Rau

Guo

Vlachos

et al. 2016

International Journal of Multiphase Flow

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“…気泡流には様々なスケールがあり、気泡が生成する乱れは多くの研究者の注目を集めている。その乱れは、流れ場と相互作用し、単相流とは異なる複雑な流動構造を示す [1][2][3][4][5][6]。特に気泡クラスターは、乱流の秩序渦構造よりも大きく、大規模な流動構造そのものを変化させる [7,8]。そのため気泡クラスター形成の有無について様々な報告が行われている [9][10][11]。気泡のクラスター形成は、まず理論的に予測された。ポテンシャル流れを仮定し、複数の気泡が上昇する際、気泡間相互作用によって水平面に気泡がクラスターを形成することが報告された [12,13]。一方で、実際の気泡流では、気泡同士の合体によって気泡径差が生まれ、通常気泡のクラスター構造は観察されない。さらに前述のポテンシャル流れを用いた理論でも、気泡径差を考慮するとクラスターは形成されない [14]。しかし、実験的研究において、界面活性剤や電解質を混入させることで気泡クラスターの形成が報告されている [15,16]。界面活性剤や電解質の混入は、気泡表面の境界条件を大きく変化させる。界面活性剤では気泡の抗力の増加や合体を防ぎ、電解質ではやクリーンな気泡を保ちながら気泡合体を防ぐ [17][18][19][20] /01 02 0/%/ü ! 1 ö 3 4 5 6 7 8 9 6 % !ú ÷ ù ' ü ü ö !…”

Section: 緒言unclassified

Influence of Surfactants on the Motion of a Pair of Bubbles in Quiescent Liquids

Kusuno¹,

Sanada²

2016

JAPANESE JOURNAL OF MULTIPHASE FLOW

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We experimentally investigated the motion of a pair of bubbles initially positioned inline configuration in ultrapure water or an aqueous surfactant solution. The bubble motion was observed by two high speed video cameras. The Reynolds number of bubbles were ranged from 50 to 200, and the bubbles hold a spherical shape in this range. In ultrapure water or small concentration of surfactant solution, initially the trailing bubble deviated from the vertical line on the leading bubble owing to the wake of the leading bubble. And then, the slight difference of the bubble radius changed the relative motion. When the trailing bubble slightly larger than the leading bubble, the trailing bubble approached to the leading bubble due to it's buoyancy difference. The bubbles attracted and collided only when the bubbles rising approximately side by side configuration. On the other hand, the trailing bubble was drafted to the wake region of leading bubble when the bubbles were rising in high concentration of surfactant solution. In this case, the bubbles always collided in line configuration. We consider that these phenomena are caused by the changes of lift force direction in the wake region owing to the surface contamination. In addition, bubble coalescence was inhibited in surfactant solution, even the relative motion was similar to the clean bubble case.

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“…Experimental investigations had been conducted by researchers [4][5][6][7][8][9]. Numerical studies had also been carried out by researchers [10][11][12][13][14][15][16][17][18].…”

Section: Introductionmentioning

confidence: 99%

Study on Liquid Turbulence Modulation by Microbubbles in Different Turbulence Layers

Pang

Wei

2014

Advances in Mechanical Engineering

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Bubbly flows exist extensively in industrial processes. To enhance efficiencies of industrial processes, it is very necessary and important to understand detailedly mechanisms of liquid turbulence modulation by bubbles. To understand mechanisms of the liquid turbulence modulation by microbubbles, an Euler-Lagrange two-way model was used to investigate and analyze deeply the liquid turbulence modulation by microbubbles in the subviscous, buffer, and outer layers, respectively. The present results show that the liquid turbulence modulation by microbubbles is related to microbubble locations; the liquid turbulence is intensified when microbubbles are in the outer layers, whereas the liquid turbulence is suppressed when microbubbles are in the subviscous and buffer layer; and the drag reduction occurs only when microbubbles are in the buffer layer.

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Laser Doppler velocimetry measurement of turbulent bubbly channel flow

Cited by 65 publications

References 12 publications

Stereo-PIV measurements of vapor-induced flow modifications in confined jet impingement boiling

Stereo-PIV measurements of vapor-induced flow modifications in confined jet impingement boiling

Influence of Surfactants on the Motion of a Pair of Bubbles in Quiescent Liquids

Study on Liquid Turbulence Modulation by Microbubbles in Different Turbulence Layers

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