Effects of Pressure on Velocity of Liquid Lumps in Horizontal Gas-Liquid Two-Phase Flow
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概要
- 論文の詳細を見る
phase flow under a wide range of pressures from near atmospheric pressure to a highly elevated pressure of about 20 MPa. The liquid lumps of interest are liquid slugs, huge waves, disturbance waves and ephemeral large waves. Velocities were determined using time-series signals of cross-sectional mean liquid holdup which were electrically detected at two axially separated locations of the test tube. It is demonstrated how the mean values of liquid lump velocity and its standard deviation depend on the gas and liquid flow rates and pressure. It is obtained that the liquid lump velocity and its standard deviation are obviously affected by the pressure and are related to flow patterns. The comparison of liquid lump velocities between vertical upward flow and horizontal flow is also discussed.
- 一般社団法人日本機械学会の論文
- 1993-05-15
著者
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Mori Koji
Department Of Mechanical Engineering Osaka University
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Sekoguchi Kotohiko
Department of Mechanical Engineering, Osaka University
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Shimizu Hideo
Intelligent System Engineering, Ube Technical College
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Nakazatomi Masao
Intelligent System Engineering, Ube Technical College
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Miyake George
Intelligent System Engineering, Ube Technical College
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Takeishi Masayuki
Department of Mechanical Engineering, Osaka University
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Mori Kouji
Department of Mechanical Engineering, Osaka University
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Miyake Gyouji
Intelligent System Engineering Ube Technical College
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Nakazatomi Masao
Intelligent System Engineering Ube Technical College
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Sekoguchi Kotohiko
Department Of Mechanical Engineering Osaka University
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Shimizu Hideo
Intelligent System Engineering Ube Technical College
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Takeishi Masayuki
Department Of Mechanical Engineering Osaka University
関連論文
- Effects of Pressure on Velocity of Liquid Lumps in Horizontal Gas-Liquid Two-Phase Flow
- Pressure Effect on Velocity of Liquid Lumps in Vertical Upward Gas-Liquid Two-Phase Flow
- Rising Characteristics of a Single Measure of Gas Slug in Stagnant Liquid : Effect of Pressure
- Void Signal Analysis and Gas-Liquid Two-Phase Flow Regime Determination by a Statistical Pattern Recognition Method : Fluids Engineering