Interaction Between Boundary-Layer Transition and Cavitation Phenomena on a Yawed Cylinder
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概要
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The turbulent transition process in three-dimensional (3-D) bounday layers is known to be greatly different from and more complicated than that in two-dimensional (2-D) cases. As a result, the transition process in 3-D boundary layers is not well understood. When such a flow field is also critical to cavitation inception, which is often the case in existing fluid machineries, flow structures become further complicated. Transition phenomena might influence the cavitation inception and its behavior ; therefore, investigation of cavitation phenomena in relation to boundary-layer transition is essential in order to refine existing fluid machineries. However, in spite of such industrial importance, such problems have not yet been investigated. Cavitation first appears at the positions where pressure is minimum. Therefore, the vortices in boundary layers developing in wall surfaces of fluid machineries are possible candidates for the cavitation inception. In the transition regions of general3-D boundary layers, streamwise vortices often appear. It is interesting to investigate such vortices from the standpoint of cavitation phenomena. In the present investigation, the relationship between cavitation phenomena and boundary-layer transition on a 45-degree yawed cylinder is investigated using both wind and water tunnels. The yawed cylinder is an appropriate model for the purpose of such investigations while there appears cross-flow instability, and streamwise vortices will appear in the boundary layer. The transition process in the case of a yawed cylinder is often investigated in relation to a swept=wing boundary-layer transition study. Appearance of the cavitation streaks, which have a regularly aligned fine structure in the streamwise direction, on the cylinder surface show that cavitation selectively appears along each cross-flow vortex where a low-pressure zone exists in the transition region of the boundary layer. The wavelengths of the cross-flow vortices measured in a wind tunnel model and of cavitation streaks measured in a water tunnel model are in good agreement. Since the comparison of other physically measurable flow properties between the 3-D boundary-layer transition and cavitation phenomena came out reasonably well, it can be considered, in general, that the cavitation inception is enhanced by cross-flow vortices appearing in a 3-D boundary layer on a 45-degree yawed cylinder.
- 一般社団法人日本機械学会の論文
- 1993-05-15
著者
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OHTA Fukuo
Institute of Fluid Science, Tohoku University
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Ohta Fukuo
Institute Of Fluid Science Tohoku University
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Ohta F
Tohoku Univ. Sendai Jpn
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Kohama Yasuaki
Department of Machine Intelligence and Systems Engineering, Tohoku University
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Kohama Yasuaki
Department Of Machine Intelligence And Systems Engineering Tohoku University
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Hishinuma Nobuo
Institute of Fluid Science, Tohoku University
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Segawa Kiyoshi
Hitachi Co. Ltd.
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Hishinuma Nobuo
Institute Of Fluid Science Tohoku University
関連論文
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- Measurement of ground effect and boundary-layer transition by towing wind tunnel
- The Response of Artificial Longitudinal Vortex Pair Embedded in the Boundary Layer to Acoustic Excitation
- Interaction Between Boundary-Layer Transition and Cavitation Phenomena on a Yawed Cylinder
- A New Parameter for Predicting Crossflow Instability