Analysis of Jet Flows with the Two-Fluid Particle Interaction Method
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概要
- 論文の詳細を見る
The particle interaction method called MPS (Moving Particle Semi-implicit) method has been developed in recent years, which is formulated by representing the differential operators in Navier-Stokes equation as the interaction between particles characterized with a kernel function and adopts a mesh-free algorithm. This method is suitable especially for treating liquid breakup. We extended the MPS method to two-fluid system, introduced a potential-type surface tension, and modified the calculation algorithm to simulate jet flows. The objective of this study is to evaluate the interfacial area (or, so called binary contact area) of immiscible two-fluid systems with a chemical reaction, where one is injected as a jet into a pool of the other fluid. As a first step, we investigated if the proposed method is capable of reproducing the hydrodynamics of jet flow by analyzing Tanasawa’s experiment. In this paper, we describe the formulation and the calculation algorithm of the method, and results of the verification studies.
- 社団法人 日本原子力学会の論文
- 2001-09-25
著者
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YAMAGUCHI Akira
O-arai Engineering Center, Japan Nuclear Cycle Development Institute
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SHIRAKAWA Noriyuki
TOSHIBA Power & Industrial Systems R&D Center
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HORIE Hideki
TOSHIBA Power & Industrial Systems R&D Center
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YAMAMOTO Yuichi
Toshiba Advanced Systems Corporation
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Shirakawa N
Power & Industrial Systems Reserch & Development Center Toshiba Corporation
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Shirakawa Noriyuki
Toshiba Power & Industrial Systems R&d Center
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Shirakawa Noriyuki
Institute Of Environmental Systems Faculty Of Engineering Kyushu University
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Yamamoto Yuichi
Toshiba It-solutions Corporation
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OKANO Yasushi
O-arai Engineering Center, Japan Nuclear Cycle Development Institute
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Okano Yasushi
O-arai Engineering Center Japan Nuclear Cycle Development Institute
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Horie H
Toshiba Power & Industrial Systems R&d Center
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Yamaguchi Akira
O-arai Engineering Center Japan Nuclear Cycle Development Institute
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