Numerical simulation of an excited round jet under helical disturbances by three-dimensional discrete vortex method

Seiichiro Izawa; Masaru Kiya; Osamu Mochizuki

doi:10.1299/kikaib.64.2880

Numerical simulation of an excited round jet under helical disturbances by three-dimensional discrete vortex method

Seiichiro Izawa, Masaru Kiya, Osamu Mochizuki

ENG - Mechanical Systems Engineering

Research output: Contribution to journal › Article › peer-review

Abstract

The evolution of vortical structure in an impulsively started round jet has been studied numerically by means of a three-dimensional vortex blob method. The viscous diffusion of vorticity is approximated by a core spreading model originally proposed by Leonard (1980). The jet is forced by axisymmetric, helical and multiple disturbances. The multiple disturbances are combinations of two helical disturbances of the same mode rotating in the opposite directions. The multiple disturbances are found to enhance both the generation of small-scale structures and the growth rate of the jet. The small-scale structures have highly organized spatial distributions. The core spreading method is effective in aquiring the core overlapping in regions of high extensional rate of strain.

Original language	English
Pages (from-to)	2880-2888
Number of pages	9
Journal	Nihon Kikai Gakkai Ronbunshu, B Hen/Transactions of the Japan Society of Mechanical Engineers, Part B
Volume	64
Issue number	625
DOIs	https://doi.org/10.1299/kikaib.64.2880
Publication status	Published - 1998

Keywords

Core spreading
Jet
Numerical analysis
Three-dimensional flow
Turbulence
Vertex blob method

ASJC Scopus subject areas

Condensed Matter Physics
Mechanical Engineering

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10.1299/kikaib.64.2880

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Numerical simulation of an excited round jet under helical disturbances by three-dimensional discrete vortex method. / Izawa, Seiichiro; Kiya, Masaru; Mochizuki, Osamu.
In: Nihon Kikai Gakkai Ronbunshu, B Hen/Transactions of the Japan Society of Mechanical Engineers, Part B, Vol. 64, No. 625, 1998, p. 2880-2888.

Research output: Contribution to journal › Article › peer-review

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abstract = "The evolution of vortical structure in an impulsively started round jet has been studied numerically by means of a three-dimensional vortex blob method. The viscous diffusion of vorticity is approximated by a core spreading model originally proposed by Leonard (1980). The jet is forced by axisymmetric, helical and multiple disturbances. The multiple disturbances are combinations of two helical disturbances of the same mode rotating in the opposite directions. The multiple disturbances are found to enhance both the generation of small-scale structures and the growth rate of the jet. The small-scale structures have highly organized spatial distributions. The core spreading method is effective in aquiring the core overlapping in regions of high extensional rate of strain.",

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AU - Kiya, Masaru

AU - Mochizuki, Osamu

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Y1 - 1998

N2 - The evolution of vortical structure in an impulsively started round jet has been studied numerically by means of a three-dimensional vortex blob method. The viscous diffusion of vorticity is approximated by a core spreading model originally proposed by Leonard (1980). The jet is forced by axisymmetric, helical and multiple disturbances. The multiple disturbances are combinations of two helical disturbances of the same mode rotating in the opposite directions. The multiple disturbances are found to enhance both the generation of small-scale structures and the growth rate of the jet. The small-scale structures have highly organized spatial distributions. The core spreading method is effective in aquiring the core overlapping in regions of high extensional rate of strain.

AB - The evolution of vortical structure in an impulsively started round jet has been studied numerically by means of a three-dimensional vortex blob method. The viscous diffusion of vorticity is approximated by a core spreading model originally proposed by Leonard (1980). The jet is forced by axisymmetric, helical and multiple disturbances. The multiple disturbances are combinations of two helical disturbances of the same mode rotating in the opposite directions. The multiple disturbances are found to enhance both the generation of small-scale structures and the growth rate of the jet. The small-scale structures have highly organized spatial distributions. The core spreading method is effective in aquiring the core overlapping in regions of high extensional rate of strain.

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KW - Jet

KW - Numerical analysis

KW - Three-dimensional flow

KW - Turbulence

KW - Vertex blob method

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Numerical simulation of an excited round jet under helical disturbances by three-dimensional discrete vortex method

Abstract

Keywords

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