NUMERICAL SIMULATION OF THE IMPACT OF A GAS JET ON A FREEWATER SURFACE

Ward Haegeman; Clément Le Touze; Joël Dupays; Marc Massot

doi:10.1615/MultScienTechn.2023047916

NUMERICAL SIMULATION OF THE IMPACT OF A GAS JET ON A FREEWATER SURFACE

Ward Haegeman, Clément Le Touze, Joël Dupays, Marc Massot

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

Abstract

In this work, we are interested in the numerical simulation of a high-speed hot jet impinging on a free liquid surface at rest by means of diffuse interface models. We first consider the case of a low-temperature subsonic jet; a 4-equation model is used on a 2D axi-symmetric setup. Turbulence is accounted for by solving the Reynolds averaged equations and using a k-! turbulence model. Numerical results are evaluated by comparing the depth of the cavity formed in the liquid surface to the predicted values using theoretical models from the literature. We then consider the case of a high-temperature jet. We start by showing the limits of the previous model as it relies on a thermal equilibrium assumption between the liquid and gas phases which is no longer valid. A 5-equation model that does not rely on this assumption is presented. Both models are compared numerically on a simplified set-up.

Original language	English
Pages (from-to)	27-48
Number of pages	22
Journal	Multiphase Science and Technology
Volume	36
Issue number	1
DOIs	https://doi.org/10.1615/MultScienTechn.2023047916
Publication status	Published - 1 Jan 2024
Externally published	Yes

Keywords

diffuse interface models
impinging jets
low-mach schemes
relaxation schemes

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10.1615/MultScienTechn.2023047916

Cite this

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title = "NUMERICAL SIMULATION OF THE IMPACT OF A GAS JET ON A FREEWATER SURFACE",

abstract = "In this work, we are interested in the numerical simulation of a high-speed hot jet impinging on a free liquid surface at rest by means of diffuse interface models. We first consider the case of a low-temperature subsonic jet; a 4-equation model is used on a 2D axi-symmetric setup. Turbulence is accounted for by solving the Reynolds averaged equations and using a k-! turbulence model. Numerical results are evaluated by comparing the depth of the cavity formed in the liquid surface to the predicted values using theoretical models from the literature. We then consider the case of a high-temperature jet. We start by showing the limits of the previous model as it relies on a thermal equilibrium assumption between the liquid and gas phases which is no longer valid. A 5-equation model that does not rely on this assumption is presented. Both models are compared numerically on a simplified set-up.",

keywords = "diffuse interface models, impinging jets, low-mach schemes, relaxation schemes",

author = "Ward Haegeman and \{Le Touze\}, Cl{\'e}ment and Jo{\"e}l Dupays and Marc Massot",

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doi = "10.1615/MultScienTechn.2023047916",

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T1 - NUMERICAL SIMULATION OF THE IMPACT OF A GAS JET ON A FREEWATER SURFACE

AU - Haegeman, Ward

AU - Le Touze, Clément

AU - Dupays, Joël

AU - Massot, Marc

PY - 2024/1/1

Y1 - 2024/1/1

N2 - In this work, we are interested in the numerical simulation of a high-speed hot jet impinging on a free liquid surface at rest by means of diffuse interface models. We first consider the case of a low-temperature subsonic jet; a 4-equation model is used on a 2D axi-symmetric setup. Turbulence is accounted for by solving the Reynolds averaged equations and using a k-! turbulence model. Numerical results are evaluated by comparing the depth of the cavity formed in the liquid surface to the predicted values using theoretical models from the literature. We then consider the case of a high-temperature jet. We start by showing the limits of the previous model as it relies on a thermal equilibrium assumption between the liquid and gas phases which is no longer valid. A 5-equation model that does not rely on this assumption is presented. Both models are compared numerically on a simplified set-up.

AB - In this work, we are interested in the numerical simulation of a high-speed hot jet impinging on a free liquid surface at rest by means of diffuse interface models. We first consider the case of a low-temperature subsonic jet; a 4-equation model is used on a 2D axi-symmetric setup. Turbulence is accounted for by solving the Reynolds averaged equations and using a k-! turbulence model. Numerical results are evaluated by comparing the depth of the cavity formed in the liquid surface to the predicted values using theoretical models from the literature. We then consider the case of a high-temperature jet. We start by showing the limits of the previous model as it relies on a thermal equilibrium assumption between the liquid and gas phases which is no longer valid. A 5-equation model that does not rely on this assumption is presented. Both models are compared numerically on a simplified set-up.

KW - diffuse interface models

KW - impinging jets

KW - low-mach schemes

KW - relaxation schemes

U2 - 10.1615/MultScienTechn.2023047916

DO - 10.1615/MultScienTechn.2023047916

M3 - Article

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JO - Multiphase Science and Technology

JF - Multiphase Science and Technology

IS - 1

ER -

NUMERICAL SIMULATION OF THE IMPACT OF A GAS JET ON A FREEWATER SURFACE

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Keywords

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