Numerical simulation of shock wave impacting bubble in vapor explosion

Yu Liu; Feng Lei Huang; Zhong Jie Lü

Numerical simulation of shock wave impacting bubble in vapor explosion

Yu Liu, Feng Lei Huang, Zhong Jie Lü^*

^*Corresponding author for this work

School of Mechatronical Engineering

Beijing Institute of Technology

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

4 Citations (Scopus)

Abstract

To study the mechanism of shock wave impacting bubble in vapor explosion caused by high-temperature molten aluminum interacting with water, the process of shock wave impacting underwater bubbles was analyzed by employing the Level set approach in Euler coordinates to track the interface and it could be clearly observed through numerical simulation. Numerical simulations of the interaction process of bubble and shock wave under different initial pressure condition were implemented. The results show that the highest pressure at where the bubble bursts decreases lineally with the increase of the interior pressure of the bubble, and that it also declines with the decrease of the pressure load of the incident plane shock wave.

Original language	English
Pages (from-to)	339-342
Number of pages	4
Journal	Beijing Ligong Daxue Xuebao/Transaction of Beijing Institute of Technology
Volume	33
Issue number	4
Publication status	Published - Apr 2013

Keywords

Bubble
Numerical simulation
Shock wave
Vapor explosion

Cite this

Liu, Y., Huang, F. L., & Lü, Z. J. (2013). Numerical simulation of shock wave impacting bubble in vapor explosion. Beijing Ligong Daxue Xuebao/Transaction of Beijing Institute of Technology, 33(4), 339-342.

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title = "Numerical simulation of shock wave impacting bubble in vapor explosion",

abstract = "To study the mechanism of shock wave impacting bubble in vapor explosion caused by high-temperature molten aluminum interacting with water, the process of shock wave impacting underwater bubbles was analyzed by employing the Level set approach in Euler coordinates to track the interface and it could be clearly observed through numerical simulation. Numerical simulations of the interaction process of bubble and shock wave under different initial pressure condition were implemented. The results show that the highest pressure at where the bubble bursts decreases lineally with the increase of the interior pressure of the bubble, and that it also declines with the decrease of the pressure load of the incident plane shock wave.",

keywords = "Bubble, Numerical simulation, Shock wave, Vapor explosion",

author = "Yu Liu and Huang, {Feng Lei} and L{\"u}, {Zhong Jie}",

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language = "English",

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T1 - Numerical simulation of shock wave impacting bubble in vapor explosion

AU - Liu, Yu

AU - Huang, Feng Lei

AU - Lü, Zhong Jie

PY - 2013/4

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N2 - To study the mechanism of shock wave impacting bubble in vapor explosion caused by high-temperature molten aluminum interacting with water, the process of shock wave impacting underwater bubbles was analyzed by employing the Level set approach in Euler coordinates to track the interface and it could be clearly observed through numerical simulation. Numerical simulations of the interaction process of bubble and shock wave under different initial pressure condition were implemented. The results show that the highest pressure at where the bubble bursts decreases lineally with the increase of the interior pressure of the bubble, and that it also declines with the decrease of the pressure load of the incident plane shock wave.

AB - To study the mechanism of shock wave impacting bubble in vapor explosion caused by high-temperature molten aluminum interacting with water, the process of shock wave impacting underwater bubbles was analyzed by employing the Level set approach in Euler coordinates to track the interface and it could be clearly observed through numerical simulation. Numerical simulations of the interaction process of bubble and shock wave under different initial pressure condition were implemented. The results show that the highest pressure at where the bubble bursts decreases lineally with the increase of the interior pressure of the bubble, and that it also declines with the decrease of the pressure load of the incident plane shock wave.

KW - Bubble

KW - Numerical simulation

KW - Shock wave

KW - Vapor explosion

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JO - Beijing Ligong Daxue Xuebao/Transaction of Beijing Institute of Technology

JF - Beijing Ligong Daxue Xuebao/Transaction of Beijing Institute of Technology

IS - 4

ER -

Numerical simulation of shock wave impacting bubble in vapor explosion

Abstract

Keywords

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