Turbulence enhancement by ultrasonically induced gaseous cavitation in the CO2 saturated water

Seung Youp Lee; Young Don Choi

doi:10.1007/BF03185176

Turbulence enhancement by ultrasonically induced gaseous cavitation in the CO₂ saturated water

Seung Youp Lee
, Young Don Choi^*

^*Corresponding author for this work

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

12 Citations (Scopus)

Abstract

Recent primary concern for the design of high performance heat exchanger and highly integrated electronic equipments is to develop an active and creative technologies which enhance the heat transfer without obstructing the coolant flows. In this study, we found through the LDV measurement that the gaseous cavitation induced by ultrasonic vibration applied to the CO₂ saturated water in the square cross-sectioned straight duct flow enhances the turbulence much more than the case of non-ultrasonic or normal ultrasonic conditions without gaseous cavitation does. We also found that gaseous cavitation can enhance effectively the turbulent heat transfer between the heating surfaces and coolants by destructing the viscous sublayer.

Original language	English
Pages (from-to)	246-254
Number of pages	9
Journal	KSME International Journal
Volume	16
Issue number	2
DOIs	https://doi.org/10.1007/BF03185176
Publication status	Published - 2002 Feb

Keywords

Gaseous Cavitation
LDV
Square Cross-sectioned Duct
Ultrasonic Vibration
Viscous Sublayer

ASJC Scopus subject areas

Mechanical Engineering

Access to Document

10.1007/BF03185176

Cite this

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title = "Turbulence enhancement by ultrasonically induced gaseous cavitation in the CO2 saturated water",

abstract = "Recent primary concern for the design of high performance heat exchanger and highly integrated electronic equipments is to develop an active and creative technologies which enhance the heat transfer without obstructing the coolant flows. In this study, we found through the LDV measurement that the gaseous cavitation induced by ultrasonic vibration applied to the CO2 saturated water in the square cross-sectioned straight duct flow enhances the turbulence much more than the case of non-ultrasonic or normal ultrasonic conditions without gaseous cavitation does. We also found that gaseous cavitation can enhance effectively the turbulent heat transfer between the heating surfaces and coolants by destructing the viscous sublayer.",

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AB - Recent primary concern for the design of high performance heat exchanger and highly integrated electronic equipments is to develop an active and creative technologies which enhance the heat transfer without obstructing the coolant flows. In this study, we found through the LDV measurement that the gaseous cavitation induced by ultrasonic vibration applied to the CO2 saturated water in the square cross-sectioned straight duct flow enhances the turbulence much more than the case of non-ultrasonic or normal ultrasonic conditions without gaseous cavitation does. We also found that gaseous cavitation can enhance effectively the turbulent heat transfer between the heating surfaces and coolants by destructing the viscous sublayer.

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