A liquid plug moving in an annular pipe – Heat transfer analysis

•Fully developed heat transfer of liquid plug moving in annular pipe is studied.•Plug flow enhances heat transfer as compared to continuous flow.•Heat transfer of plug flow includes boundary layer transport and radial transport.•Enhancement is caused by radial transport driven by vortex circulation....

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Published inInternational journal of heat and mass transfer Vol. 139; pp. 1065 - 1076
Main Authors Cao, Yadi, Gao, Xuan, Li, Ri
Format Journal Article
LanguageEnglish
Published Oxford Elsevier Ltd 01.08.2019
Elsevier BV
Subjects
Boundary layers
Continuous flow
Heat transfer
Peclet number
Pipes
Transport
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Abstract •Fully developed heat transfer of liquid plug moving in annular pipe is studied.•Plug flow enhances heat transfer as compared to continuous flow.•Heat transfer of plug flow includes boundary layer transport and radial transport.•Enhancement is caused by radial transport driven by vortex circulation.•Enhancement is a function of plug radius ratio, dimensionless length, and Peclet number. Different from a fully developed continuous flow in an annular pipe, a liquid plug moving in an annular pipe generates two toroidal vortexes, which cause radial transport that enhances heat transfer. The fully developed heat transfer of the concentric plug is studied for three types of thermal wall conditions: inner-flux, outer-flux, and isothermal. The fully developed heat transfer of the continuous flow is analytically solved for the same thermal wall conditions. The comparison of heat transfer is made between the plug and the continuous flow. Two heat transfer mechanisms, boundary layer transport and radial transport, are considered to explain the heat transfer enhancement. If the radial transport is weak, the plug shows similar heat transfer performance to the continuous flow, which is dominated by the boundary layer transport. The heat transfer enhancement relies on the radial transport, which increases with decreasing the inner radius, decreasing the plug length, and increasing the Peclet number.
AbstractList Different from a fully developed continuous flow in an annular pipe, a liquid plug moving in an annular pipe generates two toroidal vortexes, which cause radial transport that enhances heat transfer. The fully developed heat transfer of the concentric plug is studied for three types of thermal wall conditions: inner-flux, outer-flux, and isothermal. The fully developed heat transfer of the continuous flow is analytically solved for the same thermal wall conditions. The comparison of heat transfer is made between the plug and the continuous flow. Two heat transfer mechanisms, boundary layer transport and radial transport, are considered to explain the heat transfer enhancement. If the radial transport is weak, the plug shows similar heat transfer performance to the continuous flow, which is dominated by the boundary layer transport. The heat transfer enhancement relies on the radial transport, which increases with decreasing the inner radius, decreasing the plug length, and increasing the Peclet number.
•Fully developed heat transfer of liquid plug moving in annular pipe is studied.•Plug flow enhances heat transfer as compared to continuous flow.•Heat transfer of plug flow includes boundary layer transport and radial transport.•Enhancement is caused by radial transport driven by vortex circulation.•Enhancement is a function of plug radius ratio, dimensionless length, and Peclet number. Different from a fully developed continuous flow in an annular pipe, a liquid plug moving in an annular pipe generates two toroidal vortexes, which cause radial transport that enhances heat transfer. The fully developed heat transfer of the concentric plug is studied for three types of thermal wall conditions: inner-flux, outer-flux, and isothermal. The fully developed heat transfer of the continuous flow is analytically solved for the same thermal wall conditions. The comparison of heat transfer is made between the plug and the continuous flow. Two heat transfer mechanisms, boundary layer transport and radial transport, are considered to explain the heat transfer enhancement. If the radial transport is weak, the plug shows similar heat transfer performance to the continuous flow, which is dominated by the boundary layer transport. The heat transfer enhancement relies on the radial transport, which increases with decreasing the inner radius, decreasing the plug length, and increasing the Peclet number.
Author Li, Ri
Gao, Xuan
Cao, Yadi
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  email: sunny.li@ubc.ca
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Snippet •Fully developed heat transfer of liquid plug moving in annular pipe is studied.•Plug flow enhances heat transfer as compared to continuous flow.•Heat transfer...
Different from a fully developed continuous flow in an annular pipe, a liquid plug moving in an annular pipe generates two toroidal vortexes, which cause...
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elsevier
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StartPage 1065
SubjectTerms Boundary layers
Continuous flow
Heat transfer
Peclet number
Pipes
Transport
Title A liquid plug moving in an annular pipe – Heat transfer analysis
URI https://dx.doi.org/10.1016/j.ijheatmasstransfer.2019.05.088
https://www.proquest.com/docview/2256522581
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