A mechanistic model for droplet deposition heat transfer in dispersed flow film boiling

Michael J. Meholic; David L. Aumiller; Fan Bill Cheung

doi:10.13182/NT12-10

A mechanistic model for droplet deposition heat transfer in dispersed flow film boiling

Michael J. Meholic, David L. Aumiller, Fan Bill Cheung

Mechanical Engineering

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

6 Scopus citations

Abstract

A mechanistic droplet deposition model has been developed to quantify the direct-contact heat transfer present in dispersed flow film boiling. Lagrangian subscale trajectory calculations utilizing realistic velocity and temperature distributions in the momentum boundary layer are used to determine the number of dispersed droplets able to achieve contact with the heated wall. Coupling the droplet deposition model with a physical directcontact heat transfer coefficient model allows the total direct-contact heat transfer to be determined based upon the local vapor mass flux, wall superheat, and vapor superheat. Comparisons to the existing models highlight the more mechanistic nature of the proposed model.

Original language	English (US)
Pages (from-to)	106-114
Number of pages	9
Journal	Nuclear Technology
Volume	181
Issue number	1
DOIs	https://doi.org/10.13182/NT12-10
State	Published - Jan 2013

All Science Journal Classification (ASJC) codes

Nuclear and High Energy Physics
Nuclear Energy and Engineering
Condensed Matter Physics

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abstract = "A mechanistic droplet deposition model has been developed to quantify the direct-contact heat transfer present in dispersed flow film boiling. Lagrangian subscale trajectory calculations utilizing realistic velocity and temperature distributions in the momentum boundary layer are used to determine the number of dispersed droplets able to achieve contact with the heated wall. Coupling the droplet deposition model with a physical directcontact heat transfer coefficient model allows the total direct-contact heat transfer to be determined based upon the local vapor mass flux, wall superheat, and vapor superheat. Comparisons to the existing models highlight the more mechanistic nature of the proposed model.",

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year = "2013",

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AB - A mechanistic droplet deposition model has been developed to quantify the direct-contact heat transfer present in dispersed flow film boiling. Lagrangian subscale trajectory calculations utilizing realistic velocity and temperature distributions in the momentum boundary layer are used to determine the number of dispersed droplets able to achieve contact with the heated wall. Coupling the droplet deposition model with a physical directcontact heat transfer coefficient model allows the total direct-contact heat transfer to be determined based upon the local vapor mass flux, wall superheat, and vapor superheat. Comparisons to the existing models highlight the more mechanistic nature of the proposed model.

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A mechanistic model for droplet deposition heat transfer in dispersed flow film boiling

Abstract

All Science Journal Classification (ASJC) codes

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