CFD simulation of Departure from Nucleate Boiling in vertical tubes under high pressure and high flow conditions

CFD simulation of Departure from Nucleate Boiling in vertical tubes under high pressure and high flow conditions

•Bubble departure diameter and nucleation site density models are recalibrated for high pressure conditions.•Theoretical and experimental basis for boiling and momentum closures are discussed.•CFD model is developed and DNB is predicted within 15% absolute error and the error is less than 6% under h...

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Veröffentlicht in:Nuclear engineering and design 2019-10, Vol.352, p.110150, Article 110150
Hauptverfasser: Vadlamudi, Sai Raja Gopal, Nayak, Arun K.
Format: Artikel
Sprache:eng
Schlagworte:
Boiling
Closures
Computer simulation
Coupled walls
Critical heat flux
Departure from Nucleate Boiling
DNB modeling
High flow
High pressure
Impact analysis
Inlet temperature
Nucleate boiling
Nucleation
Pressure
Sensitivity analysis
Subcooled flow boiling
Tubes
Void fraction
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creator Vadlamudi, Sai Raja Gopal
Nayak, Arun K.
description •Bubble departure diameter and nucleation site density models are recalibrated for high pressure conditions.•Theoretical and experimental basis for boiling and momentum closures are discussed.•CFD model is developed and DNB is predicted within 15% absolute error and the error is less than 6% under high subcooled conditions.•Sensitivity analysis is performed to understand the impact of boiling and momentum closures.•The effect of mass flux, inlet subcooling and exit quality on DNB prediction is studied in detail. In this study, Departure from Nucleate Boiling (DNB) is investigated in vertical tubes under high pressure and high mass flux conditions using two-fluid Eulerian approach coupled with improved wall boiling model. It is essential to determine the near wall void fraction accurately in order to predict DNB. After accessing the theoretical and experimental basis of the correlations used for bubble departure diameter and nucleation site density, existing correlations are recalibrated to capture the phenomena at high pressure conditions. Sensitivity analysis is performed to analyze the impact of boiling and momentum closures. The effect of mass flux, inlet temperature, and exit quality on DNB is studied. The proposed model predicted DNB within 15%. This result indicates that CFD is a promising tool for predicting DNB.
doi_str_mv 10.1016/j.nucengdes.2019.110150
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In this study, Departure from Nucleate Boiling (DNB) is investigated in vertical tubes under high pressure and high mass flux conditions using two-fluid Eulerian approach coupled with improved wall boiling model. It is essential to determine the near wall void fraction accurately in order to predict DNB. After accessing the theoretical and experimental basis of the correlations used for bubble departure diameter and nucleation site density, existing correlations are recalibrated to capture the phenomena at high pressure conditions. Sensitivity analysis is performed to analyze the impact of boiling and momentum closures. The effect of mass flux, inlet temperature, and exit quality on DNB is studied. The proposed model predicted DNB within 15%. 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source ScienceDirect Journals (5 years ago - present)
subjects Boiling
Closures
Computer simulation
Coupled walls
Critical heat flux
Departure from Nucleate Boiling
DNB modeling
High flow
High pressure
Impact analysis
Inlet temperature
Nucleate boiling
Nucleation
Pressure
Sensitivity analysis
Subcooled flow boiling
Tubes
Void fraction
title CFD simulation of Departure from Nucleate Boiling in vertical tubes under high pressure and high flow conditions
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