Tesi etd-01312013-184409 |
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Tipo di tesi
Tesi di laurea magistrale
Autore
PUCCIARELLI, ANDREA
URN
etd-01312013-184409
Titolo
Analysis of heat transfer phenomena with supercritical fluids by four equation turbulence models
Dipartimento
INGEGNERIA DELL'ENERGIA, DEI SISTEMI, DEL TERRITORIO E DELLE COSTRUZIONI
Corso di studi
INGEGNERIA ENERGETICA
Relatori
relatore Prof. Ambrosini, Walter
relatore Dott. Forgione, Nicola
relatore Dott. Sharabi, Medhat
relatore Dott. Jackson, J. Derek
relatore Dott. Forgione, Nicola
relatore Dott. Sharabi, Medhat
relatore Dott. Jackson, J. Derek
Parole chiave
- CFD
- Supercritical fluids
Data inizio appello
08/03/2013
Consultabilità
Parziale
Data di rilascio
08/03/2053
Riassunto
This thesis is concerned with phenomena involved in heat transfer to fluids at supercritical pressure and in particular the ability of four equation RANS turbulence models to correctly reproduce observed behaviour.
Fluids at supercritical pressure exhibit property variations with temperature when crossing the so called "pseudo-critical" temperature and changing from a "liquid-like" to a "gas-like" condition. This impacts heavily on the effectiveness of the heat transfer. This can lead to either heat transfer impairment or enhancement. Such changes have presented difficulties for the two-equation k- and k- turbulence models which, in earlier studies, did not seem capable of dealing with the situation, especially when working close to the pseudo-critical conditions. The present study investigates the capabilities of some four-equation turbulence models, usually in combination with the Algebraic Heat Flux Model (AHFM) which provides an advanced relationship for modeling turbulent heat flux.
The models considered are AKN (1995), Deng et al. (2000), Hwang Lin (1999) and Zhang et al. (2010). Calculations are performed using an in-house code named THEMAT, as a versatile tool allowing the adoption of “mixed” models obtained by the combination of different model features.
Experimental data, for both carbon dioxide and water flowing in vertical circular pipes, are considered; the comparison of calculated and measured values is mainly performed on the basis of the wall temperature. Several analyses are conducted; the production terms of turbulent kinetic energy, due to both shearing and buoyancy, were evaluated especially in relation to the velocity distributions.
The experimental data considered allow a sufficiently broad range of operating conditions to be investigated; the capabilities of the four equation turbulence models are tested in many situations of interest and results helped in achieving a better understanding of the deterioration and enhancement phenomena involved.
Fluids at supercritical pressure exhibit property variations with temperature when crossing the so called "pseudo-critical" temperature and changing from a "liquid-like" to a "gas-like" condition. This impacts heavily on the effectiveness of the heat transfer. This can lead to either heat transfer impairment or enhancement. Such changes have presented difficulties for the two-equation k- and k- turbulence models which, in earlier studies, did not seem capable of dealing with the situation, especially when working close to the pseudo-critical conditions. The present study investigates the capabilities of some four-equation turbulence models, usually in combination with the Algebraic Heat Flux Model (AHFM) which provides an advanced relationship for modeling turbulent heat flux.
The models considered are AKN (1995), Deng et al. (2000), Hwang Lin (1999) and Zhang et al. (2010). Calculations are performed using an in-house code named THEMAT, as a versatile tool allowing the adoption of “mixed” models obtained by the combination of different model features.
Experimental data, for both carbon dioxide and water flowing in vertical circular pipes, are considered; the comparison of calculated and measured values is mainly performed on the basis of the wall temperature. Several analyses are conducted; the production terms of turbulent kinetic energy, due to both shearing and buoyancy, were evaluated especially in relation to the velocity distributions.
The experimental data considered allow a sufficiently broad range of operating conditions to be investigated; the capabilities of the four equation turbulence models are tested in many situations of interest and results helped in achieving a better understanding of the deterioration and enhancement phenomena involved.
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01_Abstract.pdf | 311.97 Kb |
02_Table...tents.pdf | 375.45 Kb |
References.pdf | 1.19 Mb |
8 file non consultabili su richiesta dell’autore. |