Modeling of Flashing Two-Phase Flow

Pinhasi, Gad A.; Ullmann, Amos; Dayan, Abraham

doi:10.1515/revce.2005.21.3-4.133

Cited by 40 publications

(22 citation statements)

References 204 publications

(173 reference statements)

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“…This explosive fragmentation is very similar to the sudden, explosive boiling of liquids close to the mechanical spinodal (i.e. during homogeneous nucleation under very high metastability), also called sometimes spall [41,42]. The spallation strength for a solid is the strain needed to separate the material along a plane surface instantaneously.…”

Section: Solid-vapor Stability Limitsmentioning

confidence: 92%

Solid–fluid phase transitions under extreme pressures including negative ones

Imre

Drozd-Rzoska

Horváth

et al. 2008

Journal of Non-Crystalline Solids

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Section: Solid-vapor Stability Limitsmentioning

confidence: 92%

Solid–fluid phase transitions under extreme pressures including negative ones

Imre

Drozd-Rzoska

Horváth

et al. 2008

Journal of Non-Crystalline Solids

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“…In the nuclear industry, during the hypothetical loss of coolant accident of pressurized water nuclear reactors, the rate of coolant loss is determined by the critical flashing flow through the crack [2]. In the chemical industry, the severity of failure of pressurized vessels or pipes containing liquefied chemical hazardous gases is characterized by the external flashing flow [3]. An additional flashing evaporation phenomenon was reported in [4], which refers to an aerospace application and concerns the leading edge cooling of a space vehicle.…”

Section: Introductionmentioning

confidence: 99%

“…The complexity of flashing flows is represented by gas-liquid mixture with rapid phase change and bubble dynamics [5], and numerical studies are directed towards the determination of vapour generation rate. Good reviews have been given by Pinhasi [3] and Liao & Lucas [6]. In general, two methods have been used for the evaluation of the interfacial mass transfer rate in flashing flows.…”

Section: Introductionmentioning

confidence: 99%

Evaluation of Interfacial Heat Transfer Models for Flashing Flow with Two-Fluid CFD

Liao

Lucas

2018

Fluids

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Abstract:The complexity of flashing flows is increased vastly by the interphase heat transfer as well as its coupling with mass and momentum transfers. A reliable heat transfer coefficient is the key in the modelling of such kinds of flows with the two-fluid model. An extensive literature survey on computational modelling of flashing flows has been given in previous work. The present work is aimed at giving a brief review on available theories and correlations for the estimation of interphase heat transfer coefficient, and evaluating them quantitatively based on computational fluid dynamics simulations of bubble growth in superheated liquid. The comparison of predictions for bubble growth rate obtained by using different correlations with the experimental as well as direct numerical simulation data reveals that the performance of the correlations is dependent on the Jakob number and Reynolds number. No generally applicable correlations are available. Both conduction and convection are important in cases of bubble rising and translating in stagnant liquid at high Jakob numbers. The correlations combining the analytical solution for heat diffusion and the theoretical relation for potential flow give the best agreement.

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“…The phenomenon constitutes an operational hazard for equipment containing heated pressurized liquids: after a sudden accidental pressure loss or temperature increase, the liquid might reach a deeply metastable state and then relax by explosive boiling. LOCA (Loss of Coolant Accident) in pressurized water nuclear reactors [6] and BLEVE (Boiling Liquid Expanding Vapor Explosion, [7,8]) in pressurized (liquified) gas tanks are two well known examples for violent and sudden boiling and the cause of many accidents. To minimize the risk of accidents, scientists and engineers dealing with pressurized heated liquids should be aware of the metastable region and know the properties of liquids in it.…”

Section: Introductionmentioning

confidence: 99%

Estimation of the Thermodynamic Limit of Overheating for Bulk Water from Interfacial Properties

et al. 2013

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The limit of overheating or expanding is an important property of liquids, which is relevant for the design and safety assessment of processes involving pressurized liquids. In this work, the thermodynamic stability limit -the so-called spinodal -of water is calculated by molecular dynamics computer simulation, using the molecular potential model of Baranyai and Kiss. The spinodal pressure is obtained from the maximal tangential pressure within a liquid-vapor interface layer. The results are compared to predictions of various equations of states. Based on these comparisons, a set of equations of state is identified which gives reliable results in the metastable (overheated or expanded) liquid region of water down to −55 MPa.

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Modeling of Flashing Two-Phase Flow

Cited by 40 publications

References 204 publications

Solid–fluid phase transitions under extreme pressures including negative ones

Solid–fluid phase transitions under extreme pressures including negative ones

Evaluation of Interfacial Heat Transfer Models for Flashing Flow with Two-Fluid CFD

Estimation of the Thermodynamic Limit of Overheating for Bulk Water from Interfacial Properties

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