An extension of Oberbeck–Boussinesq approximation for thermal convection problems

Duarte, Bernardo Alan de Freitas; Melo, Rafael Romão da Silva; Villar, Millena Martins; Serfaty, Ricardo; Neto, Aristeu da Silveira

doi:10.1007/s40430-018-1181-x

Cited by 3 publications

(1 citation statement)

References 22 publications

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“…,Denner et al (2014),Jesus et al (2015),Barbi et al (2016),Damasceno, Santos and Vedovoto (2018),Duarte et al (2018).…”

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confidence: 99%

Lagrangian modeling of droplet evaporation

Pinheiro¹

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Evaporation of liquid droplets in high temperature gas environment is of great importance in many engineering applications. Accurate droplet evaporation predictions are crucial in modeling spray combustion, since it is considered a rate limiting process. For this reason, the present dissertation aims are, first, to implement and validate Lagrangian droplet evaporation models that are usually used in spray calculations, including equilibrium and non-equilibrium formulations, and, second, to use these models to pursue a deeper insight on the physical phenomena that may be involved in droplet evaporation processes. In order to validate and assess these theoretical model predictions, an in-house code was developed and diameter evolution results from the numerical simulations are compared to experimental data. First, the model performance is evaluated for water in a case of low evaporation rate and, then, it is evaluated for n-heptane in moderate and high evaporation rates using recent experimental data acquired with a new technique. The Abramzon-Sirignano model is the only one which does not overestimate the evaporation rate for any ambient condition tested, when compared with experimental rate. From the results, it is also revealed that, when a correction factor for energy transfer reduction due to evaporation is incorporated in the classical evaporation model, the predictions from this model and the nonequilibrium one cannot be differentiated, even if the initial droplet diameter is small. Furthermore, the incorporation of natural and forced convection effects on the droplet evaporation rate, by using an empirical correlation, is investigated, showing that including the Grashof number into the Ranz-Marshall correlation actually overestimates the evaporation rate for atmospheric pressure. Finally, the effects of ambient conditions on ethanol evaporation are investigated. Under ambient temperatures higher than the threshold temperature, the evaporation rate is enhanced with the increase of ambient pressure, contrary to what happens for cases when the ambient temperature is lower than the threshold temperature.

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“…,Denner et al (2014),Jesus et al (2015),Barbi et al (2016),Damasceno, Santos and Vedovoto (2018),Duarte et al (2018).…”

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confidence: 99%

Lagrangian modeling of droplet evaporation

Pinheiro¹

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Ethanol droplet evaporation: Effects of ambient temperature, pressure and fuel vapor concentration

Pinheiro

Vedovoto

Neto

et al. 2019

International Journal of Heat and Mass Transfer

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Direct Contact Condensation Jet in Cross-Flow Using Computational Fluid Dynamics

Duarte¹,

Serfaty

Neto

2019

Journal of Heat Transfer

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The computational fluid dynamics is an important methodology to study the characteristics of flows in nature and in a number of engineering applications. Modeling nonisothermal flows may be useful to predict the main flow behavior allowing the improvement of equipment and industrial processes. In addition, investigations using computational models may provide key information about the fundamental characteristics of flow, developing theoretical groundwork of physical processes. In the last years, the topic of phase change has been intensively studied using computational fluid dynamics due to the computational and numerical advances reported in the literature. Among several issues related to the phase change topic, direct contact condensation (DCC) is widely studied in the literature since it is part of a number of industrial applications. In the present work, DCC was studied using a mathematical and computational model with an Eulerian approach. The homemade code MFSim was used to run all the computational simulations in the cluster of the Fluid Mechanics Laboratory from the Federal University of Uberlandia (UFU). The computational model was validated and showed results with high accuracy and low differences compared to previous works in the literature. A complex case study of DCC with cross-flow was then studied and the computational model provided accurate results compared to experimental data from the literature. The jet centerline was well represented and the interface dynamic was accurately captured during all the simulation time. The investigation of the velocity field provided information about the deeply transient characteristic of this flow. The v-velocity component presented the more large variations in time since the standard deviation was subjected to a variation of about 45% compared to the temporal average. In addition, the time history of the maximum resultant velocities observed presented magnitude from 29 m/s to 73 m/s. The importance of modeling three-dimensional (3D) effects was confirmed with the relevance of the velocity magnitudes in the third axis component. Therefore, the Eulerian phase change model used in the present study indicated the possibility to model even complex phenomena using an Eulerian approach.

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An extension of Oberbeck–Boussinesq approximation for thermal convection problems

Cited by 3 publications

References 22 publications

Lagrangian modeling of droplet evaporation

Lagrangian modeling of droplet evaporation

Ethanol droplet evaporation: Effects of ambient temperature, pressure and fuel vapor concentration

Direct Contact Condensation Jet in Cross-Flow Using Computational Fluid Dynamics

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