Thermogravitational Convective Flow Inside a Cavity with a Heated Circular Cylinder: A Finite Difference Analysis via Vorticity Stream Function Approach

K. Venkatadri; Veena Chandanam; C. Venkata Lakshmi; R. Sivaraj; Ho Hon Leung; Firuz Kamalov; Mariam AlShamsi

doi:10.1007/978-3-031-41420-6_35

Thermogravitational Convective Flow Inside a Cavity with a Heated Circular Cylinder: A Finite Difference Analysis via Vorticity Stream Function Approach

K. Venkatadri, Veena Chandanam, C. Venkata Lakshmi, R. Sivaraj, Ho Hon Leung, Firuz Kamalov, Mariam AlShamsi

Department of Mathematical Sciences

Research output: Chapter in Book/Report/Conference proceeding › Chapter

Abstract

Current numerical investigation reveals the natural convective flow and heat transfer features within the cavity containing a hot obstruction. The enclosure’s vertical walls are considered cold, and the horizontal walls are considered adiabatic. The present computational model comprises the mass, flow, and heat transfer equations with suitable boundary conditions. The system of equations is dimensionalized by utilizing the suitable nondimensional quantities. The pressure elimination technique is adopted and solved the resulting partial differential equations through vorticity-stream function approach. The features of transport phenomena within the cavity are analyzed with different thermal buoyancy parameter (i.e., Rayleigh number (Ra)) values. The graphical outcomes of the dissimilar values of Rayleigh numbers are discussed in detail.

Original language	English
Title of host publication	Trends in Mathematics
Publisher	Springer Science and Business Media Deutschland GmbH
Pages	391-400
Number of pages	10
DOIs	https://doi.org/10.1007/978-3-031-41420-6_35
Publication status	Published - 2024

Publication series

Name	Trends in Mathematics
Volume	Part F2357
ISSN (Print)	2297-0215
ISSN (Electronic)	2297-024X

Keywords

Buoyancy flow
Convection
Enclosure
Finite difference method

ASJC Scopus subject areas

General Mathematics

Access to Document

10.1007/978-3-031-41420-6_35

Cite this

Venkatadri, K., Chandanam, V., Lakshmi, C. V., Sivaraj, R., Leung, H. H., Kamalov, F., & AlShamsi, M. (2024). Thermogravitational Convective Flow Inside a Cavity with a Heated Circular Cylinder: A Finite Difference Analysis via Vorticity Stream Function Approach. In Trends in Mathematics (pp. 391-400). (Trends in Mathematics; Vol. Part F2357). Springer Science and Business Media Deutschland GmbH. https://doi.org/10.1007/978-3-031-41420-6_35

Thermogravitational Convective Flow Inside a Cavity with a Heated Circular Cylinder: A Finite Difference Analysis via Vorticity Stream Function Approach. / Venkatadri, K.; Chandanam, Veena; Lakshmi, C. Venkata et al.
Trends in Mathematics. Springer Science and Business Media Deutschland GmbH, 2024. p. 391-400 (Trends in Mathematics; Vol. Part F2357).

Research output: Chapter in Book/Report/Conference proceeding › Chapter

Venkatadri, K, Chandanam, V, Lakshmi, CV, Sivaraj, R, Leung, HH, Kamalov, F & AlShamsi, M 2024, Thermogravitational Convective Flow Inside a Cavity with a Heated Circular Cylinder: A Finite Difference Analysis via Vorticity Stream Function Approach. in Trends in Mathematics. Trends in Mathematics, vol. Part F2357, Springer Science and Business Media Deutschland GmbH, pp. 391-400. https://doi.org/10.1007/978-3-031-41420-6_35

Venkatadri K, Chandanam V, Lakshmi CV, Sivaraj R, Leung HH, Kamalov F et al. Thermogravitational Convective Flow Inside a Cavity with a Heated Circular Cylinder: A Finite Difference Analysis via Vorticity Stream Function Approach. In Trends in Mathematics. Springer Science and Business Media Deutschland GmbH. 2024. p. 391-400. (Trends in Mathematics). doi: 10.1007/978-3-031-41420-6_35

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abstract = "Current numerical investigation reveals the natural convective flow and heat transfer features within the cavity containing a hot obstruction. The enclosure{\textquoteright}s vertical walls are considered cold, and the horizontal walls are considered adiabatic. The present computational model comprises the mass, flow, and heat transfer equations with suitable boundary conditions. The system of equations is dimensionalized by utilizing the suitable nondimensional quantities. The pressure elimination technique is adopted and solved the resulting partial differential equations through vorticity-stream function approach. The features of transport phenomena within the cavity are analyzed with different thermal buoyancy parameter (i.e., Rayleigh number (Ra)) values. The graphical outcomes of the dissimilar values of Rayleigh numbers are discussed in detail.",

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AB - Current numerical investigation reveals the natural convective flow and heat transfer features within the cavity containing a hot obstruction. The enclosure’s vertical walls are considered cold, and the horizontal walls are considered adiabatic. The present computational model comprises the mass, flow, and heat transfer equations with suitable boundary conditions. The system of equations is dimensionalized by utilizing the suitable nondimensional quantities. The pressure elimination technique is adopted and solved the resulting partial differential equations through vorticity-stream function approach. The features of transport phenomena within the cavity are analyzed with different thermal buoyancy parameter (i.e., Rayleigh number (Ra)) values. The graphical outcomes of the dissimilar values of Rayleigh numbers are discussed in detail.

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Thermogravitational Convective Flow Inside a Cavity with a Heated Circular Cylinder: A Finite Difference Analysis via Vorticity Stream Function Approach

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