Application of analytical solution for extended surfaces on curved and squared ribs

Brestovič, T.; Jasminská, N.; Lázár, M.

Artykuł - szczegóły

Tytuł artykułu

Application of analytical solution for extended surfaces on curved and squared ribs

Autorzy

Brestovič T. , Jasminská N. , Lázár M.

Treść / Zawartość

Pełne teksty:

13_2014_051_BRESTOVIC_JASMINSKA_LAZAR.pdf

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Języki publikacji

Abstrakty

The presented article discusses how to increase heat transfer through ribbed surfaces and it is oriented to the mathematical representation of temperature fields and the total thermal flow. The complexity of solving for some types of ribs with variable cross-section requires the application of numerical methods, which are applied consequently to the planar rib as well. In this case there was chosen the finite-difference method (FDM). During solution of the cylindrical ribs the FDM method is preferably used directly with regard to the complexity of solving for infinite sums and improper integrals in Bessel functions. In conclusion is assessed the application suitability of the calculation procedure applied to curved ribs. This procedure is usually used to planar ribs. At the same time it is pointed out the possibility of using this method for calculation of the total thermal flow through cylindrical ribs, which have got the squared form.

Słowa kluczowe

temperature field thermal flow numerical solution finite-difference method

pole temperatury przepływ termiczny metoda różnic skończonych MRS rozwiązanie numeryczne

Wydawca

Oficyna Wydawnicza Politechniki Białostockiej

Czasopismo

Acta Mechanica et Automatica

Rocznik

2015

Tom

Vol. 9, no. 2

Strony

75--83

Opis fizyczny

Bibliogr. 19 poz., rys., tab., wykr.

Twórcy

autor

Brestovič T.

tomas.brestovic@tuke.sk

Faculty of Mechanical Engineering, Technical University in Kosice, Department of Power Engineering, Vysokoškolská 4, 042 00 Košice, Slovak Republic

autor

Jasminská N.

natalia.jasminska@tuke.sk

Faculty of Mechanical Engineering, Technical University in Kosice, Department of Power Engineering, Vysokoškolská 4, 042 00 Košice, Slovak Republic

autor

Lázár M.

marian.lazar@tuke.sk

Faculty of Mechanical Engineering, Technical University in Kosice, Department of Power Engineering, Vysokoškolská 4, 042 00 Košice, Slovak Republic

Bibliografia

1. Brestovič T., Jasminská N. (2013), Software support development for numerical solution of Ansys CFX, Acta Mechanica et Automatica. Vol. 7, no. 4, 215-221.
2. Brestovič T., Kubík M., Jasminská N. (2012), Use of numerical methods for determining the coefficients of pressure losses (in Slovak), Plynár-Vodár-Kúrenár + Klimatizácia, Vol. 10, č. 2, 46-47.
3. Čarnogurská M., Příhoda M., Kubík M., Gállik R., Hršák D. (2013), Methodology of the Sediment Thickness Calculation on the Heat Exchange Area of a Coolers Natural Gas, International Journal of Mechanic Systems Engieneering, Vol. 3, no. 1, 14-19.
4. Ferstl K., Masaryk M. (2011), Heat transfer (in Slovak), STU Bratislava.
5. Incropera F. P. et al. (2007), Fundamentals of Heat and Mass Transfer, Publisher John Wiley & Sons.
6. Kapalo P. (2005), The effect of the flow rate of hot water to the heat flow through the pipe wall (in Slovak), TZB, Vol. 13, No. 3, 22-24.
7. Kapjor A., Jandačka J., Malcho M., Papučík Š. (2010), Intensification of Heat Transport from the Floor Convector at Given Geometry and the Way of Use, Meeting´s of the department of fluid mechanics and thermodynamics – International Conference, 101 - 104.
8. Maga D., Harťanský R. (2005), Numerical solutions (in Slovak), Brno.
9. Michalec Z., Taraba B., Bojko M., Kozubková M. (2010), CFD modelling of the low-temperature oxidation of coal, Archivum Combustions, Vol. 30, No. 3, 133-144.
10. Mlynár P., Masaryk M. (2012), Optimalization of absortioption cooling unit, Gépeszet 2012, 8 th International conference of Mechanical Engineering, BME Budapest, 361-365.
11. Nagy R., Košičanová, D. (2012), Indoor environment air quality ventilation rates – numerical CFD simulations calculations and measuring apparatus applications, Czasopismo Techniczne, 109 (3), 2012, 281–295.
12. Oravec M., Števo S., Sekaj I. (2010),Comparison of Using Simple Genetic Algorithm and Parallel Genetic Algorithm in Heat Transfer Model Optimization, Journal of Cybernetics and Informatics, Vol. 9, 13-18.
13. Purcz P. (2001), Parallel algorithm for spatially one- and twodimensional initial-boundary-value problem for a parabolic eauation, Kybernetika, Vol. 37, No. 2, 171-181.
14. Pyszko R., Příhoda M., Velička M. (2010), Method for determining the thermal boundary condition in the CC mould for numeric models, Proceedings of 19. conference METAL 2010, Ostrava.
15. Rajzinger J. (2012), Calculation of maximum water content in various natural gases by using modified Peng-Robinson equation of state, Communications, Vol. 14, No. 4A, 29-35.
16. Rohsenow W. M., Hartnett J. P., Cho Y. I. (1998), Handbook of Heat Transfer, McGraw-Hill, 250-257
17. Stone C., Simiček J., Vranay F. (2014), Assessing the Thermal Stability of Rammed Earth Using Finite Element Methods, Progressive Multifunctional Building Materials, Constructions and Technological Methods - One Step Closer to Green Visegrad in V4 Countries – Kosice, 107-118.
18. Urban F., Kučák Ľ., Bereznai J., Pulmann M., Tihányi J. (2012), Influence of the mixing grid position on the coolant flow at the outflow part of the nuclear reactor fuel assembly physical model and validation of CFD model, Communications, Vol. 14, No. 4A (2012), 42-46.
19. Vranay F. (2012), Hydraulic connection with the use of existing heating distribution for cooling) (in Slovak), Vykurovanie, 499-503.

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Bibliografia

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