Effect of tube shape on the performance of a fin and tube heat exchanger

Authors

  • Djamel Sahel Department of Technical Sciences, University Amar Telidji-Laghouat, Algeria.
  • Houari Ameur Department of Technology, University Centre of Naama, Po. Box 66, 45000, Algeria. Phone: +213770343722.
  • Mustapha Mellal Faculty of Mechanical Engineering, USTO-MB, Oran, Algeria.

DOI:

https://doi.org/10.15282/jmes.14.2.2020.13.0525

Keywords:

Heat transfer, Fin and tube heat exchanger, Shape of the tube, Turbulent flow

Abstract

A numerical study is carried out to test the effect of tube shape on heat transfer and fluid flow in a finned tube heat exchanger. The effects of different shapes (circular, flat, elliptical and oval in both orientations: left and right) are analyzed. The simulations are carried out for two-dimensional and external flow of an incompressible fluid with Reynolds numbers varying between 3000 and 20000. The results obtained indicate that the shape of the tube directly affects the thermal and dynamic behaviors of a fin and tube heat exchanger. Where the circular tube ensures higher heat transfer coefficient of about 18% than the flat tube, and it generate a moderate pressure drop of about 10% in the same conditions. Also, some reliable empirical correlations are proposed to predict the Nusselt number and the friction factor.

References

B. E. Launder and T. H. Massey, "The numerical prediction of viscous flow and heat transfer in tube banks," ASME Journal of Heat Transfer, vol. 100, pp. 565-571, 1978.

A. Zukauskas, "Heat transfer from tubes in cross flow," in Advances in Heat Transfer. vol. 8, ed, 1972, pp. 93-160.

M. Fujii and T. Fujii, "A numerical analysis of laminar flow and heat transfer of air in an in-line tube bank," Numerical Heat Transfer, vol. 7, pp. 89-102, 1984.

E. M. Sparrow and S. Kang, "Longitudinally-finned cross-flow tube banks and their heat transfer and pressure drop characteristics," International journal of heat and mass transfer, vol. 28, pp. 339-350, 1985.

J. Baughn, M. Elderkin, and A. McKillop, "Heat transfer from a single cylinder, cylinders in tandem, and cylinders in the entrance region of a tube bank with a uniform heat flux," 1986.

M. Faghri and N. Rao, "Numerical computation of flow and heat transfer in finned and unfinned tube banks," International journal of heat and mass transfer, vol. 30, pp. 363-372, 1987.

G. Stanescu, A. Fowler, and A. Bejan, "The optimal spacing of cylinders in free-stream cross-flow forced convection," International journal of heat and mass transfer, vol. 39, pp. 311-317, 1996.

Z. Guo, D. Li, and B. Wang, "A novel concept for convective heat transfer enhancement," International journal of heat and mass transfer, vol. 41, pp. 2221-2225, 1998.

B. Anoop, C. Balaji, and K. Velusamy, "A characteristic correlation for heat transfer over serrated finned tubes," Annals of Nuclear Energy, vol. 85, pp. 1052-1065, 2015.

S. Beale and D. Spalding, "A numerical study of unsteady fluid flow in in-line and staggered tube banks," Journal of Fluids and Structures, vol. 13, pp. 723-754, 1999.

T. A. Tahseen, M. Ishak, and M. Rahman, "An overview on thermal and fluid flow characteristics in a plain plate finned and un-finned tube banks heat exchanger," Renewable and Sustainable Energy Reviews, vol. 43, pp. 363-380, 2015.

N. Benarji, C. Balaji, and S. Venkateshan, "Unsteady fluid flow and heat transfer over a bank of flat tubes," Heat and mass transfer, vol. 44, p. 445, 2008.

T. Fullerton and N. Anand, "Periodically fully-developed flow and heat transfer over flat and oval tubes using a control volume finite-element method," Numerical Heat Transfer, Part A: Applications, vol. 57, pp. 642-665, 2010.

M. Ishak, T. A. Tahseen, and M. M. Rahman, "Experimental investigation on heat transfer and pressure drop characteristics of air flow over a staggered flat tube bank in crossflow," International Journal of Automotive and Mechanical Engineering, vol. 7, p. 900, 2013.

T. A. Tahseen, M. Ishak, and M. Rahman, "An Experimental Study Air Flow And Heat Transfer Of Air Over In-Line Flat Tubebank," in International Conference on Mechanical Engineering Research (ICMER2013), 2013, p. 3.

T. A. Tahseen, M. Ishak, and M. Rahman, "An experimental study of heat transfer and friction factor characteristics of finned flat tube banks with in-line tubes configurations," in Applied Mechanics and Materials, 2014, pp. 197-203.

H. M. Bahaidarah, N. Anand, and H. Chen, "A numerical study of fluid flow and heat transfer over a bank of flat tubes," Numerical Heat Transfer, Part A: Applications, vol. 48, pp. 359-385, 2005.

S. S. Yogesh, A. S. Selvaraj, D. K. Ravi, and T. K. R. Rajagopal, "Heat transfer and pressure drop characteristics of inclined elliptical fin tube heat exchanger of varying ellipticity ratio using CFD code," International journal of heat and mass transfer, vol. 119, pp. 26-39, 2018.

J. Li, C. Dang, and E. Hihara, "Heat transfer enhancement in a parallel, finless heat exchanger using a longitudinal vortex generator, Part B: Experimental investigation on the performance of finless and fin-tube heat exchangers," International journal of heat and mass transfer, vol. 128, pp. 66-75, 2019.

J. Li, C. Dang, and E. Hihara, "Heat transfer enhancement in a parallel, finless heat exchanger using a longitudinal vortex generator, Part A: Numerical investigation," International journal of heat and mass transfer, vol. 128, pp. 87-97, 2019.

M. Ma’arof, G. T. Chala, H. Husain, and M. S. Mohamed, "Influence of fins designs, geometries and conditions on the performance of a plate-fin heat exchanger-experimental perspective," Journal of Mechanical Engineering and Sciences, vol. 13, pp. 4368-4379, 2019.

D. Sahel, H. Ameur, and Y. Kamla, "A numerical study of fluid flow and heat transfer over a fin and flat tube heat exchangers with complex vortex generators," The European Physical Journal Applied Physics, vol. 78, p. 34805, 2017.

H. Han, Y.-L. He, Y.-S. Li, Y. Wang, and M. Wu, "A numerical study on compact enhanced fin-and-tube heat exchangers with oval and circular tube configurations," International journal of heat and mass transfer, vol. 65, pp. 686-695, 2013.

A. M. Lavasani, H. Bayat, and T. Maarefdoost, "Experimental study of convective heat transfer from in-line cam shaped tube bank in crossflow," Applied thermal engineering, vol. 65, pp. 85-93, 2014.

T. A. Tahseen, M. Ishak, and M. Rahman, "Performance predictions of laminar heat transfer and pressure drop in an in-line flat tube bundle using an adaptive neuro-fuzzy inference system (ANFIS) model," International Communications in Heat and Mass Transfer, vol. 50, pp. 85-97, 2014.

Y.-H. Zhang, L.-B. Wang, F. Ke, Y. Su, and S. Gao, "The effects of span position of winglet vortex generator on local heat/mass transfer over a three-row flat tube bank fin," Heat and mass transfer, vol. 40, pp. 881-891, 2004.

M. Mellal, R. Benzeguir, D. Sahel, and H. Ameur, "Hydro-thermal shell-side performance evaluation of a shell and tube heat exchanger under different baffle arrangement and orientation," International Journal of Thermal Sciences, vol. 121, pp. 138-149, 2017.

D. Sahel, H. Ameur, R. Benzeguir, and Y. Kamla, "Enhancement of heat transfer in a rectangular channel with perforated baffles," Applied thermal engineering, vol. 101, pp. 156-164, 2016.

D. Sahel and R. Benzeguir, "Thermal characteristic in solar air heater fitted with plate baffles and heating corrugated surface," Energy Procedia, vol. 139, pp. 307-314, 2017.

S. Eiamsa-ard and P. Promvonge, "Numerical study on heat transfer of turbulent channel flow over periodic grooves," International Communications in Heat and Mass Transfer, vol. 35, pp. 844-852, 2008.

H. Ameur and D. Sahel, "Effect of some parameters on the thermohydraulic characteristics of a channel heat exchanger with corrugated walls," Journal of Mechanical and Energy Engineering, vol. 3, 2019.

K. Boukhadia, H. Ameur, D. Sahel, and M. Bozit, "Effect of the perforation design on the fluid flow and heat transfer characteristics of a plate fin heat exchanger," International Journal of Thermal Sciences, vol. 126, pp. 172-180, 2018.

H. Ameur, "Effect of the baffle inclination on the flow and thermal fields in channel heat exchangers," Results in Engineering, vol. 3, p. 100021, 2019.

H. Ameur and Y. Menni, "Laminar cooling of shear thinning fluids in horizontal and baffled tubes: Effect of perforation in baffles," Thermal Science and Engineering Progress, vol. 14, p. 100430, 2019.

H. Ameur, "Effect of Corrugated Baffles on the Flow and Thermal Fields in a Channel Heat Exchanger," Journal of Applied and Computational Mechanics, vol. 6, pp. 209-218, 2020.

D. Sahel, H. Ameur, and W. Boudaoud, "A new correlation for predicting the hydrothermal characteristics over flat tube banks," Journal of Mechanical and Energy Engineering, vol. 3, pp. 273-280, 2019.

H. Ameur, D. Sahel, and Y. Menni, "Enhancement of the cooling of shear-thinning fluids in channel heat exchangers by using the V-baffling technique," Thermal Science and Engineering Progress, p. 100534, 2020.

T. Kim, "Effect of longitudinal pitch on convective heat transfer in crossflow over in-line tube banks," Annals of Nuclear Energy, vol. 57, pp. 209-215, 2013.

Downloads

Published

2020-06-22

How to Cite

[1]
D. Sahel, H. Ameur, and M. Mellal, “Effect of tube shape on the performance of a fin and tube heat exchanger”, J. Mech. Eng. Sci., vol. 14, no. 2, pp. 6709–6718, Jun. 2020.

Issue

Section

Article

Similar Articles

<< < 1 2 3 4 5 6 7 8 9 10 > >> 

You may also start an advanced similarity search for this article.