Influence of fins designs, geometries and conditions on the performance of a plate-fin heat exchanger-experimental perspective

Authors

  • M. I. N. Ma’arof Department of Mechanical Engineering, INTI International University, Persiaran Perdana BBN, 71800 Nilai, Negeri Sembilan, Malaysia
  • Girma T. Chala Department of Mechanical Engineering, International College of Engineering and Management, P.O. Box 2511, C.P.O Seeb 111, Sultanate of Oman.
  • Hazran Husain Faculty of Mechanical Engineering, Universiti Teknologi MARA, Shah Alam 40450 Shah Alam, Selangor Darul Ehsan, Malaysia
  • Muhammad S. S. Mohamed Faculty of Manufacturing Engineering, Universiti Teknikal Malaysia Melaka, Hang Tuah Jaya, 76100 Durian, Tunggal, Melaka, Malaysia

DOI:

https://doi.org/10.15282/jmes.13.1.2019.02.0372

Keywords:

Heat transfer, fin heat exchanger, convective heat transfer coefficient, efficiency

Abstract

A fin heat exchanger is a simple form of cooling device that is built for efficient heat transfer from one medium to another. Generally, it involves medium such as fluid to perform heat exchange via convective heat transfer. This study is aimed at investigating the effects of diverse designs (arrangements of the fins), qualities (the total surface area of the fin for heat exchange) and conditions (the surface characteristics) of fin heat exchanger on the degree of heat transfer from the experimental perspective. The fin heat exchanger was fabricated and tested. It was observed that by varying the arrangement and condition of the fins, the rate of heat transfer could be affected. However, varying the quality of the fin didn’t have much impact. Nevertheless, the quality aspect of the fin heat exchanger could play a significant role for heat exchanger of larger in scale and dimension. The coating, that is the condition of the fins, aided in decreasing the temperature at a much higher margin at all fan speeds.

 

References

Knissel J, Peußner D. Energy efficient heat exchanger for ventilation systems. Energy and Buildings 2018;159:246-253.

Pradeep GV, Narasimha, KR. Thermal performance of a vertical closed loop pulsating heat pipe and analysis using dimensionless numbers. Journal of Mechanical Engineering and Sciences 2017;11(4):3240-3255.

Abdullah A, Mohamad IS, Hashim AY, Abdullah N, Poh BW, Isa M, Zainal AS. Thermal conductivity and viscosity of deionised water and ethylene glycol-based nanofluids. Journal of Mechanical Engineering and Sciences 2016;10:2249-2261.

Ghani S, Gamaledin SMA, Rashwan MM, Atieh MA. Experimental investigation of double-pipe heat exchangers in air conditioning applications. Energy and Buildings 2018;158:801-811.

Chala GT, Sulaiman SA, Japper-Jaafar A, Kamil WA. Investigation of convective heat transfer coefficient and initial temperature of waxy crude oil on the formation of voids. International Journal of Automotive & Mechanical Engineering 2016;13(3):3754-3762.

Haque ME, Bakar RA, Kadirgama K, Noor MM, Shakaib M. Performance of a domestic refrigerator using nanoparticles-based polyolester oil lubricant.Journal of Mechanical Engineering and Sciences 2016;10(1):1778-1791.

Sahiti N. Interrelation between pin length and heat exchanger performance.Applied Thermal Engineering 2015;91:946-952.

Yu E, Joshi Y. Heat transfer enhancement from enclosed discrete components using pin–fin heat sinks. International Journal of Heat and Mass Transfer 2002;45(25):4957-4966.

Dong J, Chen J, Chen Z, Zhang W, Zhou Y. Heat transfer and pressure drop correlations for the multi-louvered fin compact heat exchangers. Energy Conversion and Management 2007;48(5):1506-1515.

Rugh JP, Pearson JT, Ramadhyani S. Study of a very compact heat exchanger used for passenger compartment heating in automobiles. Presented in 28th National Heat Transfer Conference and Exhibition, San Diego, CA, USA, 09-12/1992:15-24.

Lyman AC, Stephan RA, Thole KA, Zhang LW, Memory SB. Scaling of heat transfer coefficients along louvered fins. Experimental Thermal and Fluid Science 2002;26(5):547-563.

Zhang X, Tafti DK. Flow efficiency in multi-louvered fins. International Journal of Heat and Mass Transfer 2003;46(10):1737-1750.

Qi ZG, Chen JP, Chen ZJ. Parametric study on the performance of a heat exchanger with corrugated louvered fins. Applied thermal engineering 2007; 27(2-3):539-544.

Baliga BR, Azrak RR. Laminar fully developed flow and heat transfer in triangular plate-fin ducts. Journal of heat transfer 1986; 108(1):24-32.

Sparrow EM, Ramsey JW. Heat transfer and pressure drop for a staggered wall-attached array of cylinders with tip clearance. International Journal of Heat and Mass Transfer 1987;21(11):1369-1378.

Tanda G. Heat transfer and pressure drop in a rectangular channel with diamond-shaped elements. International Journal of Heat and Mass Transfer 2001;44(18):3529-3541.

Pirompugd W, Wang CC, Wongwises S. Finite circular fin method for heat and mass transfer characteristics for plain fin-and-tube heat exchangers under fully and partially wet surface conditions. International Journal of Heat and Mass Transfer 2007;50(3-4):552-565.

Zhang LZ. Laminar flow and heat transfer in plate-fin triangular ducts in thermally developing entry region. International Journal of Heat and Mass Transfer 2007;50(7-8):1637-1640.

Huang J, Yu J, Yang H. Effects of key factors on the heat insulation performance of a hollow block ventilated wall. Applied Energy 2018;15(232):409-23.

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Published

2019-03-29

How to Cite

[1]
M. I. N. Ma’arof, G. T. Chala, H. Husain, and M. S. S. Mohamed, “Influence of fins designs, geometries and conditions on the performance of a plate-fin heat exchanger-experimental perspective”, J. Mech. Eng. Sci., vol. 13, no. 1, pp. 4368–4379, Mar. 2019.