ANALYSIS OF COMPACT HEAT EXCHANGER USING NANOFLUIDES

Authors

  • Guruprasath. D Department of Mechanical Engineering, Saveetha School of Engineering,Saveetha Institute of Medical and Techanical Sciences, Thandalam, Chennai, Tamilnadu, India 602 105 Author
  • Suresh Kumar S Department of Mechanical Engineering, Saveetha School of Engineering,Saveetha Institute of Medical and Techanical Sciences, Thandalam, Chennai, Tamilnadu, India 602 105 Author

DOI:

https://doi.org/10.61841/nkb13r51

Keywords:

analysis of compact heat exchanger using nanofluides

Abstract

The warmth exchanger is a tool used intensively for heat transfer from fluid. The warmth exchanger affords the switch of thermal energy among two or extra fluids at distinct temperatures. The warmth exchanger is extensively used in area heating. Refrigeration, air conditioning, power plants, chemical plant life, petrochemical plants, petroleum refineries, and natural gas processing and sewage remedies use a heat exchanger, which is a radiator in an automobile. The warmth is switched through water to the radiator. If performance may be increased, various cloth and geometries of shell and tube warmth exchangers are broadly used in many industries (35%–40%). The strong geometry production smooth preservation and viable improvements. 

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References

1. Admiraal, D.M. and C.W. Bullard, 1993, "Condensers and Evaporators," Air Conditioning and Refrigeration Center TR-48, 'The University of Illinois, Urbana, ll.

2. Webb, R. L., 1987, ''Enhancement of Single-Phase Heat Transfer," in Handbook of Single-Phase Convective Heat Transfer, edited by Kakac et al., Wiley Interscience, New York, NY.

3. A.M. Jacobi, R.K. Shah, Heat transfer surface enhancement through the use of longitudinal vortices: a

review of recent progress, Experimental Thermal and Fluid Science 11 (1995) 295–309.

4. M. Fiebig, Embedded vortices in internal flow: heat transfer and pressure loss enhancement,

International Journal of Heat and Fluid Flow 16 (1995) 376–388.

5. G.B. Schubauer, W.G. Spangenberg, Forced mixing in boundary layers, Journal of Fluid Mechanics 8

(1960) 10–31. S.H. Lee, H.S. Ryou, Y.K. Choi, Heat transfer in a three-dimensional turbulent boundary

layer with longitudinal vortices, International Journal of Heat and Mass Transfer 42 (1999) 1521–1534.

6. M.C. Gentry, A.M. Jacobi, Heat transfer enhancement by delta-wing vortex generators on a

flat plate: vortex interactions with the boundary layer, Experimental Thermal and Fluid Science

14 (1997) 231–242.

7. .F. Tsai, T.W.H. Sheu, S.M. Lee, Heat transfer in a conjugate heat exchanger with a wavy surface,

International Journal of Heat and Mass Transfer 42 (1999) 1735-1745.

8. Aytunc¸ Erek, Barıs Ozerdem, Levent Bilir , Zafer Ilken , Effect of geometrical

parameters on heat transfer and pressure drop characteristics of plate fin and tube heat exchangers,

Applied Thermal Engineering 25 (2005) 2421–243

9. D. Taler, Determination of heat transfer correlations for plate-fin-and-tube heat exchangers, Heat

and Mass Transfer 40 (2004) 809–822.

10. E. Carluccio, G. Starace , A. Ficarella, D. Laforgia, Numerical analysis of a cross-flow compact heat

exchanger for vehicle applications, Applied Thermal Engineering 25, (2005) 1995–2013.

11. Tony W. H. Sheui, S. F. Tsai, and T. P. Chiang, Numerical Study of Heat Transfer in Two-Row Heat

Exchangers Having Extended Fin Surface, Numerical Heat Transfer, Part A, 35:797 - 814, 1999 Sadik

Kakaç and Hongtan Liu (2002). Heat Exchangers: Selection, Rating and Thermal Design (2nd ed.). CRC

Press. ISBN 0-8493-0902-6.

12. Saunders, E. A. (1988). Heat Exchanges: Selection, Design and Construction. New York: Longman

Scientific and Technical.

13. Mazen M. Abu-Khader (2012), Plate heat exchangers: Recent advances, Renewable and Sustainable

Energy Reviews, Volume 16, Issue 4, Pages 1883–1891.

14. M. YousefI,A.N. Darus, H. Mohammadi (2012),An imperialist competitive algorithm for optimal design

of plate-fin heat exchangers, International Journal of Heat and Mass Transfer, 55, 3178-3185.

15. M. Mishra, P.K. Das, S. Sarangi (2009), Second law based optimisation of crossflow plate-fin heat

exchanger design using genetic algorithm, Applied Thermal Engineering, 29, 2983– 2989. M. Mishra,

P.K. Das, S. Sarangi (2004), Optimum design of crossflow plate-fin heat exchangers through genetic

algorithm, Int. J. Heat Exch., 5 (2), pp. 379–401.

16. Mourad Yataghene, Jack Legrand (2013), A 3D-CFD model thermal analysis within a scraped surface

heat exchanger,Computers & Fluids, Volume 71, Pages 380–399.

17. N. Targui, H. Kahalerras (2008), Analysis of fluid flow and heat transfer in a double pipe heat exchanger with porous structures ,Energy Conversion and Management, Volume 49, Issue 11, Pages 3217–3229.

18. P. Raskovic , A. Anastasovski, L. Markosvska,V. Mesko, Process integration in bioprocess industry waste heat recovery in yeast and ethyl alcohol plant, Journal Energy35,2010,704-717

19. A new arrangement of blades in scraped surface heat exchanger for food pastes, Luca D’Addio, Claudia Carotenuuto , Francesca Di Natalie , Roberto Nigro, J. of Food Engineering ,Volume 109 Issue 1 , January 2012, Pg 143-149

20. Heating and cooling of hazelnut paste in alternate blades scraped surface heat exchangers , , Luca D’Addio, Claudia Carotenuuto , Francesca Di Natalie , Roberto Nigro, J. of Food Engineering ,Volume 115 Issue 2 , March 2013, Pg 182-189.

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Published

31.05.2020

Issue

Vol. 24 No. 3 (2020): 24 (3) 2020

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Articles

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How to Cite

D, G., & Kumar S, S. (2020). ANALYSIS OF COMPACT HEAT EXCHANGER USING NANOFLUIDES. International Journal of Psychosocial Rehabilitation, 24(3), 4114-4119. https://doi.org/10.61841/nkb13r51