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EFFECT OF FLOW STRUCTURE ON HEAT TRANSFER IN COMPACT HEAT EXCHANGER BY USING FINITE THICKNESS WINGLET AT ACUTE ANGLE

Year 2017, , 1149 - 1162, 01.04.2017
https://doi.org/10.18186/thermal.298616

Abstract

Longitudinal
vortex generation is a well-known passive technique for thinning the thermal
boundary layer and hence enhancing the heat transfer, but its performance while
considering the thickness is essentially unknown. In this study, a single
triangular shaped winglet type vortex generator having finite thickness is
analyzed in a plate fin heat exchanger with triangular inserts as secondary
fins. The vortex generators are mounted on bottom and top plates of the heat
exchanger and triangular inserts forms a channel, each representing the
symmetry for the gas-side element of the compact heat exchanger. Heat transfer
and pressure drop is computed to determine the effectiveness of the vortex
generator while varying its thickness, size, and angle of attack under confined
laminar flow condition. In addition the winglet is tilted from vertical at an
angle known as acute angle and it was found to produce two longitudinal
vortices which better did the thinning of boundary layer. It is shown that
adding thickness to triangular winglet and mounting at ψ = 45°, augment heat transfer along the channel wall as high as
19.7% with a corresponding increase of 7.8% in pressure loss.

References

  • [1] M. Fiebig, “Embedded vortices in internal flow: heat transfer and pressure loss enhancement”, International Journal of Heat and Fluid Flow, Vol. 16, pp.376–388, (1995).
  • [2] A.M. Jacobi, and R.K. Shah, “Heat transfer surface enhancement through the use of longitudinal vortices: a review of recent progress”, Experimental Thermal and Fluid Science, Vol. 11, pp.295–309, (1995).
  • [3] K. Torii, and J. Yanagihara, “The Effects of Longitudinal Vortices on Heat Transfer of Laminar Boundary”, International Journal Series-II JSME, Vol. 32, pp.359-402, (1989).
  • [4] A.Y. Turk, and G.H. Junkhan, “Heat Transfer Enhancement Downstream of Vortex Generators on a Flat Plate”, Proceedings of the Eighth International Heat Transfer Conference, 6, pp. 2903–2908, (1986).
  • [5] M. Fiebig, P. Kallweit, and N. K. Mitra, “Wing Type Vortex Generators for Heat Transfer Enhancement”, Proc. Eighth Int. Heat Transfer Conf., Hemisphere, New York., Vol. 6, pp.2909-2913, (1986).
  • [6] M. Fiebig, P. Kallweit, N.K. Mitra, and S. Tiggelbeck, “Heat Transfer Enhancement and Drag by Longitudinal Vortex Generators in Channel Flow”, Experimental Thermal Fluid Science, Vol. 4, pp.103-114, (1991).
  • [7] G. Biswas, N.K. Mitra, and M. Fiebig, “Computation of Laminar Mixed Convection Flow in a Channel with Wing Type Built-in Obstacles”, Journal of Thermophysics, Vol.3, pp. 447-453, (1989).
  • [8] G. Biswas, and H. Chattopadhyay,“Heat Transfer in a Channel with Built-in Wing-Type Vortex Generators”, Int. Journal of Heat Mass Transfer, Vol.35, pp.803- 814, (1992).
  • [9] G. Biswas, K. Torii, D. Fujii, and K. Nishino, “Numerical and experimental determination of flow structure and heat transfer effects of longitudinal vortices in a channel flow”, Int. Journal of Heat Mass Transfer, 39:pp.3441-3451, (1996).
  • [10] R. Vasudevan, V. Eswaran, and G. Biswas, “Winglet-Type Vortex Generators For Plate Fin Heat Exchangers Using Triangular Fins”, Numerical Heat Transfer, Part A, Vol. 58, pp.533-555, (2000).
Year 2017, , 1149 - 1162, 01.04.2017
https://doi.org/10.18186/thermal.298616

Abstract

References

  • [1] M. Fiebig, “Embedded vortices in internal flow: heat transfer and pressure loss enhancement”, International Journal of Heat and Fluid Flow, Vol. 16, pp.376–388, (1995).
  • [2] A.M. Jacobi, and R.K. Shah, “Heat transfer surface enhancement through the use of longitudinal vortices: a review of recent progress”, Experimental Thermal and Fluid Science, Vol. 11, pp.295–309, (1995).
  • [3] K. Torii, and J. Yanagihara, “The Effects of Longitudinal Vortices on Heat Transfer of Laminar Boundary”, International Journal Series-II JSME, Vol. 32, pp.359-402, (1989).
  • [4] A.Y. Turk, and G.H. Junkhan, “Heat Transfer Enhancement Downstream of Vortex Generators on a Flat Plate”, Proceedings of the Eighth International Heat Transfer Conference, 6, pp. 2903–2908, (1986).
  • [5] M. Fiebig, P. Kallweit, and N. K. Mitra, “Wing Type Vortex Generators for Heat Transfer Enhancement”, Proc. Eighth Int. Heat Transfer Conf., Hemisphere, New York., Vol. 6, pp.2909-2913, (1986).
  • [6] M. Fiebig, P. Kallweit, N.K. Mitra, and S. Tiggelbeck, “Heat Transfer Enhancement and Drag by Longitudinal Vortex Generators in Channel Flow”, Experimental Thermal Fluid Science, Vol. 4, pp.103-114, (1991).
  • [7] G. Biswas, N.K. Mitra, and M. Fiebig, “Computation of Laminar Mixed Convection Flow in a Channel with Wing Type Built-in Obstacles”, Journal of Thermophysics, Vol.3, pp. 447-453, (1989).
  • [8] G. Biswas, and H. Chattopadhyay,“Heat Transfer in a Channel with Built-in Wing-Type Vortex Generators”, Int. Journal of Heat Mass Transfer, Vol.35, pp.803- 814, (1992).
  • [9] G. Biswas, K. Torii, D. Fujii, and K. Nishino, “Numerical and experimental determination of flow structure and heat transfer effects of longitudinal vortices in a channel flow”, Int. Journal of Heat Mass Transfer, 39:pp.3441-3451, (1996).
  • [10] R. Vasudevan, V. Eswaran, and G. Biswas, “Winglet-Type Vortex Generators For Plate Fin Heat Exchangers Using Triangular Fins”, Numerical Heat Transfer, Part A, Vol. 58, pp.533-555, (2000).
There are 10 citations in total.

Details

Subjects Engineering
Journal Section Articles
Authors

Bhupender Sharma This is me

Publication Date April 1, 2017
Submission Date March 17, 2017
Published in Issue Year 2017

Cite

APA Sharma, B. (2017). EFFECT OF FLOW STRUCTURE ON HEAT TRANSFER IN COMPACT HEAT EXCHANGER BY USING FINITE THICKNESS WINGLET AT ACUTE ANGLE. Journal of Thermal Engineering, 3(2), 1149-1162. https://doi.org/10.18186/thermal.298616
AMA Sharma B. EFFECT OF FLOW STRUCTURE ON HEAT TRANSFER IN COMPACT HEAT EXCHANGER BY USING FINITE THICKNESS WINGLET AT ACUTE ANGLE. Journal of Thermal Engineering. April 2017;3(2):1149-1162. doi:10.18186/thermal.298616
Chicago Sharma, Bhupender. “EFFECT OF FLOW STRUCTURE ON HEAT TRANSFER IN COMPACT HEAT EXCHANGER BY USING FINITE THICKNESS WINGLET AT ACUTE ANGLE”. Journal of Thermal Engineering 3, no. 2 (April 2017): 1149-62. https://doi.org/10.18186/thermal.298616.
EndNote Sharma B (April 1, 2017) EFFECT OF FLOW STRUCTURE ON HEAT TRANSFER IN COMPACT HEAT EXCHANGER BY USING FINITE THICKNESS WINGLET AT ACUTE ANGLE. Journal of Thermal Engineering 3 2 1149–1162.
IEEE B. Sharma, “EFFECT OF FLOW STRUCTURE ON HEAT TRANSFER IN COMPACT HEAT EXCHANGER BY USING FINITE THICKNESS WINGLET AT ACUTE ANGLE”, Journal of Thermal Engineering, vol. 3, no. 2, pp. 1149–1162, 2017, doi: 10.18186/thermal.298616.
ISNAD Sharma, Bhupender. “EFFECT OF FLOW STRUCTURE ON HEAT TRANSFER IN COMPACT HEAT EXCHANGER BY USING FINITE THICKNESS WINGLET AT ACUTE ANGLE”. Journal of Thermal Engineering 3/2 (April 2017), 1149-1162. https://doi.org/10.18186/thermal.298616.
JAMA Sharma B. EFFECT OF FLOW STRUCTURE ON HEAT TRANSFER IN COMPACT HEAT EXCHANGER BY USING FINITE THICKNESS WINGLET AT ACUTE ANGLE. Journal of Thermal Engineering. 2017;3:1149–1162.
MLA Sharma, Bhupender. “EFFECT OF FLOW STRUCTURE ON HEAT TRANSFER IN COMPACT HEAT EXCHANGER BY USING FINITE THICKNESS WINGLET AT ACUTE ANGLE”. Journal of Thermal Engineering, vol. 3, no. 2, 2017, pp. 1149-62, doi:10.18186/thermal.298616.
Vancouver Sharma B. EFFECT OF FLOW STRUCTURE ON HEAT TRANSFER IN COMPACT HEAT EXCHANGER BY USING FINITE THICKNESS WINGLET AT ACUTE ANGLE. Journal of Thermal Engineering. 2017;3(2):1149-62.

IMPORTANT NOTE: JOURNAL SUBMISSION LINK http://eds.yildiz.edu.tr/journal-of-thermal-engineering