Enhanced heat transfer

Heat exchangers were initially developed to use plain (or smooth) heat transfer surfaces. An Enhanced heat transfer surface has a special surface geometry that provides a higher thermal performance, per unit base surface area than a plain surface.

Objectives

This higher thermal performance, per unit base surface area A may be used to achieve one of the three objectives below:

This increase in heat transfer capacity per unit volume comes at the expense of an increase in pressure drop across the heat exchanger. This pressure drop may be significant, so the heat transfer enhancement is often limited by the pumping power available.

Optimization

“Enhanced” heat transfer could be achieved throughout optimization. The optimization may sometimes refer to the geometric parameters of the system [1][2][3][4][5][6] or the physical conditions [7][8][9][10][11]

Usage

The subject of “enhanced” heat transfer has become much more important to industry with progressing time. Use of relatively complex geometries were initially limited by manufacturing process. However, new manufacturing methods now allow manufacture of many complex surface geometries. Some enhanced surfaces (e.g., boiling and condensing tubes) are now in their 4th generation. Nearly all heat exchangers used in the air-conditioning and automotive industries are “enhanced” geometries. Further inroads are being seen in the electronic cooling, process and power industries.

References

  1. Lorenzini G, Biserni C, Rocha LAO. Geometric optimization of isothermal cavities according to Bejan’s theory. Int J Heat Mass Transfer 2011;54: 3868–73.
  2. MR Hajmohammadi, H Eskandari, M Saffar-Avval and A Campo, A new configuration of bend tubes for compound optimization of heat and fluid flow, Energy 62 (2013) 418-424.
  3. M. R. Hajmohammadi, S. S. Nourazar, A. Campo and S. Poozesh, Optimal discrete distribution of heat flux elements for in-tube laminar forced convection, International Journal of Heat and Fluid Flow, 40 (2013) 89–96.
  4. M. R. Hajmohammadi, S. Poozesh, S. S. Nourazar, A. Habibi Manesh, Optimal architecture of heat generating pieces in a fin, Journal of Mechanical Science and Technology, 27 (2013) 1143-1149.
  5. Bisemi C, Rocha LAO, Bejan A. Inverted fins: geometric optimization of the intrusion into a conducting wall. Int J Heat Mass Transfer 2004;47:2577–86.
  6. M. R. Hajmohammadi, V. Alizadeh Abianeh, M. Moezzinajafabadi and M. Daneshi, Fork-shaped highly conductive pathways for maximum cooling in a heat generating piece, Applied Thermal Engineering, 61 (2013) 228–235
  7. M. R. Hajmohammadi, S. Poozesh, M. Rahmani and A. Campo, Heat transfer improvement due to the imposition of non-uniform wall heating for in-tube laminar forced convection, Applied Thermal Engineering, 61 (2013) 268–277
  8. M. R. Hajmohammadi, A. Campo, S.S. Nourazar and A. M. Ostad, Improvement of forced convection cooling due to the attachment of heat sources to a conducting thick plate, Journal of Heat Transfer Trans. ASME, 135 (2013) 124504-1.
  9. M.R. Hajmohammadi, M. Moulod, O. Joneydi Shariatzadeh and S.S. Nourazar, New methods to cope with temperature elevations in heated segments of flat plates cooled by boundary layer flow, Thermal Science, DOI: 10.2298/TSCI130128159H
  10. M. R. Hajmohammadi, S. S. Nourazar, A. Campo and S. Poozesh, Optimal discrete distribution of heat flux elements for in-tube laminar forced convection, International Journal of Heat and Fluid Flow, 40 (2013) 89–96.
  11. M. R. Hajmohammadi, E. Shirani, M. R. Salimpour and A. Campo, Constructal placement of unequal heat sources on a plate cooled by laminar forced convection, International Journal of Thermal sciences, 60 (2012) 13–22.

External links


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