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HEAT TRANSFER AND FRICTION CHARACTERISTICS OF AN ARRAY OF PERFORATED FINS UNDER LAMINAR FORCED CONVECTION

Yıl 2019, Cilt: 5 Sayı: 3, 115 - 122, 14.03.2019
https://doi.org/10.18186/thermal.540007

Öz

Three-dimensional incompressible laminar fluid flow and heat transfer of a heated array of circular perforated fins are examined numerically. The Navier–Stokes and energy equations are solved by a finite volume method using the SIMPLE algorithm. The second order upwind technique is employed to discretize the momentum and energy equations. Computations were performed for a range of Reynolds numbers 100 ≤Re ≤ 350. Thermal performance and effectiveness as well as friction coefficient of perforated and solid fins are determined for the optimum porosity. The results show that the average coefficient of friction reduces with increasing the Reynolds number and the number of perforations. The heat transfer rate increases with the porosity and the Reynolds number. It is found that perforated fin effectiveness decreases with the number of peroration at constant Reynolds numbers.

Kaynakça

  • [1] Q. D. Kern, D. A. Kraus. (1972). Extended surface heat transfer, New York, McGraw-Hill.
  • [2] Arslanturk, C., Ozguc, A. F. (2006). Optimization of a central-heating radiator. Applied energy, 83(11), 1190-1197.
  • [3] El-Sayed, S. A., Mohamed, S. M., Abdel-latif, A. A., Abdel-hamid, E. A. (2004). Experimental study of heat transfer and fluid flow in longitudinal rectangular-fin array located in different orientations in fluid flow. Experimental Thermal and Fluid Science, 29(1), 113-128.
  • [4] Sahin, B., Demir, A. (2008). Performance analysis of a heat exchanger having perforated square fins. Applied Thermal Engineering, 28(5-6), 621-632.
  • [5] Dhanawade, K. H., Sunnapwar, V. K., Dhanawade, H. S. (2016). Optimization of Design Parameters for Lateral Circular Perforated Fin Arrays under Forced Convection. Heat Trans. Asian Res, 45, 30–45.
  • [6] Rawat, K., Patil, A. K. (2016). Heat Transfer and Friction Characteristics of Perforated Fin with a Longitudinal Slot under Forced Convection. Heat Transfer—Asian Research, 45(6), 536-555.
  • [7] Saadat, H., Tavakol, M. M., Yaghoubi, M. (2014, November). Experimental study on heat transfer from a perforated fin array with cross perforations. In The 2nd Heat and Mass Transfer Conference.
  • [8] Ismail, M. F., Reza, M. O., Zobaer, M. A., Ali, M. (2013). Numerical investigation of turbulent heat convection from solid and longitudinally perforated rectangular fins. Procedia Engineering, 56, 497-502.
  • [9] Shaeri, M. R.,Yaghoubi, M. (2009). Numerical analysis of turbulent convection heat transfer from an array of perforated fins. International Journal of Heat and Fluid Flow, 30(2), 218-228.
  • [10] Ashjaee, M., Goharkhah, M., Khadem, L. A., Ahmadi, R. (2015). Effect of magnetic field on the forced convection heat transfer and pressure drop of a magnetic nanofluid in a miniature heat sink. Heat and Mass Transfer, 51(7), 953-964.
  • [11] Shaeri, M. R., Bonner, R. (2017, July). Effect of Perforation Size to Perforation Spacing on Heat Transfer in Laterally Perforated-Finned Heat Sinks. In ASME 2017 Heat Transfer Summer Conference (pp. V002T14A005-V002T14A005). American Society of Mechanical Engineers.
  • [12] Wen, M. Y., Yeh, C. H. (2017). Numerical study of thermal performance of perforated circular pin fin heat sinks in forced convection. Heat and Mass Transfer, 53(6), 2031-2044.
  • [13] Mohammadi, S., Ahmadi Nadooshan, A., Bayareh, M. (2017). Numerical simulation of laminar convection heat transfer from an array of circular perforated fins. Energy Equipment and Systems, 5(2), 147-156.
  • [14] Bayareh, M., Pordanjani, A. H., Nadooshan, A. A., Dehkordi, K. S. (2017). Numerical study of the effects of stator boundary conditions and blade geometry on the efficiency of a scraped surface heat exchanger. Applied Thermal Engineering, 113, 1426-1436.
  • [15] Maurya, R. S., Singh, S. (2017). Numerical Investigation of Isothermal Flow around Impingement Plates in a Shell and Tube Exchanger. Journal of Thermal Engineering, 3(5), 1442-1452.
Yıl 2019, Cilt: 5 Sayı: 3, 115 - 122, 14.03.2019
https://doi.org/10.18186/thermal.540007

Öz

Kaynakça

  • [1] Q. D. Kern, D. A. Kraus. (1972). Extended surface heat transfer, New York, McGraw-Hill.
  • [2] Arslanturk, C., Ozguc, A. F. (2006). Optimization of a central-heating radiator. Applied energy, 83(11), 1190-1197.
  • [3] El-Sayed, S. A., Mohamed, S. M., Abdel-latif, A. A., Abdel-hamid, E. A. (2004). Experimental study of heat transfer and fluid flow in longitudinal rectangular-fin array located in different orientations in fluid flow. Experimental Thermal and Fluid Science, 29(1), 113-128.
  • [4] Sahin, B., Demir, A. (2008). Performance analysis of a heat exchanger having perforated square fins. Applied Thermal Engineering, 28(5-6), 621-632.
  • [5] Dhanawade, K. H., Sunnapwar, V. K., Dhanawade, H. S. (2016). Optimization of Design Parameters for Lateral Circular Perforated Fin Arrays under Forced Convection. Heat Trans. Asian Res, 45, 30–45.
  • [6] Rawat, K., Patil, A. K. (2016). Heat Transfer and Friction Characteristics of Perforated Fin with a Longitudinal Slot under Forced Convection. Heat Transfer—Asian Research, 45(6), 536-555.
  • [7] Saadat, H., Tavakol, M. M., Yaghoubi, M. (2014, November). Experimental study on heat transfer from a perforated fin array with cross perforations. In The 2nd Heat and Mass Transfer Conference.
  • [8] Ismail, M. F., Reza, M. O., Zobaer, M. A., Ali, M. (2013). Numerical investigation of turbulent heat convection from solid and longitudinally perforated rectangular fins. Procedia Engineering, 56, 497-502.
  • [9] Shaeri, M. R.,Yaghoubi, M. (2009). Numerical analysis of turbulent convection heat transfer from an array of perforated fins. International Journal of Heat and Fluid Flow, 30(2), 218-228.
  • [10] Ashjaee, M., Goharkhah, M., Khadem, L. A., Ahmadi, R. (2015). Effect of magnetic field on the forced convection heat transfer and pressure drop of a magnetic nanofluid in a miniature heat sink. Heat and Mass Transfer, 51(7), 953-964.
  • [11] Shaeri, M. R., Bonner, R. (2017, July). Effect of Perforation Size to Perforation Spacing on Heat Transfer in Laterally Perforated-Finned Heat Sinks. In ASME 2017 Heat Transfer Summer Conference (pp. V002T14A005-V002T14A005). American Society of Mechanical Engineers.
  • [12] Wen, M. Y., Yeh, C. H. (2017). Numerical study of thermal performance of perforated circular pin fin heat sinks in forced convection. Heat and Mass Transfer, 53(6), 2031-2044.
  • [13] Mohammadi, S., Ahmadi Nadooshan, A., Bayareh, M. (2017). Numerical simulation of laminar convection heat transfer from an array of circular perforated fins. Energy Equipment and Systems, 5(2), 147-156.
  • [14] Bayareh, M., Pordanjani, A. H., Nadooshan, A. A., Dehkordi, K. S. (2017). Numerical study of the effects of stator boundary conditions and blade geometry on the efficiency of a scraped surface heat exchanger. Applied Thermal Engineering, 113, 1426-1436.
  • [15] Maurya, R. S., Singh, S. (2017). Numerical Investigation of Isothermal Flow around Impingement Plates in a Shell and Tube Exchanger. Journal of Thermal Engineering, 3(5), 1442-1452.
Toplam 15 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Bölüm Makaleler
Yazarlar

Afshin Ahmadi Nodooshan Bu kişi benim

Yayımlanma Tarihi 14 Mart 2019
Gönderilme Tarihi 13 Eylül 2017
Yayımlandığı Sayı Yıl 2019 Cilt: 5 Sayı: 3

Kaynak Göster

APA Nodooshan, A. A. (2019). HEAT TRANSFER AND FRICTION CHARACTERISTICS OF AN ARRAY OF PERFORATED FINS UNDER LAMINAR FORCED CONVECTION. Journal of Thermal Engineering, 5(3), 115-122. https://doi.org/10.18186/thermal.540007
AMA Nodooshan AA. HEAT TRANSFER AND FRICTION CHARACTERISTICS OF AN ARRAY OF PERFORATED FINS UNDER LAMINAR FORCED CONVECTION. Journal of Thermal Engineering. Mart 2019;5(3):115-122. doi:10.18186/thermal.540007
Chicago Nodooshan, Afshin Ahmadi. “HEAT TRANSFER AND FRICTION CHARACTERISTICS OF AN ARRAY OF PERFORATED FINS UNDER LAMINAR FORCED CONVECTION”. Journal of Thermal Engineering 5, sy. 3 (Mart 2019): 115-22. https://doi.org/10.18186/thermal.540007.
EndNote Nodooshan AA (01 Mart 2019) HEAT TRANSFER AND FRICTION CHARACTERISTICS OF AN ARRAY OF PERFORATED FINS UNDER LAMINAR FORCED CONVECTION. Journal of Thermal Engineering 5 3 115–122.
IEEE A. A. Nodooshan, “HEAT TRANSFER AND FRICTION CHARACTERISTICS OF AN ARRAY OF PERFORATED FINS UNDER LAMINAR FORCED CONVECTION”, Journal of Thermal Engineering, c. 5, sy. 3, ss. 115–122, 2019, doi: 10.18186/thermal.540007.
ISNAD Nodooshan, Afshin Ahmadi. “HEAT TRANSFER AND FRICTION CHARACTERISTICS OF AN ARRAY OF PERFORATED FINS UNDER LAMINAR FORCED CONVECTION”. Journal of Thermal Engineering 5/3 (Mart 2019), 115-122. https://doi.org/10.18186/thermal.540007.
JAMA Nodooshan AA. HEAT TRANSFER AND FRICTION CHARACTERISTICS OF AN ARRAY OF PERFORATED FINS UNDER LAMINAR FORCED CONVECTION. Journal of Thermal Engineering. 2019;5:115–122.
MLA Nodooshan, Afshin Ahmadi. “HEAT TRANSFER AND FRICTION CHARACTERISTICS OF AN ARRAY OF PERFORATED FINS UNDER LAMINAR FORCED CONVECTION”. Journal of Thermal Engineering, c. 5, sy. 3, 2019, ss. 115-22, doi:10.18186/thermal.540007.
Vancouver Nodooshan AA. HEAT TRANSFER AND FRICTION CHARACTERISTICS OF AN ARRAY OF PERFORATED FINS UNDER LAMINAR FORCED CONVECTION. Journal of Thermal Engineering. 2019;5(3):115-22.

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