Research Article
BibTex RIS Cite

NUMERICAL INVESTIGATION OF FLOW AND HEAT TRANSFER IN COMMUNICATING CONVERGING AND DIVERGING CHANNELS

Year 2018, Volume: 4 Issue: 5, 2318 - 2332, 25.06.2018
https://doi.org/10.18186/thermal.439057

Abstract

Fluid flow and heat transfer in communicating converging and diverging channel has been numerically investigated. Channels are assumed to be at constant wall temperature and the flow is assumed to be steady state and incompressible. Since the flow and temperature fields to repeat periodically after a certain developing length, periodic boundary conditions are used for the calculations. Finite volume method is used to solve the governing differential equations numerically. Computations are performed for different values of the plate angles and Reynolds numbers. Moreover, velocity distributions along the flow field are illustrated. It was found that the converging- diverging channels destroy the boundary layer significantly and Nusselt number is found to be about 400% higher than those of parallel plate channels, whereas due to vortex formation, pressure drop increases also.

References

  • [1] Jasim, H. H., Söylemez, M. S. (2016). Enhancement of Natural Convection Heat Transfer of Pin Fin Having Perforated With Inclination Angle. Isi Bilimi ve Teknigi Dergisi/Journal of Thermal Science & Technology, 36(2).
  • [2] Jasjeevan, S., Ranjit, S., Brij B. (2015). Thermo hydraulic performance of solar air duct having triangular protrusions as roughness geometry, Journal of Thermal Engineering, 1:2, Special Issue 7, 607-620.
  • [3] Tokgöz, N., Aksoy, M. M., Şahin, B. (2016). Experimental investigation of flow characteristics of corrugated channel flow using PIV, Journal of Thermal Engineering, 2 (2), 754-760.
  • [4] Zunaid, M. Jindal, A., Gakhar, D., Sinha, A. (2017). Numerical study of pressure drop and heat transfer in a straight rectangular and semi cylindrical projections microchannel heat sink, Journal of Thermal Engineering, 3(5),1453-1465.
  • [5] Yılmaz, T. Flow (1977). heat and mass transfer in staggered plate rows (Turkish), Associate Professor Thesis. K.T. Ü.
  • [6] Sparrow, E. M., Baliga, B. R., Patankar, S. V. (1977). Heat transfer and fluid flow analysis of interrupted-wall channels, with application to heat exchangers. Journal of Heat Transfer, 99(1), 4-11.
  • [7] Patankar, S. V., & Prakash, C. (1981). An analysis of the effect of plate thickness on laminar flow and heat transfer in interrupted-plate passages. International Journal of Heat and Mass Transfer, 24(11), 1801-1810.
  • [8] Yilmaz, T. (1982). Numerical solution of Navier-stokes equations for laminar fluid flow in rows of plates in staggered arrangement. International Journal of Heat and Fluid Flow, 3(4), 201-206.
  • [9] Mendes, P. S., Sparrow, E. M. (1984). Periodically converging-diverging tubes and their turbulent heat transfer, pressure drop, fluid flow, and enhancement characteristics. Journal of heat transfer, 106(1), 55-63.
  • [10] Garg, V. K., Maji, P. K. (1988). Laminar flow and heat transfer in a periodically converging‐diverging channel. International journal for numerical methods in fluids, 8(5), 579-597.
  • [11] Amon, C. H., Mikic, B. B. (1990). Numerical prediction of convective heat transfer in self-sustained oscillatory flows. Journal of thermophysics and heat transfer, 4(2), 239-246.
  • [12] Herman, C. V., Mayinger, F., Sekulic, D. P. (1991). Experimental verification of oscillatory phenomena in heat transfer in a communicating channels geometry. In Proc. of the 2nd World Conf. on Exp. Heat Transfer, Fluid Mechanics and Thermodynamics, Dubrovnik, Yugoslavia (904-911).
  • [13] Wang, G. V., Vanka, S. P. (1995). Convective heat transfer in periodic wavy passages. International Journal of Heat and Mass Transfer, 38(17), 3219-3230.
  • [14] Kotcioğlu, İ., Ayhan, T., Olgun, H., Ayhan, B. (1998). Heat transfer and flow structure in a rectangular channel with wing-type vortex generator. Turkish Journal of Engineering and Environmental Sciences, 22(3), 185-196.
  • [15] DeJong, N. C., Jacobi, A. M. (1997). An experimental study of flow and heat transfer in parallel-plate arrays: local, row-by-row and surface average behavior. International Journal of Heat and Mass Transfer, 40(6), 1365-1378.
  • [16] Caliskan, S., Baskaya, S. (2012). Experimental investigation of impinging jet array heat transfer from a surface with V-shaped and convergent-divergent ribs. International Journal of Thermal Sciences, 59, 234-246.
  • [17] Kotcioglu, I., Cansiz, A., Khalaji, M. N. (2013). Experimental investigation for optimization of design parameters in a rectangular duct with plate-fins heat exchanger by Taguchi method. Applied Thermal Engineering, 50(1), 604-613.
  • [18] Min, C., Qi, C., Kong, X., Dong, J. (2010). Experimental study of rectangular channel with modified rectangular longitudinal vortex generators. International Journal of Heat and Mass Transfer, 53(15-16), 3023-3029.
  • [19] Min, C., Qi, C., Wang, E., Tian, L., Qin, Y. (2012). Numerical investigation of turbulent flow and heat transfer in a channel with novel longitudinal vortex generators. International Journal of Heat and Mass Transfer, 55(23-24), 7268-7277.
  • [20] Gholami, A. A., Wahid, M. A., Mohammed, H. A. (2014). Heat transfer enhancement and pressure drop for fin-and-tube compact heat exchangers with wavy rectangular winglet-type vortex generators. International Communications in Heat and Mass Transfer, 54, 132-140.
  • [21] Yilmaz, T., Erdinc, M. T. (2014). Fluid Flow Mixing For Heat Transfer Enhancement In Communicating Converging And Diverging Channels. In Ichmt Digital Library Online. Begel House Inc..
  • [22] Kwankaomeng, S., Promvonge, P. (2010). Numerical prediction on laminar heat transfer in square duct with 30 angled baffle on one wall. International Communications in Heat and Mass Transfer, 37(7), 857-866.
  • [23] Li, Z., Gao, Y. (2017). Numerical study of turbulent flow and heat transfer in cross-corrugated triangular ducts with delta-shaped baffles. International Journal of Heat and Mass Transfer, 108, 658-670.
  • [24] Promvonge, P., Jedsadaratanachai, W., Kwankaomeng, S. (2010). Numerical study of laminar flow and heat transfer in square channel with 30 inline angled baffle turbulators. Applied Thermal Engineering, 30(11-12), 1292-1303.
  • [25] Yilmaz, T., Erdinc, M. T. (2014). Fluid Flow Mixing For Heat Transfer Enhancement In Communicating Converging And Diverging Channels. In Ichmt Digital Library Online. Begel House Inc..
  • [26] Webb, R. L. (1981). Performance evaluation criteria for use of enhanced heat transfer surfaces in heat exchanger design. International Journal of Heat and Mass Transfer, 24(4), 715-726.
  • [27] Çengel, A. Y. (2006). Heat and Mass Transfer: A Practical Approach, McGraw-Hill, Boston.
  • [28] Bhuiya, M. M. K., Chowdhury, M. S. U., Saha, M., Islam, M. T. (2013). Heat transfer and friction factor characteristics in turbulent flow through a tube fitted with perforated twisted tape inserts. International Communications in Heat and Mass Transfer, 46, 49-57.
Year 2018, Volume: 4 Issue: 5, 2318 - 2332, 25.06.2018
https://doi.org/10.18186/thermal.439057

Abstract

References

  • [1] Jasim, H. H., Söylemez, M. S. (2016). Enhancement of Natural Convection Heat Transfer of Pin Fin Having Perforated With Inclination Angle. Isi Bilimi ve Teknigi Dergisi/Journal of Thermal Science & Technology, 36(2).
  • [2] Jasjeevan, S., Ranjit, S., Brij B. (2015). Thermo hydraulic performance of solar air duct having triangular protrusions as roughness geometry, Journal of Thermal Engineering, 1:2, Special Issue 7, 607-620.
  • [3] Tokgöz, N., Aksoy, M. M., Şahin, B. (2016). Experimental investigation of flow characteristics of corrugated channel flow using PIV, Journal of Thermal Engineering, 2 (2), 754-760.
  • [4] Zunaid, M. Jindal, A., Gakhar, D., Sinha, A. (2017). Numerical study of pressure drop and heat transfer in a straight rectangular and semi cylindrical projections microchannel heat sink, Journal of Thermal Engineering, 3(5),1453-1465.
  • [5] Yılmaz, T. Flow (1977). heat and mass transfer in staggered plate rows (Turkish), Associate Professor Thesis. K.T. Ü.
  • [6] Sparrow, E. M., Baliga, B. R., Patankar, S. V. (1977). Heat transfer and fluid flow analysis of interrupted-wall channels, with application to heat exchangers. Journal of Heat Transfer, 99(1), 4-11.
  • [7] Patankar, S. V., & Prakash, C. (1981). An analysis of the effect of plate thickness on laminar flow and heat transfer in interrupted-plate passages. International Journal of Heat and Mass Transfer, 24(11), 1801-1810.
  • [8] Yilmaz, T. (1982). Numerical solution of Navier-stokes equations for laminar fluid flow in rows of plates in staggered arrangement. International Journal of Heat and Fluid Flow, 3(4), 201-206.
  • [9] Mendes, P. S., Sparrow, E. M. (1984). Periodically converging-diverging tubes and their turbulent heat transfer, pressure drop, fluid flow, and enhancement characteristics. Journal of heat transfer, 106(1), 55-63.
  • [10] Garg, V. K., Maji, P. K. (1988). Laminar flow and heat transfer in a periodically converging‐diverging channel. International journal for numerical methods in fluids, 8(5), 579-597.
  • [11] Amon, C. H., Mikic, B. B. (1990). Numerical prediction of convective heat transfer in self-sustained oscillatory flows. Journal of thermophysics and heat transfer, 4(2), 239-246.
  • [12] Herman, C. V., Mayinger, F., Sekulic, D. P. (1991). Experimental verification of oscillatory phenomena in heat transfer in a communicating channels geometry. In Proc. of the 2nd World Conf. on Exp. Heat Transfer, Fluid Mechanics and Thermodynamics, Dubrovnik, Yugoslavia (904-911).
  • [13] Wang, G. V., Vanka, S. P. (1995). Convective heat transfer in periodic wavy passages. International Journal of Heat and Mass Transfer, 38(17), 3219-3230.
  • [14] Kotcioğlu, İ., Ayhan, T., Olgun, H., Ayhan, B. (1998). Heat transfer and flow structure in a rectangular channel with wing-type vortex generator. Turkish Journal of Engineering and Environmental Sciences, 22(3), 185-196.
  • [15] DeJong, N. C., Jacobi, A. M. (1997). An experimental study of flow and heat transfer in parallel-plate arrays: local, row-by-row and surface average behavior. International Journal of Heat and Mass Transfer, 40(6), 1365-1378.
  • [16] Caliskan, S., Baskaya, S. (2012). Experimental investigation of impinging jet array heat transfer from a surface with V-shaped and convergent-divergent ribs. International Journal of Thermal Sciences, 59, 234-246.
  • [17] Kotcioglu, I., Cansiz, A., Khalaji, M. N. (2013). Experimental investigation for optimization of design parameters in a rectangular duct with plate-fins heat exchanger by Taguchi method. Applied Thermal Engineering, 50(1), 604-613.
  • [18] Min, C., Qi, C., Kong, X., Dong, J. (2010). Experimental study of rectangular channel with modified rectangular longitudinal vortex generators. International Journal of Heat and Mass Transfer, 53(15-16), 3023-3029.
  • [19] Min, C., Qi, C., Wang, E., Tian, L., Qin, Y. (2012). Numerical investigation of turbulent flow and heat transfer in a channel with novel longitudinal vortex generators. International Journal of Heat and Mass Transfer, 55(23-24), 7268-7277.
  • [20] Gholami, A. A., Wahid, M. A., Mohammed, H. A. (2014). Heat transfer enhancement and pressure drop for fin-and-tube compact heat exchangers with wavy rectangular winglet-type vortex generators. International Communications in Heat and Mass Transfer, 54, 132-140.
  • [21] Yilmaz, T., Erdinc, M. T. (2014). Fluid Flow Mixing For Heat Transfer Enhancement In Communicating Converging And Diverging Channels. In Ichmt Digital Library Online. Begel House Inc..
  • [22] Kwankaomeng, S., Promvonge, P. (2010). Numerical prediction on laminar heat transfer in square duct with 30 angled baffle on one wall. International Communications in Heat and Mass Transfer, 37(7), 857-866.
  • [23] Li, Z., Gao, Y. (2017). Numerical study of turbulent flow and heat transfer in cross-corrugated triangular ducts with delta-shaped baffles. International Journal of Heat and Mass Transfer, 108, 658-670.
  • [24] Promvonge, P., Jedsadaratanachai, W., Kwankaomeng, S. (2010). Numerical study of laminar flow and heat transfer in square channel with 30 inline angled baffle turbulators. Applied Thermal Engineering, 30(11-12), 1292-1303.
  • [25] Yilmaz, T., Erdinc, M. T. (2014). Fluid Flow Mixing For Heat Transfer Enhancement In Communicating Converging And Diverging Channels. In Ichmt Digital Library Online. Begel House Inc..
  • [26] Webb, R. L. (1981). Performance evaluation criteria for use of enhanced heat transfer surfaces in heat exchanger design. International Journal of Heat and Mass Transfer, 24(4), 715-726.
  • [27] Çengel, A. Y. (2006). Heat and Mass Transfer: A Practical Approach, McGraw-Hill, Boston.
  • [28] Bhuiya, M. M. K., Chowdhury, M. S. U., Saha, M., Islam, M. T. (2013). Heat transfer and friction factor characteristics in turbulent flow through a tube fitted with perforated twisted tape inserts. International Communications in Heat and Mass Transfer, 46, 49-57.
There are 28 citations in total.

Details

Primary Language English
Journal Section Articles
Authors

Mehmet Tahir Erdinç

Publication Date June 25, 2018
Submission Date March 15, 2017
Published in Issue Year 2018 Volume: 4 Issue: 5

Cite

APA Erdinç, M. T. (2018). NUMERICAL INVESTIGATION OF FLOW AND HEAT TRANSFER IN COMMUNICATING CONVERGING AND DIVERGING CHANNELS. Journal of Thermal Engineering, 4(5), 2318-2332. https://doi.org/10.18186/thermal.439057
AMA Erdinç MT. NUMERICAL INVESTIGATION OF FLOW AND HEAT TRANSFER IN COMMUNICATING CONVERGING AND DIVERGING CHANNELS. Journal of Thermal Engineering. June 2018;4(5):2318-2332. doi:10.18186/thermal.439057
Chicago Erdinç, Mehmet Tahir. “NUMERICAL INVESTIGATION OF FLOW AND HEAT TRANSFER IN COMMUNICATING CONVERGING AND DIVERGING CHANNELS”. Journal of Thermal Engineering 4, no. 5 (June 2018): 2318-32. https://doi.org/10.18186/thermal.439057.
EndNote Erdinç MT (June 1, 2018) NUMERICAL INVESTIGATION OF FLOW AND HEAT TRANSFER IN COMMUNICATING CONVERGING AND DIVERGING CHANNELS. Journal of Thermal Engineering 4 5 2318–2332.
IEEE M. T. Erdinç, “NUMERICAL INVESTIGATION OF FLOW AND HEAT TRANSFER IN COMMUNICATING CONVERGING AND DIVERGING CHANNELS”, Journal of Thermal Engineering, vol. 4, no. 5, pp. 2318–2332, 2018, doi: 10.18186/thermal.439057.
ISNAD Erdinç, Mehmet Tahir. “NUMERICAL INVESTIGATION OF FLOW AND HEAT TRANSFER IN COMMUNICATING CONVERGING AND DIVERGING CHANNELS”. Journal of Thermal Engineering 4/5 (June 2018), 2318-2332. https://doi.org/10.18186/thermal.439057.
JAMA Erdinç MT. NUMERICAL INVESTIGATION OF FLOW AND HEAT TRANSFER IN COMMUNICATING CONVERGING AND DIVERGING CHANNELS. Journal of Thermal Engineering. 2018;4:2318–2332.
MLA Erdinç, Mehmet Tahir. “NUMERICAL INVESTIGATION OF FLOW AND HEAT TRANSFER IN COMMUNICATING CONVERGING AND DIVERGING CHANNELS”. Journal of Thermal Engineering, vol. 4, no. 5, 2018, pp. 2318-32, doi:10.18186/thermal.439057.
Vancouver Erdinç MT. NUMERICAL INVESTIGATION OF FLOW AND HEAT TRANSFER IN COMMUNICATING CONVERGING AND DIVERGING CHANNELS. Journal of Thermal Engineering. 2018;4(5):2318-32.

Cited By



Numerical study of boundary stresses on Jeffery-Hamel flow subject to Soret/Dufour effects
Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science
https://doi.org/10.1177/09544062221126646








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