Thermohydraulics of Turbulent Flow Through Heat Exchanger Tubes Fitted with Circular-rings and Twisted Tapes

doi:10.1016/S1004-9541(13)60504-2

Abstract

Abstract: The influences of circular-ring turbulators (CRT) and twisted tape (TT) swirl generators on the heat transfer enhancement, pressure drop and thermal performance factor characteristics in a round tube are reported. The circular-ring turbulators were individually employed and together with the twisted tape swirl generators in the heated section of the tube. Three different pitch ratios (l/D1.0, 1.5, and 2.0) of the CRT and three different twist ratios (y/W 3, 4, and 5) of the TT were introduced. The experiments were conducted using air as the working fluid under a uniform wall heat flux condition, for the Reynolds number between 6000 and 20000. The experimental results reveal that the heat transfer rate, friction factor and thermal performance factor of the combined CRT and TT are considerably higher than those of CRT alone. For the range examined, the increases of mean Nusselt number, friction factor and thermal performance, in the tube equipped with combined devices, respectively, are 25.8%, 82.8% and 6.3% over those in the tube with the CRT alone. The highest thermal performance factor of 1.42 is found for the combined device consisting of the CRT with l/D 1.0 and TT with y/W 3. The correlations of the Nusselt number, friction factor and thermal performance factor of the tubes with combined devices are also developed in terms of Reynolds number, Prandtl number, twist ratio and pitch ratio.

Key words: heat transfer enhancement, circular-ring, twisted tape, swirl generator, turbulator, heat exchanger

摘要： The influences of circular-ring turbulators (CRT) and twisted tape (TT) swirl generators on the heat transfer enhancement, pressure drop and thermal performance factor characteristics in a round tube are reported. The circular-ring turbulators were individually employed and together with the twisted tape swirl generators in the heated section of the tube. Three different pitch ratios (l/D1.0, 1.5, and 2.0) of the CRT and three different twist ratios (y/W 3, 4, and 5) of the TT were introduced. The experiments were conducted using air as the working fluid under a uniform wall heat flux condition, for the Reynolds number between 6000 and 20000. The experimental results reveal that the heat transfer rate, friction factor and thermal performance factor of the combined CRT and TT are considerably higher than those of CRT alone. For the range examined, the increases of mean Nusselt number, friction factor and thermal performance, in the tube equipped with combined devices, respectively, are 25.8%, 82.8% and 6.3% over those in the tube with the CRT alone. The highest thermal performance factor of 1.42 is found for the combined device consisting of the CRT with l/D 1.0 and TT with y/W 3. The correlations of the Nusselt number, friction factor and thermal performance factor of the tubes with combined devices are also developed in terms of Reynolds number, Prandtl number, twist ratio and pitch ratio.

关键词: heat transfer enhancement, circular-ring, twisted tape, swirl generator, turbulator, heat exchanger

Smith Eiamsa-ard, Vichan Kongkaitpaiboon, Kwanchai Nanan. Thermohydraulics of Turbulent Flow Through Heat Exchanger Tubes Fitted with Circular-rings and Twisted Tapes[J]. Chin.J.Chem.Eng., DOI: 10.1016/S1004-9541(13)60504-2.

References

1 Eiamsa-ard, S., Promvonge, P., “Experimental investigation of heat transfer and friction characteristics in a circular tube fitted with V-nozzle turbulators”, Int. Comm. Heat Mass Transfer, 33, 591-600 (2006).

2 Promvonge, P., Eiamsa-ard, S., “Heat transfer and turbulent flow friction in a circular tube fitted with conical-nozzle turbulators”, Int. Comm. Heat Mass Transfer, 34, 72-82 (2007).

3 Yakut, K., Sahin, B., Canbazoglu, S., “Performance and flow-induced vibration characteristics for conical-ring turbulators”, Appl. Energy, 79, 65-76 (2004).

4 Yakut, K., Sahin, B., “Flow-induced vibration analysis of conical rings used of heat transfer enhancement in heat exchanger”, Appl. Energy, 78, 273-288 (2004).

5 Promvonge, P. “Heat transfer behaviors in round tube with conical ring inserts”, Energy Conver. Manag., 49, 8-15 (2008).

6 Eiamsa-ard, S., Promvonge, P., “Thermal characterization of turbulent tube flows over diamond-shaped elements in tandem”, Int. J. Therm. Sci., 49, 1051-1062 (2010).

7 Kongkaitpaiboon, V., Nanan, K., Eiamsa-ard, S., “Experimental investigation of convective heat transfer and pressure loss in a round tube fitted with circular-ring turbulators”, Int. Comm. Heat Mass Transfer, 37, 568-574 (2010).

8 Kongkaitpaiboon, V., Nanan, K., Eiamsa-ard, S., “Experimental investigation of heat transfer and turbulent flow friction in a tube fitted with perforated conical-rings”, Int. Comm. Heat Mass Transfer, 37, 560-567 (2010).

9 Durmus, A., “Heat transfer and exergy loss in cut out conical turbulators”, Energy Conver. Manag., 45, 785-796 (2004).

10 Kiml, R., Mochizuki, S., Murata, A., Stoica, V., “Effects of rib-induced secondary flow on heat transfer augmentation inside a circular tube”, J. Enhanced Heat Transfer, 10, 9-20 (2003).

11 Kiml, R., Magda, A., Mochizuki, S., Murata, A., “Rib-induced secondary flow effects on local circumferential heat transfer distribution inside a circular rib-roughened tube”, Int. J. Heat Mass Transfer, 47, 1403-1412 (2004).

12 Jaisankar, S., Radhakrishnan, T.K., Sheeba, K.N., Suresh, S., “Experimental investigation of heat transfer and friction factor characteristics of thermosyphon solar water heater system fitted with spacer at the trailing edge of left-right twisted tapes”, Energy Conver. Manag., 50, 2638-2649 (2009).

13 Liao, Q., Xin, M.D., “Augmentation of convective heat transfer inside tubes with three-dimensional internal extended surfaces and twisted-tape inserts”, Chem. Eng. J., 78, 95-105 (2000).

14 Zimparov, V., “Enhancement of heat transfer by a combination of three-start spirally corrugated tubes with a twisted tape”, Int. J. Heat Mass Transfer, 44, 551-574 (2001).

15 Zimparov, V., “Enhancement of heat transfer by a combination of a single-start spirally corrugated tubes with a twisted tape”, Exp. Therm. Fluid Sci., 25, 535-546 (2002).

16 Hong, M.N., Deng, X.H., Huang, K., Li, Z.W., “Compound heat transfer enhancement of a converging-diverging tube with evenly spaced twisted-tapes”, Chin. J. Chem. Eng., 15, 814-820 (2007).

17 Pramanik, D., Saha, S.K., “Thermohydraulics of laminar flow through rectangular and square ducts with transverse ribs and twisted tapes”, Int. J. Heat Transfer Trans., 128, 1070-1080 (2006).

18 Bharadwaj, P., Khondge, A.D., Date, A.W., “Heat transfer and pressure drop in a spirally grooved tube with twisted tape insert”, Int. J. Heat Mass Transfer, 52, 1938-1944 (2009).

19 Al-Fahed, S., Chamra, L.M., Chakroun, W., “Pressure drop and heat transfer comparison for both microfin tube and twisted-tape inserts in laminar flow”, Exp. Therm. Fluid Sci., 18, 323-333 (1998).

20 Thianpong, C., Eiamsa-ard, P., Wongcharee, K., Eiamsa-ard, S., “Compound heat transfer enhancement of a dimpled tube with a twisted tape swirl generator”, Int. Comm. Heat Mass Transfer, 36, 698-704 (2009).

21 Promvonge, P., Eiamsa-ard, S., “Heat transfer behaviors in a tube with combined conical-ring and twisted-tape insert”, Int. Comm. Heat and Mass Transfer, 34, 849-859 (2007).

22 Promvonge, P., “Thermal augmentation in circular tube with twisted tape and wire coil turbulators”, Energy Conver. Manag., 49, 2949-2955 (2008).

23 Eiamsa-ard, S., Nivesrangsan, P., Chokphoemphun S., Promvonge, P., “Influence of combined non-uniform wire coil and twisted tape inserts on thermal performance characteristics”, Int. Comm, Heat Mass Transfer, 34, 849-859 (2010).

24 Pal, P.K., Saha, S.K., “Thermal and friction characteristics of laminar flow through square and rectangular ducts with transverse ribs and twisted tapes with and without oblique teeth”, J. Enhanced Heat Transfer, 17, 1-21 (2010).

25 Zhang, Y.M., Azad, G.M., Han, J.C., Lee, C.P., “Turbulent heat transfer enhancement and surface heating effect in square channels with wavy, and twisted tape inserts with interrupted ribs”, J. Enhanced Heat Transfer, 7, 5-49 (2000).

26 Murugesan, P., Mayilsamy, K., Suresh, S., “Heat transfer and friction factor studies in a circular tube fitted with twisted tape consisting of wire-nails”, Chin. J. Chem. Eng., 18, 1038-1042 (2010).

27 Japanese Industrial Standard, “Measurement of Fluid Flow by Means of Orifice Plates, Nozzles and Venturi Tubes”, Japanese Standards Association, Japan, JIS Z 8762-1988 (1988).

28 ANSI/ASME, “Measurement Uncertainty”, PTC 19, 1-1985. Part I (1986).

29 Webb, R.L., Kim N.H., Principles of Enhanced Heat Transfer, 2nd edition, Taylor& Francis Group, New York (2005).

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