Abstract
This chapter has been dedicated to understand the basic concepts of vortex generators for heat transfer enhancement in plate-fin heat exchangers. The performance of transverse, longitudinal, and wing-type vortex generators has been discussed.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Ahmed HE, Mohammed HA, Yusoff MZ (2012a) An overview on heat transfer augmentation using vortex generators and nanofluids: approaches and applications. Renew Sust Energ Rev 16:5951–5993
Ahmed HE, Mohammed HA, Yusoff MZ (2012b) Heat transfer enhancement of laminar nanofluids flow in a triangular duct using vortex generators. Superlattice Microst 52:398–415
Althaher MA, Abdul-Rassol AA, Ahmed HE, Mohammed HA (2012) Turbulent heat transfer enhancement in a triangular duct using delta-winglet vortex generators. Heat Transfer Asian Res 41:43–62
Amon CH (1989) Numerical investigation of starting flow and supercritical heat transfer enhancement in grooved channels: understanding and exploitation. In: Proceedings of the 10th Brazil cong mech eng, Rio de Janeiro, pp 197–200
Amon CH, Mikic BB (1989) Spectral element simulation of forced convective heat transfer. Application to slotted channel flow. In: National heat transfer conference, HTD, vol 110, pp 175–183
Amon CH, Mikic BB (1990) Numerical prediction of convective heat transfer in self-sustained oscillatory flows. J Thermophys Heat Transfer 4(2):239–246
Aris MS, McGlen R, Owen I, Sutcliffe CJ (2011) An experimental investigation into the deployment of 3-D, finned wing and shape memory alloy vortex generators in a forced air convection heat pipe fin stack. Appl Therm Eng 31:2230–2240
Brockmeier U (1987) Numerisches Verfahren zur Berechnung dreidimensionaler Stromungs- und Temperaturfelder in Kanlilen mit Llingswirbelerzeugern und Untersuchung von Warmeiibergang und Stromungsverlust. Dissertation, Ruhr-Universitiit Bochum
Brockmeier U, Fiebig M, Güntermann T, Mitra NK (1989) Heat transfer enhancement in fin-plate heat exchangers by wing type vortex generators. Chem Eng Technol 12(1):288–294
Brockmeier U, Guntermann T, Fiebig M (1993) Performance evaluation of a vortex generator heat transfer surface and comparison with different high performance surface. Int J Heat Mass Transfer 36:2575–2587
Chen Y (1993) Numerische Untersuchungen von Lamellen-RohrWarmeiibertragerelementen unter Beriicksichtigung der Warmeleitung in den Lamellen. Diplomarbeit Nr. 93/12, Ruhr-Universitiit Bochum
Chen TY, Shu HT (2004) Flow structures and heat transfer characteristics in fan flows with and without delta-wing vortex generators. Exp Thermal Fluid Sci 28:273–282
Chomdee S, Kiatsiriroat T (2006) Enhancement of air cooling in staggered array of electronic modules by integrating delta winglet vortex generators. Int Commun Heat Mass Transfer 33:618–626
Dake T, Majdalani J (2009) Improving flow circulation in heat sinks using quadrupole vortices. In: Proceedings of the ASME 2009 InterPACK conference. American Society of Mechanical Engineers, San Francisco, CA
Dong Y (1989) Experimentelle Untersuchung der Wechselwirkungen von Liingswirbelerzeugern und Kreiszylindern in Kanalstromungen in Bezug aufWarmeiibergang und Stromungsverlust. Dissertation, Ruhr-Universitiit Bochum
Edwards FJ, Sherill N (1974) The improvement of forced surface heat transfer using surface protrusions in the form of cubes and vortex generators. In: Proceedings of the 5th international heat transfer conference, vol 2. Tokyo, pp 244–248
Eibeck PA, Eaton JK (1987) Heat transfer effects of a longitudinal vortex embedded in a turbulent shear flow. J Heat Transfer 109:16–24
Ellouze A, Blancher S, Crelf R (1993) Flow structure and heat transfer in a wavy wall channel at steady and unsteady flow regime. In: Proc Eurotherm 31 “Vortices and Heat Transfer”, Bochum, Germany, pp 30–35
Esformes JL (1989) Ramp wing enhanced plate fin. U.S. patent 4,817, p 709
Fiebig M (1995) Vortex generators for compact heat exchangers. J Enhanc Heat Transf 2:1–2
Fiebig M, Brockmeier U, Mitra NK, Gü Termann T (1989) Structure of velocity and temperature fields in laminar channel flows with longitudinal vortex generators. Numer Heat Transfer Appl 15(3):281–302
Fiebig M, Giintermann T (1989) Heat transfer enhancement by longitudinal vortex generators. In: Proceedings of the 10th Brazil cong mech eng, Rio de Janeiro, pp 445–448
Fiebig M, Valencia A, Mitra NK (1993) Wing-type vortex generators for fin-and-tube heat exchangers. Exp Therm Fluid Sci 7(4):287–295
Fiebig M, Kallweit P, Mitra NK (1986) Wing type vortex generators for heat transfer enhancement. IHTC, vol 6, pp 2909–2913
Fiebig M, Guntermann T (1993a) A class of high performance compact fin-plate heat exchanger elements. In: Lee JS, Chung SH, Kim KH (eds) The 6th Int symp on transport phenomena in thermal engineering, vol III. Korean Society of Mechanical Engineering, Seoul, pp 49–54
Fiebig M, Guntermann T (1993b) Heat transfer surfaces with longitudinal vortex generators for compact plate heat exchangers. In: Proc 1st international thermal energy congress ITEC93, vol 1. Marakesch
Fiebig M, Guntermann T, Mitra NK (1995) Numerical analysis of heat transfer and flow loss in a parallel plate heat exchanger element with longitudinal vortex generators as fins. J Heat Transfer 117(4):1064–1068
Ferrouillat S, Tochon P, Garnier C, Peerhossaini H (2006) Intensification of heat-transfer and mixing in multifunctional heat exchangers by artificially generated streamwise vorticity. Appl Therm Eng 26:1820–1829
Guntermann T (1992) Dreidimensionale stationare und selbsterregt-schwingende Stromungs- und Temperaturfelder in Hochleistungswiirmeiibertragern mit Wirbelerzeugern. Dissertation, RuhrUniversitat Bochum
Greiner M, Chen RF, Witz RA (1989) Heat transfer augmentation through wall shape induced flow destabilization. In: National heat tranefer conference, HTD, vol 107
Grosse-Gorgemann A, Weber D, Fiebig M (1993b) Numerical and experimental investigation of self-sustained oscillations in channels with periodic structures. In: Proc Eurotherm 31 “Vortices and Heat Transfer”, Bochum, Germany, pp 42–50
Grosse-Gorgemann A, Weber D, Fiebig M (1993c) Self-sustained oscillations: heat transfer and flow losses in Laminar channel flow with rectangular vortex generators. In: Proc Eurotherm 31 “Vortices and Heat Transfer”, Bochum, Germany, pp 107–111
Henze M, von Wolfersdorf J, Weigand B, Dietz CF, Neumann SO (2011) Flow and heat transfer characteristics behind vortex generators – a benchmark dataset. Int J Heat Fluid Flow 32:318–328
Henze M, von Wolfersdorf J (2011) Influence of approach flow conditions on heat transfer behind vortex generators. Int J Heat Mass Transf 54:279–287
Herman CV, Mayinger F, Sekulic DP (1991) Experimental verification of oscillatory phenomena in heat transfer in a Communicating Channel geometry. Proc 2nd world conf on exp heat transf, Fluid mech and thermodynamics, June 23–28, Dubrovnik, Yugoslavia
Huisseune H, T’Joen C, De Jaeger P, Ameel B, De Schampheleire S, De Paepe M (2013a) Performance enhancement of a louvered fin heat exchanger by using delta winglet vortex generators. Int J Heat Mass Transf 56:475–487
Huisseune H, T’Joen C, De Jaeger P, Ameel B, De Schampheleire S, De Paepe M (2013b) Influence of the louver and delta winglet geometry on the thermal hydraulic performance of a compound heat exchanger. Int J Heat Mass Transf 57:58–72
Joardar A, Jacobi AM (2007) A numerical study of flow and heat transfer enhancement using an array of delta-winglet vortex generators in a fin-and-tube heat exchanger. J Heat Transf 129:1156–1167
Kallweit P (1986) Liingswirbelerzeuger fiir den Einsatz in Lamellenwiirmetauschern. Dissertation, Ruhr-Universitiit Bochum
Kays WM, London AL (1984) Compact heat exchangers. 3rd Edition, McGraw-Hill, New York
Kline SJ, McClintok F (1953) Describing uncertainty in single sample experiments. Mech Eng 75:3–8
Kotcioglu I, Caliskan S (2008) Experimental investigation of a cross-flow heat exchanger with wing-type vortex generators. J Enhanc Heat Transf 15(2):113–127
Kotcioğlu İ, Ayhan T, Olgun H, Ayhan B (1998) Heat transfer and flow structure in a rectangular channel with wing-type vortex generator. Turk J Eng Environ Sci 22(3):185–196
Lee GH (1979) Effect of vortex generators on the heat transfer from rectangular plate fins. The Lumus Company Limited, Heat Transfer Division, England, Report No. HR-159
Lee KB, Kwon YK (1992) Flow and thermal field with relevance to heat transfer enhancement of interrupted-plate heat exchangers. Exp Heat Transfer 5:83–100
Leu JS, Wu YH, Jang JY (2004) Heat transfer and fluid flow analysis in plate-fin and tube heat exchangers with a pair of block shape vortex generators. Int J Heat Mass Transf 47:4327–4338
Li HY, Chen CL, Chao SM, Liang GF (2013) Enhancing heat transfer in a plate-fin heat sink using delta winglet vortex generators. Int J Heat Mass Transf 67:666–677
Li HY, Liao WR, Li TY, Chang YZ (2017) Application of vortex generators to heat transfer enhancement of a pin-fin heat sink. Int J Heat Mass Transf 112:940–949
Mehta RD, Shabaka IM, Shibi A, Bradshaw P (1983) Longitudinal vortices imbedded in turbulent boundary layers. AIAA Paper, Albuquerque, NM
Milliat JP (1961) Experimental study of finned cans of the ‘herring-bone’ type. In: Int. j. Brit. nuclear energy conf., vol 6, Electricite de France, Chatou
Min C, Qi C, Kong X, Dong J (2010) Experimental study of rectangular channel with modified rectangular longitudinal vortex generators. Int J Heat Mass Transf 53:3023–3029
Mullisen RS, Loehrke RI (1986) A study of the flow mechanisms responsible for heat transfer enhancement in interrupted-plate heat exchangers. J Heat Transfer 108:377–385
Oğulata RT, Doba F, Yilmaz T (2000) Irreversibility analysis of cross flow heat exchangers. Energy Convers Manag 41(15):1585–1599
Pang K, Tao WQ, Zhang HH (1990) Numerical analysis of fully developed fluid flow and heat transfer for arrays of interrupted plates positioned convergently-divergently along the flow direction. Numer Heat Transfer Part A 18:309–324
Patankar SV, Prakash C (1981) An analysis of the effect of plate thickness on laminar flow and heat transfer in interrupted plate passages. Int J Heat Mass Transfer 24:1801–1810
Pauley WR, Eaton JK (1988) Experimental study of the development of longitudinal vortex pairs embedded in a turbulent boundary layer. AIAA J 26:816–823
Pescod D (1974) The effects of turbulence promoters on the performance of plate heat exchangers. In: Heat exchangers: design and theory sourcebook. Scripta Book Company, Washington, pp 601–616
Pesteei SM, Subbarao PM, Agarwal RS (2005) Experimental study of the effect of winglet location on heat transfer enhancement and pressure drop in fin-tube heat exchangers. Appl Therm Eng 25(11–12):1684–1696
Riemann K-A (1992) Wiirmeiibergang und Druckabfall in Kaniilen mit periodischen Wirbelerzeugern bei thermischem Anlauf. Dissertation, Ruhr-Universitiit Bochum
Russel CMB, Jones TV, Lee GH (1982) Heat transfer enhancement using vortex generators. In: Proceedings of the 7th international heat transfer conference, vol 3, pp 283–288
Sahin B, Yakut K, Kotcioglu I, Celik C (2005) Optimum design parameters of a heat exchanger. Appl Energy 82(1):90–106
Sinha A, Raman KA, Chattopadhyay H, Biswas G (2013) Effects of different orientations of winglet arrays on the performance of plate-fin heat exchangers. Int J Heat Mass Transf 57:202–214
Tauscher R, Mayinger F (1997) Enhancement of heat transfer in a plate heat exchanger by turbulence promoters. In: Shah RK, Bell KJ, Mochizuki S, Wadekar VW (eds) Proc of the int conf on compact heat exchangers for the process industries. Begell House Inc., New York, pp 253–360
Tian LT, He YL, Lei YG, Tao WQ (2009) Numerical study of fluid flow and heat transfer in a flat-plate channel with longitudinal vortex generators by applying field synergy principle analysis. Int Commun Heat Mass Transfer 36:111–120
Tiggelbeck S (1990) Experirnentelle Untersuchungen an Kanalstromungen mit Einzel- und Doppel-Wirbelerzeuger-Reihen fiir den Einsatz in kompakten Wiirmetauschem. Dissertation, RuhrUniversitiit Bochum
Tiggelbeck T, Mitra NK, Fiebig M (1993) Experimental investigations of heat transfer and flow losses in a channel with double rows of longitudinal vortex generators. Int J Heat Mass Transf 36(9):2327–2337
Tiggelbeck S, Mitra NK, Fiebig M (1994) Comparison of wing-type vortex generators for heat transfer enhancement in channel flows. J Heat Transfer 116:880–885
Torii K, Nishina K, Nakayama K (1994) Mechanism of heat transfer augmentation by longitudinal vortices in a flat plate boundary layer. In: Heat transfer proc 10th int heat trans conf, vol 5, pp 123–128
Valencia A (1993) Wiirmeiibergang und Druckverlust in LamellenRohr-Wiirmeiibertragern mil Liingswirbelerzeugern. Dissertation, Ruhr-Universitiit Bochum
Vasudevan R, Eswaran V, Biswas G (2000) Winglet-type vortex generators for plate-fin heat exchangers using triangular fins. Numer Heat Trans Part A 38(5):533
Wang CC, Lo J, Lin YT, Wei CS (2002) Flow visualization of annular and delta winlet vortex generators in fin-and-tube heat exchanger application. Int J Heat Mass Transf 45(18):3803–3815
Yakut K, Alemdaroglu N, Kotcioglu I, Celik C (2006) Experimental investigation of thermal resistance of a heat sink with hexagonal fins. Appl Therm Eng 26(17–18):2262–2271
Yang KS, Li SL, Chen IY, Chien KH, Hu R, Wang CC (2010a) An experimental investigation of air cooling thermal module using various enhancements at low Reynolds number region. Int J Heat Mass Transf 53:5675–5681
Yang KS, Jhong JH, Lin YT, Chien KH, Wang CC (2010b) On the heat transfer characteristics of heat sinks: with and without vortex generators. IEEE Trans Compon Packag Technol 33:391–397
Zhang Z (1989) Einflu8 von Deltafugel-Wirbelerzeugem auf Wiirmeiibergang und Druckverlust in Spaltstromungen. Dissertation, Ruhr-Universitiit Bochum
Author information
Authors and Affiliations
Rights and permissions
Copyright information
© 2020 The Author(s), under exclusive license to Springer Nature Switzerland AG
About this chapter
Cite this chapter
Saha, S.K., Ranjan, H., Emani, M.S., Bharti, A.K. (2020). Vortex Generators. In: Heat Transfer Enhancement in Plate and Fin Extended Surfaces. SpringerBriefs in Applied Sciences and Technology(). Springer, Cham. https://doi.org/10.1007/978-3-030-20736-6_4
Download citation
DOI: https://doi.org/10.1007/978-3-030-20736-6_4
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-030-20738-0
Online ISBN: 978-3-030-20736-6
eBook Packages: EngineeringEngineering (R0)