Abstract
The introduction on heat transfer enhancement using various insert configurations is presented in this chapter. The types of inserts and basic roughness elements have been discussed here.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Bhagoria JL, Saini JS, Solanki SC (2002) Heat transfer coefficient and friction factor correlation for rectangular solar air heater duct having transverse wedge shaped rib roughness on the absorber plate. J Renew Energy 25:341–369
Brognaux L, Webb RL, Charura LM, Chung BY (1997) Single-phase heat transfer in microfin tubes. J Heat Mass Transf 40:4345–4358
Burck E (1970) The influence of Prandtl number on heat transfer and pressure drop of artificially roughened channels. In: Bergles AE, Webb R (eds) Augmentation of convective heat and mass transfer. ASME, New York
Chang SW, Jan YJ, Liou JS (2007a) Turbulent heat transfer and pressure drop in tube fitted with serrated twisted tape. Int J Therm Sci 46:506–518
Chang SW, Yang TL, Liou JS (2007b) Heat transfer and pressure drop in tube with broken twisted tape insert. Exp Therm Fluid Sci 32(2):489–501
Dalle-Donne M, Meyer L (1977) Turbulent convection heat transfer from rough surfaces with two dimensional rectangular ribs. Int J Heat Mass Transf 20:583–620
Dawson DA, Trass O (1972) Mass transfer at rough surfaces. Int J Heat Mass Transf 15:1317–1336
Deshmukh PW, Vedula RP (2014) Heat transfer and friction factor characteristics of turbulent flow through a circular tube fitted with vortex generator inserts. Int J Heat Mass Transf 79:551–560
Deshmukh PW, Prabhu SV, Vedula RP (2016) Heat transfer enhancement for laminar flow in tubes using curved delta wing vortex generator inserts. Appl Therm Eng 106:1415–1426
Dipprey DF, Sabersky RH (1963) Heat and momentum transfer in smooth and rough tubes at various Prandtl numbers. Int J Heat Mass Transf 6:329–353
Dong Y, Huixiong L, Tingkuan C (2001) Pressure drop, heat transfer and performance of single-phase turbulent flow in spirally corrugated tubes. Exp Therm Fluid Sci 24:131–138
Edwards FJ (1966) The correlation of forced convection heat transfer data from rough surfaces in ducts having different shapes of flow cross section. In: Proceedings of the third international heat transfer conference, vol 1, pp 32–44
Esen EB, Obot NT, Rabas TJ (1994) Enhancement: Part II. The role of transition to turbulent flow. J Enhanc Heat Transf 1:157–167
Eiamsa-ard S, Promvonge P (2007) Heat transfer characteristics in a tube fitted with helical screw-tape with/without core-rod inserts. Int Commun Heat Mass Transf 34:176–185
Eiamsa-ard S, Pethkool S, Thianpong C, Promvonge P (2008) Turbulent flow heat transfer and pressure loss in a double pipe heat exchanger with louvered strip inserts. Int Commun Heat Mass Transf 35:120–129
Han JC (1984) Heat transfer and friction in channels with two opposite rib-roughened walls. J Heat Transf 106:774–781
Han JC, Glicksman LR, Rohsenow WM (1978) An investigation of heat transfer and friction for rib-roughened surfaces. Int J Heat Mass Transf 21:1143–1156
Han JC, Chandra PR, Lau SC (1988) Local heat/mass transfer distributions around sharp 180 deg turns in two-pass smooth and rib-roughened channels. J Heat Transf 110:91–98
Han JC, Zhang YM, Lee CP (1991) Augmented heat transfer in square channels with parallel, crossed, and V-shaped angled ribs. J Heat Transf 113:590–596
Hassan Ridouane EI, Campo A (2008) Heat transfer enhancement of air flowing across grooved channels: joint effects of channel height and groove depth. ASME J Heat Transf 130:1–7
Hsieh (2003) Experimental studies on heat transfer and flow characteristics for turbulent flow of air in a horizontal circular tube with strip type insert
Hsieh and Huang (2000) Experimental studies for heat transfer and pressure drop of laminar flow in horizontal tubes with/without longitudinal inserts
Jaber MH, Webb RL, Stryker P (1991) An experimental investigation of enhanced tubes for steam condensers, ASME Paper 91-HT-5. ASME, New York
Jaurker AR, Saini JS, Gandhi BK (2006) Heat transfer coefficient and friction characteristics of rectangular solar air heater duct using rib-grooved artificial roughness. Int J Solar Energy 80:895–907
Jayaraj D, Masilamani JG, Seetharamu KN (1989) Heat transfer augmentation by tube inserts in heat exchangers, SAE Technical paper 891983, Warrendale, PA
Layek A, Saini JS, Solanki SC (2007) Heat transfer coefficient and friction characteristics of rectangular solar air heater duct using rib-grooved artificial roughness. Int J Heat Mass Transf 50:4845–4854
Liao Q, Zhu X, Xin MD (2000) Augmentation of turbulent convective heat transfer in tubes with three-dimensional internal extended surfaces. J Enhanc Heat Transf 7(3):139–151
Manglik RM, Bergles AE (1992) Heat transfer enhancement and pressure drop in viscous liquid flows in isothermal tubes with twisted-tape inserts. Heat Mass Transf 27(4):249–257
Maezawa S, Lock GSH (1978) Heat transfer inside a tube with a novel promoter. In: Heat transfer 1978. Proceedings of the 6th international heat transfer C011f, vol 2. Hemisphere, Washington, DC, pp 596–600
Metzger DE, Fan CZ, Pennington JW (1983) Heat transfer and flow friction characteristics of very rough transverse ribbed surfaces with and without pin fins. In: Proc. 1983 ASME-JSME thermal engineering conference, vol 1, pp 429–436
Metzger DE, Vedula RP, Breen DD (1987) The effect of rib angle and length on convection heat transfer in rib-roughened triangular ducts. In: Proc. 1987 ASME-JSME thermal engineering conference, vol 3, pp 327–333
Murugesan P, Mayilsamy K, Suresh S, Srinivasan PSS (2011) Heat transfer and pressure drop characteristics in a circular tube fitted with and without V-cut twisted tape insert. Int Commun Heat Mass Transf 38:329–334
Mwesigye A, Bello-Ochende T, Meyer JP (2016) Heat transfer and entropy generation in a parabolic trough receiver with wall-detached twisted tape inserts. Int J Therm Sci 99:238–257
Naphon P (2006) Effect of coil-wire insert on heat transfer enhancement and pressure drop of the horizontal concentric tube. Int Commun Heat Mass Transf 33:753–763
Oni TO, Paul MC (2016) Numerical investigation of heat transfer and fluid flow of water through a circular tube induced with divers’ tape inserts. Appl Therm Eng 98:157–168
Petukhov BS (1970) Heat transfer in turbulent pipe flow with variable physical properties. In: Irvine TF, Hartnett JP (eds) Advances in heat transfer, vol 6. Academic Press, New York, pp 504–564
Prasad BN, Saini JS (1988) Effect of artificial roughness on heat transfer and friction factor in a solar air heater. Sol Energy 41(6):555–560
Prasad SB, Saini JS, Singh Krishna M (2009) Investigation of heat transfer and friction characteristics of packed bed solar air heater using wire mesh as packing material. Int J Solar Energy 83:773–783
Ravigururajan TS, Bergles AE (1985) General correlations for pressure drop and heat transfer for single-phase turbulent flow in internally ribbed tubes. In: Augmentation of heat transfer in energy systems, ASME Symp. HTD, vol 52, pp 9–20
Ravigururajan TS, Bergles AE (1996) Development and verification of general correlations for pressure drop and heat transfer in single-phase turbulent flow in enhanced tubes. Exp Therm Fluid Sci 13:55–70
Saha SK, Mallick DN (2005) Heat transfer and pressure drop characteristics of laminar flow in rectangular and square plain ducts and ducts with twisted-tape inserts. Trans ASME 127(9):966–977
Saravanan A, Senthilkumaar JS, Jaisankar S (2016) Performance assessment in V-trough solar water heater fitted with square and V-cut twisted tape inserts. Appl Therm Eng 102:476–486
Sarma (2003) Heat transfer coefficients with twisted tape inserts
Sethumadhavan R, Raja Rao M (1983) Turbulent flow heat transfer and fluid friction in helical wire coil inserted tubes. Int J Heat Mass Transf 26:1833–1845
Sethumadhavan R, Raja Rao M (1986) Turbulent flow friction and heat transfer characteristics of single- and multi-start spirally enhanced tubes. J Heat Transf 108:55–61
Sheriff N, Gumley P (1966) Heat transfer and friction properties of surfaces with discrete roughness. Int J Heat Mass Transf 9:1297–1320
Vicente PG, Garcia A, Viedma A (2002) Experimental study of mixed convection and pressure drop in helically dimpled tubes for laminar and transition flow. Int J Heat Mass Transf 45:5091–5105
Webb RL (1979) Toward a common understanding of the performance and selection of roughness for forced convection. In: Hartnett JP et al (eds) Studies in heat transfer: a Festschrift for E.R.G. Eckert. Hemisphere, Washington, DC, pp 257–272
Webb RL (1991) Advances in shell side boiling of refrigerants. J Inst Refrig 87:75–86
Webb RL, Eckert ERG (1972) Application of rough surfaces to heat exchanger design. Int J Heat Mass Transf 15:1647–1658
Webb RL, Kim NH (2005) Principles of enhanced heat transfer. Taylor & Francis, New York
Webb RL, Robertson GF (1988) Shell-side evaporators and condensers used in the refrigeration industry. In: Shah RK, Subbarao EC, Mashelkar RA (eds) Heat transfer equipment design. Hemisphere, Washington, DC, pp 559–570
Webb RL, Hui TS, Haman L (1984) Enhanced tubes in electric utility steam condensers. In: Sengupta S, Mussalli YF (eds) Heat transfer in heat rejection systems, Book G00265, HTD, vol 37, pp 17–26
Webb RL, Eckert ERG, Goldstein RJ (1971) Heat transfer and friction in tubes with repeated rib roughness. Int J Heat Mass Transf 14:601–617
Williams F, Pirie MAM, Warburton C (1970) Heat transfer from surfaces roughened by ribs. In: ASME symp volume augmentation of convective heat & mass transfer
Withers JG (1980a) Tube-side heat transfer and pressure drop for tubes having helical internal ridging with turbulent/transitional flow of single-phase fluid. Part l: single-helix ridging. Heat Transf Eng 2(1):48–58
Withers JG (1980b) Tube-side heat transfer and pressure drop for tubes having helical internal ridging with turbulent/transitional flow of single-phase fluid. Part 2: multiple-helix ridging. Heat Transf Eng 2(2):43–50
Ye QY, Chen WL, Marto PD, Tan YK (1987) Prediction of heat transfer characteristics in spirally fluted tubes by studying the velocity profiles and turbulence structure. In: Marto PD, Tanasawa I (eds) 1987 ASME-JSME thermal engineering joint conference, vol 5. ASME, New York, pp 189–194
Zhang YM, Gu WZ, Han JC (1994) Heat transfer and friction in rectangular channel with ribbed or ribbed-grooved walls. ASME J Heat Transf 116:58–65
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). Introduction. In: Insert Devices and Integral Roughness in Heat Transfer Enhancement. SpringerBriefs in Applied Sciences and Technology(). Springer, Cham. https://doi.org/10.1007/978-3-030-20776-2_1
Download citation
DOI: https://doi.org/10.1007/978-3-030-20776-2_1
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-030-20775-5
Online ISBN: 978-3-030-20776-2
eBook Packages: EngineeringEngineering (R0)