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Internally Finned Tubes and Spirally Fluted Tubes

  • Sujoy Kumar Saha
  • Hrishiraj Ranjan
  • Madhu Sruthi Emani
  • Anand Kumar Bharti
Chapter
Part of the SpringerBriefs in Applied Sciences and Technology book series (BRIEFSAPPLSCIENCES)

Abstract

The heat transfer and pressure drop characteristics of internally finned tubes and spirally fluted tubes are presented in detail in this chapter. The correlations for Nusselt number and friction factor are also presented and discussed.

Keywords

Internally finned tubes Spirally fluted tubes Advanced internal fin geometries Laminar flow Turbulent flow Annuli 

References

  1. Afroz HM, Miyara A (2007) Friction factor correlation and pressure loss of single-phase flow inside herringbone microfin tubes. Int J Refrig 30(7):1187–1194CrossRefGoogle Scholar
  2. Alam I, Ghoshdastidar PS (2002) A study of heat transfer effectiveness of circular tubes with internal longitudinal fins having tapered lateral profiles. Int J Heat Mass Transf 45:1371–1376zbMATHCrossRefGoogle Scholar
  3. Al-Fahed SF, Ayub ZH, Al-Marafie AM, Soliman BM (1993) Heat transfer and pressure drop in a tube with internal microfins under turbulent water flow conditions. Exp Thermal Fluid Sci 7(3):249–253CrossRefGoogle Scholar
  4. Al-Fahed S, Chamra LM, Chakroun W (1998) Pressure drop and heat transfer comparison for both microfin tube and twisted-tape inserts in laminar flow. Exp Thermal Fluid Sci 18(4):323–333CrossRefGoogle Scholar
  5. Arnold JA, Garimella S, Christensen RN (1993) Fluted tube heat exchanger design manual. GRI Report 5092-243-2357Google Scholar
  6. Aroonrat K, Jumpholkul C, Leelaprachakul R, Dalkilic AS, Mahian O, Wongwises S (2013) Heat transfer and single-phase flow in internally grooved tubes. Int Commun Heat Mass Transf 42:62–68CrossRefGoogle Scholar
  7. Barba A, Bergles G, Gosman AD, Launder BE (1983) The prediction of convective heat transfer in viscous flow through spirally fluted tubes. ASME Paper 83-WA/HT-37Google Scholar
  8. Bandarra Filho EP, Saiz Jabardo JM, Lopez Barbieri PE (2004) Convective boiling pressure drop of refrigerant R-134A in horizontal smooth and microfin tubes. Int J Refrig 27:895–903CrossRefGoogle Scholar
  9. Bar-Cohen A, Kraus AD (1990) Advances in thermal modeling of electronic components and systems. ASME, New York, p 2Google Scholar
  10. Baughn JW, Kapila K, Perera CK, Yan X (1993) An experimental study of local heat transfer in a spirally fluted tube. In: Turbulent enhanced heat transfer, HTD, vol 239, pp 49–56Google Scholar
  11. Bergles AE, Joshi SD (1983) Augmentation techniques for low Reynolds number in-tube flow. In: Kakaç S, Shah RK, Bergles AE (eds) Low Reynolds number flow heat exchangers. Hemisphere, Washington, DC, pp 694–720Google Scholar
  12. Bergles AE, Manglik RM (2013) Current progress and new development in enhanced heat and mass transfer. J Enhanc Heat Transf 20(1):1–15CrossRefGoogle Scholar
  13. Bergman TL, Lavine AS, Incropera FP, Dewitt DP (2011) Introduction to heat transfer, 6th edn. Wiley, New YorkGoogle Scholar
  14. Bhatia RS, Webb RL (2001) Numerical study of turbulent flow and heat transfer in microfin tubes—part 2, parametric study. J Enhanc Heat Transf 8:305–314CrossRefGoogle Scholar
  15. Bilen K, Cetin M, Gul H, Balta T (2009) The investigation of groove geometry effect on heat transfer for internally grooved tubes. Appl Therm Engg 29(4):753–761CrossRefGoogle Scholar
  16. Blumenkrantz A, Taborek J (1971) Heat transfer and pressure drop characteristics of Turbotec spirally deep grooved tubes in the laminar and transition regime. Report 2439-300-8, April 1971, Heat Transfer Research, Inc.Google Scholar
  17. Bogart J, Thors P (1999) In-tube evaporation and condensation of R-22 and R-410A with plain and internally enhanced tubes. J Enhanc Heat Transf 6:37–50CrossRefGoogle Scholar
  18. Braga CVM, Saboya FEM (1986) Turbulent heat transfer and pressure drop in smooth and finned annular ducts. In: Heat transfer 1986, vol 6. Hemisphere Publishing Corporation, Washington, DC, pp 2831–2836Google Scholar
  19. Brognaux LJ, Webb RL, Chamra LM, Chung BY (1997) Single-phase heat transfer in micro-fin tubes. Int J Heat Mass Transf 40:4345–4357CrossRefGoogle Scholar
  20. Carnavos TC (1979) Cooling air in turbulent flow with internally finned tubes. Heat Transf Eng 1(2):41–46CrossRefGoogle Scholar
  21. Carnavos TC (1980) Heat transfer performance of internally finned tubes in turbulent flow. Heat Transf Eng 4(1):32–37CrossRefGoogle Scholar
  22. Cavallini A, Del Col D, Doretti L, Longo GA, Rossetto L (1997) Pressure drop during condensation and vaporization of refrigerants inside enhanced tubes. Heat Technol 15(1):3–10Google Scholar
  23. Cavallini A, Del Col D, Mancin S, Rossetto L (2006) Thermal performance of R-410A condensing in a microfin tube. In: Proceedings of the international refrigeration conference at Purdue, R178Google Scholar
  24. Celen A, Dalkilic AS, Wongwises S (2013) Experimental analysis of the single phase pressure drop characteristics of smooth and micro-fin tubes. Int Commun Heat Mass Transf 46:58–66CrossRefGoogle Scholar
  25. Chamra LM, Mago PJ (2007) Modeling of evaporation heat transfer of pure refrigerants and refrigerant mixtures in microfin tubes. Proc Inst Mech Eng, Part C J Mech Eng Sci 221:443–454CrossRefGoogle Scholar
  26. Chang SW, Jan YJ, Liou JS (2007) Turbulent heat transfer and pressure drop in tube fitted with serrated twisted tape. Int J Therm Sci 46(5):506–518CrossRefGoogle Scholar
  27. Chen J, Muller-Steinhagen H, Duffy GG (2001) Heat transfer enhancement in dimpled tubes. Appl Therm Eng 21:535–547CrossRefGoogle Scholar
  28. Choi JY, Kedzierski MA, Domanski PA (2001) Generalized pressure drop correlation for evaporation and condensation in smooth and microfin tubes. In: Proc of IIF-IIR Commission B1 Paderborn Germany, vol B4, pp 9–16Google Scholar
  29. Choi JM, Kim Y, Lee M (2010) Air side heat transfer coefficients of discreteplate finned-tube heat exchangers with large fin pitch. Appl Therm Eng 30(s2–3):174–180CrossRefGoogle Scholar
  30. Choudhury D, Patankar SV (1985) Analysis of developing laminar flow and heat transfer in tubes with radial internal fins. In: Shenkman SM, O’Brien JE, Habib IS, Kohler JA (eds) Advances in enhanced heat transfer, HTD, vol 43, pp 57–64Google Scholar
  31. Collier JG, Thome JR (1994) Convective boiling and condensation, 3rd edn. Oxford University Press, OxfordGoogle Scholar
  32. Cope WG (1945) The friction and heat transmission coefficients of rough pipes. Proc Inst Mech Eng 145:99–105CrossRefGoogle Scholar
  33. Copetti JB, Macagnan MH, de Souza D, Oliveski RDC (2004) Experiments with micro-fin tube in single phase. Int J Refrig 27(8):876–883CrossRefGoogle Scholar
  34. Dagtekin I, Oztop HF, Sahin AZ (2005) An analysis of entropy generation through a circular duct with different shaped longitudinal fins for laminar flow. Int J Heat Mass Transf 48:171–181zbMATHCrossRefGoogle Scholar
  35. Dipprey DF, Sabersky RH (1963) Heat and momentum transfer in smooth and rough tubes at various Prandtl number. Int J Heat Mass Transf 6:329–353CrossRefGoogle Scholar
  36. Duan L, Ling X, Peng H (2018) Flow and heat transfer characteristics of a double-tube structure internal finned tube with blossom shape internal fins. Appl Therm Eng 128:1102–1115CrossRefGoogle Scholar
  37. Eckert ERG, Irvine TF (1960) Pressure drop and heat transfer in a duct with triangular cross section. J Heat Transf 82(2):125–136CrossRefGoogle Scholar
  38. El-Sayed SA, Abdel-Hamid ME, Sadoun MM (1997) Experimental study of turbulent flow inside a circular tube with longitudinal interrupted fins in the streamwise direction. Exp Therm Fluid Sci 15:1–15CrossRefGoogle Scholar
  39. Fabbri G (1998) Heat transfer optimization in internally finned tubes under laminar flow conditions. Int J Heat Mass Transf 41(10):1243–1253zbMATHCrossRefGoogle Scholar
  40. Fabbri G (1999) Optimum profiles for asymmetrical longitudinal fins in cylindrical ducts. Int J Heat Mass Transf 42:511–523zbMATHCrossRefGoogle Scholar
  41. Fabbri G (2004) Effect of viscous dissipation on the optimization of the heat transfer in internally finned tubes. Int J Heat Mass Transf 47:3003–3015zbMATHCrossRefGoogle Scholar
  42. Fabbri G (2005) Optimum cross-section design of internally finned tubes cooled by a viscous fluid. Control Eng Pract 13:929–938CrossRefGoogle Scholar
  43. Fujie K, Itoh N, Innami T, Kimura H, Nakayama N, Yanugidi T (1977) Heat transfer pipe. U. S. Patent 4,044,797, assigned to Hitachi LtdGoogle Scholar
  44. García A, Solano JP, Vicente PG, Viedma A (2012) The influence of artificial roughness shape on heat transfer enhancement: corrugated tubes, dimpled tubes and wire coils. Appl Therm Eng 35:196–201CrossRefGoogle Scholar
  45. Garimella S, Christensen RN (1995a) Heat transfer and pressure drop characteristics of spirally fluted annuli: part I—hydrodynamics. J Heat Transf 117:54–60CrossRefGoogle Scholar
  46. Garimella S, Christensen RN (1995b) Heat transfer and pressure drop characteristics of spirally fluted annuli: park II—heat transfer. J Heat Transf 117:61–68CrossRefGoogle Scholar
  47. Gee DL, Webb RL (1980) Forced convection heat transfer in helically rib-roughened tubes. Int J Heat Mass Transf 23(8):1127–1136CrossRefGoogle Scholar
  48. Ghiaasiaan SM (2008) Two-phase flow boiling and condensation. Cambridge University Press, CambridgezbMATHGoogle Scholar
  49. Goto M, Inoue N, Ishiwatari N (2001) Condensation and evaporation heat transfer of R-410A inside internally grooved horizontal tubes. Int J Refrig 24(7):628–638CrossRefGoogle Scholar
  50. Goto M, Inoue N, Yonemoto R (2003) Condensation heat transfer of R410A inside internally grooved horizontal tubes. Int J Refrig 26(4):410–416CrossRefGoogle Scholar
  51. Gowen RA, Smith JW (1968) Turbulent heat transfer from smooth and rough surfaces. Int J Heat Mass Transf 11:1657–1673CrossRefGoogle Scholar
  52. Hamilton LJ, Kedzierski MA, Kaul MP (2008) Horizontal convective boiling of pure and mixed refrigerants within a micro-fin tube. J Enhanc Heat Transf 15(3):211–226CrossRefGoogle Scholar
  53. Han DH, Lee KJ (2005) Single-phase heat transfer and flow characteristics of micro-fin tubes. Appl Therm Engg 25(11–12):1657–1669CrossRefGoogle Scholar
  54. Hatami M, Jafaryar M, Ganji DD, Gorji-Bandpy M (2014) Optimization of finned-tube heat exchangers for diesel exhaust waste heat recovery using CFD and CCD techniques. Int Commun Heat Mass 57:254–263CrossRefGoogle Scholar
  55. Hatami M, Ganji DD, Gorji-Bandpy M (2015) Experimental and numerical analysis of the optimized finned-tube heat exchanger for OM314 diesel exhaust exergy recovery. Energy Convers Manag 97:26–41CrossRefGoogle Scholar
  56. Hilding WE, Coogan CH Jr (1964) Heat transfer and pressure drop in internally finned tubes. In: ASME symposium on air cooled heat exchangers. ASME, New York, pp 57–84Google Scholar
  57. Hu MH, Chang YP (1973) Optimization of finned tubes for heat transfer in laminar flow. J Heat Transf 95(3):332–338CrossRefGoogle Scholar
  58. Huang D, Zhao RJ, Liu Y (2014) Effect of fin types of outdoor fan-supplied finned-tube heat exchanger on periodic frosting and defrosting performance of a residential air-source heat pump. Appl Therm Eng 69(1–2):251–260CrossRefGoogle Scholar
  59. Huq M, Huq AAU, Rahman MM (1998) Experimental measurements of heat transfer in an internally finned tube. Int Commun Heat Mass Transf 25(5):619–630CrossRefGoogle Scholar
  60. Iqbal Z, Syed KS, Ishaq M (2013) Optimal fin shape in finned double pipe with fully developed laminar flow. Appl Therm Eng 51:1202–1223CrossRefGoogle Scholar
  61. Islam MA, Mozumder AK (2009) Forced convection heat transfer performance of an internally finned tube. J Mech Eng 40:54–62CrossRefGoogle Scholar
  62. Ivanović M, Selimović R, Bajramović R (1990) Mathematical modeling of heat transfer in internally finned tubes. In: Hanjalić H (ed) Mathematical modeling and computer simulation of processes in energy systems. Hemisphere Publishing Corp, Washington, DC, pp 147–153Google Scholar
  63. Jensen MK, Vlakancic A (1999) Technical note experimental investigation of turbulent heat transfer and fluid flow in internally finned tubes. Int J Heat Mass Transf 42(7):1343–1351CrossRefGoogle Scholar
  64. Kelkar KM, Patankar SV (1990) Numerical prediction of fluid flow and heat transfer in a circular tube with longitudinal fins interrupted in the steamwise direction. J Heat Transf 112:342–348CrossRefGoogle Scholar
  65. Kido O, Taniguchi M, Taira T, Uehara H (1995) Evaporation heat transfer of HCFC22 inside an internally grooved horizontal tube. Proc ASME/JSME Therm Eng Conf 2:323–330Google Scholar
  66. Kim NH (2015a) Single-phase pressure drop and heat transfer measurements of turbulent flow inside helically dimpled tubes. J Enhanc Heat Transf 22(4):345–363CrossRefGoogle Scholar
  67. Kim NH (2015b) Effect of aspect ratio on evaporation heat transfer and pressure drop of R-410A in flattened microfin tubes. J Enhanc Heat Transf 22(3):177–197CrossRefGoogle Scholar
  68. Kim DK (2016) Thermal optimization of internally finned tube with variable fin thickness. Appl Therm Eng 102:1250–1261CrossRefGoogle Scholar
  69. Kim DK, Kim SJ (2007) Closed form correlations for thermal optimization of microchannels. Int J Heat Mass Transf 50(25):5318–5322zbMATHCrossRefGoogle Scholar
  70. Kim NH, Kim SH (2010) Dry and wet air-side performance of a louver-finned heat exchanger having flat tubes. J Mech Sci Technol 24:1553–1561CrossRefGoogle Scholar
  71. Kim NH, Webb RL (1989) Experimental study of particulate fouling in enhanced water chiller condenser tubes. ASHRAE Trans 76(2):507–515Google Scholar
  72. Kim NH, Webb RL (1993) Analytic prediction of the friction and heat transfer for turbulent flow in axial internal fin tubes. J Heat Transf 115(3):553–559CrossRefGoogle Scholar
  73. Kim SJ, Yoo JW, Jang SP (2002) Thermal optimization of a circular-sectored finned tube using a porous medium approach. J Heat Transf 124(6):1026–1033CrossRefGoogle Scholar
  74. Kim DK, Jung J, Kim SJ (2010) Thermal optimization of plate-fin heat sinks with variable fin thickness. Int J Heat Mass Transf 53(25):5988–5995zbMATHCrossRefGoogle Scholar
  75. Kim NH, Lee EJ, Byun HW (2013) Evaporation heat transfer and pressure drop of R-410A in flattened smooth tubes having different aspect ratios. Int J Refrig 36:363–374CrossRefGoogle Scholar
  76. Kiml R, Magda A, Mochizuki S, Murata A (2004) Rib-induced secondary flow effects on local circumferential heat transfer distribution inside a circular rib-roughened tube. Int J Heat Mass Transf 47(6–7):1403–1412CrossRefGoogle Scholar
  77. Koyama S, Yu J, Momoki S, Fujii T, Honda H (1995) Forced convective flow boiling heat transfer of pure refrigerants inside a horizontal microfin tube. In: Proceedings of the engineering foundation conference on convective flow boiling. ASME Banff CanadaGoogle Scholar
  78. Kumar R (1997) Three-dimensional natural convective flow in a vertical annulus with longitudinal fins. Int J Heat Mass Transf 40:3323–3334zbMATHCrossRefGoogle Scholar
  79. Kumbhar DG, Sane NK (2015) Exploring heat transfer and friction factor performance of a dimpled tube equipped with regularly spaced twisted tape inserts. Procedia Eng 127:1142–1149CrossRefGoogle Scholar
  80. Kuo CS, Wang CC (1996) In-tube evaporation of HCFC-22 in a 9.52 mm micro-fin/smooth tube. Int J Heat Mass Transf 39(12):2559–2569CrossRefGoogle Scholar
  81. Kuwahara H, Takahashi K, Yanagida T, Nakayama W, Sugimoto S, Oizumi K (1989) Method of producing a heat transfer tube for single-phase flow. US Patent 4,794,775 issued to Hitachi Cable LtdGoogle Scholar
  82. Lemouedda A, Schmid A, Franz E et al (2011) Numerical investigations for the optimization of serrated finned-tube heat exchangers. Appl Therm Eng 31(8–9):1393–1401CrossRefGoogle Scholar
  83. Li XW, Meng JA, Li ZX (2007) Experimental study of single-phase pressure drop and heat transfer in a micro-fin tube. Exp Thermal Fluid Sci 32(2):641–648CrossRefGoogle Scholar
  84. Li GQ, Wu Z, Li W, Wang ZK, Wang X, Li HX, Yao SC (2012) Experimental investigation of condensation in micro-fin tubes of different geometries. Exp Thermal Fluid Sci 37:19–28CrossRefGoogle Scholar
  85. Liao Q, Xin XD (1995) Experimental investigation on forced convective heat transfer and pressure drop of ethylene glycol in tubes with three-dimensional internally extended surface. Exp Therm Fluid Sci 11:343–347CrossRefGoogle Scholar
  86. Liao Q, Xin XD (2000) Augmentation of convective heat transfer inside tubes with three dimensional internal extended surfaces and twisted-tape inserts. Chem Eng J 78:95–105CrossRefGoogle Scholar
  87. 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):139–151CrossRefGoogle Scholar
  88. Lin ZM, Wang LB, Zhang YH (2014) Numerical study on heat transfer enhancement of circular tube bank fin heat exchanger with interrupted annular groove fin. Appl Therm Eng 73:1465–1476CrossRefGoogle Scholar
  89. Liu XY, Jensen MK (1999) Numerical investigation of turbulent flow and heat transfer in internally finned tubes. J Enhanc Heat Transf 6:105–119CrossRefGoogle Scholar
  90. Liu X, Jensen MK (2001) Geometry effects on turbulent flow and heat transfer in internally finned tubes. J Heat Transf 123(6):1035–1044CrossRefGoogle Scholar
  91. Liu L, Ling X, Peng H (2013a) Complex turbulent flow and heat transfer characteristics of tubes with internal longitudinal plate-rectangle fins in EGR cooler. Appl Therm Eng 54:145–152CrossRefGoogle Scholar
  92. Liu L, Fan YZ, Ling X, Peng H (2013b) Flow and heat transfer characteristics of finned tube with internal and external fins in air cooler for waste heat recovery of gas-fired boiler system. Chem Eng Process 74:142–152CrossRefGoogle Scholar
  93. Liu L, Ling X, Peng H (2015) Study on turbulent flow and heat transfer performance of tubes with internal fins in EGR cooler. Heat Mass Transf 1:1017–1027CrossRefGoogle Scholar
  94. Luo YM, Shao SQ, Xu HB, Tian CQ, Yang HX (2014) Experimental and theoretical research of a fin-tube type internally-cooled liquid desiccant dehumidifier. Appl Energy 133:127–134CrossRefGoogle Scholar
  95. Ma Y, Yuan Y, Liu Y (2012) Experimental investigation of heat transfer and pressure drop in serrated finned tube banks with staggered layouts. Appl Therm Eng 37(5):314–323CrossRefGoogle Scholar
  96. Mahmood GI, Ligrani PM (2002) Heat transfer in a dimpled channel: combined influences of aspect ratio, temperature ratio, Reynolds number and flow structure. Int J Heat Mass Transf 45(10):2011–2020CrossRefGoogle Scholar
  97. Manglik RM, Bergles AE (1993) Heat transfer and pressure drop correlations for twisted-tape inserts in isothermal tubes: part 1—laminar flows. J Heat Transf 115(4):881–889CrossRefGoogle Scholar
  98. Marner WJ, Bergles AE (1978) Augmentation of tubeside laminar flow heat transfer by means of twisted-tape inserts, static-mixer inserts, and internally finned tubes. In: Heat transfer 1978, vol 2. Hemisphere Publishing Corporation, Washington, DC, pp 583–588Google Scholar
  99. Marner WJ, Bergles AE (1985) Augmentation of highly viscous laminar tubeside heat transfer by means of a twisted tape insert and an internally finned tube. In: Shenkman SM, O’Brien JE, Habib IS, Kohler JA (eds) Advances in enhanced heat transfer, HTD, vol 43, pp 19–28Google Scholar
  100. Marner WJ, Bergles AE (1989) Augmentation of highly viscous laminar heat transfer inside tubes with constant wall temperature. Exp Therm Fluid Sci 2:252–267CrossRefGoogle Scholar
  101. Martinez E, Vicente W, Salinas-Vazquez M, Carvajal I, Alvarez M (2015) Numerical simulation of turbulent air flow on a single isolated finned tube module with periodic boundary conditions. Int J Therm Sci 92:58–71CrossRefGoogle Scholar
  102. Marto PJ, Reilly DJ, Fenner JH (1979) An experimental comparison of enhanced heat transfer condenser tubing. In: Advances in enhanced heat transfer. ASME, New York, pp 1–9Google Scholar
  103. Moreno Quiben J, Cheng L, da Silva Lima RJ, Thome JR (2009a) Flow boiling in horizontal flatten tubes: part I—two-phase frictional pressure drop results and model. Int J Heat Mass Transf 52:3634–3644CrossRefGoogle Scholar
  104. Moreno Quiben J, Cheng L, da Silva Lima RJ, Thome JR (2009b) Flow boiling in horizontal flattened tubes: part II—flow boiling heat transfer results and model. Int J Heat Mass Transf 52:3645–3653CrossRefGoogle Scholar
  105. Mukkamala Y, Sundaresan R (2009) Single-phase flow pressure drop and heat transfer measurements in a horizontal microfin tube in the transition regime. J Enhanc Heat Transf 16(2):141–159CrossRefGoogle Scholar
  106. Nandakumar K, Masliyah HH (1975) Fully developed viscous flow in internally finned tubes. Chem Eng J 10:113–120CrossRefGoogle Scholar
  107. Nasr M, Akhavan-Behabadi MA, Marashi SE (2010) Performance evaluation of flattened tube in boiling heat transfer enhancement and its effect on pressure drop. Int Commun Heat Mass Transf 37:430–436CrossRefGoogle Scholar
  108. Newell TA, Shah RK (2001) An assessment of refrigerant heat transfer, pressure drop and void fraction effects in microfin tubes. Int J HVAC&R Res 7(2):125–153CrossRefGoogle Scholar
  109. Nikuradse J (1922) Law of flows in rough pipes, Forsh Arb Ing—Wesen No 361 Translated NACATM 1292 (1950)Google Scholar
  110. Nishida S, Murata A, Saito H, Iwamoto K (2012) Compensation of three-dimensional heat conduction inside wall in heat transfer measurement of dimpled surface by using transient technique. J Enhanc Heat Transf 19(4):331–341CrossRefGoogle Scholar
  111. Nivesrangsan P, Pethkool S, Nanan K, Pimsarn M, Eiamsa-ard S (2010) Thermal performance assessment of turbulent flow through dimpled tubes. In: Proc. 14th international heat transfer conference IHTC14-22503 Washington, DCGoogle Scholar
  112. Obot NT, Esen EB, Snell KH, Rabas TJ (1991) Pressure drop and heat transfer for spirally fluted tubes including validation of the role of transition. In: Rabas TJ, Chenoweth JM (eds) Fouling and enhancement interactions, ASME Symp. HTD, vol 164, pp 85–92Google Scholar
  113. Olson DA (1992) Heat transfer in thin, compact heat exchangers with circular, rectangular, or pin-fin flow passages. J Heat Transf 114:373–382CrossRefGoogle Scholar
  114. Panchal CB, France DM (1986) Performance tests of the spirally fluted tube heat exchanger for industrial cogeneration applications. Argonne National Laboratory Report ANL/CNSV-59Google Scholar
  115. Park J, Ligrani PM (2005) Numerical predictions of heat transfer and fluid flow characteristics for seven different dimpled surfaces in a channel. Numer Heat Transf Part A Appl 47(3):209–232CrossRefGoogle Scholar
  116. Patankar SV, Chai JC (1991) Laminar natural convection in internally finned horizontal annuli. ASME Paper No. 91-HT-12Google Scholar
  117. Patankar SV, Ivanovic M, Sparrow EM (1979) Analysis of turbulent flow and heat transfer in internally finned tubes and annuli. ASME J Heat Transf 101:29–37CrossRefGoogle Scholar
  118. Peng H, Ling X (2011) Analysis of heat transfer and flow characteristics over serrated fins with different flow directions. Energy Convers Manag 52:826–835CrossRefGoogle Scholar
  119. Peng H, Ling X, Li J (2014) Performance investigation of an innovative offset strip fin arrays in compact heat exchangers. Energy Convers Manag 80:287–297CrossRefGoogle Scholar
  120. Peng H, Liu L, Ling X, Li Y (2016) Thermo-hydraulic performances of internally finned tube with a new type wave fin arrays. Appl Therm Eng 98:1174–1188CrossRefGoogle Scholar
  121. Perera KK, Baughn JW (1994) The effect of pitch angle and Reynolds number on local heat transfer in spirally fluted tubes. In: Haas LA, Downing RS (eds) Optimal design of thermal systems and components, HTD, vol 279, pp 99–112Google Scholar
  122. Prakash C, Liu Y-D (1985) Analysis of laminar flow and heat transfer in the entrance region of an internally finned circular duct. J Heat Transf 107:84–91CrossRefGoogle Scholar
  123. Prakash C, Patankar SV (1981) Combined free and forced convection in internally finned tubes with radial fins. J Heat Transf 103:566–572CrossRefGoogle Scholar
  124. Promvonge P, Eiamsa-Ard S (2007) Heat transfer augmentation in a circular tube using V-nozzle turbulator inserts and snail entry. Exp Therm Fluid Sci 32(1):332–340CrossRefGoogle Scholar
  125. Promvonge P (2015) Thermal performance in square-duct heat exchanger with quadruple V-finned twisted tapes. Appl Therm Eng 91:298–307CrossRefGoogle Scholar
  126. Rabas TJ, Mitchell H (2000) Internally enhanced carbon steel tubes for ammonia chillers. Heat Transf Eng 21(5):3–16CrossRefGoogle Scholar
  127. Raj R, Lakshman NS, Mukkamala Y (2015) Single phase flow heat transfer and pressure drop measurements in doubly enhanced tubes. Int J Therm Sci 88:215–227CrossRefGoogle Scholar
  128. Ravigururajan TS, Bergles AE (1995) Prandtl number influence on heat transfer enhancement in turbulent flow of water at low temperatures. J Heat Transf 117(2):276–282CrossRefGoogle Scholar
  129. Richards DE, Grant MM, Christensen RN (1987) Turbulent flow and heat transfer inside doubly-fluted tubes. ASHRAE Trans 93(Part 2):2011–2026Google Scholar
  130. Rout SK, Thatoi DN, Acharya AK, Mishra DP (2012) CFD supported performance estimation of an internally finned tube heat exchanger under mixed convection flow. Procedia Eng 38:585–597CrossRefGoogle Scholar
  131. Rowley GJ, Patankar SV (1984) Analysis of laminar flow and heat transfer in tubes with internal circumferential fins. Int J Heat Mass Transf 27(4):553–560CrossRefGoogle Scholar
  132. Rustum IM, Soliman HM (1988a) Experimental investigation of laminar mixed convection in tubes with longitudinal internal fins. J Heat Transf 110:366–372CrossRefGoogle Scholar
  133. Rustum IM, Soliman HM (1988b) Numerical analysis of laminar forced convection in the entrance region of tubes with longitudinal internal fins. J Heat Transf 110:310–313CrossRefGoogle Scholar
  134. Rustum IM, Soliman HM (1990) Numerical analysis of laminar mixed convection in horizontal internally finned tubes. Int J Heat Mass Transf 33(7):1485–1496CrossRefGoogle Scholar
  135. Saad AE, Sayed AE, Mohamed EA, Mohamed MS (1997) Experimental study of turbulent flow inside a circular tube with longitudinal interrupted fins in the streamwise direction. Exp Therm Fluid Sci 15(1):1–15CrossRefGoogle Scholar
  136. Said NMA, Trupp AC (1984) Predictions of turbulent flow and heat transfer in internally finned tubes. Chem Eng Commun 31:65–99CrossRefGoogle Scholar
  137. San JY, Huang WC (2006) Heat transfer enhancement of transverse ribs in circular tubes with consideration of entrance effect. Int J Heat Mass Transf 49(17–18):2965–2971CrossRefGoogle Scholar
  138. Sarkhi A, Nada E (2005) Characteristics of forced convection heat transfer in vertical internally finned tube. Int Commun Heat Mass 32:557–564CrossRefGoogle Scholar
  139. Shih TH, Liou WW, Shabbrir A, Yang ZG, Zhu J (1995) A new k–e eddy viscosity model for high Reynolds number turbulent flows. Comput Fluids 24(3):227–238zbMATHCrossRefGoogle Scholar
  140. Shome B (1998) Mixed convection laminar flow and heat transfer of liquids in horizontal internally finned tubes. Numer Heat Transf Part A 33(1):65–84CrossRefGoogle Scholar
  141. Shome B, Jensen MK (1996a) Experimental investigation of laminar flow and heat transfer in internally finned tubes. J Enhanc Heat Transf 4:53–70CrossRefGoogle Scholar
  142. Shome B, Jensen MK (1996b) Numerical investigation of laminar flow and heat transfer in internally finned tubes. J Enhanc Heat Transf 4:35–52CrossRefGoogle Scholar
  143. Siddique M, Alhazmy M (2008) Experimental study of turbulent single-phase flow and heat transfer inside a micro-finned tube. Int J Refrig 31(2):234–241CrossRefGoogle Scholar
  144. Soliman HM (1979) The effect of fin material on laminar heat transfer characteristics of internally finned tubes. In: Chenoweth JM, Kaellis J, Michel JW, Shenkman S (eds) Advances in enhanced heat transfer. ASME, New York, pp 95–102Google Scholar
  145. Soliman HM, Feingold A (1977) Analysis of fully developed laminar flow in longitudinally internally finned tubes. Chem Eng J 14:119–128CrossRefGoogle Scholar
  146. Soliman HM, Chau TS, Trupp AC (1980) Analysis of laminar heat transfer in internally finned tubes with uniform outside wall temperature. J Heat Transf 102:598–604CrossRefGoogle Scholar
  147. Song WM, Meng JA, Li ZX (2010) Numerical study of air-side performance of a finned flat tube heat exchanger with crossed discrete double inclined ribs. Appl Therm Eng 30(13):1797–1804CrossRefGoogle Scholar
  148. Sparrow EM, Lovell B (1980) Heat transfer characteristics of an obliquely impinging circular jet. J Heat Transf 102(2):202–209CrossRefGoogle Scholar
  149. Srinivasan V, Christensen RN (1992) Experimental investigation of heat transfer and pressure drop characteristics of flow through spirally fluted tubes. Exp Therm Fluid Sci 5:820–827CrossRefGoogle Scholar
  150. Srinivasan V, Vafai K, Christensen RN (1994) Experimental investigation, modeling and prediction of friction factors and friction increase ratio for flow through spirally fluted tubes. J Enhanc Heat Transf 1(4):337–350CrossRefGoogle Scholar
  151. Suresh S, Chandrasekar M, Chandrasekar S (2001) Experimental studies on heat transfer and friction factor characteristics of CuO/water nanofluid under turbulent flow in a helically dimpled tube. Exp Thermal Fluid Sci 35:542–549CrossRefGoogle Scholar
  152. Syed KS, Ishaq M, Iqbal Z, Hassan A (2015) Numerical study of an innovative design of a finned double-pipe heat exchanger with variable fin-tip thickness. Energy Convers Manag 98:69–80CrossRefGoogle Scholar
  153. Takahashi K, Nakayama W, Kuwahara H (1988) Enhancement of forced convective heat transfer in tubes having three-dimensional spiral ribs. Heat Transf Jpn Res 17(4):12–28Google Scholar
  154. Thianpong C, Eiamsa-ard P, Wongcharee K, Eiamsa-ard S (2009) Compound heat transfer enhancement of a dimpled tube with a twisted tape swirl generator. Int Commun Heat Mass Transf 36:698–704CrossRefGoogle Scholar
  155. Thome JR, Kattan N, Favrat D (1997) Evaporation in micro-fin tubes: a generalized prediction model. In: Proc. convective flow and pool boiling conference, Kloster Irsee (Paper VII-4)Google Scholar
  156. Trupp AC, Haine H (1989) Experimental investigation of turbulent mixed convection in horizontal tubes with longitudinal internal fins. In: Shah RK (ed) Heat transfer in convective flows, ASME HTD, vol 107, pp 17–25Google Scholar
  157. Trupp AC, Lau ACY, Said NNA, Soliman HM (1981) Turbulent flow characteristics in an internally finned tube. In: Webb RL, Carnavos TC, Park EL Jr, Hostetler KM (eds) Advances in enhanced heat transfer 1981, ASME Symp. HTD, vol 18. ASME, New York, pp 11–20Google Scholar
  158. Wang C-C, Chen P-Y, Jang J-Y (1996) Heat transfer and friction characteristics of convex-louver fin-and-tube heat exchangers. Exp Heat Transf 9:61–78CrossRefGoogle Scholar
  159. Wang QW, Lin M, Zeng M, Tian L (2008a) Computational analysis of heat transfer and pressure drop performance for internally finned tubes with three different longitudinal wavy fins. Heat Mass Transf 45:147–156CrossRefGoogle Scholar
  160. Wang QW, Lin M, Zeng M, Tian L (2008b) Investigation of turbulent flow and heat transfer in periodic wavy channel of internally finned tube with blocked core tube. J Heat Transf 130(6). Article No.: 061801CrossRefGoogle Scholar
  161. Wang QW, Lin M, Zeng M (2009) Effect of lateral fin profiles on turbulent flow and heat transfer performance of internally finned tubes. Appl Therm Eng 29:3006–3013CrossRefGoogle Scholar
  162. Wang Y, He Y-L, Lei Y-G, Zhang J (2010) Heat transfer and hydrodynamics of a novel dimpled tube. Exp Therm Fluid Sci 34:1273–1281CrossRefGoogle Scholar
  163. Wang YG, Zhao QX, Zhou QL, Kang ZJ, Tao WQ (2013) Experimental and numerical studies on actual flue gas condensation heat transfer in a left-right symmetric internally finned tube. Int J Heat Mass Transf 64:10–20CrossRefGoogle Scholar
  164. Wang QW, Zeng M, Ma T, Du XP, Yang JF (2014) Recent development and application of several high-efficiency surface heat exchangers for energy conversion and utilization. Appl Energy 135:748–777CrossRefGoogle Scholar
  165. Wang WJ, Bao Y, Wang YQ (2015) Numerical investigation of a finned-tube heat exchanger with novel longitudinal vortex generators. Appl Therm Eng 86:27–34CrossRefGoogle Scholar
  166. Wang YH, Zhang JL, Ma ZX (2017) Experimental determination of single-phase pressure drop and heat transfer in a horizontal internal helically-finned tube. Int J Heat Mass Transf 104:240–246CrossRefGoogle Scholar
  167. Watkinson AP, Miletti PL, Tarassoff p (1973) Turbulent heat transfer and pressure drop in internally finned tubes. AIChE Symp Ser 69(131):94–103Google Scholar
  168. Watkinson AP, Miletti PL, Kubanek GR (1975a) Heat transfer and pressure drop of internally finned tubes in laminar oil flow. ASME Paper 75-HT-41Google Scholar
  169. Watkinson AP, Miletti PL, Kubanek GR (1975b) Heat transfer and pressure drop of internally finned tubes in turbulent air flow. ASHRAE Trans 81(Part 1):330–349Google Scholar
  170. Webb RL (1981) The use of enhanced heat transfer surface geometries in condensers. In: Marto PJ, Nunn RH (eds) Power condenser heat transfer technology: computer modeling, design, fouling. Hemisphere Pub. Corp., Washington, DC, pp 287–324Google Scholar
  171. Webb RL, Iyengar A (2001) Oval finned tube condenser and design pressure limits. J Enhanc Heat Transf 8:147–158CrossRefGoogle Scholar
  172. Webb RL, Kim NH (2005) Principles of enhanced heat transfer, 2nd edn. Taylor & Francis, LondonGoogle Scholar
  173. Webb RL, Scott MJ (1980) A parametric analysis of the performance of internally finned tubes for heat exchanger application. J Heat Transf 102(1):38–43CrossRefGoogle Scholar
  174. Webb RL, Eckert ERG, Goldstein R (1971) Heat transfer and friction in tubes with repeated-rib roughness. Int J Heat Mass Transf 14(4):601–617CrossRefGoogle Scholar
  175. Webb RL, Narayanamurthy R, Thors P (2000) Heat transfer and friction characteristics of internal helical-rib roughness. J Heat Transf 122(1):134–142CrossRefGoogle Scholar
  176. Wilson MJ, Newell TA, Chato JC, Infante Ferreira CA (2003) Refrigerant charge, pressure drop and condensation heat transfer in flattened tubes. Int J Refrig 26:442–451CrossRefGoogle Scholar
  177. Wolfstein M (1988) The velocity and temperature distribution of one dimensional flow with turbulence augmentation and pressure gradient. Int J Heat Mass Transf 12:301–318CrossRefGoogle Scholar
  178. Wu Z, Wu Y, Sunden B, Li W (2013) Convective vaporization in micro-fin tubes of different geometries. Exp Thermal Fluid Sci 44:398–408CrossRefGoogle Scholar
  179. Yakut K, Sahin B, Canbazoglu S (2004) Performance and flow-induced vibration characteristics for conical-ring turbulators. Appl Energy 79(1):65–76CrossRefGoogle Scholar
  180. Yampolsky JS (1983) Spirally fluted tubing for enhanced heat transfer. In: Taborek J, Hewitt GF, Afgan N (eds) Heat exchangers-theory and practice. Hemisphere Publishing Corp, Washington, DC, pp 945–952Google Scholar
  181. Yu B, Nie JH, Wang QW, Tao WQ (1999) Experimental study on the pressure drop and heat transfer characteristics of tubes with internal wave-like longitudinal fins. Heat Mass Transf 35:65–73CrossRefGoogle Scholar
  182. Yu B, Tao WQ (2004) Pressure drop and heat transfer characteristics of turbulent flow in annular tubes with internal wave-like longitudinal fins. Heat Mass Transf 40:643–651CrossRefGoogle Scholar
  183. Yun R, Kim Y, Seo K, Kim HY (2002) A generalized correlation for evaporation heat transfer of refrigerants in micro-fin tubes. Int J Heat Mass Transf 45:2003–2010CrossRefGoogle Scholar
  184. Zdaniuk GJ, Luck R, Chamra LM (2008) Linear correlation of heat transfer and friction in helically-finned tubes using five simple groups of parameters. Int J Heat Mass Transf 51(13–14):3548–3555zbMATHCrossRefGoogle Scholar
  185. Zeitoun O, Hegazy AS (2004) Heat transfer for laminar flow in internally finned pipes with different fin heights and uniform wall temperature. Heat Mass Transf 40:253–259CrossRefGoogle Scholar
  186. Zhang HY, Ebadian MA (1992a) Heat transfer in the entrance region of semicircular ducts with internal fins. J Thermophys Heat Transf 6:296–301CrossRefGoogle Scholar
  187. Zhang HY, Ebadian MA (1992b) The influence of internal fins on mixed convection inside a semicircular duct. In: Pate MB, Jensen MK (eds) Enhanced heat transfer. ASME Symp. HTD, vol 202. ASME, New York, pp 17–24Google Scholar
  188. Zhang HG, Wang EH, Fan BY (2013) Heat transfer analysis of a finned-tube evaporator for engine exhaust heat recovery. Energy Convers Manag 65:438–447CrossRefGoogle Scholar

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© The Author(s), under exclusive license to Springer Nature Switzerland AG 2020

Authors and Affiliations

  • Sujoy Kumar Saha
    • 1
  • Hrishiraj Ranjan
    • 1
  • Madhu Sruthi Emani
    • 1
  • Anand Kumar Bharti
    • 1
  1. 1.Mechanical Engineering DepartmentIndian Institute of Engineering, Science and Technology, ShibpurHowrahIndia

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