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Flow Boiling Enhancement Techniques

  • 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

This chapter has started with the introduction to flow boiling enhancement techniques. Thereafter, the chapter runs through the fundamentals, flow patterns, thermal convection and pressure drop and flow orientation. Tube bundles, CHF and microfin tubes have also been discussed.

Keywords

Flow boiling Enhancement techniques Boiling fundamentals Flow pattern CHF 

References

  1. Abdul K, Wang CC (2016) Investigation of thermal-hydrodynamic heat transfer performance of R-1234ZE and R-134a refrigerants in a micro-fin and smooth tube. J Enhanc Heat Transf 23(3):221CrossRefGoogle Scholar
  2. Agrawal KN, Varma HK, Lal S (1982) Pressure drop during forced convection boiling of R-12 under swirl flow. J Heat Transf 104(4):758–762CrossRefGoogle Scholar
  3. Agrawal KN, Varma HK, Lal S (1986) Heat transfer during forced convection boiling of R-12 under swirl flow. J Heat Transf 108(3):567–573CrossRefGoogle Scholar
  4. Akhanda MA, James DD (1991) An experimental study of the relative effects of transverse and longitudinal ribbing of the heat transfer surface in forced convective boiling. J Heat Transf 113(1):209–215CrossRefGoogle Scholar
  5. Antonelli R, O’Neill PS (1981) Design and application considerations for heat exchangers with enhanced boiling surfaces. Paper presented at international conference on advances in heat exchangers, Dubrovnik, YugoslaviaGoogle Scholar
  6. Arai N, Fukushima T, Arai A, Nakajima T, Fujie K, Nakayama Y (1977) Heat transfer tubes enhancing boiling and condensation in heat exchanger of a refrigerating machine. ASHRAE Trans 83:58–70Google Scholar
  7. Azer NZ, Sivakumar V (1984) Enhancement of saturated boiling heat transfer by internally finned tubes. ASHRAE Trans 90(1A):58–73Google Scholar
  8. Baker O (1954), Simultaneous flow of oil and gas: A report on Magnolia's research on two-phase pipeline design, Oil Gas J 26(5):185–195Google Scholar
  9. Bao ZY, Fletcher DF, Haynes BS (2000) Flow boiling heat transfer of Freon R11 and HCFC123 in narrow passages. Int J Heat Mass Transf 43(18):3347–3358CrossRefGoogle Scholar
  10. Bennett DL, Chen JC (1980) Forced convective boiling in vertical tubes for saturated pure components and binary mixtures. AICHE J 26(3):454–461CrossRefGoogle Scholar
  11. Bergles AE, Chyu MC (1982) Characteristics of nucleate pool boiling from porous metallic coatings. J Heat Transf 104:279–285CrossRefGoogle Scholar
  12. Bergles AE, Fuller WD, Hynek SJ (1971) Dispersed flow film boiling of nitrogen with swirl flow. Int J Heat Mass Transf 14(9):1343–1354CrossRefGoogle Scholar
  13. Bhatia RS, Webb RL (2001) Numerical study of turbulent flow and heat transfer in micro-fin tubes—part 2, parametric study. J Enhanc Heat Transf 8(5)CrossRefGoogle Scholar
  14. Blatt TA, Adt RR (1963) The effects of twisted tape swirl generators on the heat transfer rate and pressure drop of boiling Freon 11 and water. In: ASME Paper No. ASME-63-WA-42Google Scholar
  15. Boling C, Donovan WJ, Decker AS (1953) Heat transfer of evaporating freon with inner-fin tubing. Refrig Eng 61:1338–1340Google Scholar
  16. Brognaux LJ, Webb RL, Chamra LM, Chung BY (1997) Single-phase heat transfer in micro-fin tubes. Int J Heat Mass Transf 40(18):4345–4357CrossRefGoogle Scholar
  17. Bukin VG, Danilova GN, Dyundin VA (1982) Heat transfer from Freons in a film flowing over bundles of horizontal tubes that carry a porous coating. Heat Transf Soviet Res 14(2):98–103Google Scholar
  18. Campolunghi F, Cumo M, Ferrari G, Palazzi G (1976) Full scale tests and thermal design of once-through steam generators. In: AIChE paper presented at 16th national heat transfer conference, St. Louis, MOGoogle Scholar
  19. Carey VP (1992) Liquid-vapor phase-change phenomena: an introduction to the thermodynamics of vaporization and condensation processes in heat transfer equipment. Hemisphere, Washington, DCGoogle Scholar
  20. Carey VP, Shah RK (1988) Design of compact and enhanced heat exchangers for liquid-vapor phase-change applications. In: Two-phase flow heat exchangers. Springer, Dordrecht, pp 909–968CrossRefGoogle Scholar
  21. Carnavos TC (1980) Heat transfer performance of internally finned tubes in turbulent flow. Heat Transf Eng 1(4):32–37CrossRefGoogle Scholar
  22. Cavallini A, Del Col D, Doretti L, Longo GA, Rossetto L (1998) Refrigerant vaporisation inside enhanced tubes: a heat transfer model. In Eurotherm seminar, pp 222–231Google Scholar
  23. Cavallini A, Del Col D, Doretti L, Longo GA, Rossetto L (2000) Heat transfer and pressure drop during condensation of refrigerants inside horizontal enhanced tubes. Int J Refrig 23(1):4–25CrossRefGoogle Scholar
  24. Celata GP, Cumo M, Mariani A (1994) Enhancement of CHF water subcooled flow boiling in tubes using helically coiled wires. Int J Heat Mass Transf 37(1):53–67CrossRefGoogle Scholar
  25. Chamra LM, Webb RL (1995) Condensation and evaporation in micro-fin tubes at equal saturation temperatures. J Enhanc Heat Transf 2(3):219CrossRefGoogle Scholar
  26. Chamra LM, Webb RL, Randlett MR (1996) Advanced micro-fin tubes for evaporation. Int J Heat Mass Transf 39(9):1827–1838CrossRefGoogle Scholar
  27. Chen JC (1966) Correlation for boiling heat transfer to saturated fluids in convective flow. Indust Eng Chem Process Des Dev 5(3):322–329CrossRefGoogle Scholar
  28. Chen T, Luo YS, Zheng J, Bi Q (2000) Boiling heat transfer and frictional pressure drop in internally rebbed tubes at high pressures. In: Symposium on energy engineering in the 21st century, Hong Kong, pp 393–398Google Scholar
  29. Chen T-K, Chen X-Z, Chen X-J (1992) Boiling heat transfer and frictional pressure drop in internally ribbed tubes. In: Chen X-J, Vezirolu TN, Tien CL (eds) Multiphase flow and heat transfer: second international symposium, vol 1. Hemisphere Pub. Corp., New York, pp 621–629Google Scholar
  30. Chisholm D (1967) A theoretical basis for the Lockhart-Martinelli correlation for two-phase flow. Int J Heat Mass Transf 10(12):1767–1778CrossRefGoogle Scholar
  31. Chun KR, Seban RA (1971) Heat transfer to evaporating liquid films. J Heat Transf 93:391–396CrossRefGoogle Scholar
  32. Chyu MC, Bergles AE (1985) Enhancement of horizontal tube spray film evaporators by structured surfaces. Adv Enhanced Heat Transf 43:39–47Google Scholar
  33. Chyu MC, Bergles AE (1989) Horizontal-tube falling-film evaporation with structured surfaces. J Heat Transf 111(2):518–524CrossRefGoogle Scholar
  34. Conklin JC, Vineyard EA (1992) Flow boiling enhancement of R22 and a nonazeotropic mixture of R143a and R124 using perforated foils. Oak Ridge National Lab, Oak Ridge, TNGoogle Scholar
  35. Conti RJ (1978) Experimental investigation of horizontal tube ammonia film evaporators with small temperature differentials. In: Proceedings of the 5th Ocean Thermal Energy Conversion (OTEC)Google Scholar
  36. Cooper MG (1984) Saturation nucleate pool boiling—a simple correlation. Chem E Symp Ser 86:786Google Scholar
  37. Cornwell K, Scoones DJ (1988) Analysis of low-quality boiling on plain and low-finned tube bundles. Presented at second UK heat transfer conference, vol 1, pp 21–32Google Scholar
  38. Crain Jr B (1973) Forced convection heat transfer to a two-phase mixture of water and steam in a helical coil. Doctoral dissertation, Oklahoma State UniversityGoogle Scholar
  39. Cui S, Tan Y, Lu Y (1992) Heat transfer and flow resistance of R-502 flow boiling inside horizontal ISF tubes. In: Multiphase flow and heat transfer: second international symposium, vol 1. Hemisphere, New York, pp 662–670Google Scholar
  40. Cui W, Mungai SK, Wilson C, Ma H, Li B (2016) Subcooled flow boiling on a two-step electrodeposited copper porous surface. J Enhanc Heat Transf 23(2):91CrossRefGoogle Scholar
  41. Cumo M, Farello GE, Ferrari G, Palazzi G (1974) The influence of twisted tapes in subcritical, once-through vapor generators in counter flow. J Heat Transf 96(3):365–370CrossRefGoogle Scholar
  42. Czikk AM, Gottzmann CF, Ragi EG, Withers JG, Habdas EP (1970) Performance of advanced heat transfer tubes in refrigerant-flooded liquid coolers. ASHRAE Trans 76:96–107Google Scholar
  43. Czikk AM, O’Neill PS, Gottzmann CF (1981) Nucleate pool boiling from porous metal films effect of primary variables. Adv Heat Tran 18:109–122Google Scholar
  44. Del Col D, Webb RL, Narayanamurthy R (2002) Heat transfer mechanisms for condensation and vaporization inside a microfin tube. J Enhanc Heat Transf 9(1)Google Scholar
  45. Dong F, Cao T, Hou L, Ni J (2019) Optimization study of artificial cavities on subcooled flow boiling performance of water in a horizontal simulated engine cooling passage. J Enhanc Heat Transf 26(1):37CrossRefGoogle Scholar
  46. Ebisu T (1999) Evaporation and condensation heat transfer enhancement for alternative refrigerants used in air-conditioning machines. In: Heat transfer enhancement heat exchangers. Springer, Dordrecht, pp 579–600CrossRefGoogle Scholar
  47. Eckels SJ, Pate MB (1991) In-tube evaporation and condensation of refrigerant-lubricant mixtures of HFC-134a and CFC-12. ASHRAE Trans 97:62–70Google Scholar
  48. Fagerholm NE, Kivioja K, Ghazanfari AR, Jaervinen E (1985) Using structured surfaces to enhance heat transfer in falling film flow. NASA STI/Recon Technical Report No. 87Google Scholar
  49. Fujie K, Itoh N, Innami T, Kimura H, Nakayama N, Yanugidi T (1977) Heat transfer pipe. US Patent 4,044,797, assigned to Hitachi LtdGoogle Scholar
  50. Fujita Y (1998) Boiling and evaporation of falling film on horizontal tubes and its enhancement on grooved tubes. In: Kakac S, Bergles AE, Mayinger F, Yuncu H (eds) Heat Transfer Enhancement of Heat Exchangers. Kluwer Academic, Dordrecht, 3259–3346Google Scholar
  51. Fujita Y (1999) Boiling and evaporation of falling film on horizontal tubes and its enhancement on grooved tubes. In: Heat transfer enhanced heat exchangers. Springer, Dordrecht, pp 325–346CrossRefGoogle Scholar
  52. Fujita Y, Ohta H, Hidaka S, Nishikawa K (1986) Nucleate boiling heat transfer on horizontal tubes in bundles. In: Proceedings of 8th Int Heat Transfer Conf, pp 2131–2136Google Scholar
  53. Fujita Y, Yang Y, Fujita N (2002) Flow boiling heat transfer and pressure drop in uniformly heated small tubes. In: Heat transfer 2002, 12th international heat transfer conference, vol 3, pp 743–748Google Scholar
  54. Gambill WR (1963) Generalized prediction of burnout heat flux for flowing, subcooled, wetting liquids. Chem Eng Prog Symp Ser 59(41):71–87Google Scholar
  55. Gambill WR (1965) Subcooled swirl-flow boiling and burnout with electrically heated twisted Tapes and Zero Wall Flux. J Heat Transf 87(3):342–348CrossRefGoogle Scholar
  56. Gambill WR, Bundy RD, Wansbrough RW (1960) Heat transfer, burnout, and pressure drop for water in swirl flow through tubes with internal twisted tapes. Oak Ridge National Lab, Oak RidgeGoogle Scholar
  57. Gan YP, Chen Q, Yuan XY, Tian SR (1993) An experimental study of nucleate boiling heat transfer from flame spraying surface of tube bundle in R113/R11-oil mixtures. In: Experimental heat transfer, fluid mechanics, and thermodynamics, p 1226CrossRefGoogle Scholar
  58. Gorenflo D (2001) State of the art in pool boiling heat transfer of new refrigerants. Int J Refrig 24(1):6–14MathSciNetCrossRefGoogle Scholar
  59. Goto M, Inoue N, Ishiwatari N (2001) Condensation and evaporation heat transfer of R410A inside internally grooved horizontal tubes. Int J Refrig 24(7):628–638CrossRefGoogle Scholar
  60. Grimley TA, Mudawwar IA, Incropera FP (1987) Enhancement of boiling heat transfer in falling films. In: Proc. 1987 ASME-JSME Therm. Eng. Joint Conf., vol 3, pp 411–418Google Scholar
  61. Gu CB, Chow LC, Beam JE (1989) Flow boiling in a curved channel. Heat Transf High Energy High Heat Flux Appl 119:25–32Google Scholar
  62. Gupte NS, Webb RL (1992) Convective vaporization of refrigerants in tube banks. ASHRAE Trans 98(Pt. 2):411–424Google Scholar
  63. Gupte NS, Webb RL (1994) Convective vaporization of pure refrigerants in enhanced and integral-fin tube banks. J Enhanc Heat Transf 1(4):351CrossRefGoogle Scholar
  64. Gupte NS, Webb RL (1995a) Convective vaporization data for pure refrigerants in Tube Banks. Part II: enhanced tubes. HVAC&R Res 1(1):48–60CrossRefGoogle Scholar
  65. Gupte NS, Webb RL (1995b) Convective vaporization data for pure refrigerants in tube banks, part I: integral-finned tubes. Int J HVAC&R Res 1(1):35–47CrossRefGoogle Scholar
  66. Hewitt GF, Roberts DN (1969) Studies of two-phase flow patterns by simultaneous X-ray and flash photography. Atomic Energy Research Establishment Harwell, UKGoogle Scholar
  67. Honda H, Takamatsu H, Wei JJ (2003) Enhanced boiling heat transfer from silicon chips with micro-pin fins immersed in FC-72. J Enhanc Heat Transf 10(2):211CrossRefGoogle Scholar
  68. Hori M, Shinohara Y (2001) Internal heat transfer characteristics of small diameter thermofin tubes. Hitachi Cable Rev 10:85–90Google Scholar
  69. Houfuku M, Suzuki Y, Inui K (2001) High performance, light weight thermos-fin tubes for air-conditioners using alternative refrigerants. Hitachi Cable Rev 20:97–100Google Scholar
  70. Hsieh YY, Lin TF (2002) Saturated flow boiling heat transfer and pressure drop of refrigerant R-410A in a vertical plate heat exchanger. Int J Heat Mass Transf 45(5):1033–1044CrossRefGoogle Scholar
  71. Hsieh SS, Huang GZ, Tsai HH (2003) Nucleate pool boiling characteristics from coated tube bundles in saturated R-134a. Int J Heat Mass Transf 46(7):1223–1239CrossRefGoogle Scholar
  72. Hu H, Ding GL, Huang XL, Deng B, Gao YF (2011) Experimental investigation and correlation of two-phase heat transfer of R410a/oil mixture flow boiling in a 5-mm microfin tube. J Enhanc Heat Transf 18(3):209–220CrossRefGoogle Scholar
  73. Huang X, Li RY, Yu HL (2004) Enhancement of boiling heat transfer for R11 and R123 by applying uniform electric field. J Enhanc Heat Transf 11(4):299CrossRefGoogle Scholar
  74. Hwang YW, Kim MS, Kim Y (2005) Evaporation heat transfer and pressure drop in micro-fin tubes before and after tube expansion. J Enhanc Heat Transf 12(1):59CrossRefGoogle Scholar
  75. Ikeuchi M, Yumikura T, Fujii M, Yamanaka G (1984) Heat-transfer characteristics of an internal microporous tube with refrigerant 22 under evaporating conditions. ASHRAE Trans 90(1A):196–211Google Scholar
  76. Ishihara K, Palen JW, Taborek J (1980) Critical review of correlations for predicting two-phase flow pressure drop across tube banks. Heat Transf Eng 1(3):23–32CrossRefGoogle Scholar
  77. Ishikawa S, Nagahara K, Sukumoda S (2002) Heat transfer and pressure drop during evaporation and condensation of HCFC22 in horizontal copper tubes with many inner fins. J Enhanc Heat Transf 9(1):17CrossRefGoogle Scholar
  78. Ito M, Kimura H (1979) Boiling heat transfer and pressure drop in internal spiral-grooved tubes. Bull JSME 22(171):1251–1257CrossRefGoogle Scholar
  79. Jensen MK (1984) A correlation for predicting the critical heat flux condition with twisted-tape swirl generators. Int J Heat Mass Transf 27(11):2171–2173CrossRefGoogle Scholar
  80. Jensen MK (1985) An evaluation of the effect of twisted-tape swirl generators in two-phase flow heat exchangers. Heat Transf Eng 6(4):19–30CrossRefGoogle Scholar
  81. Jensen MK, Bensler HP (1986) Saturated forced-convective boiling heat transfer with twisted-tape inserts. J Heat Transf 108(1):93–99CrossRefGoogle Scholar
  82. Jensen MK, Bergles AE (1981) Critical heat flux in helically coiled tubes. J Heat Transf 103(4):660–666CrossRefGoogle Scholar
  83. Jensen MK, Hsu JT 1987 A parametric study of boiling heat transfer in a tube bundle. In: Proceedings of the 1987 ASME-JSME thermal engineering joint conference, vol 3, pp 133–140Google Scholar
  84. Jensen MK, Trewin RR, Bergles AE (1992) Crossflow boiling in enhanced tube bundles. ASME, New York, NY (USA) 220:11–17Google Scholar
  85. Jones RJ, Pate DT, Thiagarajan N, Bhavnani SH (2009) Heat transfer and pressure drop characteristics in dielectric flow in surface-augmented microchannels. J Enhanc Heat Transf 6(3)CrossRefGoogle Scholar
  86. Kabata Y, Nakajima R, Shioda K (1996) Enhancement of critical heat flux for subcooled flow boiling of water in tubes with a twisted tape and with a helically coiled wire. In: ICONE-4: Proceedings. Vol 1—Part B: Basic technological advancesGoogle Scholar
  87. Kandlikar SG (1991) Correlating flow boiling heat transfer data in binary systems. Phase Change Heat Transfer, p 159Google Scholar
  88. Kasza KE, Didascalou T, Wambsganss MW (1997) Microscale flow visualization of nucleate boiling in small channels: mechanisms influencing heat transfer. Argonne National Lab., Lemont, ILGoogle Scholar
  89. Kattan N, Thome JR, Favrat D (1998) Flow boiling in horizontal tubes: part 3—development of a new heat transfer model based on flow pattern. J Heat Transf 120(1):156–165CrossRefGoogle Scholar
  90. Kazachkov IV, Palm B (2005) Analysis of annular two-phase flow dynamics under heat transfer conditions. J Enhanc Heat Transf 12(1):37CrossRefGoogle Scholar
  91. Kedzierski MA, Kedzierski MA (1997) Convective Boiling and Condensation Heat Transfer with a Twisted-tape Insert for R12, R22, R152a, R134a, R290, R32/R134a, R32/R152a, R290/R134a, R134a/R600a. US Department of Commerce, National Institute of Standards and TechnologyGoogle Scholar
  92. Kew PA, Cornwell K (1997) Correlations for the prediction of boiling heat transfer in small-diameter channels. Appl Therm Eng 17(8–10):705–715CrossRefGoogle Scholar
  93. Kim NH (2015) Effect of aspect ratio on evaporation heat transfer and pressure drop of R-410A in flattened microfin tubes. J Enhanc Heat Transf 22(3):177CrossRefGoogle Scholar
  94. Kim MH, Shin JS, Bullard CW (2001) Heat transfer and pressure drop characteristics during R22 evaporation in an oval microfin tube. J Heat Transf 123(2):301–308CrossRefGoogle Scholar
  95. Kim NH, Cho JP, Youn B (2002) Forced convective boiling of pure refrigerants in a bundle of enhanced tubes having pores and connecting gaps. Int J Heat Mass Transf 45(12):2449–2463CrossRefGoogle Scholar
  96. Kitto JB, Weiner M (1982) Effects of nonuniform circumferential heating and inclination on critical heat flux in smooth and ribbed bore tubes. In: 7th international heat transfer conference, MunichGoogle Scholar
  97. Kosky PG (1971) Thin liquid films under simultaneous shear and gravity flows. Int J Heat Mass Transf 14:1220–1223CrossRefGoogle Scholar
  98. 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 convective flow boiling, pp 137–42Google Scholar
  99. Kubanek GR, Miletti DL (1979) Evaporative heat transfer and pressure drop performance of internally-finned tubes with refrigerant 22. J Heat Transf 101(3):447–452CrossRefGoogle Scholar
  100. Kun LC, Czikk AM (1969) Surface for boiling liquids. US Patent 3,454,081 (Reissued 1979, Ref. 30,077), assigned to Union Carbide CorpGoogle Scholar
  101. Lan J, Disimile PJ, Weisman J (1997) Two phase flow patterns and boiling heat transfer in tubes containing helical wire inserts—part II—critical heat flux studies. 4(4)Google Scholar
  102. Lavin JG, Young EH (1965) Heat transfer to evaporating refrigerants in two-phase flow. AICHE J 11(6):1124–1132CrossRefGoogle Scholar
  103. Lazarek GM, Black SH (1982) Evaporative heat transfer, pressure drop and critical heat flux in a small vertical tube with R-113. Int J Heat Mass Transf 25(7):945–960CrossRefGoogle Scholar
  104. Lee SC, Chien LH (2011) Experimental study of pool boiling on pin-finned and straight-finned surfaces on an inclined plate in FC-72. J Enhanc Heat Transf 18(4):311CrossRefGoogle Scholar
  105. Lewis LG, Sather NF (1978) OTEC performance tests of the Union Carbide flooded-bundle evaporator. Argonne National Lab., Lemont, ILCrossRefGoogle Scholar
  106. Lin S, Kew PA, Cornwell K (2001) Two-phase heat transfer to a refrigerant in a 1 mm diameter tube. Int J Refrig 24:51–56CrossRefGoogle Scholar
  107. Liu ZH, Qiu YH (2002) Enhanced boiling heat transfer in restricted spaces of a compact tube bundle with enhanced tubes. Appl Therm Eng 22(17):1931–1941CrossRefGoogle Scholar
  108. Liu ZH, Tong TF (2002) Boiling heat transfer of water and R-11 on horizontally smooth and enhanced tubes enclosed by a concentric outer tube with two horizontal slots. Experimental heat transfer 15(3):161–175CrossRefGoogle Scholar
  109. Liu Z, Winterton RH (1991) A general correlation for saturated and subcooled flow boiling in tubes and annuli, based on a nucleate pool boiling equation. Int J Heat Mass Transf 34(11):2759–2766CrossRefGoogle Scholar
  110. Liu ZH, Yi J (2002) Falling film evaporation heat transfer of water/salt mixtures from roll-worked enhanced tubes and tube bundle. Appl Therm Eng 22(1):83–95CrossRefGoogle Scholar
  111. Lorenz JJ, Yung D (1979) A note on combined boiling and evaporation of liquid films on horizontal tubes. J Heat Transf 101(1):178–180CrossRefGoogle Scholar
  112. Mailen GS (1980) Experimental studies of OTEC heat transfer evaporation of ammonia on vertical smooth and fluted tubes (No. CONF-800633-2). Oak Ridge National Lab., Oak Ridge, TNGoogle Scholar
  113. Mandrusiak GD, Carey VP (1989) Convective boiling in vertical channels with different offset strip fin geometries. J Heat Transf 111(1):156–165CrossRefGoogle Scholar
  114. Manglik RM, Bergles AE (1993) Heat transfer and pressure drop correlations for twisted-tape inserts in isothermal tubes: part I—laminar flows. J Heat Transf 115(4):881–889CrossRefGoogle Scholar
  115. Marvillet C (1989) Influence of oil on nucleate pool boiling of refrigerants R-12 and R-22 from Porous Layer Tube. In: Proceedings of eighth eurotherm conference, advances in pool boiling heat transfer, Paderborn, Germany, pp 164–168Google Scholar
  116. Megerlin FE, Murphy RW, Bergles AE (1974) Augmentation of heat transfer in tubes by use of mesh and brush inserts. J Heat Transf 96(2):145–151CrossRefGoogle Scholar
  117. Mehendale S (2016) The impact of fin deformation on flow boiling heat transfer and pressure drop inmicrofin tubes. J Enhanc Heat Transf 23(3):197CrossRefGoogle Scholar
  118. Memory SB, Chilman SV, Marto PJ (1994) Nucleate pool boiling of a TURBO-B bundle in R-113. J Heat Transf 116(3):670–678CrossRefGoogle Scholar
  119. Memory SB, Akcasayar N, Eraydin H, Marto PJ (1995) Nucleate pool boiling of R-114 and R-114-oil mixtures from smooth and enhanced surfaces—II. Tube bundles. Int J Heat Mass Transf 38(8):1363–1376CrossRefGoogle Scholar
  120. Moeykens, SA, Pate MB (1996) Effect of lubricant on spray evaporation heat transfer performance of R-134a and R-22 in tube bundles (No. CONF-960254-). American Society of Heating, Refrigerating and Air-Conditioning Engineers, Inc., Atlanta, GAGoogle Scholar
  121. Moeykens SA, Huebsch WW, Pate MB (1995a) Heat transfer of R-134a in single-tube spray evaporation including lubricant effects and enhanced surface results. American Society of Heating, Refrigerating and Air-Conditioning Engineers, Inc., Atlanta, GAGoogle Scholar
  122. Moeykens SA, Newton BJ, Pate MB (1995b) Effects of surface enhancement, film-feed supply rate, and bundle geometry on spray evaporation heat transfer performance. American Society of Heating, Refrigerating and Air-Conditioning Engineers, Inc., Atlanta, GAGoogle Scholar
  123. Molki M, Ohadi MM, Rupani AP, Franca FH (2003) Enhanced flow boiling of R-134a in a minichannel plate evaporator. J Enhanc Heat Transf 10(1):1CrossRefGoogle Scholar
  124. Muller J (1986) Boiling heat transfer on finned tube bundles—the effect of tube position and intertube spacing. In: Proceedings of the 8th international heat transfer conference, vol 4, pp 2111–2116Google Scholar
  125. Muzzio A, Niro A, Arosio S (1998) Heat transfer and pressure drop during evaporation and condensation of R22 inside 9.52-mm OD microfin tubes of different geometries. J Enhanc Heat Transf 5(1):39CrossRefGoogle Scholar
  126. Nakajima K, Shiozawa A (1975) An experimental study on the performance of a flooded type evaporator. Heat Transf Jpn Res 4(3):49–66Google Scholar
  127. Nakayama W, Daikou T, Nakajima T (1982) Enhancement of Boiling and Evaporation on Structured Surfaces with Gravity-Driven Flow of R-11. In: Proceedings of the 7th international heat transfer conference, heat transfer 1982, Munich, Germany, vol 4, pp 409–414Google Scholar
  128. Nasr MR, Behfar R (2012) Enhanced evaporative fluid coolers. J Enhanc Heat Transf 19(2)Google Scholar
  129. Newell TA, Shah RK (2001) An assessment of refrigerant heat transfer, pressure drop, and void fraction effects in microfin tubes. HVAC&R Res 7(2):125–153CrossRefGoogle Scholar
  130. Nunez MP, Polley GT, Sunden B, Heggs PJ (1999) Methodology for the design of multi-stream plate-fin heat exchangers. In: Sunden B, Heggs PJ (eds) Recent advances in analysis of heat transfer for fin type surfaces. Computational Mechanics, Billerica, MA, pp 277–293Google Scholar
  131. O’Neill PS (1981) Private communication, February 16. Linde Div., Union Carbide Corp., Tonawanda, NYGoogle Scholar
  132. Ouazia B (2001) Evaporation heat transfer and pressure drop of HFC-134a inside a plate heat exchanger. In: Proceedings of American Society of Mechanical EngineersGoogle Scholar
  133. Owens WL (1978) Correlation of thin film evaporation heat transfer coefficient for horizontal tubes. In: Proceedings of the 5th OTEC conference, vol 3, pp 71–89Google Scholar
  134. Palm B (1990) Heat Transfer Augmentation in Flow Boiling by Aid of Perforated Metal Foils. In: ASME paper 90-WNHT-10, ASME, New YorkGoogle Scholar
  135. Panchal CB, France DM, Bell KJ (1992) Experimental investigation of single-phase, condensation, and flow boiling heat transfer for a spirally fluted tube. Heat Transf Eng 13(1):42–52CrossRefGoogle Scholar
  136. Parken WH, Fletcher LS, Sernas V, Han JC (1990) Heat transfer through falling film evaporation and boiling on horizontal tubes. J Heat Transf 112(3):744–750CrossRefGoogle Scholar
  137. Parker JL, El-Genk MS (2009) Saturation boiling of HFE-7100 dielectric liquid on copper surfaces with corner pins at different inclinations. J Enhanc Heat Transf 16(2)CrossRefGoogle Scholar
  138. Pearson JF, Young EH (1970) Simulated performance of refrigerant-22 boiling inside of tubes in a four pass shell and tube heat exchanger. AIChE Symp Ser 66(102):164–173Google Scholar
  139. Pettersen J (2003) Two-phase flow pattern, heat transfer, and pressure drop in microchannel vaporization of CO2/discussion. ASHRAE Trans 109:523Google Scholar
  140. Pierre B (1964) Flow resistance with boiling refrigerants: part 1 & part 2. ASHRAE J 6:58–77Google Scholar
  141. Polley GT, Ralston T, Grant ID (1980) Forced crossflow boiling in an ideal in-line tube bundle. In: ASME paper (80-HT), p 46Google Scholar
  142. Quazia B (2001) Evaporation heat transfer and pressure drop of HFC-134A inside a plate heat exchanger. In: Proceedings of the 2001 ASME international mechanical engineering congress and exposition, PID, vol 6, pp 115–123Google Scholar
  143. 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 HTD-52, pp 9–20Google Scholar
  144. Rifert VG, Butuzov AI, Belik DN (1975) Heat transfer in vapor generation in a falling film inside a vertical tube with a finely-finned surface. Heat Trans Soviet Res 7(2):22–25Google Scholar
  145. Rifert VG, Putilin J, Podberezny VL (1992) Evaporation heat transfer in liquid films flowing down the horizontal smooth and longitudinally-profiled tubes. In: Institution of Chemical Engineers, Davis Building, Rugby (ENGL)(3-1289)Google Scholar
  146. Robertson JM (1980) Review of boiling, condensing and other aspects of two-phase flow in plate fin heat exchangers. In: Shah RK, McDonald CF, Howard CP (eds) Compact heat exchangers-history, technological advances and mechanical design problems, HTD, vol 10. ASME, New York, pp 17–27Google Scholar
  147. Roser R, Thonon B, Mercier P (1999) Experimental investigations on boiling of n-pentane across a horizontal tube bundle: two-phase flow and heat transfer characteristics. Int J Refrig 22(7):536–547CrossRefGoogle Scholar
  148. Schlager LM, Pate MB, Bergles AE (1988a) Performance of microfin tubes with refrigerant-22 and oil mixtures. ASHRAE J:17–28Google Scholar
  149. Schlager LM, Pate MB, Bergles AE (1988b) Evaporation and condensation of refrigerant-oil mixtures in a smooth tube and a micro-fin tube. ASHRAE Trans 94(3112):149–166Google Scholar
  150. Schlager LM, Pate MB, Bergles AE (1990) Evaporation and condensation heat transfer and pressure drop in horizontal, 12.7-mm microfin tubes with refrigerant 22. J Heat Transf 112(4):1041–1047CrossRefGoogle Scholar
  151. Schliinder EU, Chawla J (1967) Local heat transfer and pressure drop for refrigerants evaporating in horizontal, internally finned tubes. In: Proc Int Cong Refrig paper 2.47Google Scholar
  152. Seo K, Kim Y (2000) Evaporation heat transfer and pressure drop of R-22 in 7 and 9.52 mm smooth/micro-fin tubes. Int J Heat Mass Transf 43(16):2869–2882CrossRefGoogle Scholar
  153. Shatto DP, Peterson GP (2017) Flow boiling heat transfer with twisted tape inserts. J Enhanc Heat Transf 24(1–6):21CrossRefGoogle Scholar
  154. Shinohara Y, Tobe M (1985) Development of an improved thermofin tube. Hitachi Cable Rev 4:47–50Google Scholar
  155. Shinohara Y, Oizumi K, Itoh Y, Hori M (1987) Inventors Hitachi Cable Ltd, assignee. Heat-transfer tubes with grooved inner surface. United States Patent US 4,658,892Google Scholar
  156. Steiner D, Taborek J (1992) Flow boiling heat transfer of single components in vertical tubes. Heat Transf Eng 13(2):43–69CrossRefGoogle Scholar
  157. Swenson HS, Carver JR, Szoeke G (1962) The effects of nucleate boiling versus film boiling on heat transfer in power boiler tubes. J Eng Power 84(4):365–371CrossRefGoogle Scholar
  158. Taitel Y, Dukler AE (1976) A model for predicting flow regime transitions in horizontal and near horizontal gas-liquid flow. AICHE J 22(1):47–55CrossRefGoogle Scholar
  159. Takahashi K, Daikoku T, Yasuda H, Yamashita T, Zushi S (1990) The evaluation of a falling film evaporator in an R22 chiller unit. ASHRAE Trans 96(2):158–163Google Scholar
  160. Takamatsu H, Momoki S, Fujii T (1993) A correlation for forced convective boiling heat transfer of pure refrigerants in a horizontal smooth tube. Int J Heat Mass Transf 36(13):3351–3360CrossRefGoogle Scholar
  161. Tatara RA, Payvar P (1999) Effects of oil on boiling R-123 and R-134a flowing normal to an integral-finned tube bundle. ASHRAE Trans 105:478Google Scholar
  162. Tatara RA, Payvar P (2000a) Effects of oil on boiling of replacement refrigerants flowing normal to a tube bundle-part I. In: ASHRAE Winter Meeting 2000 ASHRAEGoogle Scholar
  163. Tatara RA, Payvar P (2000b) Effects of oil on boiling of replacement refrigerants flowing normal to a tube bundle—Part II. In: ASHRAE Winter Meeting 2000 ASHRAEGoogle Scholar
  164. Tatsumi A, Oizumi K, Hayashi M, Ito M (1982) Application of inner groove tubes to air conditioners. Hitachi Rev 32(1):55–60Google Scholar
  165. Thome JR (1990) Enhanced boiling heat transfer. Hemisphere Pub. Corp (Taylor & Francis)Google Scholar
  166. Thome JR (1996) Boiling of new refrigerants: a state-of-the-art review. Int J Refrig 19(7):435–457CrossRefGoogle Scholar
  167. Thome JR, Favrat D, Kattan N (1997) Evaporation in microfin tubes: a generalized prediction modelGoogle Scholar
  168. Thome JR, Kattan N, Favrat D (1999) Evaporation in microfin tubes: a generalized prediction model. In: Convective flow and pool boiling. Taylor and Francis, pp 239–244Google Scholar
  169. Thonon B, Vidil R, Marvillet C (1995) Recent research and developments in plate heat exchangers. J Enhanc Heat Transf 2(1–2):149CrossRefGoogle Scholar
  170. Topin F, Rahli O, Tadrist L, Pantaloni J (1996) Experimental study of convective boiling in a porous medium: temperature field analysis. J Heat Transf 118(1):230CrossRefGoogle Scholar
  171. Torikoshi K, Ebisu T (1999) Japanese advanced technologies of heat exchanger in air-conditioning and refrigeration applications. In: Shah RK, Bell KJ, Honda H, Thonon B (eds) Compact heat exchangers and enhancement technology for the process industries. Begell Honse, New York, pp 17–24Google Scholar
  172. Tran TN, Wambsganss MW, France DM (1996) Small circular-and rectangular-channel boiling with two refrigerants. Int J Multiphase Flow 22(3):485–498zbMATHCrossRefGoogle Scholar
  173. Tsuchida T, Yasuda K, Hori M, Otani T (1993) Internal heat transfer characteristics and workability of narrow thermofin tubes. Hitachi Cable Rev 12:97–100Google Scholar
  174. Varma HK, Agrawal KN, Bansal ML (1991) Heat transfer augmentation by coiled wire turbulence promoters in a horizontal refrigerant-22 evaporator. Presented at winter meeting, American Society of Heating, Refrigerating, and Air-Conditioning Engineers, New York, NY. ASHRAE Trans 97:359–364Google Scholar
  175. Wadekar VV (1998) A comparative study of in-tube boiling on plain and high flux coated surfaces. J Enhanc Heat Transf 5(4):257CrossRefGoogle Scholar
  176. Wambsganss MW, France DM, Jendrzejczyk JA, Tran TN (1993) Boiling heat transfer in a horizontal small-diameter tube. J Heat Transf 115(4):963–972CrossRefGoogle Scholar
  177. Webb RL, Apparao TV (1990) Performance of flooded refrigerant evaporators with enhanced tubes. Heat Transf Eng 11(2):29–44CrossRefGoogle Scholar
  178. Webb RL, Chien LH (1994) Correlation of convective vaporization on banks of plain tubes using refrigerants. Heat Transf Eng 15(3):57–69CrossRefGoogle Scholar
  179. Webb RL, Choi K-D, Apparao T (1990) A theoretical model to predict the heat duty and pressure drop in flooded refrigerant evaporators. ASHRAE Trans 95(Pt. 1):326–338Google Scholar
  180. Webb RL, Gupte NS (1992) A critical review of correlations for convective vaporization in tubes and tube banks. Heat Transf Eng 13(3):58–81CrossRefGoogle Scholar
  181. Webb RL, Kim NH (2005) Principles of enhanced heat transfer, 2nd edn. Taylor & FrancisGoogle Scholar
  182. Webb RL, Paek JW (2003) Letter to the editors—concerning paper published by Y.-Y. Yan and T.-F. Lin. Int J Heat Mass Transf 46:1111–1112CrossRefGoogle Scholar
  183. Weiland 1991 Ripple fin tubes, Wieland-Werke AG brochure TKI-42e(M)-02.91, Ulm, GermanyGoogle Scholar
  184. Weisman J, Illeslamlou S (1988) A phenomenological model for prediction of critical heat flux under highly subcooled conditions. Fusion Technol 13:654–659CrossRefGoogle Scholar
  185. Weisman J, Pei BS (1983) Prediction of critical heat flux in flow boiling at low qualities. Int J Heat Mass Transf 26(10):1463–1477CrossRefGoogle Scholar
  186. Weisman J, Yang JY, Usman S (1994) A phenomenological model for boiling heat transfer and the critical heat flux in tubes containing twisted tapes. Int J Heat Mass Transf 37(1):69–80CrossRefGoogle Scholar
  187. Wen MY, Hsieh SS (1995) Saturated flow boiling heat transfer in internally spirally knurled/integral finned tubes. J Heat Transf 117(1):245–248CrossRefGoogle Scholar
  188. Wen MY, Jang KJ, Ho CY (2015) Flow boiling heat transfer in R-600a flows inside an annular tube with metallic porous inserts. J Enhanc Heat Transf 22(1)CrossRefGoogle Scholar
  189. Withers JG, Habdas EP (1974) Heat transfer characteristics of helical-corrugated tubes for intube boiling of refrigerant R-12. AIChE Symp Ser 70:98–106Google Scholar
  190. Yan YY, Lin TF (1998) Evaporation heat transfer and pressure drop of refrigerant R-134a in a small pipe. Int J Heat Mass Transf 41(24):4183–4194CrossRefGoogle Scholar
  191. Yan YY, Lin TF (1999) Evaporation heat transfer and pressure drop of refrigerant R-134a in a plate heat exchanger. J Heat Transf 121(1):118–127CrossRefGoogle Scholar
  192. Yasuda K, Ohizumi K, Hori M, Kawamata O (1990) Development of condensing thermofin-HEX-C tube. Hitachi Cable Rev:27–30Google Scholar
  193. Yasunobu F, Yang Y, Fujita N (2002) Flow boiling heat transfer and pressure drop in uniformly heated small tubes. Heat Transf 3:743–748Google Scholar
  194. Yilmaz S, Palen JW, Taboerk J (1981) Enhanced boiling surfaces as single tubes and tube bundles. In: Webb RL, Carnavos TC, Park EL, Hostetler KM (eds) Advances in enhanced heat transfer, HTD, vol 18, pp 123–130Google Scholar
  195. Yoshida S, Matsunaga T, Hong HP, Nishikawa K (1987) Heat transfer to refrigerants in horizontal evaporator tubes with internal, spiral grooves. In: Proceedings of the 1987 ASME-JSME thermal engineering joint conference, vol 5, pp 165–172Google Scholar
  196. Yu W, France DM, Wambsganss MW, Hull JR (2002) Two-phase pressure drop, boiling heat transfer, and critical heat flux to water in a small-diameter horizontal tube. Int J Multiphase Flow 28(6):927–941zbMATHCrossRefGoogle Scholar
  197. Yu HL, Li RY, Huang X, Chen ZH (2004) EHD boiling heat transfer enhancement outside horizontal tubes. J Enhanc Heat Transf 11(4):291CrossRefGoogle Scholar
  198. Zeng X, Chyu M, Ayub ZH (1998) Ammonia spray evaporation heat transfer performance of single low-fin and corrugated tubes. ASHRAE Trans 104(Pt.1):185–196Google Scholar
  199. Zeng X, Chyu MC Ayub ZH (2000) An experimental study of spray evaporation of Ammonia in a square-pitch, low-fin tube bundle. In: Proceedings of the 34th national heat transfer conference, Pittsburgh, PA. NHTC, pp 2000–12215Google Scholar
  200. Zhang Y, Wei J, Guo D (2012) Enhancement of flow-jet combined boiling heat transfer of FC-72 over micro-pin-finned surfaces. J Enhanc Heat Transf 19(6):489CrossRefGoogle Scholar
  201. Zhao Y, Molki M, Ohadi MM, Dessiatoun SV (2000) Flow boiling of CO2 in microchannels. Univ. of Maryland, College Park, MDGoogle Scholar
  202. Zhao Y, Molki M, Ohadi MM 2001 Predicting flow boiling heat transfer of C02 microchannels. In: Jaluria Y (ed) Proceedings of the ASME, HTD, Vol 369-3. ASME international mechanical engineering congress and exposition, ASME, New York, pp 195–204Google Scholar
  203. Zhou DW, Liu DY, Cheng P (2004) Boiling heat transfer characteristics from a horizontal tube embedded in a porous medium with acoustic excitation. J Enhanc Heat Transf 11(3):231CrossRefGoogle 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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