H�c```������(�����1�!h�"P����O�W��}r ��rt�h4WMٰ{�n���p7�J S��Qs&�b ���ܲE/8�� Institut de Mécanique des Fluides de Toulouse, Flow boiling heat transfer in microgravity: Recent results, Two-Phase Pipe Flow in Microgravity with and without Phase Change: recent progress and future prospects, Void fraction prediction in annular two-phase flow, Review of flow boiling and critical heat flux in microgravity, Influence of bubble initial size on bubble-to-slug transition, Proposed Correlations of Data for Isothermal Two-Phase Two-Component Flow in Pipes, Microgravity Heat Transfer in Flow Boiling, Universal approach to predicting saturated flow boiling heat transfer in mini/micro-channels – Part II. In: ANS topical meeting on water reactor safety, Salt Lack City, Groeneveld DC, Cheng SC, Doan T (1986) The CHF look-up table, a simple and accurate method for predicting critical heat flux. In: Proceedings of 8th Int Heat Transfer Conf, pp 2131–2136, Fujita Y, Yang Y, Fujita N (2002) Flow boiling heat transfer and pressure drop in uniformly heated small tubes. This study will review published literature concerning two-phase flow and heat transfer in reduced gravity. Its knowledge is also important for the safe operation of existing single-phase systems in case of accidental increase of heat generation rate. Argonne National Lab., Lemont, IL, 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. To investigate flow boiling in microgravity, test sections of transparent heated tube and transparent heating surface were developed, and heat transfer characteristics were directly related to the liquid-vapor behaviors observed. Int J Refrig 23(1):4–25, Celata GP, Cumo M, Mariani A (1994) Enhancement of CHF water subcooled flow boiling in tubes using helically coiled wires. Int J Multiphase Flow 22(3):485–498, Tsuchida T, Yasuda K, Hori M, Otani T (1993) Internal heat transfer characteristics and workability of narrow thermofin tubes. Nucl Eng Des 223(3):315–328, Churchill SW, Churchill RU (1975) A comprehensive correlating equation for heat and component transfer by free convection. A random numerical method is used to simulate the influence of the initial bubble size on the bubble-to-slug transition based on the bubble coalescence mechanism. PDF | On Mar 3, 2017, Catherine Colin and others published Flow Boiling in Tube in Microgravity | Find, read and cite all the research you need on ResearchGate Heat Transf Eng 7(1):46–62, Groeneveld DC et al (1996) The 1995 look-up table for critical heat flux in tubes. Appl Therm Eng 22(1):83–95, Lorenz JJ, Yung D (1979) A note on combined boiling and evaporation of liquid films on horizontal tubes. J Heat Transf 116(3):670–678, 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. This service is more advanced with JavaScript available, Handbook of Thermal Science and Engineering Int J Heat Mass Transf 38(8):1363–1376, Moeykens, SA, Pate MB (1996) Effect of lubricant on spray evaporation heat transfer performance of R-134a and R-22 in tube bundles (No. J Enhanc Heat Transf 18(3):209–220, Huang X, Li RY, Yu HL (2004) Enhancement of boiling heat transfer for R11 and R123 by applying uniform electric field. Int J HVAC&R Res 1(1):35–47, Hewitt GF, Roberts DN (1969) Studies of two-phase flow patterns by simultaneous X-ray and flash photography. The aim of the present paper is to describe the results of flow boiling heat transfer at low gravity and compare them with those obtained at earth gravity, evaluating possible differences. Int J Multiphase Flow 37(6):647–659, Brackbill JU, Kothe DB, Zemach C (1992) A continuum method for modeling surface tension. Flow boiling in tubes is a highly efficient heat transfer regime, which is used for thermal management in various engineered systems with high energy density, from power electronics to heat exchangers in power plants and nuclear reactors. J Heat Transf 112(4):1041–1047, Schliinder EU, Chawla J (1967) Local heat transfer and pressure drop for refrigerants evaporating in horizontal, internally finned tubes. Heat Transf Eng 1(4):32–37, Cavallini A, Del Col D, Doretti L, Longo GA, Rossetto L (1998) Refrigerant vaporisation inside enhanced tubes: a heat transfer model. In: Convective flow and pool boiling. Not affiliated Multiph Sci Technol 10(4):369–405, Tong LS, Tang YS (1997) Boiling heat transfer and two-phase flow, 2nd edn. A thorough theoretical approach with such microscopic experimental, The long-duration fluid physics experiments on a thermocapillary-driven flow ASHRAE Trans 94(3112):149–166, 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. Doctoral dissertation, Oklahoma State University, Cui S, Tan Y, Lu Y (1992) Heat transfer and flow resistance of R-502 flow boiling inside horizontal ISF tubes. Int J Heat Mass Transf 37(1):53–67, Chamra LM, Webb RL (1995) Condensation and evaporation in micro-fin tubes at equal saturation temperatures. The effects of inlet pressure, heat flux, and curvature ratio on heat transfer characteristic are analyzed. In: Institution of Chemical Engineers, Davis Building, Rugby (ENGL)(3-1289), Robertson JM (1980) Review of boiling, condensing and other aspects of two-phase flow in plate fin heat exchangers. US Department of Commerce, National Institute of Standards and Technology, Kew PA, Cornwell K (1997) Correlations for the prediction of boiling heat transfer in small-diameter channels. © 2020 Springer Nature Switzerland AG. Heat Transf-Sov Res 4(6):7–12, Tomiyama A (1998) Struggle with computational bubble dynamics. (1989) Saturated flow boiling of water in vertical tubes, Int. Clarendon Press, Oxford, Cousins LB, Denton WT, Hewitt GF (1965) Liquid mass transfer in annular two-phase flow. J Enhanc Heat Transf 11(4):299, Hwang YW, Kim MS, Kim Y (2005) Evaporation heat transfer and pressure drop in micro-fin tubes before and after tube expansion. AICHE J 1(4):531–535, Gosman AD, Lekakou C, Politis S, Issa RI, Looney MK (1992) Multidimensional modeling of turbulent two-phase flows in stirred vessels. Int J Heat Mass Transf 41(8):1103–1112, Yang SR, Kim RH (1988) A mathematical model of the pool boiling nucleation site density in terms of the surface characteristics. Part II: enhanced tubes. Int J Heat Mass Transf 45(11):2351–2372, Hibiki T, Ishii M (2003) Active nucleation site density in boiling systems. J Heat Transf 111(2):518–524, Conklin JC, Vineyard EA (1992) Flow boiling enhancement of R22 and a nonazeotropic mixture of R143a and R124 using perforated foils. As regards the dryout phenomenon, measurement of critical heat flux was attempted in a short microgravity duration and the process of dryout was investigated for a moderate quality region based on the measured temperature fluctuation and corresponding liquid-vapor behaviors. In: Kakac S, Bergles AE, Mayinger F, Yuncu H (eds) Heat Transfer Enhancement of Heat Exchangers. ResearchGate has not been able to resolve any citations for this publication. ���*�`��B���0�!�¾G�j��As�����)#h,#d]F@lh�2�Lt�� r���d�G�4�E4�8�1�jF��w��4�-!�d/Kܔ���pP9�Ҝ�+Nrȩ-��`I3]2�O#h��L*0� �HǢ@���h�99c�\�0J0h� 3 BH��aA5�����6:��Bc]�n ܐY#���X3X�7�M�)Mi`�d�� � Y,x�d��M�5�u��mZ�K�����a�#��`!���d�C-�^ޡCw6��B�H�*�4!r�� �:�:,V�P A3�(�i�(�AxXh����Z!d�7}�c-Sr�S]Yj�p�eq V� �@�B�3ZvF�fXw>�5��Fsa�3[��a l�:����m��89�4�����@ކV3B���س��`]�}�i�0Q`�5��]�7dz�e���F�� �kr��5�)ga���4�#�� Uve5��E˾� �|�O�$��>�_-* endstream endobj 48 0 obj 837 endobj 49 0 obj << /Filter /LZWDecode /Length 48 0 R >> stream Chem Eng Prog 48(3):141–146, Rohsenow WM, Hartnett JP, Ganic EN (1998) Handbook of heat transfer fundamentals, 3rd edn. Taylor and Francis, pp 239–244, Thonon B, Vidil R, Marvillet C (1995) Recent research and developments in plate heat exchangers. Adv Heat Tran 18:109–122, Del Col D, Webb RL, Narayanamurthy R (2002) Heat transfer mechanisms for condensation and vaporization inside a microfin tube. Furthermore, annular-to-dryout and dryout-to-mist flow transition curves have been added and integrated into the new flow pattern map, identified by distinct trends of the heat transfer coefficient as a function of vapor quality and by flow pattern observations to determine (and then predict) the inception and completion of dryout in horizontal tubes. AICHE J 22(1):47–55, Takahashi K, Daikoku T, Yasuda H, Yamashita T, Zushi S (1990) The evaluation of a falling film evaporator in an R22 chiller unit. In: Proc Int Cong Refrig paper 2.47, Seo K, Kim Y (2000) Evaporation heat transfer and pressure drop of R-22 in 7 and 9.52 mm smooth/micro-fin tubes. pp 1-44 | ASHRAE Trans 76:96–107, Czikk AM, O’Neill PS, Gottzmann CF (1981) Nucleate pool boiling from porous metal films effect of primary variables. J Enhanc Heat Transf 5(4):257, Wambsganss MW, France DM, Jendrzejczyk JA, Tran TN (1993) Boiling heat transfer in a horizontal small-diameter tube. J Heat Transf 113(1):209–215, Antonelli R, O’Neill PS (1981) Design and application considerations for heat exchangers with enhanced boiling surfaces. J Enhanc Heat Transf 11(3):231, © The Author(s), under exclusive license to Springer Nature Switzerland AG 2020, Indian Institute of Engineering, Science and Technology, Shibpur, https://doi.org/10.1007/978-3-030-20755-7_3, SpringerBriefs in Applied Sciences and Technology. Int J Heat Mass Transf 41(24):4183–4194, Yan YY, Lin TF (1999) Evaporation heat transfer and pressure drop of refrigerant R-134a in a plate heat exchanger. 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. Adv Enhanced Heat Transf 43:39–47, Chyu MC, Bergles AE (1989) Horizontal-tube falling-film evaporation with structured surfaces. Thus, analysis of flow boiling in tubes is built upon a broad knowledge base on related processes in two-phase flow and heat transfer mechanisms that have been a subject of numerous experimental, theoretical, and computational investigations over many decades. Springer, Dordrecht, pp 325–346, Fujita Y, Ohta H, Hidaka S, Nishikawa K (1986) Nucleate boiling heat transfer on horizontal tubes in bundles. Presented at second UK heat transfer conference, vol 1, pp 21–32, Crain Jr B (1973) Forced convection heat transfer to a two-phase mixture of water and steam in a helical coil.
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