Effect of Contact Angle on Nucleate Pool Boiling Heat Transfer

Abstract

Abstract:

Abstract： Based on analysis of a semi-analytical heat transfer model with contact angle effect, it is found that the boiling heat transfer characteristics could be expressed as a function of wall superheat, contact angle and physical properties. A correlation for predicting the effect of contact angle on wall heat flux of pool boiling was deduced by using the graphical method. By analyzing the saturated water data on plane metal surface or its coated surface under different pressure conditions, an empirical correlation for predicting the wall heat flux of saturated water nucleate pool boiling under atmospheric pressure was obtained. Furthermore, a semiempirical nucleate pool boiling correlation applying to various liquids under wider pressures was also proposed. The results show that predicted values of saturated water nucleate pool boiling under atmospheric pressure are in good agreement with the experimental results.

Key words: boiling, heat flux, contact angle； heat transfer characteristics

CLC Number:

TK 124

CHEN Yanjun,LI Yuanyang,LIU Zhenhua. Effect of Contact Angle on Nucleate Pool Boiling Heat Transfer[J]. Journal of Shanghai Jiaotong University, 2015, 49(01): 135-140.

References

［1］Pioro L S, Pioro I L. Industrial twophase thermosyphons: Chapter 2［M］. New York: Begell House, 1997.

［2］Kutateladze S S. Heat transfer in condensation and boiling［M］. USA: AEC Rep, 1952.

［3］Rohsenow W M. A method of correlating heat transfer data for surface boiling of liquids［R］. Cambridge, Mass: MIT Division of Industrial Cooporation, 1951.

［4］Rohsenow W M, Hartnett J P, Cho Y I. Handbook of Heat Transfer ［M］. 3rd ed. New York: McGrawHill, 1998.

［5］Jones B J, McHale J P, Garimella S V. The influence of surface roughness on nucleate pool boiling heat transfer［J］. International Journal of Heat and Mass Transfer, 2009 131(12): 121009121014.

［6］Li Y Y, Liu Z H, Wang G S. A predictive model of nucleate pool boiling on heated hydrophilic surfaces［J］. International Journal of Heat and Mass Transfer, 2013, 65: 789797.

［7］Benjamin R J, Balakrishnan A R. Nucleate pool boiling heat transfer of pure liquids at low to moderate heat fluxes［J］. International Journal of Heat and Mass Transfer, 1996, 39: 24952504.

［8］Phan H T, Caney N, Marty P, et al. Surface wettability control by nanocoating: The effects on pool boiling heat transfer and nucleation mechanism［J］. International Journal of Heat and Mass Transfer, 2009, 52(23): 54595471.

［9］Gerardi C. Investigation of the pool boiling heat transfer enhancement of nanoengineered fluids by means of highspeed infrared thermography［D］. USA: Massachusetts Institute of Technology, 2009.

［10］Rohsenow W M. Boiling［J］. Annual Review of Fluid Mechanics, 1971, 3(1): 211236.

［11］Feng B, Weaver K, Peterson G P. Enhancement of critical heat flux in pool boiling using atomic layer deposition of alumina［J］. Applied Physics Letters, 2012, 100(5): 05312013.

［12］Gaertner R F, Westwater J W. Population of active sites in nucleate boiling heat transfer［J］. Chemical Engineering Progress, 1960, 56(30): 3948.

［13］Dhir V K, Liaw S P. Framework for a united model for nucleate and transition pool boiling［J］. ASME Journal of Heat Transfer, 1989, 111(3): 739746.

［14］Li C, Wang Z K, Wang P I, et al. Nanostructured copper interface for enhanced boiling［J］. Small, 2008, 4(8): 10841088.

［15］Saeidi D, Alemrajabi A A. Experimental investigation of pool boiling heat transfer and critical heat flux of nanostructured surfaces［J］. International Journal of Heat and Mass Transfer, 2013, 60: 440449.

［16］Hsu C C, Chen P H. Surface wettability effects on critical heat flux of boiling heat transfer using nanoparticle coatings［J］. International Journal of Heat and Mass Transfer, 2012, 55 (13): 37133719.

［17］Ahn H S, Kang S H, Kim M H. Visualized effect of alumina nanoparticles surface deposition on water flow boiling heat transfer［J］. Experimental Thermal Fluid Science, 2012, 37: 154163.

［18］Kwark S M, Amaya M, Kumar R, et al. Effects of pressure, orientation, and heater size on pool boiling of water with nanocoated heaters［J］. International Journal of Heat and Mass Transfer, 2010, 53 (2324): 51995208.

［19］McGillis W R, Carey V P, Fitch J S, et al. Pool boiling enhancement techniques for water at low pressure［C］∥ Proceedings, Seventh Annual IEEE Semiconductor Thermal Measurement and Management Symposium. New York: IEEE, 1991: 6472.

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