0
TECHNICAL PAPERS: Evaporation, Boiling, and Condensation

An Experimental Investigation on Flow Boiling of Ethylene-Glycol/Water Mixtures

[+] Author and Article Information
Satish G. Kandlikar, Murat Bulut

Mechanical Engineering Department, Rochester Institute of Technology, Rochester, NY 14623

J. Heat Transfer 125(2), 317-325 (Mar 21, 2003) (9 pages) doi:10.1115/1.1561816 History: Received March 21, 1999; Revised November 14, 2002; Online March 21, 2003
Copyright © 2003 by ASME
Your Session has timed out. Please sign back in to continue.

References

Finlay, I. C., Boyle, R. J., Pirault, J. P., and Biddulph, T., 1987, “Nucleate and Film Boiling of Engine Coolants Flowing in a Uniformly Heated Duct of Small Cross Section,” SAE Technical Paper Series, No. 870032.
Kandlikar,  S. G., 1998, “Heat Transfer and Flow Characteristics in Partial Boiling, Fully Developed Boiling, and Significant Void Flow Regions of Subcooled Flow Boiling,” ASME J. Heat Transfer, 120, pp. 395–401.
Kandlikar,  S. G., 1990, “A General Correlation for Two-Phase Flow Boiling Heat Transfer Coefficient Inside Horizontal and Vertical Tubes,” ASME J. Heat Transfer, 102, pp. 219–228.
McAdams,  W. H., Minden,  C. S., Carl,  R., Picornell,  D. M., and Dew,  J. E., 1949, “Heat Transfer at High Rates to Water with Surface Boiling,” Ind. Eng. Chem., 41(9), pp. 1945–63.
Jens, W. H., and Lottes, P. A., 1951, “Analysis of Heat Transfer, Burnout, Pressure Drop and Density Data for High Pressure Water,” U.S. AEC Report ANL-4627.
Thom, J. R. S., Walker, W. M., Fallon, T. A., and Reising, G. F. S., 1965, “Boiling in Subcooled Water During Flow up Heated Tubes or Annuli,” paper presented at the Symposium on Boiling Heat Transfer in Steam Generating Units and Heat Exchangers, Manchester, Sept. 15–16, 180 (Part 3C) Institute of Mech. Eng., London.
Mikic,  B. B., and Rohsenow,  W. M., 1969, “New Correlation of Pool Boiling Data Including the Effect of Heating Surface Characteristics,” ASME J. Heat Transfer, 91, pp. 241–250.
Shah,  M. M., 1977, “A General Correlation for Heat Transfer During Subcooled Boiling in Pipes and Annuli,” ASHRAE J., 83, Part 1, pp. 205–215.
Vandervort,  C. L., Bergles,  A. E., and Jensen,  M. K., “An Experimental Study of Critical Heat Flux in Very High Heat Flux Subcooled Boiling,” Int. J. Heat Mass Transf., 37, Suppl. 1, pp. 54–57.
Kandlikar,  S. G., 1998, “Boiling Heat Transfer in Binary Systems: Part I-Pool Boiling,” ASME J. Heat Transfer, 120, pp. 380–387.
Calus,  W. F., di Montegnacco,  A., and Kenning,  D. B. R., “Heat Transfer in a Natural Circulation Single Tube Reboiler, Part II: Binary Liquid Mixtures,” Chem. Eng. J., 6 , pp. 251–264.
Bennett,  D. L., and Chen,  J. C., 1980, “Forced Convection Boiling in Vertical Tubes for Saturated Pure Components and Binary Mixtures,” AIChE J., 26(3), pp. 454–461.
Jung, D. S., 1988, “Horizontal Flow Boiling Heat Transfer Using Refrigerant Mixtures,” Ph.D. dissertation, University of Maryland.
Wettermann, M., and Steiner, D., 2000, “Flow Boiling Heat Transfer of Wide-Boiling Binary and Ternary Mixtures,” Boiling 2000, Phenomena and Emerging Applications, Proceedings of the Engineering Foundation Conference, Anchorage, Alaska, April 30–May 5, pp. 684–697.
Barbosa, J. R., Wadekar, V. V., and Hewitt, G. F., 2000, “A Review of Heat and Mass Transfer in Flow Boiling of Binary Mixtures,” Boiling 2000, Phenomena and Emerging Applications, Proceedings of the Engineering Foundation Conference, Anchorage, Alaska, April 30–May 5, pp. 754–771.
Kandlikar,  S. G., 1998, “Boiling Heat Transfer in Binary Systems: Part II-Flow Boiling,” ASME J. Heat Transfer, 120, pp. 388–394.
Ambrogi, G., McAssey, E. V., Cozzone, G., and Hoover, C., 1997, “The Effect of Off-Design Operation on the Thermal Performance of Propylene-glycol and Ethylene-glycol Engine Coolants,” SAE Paper No. 971827, Vehicle Thermal Management Conference, Indianapolis, IN, pp. 441–448.
McAssey, E. V., Stinson, C., and Gollin, M., 1995, “Evaluation of Engine Coolants Under Flow Boiling Conditions,” Proceedings of the ASME Heat Transfer Division, M. Ebadian and M. Kaviany, eds., HTD-Vol. 317-1, pp. 193–200.
Bhowmick, S., Branchi, C., Gollin, M., and Cozzone, G., 1997, “Prediction of Heat Transfer in Engine Cooling Systems,” Experimental Heat Transfer, Fluid Mechanics, and Thermodynamics 1997, June 1997, 1 , M. Giot, F. Mayinger, and G. P. Celata, eds., Brussels, Belgium, pp. 387–392.
Bhowmick, S., Branchi, C. McAssey, E. V., Gollin, M., and Cozzone, G., 1997, “Prediction of Heat Transfer in Engine Cooling Systems,” Proceedings of the 4th World Conference on Experimental Heat Transfer, Fluid Mechanics, and Thermodynamics, Brussels, Belgium.
McAssey E. V., Jr., and Kandlikar, S. G., 1999, “Convective Heat Transfer of Binary Mixtures Under Flow Boiling Conditions,” Two-Phase Flow Modelling and Experimentation 1999, Proceedings of the 2nd International Symposium on Two-phase Flow Modeling and Experimentation, Pisa, Italy, May 23–26, 1999, Eds. Celata, G. P., Di Marco, P., and Shah, R. K., pp. 271–278.
Chen,  J. C., 1966, “A Correlation for Boiling Heat Transfer to Saturated Fluids in Convective Flow,” Ind. Eng. Chem. Process Des. Dev., 5(3), pp. 322–329.
Rohsenow, W. M., Hartnett, J. P., and Ganic, E. N., 1985, Boiling, Handbook of Heat Transfer Fundamentals, p. 12, Chap. 12.
Behar, M., Courraud, M., Ricque, R., and Semeria, R., 1966, “Fundamental Aspects of Subcooled Boiling With an Without Dissolved Gases,” Proceedings of the Third International Heat Transfer Conference, AIChE-ASME, 4 , pp. 1–11.
Murphy, R. M., and Bergles, A. E., 1971, “Subcooled Flow Boiling of Fluocarbons,” M.I.T. Engineering Projects Laboratory Report No. DSR 71903-72.
Kandlikar, S. G., and Spiesman, P. H., 1997, “Effect of Surface Characteristics on Flow Boiling Heat Transfer,” paper presented at the Engineering Foundation conference on Convective and Pool Boiling, F. Mayinger and M. Lehner, eds., Irsee, Germany, May 18–25, pp. 191–197.
Kandlikar,  S. G., and Stumm,  B. S., 1995, “A Control Volume Approach to Predict Departure Bubble Diameter in Flow Boiling,” ASME J. Heat Transfer, 117, pp. 990–997.
Kandlikar, S. G., and Howell, M. J., 1996, “Investigation of Nucleation Characteristics and Heat Transfer on Microfin Surfaces,” Proceedings of the Second European Thermal-Sciences and 14th UIT National Heat Transfer Conference, Rome, Italy, May 29–31, G. P. Celata, P. DiMarco, and A. Mariani, eds., 1 , pp. 241–246.
Gnielinski,  V., 1976, “New Equations for Heat and Mass Transfer in Turbulent Pipe and Channel Flow,” Int. Chem. Eng. 16, pp. 359–368.
Petukhov,  B. S., and Popov,  V. N., 1963, “Theoretical Calculation of Heat Exchanger in Turbulent Flow in Tubes of an Incompressible Fluid with Variable Physical Properties,” High Temp., 1(1), pp. 69–83.

Figures

Grahic Jump Location
Heat flux dependence on wall superheat at constant local subcooling during subcooled flow boiling
Grahic Jump Location
Effect of dissolved gases on flow boiling heat transfer of R-113, Murphy and Bergles 25, reproduced with permission
Grahic Jump Location
Schematic of the experimental setup
Grahic Jump Location
Details of heater assembly
Grahic Jump Location
Uncertainty estimates in the experimental results
Grahic Jump Location
Variation of saturation temperature for ethylene glycol/water mixture at atmospheric pressure
Grahic Jump Location
Surface heat flux versus wall superheat for flow boiling of water/ethylene glycol mixtures at V=0.129 m/s and atmospheric pressure
Grahic Jump Location
Heat transfer coefficient versus wall superheat for flow boiling of water/ethylene glycol mixtures at V=0.129 m/s and atmospheric pressure
Grahic Jump Location
Surface heat flux versus wall superheat for flow boiling of water/ethylene glycol mixtures at V=0.387 m/s and atmospheric pressure
Grahic Jump Location
Heat transfer coefficient versus wall superheat for flow boiling of water/ethylene glycol mixtures at V=0.387 m/s and atmospheric pressure
Grahic Jump Location
Effect of hysteresis on flow boiling heat transfer for pure water at V=0.387 m/s and atmospheric pressure
Grahic Jump Location
Effect of hysteresis on flow boiling heat transfer for 6% ethylene-glycol/water mixture at V=0.387 m/s and atmospheric pressure
Grahic Jump Location
Variation of the volatility parameter in the Kandlikar 2 correlation for binary mixtures of ethylene glycol/water at atmospheric pressure
Grahic Jump Location
Comparison of the present data with the FDB correlation (asymptote to data at high superheats), Eqs. (1) and (2), water at atmospheric pressure
Grahic Jump Location
Comparison of the present data with the FDB correlation (asymptote to data at high superheats), Eqs. (1) and (2), 5 percent solution of ethylene glycol in water at atmospheric pressure
Grahic Jump Location
Comparison of the present data with the FDB correlation (asymptote to data at high superheats), Eqs. (1) and (2), 11 percent solution of ethylene glycol in water at atmospheric pressure
Grahic Jump Location
Comparison of the present data with the FDB correlation (asymptote to data at high superheats), Eqs. (1) and (2), 30 percent solution of ethylene glycol in water at atmospheric pressure
Grahic Jump Location
Comparison of the present data with the FDB correlation (asymptote to data at high superheats), Eqs. (1) and (2), 40 percent solution of ethylene glycol in water at atmospheric pressure

Tables

Errata

Discussions

Some tools below are only available to our subscribers or users with an online account.

Related Content

Customize your page view by dragging and repositioning the boxes below.

Related Journal Articles
Related eBook Content
Topic Collections

Sorry! You do not have access to this content. For assistance or to subscribe, please contact us:

  • TELEPHONE: 1-800-843-2763 (Toll-free in the USA)
  • EMAIL: asmedigitalcollection@asme.org
Sign In