Fundamental assessments and new enabling proposals for heat transfer correlations and flow regime maps for shear driven condensers in the annular/stratified regime

A. Narain; R.r. Naik; S. Ravikumar; S. S. Bhasme

doi:10.18186/jte.47856

Fundamental assessments and new enabling proposals for heat transfer correlations and flow regime maps for shear driven condensers in the annular/stratified regime

Year 2015, Volume: 1 Issue: 4, 307 - 321, 01.04.2015

A. Narain R.r. Naik S. Ravikumar S. S. Bhasme

https://doi.org/10.18186/jte.47856

Cited By: 6

Abstract

Modern-day applications need mm-scale shear-driven flow condensers. Condenser designs need to ensure large heat transfer rates for a variety of flow conditions. For this, good estimates for heat-transfer rate correlations and correlations for the length of the annular regime (beyond which plug-slug flows typically occur) are needed. For confident use of existing correlations (particularly the more recent ones supported by large data sets) for shear-pressure driven internal condensing flows, there is a great need to relate the existing correlation development approaches to direct flow-physics based fundamental results from theory, computations, and experiments. This paper addresses this need for millimeter scale shear driven and annular condensing flows. In doing so, the paper proposes/compares a few new and reliable non-dimensional heat-transfer coefficient correlations as well as a key flow regime transition criteria/correlation

Keywords

mm-scale condensers, annular condensation, heat-transfer rate correlations, flow regime transition

References

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Lasance, C.J.M. and R.E. Simons Advances In High- Performance Cooling for Electronics. Electronics Cooling, 2005. 11. 2.
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Kivisalu, M.T., P. Gorgitrattanagul, and A. Narain, Results for high heat-flux flow realizations in innovative operations of milli-meter scale condensers and boilers. International Journal of Heat and Mass Transfer, 2014. 75(0): p. 381-398. 4.
Kivisalu, M.T., et al., Sensitivity of shear-driven internal condensing flows to pressure fluctuations and its utilization for heat flux enhancements. International Journal of Heat and Mass Transfer, 2013. 56(1-2): p. 758-774. 5.
Kivisalu, M.T., Experimental Investigation of Certain Internal Condensing Flows, Their Sensitivity to Pressure
Enhancements, in Mechanical Engineering. 2015, Michigan Technological University.
Carey, V.P., Liquid-vapor phase-change phenomena : an introduction to the thermophysics of vaporization and condensation processes in heat transfer equipment. 2nd ed. 2008, New York: Taylor and Francis. xxii, 742 p.
Mitra, S., et al., A quasi one-dimensional method and results for steady annular/stratified shear and gravity driven condensing flows. International Journal of Heat and Mass Transfer, 2011. 54(15-16): p. 3761-3776.
Taitel, Y. and A.E. Dukler, A model for predicting flow regime transitions in horizontal and near horizontal gas-liquid flow. AIChE Journal, 1976. 22(1): p. 47-55. Baker, O., Simaltaneous flow of Oil and Gas. Oil and Gas Journal, 1954. 53: p. 185-215.
Coleman, J.W. and S. Garimella, Two-phase flow regimes in round, square and rectangular tubes during condensation of refrigerant R134a. International Journal of Refrigeration-Revue Internationale Du Froid, 2003. 26(1): p. 117-128.
El Hajal, J., J.R. Thome, and A. Cavallini, Condensation in horizontal tubes, part 1: two-phase flow pattern map. International Journal of Heat and Mass Transfer, 2003. 46(18): p. 3349-3363.
Kim, S.-M. and I. Mudawar, Review of databases and predictive methods for heat transfer in condensing and boiling mini/micro-channel flows. International Journal of Heat and Mass Transfer, 2014. 77(0): p. 627-652.
Kim, S.-M. and I. Mudawar, Universal approach to predicting two-phase frictional pressure drop for adiabatic and condensing mini/micro-channel flows. International Journal of Heat and Mass Transfer, 2012. 55(11–12): p. 3246-3261.
Tibiriçá, C.B., G. Ribatski, and J.R. Thome, Saturated flow boiling heat transfer and critical heat flux in small horizontal flattened tubes. International Journal of Heat and Mass Transfer, 2012. 55(25–26): p. 7873-7883. 15.
Ravikumar, S., Fundamental Assesments and New Enabling Proposals for Heat Transfer Correlations and Flow Regime Maps for Shear Driven Condensers in the Annular/Stratified Regime, in Mechanical Engineering. 2015, Michigan Technolgocial University: Houghton, Michigan USA.
Naik, R., Development of unsteady two-dimensional computational simulation tools that simulate annular internal condensing flows and characterize interfacial waves, flow stability and flow sensitivity, in Mechanical Engineering - Engineering Mechanics 2015, Michigan Technological University: Houghton, MI.
Naik, R., S. Mitra, and A. Narain, Steady and Unsteady Simulations that Elucidate Flow Physics and Instability Mechanisms
Condensing Flows inside a Channel. Being Submitted for publication in Journal of Computational Physics, 2015.
Naik, R., S. Mitra, and A. Narain, Steady and Unsteady Computational Simulations for Annular Internal Condensing Flows in a Channel, in Proceedings of 2014 ASME International Mechanical Engineering Congress and Exposition. 2014: Montreal, Canada.
Dobson, M.K. and J.C. Chato, Condensation in smooth horizontal tubes. Journal of Heat Transfer-Transactions of the Asme, 1998. 120(1): p. 193-213.
Shah, M.M., A General Correlation for Heat Transfer during Film Condensation inside Pipes. International Journal of Heat and Mass Transfer, 1979. 22: p. 547- 556.
Wang, W.W., Condensation and single-phase heat transfer coefficient and flow regime visualization in micro-channel tubes for HFC-134a. 1999, Ohio State University: Ohio.
Narain, A., et al., Direct computational simulations for internal
attainability/stability of steady solutions, their intrinsic flows
waviness, and their noise sensitivity. Journal of Applied Mechanics, 2004. 71(1): p. 69-88.
Liang, Q., X. Wang, and A. Narain, Effects of gravity, shear and surface tension in internal condensing flows: Results from direct computational simulations. Journal of Heat Transfer, 2004. 126(5): p. 676-686.
Okiishi, T.H., et al., Fundamentals of fluid mechanics. 2013, Hoboken, NJ: John Wiley & Sons, Inc.
MATLAB Documentation, Mathworks.
Bergman, T.L., et al., Fundamentals of heat and mass transfer. 7th ed. 2011, Hoboken, NJ: Wiley. xxiii, 1048 p.
Lockhart, R.W. and R.C. Martinelli, Proposed correlation of data for isothermal two-phase, two- component flow in pipes. Chemical Engineering Progress, 1949. 45: p. 39-48. Friedel,
correlations for horizontal and vertical two-phase pipe flow. in European Two-phase Group Meeting. 1979. Ispra, Italy.
Internal 18. 19. 20. 21. 22. condensing and results on 23. 24. 25. 26. 27. 28. L. Improved friction pressure drop

Fundamental assessments and new enabling proposals for heat transfer correlations and flow regime maps for shear driven condensers in the annular/stratified regime

Year 2015, Volume: 1 Issue: 4, 307 - 321, 01.04.2015

A. Narain R.r. Naik S. Ravikumar S. S. Bhasme

https://doi.org/10.18186/jte.47856

Cited By: 6

Abstract

Keywords

References

-
Lasance, C.J.M. and R.E. Simons Advances In High- Performance Cooling for Electronics. Electronics Cooling, 2005. 11. 2.
Wilson, J.R. Electronics Cooling Depends on Innovative Approaches to Thermal Management. Military & Aerospace Electronics, 2009. 3.
Kivisalu, M.T., P. Gorgitrattanagul, and A. Narain, Results for high heat-flux flow realizations in innovative operations of milli-meter scale condensers and boilers. International Journal of Heat and Mass Transfer, 2014. 75(0): p. 381-398. 4.
Kivisalu, M.T., et al., Sensitivity of shear-driven internal condensing flows to pressure fluctuations and its utilization for heat flux enhancements. International Journal of Heat and Mass Transfer, 2013. 56(1-2): p. 758-774. 5.
Kivisalu, M.T., Experimental Investigation of Certain Internal Condensing Flows, Their Sensitivity to Pressure
Enhancements, in Mechanical Engineering. 2015, Michigan Technological University.
Carey, V.P., Liquid-vapor phase-change phenomena : an introduction to the thermophysics of vaporization and condensation processes in heat transfer equipment. 2nd ed. 2008, New York: Taylor and Francis. xxii, 742 p.
Mitra, S., et al., A quasi one-dimensional method and results for steady annular/stratified shear and gravity driven condensing flows. International Journal of Heat and Mass Transfer, 2011. 54(15-16): p. 3761-3776.
Taitel, Y. and A.E. Dukler, A model for predicting flow regime transitions in horizontal and near horizontal gas-liquid flow. AIChE Journal, 1976. 22(1): p. 47-55. Baker, O., Simaltaneous flow of Oil and Gas. Oil and Gas Journal, 1954. 53: p. 185-215.
Coleman, J.W. and S. Garimella, Two-phase flow regimes in round, square and rectangular tubes during condensation of refrigerant R134a. International Journal of Refrigeration-Revue Internationale Du Froid, 2003. 26(1): p. 117-128.
El Hajal, J., J.R. Thome, and A. Cavallini, Condensation in horizontal tubes, part 1: two-phase flow pattern map. International Journal of Heat and Mass Transfer, 2003. 46(18): p. 3349-3363.
Kim, S.-M. and I. Mudawar, Review of databases and predictive methods for heat transfer in condensing and boiling mini/micro-channel flows. International Journal of Heat and Mass Transfer, 2014. 77(0): p. 627-652.
Kim, S.-M. and I. Mudawar, Universal approach to predicting two-phase frictional pressure drop for adiabatic and condensing mini/micro-channel flows. International Journal of Heat and Mass Transfer, 2012. 55(11–12): p. 3246-3261.
Tibiriçá, C.B., G. Ribatski, and J.R. Thome, Saturated flow boiling heat transfer and critical heat flux in small horizontal flattened tubes. International Journal of Heat and Mass Transfer, 2012. 55(25–26): p. 7873-7883. 15.
Ravikumar, S., Fundamental Assesments and New Enabling Proposals for Heat Transfer Correlations and Flow Regime Maps for Shear Driven Condensers in the Annular/Stratified Regime, in Mechanical Engineering. 2015, Michigan Technolgocial University: Houghton, Michigan USA.
Naik, R., Development of unsteady two-dimensional computational simulation tools that simulate annular internal condensing flows and characterize interfacial waves, flow stability and flow sensitivity, in Mechanical Engineering - Engineering Mechanics 2015, Michigan Technological University: Houghton, MI.
Naik, R., S. Mitra, and A. Narain, Steady and Unsteady Simulations that Elucidate Flow Physics and Instability Mechanisms
Condensing Flows inside a Channel. Being Submitted for publication in Journal of Computational Physics, 2015.
Naik, R., S. Mitra, and A. Narain, Steady and Unsteady Computational Simulations for Annular Internal Condensing Flows in a Channel, in Proceedings of 2014 ASME International Mechanical Engineering Congress and Exposition. 2014: Montreal, Canada.
Dobson, M.K. and J.C. Chato, Condensation in smooth horizontal tubes. Journal of Heat Transfer-Transactions of the Asme, 1998. 120(1): p. 193-213.
Shah, M.M., A General Correlation for Heat Transfer during Film Condensation inside Pipes. International Journal of Heat and Mass Transfer, 1979. 22: p. 547- 556.
Wang, W.W., Condensation and single-phase heat transfer coefficient and flow regime visualization in micro-channel tubes for HFC-134a. 1999, Ohio State University: Ohio.
Narain, A., et al., Direct computational simulations for internal
attainability/stability of steady solutions, their intrinsic flows
waviness, and their noise sensitivity. Journal of Applied Mechanics, 2004. 71(1): p. 69-88.
Liang, Q., X. Wang, and A. Narain, Effects of gravity, shear and surface tension in internal condensing flows: Results from direct computational simulations. Journal of Heat Transfer, 2004. 126(5): p. 676-686.
Okiishi, T.H., et al., Fundamentals of fluid mechanics. 2013, Hoboken, NJ: John Wiley & Sons, Inc.
MATLAB Documentation, Mathworks.
Bergman, T.L., et al., Fundamentals of heat and mass transfer. 7th ed. 2011, Hoboken, NJ: Wiley. xxiii, 1048 p.
Lockhart, R.W. and R.C. Martinelli, Proposed correlation of data for isothermal two-phase, two- component flow in pipes. Chemical Engineering Progress, 1949. 45: p. 39-48. Friedel,
correlations for horizontal and vertical two-phase pipe flow. in European Two-phase Group Meeting. 1979. Ispra, Italy.
Internal 18. 19. 20. 21. 22. condensing and results on 23. 24. 25. 26. 27. 28. L. Improved friction pressure drop

There are 33 citations in total.

Details

Primary Language	English
Journal Section	Articles
Authors	A. Narain This is me R.r. Naik This is me S. Ravikumar This is me S. S. Bhasme This is me
Publication Date	April 1, 2015
Submission Date	May 14, 2015
Published in Issue	Year 2015 Volume: 1 Issue: 4

Cite

APA	Narain, A., Naik, R., Ravikumar, S., Bhasme, S. S. (2015). Fundamental assessments and new enabling proposals for heat transfer correlations and flow regime maps for shear driven condensers in the annular/stratified regime. Journal of Thermal Engineering, 1(4), 307-321. https://doi.org/10.18186/jte.47856
AMA	Narain A, Naik R, Ravikumar S, Bhasme SS. Fundamental assessments and new enabling proposals for heat transfer correlations and flow regime maps for shear driven condensers in the annular/stratified regime. Journal of Thermal Engineering. April 2015;1(4):307-321. doi:10.18186/jte.47856
Chicago	Narain, A., R.r. Naik, S. Ravikumar, and S. S. Bhasme. “Fundamental Assessments and New Enabling Proposals for Heat Transfer Correlations and Flow Regime Maps for Shear Driven Condensers in the annular/Stratified Regime”. Journal of Thermal Engineering 1, no. 4 (April 2015): 307-21. https://doi.org/10.18186/jte.47856.
EndNote	Narain A, Naik R, Ravikumar S, Bhasme SS (April 1, 2015) Fundamental assessments and new enabling proposals for heat transfer correlations and flow regime maps for shear driven condensers in the annular/stratified regime. Journal of Thermal Engineering 1 4 307–321.
IEEE	A. Narain, R. Naik, S. Ravikumar, and S. S. Bhasme, “Fundamental assessments and new enabling proposals for heat transfer correlations and flow regime maps for shear driven condensers in the annular/stratified regime”, Journal of Thermal Engineering, vol. 1, no. 4, pp. 307–321, 2015, doi: 10.18186/jte.47856.
ISNAD	Narain, A. et al. “Fundamental Assessments and New Enabling Proposals for Heat Transfer Correlations and Flow Regime Maps for Shear Driven Condensers in the annular/Stratified Regime”. Journal of Thermal Engineering 1/4 (April 2015), 307-321. https://doi.org/10.18186/jte.47856.
JAMA	Narain A, Naik R, Ravikumar S, Bhasme SS. Fundamental assessments and new enabling proposals for heat transfer correlations and flow regime maps for shear driven condensers in the annular/stratified regime. Journal of Thermal Engineering. 2015;1:307–321.
MLA	Narain, A. et al. “Fundamental Assessments and New Enabling Proposals for Heat Transfer Correlations and Flow Regime Maps for Shear Driven Condensers in the annular/Stratified Regime”. Journal of Thermal Engineering, vol. 1, no. 4, 2015, pp. 307-21, doi:10.18186/jte.47856.
Vancouver	Narain A, Naik R, Ravikumar S, Bhasme SS. Fundamental assessments and new enabling proposals for heat transfer correlations and flow regime maps for shear driven condensers in the annular/stratified regime. Journal of Thermal Engineering. 2015;1(4):307-21.