Research Article
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Year 2021, Volume: 5 Issue: 3, 475 - 483, 15.12.2021
https://doi.org/10.35860/iarej.992871

Abstract

References

  • 1. Roadmap, IN, International Technology Roadmap for Semiconductors, 2006 Semiconductor Industry Association, 2009, http://www.itrs.net/ Last visited on August 30, 2015.
  • 2. Krishnan, S., S. Garimella, G. Chrysler, and R. Mavajan, Towards a thermal Moore's law, IEEE Transactions on Advanced Packaging, 2007. 30(3): p. 462-474.
  • 3. Price, D. C., A review of selected thermal management solutions for military electronic systems, IEEE Transactions on Components and Packaging Technologies, 2003. 26(1): p. 26-39.
  • 4. Çengel, Y. A., and A. J. Ghajar, Heat and mass transfer: fundamentals and applications. 2014, McGraw-Hill Education.
  • 5. Jafari, R., T. Okutucu-Özyurt, H. Ünver, and Ö. Bayer, Experimental investigation of surface roughness effects on the flow boiling of R134a in microchannels, Experimental Thermal and Fluid Science, 2016. 79: p. 222-230.
  • 6. Lee, J., and I. Mudawar, Two-phase flow in high-heat-flux micro channel heat sink for refrigeration cooling applications Part II—Heat transfer characteristics, International Journal of Heat and Mass Transfer, 2005. 48(5): p. 941–955.
  • 7. Kim, S.M., and I. Mudawar, Universal approach to predicting saturated flow boiling heat transfer in mini/micro-channels – Part II. Two-phase heat transfer coefficient, International Journal of Heat and Mass Transfer, 2013. 64: p. 1239–1256.
  • 8. Zhou, S., X. Xu, B.G., and Sammakia, Modeling of boiling flow in microchannels for nucleation characteristics and performance optimization, International Journal of Heat and Mass Transfer, 2013. 64: p. 706–718.
  • 9. Akhlaghi Amiri, H.A., and A.A. Hamouda, Evaluation of level set and phase-field methods in modeling two phase flow with viscosity contrast through dual-permeability porous medium, International Journal of Multiphase Flow, 2013. 52: p. 22–34.
  • 10. Zu, Y.Q., Y.Y. Yan, S. Gedupudi, T.G. Karayiannis, and D.B.R., Kenning, Confined bubble growth during flow boiling in mini-micro-channel of rectangular cross-section part II: approximate 3-D numerical simulation, International Journal of Thermal Sciences, 2011. 50(3): p. 267-273.
  • 11. Jafari, R., and T. Okutucu-Özyurt, Phase-field modeling of vapor bubble growth in a microchannel, Journal of Computational Multiphase Flows, 2015. 7(3): p. 143–158.
  • 12. Jafari, R., and T. Okutucu-Özyurt, Numerical simulation of flow boiling from an artificial cavity in a microchannel, International Journal of Heat and Mass Transfer, 2016. 97: p. 270–278.
  • 13. Jafari, R., and T. Okutucu-Özyurt, 3D numerical modeling of boiling in a microchannel by arbitrary Lagrangian–Eulerian (ALE) method, Applied Mathematics and Computation, 2016. 272: p. 596–603.
  • 14. Gong, S., and P. Cheng, Numerical investigation of saturated flow boiling in microchannels by the Lattice Boltzmann method, Numerical Heat Transfer, 2014. 65(7): p. 644–661.
  • 15. Türkakar, G., and T. Okutucu-Özyurt, Dimensional optimization of micro-channel heat sinks with multiple heat sources, International Journal of Thermal Sciences, 2012. 62: p. 85–92.
  • 16. Turkakar, G., T. Okutucu-Ozyurt, and S.G. Kandlikar, Entropy generation analysis of a microchannel-condenser for use in a vapor compression refrigeration cycle, International Journal of Refrigeration, 2017. 70: P. 71–83.
  • 17. Crowe, C., M. Sommerfeld, and Y. Tsuji, Multiphase Flows with Droplets and Particles, 1998. CRC Press.
  • 18. Cooper, M.G, The microlayer and bubble growth in nucleate pool boiling, International Journal of Heat and Mass Transfer, 1969. 12(8): p. 915–933.
  • 19. Fath, H.S., and R.L. Judd, Influence of system pressure on microlayer evaporation heat transfer, ASME Journal of Heat Transfer, 1978. 100(1): p. 49–55.
  • 20. Victor, H., M. Del Valle, and D.B.R. Kenning, Subcooled flow boiling at high heat flux, International Journal of Heat and Mass Transfer, 1985. 28(10): p. 1907–1920.
  • 21. Hsu, Y.Y. and R.W. Graham, Transport Processes in Boiling and Two-phase Systems, 1976. Hemisphere, Washington, DC.
  • 22. Graham, R.W., and R.C. Hendricks, Assessment of convection and evaporation in nucleate boiling, 1967. NASA TN D-3943.
  • 23. Anwar, Z., B. Palm, and R. Khodabandeh, Flow boiling heat transfer and dryout characteristics of R152a in a vertical mini-channel, Experimental Thermal and Fluid Science, 2014. 53: p. 207–217.
  • 24. Bao, Z.Y., D.F. Fletcher, and B.S. Haynes, Flow boiling heat transfer of freon R11 and HCFC123 in narrow passages, International Journal of Heat and Mass Transfer, 2000. 43(18): p. 3347–3358.
  • 25. Qu, W., and I. Mudawar, Flow boiling heat transfer in two phase microchannel heat sinks: I. Experimental investigation and assessment of correlation methods, International Journal of Heat and Mass Transfer, 2003. 46(15): p. 2755–2771.
  • 26. Boye, H., Y. Staate, and J. Schmidt, Experimental investigation and modelling of heat transfer during convective boiling in a minichannel, International Journal of Heat and Mass Transfer, 2007. 50(1): p. 208–215.
  • 27. Lin, S., P.A. Kew, and K. Cornwell, Flow boiling of refrigerant R141b in small tubes, Transactions of the Institution of Chemical Engineers, 2001. 79(A): p. 417–424.
  • 28. McNeil, D.A., A.H. Raeisi, P.A. Kew, and R.S. Hamed, Flow boiling heat-transfer in micro to macro transition flows, International Journal of Heat and Mass Transfer, 2013. 65: p. 289–307.
  • 29. Bowring, R.W., Physical model based on bubble detachment and calculation of steam voidage in the subcooled region of a heated channel, Report HPR-10, Institute for Atomenergies, Halden, Norway, 1962.
  • 30. Lemmert, M.,J., and J.M. Chwala, Influence of flow velocity on surface boiling heat transfer coefficient, in: E. Hahne, U. Grigull (Eds.), Heat Transfer in Boiling, Academic Press and Hemisphere, 1977. New York and Washington, DC.
  • 31. Wang, C.H., and V.K. Dhir, Effect of surface wettability on active nucleation site density during pool boiling of water on a vertical surface, Journal of Heat Transfer, 1993. 115(3): p. 659-669.
  • 32. Benjamin, R.J., and A.R. Balakrishnan, Nucleation site density in pool boilingof saturated pure liquids: effect of surface microroughness and surface and liquid physical properties, Experimental Thermal and Fluid Science, 1997. 15(1): p. 32-42.
  • 33. Yoo, J., C.E. Estrada-Perez, and Y.A. Hassan, A proper observation and characterization of wall nucleation phenomena in a forced convective boiling system, International Journal of Heat and Mass Transfer, 2014. 76: p. 568–584.
  • 34. Plesset, M.S., and S. A. Zwick, The growth of vapour bubble in superheated liquid, Journal of Applied Physics., 1954. 25(4): p. 493–500.
  • 35. Mikic, B.B., and W.M. Rohsenow, A new correlation of pool walking data including the fact of heating surface characteristics, ASME Journal of Heat Transfer, 1969. 91(2): p. 245–250.
  • 36. Lee, J., and I. Mudawar, Two-phase flow in high-heat-flux micro-channel heat sink for refrigeration cooling applications: Part II—heat transfer characteristics, International Journal of Heat and Mass Transfer, 2005. 48(5): p. 941–955.
  • 37. Li, W., and Z. Wu, A general correlation for evaporative heat transfer in micro/minichannels, International Journal of Heat and Mass Transfer, 2010. 53(9-10): p. 1778–1787.
  • 38. Kim, S.M., and I. Mudawar, Universal approach to predicting saturated flow boiling heat transfer in mini/micro-channels – Part II. Two-phase heat transfer coefficient, International Journal of Heat and Mass Transfer, 2013. 64: p. 1239–1256.
  • 39. Agostini, B., J.R. Thome, M. Fabbri, B. Michel, D. Calmi, and U. Kloter, High heat flux flow boiling in silicon multi-microchannels - Part I: Heat transfer characteristics of refrigerant R236fa, International Journal of Heat and Mass Transfer, 2008. 51(21-22): p. 5400-5411.
  • 40. Bertsch, S., E.A. Groll, and S.V. Garimella, Refrigerant flow boiling heat transfer in parallel micro channels as a function of local vapor quality, International Journal of Heat and Mass Transfer, 2008. 51(19-20): p. 4775-4787.
  • 41. Thiangtham, P., C. Keepaiboon, P. Kiatpachai, L.G. Asirvatham, O. Mahian, A.S. Dalkilic, and S. Wongwises, An experimental study on two-phase flow patterns and heat transfer characteristics during boiling of R134a flowing through a multi-microchannel heat sink, International Journal of Heat and Mass Transfer, 2016. 98: p. 390-400.
  • 42. Powell, M.J.D., The BOBYQA algorithm for bound constraint optimization without derivatives, Report DAMTP 2009/NA06, University of Cambridge, UK.
  • 43. Powell, M.D.J., Developments of NEWUOA for minimization without derivatives, IMA Journal of Numerical Analysis, 2008. 28(4): p. 649-664.

Dimensional optimization of two-phase flow boiling in microchannel heat sinks

Year 2021, Volume: 5 Issue: 3, 475 - 483, 15.12.2021
https://doi.org/10.35860/iarej.992871

Abstract

The heat transfer coefficient (HTC) of microchannel heat sinks (MHS) is higher than common heat sinks due to higher area to volume ratio. Its value for two-phase flow boiling is much superior to single-phase flow. In addition, the two-phase flow boiling provides uniform wall temperature close to the coolant’s saturation temperature in low vapor qualities. In the present study, a heat sink is optimized dimensionally after modeling of the boiling of R134a refrigerant in the microchannels. Firstly, mixture two-phase method along with the wall heat flux partitioning are utilized to introduce an applied thermal model to design MHSs. The heat sink mounted on the backside of an Intel core i7-900 desktop processor with dimensions of 19 mm×14.4 mm× 1 mm is numerically simulated to investigate the thermal performance. The HTC and the exit vapor quality are comparable with the available empirical correlations and first law of thermodynamics, respectively. Then the proposed model is developed to optimize the dimensions of the microchannels to design the heat sink with minimized wall temperature. Bound optimization by quadratic approximation (BOBYQA) method results in the optimized dimensions of the microchannels in the heat sink. Optimization of heat sink’s geometry in terms of the dimensions of the microchannels at various boundary conditions will be practical as the unique application of the model.

References

  • 1. Roadmap, IN, International Technology Roadmap for Semiconductors, 2006 Semiconductor Industry Association, 2009, http://www.itrs.net/ Last visited on August 30, 2015.
  • 2. Krishnan, S., S. Garimella, G. Chrysler, and R. Mavajan, Towards a thermal Moore's law, IEEE Transactions on Advanced Packaging, 2007. 30(3): p. 462-474.
  • 3. Price, D. C., A review of selected thermal management solutions for military electronic systems, IEEE Transactions on Components and Packaging Technologies, 2003. 26(1): p. 26-39.
  • 4. Çengel, Y. A., and A. J. Ghajar, Heat and mass transfer: fundamentals and applications. 2014, McGraw-Hill Education.
  • 5. Jafari, R., T. Okutucu-Özyurt, H. Ünver, and Ö. Bayer, Experimental investigation of surface roughness effects on the flow boiling of R134a in microchannels, Experimental Thermal and Fluid Science, 2016. 79: p. 222-230.
  • 6. Lee, J., and I. Mudawar, Two-phase flow in high-heat-flux micro channel heat sink for refrigeration cooling applications Part II—Heat transfer characteristics, International Journal of Heat and Mass Transfer, 2005. 48(5): p. 941–955.
  • 7. Kim, S.M., and I. Mudawar, Universal approach to predicting saturated flow boiling heat transfer in mini/micro-channels – Part II. Two-phase heat transfer coefficient, International Journal of Heat and Mass Transfer, 2013. 64: p. 1239–1256.
  • 8. Zhou, S., X. Xu, B.G., and Sammakia, Modeling of boiling flow in microchannels for nucleation characteristics and performance optimization, International Journal of Heat and Mass Transfer, 2013. 64: p. 706–718.
  • 9. Akhlaghi Amiri, H.A., and A.A. Hamouda, Evaluation of level set and phase-field methods in modeling two phase flow with viscosity contrast through dual-permeability porous medium, International Journal of Multiphase Flow, 2013. 52: p. 22–34.
  • 10. Zu, Y.Q., Y.Y. Yan, S. Gedupudi, T.G. Karayiannis, and D.B.R., Kenning, Confined bubble growth during flow boiling in mini-micro-channel of rectangular cross-section part II: approximate 3-D numerical simulation, International Journal of Thermal Sciences, 2011. 50(3): p. 267-273.
  • 11. Jafari, R., and T. Okutucu-Özyurt, Phase-field modeling of vapor bubble growth in a microchannel, Journal of Computational Multiphase Flows, 2015. 7(3): p. 143–158.
  • 12. Jafari, R., and T. Okutucu-Özyurt, Numerical simulation of flow boiling from an artificial cavity in a microchannel, International Journal of Heat and Mass Transfer, 2016. 97: p. 270–278.
  • 13. Jafari, R., and T. Okutucu-Özyurt, 3D numerical modeling of boiling in a microchannel by arbitrary Lagrangian–Eulerian (ALE) method, Applied Mathematics and Computation, 2016. 272: p. 596–603.
  • 14. Gong, S., and P. Cheng, Numerical investigation of saturated flow boiling in microchannels by the Lattice Boltzmann method, Numerical Heat Transfer, 2014. 65(7): p. 644–661.
  • 15. Türkakar, G., and T. Okutucu-Özyurt, Dimensional optimization of micro-channel heat sinks with multiple heat sources, International Journal of Thermal Sciences, 2012. 62: p. 85–92.
  • 16. Turkakar, G., T. Okutucu-Ozyurt, and S.G. Kandlikar, Entropy generation analysis of a microchannel-condenser for use in a vapor compression refrigeration cycle, International Journal of Refrigeration, 2017. 70: P. 71–83.
  • 17. Crowe, C., M. Sommerfeld, and Y. Tsuji, Multiphase Flows with Droplets and Particles, 1998. CRC Press.
  • 18. Cooper, M.G, The microlayer and bubble growth in nucleate pool boiling, International Journal of Heat and Mass Transfer, 1969. 12(8): p. 915–933.
  • 19. Fath, H.S., and R.L. Judd, Influence of system pressure on microlayer evaporation heat transfer, ASME Journal of Heat Transfer, 1978. 100(1): p. 49–55.
  • 20. Victor, H., M. Del Valle, and D.B.R. Kenning, Subcooled flow boiling at high heat flux, International Journal of Heat and Mass Transfer, 1985. 28(10): p. 1907–1920.
  • 21. Hsu, Y.Y. and R.W. Graham, Transport Processes in Boiling and Two-phase Systems, 1976. Hemisphere, Washington, DC.
  • 22. Graham, R.W., and R.C. Hendricks, Assessment of convection and evaporation in nucleate boiling, 1967. NASA TN D-3943.
  • 23. Anwar, Z., B. Palm, and R. Khodabandeh, Flow boiling heat transfer and dryout characteristics of R152a in a vertical mini-channel, Experimental Thermal and Fluid Science, 2014. 53: p. 207–217.
  • 24. Bao, Z.Y., D.F. Fletcher, and B.S. Haynes, Flow boiling heat transfer of freon R11 and HCFC123 in narrow passages, International Journal of Heat and Mass Transfer, 2000. 43(18): p. 3347–3358.
  • 25. Qu, W., and I. Mudawar, Flow boiling heat transfer in two phase microchannel heat sinks: I. Experimental investigation and assessment of correlation methods, International Journal of Heat and Mass Transfer, 2003. 46(15): p. 2755–2771.
  • 26. Boye, H., Y. Staate, and J. Schmidt, Experimental investigation and modelling of heat transfer during convective boiling in a minichannel, International Journal of Heat and Mass Transfer, 2007. 50(1): p. 208–215.
  • 27. Lin, S., P.A. Kew, and K. Cornwell, Flow boiling of refrigerant R141b in small tubes, Transactions of the Institution of Chemical Engineers, 2001. 79(A): p. 417–424.
  • 28. McNeil, D.A., A.H. Raeisi, P.A. Kew, and R.S. Hamed, Flow boiling heat-transfer in micro to macro transition flows, International Journal of Heat and Mass Transfer, 2013. 65: p. 289–307.
  • 29. Bowring, R.W., Physical model based on bubble detachment and calculation of steam voidage in the subcooled region of a heated channel, Report HPR-10, Institute for Atomenergies, Halden, Norway, 1962.
  • 30. Lemmert, M.,J., and J.M. Chwala, Influence of flow velocity on surface boiling heat transfer coefficient, in: E. Hahne, U. Grigull (Eds.), Heat Transfer in Boiling, Academic Press and Hemisphere, 1977. New York and Washington, DC.
  • 31. Wang, C.H., and V.K. Dhir, Effect of surface wettability on active nucleation site density during pool boiling of water on a vertical surface, Journal of Heat Transfer, 1993. 115(3): p. 659-669.
  • 32. Benjamin, R.J., and A.R. Balakrishnan, Nucleation site density in pool boilingof saturated pure liquids: effect of surface microroughness and surface and liquid physical properties, Experimental Thermal and Fluid Science, 1997. 15(1): p. 32-42.
  • 33. Yoo, J., C.E. Estrada-Perez, and Y.A. Hassan, A proper observation and characterization of wall nucleation phenomena in a forced convective boiling system, International Journal of Heat and Mass Transfer, 2014. 76: p. 568–584.
  • 34. Plesset, M.S., and S. A. Zwick, The growth of vapour bubble in superheated liquid, Journal of Applied Physics., 1954. 25(4): p. 493–500.
  • 35. Mikic, B.B., and W.M. Rohsenow, A new correlation of pool walking data including the fact of heating surface characteristics, ASME Journal of Heat Transfer, 1969. 91(2): p. 245–250.
  • 36. Lee, J., and I. Mudawar, Two-phase flow in high-heat-flux micro-channel heat sink for refrigeration cooling applications: Part II—heat transfer characteristics, International Journal of Heat and Mass Transfer, 2005. 48(5): p. 941–955.
  • 37. Li, W., and Z. Wu, A general correlation for evaporative heat transfer in micro/minichannels, International Journal of Heat and Mass Transfer, 2010. 53(9-10): p. 1778–1787.
  • 38. Kim, S.M., and I. Mudawar, Universal approach to predicting saturated flow boiling heat transfer in mini/micro-channels – Part II. Two-phase heat transfer coefficient, International Journal of Heat and Mass Transfer, 2013. 64: p. 1239–1256.
  • 39. Agostini, B., J.R. Thome, M. Fabbri, B. Michel, D. Calmi, and U. Kloter, High heat flux flow boiling in silicon multi-microchannels - Part I: Heat transfer characteristics of refrigerant R236fa, International Journal of Heat and Mass Transfer, 2008. 51(21-22): p. 5400-5411.
  • 40. Bertsch, S., E.A. Groll, and S.V. Garimella, Refrigerant flow boiling heat transfer in parallel micro channels as a function of local vapor quality, International Journal of Heat and Mass Transfer, 2008. 51(19-20): p. 4775-4787.
  • 41. Thiangtham, P., C. Keepaiboon, P. Kiatpachai, L.G. Asirvatham, O. Mahian, A.S. Dalkilic, and S. Wongwises, An experimental study on two-phase flow patterns and heat transfer characteristics during boiling of R134a flowing through a multi-microchannel heat sink, International Journal of Heat and Mass Transfer, 2016. 98: p. 390-400.
  • 42. Powell, M.J.D., The BOBYQA algorithm for bound constraint optimization without derivatives, Report DAMTP 2009/NA06, University of Cambridge, UK.
  • 43. Powell, M.D.J., Developments of NEWUOA for minimization without derivatives, IMA Journal of Numerical Analysis, 2008. 28(4): p. 649-664.
There are 43 citations in total.

Details

Primary Language English
Subjects Mechanical Engineering
Journal Section Research Articles
Authors

Rahım Jafarı 0000-0003-1155-3711

Publication Date December 15, 2021
Submission Date September 8, 2021
Acceptance Date December 10, 2021
Published in Issue Year 2021 Volume: 5 Issue: 3

Cite

APA Jafarı, R. (2021). Dimensional optimization of two-phase flow boiling in microchannel heat sinks. International Advanced Researches and Engineering Journal, 5(3), 475-483. https://doi.org/10.35860/iarej.992871
AMA Jafarı R. Dimensional optimization of two-phase flow boiling in microchannel heat sinks. Int. Adv. Res. Eng. J. December 2021;5(3):475-483. doi:10.35860/iarej.992871
Chicago Jafarı, Rahım. “Dimensional Optimization of Two-Phase Flow Boiling in Microchannel Heat Sinks”. International Advanced Researches and Engineering Journal 5, no. 3 (December 2021): 475-83. https://doi.org/10.35860/iarej.992871.
EndNote Jafarı R (December 1, 2021) Dimensional optimization of two-phase flow boiling in microchannel heat sinks. International Advanced Researches and Engineering Journal 5 3 475–483.
IEEE R. Jafarı, “Dimensional optimization of two-phase flow boiling in microchannel heat sinks”, Int. Adv. Res. Eng. J., vol. 5, no. 3, pp. 475–483, 2021, doi: 10.35860/iarej.992871.
ISNAD Jafarı, Rahım. “Dimensional Optimization of Two-Phase Flow Boiling in Microchannel Heat Sinks”. International Advanced Researches and Engineering Journal 5/3 (December 2021), 475-483. https://doi.org/10.35860/iarej.992871.
JAMA Jafarı R. Dimensional optimization of two-phase flow boiling in microchannel heat sinks. Int. Adv. Res. Eng. J. 2021;5:475–483.
MLA Jafarı, Rahım. “Dimensional Optimization of Two-Phase Flow Boiling in Microchannel Heat Sinks”. International Advanced Researches and Engineering Journal, vol. 5, no. 3, 2021, pp. 475-83, doi:10.35860/iarej.992871.
Vancouver Jafarı R. Dimensional optimization of two-phase flow boiling in microchannel heat sinks. Int. Adv. Res. Eng. J. 2021;5(3):475-83.



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