The high power density of emerging electronic devices is driving the transition from remote cooling, which relies on conduction and spreading, to embedded cooling, which extracts dissipated heat on-site. Two-phase microgap coolers employ the forced flow of dielectric fluids undergoing phase change in a heated channel within or between devices. Such coolers must work reliably in all orientations for a variety of applications (e.g., vehicle-based equipment), as well as in microgravity and high-g for aerospace applications, but the lack of acceptable models and correlations for orientation- and gravity-independent operation has limited their use. Reliable criteria for achieving orientation- and gravity-independent flow boiling would enable emerging systems to exploit this thermal management technique and streamline the technology development process. As a first step toward understanding the effect of gravity in two-phase microgap flow and transport, in the present effort the authors have studied the effect of evaporator orientation, mass flux, and heat flux on flow boiling of HFE7100 in a 1.01 mm tall × 13.0 mm wide × 12.7 mm long microgap channel. Orientation-independence, defined as achieving similar critical heat fluxes (CHFs), heat transfer coefficients (HTCs), and flow regimes across orientations, was achieved for mass fluxes of 400 kg/m2 s and greater (corresponding to a Froude number of about 0.8). The present results are compared to published criteria for achieving orientation- and gravity-independence.
Issue Section:
Research Papers
References
1.
Bar-Cohen
, A.
, Robinson
, F. L.
, and Deisenroth
, D. C.
, 2018
, “Challenges and Opportunities in Gen3 Embedded Cooling With High-Quality Microgap Flow
,” International Conference on Electronics Packaging and iMAPS All Asia Conference
, Mie, Japan, Apr. 17–21.2.
Nakayama
, W.
, 2017
, “Evolution of Hardware Morphology of Large-Scale Computers and the Trend of Space Allocation for Thermal Management
,” ASME J. Electron. Packag.
, 139
(1
), p. 010801
.3.
Brunschwiler
, T.
, Sridhar
, A.
, Ong
, C. L.
, and Schlottig
, G.
, 2016
, “Benchmarking Study of the Thermal Management Landscape for Three-Dimensional Integrated Circuits: From Back-Side to Volumetric Heat Removal
,” ASME J. Electron. Packag.
, 138
(1
), p. 010911
.4.
Bar-Cohen
, A.
, 2014
, “Towards Embedded Cooling—Gen 3 Thermal Packaging Technology
,” Encyclopedia of Thermal Packaging
, World Scientific Publishing Company
, Hackensack, NJ
, pp. 367
–398
.5.
Bar-Cohen
, A.
, 2013
, “Gen-3 Thermal Management Technology: Role of Microchannels and Nanostructures in an Embedded Cooling Paradigm
,” ASME J. Nanotech. Eng. Med.
, 4
(2
), p. 020907
.6.
Swanson
, T.
, and Motil
, B.
, 2015
, “NASA Technology Roadmaps TA 14: Thermal Management Systems
,” National Aeronautics and Space Administration, Washington, DC, accessed Jan. 21, 2019, www.nasa.gov/sites/default/files/atoms/files/2015_nasa_technology_roadmaps_ta_14_thermal_management_final.pdf7.
Sunada
, E.
, Furst
, B.
, Bhandari
, P.
, Carroll
, B.
, Birur
, G. C.
, Nagai
, H.
, Daimaru
, T.
, Sakamoto
, K.
, Cappucci
, S.
, and Mizerak
, J.
, 2016
, “A Two-Phase Mechanically Pumped Fluid Loop for Thermal Control of Deep Space Science Missions
,” 46th International Conference on Environmental Systems
, Vienna, Austria, July 10–14, Paper No. ICES-2016-129.https://ttu-ir.tdl.org/handle/2346/675458.
Bar-Cohen
, A.
, Sheehan
, J. R.
, and Rahim
, E.
, 2012
, “Two-Phase Thermal Transport in Microgap Channels—Theory, Experimental Results, and Predictive Relations
,” Microgravity Sci. Technol.
, 24
(1
), pp. 1
–15
.9.
Bar-Cohen
, A.
, and Rahim
, E.
, 2009
, “Modeling and Prediction of Two-Phase Microgap Channel Heat Transfer Characteristics
,” Heat Transfer Eng.
, 30
(8
), pp. 601
–625
.10.
Alam
, T.
, Lee
, P. S.
, and Jin
, L.-W.
, 2014
, Flow Boiling in Microgap Channels: Experiment, Visualization, and Analysis
, Springer Science & Business Media
, New York
.11.
Taitel
, Y.
, 1990
, “Flow Pattern Transition in Two-Phase Flow
,” Ninth International Heat Transfer Conference
, Jerusalem, Israel, Aug. 19–24, pp. 237–254.12.
Kandlikar
, S. G.
, 2010
, “Scale Effects on Flow Boiling Heat Transfer in Microchannels: A Fundamental Perspective
,” Int. J. Therm. Sci.
, 49
(7
), pp. 1073
–1085
.13.
Robinson
, F.
, and Bar-Cohen
, A.
, 2017
, “Gravity Effects in Microgap Flow Boiling
,” 16th IEEE Intersociety Conference on Thermal and Thermomechanical Phenomena Electronic Systems
(ITherm
), Orlando, FL, May 30 to June 2, pp. 480–491.14.
Ullmann
, A.
, and Brauner
, N.
, 2007
, “The Prediction of Flow Pattern Maps in Minichannels
,” Multiphase Sci. Technol.
, 19
(1
), pp. 49
–73
.15.
Baldassari
, C.
, and Marengo
, M.
, 2013
, “Flow Boiling in Microchannels in Microgravity
,” Prog. Energy Combust. Sci.
, 39
(1
), pp. 1
–36
.16.
Zhang
, H.
, Mudawar
, I.
, and Hasan
, M. M.
, 2009
, “Application of Flow Boiling for Thermal Management of Electronics in Microgravity and Reduced-Gravity Space Systems
,” IEEE Trans. Compon. Packag. Tech.
, 32
(2
), pp. 466
–477
.17.
Konishi
, C.
, Mudawar
, I.
, and Hasan
, M. M.
, 2013
, “Investigation of the Influence of Orientation on Critical Heat Flux for Flow Boiling With Two-Phase Inlet
,” Int. J. Heat Mass Trans.
, 61
, pp. 176
–190
.18.
Kharangate
, C. R.
, Konishi
, C.
, and Mudawar
, I.
, 2016
, “Consolidated Methodology to Predicting Flow Boiling Critical Heat Flux for Inclined Channels in Earth Gravity and for Microgravity
,” Int. J. Heat Mass Transfer
, 92
, pp. 467
–482
.19.
Wang
, C.-C.
, Chang
, W.-J.
, Dai
, C.-H.
, Lin
, Y.-T.
, and Yang
, K.-S.
, 2012
, “Effect of Inclination on the Convective Boiling Performance of a Microchannel Heat Sink Using HFE-7100
,” Exp. Therm. Fluid Sci.
, 36
, pp. 143
–148
.20.
Lee
, H.
, Park
, I.
, Mudawar
, I.
, and Hasan
, M. M.
, 2014
, “Micro-Channel Evaporator for Space Applications—1: Experimental Pressure Drop and Heat Transfer Results for Different Orientations in Earth Gravity
,” Int. J. Heat Mass Transfer
, 77
, pp. 1213
–1230
.21.
Lee
, H.
, Park
, I.
, Mudawar
, I.
, and Hasan
, M. M.
, 2014
, “Micro-Channel Evaporator for Space Applications—2: Assessment of Predictive Tools
,” Int. J. Heat Mass Transfer
, 77
, pp. 1231
–1249
.22.
Zhang
, H. Y.
, Pinjala
, D.
, and Wong
, T. N.
, 2005
, “Experimental Characterization of Flow Boiling Heat Dissipation in a Microchannel Heat Sink With Different Orientations
,” Seventh Electronic Packaging Technology Conference
, Singapore, Dec. 7–9, pp. 670–676.23.
Leão
, H.
, Chávez
, C. A.
, do Nascimento
, F. J.
, and Ribatski
, G.
, 2015
, “An Analysis of the Effect of the Footprint Orientation on the Thermal-Hydraulic Performance of a Microchannels Heat Sink During Flow Boiling of R245fa
,” Appl. Therm. Eng.
, 90
, pp. 907
–926
.24.
Kandlikar
, S. G.
, and Balasubramanian
, P.
, 2005
, “An Experimental Study on the Effect of Gravitation Orientation on Flow Boiling of Water in 1054 × 197 μm Parallel Minichannels
,” ASME J. Heat Trans.
, 127
(8
), pp. 820
–829
.25.
Kandlikar
, S. G.
, 2012
, “History, Advances, and Challenges in Liquid Flow and Flow Boiling Heat Transfer in Microchannels: A Critical Review
,” ASME J. Heat Trans.
, 134
(3
), p. 034001
.26.
Karayiannis
, T. G.
, and Mahmoud
, M. M.
, 2017
, “Flow Boiling in Microchannels: Fundamentals and Applications
,” Appl. Therm. Eng.
, 115
, pp. 1372
–1397
.27.
Cheng
, L.
, and Xia
, G.
, 2017
, “Fundamental Issues, Mechanisms, and Models of Flow Boiling Heat Transfer in Microscale Channels
,” Int. J. Heat Mass Trans.
, 108
, pp. 97
–127
.28.
Ohta
, H.
, Baba
, A.
, and Gabriel
, K.
, 2002
, “Review of Existing Research on Microgravity Boiling and Two-Phase Flow: Future Experiments on the International Space Station
,” Ann. New York Acad. Sci.
, 974
(1
), pp. 410
–427
.29.
Celata
, G. P.
, 2007
, “Flow Boiling Heat Transfer in Microgravity: Recent Results
,” Microgravity Sci. Technol.
, 19
(3–4
), pp. 13
–17
.30.
Konishi
, C.
, and Mudawar
, I.
, 2015
, “Review of Flow Boiling and Critical Heat Flux in Microgravity
,” Int. J. Heat Mass Transfer
, 80
, pp. 469
–493
.31.
Reynolds
, W. C.
, Saad
, M. A.
, and Satterlee
, H.
, 1964
, “Capillary Hydrostatics and Hydrodynamics at Low g
,” Stanford University, Stanford, CA, Report No. LG-3.32.
Baba
, S.
, Ohtani
, N.
, Kawanami
, O.
, Inoue
, K.
, and Ohta
, H.
, 2012
, “Experiments on Dominant Force Regimes in Flow Boiling Using Mini-Tubes
,” Front. Heat Mass Transfer
, 3
(4
), pp. 1
–8
.33.
Rausch
, M.
, Kretschmer
, L.
, Stefan
, W.
, Leipertz
, A.
, and Fröba
, A. P.
, 2015
, “Density, Surface Tension, and Kinematic Viscosity of Hydrofluroethers HFE-7000, HFE-7100, HFE-7200, HFE-7300, and HFE-7500
,” J. Chem. Eng. Data
, 60
(12
), pp. 3759
–3765
.34.
Qi
, H.
, Fang
, D.
, Meng
, X.
, and Wu
, J.
, 2014
, “Liquid Density of HFE-7000 and HFE-7100 From T = (283 to 363) K at Pressures Up to 100 MPa
,” J. Chem. Thermodyn.
, 77
, pp. 131
–136
.35.
Zheng
, Y.
, Wei
, Z.
, and Song
, X.
, 2016
, “Measurements of Isobaric Heat Capacities for HFE-7000 and HFE-7100 at Different Temperatures and Pressures
,” Fluid Phase Equilibria
, 425
, pp. 335
–341
.36.
Klein
, S. A.
, 2018
, “Engineering Equation Solver: F-Chart Software Version 10.467
,” F-Chart Software Company, Madison, WI.37.
Martin
, J. J.
, and Hou
, Y.-C.
, 1955
, “Development of an Equation of State for Gases
,” AlChE J.
, 1
(2
), pp. 142
–151
.38.
An
, B.
, Duan
, Y.
, Tan
, L.
, and Yang
, Z.
, 2015
, “Vapor Pressure of HFE 7100
,” J. Chem. Eng. Data
, 60
(4
), pp. 1206
–1210
.39.
Sawada
, K.
, Kurimoto
, T.
, Okamoto
, A.
, Matsumoto
, S.
, Asano
, H.
, Kawanami
, O.
, Suzuki
, K.
, and Ohta
, H.
, 2014
, “Investigation of Dissolved Air Effects on Subcooled Flow Boiling Heat Transfer for Boiling Two-Phase Flow Experiment Onboard the ISS
,” 44th International Conference on Environmental Systems
, Tucson, AZ, July 13–17, Paper No. ICES-2014-228
.https://ttu-ir.tdl.org/handle/2346/5958140.
Chen
, T.
, and Garimella
, S. V.
, 2006
, “Effects of Dissolved Air on Subcooled Flow Boiling of a Dielectric Coolant in a Microchannel Heat Sink
,” ASME J. Electron. Packag.
, 128
(4
), pp. 398
–404
.41.
Müller-Steinhagen
, H.
, Epstein
, N.
, and Watkinson
, A.
, 1988
, “Effect of Dissolved Gases on Subcooled Flow Boiling Heat Transfer
,” Chem. Eng. Process.: Process Intensification
, 23
(2
), pp. 115
–124
.42.
Rottländer
, H.
, Umrath
, W.
, and Voss
, G.
, 2016
, “Fundamentals of Leak Detection: Cat. No. 199 79_VA.02
,” Leybold GmbH, Cologne, Germany, accessed Apr. 5, 2019, www.leyboldproducts.com/media/pdf/90/c7/87/Fundamentals_of_Leak_Detection_EN.pdfCopyright © 2019 by ASME
You do not currently have access to this content.
