The present work reports on flow boiling visualization of refrigerant R-134a in a vertical circular channel with an internal diameter of 1.33 mm and 235 mm in heated length. A quartz tube with a homogeneous Indium Tin Oxide coating is used to allow heating and simultaneous visualization. Flow patterns have been observed along the heated length with the aid of high-speed complementary metal oxide semiconductor (CMOS) digital camera. From the flow boiling visualization, seven distinct two-phase flow patterns have been observed: isolated bubbly flow, confined bubbly flow, slug flow, churn flow, slug-annular flow, annular flow, and mist flow. Two-phase flow pattern observations are presented in the form of flow pattern maps. The effects of the saturation temperature and the inlet subcooling degree on the two-phase flow pattern transitions are elucidated. Finally, the experimental flow pattern map is compared with models developed for conventional sizes as well as to a microscale map for air-water mixtures available in literature, showing a large discrepancy.
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e-mail: claudi@energy.kth.se
e-mail: bpalm@energy.kth.se
e-mail: wahib@energy.kth.se
e-mail: rashid.ali@energy.kth.se
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Flow Boiling Visualization of R-134a in a Vertical Channel of Small Diameter
Claudi Martín-Callizo,
Claudi Martín-Callizo
Applied Thermodynamics and Refrigeration,
e-mail: claudi@energy.kth.se
Royal Institute of Technology, KTH
, SE100-44 Stockholm, Sweden
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Björn Palm,
Björn Palm
Applied Thermodynamics and Refrigeration,
e-mail: bpalm@energy.kth.se
Royal Institute of Technology, KTH
, SE100-44 Stockholm, Sweden
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Wahib Owhaib,
Wahib Owhaib
Applied Thermodynamics and Refrigeration,
e-mail: wahib@energy.kth.se
Royal Institute of Technology, KTH
, SE100-44 Stockholm, Sweden
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Rashid Ali
Rashid Ali
Applied Thermodynamics and Refrigeration,
e-mail: rashid.ali@energy.kth.se
Royal Institute of Technology, KTH
, SE100-44 Stockholm, Sweden
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Claudi Martín-Callizo
Applied Thermodynamics and Refrigeration,
Royal Institute of Technology, KTH
, SE100-44 Stockholm, Swedene-mail: claudi@energy.kth.se
Björn Palm
Applied Thermodynamics and Refrigeration,
Royal Institute of Technology, KTH
, SE100-44 Stockholm, Swedene-mail: bpalm@energy.kth.se
Wahib Owhaib
Applied Thermodynamics and Refrigeration,
Royal Institute of Technology, KTH
, SE100-44 Stockholm, Swedene-mail: wahib@energy.kth.se
Rashid Ali
Applied Thermodynamics and Refrigeration,
Royal Institute of Technology, KTH
, SE100-44 Stockholm, Swedene-mail: rashid.ali@energy.kth.se
J. Heat Transfer. Mar 2010, 132(3): 031503 (8 pages)
Published Online: January 7, 2010
Article history
Received:
February 13, 2008
Revised:
September 1, 2008
Published:
January 7, 2010
Citation
Martín-Callizo, C., Palm, B., Owhaib, W., and Ali, R. (January 7, 2010). "Flow Boiling Visualization of R-134a in a Vertical Channel of Small Diameter." ASME. J. Heat Transfer. March 2010; 132(3): 031503. https://doi.org/10.1115/1.4000012
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