Detection of liquid–vapor–solid triple contact line in two-phase heat transfer phenomena using high-speed infrared thermometry

Abstract Heat transfer in complex physical situations such as nucleate boiling, quenching and dropwise condensation is strongly affected by the presence of a liquid–vapor–solid triple contact line, where intense energy transfer and phase change occur. A novel experimental technique for the detection of the liquid–vapor–solid line in these situations is presented. The technique is based on high-speed infrared (IR) thermometry through an IR-transparent silicon wafer heater; hence the name DEPIcT, or DEtection of Phase by Infrared Thermometry. Where the heater surface is wet, the IR camera measures the temperature of the hot water in contact with the heater. On the other hand, where vapor (whose IR absorptivity is very low) is in contact with the heater, the IR light comes from the cooler water beyond the vapor. The resulting IR image appears dark (cold) in dry spots and bright (hot) in wetted area. Using the contrast between the dark and bright areas, we can visualize the distribution of the liquid and gas phases in contact with the heater surface, and thus identify the liquid–vapor–solid contact line. In other words, we measure temperature beyond the surface to detect phases on the surface. It was shown that even small temperature differences (∼1 °C) can yield a sharp identification of the contact line, within about 100 μm resolution. DEPIcT was also shown to be able to detect thin liquid layers, through the analysis of interference patterns.

[1]  H. Prasser,et al.  A new electrode-mesh tomograph for gas–liquid flows , 1998 .

[2]  D. Dumin Measurement of Film Thickness Using Infrared Interference , 1967 .

[3]  T. Theofanous,et al.  The boiling crisis phenomenon. Part I: nucleation and nucleate boiling heat transfer , 2002 .

[4]  Hee Cheon No,et al.  Simultaneous visualization of dry spots and bubbles for pool boiling of R-113 on a horizontal heater , 2003 .

[5]  Mamoru Ishii,et al.  Development of the Miniaturized Four-sensor Conductivity Probe and the Signal Processing Scheme , 2000 .

[6]  J. Rose Dropwise condensation theory and experiment: A review , 2002 .

[7]  N. Rivière,et al.  Single and double optical probes in air-water two-phase flows: real time signal processing and sensor performance , 1999 .

[8]  T. Theofanous,et al.  High heat flux boiling and burnout as microphysical phenomena : Mounting evidence and opportunities , 2006 .

[9]  U. Hampel,et al.  Experimental two-phase flow measurement using ultra fast limited-angle-type electron beam X-ray computed tomography , 2009 .

[10]  Lei Zhang,et al.  Nucleation site interaction in pool boiling on the artificial surface , 2003 .

[11]  H. Fath,et al.  Influence of System Pressure on Microlayer Evaporation Heat Transfer , 1978 .

[12]  R. Judd,et al.  A Comprehensive Model for Nucleate Pool Boiling Heat Transfer Including Microlayer Evaporation , 1976 .

[13]  M. Cooper,et al.  The microlayer in nucleate pool boiling , 1969 .

[14]  Jungho Kim Review of nucleate pool boiling bubble heat transfer mechanisms , 2009 .

[15]  Jacopo Buongiorno,et al.  Study of bubble growth in water pool boiling through synchronized, infrared thermometry and high-speed video , 2010 .

[16]  Manolis Gavaises,et al.  Numerical investigation on the evaporation of droplets depositing on heated surfaces at low Weber numbers , 2008 .

[17]  M. Querry,et al.  Wedge shaped cell for highly absorbent liquids: infrared optical constants of water. , 1989, Applied optics.

[18]  P. Stephan,et al.  High-Resolution Measurements at Nucleate Boiling of Pure FC-84 and FC-3284 and Its Binary Mixtures , 2009 .

[19]  Development of an ultrafast X-ray computed tomography scanner system : Application for measurement of instantaneous void distribution of gas-liquid two-phase flow , 2000 .

[20]  Shigefumi Nishio,et al.  Visualization of boiling structures in high heat–flux pool-boiling , 2004 .