Measurement of a heated surface temperature using a high-speed infrared camera during critical heat flux enhancement by a honeycomb porous plate in a saturated pool boiling of a nanofluid

This article presents an experimental study to investigate the critical heat flux (CHF)enhancement mechanism using honeycomb porous plate (HPP). The CHF enhanced significantly with combination of the HPP and nanofluid, up to 3.2MW/m2 at maximum compared to a plain surface, 1.0MW/m2. The mechanism b...

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Main Authors: Mori, Shoji, Mt Aznam, Suazlan, Yanagisawa, Ryuta, Yokomatsu, Fumihisa, Okuyama, Kunito
Format: Article
Language:English
English
English
Published: Taylor & Francis 2019
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Online Access:http://irep.iium.edu.my/73198/1/73198_Measurement%20of%20a%20heated%20surface%20temperature.pdf
http://irep.iium.edu.my/73198/13/73198_Measurement%20of%20a%20Heated%20Surface%20Temperature_scopus.pdf
http://irep.iium.edu.my/73198/2/73198_Measurement%20of%20a%20heated%20surface%20temperature_WoS.pdf
http://irep.iium.edu.my/73198/
https://www.tandfonline.com/doi/full/10.1080/01457632.2019.1628487
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Summary:This article presents an experimental study to investigate the critical heat flux (CHF)enhancement mechanism using honeycomb porous plate (HPP). The CHF enhanced significantly with combination of the HPP and nanofluid, up to 3.2MW/m2 at maximum compared to a plain surface, 1.0MW/m2. The mechanism by which the CHF is improved in this system was elucidated by measuring the temperature of the heated surface using an indium tin oxide (ITO) heater and a high-speed infrared camera. The pool boiling experiment of water and nanofluid is performed under saturated temperature and atmospheric pressure conditions. The CHF values obtained using ITO heater is in good agreement with a conventional CHF pool boiling experiment with HPP attachment. High-speed infrared camera is analyzed to understand the behavior of local temperature at various locations over time. It is observed at the burnout condition, the highest average temperature is occurred at the intersection of HPP wall. Moreover, the reversible dry spots were initiated in the cell part of the HPP, and small dry spots coalesced into a growth of large irreversible dry out that leads to burnout. Further CHF enhancement could be realized if the initiation of the dryout region could be suppressed.