The characteristics of premature and stable critical heat flux for downward flow boiling at low pressure in a narrow rectangular channel

•We investigated flow instability and critical heat flux for downward flow in a narrow rectangular channel heated from both sides for various amounts of applied inlet throttling.•The unstable and stable flow boiling was investigated by monitoring the channel pressure drop and high speed visualizatio...

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Published in:Experimental thermal and fluid science 2015-12, Vol.69, p.86-98
Main Authors: Lee, Juhyung, Jo, Daeseong, Chae, Heetaek, Chang, Soon Heung, Jeong, Yong Hoon, Jeong, Jae Jun
Format: Article
Language:English
Subjects:
Boiling
Channels
Critical heat flux
Downward flow
Flow instability
Fluctuation
Heat flux
Heat transfer
Inlets
Narrow rectangular channel
Pressure drop
Research reactors
Throttling
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Summary:•We investigated flow instability and critical heat flux for downward flow in a narrow rectangular channel heated from both sides for various amounts of applied inlet throttling.•The unstable and stable flow boiling was investigated by monitoring the channel pressure drop and high speed visualization.•Premature CHF was characterized by the maximum pressure drop fluctuation and occurred in the unstable slug–churn flow regime.•Stable CHF occurred in the re-stabilized annular flow regime with reduced fluctuations over saturated liquid condition. Flow instability and critical heat flux (CHF) especially for downward flow of water in a vertical narrow rectangular channel heated from both sides were experimentally investigated. The gap, width, heated width, and heated length of the channel were 2.35, 40, 30, and 350mm, respectively. The flow boiling was developed as the wall heat flux was increased for the imposed mass flux of 500 and 1000kgm−2s−1 for high inlet subcooling (52–74K) conditions under atmospheric pressure. In this paper, the unstable boiling flow was investigated by monitoring the channel pressure drop and high speed visualization for side view of boiling (HSV-SVB) with the back-lighting method. The results showed that an irremovable pressure drop fluctuation was involved in the flow boiling after the distinct initiating point called as the onset of pressure drop fluctuation (OPDF). We determined that coalescence of bubble (or vapor) layers on opposing heated surfaces triggered the OPDF, since an abrupt increase of pressure drop was occurred as the expansion of the liquid–vapor interface became bounded by the other layer on the opposite side. The fluctuation was amplified as the exit quality was increased and the flow regime passed through the unstable slug or churn flow. For a low inlet throttling condition, premature CHF was induced at the maximum fluctuation during those flow regimes. On the other hand, stable CHF was obtained in the re-stabilized flow regime as the annular flow was developed only for large inlet throttling conditions with an additional pressure drop across the valve of more than 0.4bar for our experimental configuration.
ISSN:0894-1777
1879-2286
DOI:10.1016/j.expthermflusci.2015.07.015