Surface heat transfer due to sliding bubble motion
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Donnelly, B., O'Donovan, T.S. and Murray, D.B., Surface heat transfer due to sliding bubble motion, Applied Thermal Engineering, 29, 2009, 1319 - 1326
Abstract
The presence of a rising bubble in a fluid can greatly enhance heat transfer from adjacent heated surfaces
such as in shell and tube heat exchangers and chemical reactors. One specific case of this is when a bubble
impacts and slides along the surface. The result is heat transfer enhancement by two main mechanisms:
first, the bubble itself acting as a bluff body, and second, the wake generated behind the bubble
leads to increasing mixing. The current research is concerned with measuring the heat transfer from a
submerged heated surface that is subject to a sliding bubble flow. An ohmically heated 25 lm thick stainless
steel foil, submerged in a water tank, forms the test surface. An air bubble is injected onto the lower
surface of the test plate, it slides along its length and the effects are monitored by two methods. Thermochromic
liquid crystals (TLC?s) are used in conjunction with a high speed camera to obtain a time varying
2D temperature map of the test surface. A second synchronised camera mounted below the foil records
the bubble motion. Tests are performed at angles of 10, 20 and 30 to the horizontal. This paper reports
on the enhancement of the heat transfer due to the bubble. It has been found that the angle made
between the heated surface and the horizontal influences heat transfer by changing the bubble?s motion.
In general, a steeper angle leads to a higher bubble velocity, which results in greater heat transfer
enhancement.
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Author's Homepage: http://people.tcd.ie/dmurray
Type of material: Journal Article

