SUBJECT: Ph.D. Dissertation Defense
BY: Vladimir Novak
TIME: Wednesday, March 29, 2006, 11:30 a.m.
PLACE: MRDC Building, 4211
TITLE: Experimental and Numerical Studies of Mist Cooling with Thin Evaporating Subcooled Liquid Films
COMMITTEE: Dr. Said I. Abdel-Khalik, Chair (ME/NRE)
Dr. S. Mostafa Ghiaasiaan (ME)
Dr. Sheldon M. Jeter (ME)
Dr. W. Russell Callen, Jr. (ECE)
Dr. Daniel W. Tedder (ChBE)


An experimental and numerical investigation has been conducted to examine steady, internal, nozzle-generated, gas/liquid mist cooling in vertical channels with ultra-thin, evaporating subcooled liquid films. Interest in this research has been motivated by the need for a highly efficient cooling mechanism in high-power lasers for inertial fusion reactor applications. The aim is to quantify the effects of various operating and design parameters, viz. liquid atomization nozzle design (i.e. spray geometry, droplet size distribution, etc.), heat flux, liquid mass fraction, film thickness, carrier gas velocity, temperature, and humidity, injected liquid temperature, gas/liquid combinations, channel geometry, length, and wettability, and flow direction, on mist cooling effectiveness. A fully-instrumented experimental test facility has been designed and constructed. The facility includes three cylindrical and two rectangular electrically-heated test sections with different unheated entry lengths. Water is used as the mist liquid with air, or helium, as the carrier gas. Three types of mist generating nozzles with significantly different spray characteristics are used. Numerous experiments have been conducted; local heat transfer coefficients along the channels are obtained for a wide range of operating conditions. The data indicate that mist cooling can increase the heat transfer coefficient by more than an order of magnitude compared to forced convection using only the carrier gas. Comparison has been made between the data and predictions of a modified version of the KIVA-3V code, a mechanistic, three-dimensional computer program for internal, transient, dispersed two-phase flow applications. Excellent agreement has been obtained.