PRESSURE-DROP WITH HIGHLY SUBCOOLED FLOW BOILING IN SMALL-DIAMETER TUBES

Citation
W. Tong et al., PRESSURE-DROP WITH HIGHLY SUBCOOLED FLOW BOILING IN SMALL-DIAMETER TUBES, Experimental thermal and fluid science, 15(3), 1997, pp. 202-212
Citations number
28
Categorie Soggetti
Engineering, Mechanical","Phsycs, Fluid & Plasmas",Thermodynamics
ISSN journal
08941777
Volume
15
Issue
3
Year of publication
1997
Pages
202 - 212
Database
ISI
SICI code
0894-1777(1997)15:3<202:PWHSFB>2.0.ZU;2-9
Abstract
Pressure drop may be the most important consideration in designing hea t-removal systems utilizing high-heat-flu subcooled boiling. In this s tudy, an experimental investigation was performed to identify the impo rtant parameters affecting pressure drop across small-diameter tubes i n highly subcooled flour boiling. The effects of five parameters-mass flux, inlet temperature, exit pressure, tube internal diameter, and le ngth-to-diameter ratio-on both single-and two-phase pressure drop were studied and evaluated. Experiments were carried out with tubes having inside diameters ranging from 1.05 to 2.44 mm. Mass fluxes ranged fro m 25,000 to 45,000 kg/(m(2) s), exit pressures from 4 to 16 bar, and i nlet temperatures from 22 to 66 degrees C. Two length-to-diameter rati os were tested. These conditions resulted in critical heat flux levels of 50-80 MW/m(2).The experimental results indicate that mass flux, tu be diameter, and length-to-diameter ratio are the major parameters tha t alter the pressure-drop curves. Both single-and two-phase pressure d rops increase with increasing mass flux and length-to-diameter ratio b ut decrease with increasing internal diameter. Inlet temperature and e xit pressure have been shown to have significant effects on two-phase pressure drop but very small effects on single-phase pressure drop. Th ese results agree well with those from other investigations under simi lar conditions. As a result of this study, pressure-drop correlations are presented for predicting bath single-phase and subcooled boiling p ressure drop in small-diameter tubes under different heat-flux conditi ons. (C) Elsevier Science Inc., 1997.