The heat transfer performance of two microjet arrays was investigated using degassed deionized water and air. The inline jet arrays had diameters of 54μm and 112μm, a spacing of 250μm, a standoff of 200μm (S/d=2.2 and 4.6, H/d=1.8 and 3.7), and jet-to-heater area ratios from 0.036 to 0.16. Average heat transfer coefficients with deionized water were obtained for 150Red3300 and ranged from 80,000W/m2K to 414,000W/m2K. A heat flux of 1110W/cm2 was attained with 23°C inlet water and an average surface temperature of 50°C. The Reynolds number range for the same arrays with air was 300Red4900 with average heat transfer coefficients of 2500W/m2K to 15,000W/m2K. The effect of the Mach number on the area-averaged Nusselt number was found to be negligible. The data were compared with available correlations for submerged jet array heat transfer.

Issue Section:
Research Papers
Keywords:
heat transfer, jets, Mach number, microfluidics, electronics cooling, microscale jet heat transfer, microjet, microjet array
Topics:
Heat transfer, Heat transfer coefficients, Reynolds number, Temperature, Water, Mach number, Heat losses, Flow (Dynamics), Jets
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