Experimental investigation and analysis of parametric trends of instability in two-phase micro-channel heat sinks

This study explores Density Wave Oscillation (DWO) and Parallel Channel Instability (PCI) in a microchannel heat sink containing 38 parallel channels having a hydraulic diameter of 316 mu m. Experiments are executed using FC-72 as working fluid with mass velocities from 171.2 to 1124 kg/m(2)s and a fairly constant inlet subcooling of similar to 15 degrees C. The flow instabilities are reflected in pressure fluctuations detected mostly in the heat sink's upstream plenum. Both inlet pressure and pressure drop signals are analyzed in pursuit of amplitude and frequency characteristics for different mass velocities and over a range of heat fluxes. The analysis is complemented by detailed visualization of interfacial features along the parallel channels using high-speed video. Appreciable confinement of bubbles in individual channels is shown to promote rapid axial bubble growth. The study shows significant variations in the amount of vapor generated and dominant flow patterns among channels, a clear manifestation of PCI, especially for low mass velocities and high heat fluxes. It is also shown effects of the heat sink's instabilities are felt in other components of the flow loop. The parametric trends for PCI are investigated with the aid of three different types of stability maps which show different abilities at demarcating stable and unstable operation. (C) 2021 Elsevier Ltd. All rights reserved.

Automated summary

This study investigates Density Wave Oscillation (DWO) and Parallel Channel Instability (PCI) in a microchannel heat sink, showing significant variations in bubble growth and flow patterns among channels under different mass velocities and heat fluxes. The effects of instabilities in the heat sink are also found to impact other components of the flow loop. The parametric trends for PCI are explored using three different types of stability maps, which demonstrate varying abilities in distinguishing stable and unstable operations.