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Liquid synthetic jets for high flux electronics cooling

Mohammad Azarifar, Mehmet Arık

2024Applied Thermal Engineering15 citationsDOIOpen Access PDF

Abstract

• LSJD is modeled, manufactured, and experimentally studied. • Achieved 1.52 W/(cm 2 ·K) heat transfer coefficient in DI water. • Heat removal to input power is among highest coefficient of performance reported. • Nusselt number increases by 12 times compared to unassisted cooling. This study presents an approach to high-efficiency, low-energy liquid cooling using liquid synthetic jet devices. These devices generate dynamic pressure exactly where needed, addressing the inefficiencies of conventional liquid cooling systems. Powered by a piezoelectric actuator, localized, high-velocity jet impingement is achieved with minimal power consumption as low as 50 mW. With a dielectric working fluid as deionized water, liquid synthetic jet impingement showed a heat transfer coefficient of up to 1.52 W/(cm 2 ·K). Compared to existing methods, superior heat removal per unit of consumed power is achieved. This work presents an advancement in sustainable thermal management, with broad potential applications, including immersion cooling in data centers.

Topics & Concepts

ElectronicsFlux (metallurgy)Electronics coolingComputer coolingMaterials scienceMechanical engineeringEngineeringEngineering physicsNuclear engineeringEnvironmental scienceElectrical engineeringThermal management of electronic devices and systemsMetallurgyPlasma and Flow Control in AerodynamicsFluid Dynamics and Turbulent FlowsAerodynamics and Fluid Dynamics Research