Micro-Scale Simulations of Boiling Heat Transfer via a Volume of Fluid Approach: Application to Pool Boiling and Flow Boiling
Abstract
The current trend in the electronics industry is to offer products that are progressively smaller and more powerful, resulting to an exponential increase in the generated residual heat. Effective and environmental-friendly cooling of electronic components is of upmost importance for the Thermal Management of Data Centres, Fuel Cells, Insulated-Gate Bipolar Transistors, Lithium-Ion Batteries and a variety of other important technological applications. Boiling heat transfer has been proven as one of the most efficient cooling strategies for such High-Power Density Electronics. However, such thermal management solutions that rely on the phase-change of a working fluid, are not yet used fully in practice. This is due to a lack of deep understanding of the underpinned complex flow and transport processes and a corresponding lack of reliable and easy-to-use thermal design tools. The cooling efficiency of phase-change heat transfer devices and components depends mainly on phenomena occurring at very small scales, such as bubble nucleation and bubble growth characteristics. Therefore, a parallel effort on developing interlinked (i) suitable theoretical models, (ii) specialized 3D, high-fidelity numerical simulations and (iii) accurate experiments is required to make a real breakthrough on understanding the underlying mechanisms of heat transfer during phase-change, especially in small scales.
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