Titlebook: Buoyancy-Thermocapillary Convection of Volatile Fluids in Confined and Sealed Geometries; Tongran Qin Book 2017 Springer International Pub

BINGE

Convection at Atmospheric Conditions,Most of the intuition on which the design of current two-phase thermal management devices, such as heat pipes, is based on studies of convection at atmospheric conditions. The strength of the two main forces driving convection, buoyancy and thermocapillarity, is most commonly described in terms of the nondimensional parameters

Acetabulum

螢火蟲

牽索

Convection Under Pure Vapor, at least to some extent, under atmospheric conditions when the gas phase is dominated by noncondensables (air). On the other hand, it is well known that noncondensables significantly impede phase change and hence degrade the thermal performances of two-phase cooling devices [.]. Hence, their optima

amplitude

Convection at Reduced Pressures,c conditions and under pure vapor, respectively. Recent fundamental studies of this problem were mainly motivated by applications to thermal management. Although the ideal operating conditions for two-phase cooling devices such as thermosyphons, heat pipes, and heat spreaders corresponds to the pure

vascular

Linear Stability Analysis, formation of a stationary pattern at .. = .(1). This study by Priede and Gerbeth [.] is, however, based on a one-layer model where phase change is neglected and the free surface is considered adiabatic. While this description may be acceptable for nonvolatile liquids or at high concentrations of no

INERT

Conclusions and Recommendations,d only atmospheric conditions, were extended in this thesis to reduced pressures. This thesis work, which is hence more relevant for thermal management applications, used a combination of numerical simulations and analytical techniques. The main conclusions and contributions of this work, as well as

Contend

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Interim