Sinopsis
In the last two decades, heat transfer study on discrete heat sources has become a subject of increased interest due to advances in the electronics industry. Increased power dissipation is the most significant feature of new generation electronic devices and more significant heat flux densities are obtained as a result of miniaturization. Consequently, the assumption of cooling of electronic devices has increased interest in the analysis of fluid flow and heat transfer in discrete heating situations. Previous works have studied the natural, mixed, and forced convection in inclined channels due to their practical applications such as electronic systems, high performance heat exchangers, chemical process equipments, combustion chambers, environmental control systems and so on.
An interesting study was reported on the fluid flow and heat transfer characteristics associated with cooling an in-line array of discrete protruding heated blocks in a channel by using a single laminar slot air jet (Arquis et al., 2007). Numerical experiments were carried out for different values of jet Reynolds number, channel height, slot width, spacing between blocks, block height, and block thermal conductivity. The effects of variation of these parameters were detailed to illustrate important fundamental and practical results that are relevant to the thermal management of electronic packages. In general, the effective cooling of blocks was observed to increase with the increase of Reynolds number and the decrease of channel height. Circulation cells that may appear on the top surface of the downstream blocks were shown to decrease the value of Nusselt number for these blocks. The values of surface averaged Nusselt number attained their maximum at the block just underneath the impinging air jet, decreased for the downstream blocks, and approximately reached a constant value after the third block.
A numerical study (Madhusudhana & Narasimham, 2007) was carried out on conjugate mixed convection arising from protruding heat generating ribs attached to substrates forming a series of vertical parallel plate channels. A channel with periodic boundary conditions in the transverse direction was considered for analysis where identical disposition and heat generation of the ribs on each board were assumed. The governing equations were discretised using a control volume approach on a staggered mesh and a pressure correction method was employed for the pressure–velocity coupling.
Content
- A Mixed Convection Study in Inclined Channels with Discrete Heat Sources
- Periodically Forced Natural Convection Through the Roof of an Attic-Shaped Building
- Analysis of Mixed Convection in a Lid Driven Trapezoidal Cavity
- Convective Heat Transfer of Unsteady Pulsed Flow in Sinusoidal Constricted Tube
- Numerical Solution of Natural Convection Problems by a Meshless Method
- Hydromagnetic Flow with Thermal Radiation
- Transient Heat Conduction in Capillary Porous Bodies
- Non-Linear Radiative-Conductive Heat Transfer in a Heterogeneous Gray Plane-Parallel Participating Medium
- Optimization of the Effective Thermal Conductivity of a Composite
- Computation of Thermal Conductivity of Gas Diffusion Layers of PEM Fuel Cells
- Analytical Methods for Estimating Thermal Conductivity of Multi-Component Natural Systems in Permafrost Areas
- Heating in Biothermal Systems
- A Generalised RBF Finite Difference Approach to Solve Nonlinear Heat Conduction Problems on Unstructured Datasets
- Heat Transfer Analysis of Reinforced Concrete Beams Reinforced with GFRP Bars
- Modelling of Heat Transfer and Phase Transformations in the Rapid Manufacturing of Titanium Components
- Measurement of Boundary Conditions - Surface Heat Flux and Surface Temperature
- Properties and Numerical Modeling-Simulation of Phase Changes Material
- Finite Element Methods to Optimize by Factorial Design the Solidification of Cu-5wt%Zn Alloy in a Sand Mold
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