Enhanced active cooling of high power led light sources by utilizing shrouds and radial fins

Gleva, Mark.

January 2009

Thesis (M. S.)--Mechanical Engineering, Georgia Institute of Technology, 2009. / Committee Chair: Graham, Samuel; Committee Member: Joshi, Yogendra; Committee Member: Kumar, Satish. Part of the SMARTech Electronic Thesis and Dissertation Collection.

Heat transport in nanofluids and biological tissues

Fan, Jing, 范菁

January 2012

The present work contains two parts: nanofluids and bioheat transport, both involving multiscales and sharing some common features. The former centers on addressing the three key issues of nanofluids research: (i) what is the macroscale manifestation of microscale physics, (ii) how to optimize microscale physics for the optimal system performance, and (iii) how to effectively manipulate at microscale. The latter develops an analytical theory of bioheat transport that includes: (i) identification and contrast of the two approaches for developing macroscale bioheat models: the mixture-theory (scaling-down) and porous-media (scaling-up) approaches, (ii) rigorous development of first-principle bioheat model with the porous-media approach, (iii) solution-structure theorems of dual-phase-lagging (DPL) bioheat equations, (iv) practical case studies of bioheat transport in skin tissues and during magnetic hyperthermia, and (v) rich effects of interfacial convective heat transfer, blood velocity, blood perfusion and metabolic reaction on blood and tissue macroscale temperature fields. Nanofluids, fluid suspensions of nanostructures, find applications in various fields due to their unique thermal, electronic, magnetic, wetting and optical properties that can be obtained via engineering nanostructures. The present numerical simulation of structure-property correlation for fourteen types of two/three-dimensional nanofluids signifies the importance of nanostructure’s morphology in determining nanofluids’ thermal conductivity. The success of developing high-conductive nanofluids thus depends very much on our understanding and manipulation of the morphology. Nanofluids with conductivity of upper Hashin-Shtrikman bounds can be obtained by manipulating structures into an interconnected configuration that disperses the base fluid and thus significantly enhancing the particle-fluid interfacial energy transport. The numerical simulation also identifies the particle’s radius of gyration and non-dimensional particle-fluid interfacial area as two characteristic parameters for the effect of particles’ geometrical structures on the effective thermal conductivity. Predictive models are developed as well for the thermal conductivity of typical nanofluids. A constructal approach is developed to find the constructal microscopic physics of nanofluids for the optimal system performance. The approach is applied to design nanofluids with any branching level of tree-shaped microstructures for cooling a circular disc with uniform heat generation and central heat sink. The constructal configuration and system thermal resistance have some elegant universal features for both cases of specified aspect ratio of the periphery sectors and given the total number of slabs in the periphery sectors. The numerical simulation on the bubble formation in T-junction microchannels shows: (i) the mixing enhancement inside liquid slugs between microfluidic bubbles, (ii) the preference of T-junctions with small channel width ratio for either producing smaller microfluidic bubbles at a faster speed or enhancing mixing within the liquid phase, and (iii) the existence of a critical value of nondimensional gas pressure for bubble generation. Such a precise understanding of two-phase flow in microchannels is necessary and useful for delivering the promise of microfluidic technology in producing high-quality and microstructure-controllable nanofluids. Both blood and tissue macroscale temperatures satisfy the DPL bioheat equation with an elegant solution structure. Effectiveness and features of the developed solution structure theorems are demonstrated via examining bioheat transport in skin tissues and during magnetic hyperthermia. / published_or_final_version / Mechanical Engineering / Doctoral / Doctor of Philosophy

Nanofluids - Mechanical properties.

Tissues - Mechanical properties.

Heat transfer effects on the power coefficient of reactivity of natural convection-cooled reactors

Spriggs, Gregory D.

January 1976

No description available.

Nuclear reactors.

Towards numerical modeling of two-phase flow in seafloor hydrothermal systems

Xu, Wenyue

12 1900

No description available.

Porous materials Thermal properties

Two-phase flow

Heat Transmission

Time varying eddy meridional heat transport vectors

Burns, Leo Michael David

January 1974

No description available.

Eddies.

Dynamic meteorology.

Energy transfer.

Heat -- Transmission.

Atmospheric circulation.

Heat transmission along the surface of dental implant

Patel, Zaheed

January 2009

<p>Objectives: Temperature changes along an implant body have not been widely studied. The objectives of this in vitro study were (i) to establish if the temperature of the abutment influences the temperature of the implant surface, (ii) to establish the temperature transmission from abutment to implant body, and (iii) to establish for what abutment temperature the critical time/temperature threshold of 47oC for 1 minute at implant level is reached.</p>

1. Dental implants

2. Heat transmission

3. Thermocouple.

Numerical and experimental study of transient heat transfer through concrete.

Mabuya, Thabo Gordon.

January 2001

The increase in temperature of developing concrete as a result of heat liberated by cementing reactions is the primary cause for thermally induced cracks in large concrete elements. It is very essential, in engineering to predict the temperature rises in order to be able to minimise the potential of crack formation. This thesis covers the experimental determination of the heat of hydration curve using the adiabatic calorimeter and experimental determination of transient heat transfer obtained from measurement of temperature variations in concrete at its early ages of hydration. The measured temperature profiles from a one-dimensional heat transfer scenario are then compared with the predicted temperature profiles. The adiabatic hydration curve of a concrete beam sample is used as input into a numerical technique known as the Green Element Method for the calculation of temperature profiles. Time-based boundary conditions are imposed on the equation governing the model and will be solved using the Green Element Method coded in Fortran Power Station 4.0. / Thesis (M.Sc.Eng.)-University of Durban-Westville, 2001.

Heat transfer.

Heat--Transmission.

Concrete--Testing.

Theses--Civil engineering.

Heat transfer to an accelerated stream of droplets impinging onto a heated surface

Messana, Michael R.

12 1900

No description available.

Nuclear reactors Fluid dynamics

Nuclear reactors Cooling

Heat Transmission

The development of a Heat Transfer Module (HTM) for the thermal management of sealed electronic enclosures

Minichiello, Angela

12 1900

No description available.

Integrated circuits Heat treatment

Heat Transmission

Electronic apparatus and appliances

An analysis of the thermal stability of the soil environment of underground electrical cables

Hartley, James Gary

08 1900

No description available.

Soils Thermal properties

Heat Transmission

Underground electric lines