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An experimental investigation of droplet impact cooling at controlled surface temperaturesWang, Jianwei 05 1900 (has links)
No description available.
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Transient free convection in a closed container with heating at the bottom and at the sidesTatom, John Wilbur 05 1900 (has links)
No description available.
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Thermal convection within superheated liquid metal cavitiesRastegar, Freidoon 08 1900 (has links)
No description available.
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Numerical analysis of the dropwise evaporation processRuiz, Orlando E. 05 1900 (has links)
No description available.
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Onset of flow instability in heated horizontal annuliBlasick, Ann Marie 05 1900 (has links)
No description available.
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Natural convection in liquid metals and alloys.Chiesa, Franco. January 1972 (has links)
No description available.
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Natural convection mass transfer to particlesAstrauskar, Peter. January 1980 (has links)
No description available.
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Heat transfer in fluids in the thermodynamic critical regionKenkare, Arvind S. January 1967 (has links)
No description available.
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Natural convection in liquid metalsStewart, Murray John January 1970 (has links)
Natural convection in liquid metals has been studied by direct observation of the fluid flow, using radioactive tracer techniques. The study is of importance in understanding the solidification of metals since fluid flow strongly influences the heat and mass transfer in the system which in turn strongly influences the structure, homogeneity, and mechanical properties of the solid metal produced.
The system examined in this investigation was a rectangular liquid cell of variable thickness, positioned on edge. A small driving force for natural convection was imposed across the liquid cell and when steady state conditions were reached, a small amount of the same material containing a radioactive isotope was added to the top of the cell. The tracer material was picked up by the flow and after a given time interval the liquid was quenched to fix the tracer position. The resultant solid block was autoradiographed to determine the distribution of the added radioactive material.
Thermal convection was observed in liquid tin and liquid lead using radioactive Sn¹¹³ and radioactive TI²º⁴ respectively. The results show that the flow rates increase with increasing temperature difference across the liquid cell, increasing average temperature, and increasing liquid cell thickness. Flow rates with Grashof numbers from 10⁶ to 10⁸ were experimentally observed.
A finite difference numerical solution for the problem of thermal convection is presented for Prandtl numbers of 10.0, 1.0, 0.1, and 0.0127 with Grashof numbers from 2 x 10³ to 2 x 10⁷. The experimental results for liquid tin (Pr = 0.0127) are found to approach the theoretical analysis for large cell thicknesses and large temperature differences. The flow behavior of various types of fluids is compared with liquid metals to show that non-metallic analogies to .metallic flow problems have very limited value.
Solute convection is experimentally considered from three different viewpoints; a) independent solute convection, b) the influence of solute convection on thermal convection, and c) the thermal and solute conditions for complete liquid mixing. It was found that there must be a horizontal density inversion across the whole liquid cell for complete mixing to occur throughout the liquid zone.
Interdendritic liquid flow resulting from the natural convection in the residual liquid pool was observed in lead-tin alloys. The flow penetrated into the solid-liquid zone to a point of approximately 12 - 22 % solid for primary dendrite spacings of from 700 to 1000 microns. Several experimental models are presented for interdendritic flow. A three-dimensional wire mesh model predicts that the finer the dendrite structure, the greater the flow penetration into the solid-liquid zone. The experimental results for the lead-tin alloys compared favorably with the model.
As an extension of the fluid flow considerations, an investigation was carried out to determine macrosegregation in castings which have imposed fluid flow patterns. The macrosegregation present in stationary, rotated, and oscillated castings of Al - 3 wt. % Ag was determined by measuring the distribution of radioactive silver added to the melt. It was found that, no significant macrosegregation was present in the stationary and rotated castings. Extensive macro-segregation was detected in the oscillated casting. For the oscillated case the macrosegregation can be accounted for on the basis of the long range movement of dendrite fragments which break and/or melt off in the solid-liquid interface region. This movement is a direct result of turbulent waves associated with the oscillation. The maximum silver concentration
is shown to be related to the columnar-to-equiaxed transition. / Applied Science, Faculty of / Materials Engineering, Department of / Graduate
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Forced convection heat transfer from a cylinder in supercritical carbon dioxideGreen, John Richard January 1970 (has links)
Heat transfer rates have been measured for forced flow of supercritical carbon dioxide normal to a horizontal heated cylinder. The 0.006 inch diameter cylinder was held at various constant temperatures by a feed-back bridge circuit. Free convection results are also included.
The effects of bulk fluid temperature, bulk fluid pressure, and surface temperature were studied for a range of bulk fluid temperature and pressure of from 0.8 to 1.4 times the critical temperature and pressure for several free stream velocities from zero to three feet per second. The temperature difference between the heated cylinder and the bulk fluid was varied from 1 deg F to 320 deg F.
Flow fields of all data runs were observed. Still photographs and high speed movies have been taken at operating conditions of interest.
In a supercritical fluid the heat transfer rate increases smoothly and monotonically with increasing temperature difference, increasing velocity, and increasing pressure. In fluid with the bulk temperature below the pseudo-critical temperature the heat transfer coefficient shows large peaks when the cylinder temperature is near the pseudocritical temperature. Peaks are largest when
the bulk fluid pressure is near the critical pressure. The heat transfer coefficient decreases with increasing temperature difference when the bulk fluid temperature is above the pseudo-critical temperature. The heat transfer rate noteably increases with increasing pressure only when vapour-like fluid is in contact with the heated cylinder.
Supercritical forced flow has been compared to forced flow boiling. The supercritical case does not exhibit the characteristic strong maxima in heat transfer rate shown in forced flow nucleate boiling. Heat transfer rates at larger temperature differences are very similar in forced flow film boiling and supercritical forced flow heat transfer.
With this horizontal, constant temperature cylinder, no "bubble-like" or "boiling-like" mechanisms of heat transfer were observed in supercritical free or forced convection. The flow field and heat transfer rate in free convection were found to be very unstable and sensitive to small temperature disturbances in the bulk fluid. / Applied Science, Faculty of / Mechanical Engineering, Department of / Graduate
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