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41	THERMAL CONDUCTIVITY MEASUREMNT AT ULTRA LOW TEMPERATURES Alkhesho, Issam 29 October 2010 (has links) Thermal Conductivity studies can provide fundamental information regarding the symmetry of the superconducting energy gap. To perform this kind of experiment, we need to use a very low temperature environment. Also a special mount has been to designed and constructed for the thermal conductivity measurements. This mount will allow holding the sample in different directions with respect to the applied magnetic field. The results are consistent with Wiedemann-Franz law to within 2.5\%. We also discuss a series of thermal conductivity experiments to shed additional light on the symmetry of the superconducting order parameter in the unconventional superconductor PrOs4Sb12. THERMAL CONDUCTIVTY LOW TEMPERATURES Physics
42	Deformation of aluminum at high temperatures and stainrates. Wong, Winston Alexander. January 1967 (has links) No description available. Aluminum
43	High heat flux cooling via A monodisperse controllable spray Denney, D. Lawrence 05 1900 (has links) No description available. Cooling Materials at high temperatures
44	High heat flux spray cooling Sheffield, Randolph J. 08 1900 (has links) No description available. Cooling Materials at high temperatures
45	An investigation of metal particle reaction with the sodium D line reversal technique Schliessmann, Michael O. 08 1900 (has links) No description available. Metals at high temperatures Thermodynamics
46	Experimental study of radiation from coated turbine blades Husain Al-taie, Arkan Khilkhal January 1990 (has links) The specific power (or specific thrust) of modern gas turbines is much influenced by the gas temperature at turbine inlet. Even with the use of the best superalloy available and the most advanced cooling configurations, there are competitive pressures to operate engines at even higher gas temperatures. Ceramic coatings operate as thermal barriers and can allow the gas temperature to be increased by 50 to 220 K over the operating gas temperature for an uncoated turbine . It is important that the surface temperature of the blade be determined as accurately as possible. Large uncertainties as to the surface temperature require significant margins for safe operation . Blade surface temperatures can be determined with an accuracy of 10 K using radiation pyrometry and about'30 to 40 K by calculating the blade temperature based on---gas temperature measurement of the exhaust gas plane. This'- makes pyrometry an attractive option for advanced high temperature gas turbines . However, there is little experience in measuring surface temperatures of blades coated with ceramic coatings. There is evidence that the. radiation signal picked up by the pyrometer will not only depend on the surface temperature but also on a number of optical properties of the coating. Important among these are the emissivity of the coating and whether the coating is translucent. Parameters affecting this are the coating material, coating surface finish, coating thickness and whether or not a bond coat is used . This work explores these variables in a rig that simulates the conditions within a turbine stage of a gas turbine engine. In which six thermal barrier coating systems were tested. These systems are of current interest to gas turbine manufacturers and users. They include the latest advances in coating technology. Four stabilized zirconia systems and two alumina based systems were tested. It was found experimentally that the surface emissivity of these coating systems was invariant over the range 873 to 1023 K surface temperature. It was found that the use of different stabilizers did not affect the surface spectral emissivity. In further experiments six turbine wheels were coated with these systems and tested at turbine entry temperatures of 973, 1073, and 1173 K. It was found that the blade surface temperature was function of the coating material, coating thickness and turbine entry temperature. The blade surface temperature was also function of the blade height being maximum at the blade tip and minimum at the blade root . It was found that the C-YPSZ was better insulator than the rest of the systems. Whilst the blades coated with zirconia based systems suffered minor loss near the edges, the two alumina based systems were lost from more than a blade during the test. This coating loss was picked up by. the pyrometer . Analysis shows that the measured blade surface temperature was within 10 K of that calculated. The use of 0.3 mm of C-YPSZ on air cooled turbine blades caused 250 K surface temperature increase and 270 K metal temperature decrease for turbine entry temperature of 1673 K. The metal temperature reduction was as high as 310 K for coating thickness of 0.5 mm. 621.4352 Gas turbine inlet temperatures
47	Characterization of high temperature creep in siliconized silicon carbide using ultrasonic techniques / Buttram, Jonathan D., January 1990 (has links) Thesis (M.S.)--Virginia Polytechnic Institute and State University, 1990. / Vita. Abstract. Includes bibliographical references (leaves 75-76). Also available via the Internet.
48	Functional qualities of rice for high temperature food processing / Chui, Man-yung. January 2002 (has links) Thesis (M. Phil.)--University of Hong Kong, 2002. / Includes bibliographical references (leaves 102-109).
49	Low temperature relations in the system MgO-SiO₂-CO₂-H₂O, Hostetler, Paul Blair. January 1960 (has links) Thesis (Ph. D.) - Harvard University, 1960. / Bibliography: leaves [90-93]
50	Une conception nouvelle de la supraconductibilité ... London, Fritz, Bauer, Edmond, Winter, J., January 1937 (has links) Thèse--Université de Paris. / At head of title: ... F. London. Published also as no. 458 in series Actualités scientifiques et industrielles. Translated by Edmond Bauer and J. Winter. "Rèfèrences": p. [79]-80. Includes bibliographical references.

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