R. E. Taylor scite author profile

The boundary radiation heat loss method is investigated for the flash method in measuring thermal difTusivity. Present correction procedures for heat loss are tested experimentally using AXM -5Q (POCO) graphite. In addition, a new method for radiation loss correction is presented based solely on the heating portion of the temperature rise curve. Using the new method, corrections of 35% can be made within a ± 3% error. The thermal difTusivity results calculated using the adiabatic expression for various portions of the fractional rise curve and for various heat losses are also presented.

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Degradation of Thermal-Barrier Coatings at Very High Temperatures

Stott¹,

Wet²,

Taylor³

1994

MRS Bull.

138

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Thermal-barrier coatings are finding increasing use in engineering applications, particularly in gas turbines. Such coatings, consisting of ceramic insulating layers bonded to the superalloy substrate by oxidation-resistant alloy coatings, are deposited onto components to reduce heat flow through the cooled substrate and to limit operating temperature. They have been used effectively on static components such as combustor cans, flare heads, hot gas seal segments, fuel evaporators, and deflector plates, giving considerable improvements in component life. They have been used successfully on vane platforms. In recent years, the emphasis has shifted toward the development of coatings for high-risk areas, such as turbine blades.A ceramic thermal-barrier coating needs to be refractory and chemically inert, and to have low thermal conductivity. However, it also needs to possess a high thermal expansion coefficient of ~11 × 10−6 K−1, to match the nickel-base superalloy substrate. The latter specification has focused attention on ZrO2. However, ZrO2 is polymorphic and undergoes two phase changes, cubic to tetragonal at 2350°C and tetragonal to monoclinic at 1170°C. The latter transformation is accompanied by a 5% volume increase which means that ZrO2 has to be alloyed to stabilize one of the high-temperature phases. Early systems in the 1970s consisted of ZrO2 stabilized with MgO, but this has been shown to be a metastable system. Present-day commercial thermal-barrier coatings consist of a plasma-sprayed yttria- or magnesiastabilized zirconia layer on top of an M-Cr-Al-Y bond coat. The latter plays a very important role by helping to key the ceramic to the alloy substrate and to accommodate the mechanical strains arising because of differences in thermal expansion coefficients and elastic moduli between the ceramic and the substrate.

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The thermal conductivity of pyrolytic graphite

Taylor

1966

Philosophical Magazine

130

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R. E. Taylor

Numerical Data on Thermal Linear Expansion of Metallic Elements and Alloys

Numerical Data on Thermal Linear Expansion of Nonmetallic Solids

Radiation loss in the flash method for thermal diffusivity

Degradation of Thermal-Barrier Coatings at Very High Temperatures

The thermal conductivity of pyrolytic graphite

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