non-contact measurement of creep resistance of ultra-high-temperature materials|High : distributors Conventional techniques for the measurement of creep are limited to about 1700 °C. A new method which can be applied at temperatures higher than 2000 °C is strongly demanded. This paper presents a non-contact method for creep measurements of ultra-high-temperature materials at 2300 °C. Using the electrostatic levitation facility at NASA MSFC .
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This paper presents a non-contact method for creep measurements of ultra-high-temperature materials at 2300 °C. Using the electrostatic levitation facility at NASA MSFC, a spherical sample was rotated quickly enough to cause creep deformation due to centripetal . This paper presents a non-contact method for creep measurements of ultra-high-temperature materials at 2300 °C. Using the electrostatic levitation facility at NASA MSFC, a .
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[33] Lee J 2007 Non-contact measurement of creep resistance . of ultra-high-temperature materials PhD Dissertation. University of Massachusetts, Amherst, MA
[32] Lee J, Bradshaw R C, Rogers J R, Rathz T J, Wall J J, Choo H, Hyers R W and Liaw P K 2007 Non-contact measurement of creep resistance of ultra-high-temperature materials Mater. Sci. Eng. A 463 185–96. Go to reference in article; Crossref; Google Scholar
A need for higher service temperatures is driving development of new, higher temperature materials that are resistant to creep. However, conventional methods of measuring creep become increasingly difficult over about 1700 °C.A non-contact method with the capability of measurements at much higher temperature has been demonstrated on niobium using .Conventional techniques for the measurement of creep are limited to about 1700 °C. A new method which can be applied at temperatures higher than 2000 °C is strongly demanded. This paper presents a non-contact method for creep measurements of ultra-high-temperature materials at 2300 °C. Using the electrostatic levitation facility at NASA MSFC . A need for higher service temperatures is driving development of new, higher temperature materials that are resistant to creep. However, conventional methods of measuring creep become increasingly difficult over about 1700 °C. A non-contact method with the capability of measurements at much higher temperature has been demonstrated on niobium using . In addition to swelling resistance, ODS steels offer excellent high-temperature creep resistance. In ODS, the presence of nano-dispersoids (e.g. Y 2 O 3) or nano-clusters (e.g. Y–Ti–O) hinders the dislocation motion in the ferritic steel matrix. Furthermore, the nano-clusters or nano-dispersoids act as a sink of defects induced by radiation.
In materials science, creep (sometimes called cold flow) is the tendency of a solid material to undergo slow deformation while subject to persistent mechanical stresses.It can occur as a result of long-term exposure to high levels of stress that are still below the yield strength of the material. Creep is more severe in materials that are subjected to heat for long periods and generally . Ni-based single crystal (SX) superalloys are key materials for the manufacture of blades and vanes used in the hottest parts of the most advanced aero-engines and industrial gas turbines [1,2,3].These alloys are currently used at temperatures of up to 1100 °C–1150 °C during operation of civil and military aero-engines owing to a combination of both good environmental . This research develops a non-contact method for the measurement of creep at the temperatures over 2,300 C. Using the electrostatic levitator in NASA MSFC, a spherical sample was rotated to cause creep deformation by centrifugal acceleration. The deforming sample was captured with a digital camera and analyzed to measure creep deformation. Exceptional Ultra-High Temperature Creep Resistance of a [111]-Oriented Single Crystal Superalloy AMI: Scripta Materialia 11 Pages Posted: 14 Nov 2023 Publication Status: Published
Semantic Scholar extracted view of "High temperature creep testing of ceramics" by D. F. Carroll et al. . Non-contact measurement of creep resistance of ultra-high-temperature materials. Jong-Hyun Lee R. Bradshaw +5 authors P. Liaw. Materials Science, Engineering. 2007; 18.
Some very high-temperature materials are being developed, including platinum group metals, carbides, borides, and silicides. But the measurement of creep properties at very high temperatures is itself problematic, because the testing instrument must operate at such high temperatures. Conventional techniques are limited to about 1700 C. For high-temperature applications (greater than 2,000 C) such as solid rocket motors, hypersonic aircraft, nuclear electric/thermal propulsion for spacecraft, and more efficient jet engines, creep becomes one of the most important design factors to be considered. Conventional creep-testing methods, where the specimen and test apparatus are in contact . A non-contact technique for measuring the creep properties of materials has been developed and validated as part of a collaboration among the University of Massachusetts, NASA Marshall Space Flight Center Electrostatic Levitation Facility (ESL), and the University of Tennessee. This novel method has several advantages over conventional creep testing.
High-temperature titanium alloys are one of the most important research directions in the field of high-temperature aerospace alloys. They are mainly used in high-temperature-resistant components, such as blade disks, blades, .
Conventional techniques for the measurement of creep are limited to about 1700 °C. A new method which can be applied at temperatures higher than 2000 °C is strongly demanded. This paper presents a non-contact method for creep measurements of ultra-high-temperature materials at 2300 °C. Using the electrostatic levitation facility at NASA MSFC .This study concerns the quasi-static and time-dependent mechanical behavior obtained via the miniaturized electro-thermal mechanical testing (ETMT) approach for single crystal (SX) and conventional cast Mar-M-247 superalloy. The experimental outcome was benchmarked against standardized testing procedures. It is found that tensile yielding behavior can be captured . The deformation rate at the stationary stage defines the creep strength of a material. The materials used in high-temperature applications should have high corrosion resistance, oxidation resistance, and creep strength.
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Some very high-temperature materials are being developed, including platinum group metals, carbides, borides, and silicides. But the measurement of creep properties at very high temperatures is itself problematic, because the testing instrument must operate at such high temperatures. Conventional techniques are limited to about 1700 C.
Creep of crystalline materials at high temperatures is a thermally activated process and is governed by the mobility of point or line defects. Shear or sliding in the grain-boundary regions introduces additional complexities to the creep of polycrystalline materials at elevated temperatures. The creep behavior of single crystals of the nickel-based superalloy CMSX-4 was investigated at 1288 °C, which is the temperature of the hot isostatic pressing treatment applied to this superalloy in the industry. It was found that at this super-solvus temperature, where no γ′-strengthening occurs, the superalloy is very soft and rapidly deforms under stresses between . A new non-contact method for creep measurements of ultra-high-temperature metals and ceramics has been developed and validated. Using the electrostatic levitation (ESL) facility at NASA Marshall Space Flight Center, a spherical sample is rotated quickly enough to cause creep deformation due to centrifugal acceleration. . Non-contact Creep .Conventional techniques for the measurement of creep are limited to about 1,700°C. A new method which can be applied at temperatures higher than 2,000°C is strongly demanded. This research presents a non-contact method for the measurements of creep resistance of ultra-high-temperature materials.
Fig. 1 a presents the creep curve of the designed alloy deformed under 1150 °C and 137 MPa condition, loading direction was along [111] direction. As shown, the alloy's creep life was approximately 217 h, setting a new record in literatures [10].The total creep strain was about 6 %, and the minimum strain rate was calculated to be about 5 × 10 −5 /s. Creep property of high-temperature titanium alloys is one of the most important indexes to evaluate their high-temperature performance. The microstructure of titanium alloy materials plays a decisive role in creep resistance. Coarser the grains are and finer the secondary phase is, better is the creep property. Suitable hot deformation parameters, heat .know the creep characteristics of new ultra-high-temperature materials. Conventional creep-testing methods, where the . Non-contact measurements of creep properties of niobium at 1985 °C J Lee1 . Ultra-high temperature ceramics (UHTCs), with their exceptionally high melting points and outstanding thermomechanical behaviour, are critical materials for extreme environment technologies. This .
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non-contact measurement of creep resistance of ultra-high-temperature materials|High