Development of miniature cruciform specimen and testing machine for multiaxial creep investigation

Development of miniature cruciform specimen and testing machine for multiaxial creep investigation

•Biaxial tension-type testing machine is developed for multiaxial creep investigation.•Miniature cruciform specimen is designed for multiaxial creep testing.•Non-contact displacement measuring method for the miniature specimen is developed.•Specimen surface conditions during tests can be observed wi...

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Veröffentlicht in:Theoretical and applied fracture mechanics 2020-08, Vol.108, p.102582, Article 102582
Hauptverfasser: Hiyoshi, Noritake, Itoh, Takamoto, Sakane, Masao, Tsurui, Takafumi, Tsurui, Masaaki, Hisaka, Chiaki
Format: Artikel
Sprache:eng
Schlagworte:
Biaxial tests
Boiler tubes
Contact
Creep test
Creep tests
Cruciform specimen
Cruciform tests
Displacement
Extensometers
Finite element method
High temperature
Jet engines
Miniature specimen
Multiaxial stress
Plane stress
Strain
Testing machine development
Turbine blades
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container_end_page
container_issue
container_start_page 102582
container_title Theoretical and applied fracture mechanics
container_volume 108
creator Hiyoshi, Noritake
Itoh, Takamoto
Sakane, Masao
Tsurui, Takafumi
Tsurui, Masaaki
Hisaka, Chiaki
description •Biaxial tension-type testing machine is developed for multiaxial creep investigation.•Miniature cruciform specimen is designed for multiaxial creep testing.•Non-contact displacement measuring method for the miniature specimen is developed.•Specimen surface conditions during tests can be observed with developed apparatus. High temperature components such as boiler tubes and jet engine turbine blades undergo multiaxial creep damage due to extreme temperature conditions and their complex shapes. A multiaxial creep investigation is required for the safety of high temperature components in the design phase of the manufacture of such a component. However, there are only a few commercial testing machines that can conduct multiaxial loading at high temperatures. A miniature cruciform specimen having a plane stress condition gauge section that is 5 mm square was designed using finite element (FE) analysis. Further, a biaxial testing machine capable of tensile loading was designed to conduct multiaxial creep tests. The testing machine had a 2 kN loading capacity and a 1 kW furnace. We also developed a non-contact displacement measuring method for the miniature specimen, which had an excessively small gauge section to permit the attachment of a mechanical extensometer. The proposed method uses a conventional optical camera to capture some images of the surface. We obtained the displacement value of the specimen, by tracking the trace of the target marks painted on the surface of the specimen. The measured strain value that was obtained from the non-contact displacement measuring method corresponds to the strain obtained by the mechanical method at room and high temperatures. By using the developed multiaxial creep testing machine and the non-contact observation system, we can investigate not only the deformation of the testing specimen, but also the surface conditions of materials during the creep test.
doi_str_mv 10.1016/j.tafmec.2020.102582
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High temperature components such as boiler tubes and jet engine turbine blades undergo multiaxial creep damage due to extreme temperature conditions and their complex shapes. A multiaxial creep investigation is required for the safety of high temperature components in the design phase of the manufacture of such a component. However, there are only a few commercial testing machines that can conduct multiaxial loading at high temperatures. A miniature cruciform specimen having a plane stress condition gauge section that is 5 mm square was designed using finite element (FE) analysis. Further, a biaxial testing machine capable of tensile loading was designed to conduct multiaxial creep tests. The testing machine had a 2 kN loading capacity and a 1 kW furnace. We also developed a non-contact displacement measuring method for the miniature specimen, which had an excessively small gauge section to permit the attachment of a mechanical extensometer. The proposed method uses a conventional optical camera to capture some images of the surface. We obtained the displacement value of the specimen, by tracking the trace of the target marks painted on the surface of the specimen. The measured strain value that was obtained from the non-contact displacement measuring method corresponds to the strain obtained by the mechanical method at room and high temperatures. 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High temperature components such as boiler tubes and jet engine turbine blades undergo multiaxial creep damage due to extreme temperature conditions and their complex shapes. A multiaxial creep investigation is required for the safety of high temperature components in the design phase of the manufacture of such a component. However, there are only a few commercial testing machines that can conduct multiaxial loading at high temperatures. A miniature cruciform specimen having a plane stress condition gauge section that is 5 mm square was designed using finite element (FE) analysis. Further, a biaxial testing machine capable of tensile loading was designed to conduct multiaxial creep tests. The testing machine had a 2 kN loading capacity and a 1 kW furnace. We also developed a non-contact displacement measuring method for the miniature specimen, which had an excessively small gauge section to permit the attachment of a mechanical extensometer. 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subjects Biaxial tests
Boiler tubes
Contact
Creep test
Creep tests
Cruciform specimen
Cruciform tests
Displacement
Extensometers
Finite element method
High temperature
Jet engines
Miniature specimen
Multiaxial stress
Plane stress
Strain
Testing machine development
Turbine blades
title Development of miniature cruciform specimen and testing machine for multiaxial creep investigation
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