In-Situ Thermography Investigation of Crack Growth in Armco Iron under Gigacycle Fatigue Loading

A non-destructive thermographic methodology based on the temperature field is utilized to determine the crack tip position during the very high cycle fatigue (VHCF) test of pure iron and deduce the corresponding fatigue crack growth rate (FCGR). To this end, a piezoelectric fatigue machine is employ...

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Bibliographic Details
Published in:Metals (Basel ) 2022-05, Vol.12 (5), p.870
Main Authors: Postel, Victor, Petit, Johann, Wang, Chong, Tan, Kai, Ranc-Darbord, Isabelle, Wang, Qingyuan, Wagner, Daniele
Format: Article
Language:English
Subjects:
Cameras
Cast iron
Crack initiation
Crack propagation
Crack tips
Dissipation
Energy dissipation
Engineering Sciences
fatigue crack growth rate
Fatigue failure
Fatigue tests
Fracture mechanics
Heat
High cycle fatigue
intrinsic dissipation
Nondestructive testing
Piezoelectricity
Propagation
Short cracks
Stress concentration
Temperature distribution
Thermography
ultrasonic fatigue test
very high cycle fatigue
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Summary:A non-destructive thermographic methodology based on the temperature field is utilized to determine the crack tip position during the very high cycle fatigue (VHCF) test of pure iron and deduce the corresponding fatigue crack growth rate (FCGR). To this end, a piezoelectric fatigue machine is employed to test 1 mm thick pure iron samples at 20 kHz in push–pull fatigue loading. Two cameras are placed on each side of the plate sample, an infrared one for measuring the temperature fields on the specimen surface and an optical one for visualizing the crack tip verification. The centre section of the specimen is notched to initiate the crack. The temperature field is converted into intrinsic dissipation to quantify the inelastic strain energy according to energy conservation. The maximum value of intrinsic dissipation in each thermal image is related to the position of the crack tip and thus allows monitoring of the crack evolution during the fatigue test. The obtained results show that one specific specimen broke at 7.25 × 107 cycles in the presence of a very low-stress amplitude (122 MPa). It is observed that the intrinsic dissipation has a low-constant level during the initiation and the short cracking, then sharply grows during the long cracking. This transition is visible on the polished surface of the sample, where the plasticity appears during the long cracking and slightly before. The material parameters in the Paris equation obtained from the intrinsic dissipation in the short crack growth are close to the results available in the literature as well as those obtained by the optical camera.
ISSN:2075-4701
2075-4701
DOI:10.3390/met12050870