A multianalysis thermography‐based approach for fatigue and damage investigations of ASTM A182 F6NM steel at two stress ratios

Efforts to understand fatigue in materials generally rely on defining relationships between the material response to fatigue loading and the evolving remaining material life portion. Typical measurements and data associated with such relationships include load (stress), displacement (strain), and associated properties (eg, mean stress and strain, energy dissipation, and residual stiffness). In addition to obtaining such measurements, efforts have been made to leverage nondestructive evaluation (NDE) methods to obtain additional information and enhance the description of the material fatigue response, especially its evolution due to interacting material‐microstructure‐property relationships. Given the range of available NDE methods and the number of materials they can be applied to, a critical overview of related investigations is presented in this article. Specifically, the state of the art of applying optical, thermal, acoustic, electromagnetic, X‐ray, and other diffraction NDE methods in fatigue investigations is provided and discussed. The methods are individually described for background and defining their relationship to fatigue, followed by descriptions of their current uses and contributions to enhancing the understanding of fatigue, and their limitations and ways that improvements could be made.

Section: Key Results Contributions To Fatigue and Limitationsmentioning

confidence: 99%

Section: Thermal Nde Methods Used In Materials Fatiguementioning

confidence: 99%

The use of nondestructive evaluation methods in fatigue: A review

Wisner

Mazur

Kontsos

2020

“…This short and strongly simplified description of the correlation between mechanical loading and temperature evolution illustrates that the use of temperature‐based inspection methods, such as IrT can be used to monitor the damage procedures of loaded structures. Methods as the thermal stress analysis for instance even provide the potential of correlating cyclic heat and temperature changes with fatigue properties 28,29 . To facilitate the interpretation of the test results, a short introduction into the functionality of IrT is provided.…”

Section: Theorymentioning

confidence: 99%

Monitoring multiple damage mechanisms in crack‐patched structures using optical infrared thermography

Martens

Schröder

2020

The ability to understand the overall long‐term damage behaviour of crack patched components is essential to improve methods for the performance prediction. The method of passive infrared thermography comprises great opportunities to support the comprehension of the subsurface damage progress of crack‐patched structures. Quasi‐static and cyclic coupon tests are performed with patched metallic specimens and monitored with qualitative and comparative passive infrared thermography. Different test set‐ups help to differentiate between pure metallic crack growth and adhesive damage on thermal images. Results show that metallic crack growth can be monitored from the patched side, also in combination with local delamination at the patch/metal interface overlaying the crack. Thus, it is possible to evaluate position and size of the different damage types at the same time with a rather simple test set‐up. The information on the degradation progress of the crack patched component under loading conditions can help identify the driving damage mechanism of the particular repair configuration. This knowledge can in return be used in the patch design process.

“…• either the initial gradient of temperature is analysed during the beginning of the cycling 17,23,24 by assuming adiabatic condition (on a short duration), or at the end of the loading 25,26 ; • or, recently, De Finis et al 27 show that cyclic variations of temperature is linked with fatigue limit through the phase and amplitude of the first two harmonics; • else, the stabilized temperature after the increasing phase is handled by assuming a steady-state case ( _ T = 0 ), and so neglecting the thermal inertial term ρc _ T.…”

Section: Introductionmentioning

confidence: 99%

Thermographic approach for high cycle fatigue of seam welded steel joints under variable amplitude loadings

Pierron

Maïtournam

Raoult

2020

In the automotive field, welded joints are the weak points of the steel parts of the chassis in terms of fatigue. The fatigue strength of arc-welded parts is generally evaluated using fatigue tests under constant amplitude loadings designed according the Palmgren-Miner rule. In this paper, the relevance of this process is tested with an experimental campaign on welded specimens subjected to various variable amplitude loads. In addition, to solve the recurrent issue of lack of fatigue data, a thermographic method is investigated as an alternative for monitoring the damage rate evolution. A theoretical thermal model is proposed to estimate a local heat source from the infrared thermal measurements during constant and variable amplitude loading tests. This heat source is shown to be correlated with fatigue damage, which provides a further insight on the evolution of damage during nonconstant amplitude fatigue tests.