Thermoelastic Stress and Damage Analysis Using Transient Loading

Fruehmann, R.K.; Dulieu-Barton, J.M.; Quinn, Simon

doi:10.1007/s11340-009-9295-9

Cited by 15 publications

(21 citation statements)

References 6 publications

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“…TSA maps the surface stresses in a material based on small temperature variations measured by an infrared (IR) detector while the material is dynamically loaded [5,9]. Cracks or damage can therefore be located due to the indicative stresses present, which has been exploited previously in a range of studies [10][11][12][13][14][15]. The position of the crack is often determined from the phase profile along the line of the crack, which requires knowledge of the crack location and orientation [10][11][12].…”

Section: Introductionmentioning

confidence: 99%

Towards Automated Tracking of Initiation and Propagation of Cracks in Aluminium Alloy Coupons Using Thermoelastic Stress Analysis

Middleton

Gaio

Greene³

et al. 2019

J Nondestruct Eval

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Full-field non-destructive evaluation techniques are useful tools for indicating damage in fatigue-prone environments. Here, the full-field technique thermoelastic stress analysis (TSA) is employed to locate and track naturally initiating cracks in aluminium alloy specimens. An algorithm, based on the concept of optical flow, is used to track changes in the characteristic stress field present ahead of a crack during loading, and thereby to locate the crack-tip position. The initiation of cracks is indicated at sub-mm lengths, before the crack is observable by visual inspection, and in bolted specimens TSA indicates the presence of a crack before it extends beyond the bolt-head. The crack path propagation is mapped and matches well with the final crack geometry. Results are equivalent for surfaces prepared with matt black and aircraft primer paint, showing that optical flow processing of TSA data would be particularly useful for crack tracking in aerospace applications, as no additional surface preparation would be required to implement full-field TSA measurements.

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Section: Introductionmentioning

confidence: 99%

Towards Automated Tracking of Initiation and Propagation of Cracks in Aluminium Alloy Coupons Using Thermoelastic Stress Analysis

Middleton

Gaio

Greene³

et al. 2019

J Nondestruct Eval

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show abstract

“…However, it is believed that the strain induced in an artefact by a defined, reproducible loading condition is the most directly related to the structural integrity, because structural failure is a consequence of the strain induced by the loads in service. Therefore, the approach pioneered by, for example, Findeis et al, 21 Fruehmann et al 24 and Emery and Dulieu-Barton, 25 offer tremendous potential and should be combined with the quantitative comparison methodology based on image decomposition and a similarity measure, as for the validation process.…”

Section: Discussionmentioning

confidence: 99%

On the integration of validation, quality assurance and non-destructive evaluation

Patterson

Feligiotti

Hack

2012

The Journal of Strain Analysis for Engineering Design

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Experimental strain analysis, structural health monitoring and non-destructive testing and evaluation are regarded as separate disciplines that, in general, are deployed independently at different phases in the life cycle of an engineering component, i.e. in the design process, in service and after an event or service period, respectively. It is proposed that the integrated use of these three disciplines is advantageous and beneficial in terms of reduced capital and operational costs for critical and safety-relevant components, as well as, in validating simulations, in both quantifying and reducing risk of unexpected failure, and in estimating remanent life. We propose the foundation of this integration to be data-rich strain fields measured and compared quantitatively, with each other and with data from simulations, at temporal intervals during the life of a component.

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“…If the emissivity of the body is known and if the camera has been calibrated, the thermal field on the specimen surface can be obtained using the infrared camera. During mechanical testing, the temperature of the specimen varies with the intensity of the applied load on the one hand and with the appearance of dissipative phenomena on the other hand. As was mentioned, to obtain a quantitative measurement, the infrared camera has to be calibrated for each camera configuration (frequency, integration time, objective, etc.).…”

Section: Methodsmentioning

confidence: 99%

Passive infrared thermography measurement of transverse cracking evolution in cross‐ply laminates

Berthe

Ragonet

2018

Strain

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Over the last decades, various experimental methodologies have been used to study the matrix crack density evolution in cross-ply laminates. The main drawback of these techniques is their difficult use at intermediate and high strain rates. In this study, a new experimental protocol to evaluate matrix crack density evolution at intermediate strain rates is proposed and applied to [0∕90 3 ] s carbon/epoxy laminate. It is based on the use of passive infrared thermography to monitor the matrix cracking appearance. This methodology is used to first demonstrate that the crack appearance in the 90 • ply remains instantaneous from side to side with the increase of the strain rate. Finally, the rate insensitivity of the crack density as a function of the applied stress for the studied material in the studied range of strain rates (8.3 × 10 −4 up to 6.69 × 10 −2 s −1 ) is demonstrated. KEYWORDScomposite materials, crack density, infrared thermography, strain rate dependency, transverse cracking Strain. 2018;54:e12293.wileyonlinelibrary.com/journal/str

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Thermoelastic Stress and Damage Analysis Using Transient Loading

Cited by 15 publications

References 6 publications

Towards Automated Tracking of Initiation and Propagation of Cracks in Aluminium Alloy Coupons Using Thermoelastic Stress Analysis

Towards Automated Tracking of Initiation and Propagation of Cracks in Aluminium Alloy Coupons Using Thermoelastic Stress Analysis

On the integration of validation, quality assurance and non-destructive evaluation

Passive infrared thermography measurement of transverse cracking evolution in cross‐ply laminates

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