A New Approach for Severity Estimation of Transversal Cracks in Multi-layered Beams

Gillich, Gilbert-Rainer; Maia, N. M. M.; Mituletu, Ion-Cornel; Tufoi, Marius; Iancu, Vasile; Korka, Zoltan-Iosif

doi:10.1590/1679-78252541

Cited by 17 publications

(9 citation statements)

References 9 publications

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“…From paper [15], the beam's free end deflection for the healthy and damaged state is expressed by the mathematical relations:…”

Section: The Finite Element Model Of the Test Structurementioning

confidence: 99%

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Numerical study on complex shaped cracks in cantilever beams concerning frequency and stiffness changes

Tufiși¹,

Gillich²,

Nedelcu³

et al. 2018

Vib. proced.

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The paper presents a mathematical relation to express the effects of a T-shaped crack on beam-like structures. The study is performed by using the finite element method (FEM) and contrived analytical formulas for proving the existing correlation between deflection, strain energy, and natural frequency changes. The damaged beam static and dynamic behaviors are analyzed by means of the FEM. The frequency shift for the first mode of vibration derived directly was compared with the frequency alteration calculated involving the change in the beam deflection for several scenarios of the T-shaped crack. The frequency shift is derived using the relations between deflection and natural frequency. As the final step in the research, we compared the outcomes for the same crack with the results achieved from a beam suffering a loss of stiffness.

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“…From paper [15], the beam's free end deflection for the healthy and damaged state is expressed by the mathematical relations:…”

Section: The Finite Element Model Of the Test Structurementioning

confidence: 99%

“…In previous studies [15][16][17][18], the authors developed a robust method for detecting, locating and evaluating transverse cracks in all types of beams, regardless of the constraining method, based on the natural frequency changes.…”

Section: Introductionmentioning

confidence: 99%

Numerical study on complex shaped cracks in cantilever beams concerning frequency and stiffness changes

Tufiși¹,

Gillich²,

Nedelcu³

et al. 2018

Vib. proced.

Self Cite

View full text Add to dashboard Cite

show abstract

“…In our previous research we approached this topic and found a relation to express the frequency of cracked beams in respect to the damage severity [9] - [11]. The severity is found involving Castigliano's second theorem [12], and it was shown that the severity does not directly depend on the moment of inertia of the damaged cross-section [13].…”

Section: Introductionmentioning

confidence: 99%

Estimation of the severity of damage produced by a transverse crack

Pop

2020

Studia UBB Engineering

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This paper presents a method to find the severity of a crack for cantilever beams that can be used to estimate the frequency drop due to the crack. The severity is found for the crack located at the location where the biggest curvature (or bending moment) is achieved. Because the fixing condition does not permit a symmetrical deformation around the crack, the apparent severity is smaller as the real one. The latter is found by the estimated value of the trend-line at the fixed end, it being constructed on points that consider the crack position (equidistant points in the proximity of the fixed end) and the resulted deflections.

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“…In this point, it is worth-mentioning that previous works has introduced damage estimators as a function of the strain energy. For instance, Gillich et al expressed the damage severity produced by cracks located in a cantilever, multi-layered beam as a function of the stored energy, in order to study the influence of the crack depth on the natural frequency ship at several longitudinal positions of the beam (Gillich et al 2016). Accurate results were obtained in that work for some vibration modes when compared to experiments.…”

Section: Introductionmentioning

confidence: 99%

Fragmentation model for the tensile response of unidirectional composites based on the critical number of fiber breaks and the correction of the fiber-matrix interfacial strength.

Vanegas-Jaramillo

Patiño-Arcila

2019

Lat. Am. j. solids struct.

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A fragmentation model based on global load sharing (GLS) theory is developed to obtain stress-strain curves that describe the mechanical behavior of unidirectional composites. The model is named + * because it is based on the Critical Number of Breaks model (CNB) and on the correction of the fiber matrix interfacial strength, *. Model allows both obtaining the ultimate tensile strength of CFRP and GFRP composites, and correcting the vs curve to match its peak point with the predicted strength, which is more accurate than the one obtained by previous GLS-based models. Our model is used to classify the mechanical response of the material according to the energetic contributions of two phenomena up to the failure: intact fibers (IF) and fragmentation (FM). Additionally, the influence of fiber content, , on the tensile strength, , failure strain, , and total strain energy, , is analyzed by means of novel mechanical-performance maps obtained by the model. The maps show a dissimilar behavior of , and with between GFRP and CFRP composites. The low influence of on the percent energetic contributions of IF and FM zones, as well as the larger energetic contribution of the FM zone, are common conclusions that can be addressed for both kinds of composites.

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A New Approach for Severity Estimation of Transversal Cracks in Multi-layered Beams

Cited by 17 publications

References 9 publications

Numerical study on complex shaped cracks in cantilever beams concerning frequency and stiffness changes

Numerical study on complex shaped cracks in cantilever beams concerning frequency and stiffness changes

Estimation of the severity of damage produced by a transverse crack

Fragmentation model for the tensile response of unidirectional composites based on the critical number of fiber breaks and the correction of the fiber-matrix interfacial strength.

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