Prediction of Fatigue Crack Growth Rate Based on Entropy Generation

Idris, Rubia; Abdullah, Shahrum; Thamburaja, T Prakash G.; Omar, Mohd Zaidi

doi:10.3390/e22010009

Cited by 12 publications

(9 citation statements)

References 68 publications

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“…Sato et al reported that the fracture entropy generation of TriA-X polyimide was ~15.5 kJ/m 3 K [11]. Entropy-based damage evaluation has been experimentally confirmed for metallic [12][13][14], polymeric [9], and composite materials [15][16][17][18]. In the following, we distinguish between thermal and mechanical entropies.…”

Section: Introductionmentioning

confidence: 90%

A Possibility for Quantitative Detection of Mechanically-Induced Invisible Damage by Thermal Property Measurement via Entropy Generation for a Polymer Material

et al. 2022

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Entropy generation from a mechanical and thermal perspective are quantitatively compared via molecular dynamic (MD) simulations and mechanical and thermal experiments. The entropy generation values regarding mechanical tensile loading—which causes invisible damage—of the Polyamide 6 (PA6) material are discussed in this study. The entropy values measured mechanically and thermally in the MD simulation were similar. To verify this consistency, mechanical and thermal experiments for measuring entropy generation were conducted. The experimentally obtained mechanical entropy was slightly less than that calculated by MD simulation. The thermal capacity is estimated based on the specific heat capacity measured by differential scanning calorimetry (DSC), applying the assumed extrapolation methods. The estimated entropy generation was higher than the aforementioned values. There is a possibility that the entropy-estimating method used in this study was inappropriate, resulting in overestimations. In any case, it is verified that entropy increases with mechanical loading and material invisible damage can be qualitatively detected via thermal property measurements.

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Section: Introductionmentioning

confidence: 90%

A Possibility for Quantitative Detection of Mechanically-Induced Invisible Damage by Thermal Property Measurement via Entropy Generation for a Polymer Material

et al. 2022

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“…Recientemente, se han propuesto enfoques experimentales para evaluar la propagación de grietas [6,7], principalmente a partir del desarrollo de las técnicas modernas de medición de la temperatura, la cual, como se reporta ampliamente en la literatura [8][9][10][11][12], se puede correlacionar con la propagación de grieta por fatiga debido a que una gran variedad de estudios demuestran que, en la mayoría de los materiales metálicos, la energía de histéresis por deformación plástica se convierte en calor, como se reportó en el trabajo de Meneghetti et al [13].…”

Section: Antecedentesunclassified

“…Resultados de trabajos recientes demuestran que, a medida que crece la grieta, hay un aumento de la temperatura superficial de la probeta, lo cual plantea la necesidad de comprender los fenómenos físicos en la propagación de grietas por fatiga desde el punto de vista de la Termodinámica. Un ejemplo es el trabajo de Idris et al [19], quienes midieron simultáneamente la temperatura y la longitud de la grieta durante los Revista de Ciencias Tecnológicas (RECIT). Volumen 6 (1): 14-27 ensayos de crecimiento de grietas por fatiga hasta la ruptura, bajo condiciones de carga de amplitud constante y variable.…”

Section: Antecedentesunclassified

Relación entre el crecimiento y la temperatura en la punta de la grieta por fatiga en acero AISI 1018

et al. 2023

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En este artículo se presenta un estudio sobre la relación que existe entre el comportamiento del crecimiento de grieta por fatiga y la evolución de la temperatura en la punta de grieta en un acero AISI 1018. Tanto la longitud de la grieta como la temperatura se obtuvieron experimentalmente de ensayos de fatiga de acuerdo a la norma ASTM E647. La temperatura se midió simultáneamente a través de termopares y termografía infrarroja, mientras que la longitud de la grieta se midió a través de un microscopio. Los datos experimentales se procesaron para obtener curvas de ciclos contra temperatura y ciclos contra longitud de grieta para posteriormente correlacionar la información y obtener, por regresión lineal de los datos experimentales, un modelo para relacionar la temperatura con la longitud de la grieta. Los resultados muestran que el modelo propuesto está en buena concordancia con los datos experimentales y permite estimar la tendencia y la magnitud de la temperatura al crecer la grieta.

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“…T m is the mean temperature, k is the thermal conductivity, a y is a parameter obtained by parabolic curve fitting to the temperature profile, ρ is the density, C is the heat capacity, h G is the global heat transfer coefficient, S conv is exchange surface, V spe is the specimen volume. Roslinda Idris et al [95] proposed an entropy-based model to predict the fatigue crack growth rate for dual-phase steel under spectrum loading. They monitored the crack length and temperature evolution during the fatigue crack test until failure to validate the estimation.…”

Section: Models Using Irreversible Entropy As a Metric With An Empiri...mentioning

confidence: 99%

A Review of Damage, Void Evolution, and Fatigue Life Prediction Models

Lee

Basaran

2021

Metals

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Degradation, damage evolution, and fatigue models in the literature for various engineering materials, mostly metals and composites, are reviewed. For empirical models established under the framework of Newtonian mechanics, Gurson–Tvergaard–Needleman (GTN) type model, Johnson-Cook (J-C) type damage model, microplasticity model, some other micro-mechanism based damage models, and models using irreversible entropy as a metric with an empirical evolution function are thoroughly discussed. For Physics-based models, the development and applications of unified mechanics theory is reviewed.

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Prediction of Fatigue Crack Growth Rate Based on Entropy Generation

Cited by 12 publications

References 68 publications

A Possibility for Quantitative Detection of Mechanically-Induced Invisible Damage by Thermal Property Measurement via Entropy Generation for a Polymer Material

A Possibility for Quantitative Detection of Mechanically-Induced Invisible Damage by Thermal Property Measurement via Entropy Generation for a Polymer Material

Relación entre el crecimiento y la temperatura en la punta de la grieta por fatiga en acero AISI 1018

A Review of Damage, Void Evolution, and Fatigue Life Prediction Models

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