Comprehensive Modelling of the Hysteresis Loops and Strain–Energy Density for Low-Cycle Fatigue-Life Predictions of the AZ31 Magnesium Alloy

Klemenc, Jernej; Šeruga, Domen; Nagode, Aleš; Nagode, Marko

doi:10.3390/ma12223692

Cited by 11 publications

(12 citation statements)

References 35 publications

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“…AZ31 alloy showed cyclic softening at 150 C in the tensile region of the hysteresis loop whereas cyclic hardening was observed in the tensile region at room temperature tests in previous studies. [21][22][23] On the contrary, cyclic hardening was obtained in the compressive region of the hysteresis loop at 150 C which corresponded to the observations at room temperature [21][22][23] (Figure 8A).…”

Section: Resultssupporting

confidence: 78%

Determination of Stress–Strain Behaviour of Magnesium Alloy AZ31 under Variable Thermomechanical Loading

Šeruga

Bešter

Nagode

et al. 2021

Fatigue Fract Eng Mat Struct

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Growing environmental demands and higher fuel efficiency encourage the use of new light‐weight load‐bearing materials even for operation under rougher environmental conditions. Consequently, as the materials used in the vital load‐bearing components of the chassis, brake system or exhaust system are subjected to thermomechanical fatigue during the operation due to variable mechanical and thermal loads, it is crucial for design engineers and CAE analysts to understand the cyclic behaviour of new materials under such conditions. Here we have analysed the stress–strain behaviour of magnesium alloy AZ31 and the influence of variable thermomechanical loads. A uniaxially loaded flat specimen has been first mechanically loaded at −25°C. The temperature was then increased to 150°C whilst the variable mechanical loading remained unchanged. The tests have been strain‐controlled using a video extensometer. The stress–strain behaviour of the magnesium alloy AZ31 has been then investigated considering both variable temperature and variable mechanical load.

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Section: Resultssupporting

confidence: 78%

Determination of Stress–Strain Behaviour of Magnesium Alloy AZ31 under Variable Thermomechanical Loading

Šeruga

Bešter

Nagode

et al. 2021

Fatigue Fract Eng Mat Struct

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“…Fatigue life prediction using strain‐energy density approaches has been studied by several researchers, 17,18,23,37,43,44 and is essential in the case of strain‐controlled fatigue tests, as the plastic strain amplitude plays a dominant role in determining fatigue behavior, including the nature of fatigue damage. Wang et al 17,23 proposed a strain‐energy density expression for Al–Si hypereutectic piston alloy fatigued at room and elevated temperatures, considering the concept of accumulated damage, and found that the expression was linked to fatigue life ( N f ) nicely.…”

Section: Discussionmentioning

confidence: 99%

Cyclic deformation behavior and fatigue life prediction of an automotive cast aluminum alloy: A new method of determining intrinsic fatigue toughness

Zeng

et al. 2021

Fatigue Fract Eng Mat Struct

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The aim of this study was to identify cyclic deformation behavior of a high‐pressure die‐cast Silafont®‐36 automotive cast aluminum alloy consisting of heterogeneous composite‐like microstructures of nearly circular eutectic silicon particles embedded in Al matrix, with particular attention to fatigue life prediction. The alloy exhibited superior fatigue resistance at higher strain amplitudes, where cyclic hardening occurred. The fatigue life of the alloy could be well predicted via a strain‐energy density based accumulative damage model using a new method proposed to calculate the intrinsic fatigue toughness. The predicted fatigue life was in good agreement with the experimental life, and also lay in‐between the results obtained via other methods. Fatigue crack initiation was observed to occur from the sample surface or near‐surface defects and crack propagation was characterized by fatigue striations along with tear ridges in the primary Al‐grains.

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“…In applications that use aluminium alloys frequently, it is necessary to understand the fatigue performance of the components and the effects of operating parameters on the fatigue behaviour of the analysed constructional components. A fatigue assessment can be carried out using the stress–life (S–N) or the strain–life approach, depending on whether stresses in the critical cross-sections of the analysed component are in the elastic or plastic areas [ 15 , 16 ]. In the case that only elastic stresses occur, the S–N approach is usually used to obtain the fatigue life up to the final failure of the component.…”

Section: Introductionmentioning

confidence: 99%

High-Cycle Fatigue Behaviour of the Aluminium Alloy 5083-H111

et al. 2023

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This study presents a comprehensive experimental investigation of the high-cycle fatigue (HCF) behaviour of the ductile aluminium alloy AA 5083-H111. The analysed specimens were fabricated in the rolling direction (RD) and transverse direction (TD). The HCF tests were performed in a load control (load ratio R = 0.1) at different loading levels under the loading frequency of 66 Hz up to the final failure of the specimen. The experimental results have shown that the S–N curves of the analysed Al-alloy consist of two linear curves with different slopes. Furthermore, RD-specimens demonstrated longer fatigue life if compared to TD-specimens. This difference was about 25% at the amplitude stress 65 MPa, where the average fatigue lives 276,551 cycles for RD-specimens, and 206,727 cycles for TD-specimens were obtained. Similar behaviour was also found for the lower amplitude stresses and fatigue lives between 106 and 108 cycles. The difference can be caused by large Al6(Mn,Fe) particles which are elongated in the rolling direction and cause higher stress concentrations in the case of TD-specimens. The micrography of the fractured surfaces has shown that the fracture characteristics were typical for the ductile materials and were similar for both specimen orientations.

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Comprehensive Modelling of the Hysteresis Loops and Strain–Energy Density for Low-Cycle Fatigue-Life Predictions of the AZ31 Magnesium Alloy

Cited by 11 publications

References 35 publications

Determination of Stress–Strain Behaviour of Magnesium Alloy AZ31 under Variable Thermomechanical Loading

Determination of Stress–Strain Behaviour of Magnesium Alloy AZ31 under Variable Thermomechanical Loading

Cyclic deformation behavior and fatigue life prediction of an automotive cast aluminum alloy: A new method of determining intrinsic fatigue toughness

High-Cycle Fatigue Behaviour of the Aluminium Alloy 5083-H111

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