Temperature evolution in magnesium alloy during static and cyclic loading

Yan, Zhifeng; Zhang, H. X.; Wang, W. X.; He, Xiao; Liu, X. Q.

doi:10.1179/1743284713y.0000000442

Cited by 7 publications

(5 citation statements)

References 18 publications

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“…Then, the temperature rise started to drop rapidly from about 30 s. Finally, at about 400 s, the temperature evolution began to enter a relatively stable stage. This stable stage will continue until macro fatigue cracks are initiated [ 32 ]. The macroscopic fatigue crack will grow rapidly after initiation.…”

Section: Resultsmentioning

confidence: 99%

Fatigue Performance Evaluation of AZ31B Magnesium Alloy Based on Statistical Analysis of Self-Heating

et al. 2021

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AZ31B magnesium alloy is the experimental material in this study. Considering its anisotropy, fatigue assessment based on self-heating is carried out for both the extrusion direction and the transverse direction. The self-heating behavior in the two orientations is compared. Similar to steels, an obvious inflection point that corresponds to the fatigue limit can be found in the self-heating vs. load curve for AZ31B. A new fatigue limit assessment method is proposed based on a statistical analysis of self-heating data. This method can provide a satisfactory assessment of the fatigue limit for AZ31B in the both orientations.

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Section: Resultsmentioning

confidence: 99%

Fatigue Performance Evaluation of AZ31B Magnesium Alloy Based on Statistical Analysis of Self-Heating

et al. 2021

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“…The rate of energy release increases when the load exceeds the fatigue limit, because of the change caused by damage [9,33]. Viscoelasticity deformation was the main form of deformation when the load was lower than the fatigue limit.…”

Section: Fatigue Limit Estimationmentioning

confidence: 99%

“…This method is time-consuming, as it requires testing a large number of specimens at different load levels. Infrared thermography-based methodologies were later employed to overcome this fundamental limitation and to facilitate the rapid determination of fatigue limit [9,10]. Risitano et al developed a thermographic method (TM) to establish the fatigue limit [11].…”

Section: Introductionmentioning

confidence: 99%

Rapid evaluation of fatigue limit in AZ31B magnesium alloy using acoustic emission

Yan

Dong

et al. 2018

Materials Science and Technology

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Acoustic emission (AE) was used in a fatigue experiment to characterise AE signals and to rapidly determine the fatigue limit of AZ31B magnesium (Mg) alloy. The AE signals during fatigue were characterised according to waveforms and frequency. Meanwhile, the energy dissipation in the process of fatigue, which was represented by the accumulative AE energy, can be used to determine the fatigue limit. Based on the AE parameters, the fatigue limit was 97 MPa, with an 8% error value when compared with the results obtained by the conventional S–N curve method. This model only requires the accumulated energy of the signals during strain hardening. Therefore, the fatigue limit can be determined rapidly.

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“…Stage III is the stable phase, and the nonelastic effect and heat conduction can reach the dynamic equilibrium. 26 In stage IV, microcrack initiates and expands speedy with the cyclic cycles, meanwhile, the crack tip produces a localised plastic deformation, leading to a rapid temperature rise until the specimen fracture. In the last stage, the sample is gradually cooled to room temperature.…”

Section: Temperature Evolution Under High Cycle Fatiguementioning

confidence: 99%

Cyclic hardening/softening behaviour in AZ31B magnesium alloy based on infrared thermography

Wang

Zhang

Yan

et al. 2016

Materials Science and Technology

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The work-hardening/softening behaviour of AZ31B magnesium alloy during high cycle fatigue was investigated. The superficial temperature evolution during fatigue tests was used as a criterion for the different levels of work-hardening/softening. The microstructures under different cycles were observed by transmission electron microscope. Tensile test (with post-fatigue) was conducted to quantify the work-hardening/softening behaviour which showed that high dislocation density after cyclic loading lead to high tensile strength. The temperature evolution of the specimens with different levels of work-hardening/softening during tensile tests is related to the microstructures; the results indicated that the temperature rise of the specimen with high density dislocation was lower. Microstructures after tensile tests showed that high dislocation density after cyclic loading would lead to high twinning density.

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Temperature evolution in magnesium alloy during static and cyclic loading

Cited by 7 publications

References 18 publications

Fatigue Performance Evaluation of AZ31B Magnesium Alloy Based on Statistical Analysis of Self-Heating

Fatigue Performance Evaluation of AZ31B Magnesium Alloy Based on Statistical Analysis of Self-Heating

Rapid evaluation of fatigue limit in AZ31B magnesium alloy using acoustic emission

Cyclic hardening/softening behaviour in AZ31B magnesium alloy based on infrared thermography

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