Abstract
Fatigue crack growth (FCG) experiments were performed using a low-temperature extruded magnesium alloy AZ31 with texture. Under a constant maximum stress intensity factor (Kmax), the stress ratio R was changed from 0.1 to −1 during the fatigue crack growth process, and the FCG behavior before and after the R change was investigated. As a result, tensile twins were generated owing to the fatigue load on the compression side of R = −1, and the FCG velocity was accelerated. In addition, when the maximum compressive stress at R = −1 (|(σmin)R = −1|) exceeded the compressive yield strength of the material (σcy), the FCG velocity after R fluctuation greatly accelerated. On the other hand, under the condition |(σmin)R = −1| < σcy, the degree of acceleration of the FCG velocity due to R fluctuation was small. In either case, the degree of acceleration in the FCG increased as the Kmax value increased. The above FCG acceleration mechanism due to the R fluctuation was considered based on the observation of the deformation and twinning states of the fatigue crack tip, the fatigue crack closure behavior, and the cyclic stress–strain curve of the fatigue process. The FCG acceleration mechanism was as follows: First, the driving force of the FCG increased owing to the increase in crack opening displacement due to the generation of tensile twins. Second, the coalescence of the main crack and a plurality of microcracks were generated at the twin interface. The elasto-plastic FCG behavior after the stress ratio fluctuations is defined by the effective J-integral range ΔJeff.
Highlights
Publisher’s Note: MDPI stays neutralMagnesium (Mg) alloys are the lightest of all practical metals and have excellent properties such as specific strength, vibration absorption, and recyclability [1]
MDPI stays neutralMagnesium (Mg) is available because it is distributed worldwide in a variety of minerals. This alloy is inferior in cost and corrosion resistance [1]
The single-edge notched tensile (SENT) specimens had a sharp notch with a length of 4 mm on one tensile side; and(SENT)
Summary
Magnesium (Mg) alloys are the lightest of all practical metals and have excellent properties such as specific strength, vibration absorption, and recyclability [1]. Mg is available because it is distributed worldwide in a variety of minerals. This alloy is inferior in cost and corrosion resistance [1]. There has been an increasing momentum to use Mg alloys as structural materials to reduce the environmental load and save energy in equipment. The use of wrought materials, such as extruded and rolled materials, is expected because of their excellent mechanical properties and few defects
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