Temperature evolution and fatigue life evaluation of AZ31B magnesium alloy based on infrared thermography
(College of Material Science and Engineering, Taiyuan University of Technology, Taiyuan 030024, China)
Abstract: The surface temperature of extruded AZ31B alloy plate was measured by infrared thermograph in air during tension and high-cycle fatigue tests. The mechanism of heat production was discussed and the value of critical fatigue damage temperature was calculated according to the P—?T curve. Results show that the variation trend of temperature is different between tension and fatigue tests. The temperature evolution in tension test consists of four stages: linear decrease, reverse linear increase, abrupt increase, and final drop. The initial decrease of temperature is caused by thermal elastic effect, which is corresponding to the elastic deformation in tension progress. When cyclic loading is above the fatigue limit, the temperature evolution mainly undergoes five stages: initial increase, steep reduction, steady state, abrupt increase, and final drop. The peak temperature in fatigue test is caused by strain hardening that can be used to evaluate the fatigue life of magnesium alloy. The critical temperature variation that causes the fatigue failure is 3.63 K. When ?T≤3.63 K, the material is safe under cyclic loading. When ?T>3.63 K, the fatigue life is determined by cycle index and peak temperature.
Key words: AZ31B magnesium alloy; high-cycle fatigue; thermographic analysis; temperature evolution