Assessment of Fatigue Life and Failure Criteria in Ultrasonic Testing Through Thermal Analyses

An experimental study was conducted to analyze temperature evolution during very high cycle fatigue tests. The temperature-number of cycles (T-N) curve is typically divided into three phases: Phase I-a rapid temperature increases at the start of the test, Phase II-temperature stabilization, and Phase III-a sharp temperature rise at the test's end, coinciding with specimen fracture. The high frequencies used in ultrasonic fatigue testing can induce self-heating in specimens, but the thermal effects are not yet fully understood. Temperature is known to influence the fatigue performance of materials. To explore this, specimens were subjected to varying stress levels and intermittent loading conditions while monitoring temperature evolution using infrared thermography. The T-N curves were obtained, and S-N curves were constructed for specimens tested at room temperature. All tests were performed under fully reversed loading conditions. The experimental data were used to evaluate models commonly applied in conventional fatigue testing. Additionally, the temperature gradient at the beginning of the ultrasonic fatigue test and the heat dissipation per cycle were estimated and analyzed as potential fatigue damage parameters. These findings indicate that parameters derived from the T-N curve have significant potential for predicting very high cycle fatigue life.