Issue34

B. Žužek et alii, Frattura ed Integrità Strutturale, 34 (2015) 160-168; DOI: 10.3221/IGF-ESIS.34.17 165 300°C fatigue failure at bending stress level of 330, 380 and 430 MPa occurred after approximately 120.000, 50.000 and 30.000 cycles, respectively. At the highest tempering temperature of 475°C fatigue life at given bending stress levels increased to approx. 170.000, 75.000 and 45.000 cycles. The number of bending cycles till failure at the same stress levels has been shortened for 10-15% when using ESR refinement, as clearly shown in Fig. 4. Figure 4 : Effect of ESR refinement and segregations removal on bending fatigue resistance. Effect of ESR process shown in microstructure refinement and segregations removal has even more negative effect on fatigue properties of spring steel under tensile-compression loading mode. However, these tests were carried out only for tempering temperature of 475°C. For the ESR test specimens tempered at 475°C fatigue failure at 660, 720 and 780 MPa stress level occurred after 29.000, 43.000 and 54.000 cycles, respectively. On the other hand, classical CCC specimens tempered at 475°C showed between 5 to 20% longer lifetime, lower scattering and about 5% higher tensile fatigue limit of 650 MPa, as shown in Fig. 5. These results indicate positive effect of elongated segregations being present in CCC spring steel on its fatigue resistance. However, this positive effect of segregations can be expected only when segregations are oriented perpendicular to the crack propagation direction. On the other hand, presence of some Al inclusions after ESR, as revealed by SEM microstructure analysis has further negative effect on the fatigue resistance of ESR refined spring steel, representing critical locations for crack initiation. Figure 5 : Tensile-compression fatigue properties of CCC and ESR spring steel, tempered at 475°C. Fractographic analysis Macrographic investigation of the fractured surfaces reveals positive effect of segregations on the crack propagation resistance. It is assumed that combination of softer sulphide-type non-metallic inclusions in positive segregations (fully martensitic) and harder negative segregations (martensite and bainite) in CCC specimens retard propagation of transversal crack, thus improving spring steel fatigue resistance. Fractured surfaces of both CCC and ESR samples are shown in Fig.