Issue 13

F. Iacoviello et alii, Frattura ed Integrità Strutturale, 13 (2010) 3-16; DOI: 10.3221/IGF-ESIS.13.01 10 SEM fracture surface analisys Ferritic DCI fracture surface is characterized by the presence of secondary cracks (Fig. 33) with some cleavage of ferritic grains (Fig. 34) . Graphite nodules on fracture surface are partially disintegrated (Fig. 34), with evident residual graphite in cavities. (Fig. 35) . Partial disintegration is confirmed both by the presence of damaged nodules (Fig. 36, point 1 and Fig. 37) and by the presence of residual graphite (Fig. 36, point 2). All the observed fracture morphologies are not influenced by the loading conditions (R and/or  K values). Figure 33 : Ferritic DCI (R = 0.1,  K = 10 MPa√m). Figure 34 : Ferritic DCI (R = 0.1,  K = 12 MPa√m). Figure 35 : Ferritic DCI (R = 0.1,  K = 19 MPa√m). Figure 36 : Ferritic DCI (R = 0.5,  K = 9 MPa√m). Figure 37 : Ferritic DCI (R = 0.75,  K = 11 MPa√m). Few secondary cracks are observed in pearlitic DCI and their length is really reduced (e.g., Fig. 38). Also cleavage importance is really reduced (Fig. 39, white arrow) : striations are the main observed fatigue crack propagation micromechanisms (figur e Fig. 39 and 40) . The definition of this morphology as “striations” is not absolutely correct: in fact, considering the results obtained in crack profile analysis, the observed morphology is due to the fracture of pearlite lamellae during the fatigue crack propagation. Also rare “cleavage” is due to pearlite lamellae delamination and not to an effective cleavage mechanism (compare Fig. 24 w ith Fig 39) . Focusing graphite nodules debonding, neither residual graphite nor graphite nodules disintegration are observed. Considering the ferritic-pearlitic DCI GJS500-7, fracture surfaces are characterized by the presence of an evident cleavage in ferritic shields around the graphite nodules (Fig. 41, 42, 43) . Analogously to the ferritic DCI, graphite nodules are characterized by a partial disintegration, with residual graphite in cavities; analogously to the pearlitic DCI, secondary cracks are almost absent. Also for this DCI, “striations” are manly connected to a delamination mechanism of pearlite lamellae. Focusing the ferritic-pearlitic DCI obtained by means of an annealing of a pearlitic DCI, and considering the different distribution of ferritic grains and pearlitic colonies if compared to GJS500-7, cleavage around graphite nodule is absent, with graphite nodules that could be both partially disintegrated (Fig. 44) and absolutely sound (Fig. 45, 46). No residual graphite in cavities is observed. Also ADI fracture surface, with its bainitic microstructure, is characterized by the presence of delamination (Fig. 47). Graphite nodules could be sometimes partially disintegrated (Fig. 47) , but an absolutely sound shape is more frequent (Fig. 48, 49), with an evident ductile and “clean” matrix-nodules debonding. Secondary cracks are absent or really short.

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