Issue 33

F. Iacoviello et alii, Frattura ed Integrità Strutturale, 33 (2015) 111-119; DOI: 10.3221/IGF-ESIS.33.15 111 Focussed on characterization of crack tip fields Fatigue crack tip damaging micromechanisms in a ferritic-pearlitic ductile cast iron Francesco Iacoviello, Vittorio Di Cocco Università di Cassino e del Lazio Meridionale, DICeM, via G. Di Biasio 43, 03043 Cassino (FR), Italy iacoviello@unicas.it , v.dicocco@unicas.it Mauro Cavallini Università di Roma “Sapienza”, DICMA, via Eudossiana 18, Rome, Italy mauro.cavallini@uniroma1.it A BSTRACT . Due to the peculiar graphite elements shape, obtained by means of a chemical composition control (mainly small addition of elements like Mg, Ca or Ce), Ductile Cast Irons (DCIs) are able to offer the good castability of gray irons with the high mechanical properties of irons (first of all, toughness). This interesting properties combination can be improved both by means of the chemical composition control and by means of different heat treatments(e.g. annealing, normalizing, quenching, austempering etc). In this work, fatigue crack tip damaging micromechanisms in a ferritic-pearlitic DCI were investigated by means of scanning electron microscope observations performed on a lateral surface of Compact Type (CT) specimens during the fatigue crack propagation test (step by step procedure), performed according to the “load shedding procedure”. On the basis of the experimental results, different fatigue damaging micromechanisms were identified, both in the graphite nodules and in the ferritic – pearlitic matrix. K EYWORDS . Ferritic-pearlitic ductile cast irons; Fatigue damaging mechanism; Crack tip. I NTRODUCTION uctile iron discovery in 1948 gave a new lease on life to the cast iron family. In fact, these cast irons (DCIs) combine the good castability of gray irons and high toughness values of steels and they are also characterized by an interesting fatigue crack propagation resistance. Considering their interesting mechanical properties, DCIs are widely used in the critical automotive parts (e.g., crankshafts, truck axles, etc.), and in many other application, like pumps, pipes or turbine components [1, 2]. DCIs can be considered as natural composites, with graphite nodules embedded in a metal matrix. The DCIs performances are strongly affected by the graphite elements morphological peculiarities (e.g., graphite elements nodularity, volume fraction, density, distribution, dimension). Different combinations of the mechanical properties can be obtained depending on the matrix microstructure [3]: ranging from ferritic to pearlitic DCIs, different combination of ductility or tensile strength values can be obtained (anyway, equivalent to the values offered by low carbon steels); martensitic DCIs are characterized by a very high strength, but low levels of toughness and ductility; bainitic grades are characterized by a high hardness; austenitic DCIs show good corrosion resistance, good strength and dimensional stability at high temperature; finally, austempered grades (ADI) show D