Issue 35

W. Ozgowicz et alii, Frattura ed Integrità Strutturale, 35 (2016) 11-20; DOI: 10.3221/IGF-ESIS.35.02 17 Figure 7 : Acoustic emission and stress during the deformation of CuSn6P alloy at 250  C after annealing. Figure 8 : Acoustic emission and stress during the deformation of CuSn6P alloy at 300  C after annealing. Fractures of the tested samples of tin bronzes after tensile tests in the temperature range (T E ÷TMP) have been presented in the microphotographs (Fig. 10 to 13). The temperature of deformation has been found to be the main factor determining the fractographs of the surfaces of the tested fractures of tin bronzes. Annealed and continuously cast bronze CuSn6P displays in the range of the temperature of transition from ductility to brittleness (T E ) a mixed fracture with a considerable share of smooth cleavage surfaces (Fig. 10), characteristic for brittle intercrystalline cracking. The share of ductile surfaces in the fracture (Fig.11) drops considerably with the rise of the temperature of deformation. In the range T E on intercrystalline surfaces there occur distinct traces of plastic deformation and cavitation (Fig.10 and 11). It has been found that deformation in the range of TMP (about 400  C) leads to the formation of a fracture on the fully intercrystalline brittle surface (Fig.12, 13). Intercrystalline cracking encountered on boundary surfaces at the contacts of two or three grains (Fig. 13) usually runs across the pores of cavitations, which is typical for cast structures. Moreover, it has been found that intercrystalline fissures mostly nucleate in the vicinity of microvoids at the grain boundaries and on intersections twins or bands of deformations and the grain boundaries.