Issue 35

W. Ozgowicz et alii, Frattura ed Integrità Strutturale, 35 (2016) 11-20; DOI: 10.3221/IGF-ESIS.35.02 15 Table 2 : Contractual coefficients of the shape of the curves  -ε with the effect PLC concerning the CuSn6P alloy. The temperature of tensile tests determines also the fundamental characteristics of mechanical properties of the investigated alloy. With the rise of temperature the strength of the alloy distinctly decreases, slightly also a monotonous drop of the value of the yield point can be observed (Fig. 4). Tensile tests also proved that the plastic properties of the investigated bronze become distinctly worse (Fig.5) in the range of equicohesive temperature (T E ), which determines the transition of the alloy from the ductile state to brittleness , independent of the state in which the samples were provided for the purpose of being tested. The mean values of the reduction of area (Z) by about 70% in the range of the temperature of deformation (20÷400  C) decreases to about 10% at about 300  C. The shape of the function Z = f(T def ) indicates a distinct relation between thermally activated phenomena and the intensity of the instability of the PLC-type of plastic deformation, as well as the phenomena which control the brittleness of the alloy in the temperature range T E . Figure 4 : The dependence of the reduction in area on the temperature of stretching of the CuSn6P alloy in varying states of delivery. Figure 5 : The influence of the temperature on the tensile properties of industrial bronze CuSn6P in various metallurgical states The results of measurements of the acoustic emission (AE) in tensile tests of the bronze CuSn6P within the range of temperature from 20  C to 400  C with a strain rate of 1.2·10 -3 sec -1 have been presented in the diagrams (Fig.6 to 8) and Tab. 3. In most tensile tests the activity AE increased distinctly in the elastic range of curves σ-ε and also in the range of the transition from the elastic to the plastic state (Fig.6). The growth of the activity AE is in these cases characterized by a more or less wide maximum of changes of the energy of the signals, after which AE is at its minimum. This growth may be caused by such mechanical factors as friction and the matching of the sample in the clamps of the strength machine. In the range of the yield point, however, the observed growth of activity AE of the signal displays a physical character, connected with processes of the motion of dislocation. It has been found that the level of AE of the investigated bronze No. Temperature of deformation ε c [%] Coefficients of the shape of curves  -ε in the range (ε max -10% < ε <ε max ) R L A f Oscillation type CuSn6P after continuous casting 1 150 17 1.67 1.97 3.29 A+B 2 200 5 2.68 3.37 9.05 B+C 3 250 1 4.92 3.02 14.87 B 4 300 1.5 5.74 2.36 13.56 B+C CuSn6P in the annealed state 5 150 34 2.35 3.57 8.41 A+B, 6 200 1 5.93 3.12 18.52 A+B, B, C 7 250 1.5 6.00 3.87 23.23 A+B, B 8 300 2 5.70 1.73 9.88 B+C