Study on phase transformation behavior and mechanical properties of equiatomic ratio NiTi alloy formed by selective laser melting

PurposeThis paper aims to better control the mechanical properties and functional properties of NiTi alloy. Design/methodology/approachNiTi alloy samples with equal atomic ratio were formed by selective laser melting (SLM). X-ray diffraction (XRD), differential scanning calorimetry (DSC), scanning electron microscopy and tensile testing methods were used to study the effects of different laser power and scanning speed on the densification behavior, phase transformation characteristics and mechanical properties of NiTi alloy. FindingsCompared with the laser power, the variation of the keyhole effect caused by the change of scanning speed is more intense, which has a greater effect on the densification behavior of SLM NiTi alloy. The effect of the laser power on the phase transition temperature is small. The increase of scanning speed weakens the burning degree of Ni element, so phase transition temperature decreases. The results of DSC test and tensile test show that the scanning velocity can significantly change the phase transition temperature, martensite twins reorientation and stress-strain behavior of SLM NiTi alloy. Originality/valueThis study provides a potential method to regulate the mechanical properties and functional properties of NiTi shape memory alloy in the future and NiTi alloys formed by SLM with good elongation were obtained because the Supercellular crystal structure formed during the nonequilibrium solidification of SLM and the superfine precipitates dispersed in the alloy prevented the dislocation formation.

Automated summary

The aim of this study is to investigate the control of mechanical properties and functional properties of NiTi alloy through selective laser melting (SLM). X-ray diffraction (XRD), differential scanning calorimetry (DSC), scanning electron microscopy and tensile testing methods were used to study the effects of different laser power and scanning speed on the densification behavior, phase transformation characteristics and mechanical properties of NiTi alloy. The study found that the variation of the keyhole effect caused by scanning speed has a greater effect on the densification behavior of SLM NiTi alloy compared to laser power. The increase in scanning speed weakens the burning degree of Ni element, leading to a decrease in phase transition temperature.