Effects of B addition on microstructure and mechanical properties of CuAlNiMn shape memory alloy

The Cu-12Al-4Ni-1Mn-xB(x= (x= 0 degrees 0 ,0. 1 degrees 0,0. ,0. 2 degrees 0,0. ,0. 3 degrees 0 ,mass fraction,the ,the same below) ) shape memory alloys were prepared by vacuum arc melting furnace after introducing trace boron element into the alloy. The influence of boron addition on the microstructure,phase transformation, and mechanical properties of the alloy was investigated. The results show that the addition of boron significantly refines the grain size, with the grain size decreasing from hundreds of microns to (11 +/- 3. 45) ) mu m. The phase transformation temperature shifts to the high-temperature side after boron is added, indicating that the phase transformation process requires higher thermal activation energy. When the boron content is 0. 2 degrees 0, the microhardness of the alloy is enhanced, from (301. 7 +/- 2. 6)HV )HV without adding boron element to (334. 3 +/- 3. 4)HV, )HV , which is attributed to grain refinement and the precipitation of hard and brittle borides. The tensile fracture strength and elongation are greatly improved, with the fracture strength increasing from (320 +/- 2. 6) ) MPa to (788 +/- 17 ) MPa, and the elongation increasing from (1. 44 +/- 0. 05)% ) to (3. 74 +/- 0. 12)%. ). After solid solution annealing, the fracture strength and the elongation are both further increased to (856 +/- 10. 7) ) MPa and (5. 78 +/- 0. 16)% ), respectively. Analysis indicates that grain refinement strengthening, precipitation strengthening of borides, and solid solution strengthening are the main mechanisms for the improvement of mechanical properties. The fracture mode of the alloy shifts from brittle fracture to ductile fracture.