Additive Manufacturing of Ni–Ti SMA by the Sinter-Based MoldJet Method

Additive Manufacturing (AM) of Shape Memory Alloys (SMA), and specifically Ni–Ti alloys, is an evolving field with significant potential to applications in actuation, energy harvesting, and refrigeration. Sinter-based AM technologies show promise in tailoring and controlling the microstructure and properties of Ni–Ti, because the metal particles remain in the solid-state throughout the process. Here, we report on the manufacturing and characterization of Ni–Ti produced using a novel sinter-based MoldJet method: a wax-based mold is deposited layer-by-layer using jet-printing, and its cavities are simultaneously filled with metallic paste. This additive process produces a green body that is sintered to form a dense metal part. The low content of organic binder in the metallic paste results in reduced carbon and oxygen contamination compared to other sinter-based AM methods. Consequently, the reduced formation of carbides and oxides enhances the thermomechanical properties. Here, we show that Ni–Ti produced via MoldJet exhibits a superelastic response with a substantial recoverable strain of 5.6% in tension and 4.5% in compression, and irrecoverable plastic strain below 0.2%. The results indicate that MoldJet is a promising method for AM of Ni–Ti for advanced applications. Specifically, we show that the obtained material properties are adequate for elastocaloric cooling devices.