4D printing method and application of titanium-nickel shape memory alloy

The invention claimed is: 1. A 4D printing method of titanium-nickel shape memory alloy, characterized in that: this method comprises the following steps: (1) milling: mixing and smelting pure titanium and pure nickel to obtain titanium-nickel alloy bars, then preparing alloy powder by a rotating electrode atomization method, and sieving the powder to obtain titanium-nickel alloy powder with a particle size of 15-53 μm; (2) powder modification: placing the titanium-nickel alloy powder obtained in step (1) in a discharge plasma assisted ball mill for discharge treatment to perform surface modification of the powder; and (3) 4D printing forming: subjecting the titanium-nickel alloy powder after the surface modification treatment in step (2) to SLM forming to obtain a titanium-nickel shape memory alloy; wherein the rotating electrode atomization method in step (1) comprises the following specific steps: using electrode induction gas atomization milling equipment to heat the titanium-nickel alloy bar to a temperature of 1250° C. to 1500° C. through electrode induction; atomizing the bar with high-purity argon gas to obtain alloy powder, with the pressure during the atomization process controlled at 2.5-8 MPa. 2. The 4D printing method of titanium-nickel shape memory alloy according to claim 1 , characterized in that: the atomic percentage elemental composition of the titanium-nickel alloy bar in step (1) is Ti 44-55 at. %, with the balance of Ni. 3. The 4D printing method of titanium-nickel shape memory alloy according to claim 1 , characterized in that: the conditions of the surface modification in step (2) are as follows: no ball milling medium is added, and the protective atmosphere is 0.15-0.2 MPa high-purity argon gas; the discharge voltage is controlled at (130±5) V, the current is controlled at 1.2-2 A, and the motor speed is 600-1200 r/min; the duration of each discharge treatment is 1-2 hours, the time interval between two adjacent discharge treatments is 30 min, and the number of the discharge treatment is 6-10 times. 4. The 4D printing method of titanium-nickel shape memory alloy according to claim 1 , characterized in that: the conditions of the SLM forming in step (3) are as follows: laser beam power P≥60 W, laser beam scanning speed v≤200 mm/s, and laser beam scanning distance h=60-100 μm; the thickness t of the powder layer meets t=30˜60 μm, and the energy input density E meets 150 J/mm 3 ≤E≤300 J/mm 3 . 5. A titanium-nickel shape memory alloy, characterized in that: it is prepared by the method according to any of claim 1 ; the phase composition of the titanium-nickel shape memory alloy consists of a B2 austenite phase with the CsCl type structure, a B19′ martensite phase with the monoclinic structure, and a Ti 2 Ni precipitation phase; the microstructure of the titanium-nickel shape memory alloy includes nano-scale cellular crystals and micron-scale dendrites, which are alternately distributed in layers. 6. Application of the titanium-nickel shape memory alloy according to claim 5 in the preparation of eyeglass frames, orthodontic wires, compression bone plates, spinal orthopedic rods, drive devices, components, complex dampers, corrosion-resistant equipment, intelligent temperature control devices, self-expanding trusses, self-expanding communication satellite parts, and variant aircraft parts. 7. The titanium-nickel shape memory alloy according to claim 5 , characterized in that: for the nano-scale cellular crystals, the grain boundaries are composed of discontinuous Ti 2 Ni precipitates with a size of 20-180 nm, and there are nano-scale twin crystals inside; the micron-scale dendrites have inside high-density dislocations and a dispersed Ti 2 Ni nanoparticle phase with a size of 5-30 nm. 8. Application of the titanium-nickel shape memory alloy according to claim 7 in the preparation of eyeglass frames, orthodontic wires, compression bone plates, spinal orthopedic rods, drive devices, components, complex dampers, corrosion-resistant equipment, intelligent temperature control devices, self-expanding trusses, self-expanding communication satellite parts, and variant aircraft parts.