Ni-Ti50 Alloy Micron Powder, Purity: 99.9%, APS: 45-105 μm

Ni-Ti50 Alloy Micron Powder (99.9% Purity, APS: 45-105 μm)

Technical Specifications:

• Material: Ni-Ti50 Alloy (Nickel-Titanium 50/50)
• Purity: 99.9% (high purity)
• Particle Size: APS (Average Particle Size) 45-105 μm
• Shape: Typically spherical or irregular (depending on the manufacturing process)
• Density: Approximately 6.45 g/cm³ (for the alloy)
• Melting Point: Around 1,500°C (2,732°F) (depending on the exact composition and crystalline form)
• Boiling Point: Above 2,000°C (3,632°F) for both nickel and titanium
• Chemical Composition (Ni-Ti50):
  • Nickel (Ni): 50%
  • Titanium (Ti): 50%

Applications:

1. Powder Metallurgy:
   • Ni-Ti50 Alloy Powder is widely used in powder metallurgy for manufacturing high-performance and durable components. The 45-105 μm particle size is ideal for creating complex-shaped, high-strength parts for use in aerospace, automotive, and medical applications. Common parts include gears, bearings, pistons, and electrical connectors.
   • The superior mechanical properties of Ni-Ti50 alloy make it suitable for parts that must perform under high stress and high-temperature conditions.
2. Additive Manufacturing (3D Printing):
   • Ni-Ti50 Alloy is frequently used in metal 3D printing technologies such as Selective Laser Melting (SLM) and Electron Beam Melting (EBM). The micron powder size enables the production of complex, high-performance parts with excellent strength, ductility, and thermal stability. These characteristics are essential for aerospace, automotive, and medical applications.
   • This alloy is ideal for creating customized, precision parts with superior mechanical properties, such as functional prototypes and production-grade components.
3. Shape Memory Alloys (SMAs):
   • Ni-Ti50 is a shape memory alloy (SMA) with the ability to return to a pre-set shape when heated above a specific transition temperature. This makes it ideal for use in actuators, sensors, and temperature-responsive components. Ni-Ti50 alloy is often used in applications such as self-expanding stents in the medical field or thermally activated valves and mechanisms in engineering systems.
   • The alloy’s shape memory and superelastic properties are essential for applications where precise mechanical motion or control is required in response to temperature changes.
4. Medical Implants and Devices:
   • Ni-Ti50 alloy is widely used in the medical industry for implants such as dental implants, stents, and orthopedic devices. The biocompatibility, superelasticity, and shape memory properties of Ni-Ti make it ideal for bioengineering applications where flexibility and durability are critical.
   • The micron powder is utilized in additive manufacturing for customized implants that adapt to individual patient needs, especially in minimally invasive procedures.
5. Aerospace Components:
   • Ni-Ti50 alloy is used in aerospace applications such as actuators and valve mechanisms. The shape memory and superelastic properties allow for precise control in aerospace systems, such as spacecraft, satellite components, and aircraft.
   • Ni-Ti50 powder is used in 3D printing to create custom parts that require high strength-to-weight ratios and the ability to withstand extreme conditions in the aerospace environment.
6. Automotive Applications:
   • Ni-Ti50 alloy is used in automotive applications for components that require precise, thermally responsive behavior such as temperature sensors, active suspension systems, and self-healing parts. The shape memory capability allows for the automatic adjustment of automotive systems in response to temperature changes, improving both safety and performance.
   • The micron powder is also used in additive manufacturing to create lightweight, high-performance components in braking systems, transmission components, and fuel delivery systems.
7. Thermally Activated Components:
   • Ni-Ti50 alloy is utilized in the production of thermally activated devices such as temperature sensors and actuators. It is used in applications that require precision movement or control based on temperature fluctuations, such as electromechanical systems and thermostatic controls.
   • The alloy’s shape memory and thermal expansion properties make it suitable for valve actuators, springs, and mechanical systems where reliable, temperature-driven performance is needed.
8. Industrial Applications:
   • Ni-Ti50 alloy is used in the production of industrial components such as heat exchangers, thermal switches, mechanical actuators, and pressure sensors. Its corrosion resistance, strength, and shape memory properties make it well-suited for use in high-stress, high-temperature environments.
   • The micron powder is often employed in additive manufacturing to create durable, complex parts with shape memory properties for use in heavy machinery and energy systems.
9. Research and Development:
   • Ni-Ti50 micron powder is extensively used in research and development to explore new applications for shape memory alloys and superelastic materials. Researchers use the powder for developing new manufacturing techniques, studying the material properties, and testing the performance of Ni-Ti50 in cutting-edge technologies.
   • The micron powder is useful in material science studies that focus on thermal actuators, biomedical devices, and smart materials.

Ni-Ti50 Alloy Micron Powder (99.9%, APS: 45-105 μm) is a high-performance material with shape memory and superelastic properties, making it suitable for a wide range of applications that require precise mechanical motion and temperature-based behavior. Its use in additive manufacturing, powder metallurgy, and the production of shape memory alloys for industries like aerospace, automotive, medical devices, and industrial systems ensures its role in creating complex, durable, and high-performance parts. The powder’s versatility, combined with its excellent mechanical properties and corrosion resistance, makes it an essential material for cutting-edge technologies and precision applications.