Aluminum 7075 Alloy Powder, Purity: 99.5+%, Size: <325 mesh

Description

Aluminum 7075 Alloy Powder – <325 Mesh, 99.5+% Purity

Aluminum 7075 Alloy Powder is a high-strength aluminum alloy known for its exceptional mechanical properties and high strength-to-weight ratio. With zinc as the primary alloying element, this material offers superior fatigue resistance and is widely used in aerospace, defense, and high-performance engineering applications. The powder form (<325 mesh) enables high precision and consistent performance in additive manufacturing and powder metallurgy.

Although less corrosion-resistant and weldable than some other aluminum alloys, 7075 aluminum provides unparalleled strength and toughness in structural components subjected to extreme stress.

Key Technical Specifications:

• Purity: 99.5+%

• Particle Size: <325 mesh

• Melting Point: 477–635 °C

• Density: 2.81 g/cm³

• Poisson’s Ratio: 0.33

• Specific Heat: 0.96 J/g·°C

• Thermal Conductivity: 130 W/m·K

• Thermal Expansion: 25.2 µm/m·°C

• Vickers Hardness: 175

• Tensile Strength (Ultimate): 572 MPa

• Yield Strength: 503 MPa

Particle Size Distribution (Laser Diffraction):

• D10: 15.3 µm

• D50: 27.6 µm

• D90: 47.7 µm

Elemental Composition (wt%):

Features & Benefits:

• Exceptional Strength & Fatigue Resistance: Ideal for high-load, cyclic applications.

• Fine Powder Consistency: <325 mesh size allows excellent flowability and uniform sintering in powder-based manufacturing.

• High Hardness: Vickers hardness of 175 enables strong wear resistance and structural integrity.

• Optimized Particle Distribution: D50 of 27.6 µm for controlled packing density and layer deposition.

• High Thermal Conductivity: Suitable for thermal management components in structural systems.

Applications:

• Aerospace & Aviation:
  Used in fuselage frames, wing components, bulkheads, and support structures where strength-to-weight is critical.

• Defense & Tactical Systems:
  Applied in missile bodies, weapon components, armor plating, and structural frames.

• Automotive & Motorsports:
  Ideal for lightweight high-stress parts such as suspension elements, wheel hubs, and drive shafts.

• Additive Manufacturing (AM):
  Optimized for use in selective laser sintering (SLS), binder jetting, and direct energy deposition (DED) technologies.

• Powder Metallurgy & Metal Injection Molding (MIM):
  Suitable for near-net-shape manufacturing of complex components with minimal machining.

• High-Performance Engineering:
  Used in robotics, precision tools, and sporting equipment requiring maximum mechanical performance.