Sign In  |  Register  |  About Corte Madera  |  Contact Us

Corte Madera, CA
September 01, 2020 10:27am
7-Day Forecast | Traffic
  • Search Hotels in Corte Madera

  • CHECK-IN:
  • CHECK-OUT:
  • ROOMS:

Uniformity Labs Launches UniFuse™ AlSi10Mg Aluminum Powder for Laser Powder Bed Fusion (L-PBF)

FREMONT, Calif., Feb. 02, 2023 (GLOBE NEWSWIRE) -- Engineered materials company Uniformity Labs (Uniformity) announces the availability of its UniFuse™ AlSi10Mg Aluminum powder and optimized parameters for L-PBF printing at 50um and 90um layer thickness. This follows the previously announced release of UniFuse™ AlSi10Mg and optimized parameters for 30um layer thickness printing. UniFuse™ AlSi10Mg powder and processing parameters at each layer thickness are optimized for best-in-class material properties and repeatability simultaneous with the highest throughput printing across L-PBF platforms. The UniFuse™ AlSi10Mg powder and optimized print processes have been used to create parts across various L-PBF platforms at much greater speed and improved properties relative to comparably priced competitor materials.

Uniformity Labs has now designed High-Performance Scanning parameters for printing UniFuse™ AlSi10Mg at 50um and 90um layer thickness in platforms with lasers exhibiting maximum power between 400W and 700W. Uniformity materials and High-Performance Scanning deliver superior properties at an approximately 75% increased build rate compared to competitors' same layer thickness scan strategies. This throughput improvement is typical for UniFuse™ AlSi10Mg builds.

Higher bed and tap densities with particle size distributions optimized for uniform, repeatable printing at the highest throughput enables Uniformity powders to deliver improved mechanical properties and consistent performance across the build bed, even printing at thicker layers with high laser powers.

“With UniFuse™ AlSi10Mg we’re able to deliver best-in-class mechanical properties, surface finish, printing yield, and part reliability with substantially increased throughput printing at 50um and 90um layer thickness, and when using higher power lasers,” said Uniformity founder and CEO Adam Hopkins. “This is significant for advancing AM as a viable pillar for industrial manufacturing and shows that our technology and process deliver on the promise of no compromise additive manufacturing.”

Uniformity Labs is addressing the industry challenge of achieving serial production in AM with the development and production of its highly advanced ultra-low porosity metal powder feedstock. Currently in production under the product brands UniFuse™ (for L-PBF) and UniJet™ (for binder jetting), and with its High-Performance Scanning strategies, Uniformity Labs has dramatically improved the ability to produce high-quality parts repeatedly and at scale – allowing additive manufacturing to become an increasingly better-established serial production tool.

This announcement follows the recent availability of a range of steel, aluminum, and titanium powders under the brand UniFuse™ for L-PBF and UniJet™ for binder jetting, with many others nearing availability. Datasheets and use cases can be found here.

AlSi10Mg AS Printed Mechanical and Density Information

At a glance, mechanical and density properties are listed below:

  • 50um layer thickness, 400W
  • > 99.7% density, 1.4 times the throughput with superior properties compared to competitor 60um layer thickness printing
  • Ultimate Tensile Strength (Rm z) – 426 ± 8 MPa
  • Ultimate Tensile Strength (Rm xy) – 439 ± 4 MPa
  • Yield Strength (Rm z) – 242 ± 2 Mpa
  • Yield Strength (Rm xy) – 271 ± 4 MPa
  • Fracture Elongation (Rm z) – 4.7 ± 0.4%
  • Fracture Elongation (Rm xy) – 7.0 ± 0.3%
  • Surface roughness in z direction (um) 5.1 ± 1.4
  • Click here for the full datasheet

  • 90um layer thickness, 400W
  • > 99.5% density, with properties most similar to competitor 60um layer thickness printing and far superior to competitor 80um layer thickness printing, with 1.6 times the throughput compared to competitor 60um layer thickness printing
  • Ultimate Tensile Strength (Rm z) – 372 ± 13 MPa
  • Ultimate Tensile Strength (Rm xy) – 399 ± 5 MPa
  • Yield Strength (Rm z) – 238 ± 2 Mpa
  • Yield Strength (Rm xy) – 254 ± 2 MPa
  • Fracture Elongation (Rm z) – 3.2 ± 0.3%
  • Fracture Elongation (Rm xy) – 4.9 ± 0.3%
  • Surface roughness in z direction (um) 14 ± 0.7
  • Click here for the full datasheet

  • 90um layer thickness, 700W
  • >99.7% density and 1.8 times the throughput and comparable properties to competitor 700W platform printing at 60um layer thickness.
  • Ultimate Tensile Strength (Rm z) – 401 ± 9 MPa
  • Ultimate Tensile Strength (Rm xy) – 420 ± 6 MPa
  • Yield Strength (Rm z) – 230 ± 3 Mpa
  • Yield Strength (Rm xy) – 247 ± 1 MPa
  • Fracture Elongation (Rm z) – 4.4 ± 0.4%
  • Fracture Elongation (Rm xy) – 6.8 ± 0.8%
  • Surface roughness in z direction (um) 15 ± 0.7
  • Click here for the full datasheet

About Uniformity Labs
Uniformity Labs develops breakthrough material and software solutions to accelerate and expand global commercial/industrial 3D printing (AM) markets. Its patented technology uniquely enables fully dense printing with minimal shrinkage of binder jetting materials, delivering significant cost savings, speed, and quality improvements across all mainstream AM printers. Uniformity’s feedstock materials and print processes dramatically impact the AM value chain by increasing the reliability and efficiency of printing.

For more information, please visit our website – www.uniformitylabs.com

Media contact:
Frank De Maria – 347 647 0284
frank@uniformitylabs.com

A photo accompanying this announcement is available at https://www.globenewswire.com/NewsRoom/AttachmentNg/61409b00-af2d-4569-953a-ca44c479577e


Primary Logo

Data & News supplied by www.cloudquote.io
Stock quotes supplied by Barchart
Quotes delayed at least 20 minutes.
By accessing this page, you agree to the following
Privacy Policy and Terms and Conditions.
 
 
Copyright © 2010-2020 CorteMadera.com & California Media Partners, LLC. All rights reserved.