Freemelt ONE METAL 3D PRINTER

A metal 3D printer specifically designed
for material research and development.

Freemelt ONE Metal 3D Printer Brochure Download

Freemelt ONE METAL 3D PRINTER

A metal 3D printer specifically designed for material research and development.

Freemelt ONE Metal 3D Printer Brochure Download

APPLICATION EXAMPLES

DISCOVER THE FREEMELT ONE METAL 3D PRINTER!

High beam power and fully open scanning parameters
Create your own IP with full control in an open architecture
Develop new materials optimized for your application
Develop faster processes and use a wider range of metal powders
Benefit from shared knowledge and data in an open community
Adapt the system to your needs with an open system architecture

Freemelt ONE Metal 3D Printer Brochure Download

For detailed information, pricing, and contact regarding the Freemelt ONE 3D Printer, please fill out the form!

TECHNICAL SPECIFICATIONS

Beam Power: 0-6 kW adjustable
Beam Acceleration Voltage: 60 kV
Build Volume: 100 mm H x 100 mm Ø
Base Pressure in the Vacuum Chamber: 10^-6 hPa (mbar)
Base Pressure in the Electron Gun: 10^-7 hPa (mbar)
Pumping Time of the Vacuum Chamber: <15 minutes
Cathode Heater: CO2 Laser
Operating System: Linux
Data Clock Frequency: 350 kHz (1 MHz optional)
File Format: Open Beam Path (OBP)

VACUUM CHAMBER

Low outgassing materials, fully metallic seals, and intelligent design that prevents moisture-absorbing metalization ensure superior vacuum quality.

POWDER FEEDING

The linear movement of the powder feeder is driven by a mechanism located outside the vacuum chamber. It provides easy access, maintenance, and durability since it is not exposed to process conditions.

OPEN SOURCE

Açık kaynak platformumuz, uygulamalar geliştirmek için tüm potansiyelinizi kullanmanıza olanak tanır.

WHAT IS EBM (ELECTRON BEAM MELTING) TECHNOLOGY?

EBM uses an electron beam as the energy source for melting powder in a powder bed held at high temperatures in a vacuum atmosphere, and it also requires a long cooling time after manufacturing the part. EBM is quite similar to SLM technology in terms of operation. The advantages of EBM include the prevention of oxidation in manufactured parts, a non-porous or dense microstructure, crack-free structures, and the ability to process brittle intermetallic materials. In contrast, EBM has some inherent limitations: optimizing EBM process parameters is quite challenging, its use is limited to selected materials, processing the produced parts takes significantly more time, and there are relatively high costs and size limitations in part fabrication.