Technology That Drives Possibility

LPBF is a metal additive manufacturing process that uses a high-powered laser to selectively melt and fuse layers of fine metal powder into dense, complex parts. This technology enables the production of fully functional metal components with intricate geometries, exceptional precision, and mechanical properties comparable to—or even exceeding—those of conventionally manufactured materials.

LPBF is ideal for aerospace, medical, automotive, and research applications where lightweighting, customization, and performance optimization are key.

AMIST LPBF Equipment 

• EOS M270

  The EOS M270 provides dependable, earlier-generation LPBF capability for research and education.

  • Build Volume: 250 × 250 × 215 mm
  • Key Features: Open process parameters and robust performance for small-batch and training applications.
  • Distinction: Well-suited for fundamental research, powder testing, and student learning environments.

• EOS M280

  The EOS M280 is a versatile production and research platform that bridges development and industrial use.

  • Build Volume: 250 × 250 × 325 mm
  • Key Features: Stable laser performance, proven process reliability, and flexibility for parameter customization.
  • Distinction: Often used for process development, material parameter tuning, and application prototyping before scaling to full production systems. 

• EOS M280

  The EOS M290 is a flagship industrial LPBF system built for precision and repeatability.

  • Build Volume: 250 × 250 × 325 mm
  • Key Features: Advanced laser control, in-process monitoring, and compatibility with a wide range of alloys (aluminum, titanium, Inconel, stainless steel, etc.).
  • Distinction: Delivers production-grade part quality ideal for qualification studies and end-use manufacturing.

DED is an additive manufacturing process that uses a focused energy source—typically a laser—to melt metal feedstock (powder or wire) as it’s deposited, creating fully dense, near-net-shape components. Unlike powder bed systems, DED can build on existing parts, repair components, or add new features to existing geometries, making it ideal for repair, refurbishment, and large-scale metal fabrication.

This technology provides flexibility in material selection, gradient builds, and multi-material deposition, supporting both research and industrial applications.

AMIST DED Equipment

• BeAM Modulo 400

  The BeAM Modulo 400 is an industrial-grade DED system designed for precision metal deposition and hybrid manufacturing research.

  • Build Volume: 650 × 400 × 400 mm
  • Feedstock: Metal powder feed through coaxial nozzle system
  • Key Features: 5-axis motion control, sealed inert atmosphere, and adaptive laser power adjustment for complex geometries
  • Distinction: Enables repair and feature addition on existing parts, multi-material gradient builds, and process parameter development for new alloys and applications.

Metal powder atomization is the process of converting molten metal into fine, spherical powders suitable for use in metal additive manufacturing. These powders are critical for achieving consistent part quality, flowability, and density in processes such as Laser Powder Bed Fusion (LPBF) and Directed Energy Deposition (DED).

AMIST’s atomization technology enables the creation of custom alloy compositions and small-batch powder production, supporting research in alloy development, process parameter optimization, and feedstock innovation.

AMIST Atomization Equipment

• Amazemet rePowder Ultrasonic Atomizer & Alloying Platform

  The Amazemet rePowder system is a compact ultrasonic atomization and alloying unit designed for laboratory-scale powder production.

  • Powder Size Range: Typically 20–80 µm
  • Feedstock Options: Wires, rods, or compacted metal feed materials
  • Key Features: Ultrasonic atomization for highly spherical powders, controlled particle size distribution, and oxygen-sensitive material handling
  • Distinction: Enables custom alloy creation, rapid powder development, and on-demand small-batch production for advanced research and testing applications.

Ideal for quick, cost-effective prototyping using durable thermoplastics.

AMIST FDM Equipment

• Creality Ender 3 Max Neo

  A dependable FDM 3D printer designed for rapid prototyping, education, and research applications. The Ender 3 Max Neo combines a large build area with automatic bed leveling and quiet operation, delivering consistent, high-quality results across a range of materials.

  • Build Volume: 11.8 × 11.8 × 12.6 in (300 × 300 × 320 mm)
  • Layer Resolution: 100–400 µm
  • Key Features: CR Touch auto-leveling, all-metal Bowden extruder, filament runout sensor, and resume printing function
  • Distinction: Ideal for hands-on learning environments, iterative design, and cost-effective prototyping.

• Bambu Lab X1E

  A cutting-edge CoreXY FDM printer built for speed, precision, and professional-grade performance. The X1E integrates advanced automation, multi-material printing, and intelligent environmental controls for consistent results in demanding applications.

  • Build Volume: 10.3 × 10.3 × 10.3 in (256 × 256 × 256 mm)
  • Layer Resolution: Up to 50 µm
  • Key Features: Multi-material AMS system, closed-chamber printing, active temperature regulation, and AI-based print monitoring
  • Distinction: Perfect for engineering validation, multi-material prototypes, and production-quality polymer parts.

• Creality CR-10S Pro

  A large-format FDM printer built for reliability and versatility in rapid prototyping and production environments. The CR-10S Pro offers precision printing with a robust frame, automatic bed leveling, and compatibility with a wide range of filament types.

  • Build Volume: 11.8 × 11.8 × 15.7 in (300 × 300 × 400 mm)
  • Layer Resolution: 100–400 µm
  • Key Features: BLTouch auto-leveling, Capricorn Bowden tubing, dual-gear extrusion, and filament runout detection
  • Distinction: Ideal for large prototypes, functional testing, and high-quality polymer part fabrication.

• Prusa MK3S+

  A professional-grade desktop FDM printer known for precision, reliability, and open-source flexibility. The Prusa MK3S+ combines intelligent sensors, silent operation, and a magnetic build plate system to deliver consistent, detailed prints.

  • Build Volume: 9.8 × 8.3 × 8.3 in (250 × 210 × 210 mm)
  • Layer Resolution: Up to 50 µm
  • Key Features: SuperPINDA auto-leveling sensor, filament runout detection, power-loss recovery, and modular design
  • Distinction: Perfect for research labs, student projects, and small-batch production requiring precise, repeatable results.

Delivers smooth, highly detailed resin prints for design validation, mold masters, and end-use components.

AMIST SLA/mSLA Equipment

• Elegoo Mars 5

  A compact, high-resolution MSLA resin printer built for precision and speed. The Mars 5 features a 12K monochrome LCD for exceptional detail and smooth surfaces, making it perfect for small-scale prototypes, dental models, and research applications.

  • Build Volume: 7.6 × 4.7 × 9.8 in (195 × 120 × 250 mm)
  • Resolution: 19 µm XY precision
  • Key Features: Fast layer curing, automatic resin feeding, and intuitive touchscreen interface
  • Distinction: Ideal for high-detail, small-format printing in research and education settings.

• Phrozen Sonic Mega

  An industrial-grade LCD resin printer designed for large-scale, high-volume production. The Sonic Mega combines speed, stability, and accuracy—enabling users to print multiple large parts simultaneously without compromising quality.

  • Build Volume: 15 × 8.6 × 15.7 in (380 × 220 × 400 mm)
  • Resolution: 43 µm XY resolution
  • Key Features: Reinforced Z-axis, full-metal frame, and uniform UV light distribution
  • Distinction: Perfect for batch production, large prototypes, and full-size component fabrication.

• Nexa3D XiP

  A professional LSPc® (Lubricant Sublayer Photocuring) printer engineered for ultra-fast, high-precision production. The Nexa3D XiP combines speed, accuracy, and versatility with an open material platform suitable for standard, clear, flexible, and engineering-grade resins.

  • Build Volume: 7.7 × 4.5 × 8.3 in (195 × 115 × 210 mm)
  • Resolution: 52 µm XY resolution
  • Key Features: Modular resin cartridge system, high-speed layer curing, and precision optics
  • Distinction: Delivers industrial-quality prints at desktop scale—ideal for functional prototypes and complex geometries.

AMIST’s SLS capabilities expand polymer manufacturing options by enabling functional, end-use part production with engineering-grade performance—bridging the gap between prototype and production.

AMIST SLS Equipment 

• DTM Sinterstation 2500+ (SLS)

  The DTM Sinterstation 2500+ is a Selective Laser Sintering (SLS) system designed for producing durable, high-performance polymer parts without the need for support structures. Using a CO₂ laser to fuse nylon-based powders, this system enables the creation of complex geometries and functional prototypes ideal for engineering applications.

  • Build Volume: 13 × 11 × 15 in (330 × 280 × 380 mm)
  • Layer Resolution: 80–150 µm
  • Key Features: High-temperature build chamber, consistent powder recycling, and support-free fabrication of intricate designs
  • Distinction: Ideal for functional testing, low-volume production, and research requiring durable, end-use polymer parts.