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Ceramic 3D Printers (AMC)

Industrial Metal Additive Manufacturing Systems

Overview

Additive Manufacturing of Ceramics (AMC) refers to a class of 3D printing technologies, primarily Stereolithography (SLA) and Digital Light Processing (DLP), designed to fabricate complex technical ceramic components. The process involves selectively curing ceramic using UV light sources.

Ceramic 3D Printers (AMC)

Forgecise deliver high-precision 3D solutions like Alumina (Al₂O₃) and Zirconia (ZrO₂) for Biomedical,  Aerospace,  Electronics etc.

Key Features

High-resolution photopolymerization delivers dimensional accuracy

Scalable Build Volume ranges from micro-scale to large-format chambers

Intelligent temperature control and low-shear recoating systems

Seamless Sintering Workflow

Robust Green Body Strength

Multi-material versatility supports a wide spectrum of technical ceramics

Compatible Ceramic Materials

Compatible metal powders include Nickel Alloys, Niobium Alloys, Tungsten Alloys, Molybdenum Alloys, Stainless Steel, Aluminum Alloys, Titanium Alloys, Cobalt-Chrome Alloys, Tool Steel, and High-Conductivity Copper.

Forgecise Cera ZrO₂ (Zirconia) Ceramic Paste for Stereolithography (AMC) 3D Printing Additive Manufacturing Material
Cera ZrO₂ (Zirconia)
Forgecise Cera Al₂O₃ (Alumina) Ceramic Paste for Stereolithography (AMC) 3D Printing Additive Manufacturing Material
Cera Al₂O₃ (Alumina)

Case Studies

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Aerospace: Large-Scale Structural Components

Leveraging our 1.2m+ ultra-large build volume, we use Titanium Alloys (TC4) or Aluminum Alloys (AlSi₁₀Mg) to directly print complete wing stiffeners or satellite payload brackets in a single piece.

Automotive: Conformal Cooling Molds & Lightweight Chassis

Printing EV battery trays or subframes that integrate the functions of multiple parts.

3. Medical: Customized Orthopedic Implants & Surgical Guides

Using biocompatible Cobalt-Chrome Alloys (MP1) or Titanium Alloys (TC4), we print pelvic repair plates or spinal fusion cages that perfectly match patient anatomy based on CT data, featuring biomimetic porous surfaces.

Heavy Industry: High-Temperature Turbine Blades & Heat Exchangers

Utilizing Nickel-Based Superalloys or Refractory Metals (Tungsten/Molybdenum Alloys) to print large turbine blades with complex internal film-cooling holes or highly efficient compact heat exchangers.

Electronics Thermal Management: High-Conductivity Complex Components

Using High-Conductivity Copper (QCr1) to directly print integrated heat sinks featuring micro-channels and (irregular) fins.

Info Box

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