Direct Writing 3D Printer - Starter Version

  • 1

    Intelligent 3D/4D Print Path Planning

    Self-developed “ADT-Slicer” and “CAD-Slicer” software for easy implementation of 3D and 4D printing.

  • 2

    High Precision

    High repeatability and motion resolution.

  • 3

    Flexible Print Control

    Supports instant material start/stop with adjustable print speeds from 25% to 300%.

  • 4

    Multi-Material and Multi-Model Printing

    Dual nozzle and precise control system enable single model-multiple materials and multiple models-multiple materials printing.

  • 5

    Custom Options

    Supports base heating, extruder heating, and nozzle photocuring features.

Why Choose Our Ceramic 3D Printing Solutions

Precision Printing

Precision Printing

Achieve unparalleled accuracy in ceramic 3D printing for complex geometries and intricate designs.

Dental Printing

Dental Printing

Create precise dental restorations, implants, and prosthetics with advanced ceramic 3D printing.

Medical Ceramics

Medical Ceramics

Produce biocompatible ceramic components for medical implants and surgical tools.

High-Quality Materials

High-Quality Materials

Utilize advanced ceramic materials for durable and high-performance components.

Eco-Friendly

Eco-Friendly

Sustainable printing methods reduce waste and environmental impact.

Versatile Applications

Versatile Applications

From aerospace to medical, our technology supports diverse industry needs.

Product Introduction

Product Introduction

Self-Developed Control Software

Self-Developed Control Software

Equipped with our proprietary ADT-Slicer software for precise control, allowing for "one-stroke forming" to achieve efficient and stable printing results. Paired with the CAD-4D printing engine for easy implementation of 4D printing.

Supports Multi-Material Printing

Supports Multi-Material Printing

Supports multi-material printing, ideal for material research in academic settings. Capable of printing biological tissues, cells, biocompatible materials, and ceramics. Users can select various material combinations for material validation and performance testing in research projects, flexibly meeting laboratory printing needs.

Multi-functional Extrusion Nozzle

Multi-functional Extrusion Nozzle

The multifunctional extrusion nozzle combines three features: high-precision pneumatic control, localized heating of the print head, and UV light curing. It supports stable extrusion of various materials, meeting researchers' needs for different materials in experiments and ensuring efficient and stable material deposition.

Printing Case

For more case and model information, please contact us
Live Cell Biological Tissue
Bionic 4D Printing
Battery Materials
Silicone Material
Photonic Crystal Printing
Graphene Material
GelMA Support
4D Ceramic Material Printing
TCP - Block
SiO₂ - Sphere
HA - Block
PZT - Block
Al₂O₃ - Crafts
Si-Al Composite-Co
ZrO₂ - Filter Element
SiC - Block
Direct Writing 3D Printer - Standard Version
Equipment name Direct Writing 3D Printer-Starter Version
Equipment type ADT-DIW50
Equipment size 460*390*700mm
Formating space 120*120*120mm
Motor type Dc servo-mute
X/Y axis transmission structure GT2 timing belt (Preload)
Z axis transmission structure Mute module
Guide rail model MGN12
Repeatability ±50μm
XY linewidth motion resolution ≤5μm
Layer thickness resolution ≤15μm
Number of extruder heads 2
Base heating Up to 80℃
Base refrigeration -5℃ (room temperature ≤20℃,humidity ≤40%RH)
Base refrigeration -5℃ (room temperature ≤20℃,humidity ≤40%RH)
UV curing
UV light source power PWM modulation
UV light source power Standard configuration 0.6W (optional 1.5W)
UV light selectable Standard configuration 405nm (optional 365/385nm)

Equipment Printing Process

Equipment Printing Process

Constructing Magnetic Field Controlled 4D Photonic Crystals

Magnetic Field-Controlled 4D Photonic Crystals via Adventure-3D-LB-Printer Fine Direct Write 4D Printing
Constructing Magnetic Field Controlled 4D Photonic Crystals

Constructing μm-Scale THz Photonic Crystals

μm-Scale Photonic Crystals Fabricated by Adventure-3D-LB-Printer Fine Direct Write 3D Printing
Constructing μm-Scale THz Photonic Crystals

FAQ: 3D Ceramic Printer

The system is engineered for non-Newtonian fluids. To ensure printability and self-supporting capability, the slurry should exhibit distinct shear-thinning behavior and a high yield stress. We typically recommend a ceramic solid loading of 45 vol% to 60 vol% to guarantee that the green body retains its shape immediately after extrusion.

The system features a standard Luer-lock interface, supporting high-precision dispensing needles ranging from 100 $mu$m to 1.5 mm. Under optimal laboratory conditions and with highly viscous materials, the minimum stable extrusion layer thickness can reach approximately 0.1 mm, depending on the particle size and rheological stability of your material.

The Basic Version utilizes a high-precision pneumatic extrusion system. This setup offers an excellent instantaneous flow response, making it ideal for materials with a viscosity range of 10^2 to 10^6mPa·s. For ultra-high viscosity pastes requiring extreme volumetric precision, we can provide customized mechanical screw-driven assistance components upon request.

Thanks to the continuous extrusion nature of DIW technology, the relative density of the green body typically reaches 55% to 65% after optimizing slicing paths and overlap rates. Following standard debinding and sintering post-processing, the final sintered part can achieve a theoretical density of over 98%.

Yes, this model is equipped with a precision heated bed capable of reaching up to 80°C (or higher depending on custom configurations). The heated platform effectively promotes controlled solvent evaporation and minimizes internal stress accumulation, preventing warping or inter-layer cracking during the printing of large or thick-walled ceramic parts.

We provide dedicated slicing parameter recommendations optimized for DIW processes. By precisely matching the extrusion pressure with the movement speed (E-steps adjustment), micro-pore sizes, pore distribution, and strut diameters can be controlled at the micron level to meet strict tissue engineering or catalyst carrier standards.

The standard DIW Basic Version is configured as a single-nozzle system. However, its modular architecture allows for multi-nozzle upgrades. Combined with specific control software, it can be adapted to achieve the alternating printing of heterogeneous materials or Functionally Graded Materials (FGM).

For highly abrasive advanced technical ceramic slurries, we highly recommend using hardened steel needles or ruby-tipped nozzles. This significantly extends the nozzle lifespan and ensures consistent extrusion diameter and flow rate during long-cycle print jobs.

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    Direct Ink Writing 3D Printer Starter Version

    One Machine, Unlimited Research Possibilities

    DIW Ceramic 3D Printer Basic Version
    DIW Ceramic 3D Printer Basic Version
    DIW Ceramic 3D Printer Basic Version
    Equipment Type ADT-3D-LB-Printer-0100 ADT-3D-LB-Printer-0050 ADT-3D-LB-Printer-0005
    Equipment Size 460×390×700mm 460×390×700mm 590×470×750mm
    Forming Space 100×100×100mm 120×120×120mm 150×150×150mm
    Repeatability ±100μm ±50μm ±5μm
    Number of Extruders 2 2 2
    Base Heating Up to 60℃ Up to 80℃ Up to 80℃
    Base Refrigeration① - -5℃ -
    UV Curing -
    UV Wavelength - 405nm 405nm
    Printable Material Bio-materials, Living cell-based biological tissues, Ceramic materials, etc.

    ① Conditions: room temperature ≤ 20℃, and humidity ≤ 40% RH.

    Note: The plus version requires customization.

    DIW printing principle poster
    • Wide Material Compatibility
    • High Precision

    • Multi-material Printing

    ADT's 3D ceramic printing materials

    Printing Case

    For more case and model information, please contact us
    Alumina 3D printed ceramic sleeve broken sample
    Silicon nitride 3D printed samples
    Potassium sodium niobate 3D ceramic printing sample
    Alumina 3D printed ceramic large plate sample
    Alumina 3D printed ceramic rose sample

    FAQ: 3D Ceramic Printer

    This desktop ceramic 3D printing machine measures 605×510×850mm, making it highly suitable for compact laboratory environments, research institutes, and space-constrained production facilities.

    The printer offers a build size of 96×54×90mm, which is ideal for producing high-resolution ceramic components, UV-curable microstructures, and functional ceramic prototypes with tight tolerances.

    The system features a 1920×1080 DLP projection engine with an optical resolution of 50μm, allowing precise fabrication in advanced ceramic 3D printing workflows such as microfluidics, biomedical scaffolds, and dielectric components.

    This DLP-based ceramic 3D printer operates at a UV light wavelength of 405nm, compatible with a wide range of light-sensitive ceramic slurries and photopolymer resins commonly used in high-performance ceramic fabrication.

    Under full-exposure conditions, this lab-scale ceramic 3D printer can reach speeds up to 700 layers per hour, making it one of the most efficient compact systems for rapid ceramic prototyping and small-batch fabrication.

    To print a 1mm-thick sample, an initial ceramic slurry volume of 250mL is needed. This supports cost-effective material use in experimental ceramic printing setups.

    The ADT-3D-ZM-Ceramic-96-50 supports various UV-curable ceramic 3D printing materials, including alumina (Al₂O₃), zirconia (ZrO₂), silicon carbide (SiC), and custom ceramic-polymer composites, making it adaptable for a broad range of technical ceramics applications.

    This model is ideal for academic research, biomedical device prototyping, electronic ceramics, and custom component production. It is a trusted choice among users seeking a high-resolution ceramic 3D printer for laboratory and R&D purposes.

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