Bambu Lab H2C AMS Combo 3D Printer
Selling fast! 21 people have this in their carts.
- Hotend Change Multi-material Printing
- Minimal Purge Waste Multi-Color Printing
- Precise & Fast Inductive Nozzle Heating
- Close-loop Servo Extruder
- Full Filament Path AI Error Detection
- 350°C Nozzles & 65°C Active Heated Chamber
- Optional 10W/40W Laser and Cutting Module
- 330*320*325 mm³ Build Volume
Return within 2 days of purchase.
Guarantee Safe Checkout
Bambu Lab H2C AMS Combo 3D Printer
Paint No More, Print 7 Colors
in One-Piece.
Geminaraptor
@FireBird(Sophie)
No More Assembly – Print
Multi-Material Parts in One Piece.
Aero Mobius Drone Frame
@极尘悦
Print Durable Joints — Built Right Into the Parts.
Heavy Second Core Mecha
@Kit Crafters
Vortek Hotend Change System
Multi-Material Printing with Minimal Purge Waste
Always Delivering the Most Efficient Combination
Always Delivering the Most Efficient Combination
Fast and efficient multi-color printing
In traditional single-nozzle multi-material printing, purging is needed to clear leftover material between filament changes.Vortek changes that with an intelligent hotend-swapping system that replaces the entire hotend — delivering faster, cleaner prints with minimal waste.
Always Delivering the Most Efficient Combination
The Vortek system works seamlessly with our highly reliable AMS (Automatic Material System), making the entire filament change process fully automatic — no need to manually load each filament into the toolhead.
Always Delivering the Most Efficient Combination
The Vortek system can store filament information in the hotend’s memory, ensuring the correct filament is matched to each hotend. If you are printing with more than seven filament types, the system can calculate the optimal combination to minimize purge waste.
Why Vortek?
Small Form Factor, More Filaments
Learn More ›
8-Second Induction Heating
Learn More ›
Contactless Design For Reliability
Learn More ›
Colors Are No Longer Limited By How Many Toolheads You Have
Learn More ›
Enclosed for High-Performance Printing
Learn More ›
Fully Automatic Nozzle Offset Calibration
Learn More ›
Dedicated Hotends for Specific Filaments
Learn More ›
Small Form Factor, More Filaments
Because only the hotend is swapped, the system can house up to six replaceable hotends without significantly reducing the build volume. That means more materials, more colors, and more possibilities — all in one print.
8-Second Induction Heating
Our industry-leading induction heating technology brings the nozzle to temperature in 8-sec, significantly reducing the preheating time for each material swap compared to traditional methods.
Contactless Design For Reliability
Our high standards for reliability led us to move away from contact-based metal pins, which are prone to oxidation and unstable connections. We developed a contactless solution that ensures a stable, high-frequency connection — the foundation for precise temperature control and intelligent hotend sync.
Colors Are No Longer Limited By How Many Toolheads You Have
Unlike traditional tool changer printers that limit color count by the number of toolheads, the H2C supports up to 24 materials in a single print through parallel-connected AMS units. Its intelligent algorithm optimizes filament-to-hotend allocation to minimize purge waste while delivering outstanding multi-color and multi-material results.
Enclosed for High-Performance Printing
With its seamless enclosure and adaptive airflow system, the H2C maintains a stable chamber temperature for high-performance materials and filters the air to keep your workspace clean and safe.
Fully Automatic Nozzle Offset Calibration
Our inductive nozzle offset calibration is fully automated — no manual steps, no calibration plates, no extra setup. In just a few minutes, the H2C precisely calibrates nozzle offset to within 25 microns.
Dedicated Hotends for Specific Filaments
The H2C's Vortek system lets you dedicate one of its six interchangeable hotends to specific filaments — a game-changer for valuable engineering materials. This ensures superior consistency and reliability across prints. Each hotend can even automatically store filament information, so the next time you load that material, it's instantly matched to the correct hotend.
Top Tier Printing Performance
Better High-Speed Reliability & Real-Time Error Detection.
The PMSM servo extruder delivers up to 10 kg of maximum extrusion force—70% more than stepper motor—dramatically improves high-flowrate extrusion stability. Our proprietary servo architecture samples resistance and position at 20 kHz, actively detecting filament grinding and clogs in real time.
50 µm Ultra-Fine Motion Accuracy*
With its Vision Encoder, the H2C achieves a distance-independent motion accuracy of less than 50 μm—thinner than human hair. The system automatically compensates for any mechanical drift during calibration, ensuring consistent precision and peak performance over time.*
Unleash The Full Potential of
High-Performance
Materials
The H2C’s 65°C actively heated chamber & 350°C Nozzles minimizes warping and deformation while enhancing layer adhesion.
AI Camera
The H2C features an AI-backed camera system. This intelligent monitoring system continuously tracks extrusion patterns, immediately detecting material accumulation, filament deviations, and extrusion failures. Also runs a pre-flight scan to ensure a safe start.
Comprehensive Print Monitoring
The H2C is equipped with an array of 59 sensors* and a quad-camera computer vision system, all orchestrated by our proprietary neural algorithm. During printing, this system delivers intelligent, real-time diagnostics that can detect even the most subtle print anomalies as they happen. You don't have to be an expert to solve problems—your printer does the job for you.
Best-In-Class Air Filtration
The H2C's three-stage filtration system is essential for printing with engineering filaments. This powerful combination of a G3 pre-filter, an H12 HEPA filter, and a coconut shell activated carbon filter effectively minimizes the odors and harmful particulates often released by engineering materials.
Fire-Retardant Construction
The H2C's chamber is constructed entirely with flame-retardant material, providing robust, passive fire safety protection across the entire enclosure.
Flexible Network Security & Connectivity
The H2C offers convenient cloud connectivity for remote control from any device. For security-sensitive applications, it also provides full offline functionality, ensuring complete physical isolation. Users can operate the printer, send files, and update firmware without an internet connection. For advanced users, Developer Mode enables MQTT port access for integrating third-party components and software.*
Additional Information
What’s in the box
| H2C AMS Combo | |
|---|---|
|
1 |
|
1 |
|
1 |
|
1 |
|
1 |
|
1 |
|
2 |
|
1 |
|
1 |
|
1 |
Technical Specifications
| Printing Technology | Fused Deposition Modeling |
| Single Nozzle Printing (Left) | 325 × 320 × 320 mm³ |
| Single Nozzle Printing (Right) | 305 × 320 × 325 mm³ |
| Dual Nozzle Printing | 300 × 320 × 325 mm³ |
| Total Volume for Two Nozzles | 330 × 320 × 325 mm³ |
| Chassis | Aluminum and Steel |
| Outer Frame | Plastic and Glass |
| Physical Dimensions | 492 × 514 × 626 mm³ |
| Recommended Space for Printer | 700 × 700 × 1100 mm |
| Net Weight | 32.5 kg |
| Extruder Gear | Hardened Steel |
| Nozzle | Hardened Steel |
| Max Nozzle Temperature | 350 °C |
| Supported Nozzle Diameter | 0.2 mm, 0.4 mm, 0.6 mm, 0.8 mm |
| Filament Cutter | Built-in |
| Filament Diameter | 1.75 mm |
| Extruder Motor | Bambu Lab High-precision Permanent Magnet Synchronous Motor |
| Build Plate Material | Flexible Steel Plate |
| Included Build Plate Type | Textured PEI Plate |
| Supported Build Plate Type | Textured PEI Plate, Engineering Plate |
| Max Heatbed Temperature | 120 °C |
| Max Speed of Toolhead | 1000 mm/s |
| Max Acceleration of Toolhead | 20,000 mm/s² |
| Max Flow for Hotend | 40 mm³/s (Test: 250 mm round model, single outer wall, Bambu Lab ABS, 280 °C) |
| Active Chamber Heating | Supported |
| Max Temperature | 65 °C |
| Pre-filter Grade | G3 |
| HEPA Filter Grade | H12 |
| Activated Carbon Filter Type | Granulated Coconut Shell |
| VOC Filtration | Superior |
| Particulate Matter Filtration | Supported |
| Part Cooling Fan | Closed Loop Control |
| Cooling Fan for Hotend | Closed Loop Control |
| Main Control Board Fan | Closed Loop Control |
| Chamber Exhaust Fan | Closed Loop Control |
| Chamber Heat Circulation Fan | Closed Loop Control |
| Auxiliary Part Cooling Fan | Closed Loop Control |
| Toolhead Enhanced Cooling Fan | Closed Loop Control |
| Supported Filament Type | PLA, PETG, TPU, PVA, BVOH, ABS, ASA, PC, PA, PET, PPS |
| Reinforced Filaments | Carbon/Glass Fiber Reinforced: PLA, PETG, PA, PET, PC, ABS, ASA, PPA, PPS |
| Live View Camera | Built-in; 1920 × 1080 |
| Nozzle Camera | Built-in; 1920 × 1080 |
| BirdsEye Camera | Built-in; 3264 × 2448 (Equipped with Laser Edition) |
| Toolhead Camera | Built-in; 1600 × 1200 |
| Door Sensor | Supported |
| Filament Run Out Sensor | Supported |
| Filament Tangle Sensor | Supported |
| Filament Odometry | Supported with AMS |
| Power Loss Recovery | Supported |
| Voltage | 100-120 VAC / 200-240 VAC, 50/60 Hz |
| Max Power | 1800 W @ 220 V / 1250 W @ 110 V |
| Typical Power | 200 W @ 220 V / 200 W @ 110 V (Single Nozzle Printing PLA) |
| Working Temperature | 10 °C - 30 °C |
| Touchscreen | 5-inch 720 × 1280 Touchscreen |
| Storage | Built-in 8 GB EMMC and USB Port |
| Control Interface | Touchscreen, Mobile App, PC App |
| Motion Controller | Dual-core Cortex-M4 and Single-core Cortex-M7 |
| Application Processor | Quad-core ARM with NPU |
| Slicer | Bambu Studio (Supports third-party slicers: Super Slicer, PrusaSlicer, Cura) |
| Supported Operating System | MacOS, Windows, Linux |
| Ethernet | Not Available |
| Wireless Network | Wi-Fi |
| Network Kill Switch | Not Available |
| Removable Network Module | Not Available |
| 802.1X Network Access Control | Not Available |
| Operating Frequency | 2412-2472 MHz, 5150-5850 MHz (FCC/CE) | 2400-2483.5 MHz, 5150-5850 MHz (SRRC) |
| Wi-Fi Transmitter Power (2.4 GHz) | <23 dBm (FCC); <20 dBm (CE/SRRC/MIC) |
| Wi-Fi Transmitter Power (5 GHz Band1/2) | <23 dBm (FCC/CE/SRRC/MIC) |
| Wi-Fi Transmitter Power (5 GHz Band3) | <30 dBm (CE); <24 dBm (FCC) |
| Wi-Fi Transmitter Power (5 GHz Band4) | <23 dBm (FCC/SRRC); <14 dBm (CE) |
| Wi-Fi Protocol | IEEE 802.11 a/b/g/n |
