June 1, 2026
Description
A compact DIY chamber heater for enclosed 3D printers, designed to help reach and maintain higher chamber temperatures quickly, consistently, and without spending a fortune.
The main electronics for this build cost approximately 26.86 USD based on the linked components listed below.
This heater uses a 100W PTC air heating element, a 24V blower fan, a digital temperature controller, an AC voltage regulator, and a separate electronics chamber inside a 3D-printed housing.
The goal was simple:
Easy to build. Effective in use. Affordable enough that your wallet does not need therapy.
Tested with a Snapmaker U1 enclosed 3D printer:
Without using the heated bed:
Chamber temperature reached 50°C in approximately 20 minutes
With the heated bed set to 80°C:
Chamber temperature reached a stable 65°C in approximately 10 to 15 minutes
Actual results may vary depending on printer size, enclosure insulation, ambient room temperature, airflow, heater placement, and how well the printer chamber is sealed.
The heater is powered on and off manually using the inline switch.
The target temperature is set on the digital temperature controller. Once set, the controller remembers the selected temperature until you change it again.
When the printer chamber reaches the target temperature, the controller automatically turns the heater off. When the chamber temperature drops below the target, the heater turns on again.
Turn the heater on manually using the inline switch.
Set your desired chamber temperature on the controller.
Let the controller regulate the heater automatically.
Turn the unit off manually when the print is finished.
The voltage regulator allows the heater output to be adjusted, so the PTC heater does not always have to run at full power.
This model must be printed with high-temperature materials only.
Recommended materials:
ABS
ASA
PC
Other suitable heat-resistant engineering filaments
Do not print this with:
PLA
PETG
PLA and PETG are not suitable for this project because the heater housing is exposed to elevated chamber temperatures and heat from the internal heater assembly.
For a chamber heater, this is not the place for optimistic PLA dreams. Use the spicy plastic.
13 × M3 heat-set inserts
Minimum length: 4 mm or longer
11 × M3 screws
Length: 10 mm or longer
2 × M3 screws
Length: 30 mm
I will include links to the electronic components so the listed prices are actually achievable and easy to compare.
Component | Approx. Cost |
|---|---|
6.10 USD | |
1.90 USD | |
4.26 USD | |
7.76 USD | |
1.91 USD | |
4.93 USD |
Approximate electronics cost: 26.86 USD
This price does not include filament, screws, heat-set inserts, and wiring.
Wiring Diagram
Assembly 01
Assembly 02
Assembly 03
This build uses mains-powered components. The listed PTC heater is 220V, and the wiring diagrams are based on a 220V AC setup.
If you live in a 110V region, make sure every component you use is suitable for your local mains voltage. Do not mix incompatible voltage-rated parts.
This project uses mains voltage and heat-producing components.
Build this only if you are experienced and confident working with AC electrical wiring. Incorrect wiring can cause electric shock, fire, damage to your printer, or injury.
Before building or using this project:
Disconnect power before wiring, adjusting, or servicing.
Insulate all exposed terminals properly.
Use proper strain relief for all cables.
Keep AC wiring separated from low-voltage DC wiring.
Use heat-resistant wiring where appropriate.
Make sure the heater outlet is never blocked.
Do not leave the heater running unattended.
Verify wiring according to the actual labels on your components.
Use at your own risk.
For extra safety, I strongly recommend adding appropriate protection such as a fuse, thermal cutoff, grounding where applicable, and a properly rated enclosure according to your local electrical safety standards.
This is a DIY modification for enclosed 3D printers. I am sharing the design, component list, wiring concept, and my own test results, but every build environment is different.
You are responsible for checking the electrical safety, thermal safety, component ratings, wiring, and suitability for your own printer.
Be careful, be reasonable, and remember:
Warm chamber good. Spontaneous indoor campfire bad.
License:
Creative Commons — Attribution — Noncommercial — Share Alike
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