Guide: How to Install a Silicone Heater Build Plate

Printed circuit boards (PCB) have long since been the gold standard for heated beds. The main advantage of a PCB heating source is the thermal distribution, keeping the temperature spread evenly across the entire surface. While these work great for small volume 3D Printers, larger sizes can take an excessive amount of time to reach temperature. This is where a Silicone Heater will shine, offering a much better heat output/power ratio and usually capable of reaching 60 °C in less than 90 seconds.

Should every 3D Printer be upgraded to Silicone Heater? Probably not. It is however a noticeable improvement, and capable of reaching higher temperatures than the alternative.

When writing a previous article on safety mods for the Anet A8, a defective heated bed connector was one of the most notable concerns. There were plenty of cheap workarounds available, but most were just band-aids for a larger problem. Disappointed with the results, I tossed it in the trash and decided to replace it instead. This was a perfect opportunity to try out one of the silicone heater mats we carry at Gulfcoast Robotics, looking at both the steps for installation and differences in performance.

Silicone Bed Heater Parts

Purchased Parts List

220x220 Build Plate w/ Silicone Heater (Full Kit) - $0.00

Individual Parts

12V 200W Silicone Heater - $0.00 220x220 Aluminum Build Plate - $0.00 Heated Bed Mounting Hardware Kit – $5.99

Installation Steps

A silicone heater will often come with 3M adhesive backing in place, meaning we can just peel the protective sheet and stick it to the build plate. We don’t need to worry much about air bubbles, but it’s a good idea to press it out in segments and make sure it adheres with a solid bond.

To get started, line up the silicone heater with the build plate right between the screw holes, and peel back about 1/4th of the protective sheet. Turn it over and carefully start to press the exposed adhesive down, using your fingers to smooth it out. Once you are satisfied, repeat this a few more times until the silicone heater has completely stuck to the surface.

 

If you aren’t using the heated bed hardware kit, go ahead and put the original screws and springs back on, then install the bed on the 3D Printer. Otherwise, the hardware kit comes with new bolts, lock nuts, washers and high temperature silicone tubing to replace the springs. Alternatively, most of this can be purchased at the local hardware store, and the tubing is sold online at McMaster-Carr.

Now this bit is entirely personal preference, but I chose to put a washer at the base with a locking nut on top. On build plates with threaded holes this won’t matter as much, but it will secure the bolt in place and prevent movement that can otherwise affect the bed’s leveling.

 

As the included silicone tubing is a single 50mm piece, we will first need to cut it down to (4) individual segments before we can use it. As per the product page, it is recommended to give each piece a length of around 9mm or so.

To keep things simple, I grabbed a piece of cardboard and measure out the desired length with digital calipers. I then marked the two endpoints as a guide, and the silicone tubing was placed in between them to make the cuts. They don’t have to be perfect, but get them as close as possible and clean up the ends with a straight edge razor before installation (box cutter works great).

 

Once the silicone tubing is cut down to size, we can go ahead and install it in place of the bed springs. Slide (1) piece of silicone tube on each screw and place a second washer on top of it. It will just sit on the nut for now, but as we tighten the corners down, the silicone will expand and cover it.

 

With the hardware installed, we can put the heated bed back on the 3D Printer and then start wiring it up. If you have spare M3 nuts on hand, you can thread one on the end of each screw to temporarily keep things in place, but otherwise just turn it over slowly and slide the screws in to the Y-carriage one at a time.

 

Silicone Heater Wiring

The Silicone Heater will consume 17 amps of electricity, compared to an average of 12 amps on a PCB board. The manufacturer recommends (A) power supply with at least 360 watts and (B) fan cooled MOSFET board to handle the heated bed output. This will prevent too much current passing through the connector and causing a meltdown.

Related: How to Install a MOSFET Board

This particular product comes with 3 feet of power and thermistor wiring integrated in to the heater, but it’s also a universal design and the ends are left exposed. Since we are using a MOSFET board, we can just crimp spade terminals on the white power cables for easy installation.

Move your heated bed to the furthest point away from the electronics and cut the wiring to length, leaving a bit of excess just in case. Now use a stripper/crimper multi-tool and remove about a 1/2″ of insulation from the end of each cable. Slide a 14 gauge spade terminal over the bare wires and crimp it down, then give a light tug to make sure they are secure.

 

Now we also need to crimp a connector on to the thermistor wires, but the type we use will vary depending on the electronics board. My Anet A8 has a RAMPS board that takes a 3-pin JST-XH connector for the thermistor, with an empty middle pin between the positive and negative wires. Most 3D printers will use some form of JST, but check the machine just to make sure.

For those that do frequent upgrades, a JST Connector Kit and JST Ratchet Crimping tool can be an absolute life saver on such occasions. If those aren’t part of your toolbox though, we can still make do with the original bed wiring as well. Just cut the original heated bed connector off with about 8 to 12 inches of spare wire, and crimp, splice or solder these to the silicone heater mat’s thermistor. In such cases, it’s a good idea to put some heat shrink tubing over the connection to protect it.

Tip: The individual thermistor wires are too small (28 gauge) for most stripping tools. Strip the black insulation, then use flush cutters to carefully expose the thermistor wire ends.

 

Once the Silicone Heater wiring is prepped and ready for the 3D printer, all we have left to do is install it. Run the white power cables to your MOSFET board, where they will lock in to the screw terminals labeled “HOT BED”. These wires are non-polarized, so it doesn’t matter which order they are installed. Plug the thermistor connector in to the electronics board to wrap things up, and double check the connections are secure.

4 thoughts on “Guide: How to Install a Silicone Heater Build Plate

  1. It is interesting that silicon heaters uses 17 amps compared to 12 amps on the PCB board. My buddy wanted to use my 3d printer but I don’t have a heated bed so it wouldn’t work for him. It seems like anything heater related, even heaters in the house, I’d consider hiring a professional to make sure it is done right.

    1. Hi James,

      The most concerning point of failure with heated beds would be the wiring. If the solder points are stressed while moving back and fourth, it can create a short. In fact, I own one of the early model Creality CR-10 3D Printers and this just happened a few weeks ago. It wasn’t shipped with a strain relief bracket and the movement eventually created a bad connection. The bed stopped heating past a certain temperature, and the cables were burnt/smoking.

      The silicone heaters on the other hand have wiring integrated in to the pad itself, where these are a relatively safer design. It’s still a good idea to use strain relief for cables moving back and fourth, but the power consumption isn’t so much the concern, rather the connection points that are soldered on stock PCB heaters.

  2. You say the manufacturer recommends a PSU with at least 360W. Is this necessary (as opposed to “recommended”)? Wouldn’t a PSU upgrade to 360W also be an upgrade to 24V, and if I have the 12V 200W heater, would using a 24V PSU be incorrect for the heater? I’ve had the bed for almost a week and have yet to install it because I don’t know and can’t find the answers to these questions.

    1. Hi John,

      Most modern 3D Printer power supplies are already 360W, this is the industry standard and probably not an issue. This recommendation is just mentioned to be on the safe side. The silicone heater uses 200W, and the hotend heater uses 40W, putting the main power draw at 240W. Other electronics like the stepper motors are relatively low wattage, so total consumption of most 3D Printers is about 260-270W max.

      You do want to make sure that the voltage of your components (e.g. silicone heater) is the same as your power supply. So a 12V 200W heater should be used with a 12V PSU, and a 24V 200W heater should be used with a 24V PSU.

      -Brett

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