TMC2209 design thermal tests

I did some simple thermal tests on the TMC2209 board. In theory these driver chips can supply up to 2A RMS current to the motors. Silent StepSticks with the same drivers are rated around 1.2 to 1.4A depending on the manufacturer.

The test setup

I used all passive cooling. Ambient temperature was 25C. I used a small 9x9x12mm heatsink on top of the driver chip. These are commonly used on the TMC2209 StepStick boards from China (FYSETC or BIGTREETECH). These are not great, but that is what I could fit in the space. I’ll try to move some of the capacitors to make space for a larger heatsink.

On the bottom I used a 20x14x6 heatsink. Not ideal, but that is what I had laying around. There is enough space for a much larger one (25x25x8 for example).

I used a Seek thermal camera “mounted” on a small microscope stand and connected to my old Nexus 5X phone.

The results

First I tested it at 1A RMS current. I use several very slow speed motion commands (G1 Y250 F50 followed by G1 Y0). I found that slow speed motion is much more challenging to the driver heat  wise.

After about 20 minutes it board heated to about 47C on the top:

The heatsink was barely warm to the touch. In my experiments the top of the drivers always heats up more than the bottom, probably because of the relatively large thermal mass of the PCB itself.

Next I ran the board at 1.4A RMS. This was more challenging test for the heat dissipation. It took a while for the temperature to stop rising. It stabilized at around 64C on the top:

And around 55C on the bottom:

In the picture the heatsink looks “cool” because the camera can not compensate for the different emissivity of the bare aluminum.

Both top and bottom heatsinks were considerably hot to the touch. Not “burn your fingers” hot, but “I cant keep my fingers longer that 5 seconds” type of hot.

In both cases I did not get any over-temperature warnings from Marlin. I would say 1.4A is the limit on convection heat dissipation of this board in this configuration.

The Seek camera has around +/ – 5C accuracy.

I did one last test at 1.8A RMS. This was on the extreme side of the capabilities of the board. The temperature of the driver kept climbing slowly. Once it reached around 75C on the top I got an overheat alarm in Marlin, so I turned the power off.

I’m confident with some active cooling the driver would be able to run at this setting, because it took quite some time to get to the alarm.


Marlin ported to the TMC2209 board

I just got Marlin to boot and move the motors. Had to make some tweaks to the serial port configuration, because I have unique setup (X, Y and Z share one serial port) and the two extruders share another. I also use proper hardware serial ports, not the SoftwareSerial library. At the moment the code requires special patches to the STM32Duino core and the Trinamic library so it can properly support serial half-duplex communication.

On separate topic, I got a prototype of an LCD i/o board for the Nucleo-F407. I tested it with the REPRAP_DISCOUNT_SMART_CONTROLLER and was working flawlessly.

Here it is connected to my soldering machine:

The very first prototype had a bug, hence the little red wire. This adds support for the traditional EXT1 and EXT2 connectors that are popular with other boards. Graphics panels would require a little work, to convince marlin to use the second SPI hardware block.

Some early experiments with the TMC2209 board

Good news first: I managed to get one motor moving with a simple Arduino sketch.

I’m starting to hate QFN packages with a passion. I spent a whole afternoon trying to re-work two pesky drivers. The chips would not communicate via the UART port, no matter what I tried. Finally traced the issue to a bad solder joint on the QFN package and boy these are hard to spot. Simply re-heating the drivers and re-positioning was not enough, I had to remove the chip, add more solder paste, melt it, then re-insert the chip, wipe the excess solder with a soldering iron and finally re-flow the chip one more time. Complete and total PITA.

To top it off this destroys any near by plastic connectors, so now I have the drivers in-place but have to re-solder the connectors back. This would be an endeavor for the next week.

Now all 5 steppers are communicating with the MCU reliably. I had to add support for half-duplex mode to the stm32duino core. The proposed changes are still pending, but I verified that the TMCStepper library is able to communicate with the drivers.

First prototype of the TMC2209 design

This took me whole day. Working with QFN drivers is plain PITA. It does look good though. I just hope it works.

I finally figured out how to wash most of the flux from the board. It is still not perfect, but looks really good.

I have another revision with 3 fuses. I figured that one fuse for both motors and extruder heaters may be too taxing. In my latest design I have one 15A fuse for the heated bed; one 10A fuse for the extruder heaters and one more 10A fuse for the rest of the electronics.

PRNTRboard update

The TMC2130 version of the PRNTRboard is working very well. I’ve been using it for over 6 months on my soldering robot project. It is very stable and reliable.

I didn’t have time polishing the Marlin firm ware for it. I wanted to make the SD-card work on the F407 Nucleo-64 replacement board. Alas every time I look at the Marlin code, I loose all hope and start doing something else.

A few months ago I started working again on the TMC2660 version. This was the first variant I routed successfully, but I ran into trouble with controlling the drivers over SPI and switched my effort to the TMC2130 version. Long story short, when the TMC2130 was in a good shape I started looking back at the TMC2660 version. It is on rev 5 now and I’m really happy with the layout. In my opinion it looks much better than the TMC2130.

I managed to produce a working Marlin firmware for the TMC2660 board and tested a few motors. So far it works like a charm.

My only gripe is that while the mate black finish looks awesome, it is absolute PITA to clean the solder residue from it. I washed this board 3 times and you can still see some spots on it.

As a kick all thru-hole pins on the Nucleo-F407 board underneath are soldered using my soldering robot. On the TMC2660 I soldered the two headers with the robot.

Last but not least I started working on a version with TMC2209 drivers – these are quite capable and low cost compared to other Trinamic offerings.

TMC2660 success at last

I was very frustrated with my failure to get the TMC2660 board variation running. I checked and double checked the connections, alas the steppers would not move at all.

I purchased one TMC2660-BOB kit from digikey and started experimenting with it, instead of my board. At first, I had the same failure – the stepper would not move at all. The software was a very simple Arduino sketch – what would be that wrong. Since the kit was designed by Trinamic, the hardware should be proper. Alas, no luck. I declared the TMC2660 chip cursed and moved to my soldering machine project.

Yesterday I decided to give the test jig one more try. After a few failed attempts. I spotted an error in the Arduino code – I was passing the incorrect CS pin in the driver setup. DUH!!! After a quick fix it was working.

Then I moved back to my original goal to test the thermal dissipation ability of my TMC2660 PrntrBoard design. I connected my board and started to torture test the motor driver. Unfortunately I was not able to run the driver past 1.5A RMS, which is a shame. I’ll try using a different motor with higher coli resistance. Anyhow here is an image from my thermal camera of the top of the ship:

The chip has no heat-sink and runs at 54C. This is not bad at all. much cooler than the TMC2130 version. The board seems to be dissipating quite a bit of the energy.

Here is a picture of the bottom of the board:

The bottom is at 45C in the center, which I think is quite good thermal conductivity of the board layers.

I feel good about the board thermal capabilities. If I add heat-sinks on the top and the bottom it should be able to run at 2A RMS and above with active cooling.

The TMC2660 board was a bust

I dusted off my trusty pick and place and made one of the newly received TMC2660 driver boards.

Since it’s the first time I test this setup I populated only one of the driver chips – the X axis.

Alas it was all in vain. After fighting with it for several days, the motor would not spin properly. Either my stepper driver configuration so completely busted (although I double and triple checked) or the driver chip is fried. One of the phases works, but the other sends no current to the stepper motor.

Also I was trying to fit some automotive fuses on the board – you know for protection. Alas the fuse holders I ordered are very flimsy and don’t fit the fuses at all. Ordered a different set, but have to wait.

Bummer 🙁

Completed redesign of the TMC2660 branch

I spent a lot of time getting the PrntrBoard tmc2130 version to work. I’m at the point where I’m quite happy with it and don’t see major further changes. The tmc2660 branch did not get a lot of attention in the mean time.

So I spent a weekend completely re-designing the tmc2660 board. I ported all changes from the tmc2130 version. There is now a dedicated ground plane layer and routing it much easier.

I opted to put all drivers on one side of the board. Unfortunately limiting the size to 10x10cm (or 3.9×3.9 inches), I could not fit all drivers in one row.  Hopefully cooling would not be major PITA as it was on the tmc2130 version.

Here is a screenshot of the 3D rendering of the redesigned board:

Please excuse my mistake, the top row of power connectors is facing backwards. Fortunately these are symmetrical and I can simply solder them the other way.

Here is a view from the top:

I used very aggressive layout for the connectors and I ended with some spare space in the middle of the board. I was thinking to add two automotive type fuse holders for extra protection. I haven’t quite settled on what fuse holder to use. Here are two renderings with the footprints in KiCAD:

And view from the top:

All changes have been pushed to my GitHub design repository page. The version with the fuses is in the tmc2660-fuse branch.

More progress on the Smoothieware for STM32

After a few unsuccessful attempts, I got Smoothie to move my stepper motors on the PrntrBoard controller.

At first the smoothie had a bug in the SPI dirver and was unable to talk to the TMC2130 chips. Fixed that, then the steppers still would not move.

I can see the drivers were sending current, because my power supply would start the fans up, but zero steps. I spend the day trying to diff the configuration between Marlin and Smoothie, but nothing was wrong. Finally caught a bug in the Stepper timers and lo and behold movement.

I’ll make a video of my Rigidbot running Smoothie on STM32 next week.