In a previous blog I tested the printing properties of Proto Pasta’s Conductive PLA and Aromatic Coffee PLA.
According to information from Proto Pasta, Aromatic Coffee Filament is a high temperature blend. Proto Pasta also provides a procedure to anneal it to be harder and more heat-resistant than normal PLA.
A high temperature PLA is appealing to 3D printers. Instead of dealing with the hassles of ABS, or the cost of Nylon filaments, a high temp PLA would appeal to 3D printers that are looking for an easy to print material for the kitchen.
This is an interesting property for PLA. In the past I put standard PLA cookie cutters on the top rack of the dishwasher, only to see them warp like crazy.
For this test I originally tried to 3D print 2 walnut leaf trivets. However, both times I tried printing the print failed. I was printing at 210 C through the hot end, and it seemed that there were a couple of spots in the filament that would not get up to temperature, resulting in a jam.
I switched to a smaller print, a rice spoon. I was able to print one spoon at 210 C, but after another spoon failed to print, I had to bump the hot end temperature to 215 C. Even at this temp, I had moments where filament again jammed. Of course this happened while I was away from the printer for a moment, so I do not know if something else is causing this jamming.
I do not know why this batch of prints was so problematic compared to my previous test print.
To test the properties of annealed PLA, I followed the companies instructions to heat-treat its PLA for two spoons (210 C and 215 C), leaving the other (215 C) as the control.
How To Heat Treat HTPLA
According to Proto Pasta’s instructions,
“For maximum performance, your prints should be heat-treated (i.e. crystallized) in an oven until you see a change from translucent to opaque. Yes, there is an obvious visual change indicating the improved performance! We had good luck in a lab oven at 110C (230F) for an hour or less. We recommend leaving the supports on your parts, placing them on a non-radiating surface (like glass, ceramic, or composite), and letting them cool in the oven to minimize distortion. Parts can be baked at a lower temperature (though must be above 60C for any reaction) for a longer time with less risk of unwanted deformation.”
Before Heat Treating
Two spoons were printed at 215 C. The higher temperature gives them a smoother milky brown tone, compared to the banding I see in the spoon I printed at 210 C.
For the comparison, I’ll use all three spoons.To see if heat treating changes the size, I recorded the measurements of the spoons in the table. All measurements in mm.
Spoon | Handle Width | Handle Length | Bowl Width | Bowl Length
210 C Pre treat | 19.90 | 88.48 | 44.80 | 71.80
210 C post treat | 18.74 | 88.51 | 44.76 | 69.72
215 C control | 19.75 | 88.51 | 44.81 | 71.82
215 C Pre treat | 19.75 | 90.56 | 40.81 | 71.81
215 C post treat | 18.75 | 88.51 | 45.78 | 68.71
I put the 210 C and 215 C samples in a glass dish to heat-treat. I placed the samples in an oven preheated to 110 C (230 F). I then cooked them for an hour, with a half hour cool down time in the oven.
The only change I noticed when I did this was the color. Previously the samples all had bands of light and dark brown. After heating, the samples both turned a uniform light brown compared to the control. The rough layer in one sample piece did shrink, and some hairs and bumps did shrink down as well.
Unlike the time I printed the spoon, my oven did not smell like coffee as it was treated. It also did not melt to the glass dish, though there was a slight film left behind in the dish.
After they were cool, I could not feel any difference in flexibility or strength between the control and heat-treated samples.
Both heat-treated samples shrunk .5 to 2 mm depending on the measurements. In the future I’d test with something like a test cube to get a better idea of how this filament changes directions.
Boiling Water Test
For this test I got a pot of tap water to a rolling boil. I then put a spoon in the water for a minute, and then took them out to see if they were flexible be squeezing them at the spoon bowl and handle.
The control spoon was the most flexible, flexing about 4 mm at the bowl and about 2 mm at the handle.
The 215 C control spoon also lightened significantly in color to a more milky brown, while the heat-treated spoons retained their color.
The heat-treated spoons were slightly less flexible than the control while hot. However, all three spoons became rigid quickly as they cooled.
Heat treating made a small perceivable difference in the warm flexibility of the test samples. If you plan to use Aromatic Coffee PLA in your kitchen for things like stirring spoons or soup spoons, you may be able to justify the time it takes to heat-treat the material.
But for other uses, I can’t say it’s worth the time to heat-treat this filament. Being a high temperature PLA, you can use it as is for medium temperature applications. The heat treating may keep it rigid at higher temperatures, but not by much.
The appeal of Aromatic Coffee HTPLA is the novelty of your printer smelling like coffee as you print. As to the high temperature properties, It is more durable than standard PLA, which bodes well for it. As to its heat treatment, I can’t say it makes much difference at all.
If you buy Aromatic Coffee HTPLA, you’re paying the premium for the coffee smell and novelty value of the filament.
If you make filament and want me to review it, please contact me Stan@3dpt.club or leave a comment in the section below.