PCTG
claims to be a better alternative to the well-known PETG and, even more importantly, brags with
similar strength values regardless of the printing orientation, so perfect layer adhesion!
Too good to be true? Let’s find out more! Guten Tag everybody, I’m Stefan, and welcome
to CNC Kitchen! First things first: PCTG doesn’t have anything
to do with Polycarbonate. If you’re interested in Polycarbonate or Polycarbonate blends,
make sure to be subscribed because I’ve got reviews of Prusa’s PCBlend and the even
cooler Carbon Fiber PCBlend coming up! PCTG in its full, written form is hard to
pronounce but it’s similarly to PETG and also a glycol modified Copolyester for better
printability and material performance. It claims to be an alternative to PETG only with
better impact strength, surface gloss, and for me, more importantly, almost perfect layer
adhesion, and this is also why I was approached by so many to test this material. And this
is exactly what I did! We’ll take a look at print quality, tensile strength, stiffness,
impact resistance, and thermal resistance to find out if the claims hold true and if
this material is something you should consider for your next project!
Essentium sent me two rolls of their PCTG to try out because I wasn’t able to find
their material here in Germany. It sells for $40 for a 750g spool in the US, which makes
$53 per kilo. Therefore, it’s not a super cheap material but definitely more affordable
than other engineering materials. If you want to buy PCTG filament in Europe, check out
Fiberlogy PCTG filament that also even comes cheaper at a very competitive price of 36€
per kilo. Since each of the manufacturers might use different grades of raw material,
I unfortunately can’t tell if they will perform exactly the same but just looking
at the datasheets they do seem very similar. Speaking of datasheets, I was really happy
to see that Essentium provided a proper one that even includes drying instructions!
Their PCTG comes sealed in a nice Mylar bag because the material seems susceptible to
moisture. Only those metalized plastic bags will really hold back the moisture during
shipping and storing. I directly transferred the spool into one of my dry-boxes, out of
which I printed all of the parts to avoid moisture uptake. I used the clear natural
color for all mechanical tests, though they also sell this material in black and white.
I started with my general print settings test and printed 100% infill boxes on supports
to find the right extrusion amount. Then I printed Joe’s temperature test tower two
times. On one, I varied the fan speed from 0 to 100%, keeping the extrusion temperature
in the middle of the recommended temperature range. On the other, I varied extrusion temperatures
between 280°C to 240°C while keeping the fan speed constant. I first tried printing
on glue stick covered PEI, which didn’t work perfectly though switching to directly
printing on powder coated PEI did the trick, and parts held firmly on the plate using bed
temperatures of 85°C and released easily after cooling down. Essentium PCTG prints
without any smell, though especially due to the high extrusion temperatures, I can only
recommended to print it in a well-ventilated area. An extrusion factor of 1.0 seemed to
provide very nice results with no under or over-extrusion.
PCTG seems to need at least a minimum amount of cooling if you have bridges and overhangs
because with no cooling fan at all, the results looked horrible. Starting at 25% fan, the
print quality became nicer and nicer. Print quality for an engineering material is not
everything, so what I tend to do when printing these towers is that I break the spikes to
get an impression about layer strength. Without fan and even with 25% cooling, the spike only
bent but didn’t break, which already speaks for its layer strength. The more cooling,
the easier it was to break the spikes off. The temperature variation tower showed very
similar results in the whole temperature range with a bit more stringing at higher temperatures
and a slightly matte surface at lower temperatures. The spikes printed at 280°C and 270°C again
only just bent. The lower I went, the easier it was to break them off, so printing hot
seems to be necessary for high strength. Looking at these extrusion temperatures already shown
us one challenge with this material. Due to its requirements in nozzle temperature, I
highly suggest using this material only with an all-metal hotend. Anything PTFE lined will
give you a bad time pretty soon. In the end, I settled with 270°C on the nozzle and 30%
cooling fan for the rest of my test prints. Using these settings, I printed a bunch of
quality test parts. Overhangs looked great and only showed some artifacts at a 75° angle.
The stringing test looked nice with just a bit of tiny hairs and even small details came
out nicely. Bridges were very impressive and printed almost flawlessly up to the biggest
gap of 100mm. This all resulted in an almost perfect 3DBenchy with very nice and shiny
surfaces and good detail reproduction. So in terms of print quality on a very similar
level as a good spool of PETG with a bit more gloss and with hopefully better mechanical
strength. Also, the other parts I printed came out very nice and shiny and shows the
materials’ visual appeal! The strength test parts were all printed in
my office at around 22°C without any enclosure. The materials hardly warped, and I was able
to even print these big samples without them lifting from the print platform even not using
a brim. Let’s start with tensile strength. If you’re
by the way interested in the full test reports, they are available for my Patrons! For the
samples printed flat, I tested standard dogbone samples as well as my mini specimens. Both
showed very similar results, and the PCTG was able to bear around 48 to 51 MPa of stress
until it severely started yielding. The way the material is necking shows that it’s
very ductile and will not break as unpredictably as, for example, regular PLA. Comparing that
value to other materials shows that it’s definitely not the strongest but well in the
range of what you’d also expect from PETG. Where it gets interesting is when we take
a look at layer adhesion so, when we test samples that were printed standing. Just bending
one of these samples by hand shows that they don’t simply break between the layers but
nicely yield. Unfortunately, if we take a look at the raw numbers, we can see that the
samples printed standing didn’t yield that nicely and were at least a little weaker than
the ones printed flat. With 38 MPa layer strength, they still have one of the best layer adhesion
ratios I’ve ever tested. I even gave it a second chance and printed samples with only
10% part cooling instead of 30%. Here the strength increased slightly but I still was
only able to improve the layer adhesion strength to 40 MPa.
Next I tested the bending stiffness of Essentiums PCTG by loading a testbar with increasing
weights on my 3-point-bending rig and noted down the deformation. With 1600 MPa it’s
a rather soft material in-between Nylon and ABS or PETG, so not the best choice for applications
where you need rigidity. My test hook is representing a more realistic
part with a combined loadcase of bending and tension. The hook that was printed flat failed
at 58 kg but didn’t just rip and nicely yielded. The hook I printed standing failed
significantly lower at only 36 kg which is the same load level where also the other sample
failed that was printed with only 10% part cooling. This again showsn that the material
properties are not isotropic though layer adhesion is still better than with many other
filaments. Turning partcooling totally off might improve strength even further but might
result in severe degradation of quality. Next we get to impact strength which is a
property many are not aware, that is kind of bad for PETG. PCTG was able to really shine
here and the notched samples were able to absorb around 24 kJ/m² which puts it way
above PLA and PETG and on a similar level as for example ABS. Unfortunately, the samples
printed standing performed way worse and had an impact strength of only 1.5 kJ/m² on average.
Similar to most other polymers in such a situation but again just shown that this is still not
the perfect 3D printing material. Finally let’s take a look at the temperature
resistance of this material. For that test I put a bar which is loaded in the middle
into my oven and gradually increased the temperature. At 80 °C it became soft and then totally
failed just a couple of degrees above. Comparing that to other materials it’s very similar
to PETG and should therefore also be able to cope with the temperatures on a hot day
though I would have somehow expected more due to the necessary high printing temperatures
of around 270°C. And there we have it! Is PCTG the new wonder-material?
No but still a bit yes. I wasn’t able to reproduce the perfect isotropic properties
of this material claimed by some, though still, in terms of layer adhesion the material basically
outperformed almost anything else which does still make it very usable in technical applications
together with the high impact strength. I heared from others that they had problems
with brittleness and bad layer adhesion, so make sure to keep the material very dry, print
as hot as possible and with very little to no cooling. Printability, if your Hotend can
handle it, was awesome, with very nice and shine surfaces, nice overhangs and bridges
with only a bit of stringing. In the end, it is in almost any way a better material
than PETG while still retaining a reasonable price. I personally enjoyed working with this
material and see it as an easier to use alternative to Nylon or pure Polycarbonate and honestly
don’t know why there aren’t that many other PCTG filaments out in the wild. But
what’s your opinion. Where do you see the applications for this material and would you
consider buying a roll for your next project? Thanks for watching everyone I hope you’re
all doing well! If you found this video helpful than leave a like, share it with the community
and make sure that you're subscribed. If you want to support the channel, head over to
Patreon, become a YouTube member or even check out my merch! Stay healthy, auf wiedersehen
and until next time !
Just did some reading up on this and I’m definitely going to be ordering some. I’d love to see someone do some side by side strength test comparisons against PLA+, ABS, etc.
Edit: just actually watched the video and this looks sick.
The thing that worries me is that it's less rigid than PETG, which is already much less rigid than PLA