Rethink how you use 3D printer infill!

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Ah, 3D printer infill. A topic that’s so full of  polarized points of views, personal preferences  

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and passionate presumptions that I thought, well  this is something that I can jump into and surely  

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not get wrapped up in any controversies. Perfect. But on a serious note, there are still plenty  

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of things that don’t have a  definitive answer yet, so today,  

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I want to test three different aspects to infill: First, what is the “best” infill pattern? And yes,  

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“best” almost never has one single answer, so  this breaks down into a couple of sub-sections.  

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I’ll be comparing both how fast they print, how  strong they are, and how good of a job they do  

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supporting the print’s top surface, because yes,  sometimes all you care about is your print’s  

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looks, and not how rigid or strong they are. And I’ll be doing all of this with the same amount  

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of material used for each pattern, not just with  the same infill percentage - because turns out,  

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you can’t trust the infill percentage  number at all when changing patterns. 

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Second, should you be printing your infill  with a thicker nozzle? This keeps coming up  

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as an argument for dual-extruder or toolchanger  printers, basically saying you can speed up your  

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prints by just using a fatter nozzle for the  infill when you won’t be seeing it anyway.  

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But that also makes the infill structure  coarser, so is it worth the speed gain? 

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And third, more infill or a thicker shell?  The engineering logic is that you should  

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always prefer putting more material into the  shell of your parts, because that’s where the  

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majority of the strain is happening, but there  has got to be a crossover point where there’s  

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simply not enough infill to support the  shells, so we’ll find that point, again,  

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keeping the amount of filament used constant. I’ll be printing all this on the XL,  

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because that’s the only printer where I can chuck  up different nozzle sizes and use them in the same  

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print. For filament, I thought about materials  I would actually use when strength matters. PLA  

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is very rigid and strong, but it also likes  to creep and when you really need strength in  

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mechanical applications, you quite often also  have at least some amount of heat involved,  

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so while it may make for some easy testing, PLA  just seemed a bit pointless. The other end of the  

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spectrum with polycarbonates, ABS or ASA are  good candidates for mechanical applications,  

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but because I don’t have the enclosure set  up yet and even then, I don’t think it would  

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be controlled to a consistent temperature, so  I compromised and used PETG. It’s the softest  

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of materials and might sometimes bend instead  of snapping off, but that’s still good data.

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And what a coincidence - all the PETG I’ll  be using is from today’s sponsor, VOXELPLA! 

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Their PETG Plus and PLA Pro are among the most  affordable filament choices you can print with  

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at just $16.99 per spool or even less with bulk  discounts. VOXEL filaments are exclusively used  

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in their 150-machine print farm in Southern  California - and I only have good things to  

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report about them as well. They print great  with default profiles and no tweaking,  

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they’re suitable for high-flow printing and  have been a perfectly reliable choice for me. 

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Also check out their printer upgrades  like the Bento Box Air Filter,  

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HULA Vibration Damper, and the Python  AMS Dryer Upgrade - at the link below.

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Let’s get started with infill patterns. I’m  going to group these into four categories:  

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“2D”, “3D”, “specialty”, and “dubious”. In the  basic 2D camp, we’ve got old favorites like grid,  

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triangles, stars and honeycomb. The odd one out  here is honeycomb, because it’s the only one that  

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avoids crossing over itself and instead creates  double-width walls in some spots. Crossing over  

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already printed paths can be an issue, especially  when going fast, because you’ll often see the  

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extruded line rip and tear at those points, which  can weaken the infill structure as a whole. But  

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honeycomb, being a hexagonal pattern, has tons  of corners that the printer has to slow down  

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for, so it’s a rather slow pattern to print.  We’ll get to the exact print speeds in a bit,  

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but as a rough estimate, for the same amount  of material, honeycomb takes about 20% longer  

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to print, and that difference only goes up  the faster your maximum print speeds are. 

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Then, the 3D group, the cool kids of the  bunch: cubic and its varieties, 3D honeycomb,  

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and gyroid. 3D honeycomb and gyroid are  both no-cross patterns too, but again,  

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they’re both on the slower side. The gyroid  pattern is explicitly meant to have even strength  

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in all directions and uses a very organic  pattern, while 3D honeycomb is more of an  

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octagonal pattern that changes print direction  every layer. Cubic is actually just cubes stacked  

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on their corners, hence the name, so it looks a  lot fancier in the slicer than it actually is,  

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and essentially, it’s just a tilted version  of grid if it were to print a solid layer  

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every couple of layers. I do like the 3D  patterns because I feel like they do a better job  

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of consistently providing some support for top  surfaces and tying together perimeters that may  

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not ever get crossed by the static 2D patterns. Then, “specialty”. These are circumstantially  

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useful, and that’s lightning infill, which is  designed to use as little material as possible  

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while still holding up the top solid surface,  and support cubic, which… does the same thing,  

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but with the cubic pattern that prints tighter  and tighter cubes the closer you get to the top  

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surface. Neither one of these is designed for  strength, but just to give you good-looking  

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parts. I’ve printed some samples with lightning  infill anyway, but since its strength literally  

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depends on which way you hold it, this  is more for completeness than anything. 

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And then the “dubious” patterns. I mean, I see  why they’re in here, and that’s because they are,  

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by their mathematical definition, patterns  that fill in a surface, with an adjustable  

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amount of fill density. Yay! These all happen to  be non-crossing patterns by the way, but honestly,  

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I don’t think these will provide any value at all,  but hey, I’m very open to be convinced otherwise. 

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The most striking one certainly is the  Hilbert curve. It’s more of a mathematical  

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phenomenon than an actually mechanically sound  concept, but I have to admit, it does look  

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cool! I’d also put concentric, Archimedian  Chords, and Octagram Spiral in that camp. 

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Rectangular looks similar to grid, only that each  layer is exclusively printed in one direction, and  

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it alternates every layer. So this is a pattern  that only has point contact between the layers and  

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uses most of its material in unsupported bridges. Aligned rectilinear is the same pattern,  

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just with all the layers aligned in the  same direction. Makes sense. And lastly,  

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the line infill once again is the same  pattern as rectilinear, but this time, drunk.

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I still printed all of the patterns as test parts,  and because my intuition would be that the effect  

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of the different infill patterns would be more  pronounced the more space it has to work with,  

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but printing samples large enough where  especially the 3D patterns don’t just turn  

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into mush would mean I’d samples that would end  up breaking me instead of me breaking them. So  

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I simply scaled everything down and used a  0.25mm nozzle for the parts. The parts all  

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printed perfectly with the smaller nozzle, so  all I’m doing is scaling down the strength of  

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all the parts evenly. This, of course, also  saved me a bunch of filament and print time.

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Speaking of time, here’s how the  patterns stacked up for print times: 

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Basically, there is a fast group and a slow group,  but within each group, you’re probably not going  

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to notice a dramatic difference in print times.  But when going from a “fast” pattern to a “slow”  

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one, print times increased on average by a third,  and that is with the same amount of material laid  

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down in each of these prints. As expected,  patterns that use many short moves instead  

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of longer continuous ones do take significantly  longer; with the fastest one being concentric,  

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which does one single, continuous line, making  it very hard to beat. The default grid pattern is  

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tied for second place with the three rectangular  varieties that also just print straight lines,  

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followed by Stars, Cubic and Triangles. The slowest pattern overall is Lightning,  

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but it’s an odd one out, because a) I couldn’t get  it to lay down so much material that it would use  

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as much as the others, and b) it’s not meant  to be used at such high infill ratios anyway,  

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all it does is make the very top structure denser,  which, at a certain point, just ends up being  

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material that doesn’t really help the print. Over in the “slow” group, gyroid is the fastest  

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pattern, and while it didn’t make much difference  for print times back when the pattern was first  

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introduced before input shaping had become a  thing, with printers moving much faster now, it  

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means that they have to slow down to accurately  print the swirly goodness that is gyroid. 

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But maybe it makes up for it with its strength?  Well, sort of. It takes third place. Second  

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place is actually the fastest-printing pattern,  concentric. Though take this with a grain of salt,  

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because concentric doesn’t have  a consistent pattern throughout,  

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and I think really, we just got lucky here  and managed to get a spot that was perfectly  

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oriented for the bend load I was applying. Most of the other patterns form a surprisingly  

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tight middle group, with the only outliers  being lightning, again, not meant for strength,  

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and Hilbertcurve, which falls into the same  camp as Concentric, Archimedian Chords,  

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Octagram Spiral, of not being a consistent  pattern, which I think disqualifies all of  

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them from being used for structural prints. And if you’ve been counting cards,  

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you’ll know what the top spot is - it’s  cubic! With a significant lead, actually! 

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Now, caveats. I tested these patterns printed  flat and on their side, but not in any other  

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orientation, so some patterns might behave  differently in slightly different alignments;  

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and I only tested for bend load, as it’s  the easiest one for me to test, but also,  

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most real-life loads end up inducing a bend  load of at least some amount of significance. 

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Also, while these results are consistent for this  geometry with this combination of print profile,  

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machine and material, things might  slightly change with different part  

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geometries, and with filament that’s  more or less rigid or has higher or  

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lower material strength. But I think the  general trends should still transfer.

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We’re going to dive a bit deeper  on strength in a bit, but first,  

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let’s look at top solid layer support.  The test prints for these were done  

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with only three top solid layers  and roughly 10% infill, again,  

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I had to adjust each pattern individually to make  sure they all used the same amount of material. 

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And all these prints look about the same. They  all have some areas where they covered well,  

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other bits where they didn’t do so  well, except… for aligned rectilinear.  

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That one is almost perfect, and it makes total  sense! All the other patterns have sections where  

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that first solid layer has to span a distance  that’s too large to bridge over cleanly,  

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but because aligned rectangular is, well, aligned,  it ends up being perfectly at a 90° angle, which  

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gives that first solid layer the perfect geometry  to bridge over. Even lightning isn’t this good! 

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One interesting thing here is that between  the regular cubic and the support cubic print,  

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the support cubic one does print a coarser  structure down low, as it should, but because  

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it then wastes material on printing double walls  as it transitions to the full-density pattern,  

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if you actually give it the same total amount of  material to use, it has the exact same density  

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of pattern when it gets to the top where it  supports the top solid layers. With larger parts,  

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there is an actual benefit to using support cubic,  but keep in mind that if you just give the support  

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and adaptive cubic patterns the same infill  percentage, without even doing anything adaptive,  

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they will by default create a coarser structure  and use less material than standard cubic.

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I know I’m talking a lot about cubic, because  that’s the pattern that I think so far comes out  

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as the overall winner. It’s very strong, prints  quickly and doesn’t show issues with its ability  

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to support material printed on top of it. So  it’s the pattern I’m moving forward with for the  

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next test, and that is figuring out whether  you can just print your infill thicker. Now,  

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this was all done on the XL because I could mix  and match nozzle sizes. But as good as these parts  

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look, the alignment issues struck once again and  while one side is perfectly bonded between the  

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shell done on one nozzle and the infill done on  another, the other side was completely loose, and  

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this isn’t exactly good for strength. Maybe I’ll  come back in the future and explore this topic  

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more, but for this video, I had to compromise  and just print everything with one nozzle and  

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different extrusion widths, which worked really  well, too, but it’s not the cool two-color look  

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I was going for. The results with what  I tested here, though, are promising,  

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and there doesn’t seem to be any significant  loss in strength with printing the infill wider  

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and faster. But again, this was fairly limited  testing and more exploration is required here.

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And lastly, and this was actually the biggest  chunk of printing, where should you put your  

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material - into the infill or into the perimeter?  I need to explain my methodology here real quick.  

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I wanted to test 1, 2, 3, 4 and 5 perimeters,  so I started with a 30% infill part for each  

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one. I then looked at the weight of each of those  samples and for each series, adjusted the infill  

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percentage for all the other perimeter counts  until I had a set of parts that all used the same  

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amount of filament, just distributed differently.  And of course, I did that for all the other other  

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starting points as well, I also used 5 perimeters  and 50% infill as a high-fill starting point,  

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and a single 100% print. By the way, when I say  “perimeters”, I actually mean “shell thickness”, I  

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did increase the top and bottom minimum thickness  to be identical to the actual perimeters.

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And these ended up being quite interesting,  or boring, depending on which way you look  

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at it. There was not a single instance where  more infill ended up being the better choice  

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over a thicker shell. This is the result that  one should expect, but I definitely thought we  

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would be running into issues with things like  wall buckling which would reduce strength, but  

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it looks like those might only start becoming an  issue once you go into the extremes with almost no  

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infill and very thin shells, but since I’m testing  for strength, I wanted to use settings that you’d  

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typically for functional parts, so those sort  of featherweight prints aren’t included here,  

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but they might still hold some interesting data. Now, while these trends would suggest that the  

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best setting to use for strength would be as  thick of a shell as you can get and zero infill,  

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I wouldn’t say that that’s universally true.  Again, it’s true for this one part shape,  

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but I can easily think of a bunch of shapes that  would profit from at least some amount of infill.  

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Let’s say you have a large flat part, that would  not just be unprintable without infill, it would  

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also be pretty bad at supporting any amount of  weight. Or something that has, like, a corrugated  

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or baffle-shaped outer wall, even just a small  amount of infill would help with the strength and  

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rigidity of that part much more than extra shells. So with typical prints, which are most often  

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compact parts with walls that are a couple of  millimeters thick, your material will still be  

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best used in the shell and not in the infill.  I guess as a rule of thumb - I’d say use just  

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enough infill, 15, 20% so that your part prints  cleanly, and then use whatever you would have put  

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into the infill to increase the shell  thickness. And even in high-infill situations,  

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you’re probably not going to need to go above 30%. And for patterns, honestly, I think your and your  

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slicer’s default should be cubic. Maybe even  adaptive cubic, because that will conveniently  

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save some material with really chunky parts while  behaving like regular cubic otherwise as long as  

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you account for the difference in fill density at  the same percentage. And if you don’t care about  

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strength and just want fast, clean prints, maybe  even give aligned rectilinear a try! Just don’t  

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forget to add a solid layer every now and then. Let me know what your experiences have been  

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when printing structural parts - do you  have a favorite infill pattern? I’d love  

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to hear from you in the comments below. As always, I hope you learned something,  

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thanks for watching, keep on making,  and I’ll see you in the next one.