Surprised you didn't try nut pockets (what prusa does with their printer parts). That creates a nice solid wall that isn't distorted by brass teeth. I typically use wood screws if it's a one time use, and the inserts if it's a part that may need dis-assembly (also looks more professional). In injection molding it's exactly the same, if it's a one time assembly then self-tapping, if it needs to be serviceable there better be inserts included.

I think it could be interesting to see how the number of perimeters around the hole and the type of infill (geometry and density) affects the strength of the insert (using CNC kitchen ones for example)

Flip the camera inserts to the other side of the printed piece. That way you have a larger flange you are pulling against the print. Essentially acting as a larger backup washer.

Test it with a regular hex nut countersink in a hexagon hole from the back on the part or a square hole in side the part and push the nut in from the side. I do this all the time and it works perfect and does not require any special nuts.

Friendly tip - for anything starting at M4+, I am not using inserts for plastic, but inserts for wood. They have larger diameter of the metal part. And I am heating them up and screwing them to the plastic - significantly increasing the contact area. Works much better. And the best part - you can then screw in the bolt from the other side, make the insert invisible and even stronger :)

Just a FYI, spiral fluted taps are much better suited to tapping plastics and soft materials like aluminum as they evacuate the chips while tapping.

Perhaps consider printing a 100% infill 'doughnut' of say 10mm around each insert/tap/thread point to eliminate some of the variability caused by your part flex and infill interface, along with using an omnidirectional infill like Gyroid. It would improve pull-to-pull consistency and more accurately demonstrate the ultimate/average strength of each method.

I typically use self-tapping 3mm screws in 2mm holes with no printed thread. Even for parts that need occasional disassembly and re-assembly they work great. And let's not forget that lots of injection molded cases do the same thing. And in my experience PLA parts survive unscrewing and rescrewing better than the industrially produced ABS parts. As I'm writing this I'm printing 3.5" to 5.25" mounting adapters that I designed today (because the ones on Thingiverse are all just imitations of mass produced parts and these designs work poorly for 3D printing) and the means of fastening the adapter to the PC case is by means of 3mm self-tapping screws. I always use the longest screws that will fit.

In combat robots, we all use plastite screws. They have triangular lobe coarse threads. You just screw them into the plastic, no tapping required. A common failure mode we see are heat set inserts pulling out, but the plastite screws fare much better. We also tend to use a lot of walls since we’re printing for strength. Usually 3mm walls or more. Plastites are also lighter than inserts.

Would be more interesting to test screws made for screwing into plastic, like "plastite" instead of screwing ISO screws directly into plastic. Right tool for the right job!

LOVED the Blondihacks "Yahtzee" nod with the lathe part-off 😂

A handy tip for increasing the number of perimeters around just a hole: You can put an infinitesimally thin annular gap spaced out a few perimeters lines from the ID of the hole. This will force the slicer to an extra set of perimeter lines around the hole without having the increase the number of perimeters everywhere. I'll actually put these phantom gaps anywhere I need to add solid perimeter lines in an area that would otherwise just be infill.

For the past 5-6 years I’ve just self-tapped into a tighter printed hole and had excellent results that way. Yes, occasionally I’ll use a nut on the back and once or twice inserts but for 90% of the loads I put my prints through (including my CNC machine), the self-tapped printed holes seems just fine.

FYI, when you tap plastic you should hand tap not use a drill, you will heat up the part and melt it. Also do 1 revolution and clean out the tap, then continue the next revolution and cleaning until you are done. If not you will mess up the threads. Also don’t lube the PLA, oil will weaken it.

In my experience the screws for wood work much better. The hole in the printed part should be a bit bigger than the core and since these screws have a very deep and sharp thread, they usually connect very nicely with the part. The failure point is typically the connection between the printed hole and the rest of the part. For tapping the thread into PLA i found that a decent lubrication makes the process almost perfect. I typically use some grease since it does not flow away unlike oil. By the way adding a little of grease on woodscrews eases the joint process a lot. Cheers

Love the machining work and the Quinn reference, yahtzee! Would like to see your mill and lathe setups more!

I usually embed nuts inside the print by modeling a cavity and pausing the print at the top layer of the cavity. Nuts are usually a lot easier to find for a particular size than threaded inserts, and more broadly useful. If you need even more strength, modeling in space for a steel washer between the nut and the inside wall of the part increases the engagement with the plastic part by quite a bit.

My favorite is the wood thread insert with spikes on a flat washer on the back of the part. Also always add some extra walls around the thread and it won’t pull out but generally I’d print a section of 100% infill there anyways. If you can get 4x diameter on the hole depth, printed threads chased with a forming tap are wicked strong. And like others said, burying a nut in the print in some way is always a super good option. If the nut is near an edge, you can add a keyhole slot on the side to slip the nut in and then screw through the front. I had to make a super tricky assembly once and used a thick 3mm washer tapped for an m4 bolt and slipped it in through a side slot that got plugged with epoxy to hold the threaded washer and plug in.

Did you test torque-out at all? Because that pull-out test is honestly almost entirely pointless as that is just not the way you use them in, dare I say it, almost any case.

I'd be really interested in seeing the results of different infills as the failure mode was always to rip the connecting walls, I think that'd be much more useful for figuring out how to get the strongest output for each usage case!

Please also test the strength of self tapping screws. The "threads" of those, are spread over several layers, and seams to make a quite strong bond. It's a way quicker solution to use, that I have had good succes with.

For extremely small screws (M2, M2.5, M3) I tend to just screw directly into an oversized printed hole; basically the tapping method, but skipping the tapping step. I get fine results, but I'm also never designing parts for strain, just assembly.

I like to use “alternate extra walls” and “connect infill lines” to really boost the strength of printed parts. The perimeters become interlaced with the infill structure and resists pullout and deformation. I use grid for faster prints but prefer gyroidal for strength in all directions or for parts susceptible to warping.

My solution (not applicable everywhere but..) is adding a little pocket for a square nut.. it's not going anywhere and it's fairly cheap.

First year Uni manufacturing here in Australia taught me that a bolt has a un-threaded shank portion where as a machine screw (not a wood screw) is threaded all the way to the head. Love the testing videos, keep up the great work.

The vast majority of installation torque (80-90% in steel nuts and bolts) goes into overcoming friction so it's not a good way of measuring pull out force. Once installed the assembly strength is determined by bearing and pullout strengths, not twisting of the insert.

Great video 👍 something that people don't often talk or think about is that in many cases threaded inserts aren't necessarily "stronger" than direct threading...but in applications where you need to often remove a threaded fastener (eg. a thumbscrew) they are a must (for example helicoils in aluminum).

This video needed to be made, thank you. Please test nut captures and the strength of inserts from the opposite side. Tapping holes with a hand drill is something I never do regardless of material as while it takes a little longer I find that doing it by hand results is less damage to the threads especially for fine pitch threads.

I find myself wondering about the testing methodology. When turning a screw in PLA, won't the friction heat/weaken the PLA giving the metal on metal solutions an unfair advantage?

Hi Thomas, first at all thank you for your always excellent videos. If this video, you are in fact testing resistance vs. torque which is fine to know how the attachment will resist to an over torque. But according to me, should you be able to test resistance vs. axial force, this will provide tremendous inputs on how these fixtures resist under load. And we could have some surprise with plastic tapping. And should you be also able to test self-tapping screws at the same time, this will give us a whole overview of attachment resistance.

Few other types of threaded inserts: "thin wall threaded insert" and "helicoil" both would be interesting to have in the comparison. As another comment mentioned, would be interesting to know print settings and do a review on things to improve the joint. I would also love to see how using a "matching" grade of screw would affect the strength of joint (i.e plastic screws). Ace video as always Tom, loving the new clean feel of the production.👍

Two ideas I have are creating a wide ring in the middle of the screw hole that acts like an anchor in the shape of a washer. Or creating a recessed area on the backside to actually install something like a fender washer to spread the load out if you really need the strength.

I personally think, the Torqueout Test won't give completely comparable results, because of different coefficients of friction (galvanized steel bolt - PLA/brass/Nickel plated brass). A pullout test would give indefent results, sadly requires a test machine. But I think the "ranking" would be quite similar. I tend to use woodscrews for simple "once" connections, Bolts in printed threads if the simple connection needs to be a bolt for other design reasons. Sometimes printing only the first few millimeters and let the Bolt cut the rest by itself (friction stops unwanted rotations). Heat inserts only when I need wear resistance, if even more is needed Ensat-Gewindeeinsätze. Really strong threads I get by designing in massively longer threading depth or a nut placed inside during the print.

Hi, I use the best combination of materials. Let me explain: if I'm working with plastic, I also use a plastic screw. But too small sizes often do not allow this. So I place the empty space under the female screw and then pause the slicer on the last layer to place the nut there. As a result, I have a part that fits the hole perfectly, has the correct threads and the right material hardness. I would be glad to see similar tests with my method of making threads

I would love for you to test the direction of pulling out, AFAIK, Voron parts sometimes have you thread in the direction of installation and sometimes opposite. Taking your thread adapter into consideration, the large flange on the end would take a LOT of force to pull out in the opposite side of the install. Also it would be nice to know how much the different techniques of linking the perimeters to the infill would work! Great video!

Another thing which is worth noting, is loosening of the screws over time. Having a metal threaded insert allows you to use a more diverse range of threadlockers (e.g. Loctite 222 or 243 etc). I designed a custom hotend shroud and ended up simply under-sizing the holes and forcing machine screws through as "self-tappers" which holds pretty well, but the screws do end up getting loose (I think it's because the bowden tube puts varying pressure on the hotend as it travels across the x-axis). Something else worth testing, is instead of using machine-screws, use actual thread forming screws meant for self-tapping into plastic. They tend to have a sharper, more coarse thread and are often seen in injection molded parts.

A few things spring to mind here: 1) If the limiting factor is the perimeters around the hole, beefing that up to the point where the insert turns in or pulls out seems necessary to get meaningful test data on the insert or thread. 2) I don't advise tapping under power for this sort of thing - use a manual hand-operated tap wrench. It'll keep the heat down and you'll be able to feel what you're doing. I've actually used threaded inserts and stainless machine screws to replace self tappers on bits of plastic under-bonnet trim on my car - they are a huge improvement! 19 years of taking those old self-tappers in and out doing maintenance and they didn't really tighten up properly anymore. A great quality of life modification.

What about wood screws? They are made to hold on to the wood fibers that are weaker than metal. They are also very cheap

I am surprised you tried to tap the holes... what i do is print a perfect hole (lets say 2.9mm in diameter for m3) and then slowly let the screw make its own "threads" while going in, I found its a really nice and strong solution... probably stronger than modeled or tap holes...

Super interesting. Personnaly I usually extrude the shape of the nut from the other side of the part. thats my prefered solution as you often get the nut provided with the bolt, you dont have to buy plenty of insert or spend the time inserting them. Maybe you can do an addon video and compare to these results to this method, that would interest me a lot. Thanks !

Great idea to run this test. I did 3 years ago a similar test for my machine designs and found out Prusa Pla is the best PLA for this application (the strongest, less ductile) and actually don‘t put a insert in and don‘t tap the hole. Just put around 4 perimiters and let the screw tap itself while screwing it in. With PLA this generates that much heat from friction that a perfect new thread forms around the screw, which additionally acts like loctite and is self locking. Takes some time to find the right hole diameter for each screw, but worth it.

I prefer cut threads for everything below m6. I use 3d printing mainly to prototype parts that eventually get machined. 99% of the time some cheap PLA is sufficient for my needs. usually I print with 3-5 perimeters. I usually use alcohol as cutting fluid. few drops of cutting oil dissolved in the alcohol works even better. also aluminium taps work way better then normal ones (the ones that have every other tooth missing to reduce friction) through hole whenever possible, bottoming taps that push the swarf up only when really necessary. ...in 3d printing I can make the hole super deep or all the way through the part even if I'm not going to do that on the machined part for obvious reasons. a final note: for embedded nuts: get some square ones - they work better in every regard I can think of compared to hex nuts when it comes to incorporating them into 3d prints. (don't rotate as easy, easier to design the pocket/slot, usually better bridging if pocket has to be upside down...)

Tom, I doubt you'll even see this but, we need a machining channel from you. I also see you for your blondiehacks reference! Been watching for a decade or so. I can't thank you enough for the knowledge you've shared.

This is a valuable contribution to 3D print engineering, Tom!

I switched from stocking machine screws to self tapping plastic-threading screws a little while ago and have had a fantastic time with them! Most of my parts aren't particularly load-bearing, but need to be held together... They're just so simple to add to a design!

Yea, dont power tap plastic dude. Especially fine threads. This is the second video of this channel I've seen today where your process is severely flawed because you have no idea what you're doing. How about doing some research first. Blind leading the blind.

Thomas, in tru holes you are blessed with having the possibility of using the insert from the backside of your workpiece. which creates the fact you have to pull the insert not only out but also tru the complete printing. And a bit of a hassle but you can also demonstrate the "print in place" possibility, if someone might be interested. possible with an ordinary nut.

You should be able to test for lead content of the Alibaba inserts using a swipe test. These are marketed for use in testing house paint and toys, but would work for this purpose too.

my favorite by far is taking one of the screws I'm going to use for the project and then cutting relief slots at the tip with a Dremel and cutting wheel. I then use that one screw to tap and clean all the screw holes leaving perfectly matched treads. The end result is better than printed threads, not quite as good as using wood screws but there are more head shape options and definitely not as strong as bolt and nut but definitely less fussy.

I am just saying this before watching... I print all my threads on my designs and don't have an issue, so I am very interested in the results. EDIT: now having watched it I can see how the inserts would have a benefit but unless there is a need for more strength I'll stock with printed

Thank you for putting in the research work! Since you asked what to check next: Self-tapping screws, wood screws, inserting nuts, use of washers (larger area might not pull out as easily?), using the inserts from the other side (pulling through the entire part instead of pulling them back out where they inserted) and of course more walls / more infill / both...

you are washing your hands too much with harsh alcohol hand sanitizer ? you need to moisturize !

Large diameter steel washers can spread the load over a wider area of the plastic when used in conjunction with a steel not. A thread for the screw can be included in the hole so that a lockout effect can be achieved with the steel nut.

For the love of god please moisture your hands 🫣🥲

I've found that friction threading fasteners into unthreaded holes works quite well.... What you do is you rapidly turn the fastener in about a 1/4 turn then back out a little less than 1/4 then back in a 1/4 until the fastener is seated. The friction from this rapid back and forth heats the fastener so it doesn't cut rather it melts it's thread into the plastic. If you size the hole correctly it will take a little bit of muscle to seat the fastener and you will be able to feel the resistance slightly lower when the fastener starts melting it's way in.... The result should be a tight thread with it's layer lines fused together. Something you will not get from a printed tread. Also this method of threading does not clog the hole or remove any plastic. The plastic is pushed outward into the walls, if anything leaving the wall thickness slightly higher.....I've used the word fastener in this description over bolt because I've used this method with screws as well as bolts up to 1/4-20. Other than that if I just need a thread in my print where the bolt will be repeatedly adjusted I heat set an ordinary nut into the print. Which is cheap strong wears good and I don't have to order anything online to complete my project. With heat set nuts I print a hexagonal recess in the hole slightly smaller than the nut and push the nut in with soldering iron set to as low a temp as I can where the nut will still push in. Like with fiction threaded fasteners no plastic is pushed down into the hole. The plastic is instead also pushed outward increasing the wall thickness. So far I have had zero issues with pullout of friction threaded fasteners and heat set ordinary nuts have only failed in bad designs and when over torqued.

Thanks for another great test. This was basically already the conclusion that I have come to over the years. If I only ever intend to screw something together once, I may just size the hole so the screw bites in and cuts threads, or use a nut. Same for quick one-off prototypes. However anything I intend to unscrew or use multiple times, gets inserts. I made myself a custom profile in openscad for the inserts that I use so that the hole is a little wider where the insert goes, so that a little less plastic is pushed down but there is still plenty to melt around the brass and make a tight hold.

Very comprehensive test! From a Design For Assembly standpoint, threaded connections can be achieved with stainless DIN 7981/7982 screws. Faster, easier and cheaper.

I mostly use the modeled threads, but if I need the strength I will use a normal nut pressed in the back of the part. Where I think the inserts shine is with parts that need to be disassembled many times. The modeled threads are only good for a couple assembly cycles and a nut can sometimes get out of place if the press fit is not great.

This is the type of video i love to see from you. Suggestion for the next one. What is the best way to use screws with 3d printing. There will be different use cases, lid that you screw and unscrew. a load bearing part(multiple directions), etc.

This is a fantastic video! You mentioned that you solder lead free. Could you make a video on how you do this and what solder you use. I have been trying to use lead free solder for a while and I just can't get the solder to cooperate.

The best thing about the inserts is that they allow for the screws to removed and replaced many times without messing the plastic up. Holding force on most screws into plastic is usually fine for screw it together once jobs.

Whenever the design allows it, I press hex nuts into the back side of the part with a clearance through hole to screw in from the other side. Make the nut recess compliant to avoid splitting the 3D print. PrusaSlicer has a couple of tricks that help. Modifiers allow more perimeter layers and/or more infill to strengthen the 3D part around the threads. PrusaSlicer also has negative volumes that can increase part strength in a particular direction that can be useful to support loads attached with threaded fasteners. There are slicer tricks for bridging over the top of the inserted nut pocket, with KZbin demonstrations. For smaller inserted nuts, typically M4 / #8 or smaller, using square nuts instead of hex nuts will help prevent the nut from spinning in the 3D printed part.

When I played with this situation (using PETG) I found that unless you are constantly assembling/disassembling, that just drilling an undersized hole in the fastener-area that was 100% infill, that the raw plastic was just as strong as the inserts. In a couple of cases, it seemed like maybe the insert was better but not consistently. Finally, the only times I use inserts is if I want ease of assembly/disassembly cycles or for a customer that is under the belief that they just gotta have them! Thanks for doing the tests. One last thing: I also found that after a couple of screw-unscrew cycles that adding cyanoacrylate glue worked well to harden the plastic screw-hole. I also found that the longer the screw remains in the hole the more the plastic confirms around and makes it tighter. I do feel that if you would just drill undersized holes instead of printing them, you would get better results not using inserts.

Pro tip I recently discovered and have been using for my 3d printed items: R-Type Nylon Rivets. You can put things together pretty easily with them, and unlike heat set inserts, or screws or bolts, you dont need nuts, you dont need to model any threads or places to insert a heat insert, when you prototype you dont have to throw the hardware out with each failure, and they're cheap as chips. All you need are holes for these, so its dead easy to use them to prototype and for final assembly due to them being cheap and reusable. You can even toss in a few extra if you are selling a product with how cheap they are.

Great video. I appreciated the quantified testing and also your willingness to toss out bad data as needed. My personal wishes would be: 1) Holes with thicker walls. I usually design my parts to final size and don't have Cura do any hollowing, so I can make any desired wall thickness. 2) Test with PETG. I don't trust PLA for my boxes, which can get pretty warm in use. 3) Small bolt sizes. M3.5 is a maximum for me, and M3 is probably the sweet spot. 4) I'm mainly interesting in the brass inserts, but a comparison with a self-threading wood screw would be useful, especially if it includes multiple cycles of insertion and removal.

I have threaded inserts (somewhere) & have never used them. Screwing into the bare holes in the print has worked just fine.

Usually, a screw is tapered to a point at the end, and a bolt is the same diameter for the entire shaft.

@MadeWithLayers I could watch you 'make chips' all day! So glad you finally have a workshop you deserve. Can't wait for more chips to come!

for low stress/torque, for M3-5, makign the thread directly with the screw, works, it will heat up due to friction, but it will work. That's how i mounted a adaptor plate for a shifter in my sim rig

I see you teased the rivnuts. I've been using rivnuts as inserts for a while. I design for them to be inserted from the back side so that the flange can act as an anchor. The resulting connection is more robust than typical inserts.

I've always used printed threads and they are fine from M5 up. Pro tip is to tap them after printing but not with a drill and machine taps but with a proper set of hand taps. For anything smaller than M5 I typically use hexagonal holes and nuts. Great video BTW!

I have had good success by adding more walls around the hole and then taping threads by hand. NOT a power tool. It takes a little longer but it also eliminates the heat issue with the tap.

This is why I print my wall loops with 6 lines thick if I'm planning inserts. I have found that this adds significant strength increase in pull-out strength. Where I think the opposite threading would help, is if your object is expected to operate under pressure in a warm environment. That should help decrease the failure pull-out point. To me though, the plastic will always be the more likely failure point before the insert fails. The benefit of the insert, is if you plan to frequently remove the screws for maintenance/access reasons (like case access screws for example).

Great informative & practical segment. I designed a hole with fins (negative cut-outs) extending into the infill area, increasing the hole perimeter material and the engaged surface between perimeter & infill. They are arranged radially around the hole. In my example for a 5mm hole, the fins are 0.5mm wide by 3mm long, with 8 in the radial array. I start & end the fins 0.5mm inside the object surface so that they're not visible from the outside. Since the area around the hole is where the failures are located, this should increase strength substantially. This also would provide space for the excess material to go with thermal insertion. I haven't tested or even printed this design yet - wish I could send a screenshot of how it looks in the slicer.

Please test with 100% infill

I tested a lot of different solutions. Here is the best one iv found : print your part with 4mm wall around the hole where you need a thread. Never use 100% infill as the insert will deform the part. Use 80% so there is some space between the walls and the insert. Put the brass insert in the hole with some heat. Wait it cools down, then anneal the part in your oven. The brass insert will slowly melt the plastic layers and crystallize around it. I got incredible results with this method, using nylon. It also works with PLAplus HT. I always use M5/M6 inserts. Second method, use Helicoil inserts (80% infill) then anneal the part in the oven. After annealing, tap inside the helicoil so it removes excess plastic inside the threads

I printed some tool heads for my Dillon 650 Reloading Press. I did it just for low-stress depriming only, so very light loads. I dabbled with printing threads, but what worked best was printing 20 walls in the holes, and running a 7/8-14 tap through the holes. Yes, it was messy, but it worked, and continues to work.

For the injection moulding inserts, to make the plastic pushed away less of a problem I insert a bold into the insert and then put the soldering iron on the bold...like that the area that needs to remain free for the bolt is clear

Some things I would think would be interesting to test: - A test of different perimeters - Are there diminishing returns? Where is the curve for "enough" to make more perimeters not worth the extra plastic. - Given a standard thickness of say 12mm - You put a long heat insert in one side and Pull it from the other side with ~3+ perimeters, and compare that to modeling a Hex or Square hole into the part to use a standard (non-heat-insert) nut. - Quick comparison of a few different filaments - Specifically interested in PETG, PC and ASA. (Nylon has way too many other variables) - A nice graphic final breakdown graphic with a "Strongest Tested", and "Budget Pick" for each Thread Size/Filament Type

This test left out the OG method of screwing into printer parts - print slightly undersized and use the screw to tap the threads as you put it in. You don't compromise the wall thickness at all in this way, and an added bonus is that the printed part now acts as a bit of a threadlocker.

I once tapped E-SUN cf-nylon and was amazed by how well it worked. It almost felt like tapping aluminum the way the chips came out!

I have not needed to print many parts or projects needing a fixing like this but I think one thing that has not been mentioned is, How Tight Does Your Fixing Need To Be? clamping down the parts to destruction does tell you their ultimate stregnth but what if you do not need that stregnth, say just for a lid on a box but need to be removed often and look professional, I think most of these fixings would do that quite nicely. Having said that, you went to great legnths to bring this topic to our attention and did a fine and thorough job too. Regards, Geoff.

Tom, another significant aspect of threaded inserts is the ability to torque a fastener tight enough such that they don't back out. If your fastening application compresses plastic at any point, you will never be able to tighten your fastener enough such that it cannot back out. Another option you could try is a Threaded Flanged Insert Nut. They are designed for use in wood, but I find they work just as well in 3D prints.

My daughter in law's father and I both had the same thought when we got our 3d printers. "Now I can print a hexagonal pit in the 'backside' of a terminal strip, and trap plastic between a conventional hex nut and the screw head." He 3d printed a threaded hole thru the rest of the pla from the bottom of the pit holding the nut to the other surface. I just drilled and tapped mine.

I undersize the hole to about the minimum diameter of the bolt and just screw it in. I love these kids of videos and think you did a great job. One thing to consider is that determining preload from torque is quite inconsistant (~35% spread but there will be outliers even higher). Also since you are measuring pull out preload might not be important. Preload builds up the memeber strength of the joint to prevent the fasteners being put in pure shear. Metals are typically stronger in tension than shear, so making the joint tight translates some of that tensile strength into friction that keeps the bolted joint from slipping (and putting the fastener in shear). This was great and I am a big fan of your videos! Thank you!!

Great video that highlights the fact that we are under using the max specs of screws for sure. Their is also other things that we need to take into consideration here as well. I'm working at a company producing underwater robots. We are using lots of 3d printed parts in prototypes and also production. Having a thread in the plastic make things light and still plenty strong, but it needs to be tightened once in the factory and not user replaceable. If the user needs to work on the screw. I directly put a nut or an insert to have this thread last. Also for underwater things, having the tapped part in the same material as the screw avoids galvanic corrosion which kills metal in salt water. This things never get to be talked about but I'm sure that they are super interesting subjects.

One thing to remember with modelled threads is that they require a small layer height. No point modelling threads when you intend to print at 0.4mm. And remember that small layers = longer print time.

I print a slightly undersized round hole and tap with a screw with a tiny bit of lithium grease on it. This keeps the plastic from melting too much and shapes it into a perfect fit. Since it’s not a cutting tap bit, none of the plastic is removed. I also design parts with “nut pockets”, if there’s enough space.

Thanks from Colorado. If I use printed threads, I increase the perimeters. Also I only use printed threads for single operation, you'll wear out the thread if used often.

What if you push in the insers into the opposing side of the hole of where the screw goes into? I imagine the additional plastic the insert will press against when you try to pull out the screw will add a substantial amount of resistance.

Was glad to learn about the threaded adapters. I’ll be trying those. But I do have good results printing a coarser thread in soft materials like we have with 3D printed parts. In particular I frequently use #10-24 printed threads for small part assemblies.

I have had good luck with the injection mold inserts with resin prints for my drone. Even experimented with camera threads printed directly into the resin. Surprisingly it worked out very well.

As for tapping M3 or such - here is, how I do it: I print a 3mm hole, which due to tolerances will end up shy of 3mm. Then I heat up the screw, screw it in, wait for it to cool down, and unscrew itagain. Works a treat. Should you use stainless screws or dont have a magnetic bit, blue tak or such is your friend for holding the hot screw to the bit :-)

It would also be cool to see a resin version of this test, with different resins, of course.

An idea i just jad while watching this was to redesign the insert to be a truncated cone that is pressed into the opposite side of the material. This would greatly increase the contact area of the insert. It also spreads the load out over more material and gets rid of the aligned perimeters that pull out so easily. No blind holes and slightly more limiting but would also be more hidden. Or maybe just putting the bolts in from the opposite side of the inserts. The inserts do seem to move a lot of material out of the way, which may be creating a shoulder for the insert to push on. You're likely still only contacting the perimeters though, which would still be the weak point.

I usually use square nuts that are inserted during a pause in the print. The thing is that you are then not pulling the nut out of the material, you are compressing the perimeter material, so it's *much* stronger than inserts. You can regulate the strength by the depth of the insertion and the width of the solid infill around the hole.

The greatest thing about threaded inserts is being able to maintain screw strength when multiple unscrewing and screwing. If you have a part you will adjust or open often, these inserts are divine.

Alternatively, create a pocket for a hexagonal nut, pause the print and drop the nut into the pocket before continuing. You can also use a square nut slid in from the side or a nut from the back if you have acces to the back.

I have done a lot of tapped M3 holes in plastic. I print the holes at 2.9mm and run a tap through them. All you need is a screwdriver handle for a TAP. You can print this. You can tap them by hand. No coolant necessary. No T handle. Just screw it in like you're screwing in a self-tapping screw. Run it in far enough that it's coming through the other side - even if that's down in a 5mm diameter hole - and blow the swarf out of the flutes with a quick puff of air. Then run the tap back out by hand. So many KZbinrs who try to do threaded plastic holes over complicate it with T handles or power tools. That stuff is not necessary. A 3D printed knob/handle and 15 seconds of elbow grease is enough. Of course it's not as strong as inserts. But for things like raspberry pi cases and phone stands, it's more than good enough. You can use superglue as threadlocker if you have trouble with the screws coming loose, I don't really find that to be a problem. Also a 2.9mm hole is good for a #4 self tapping screw. So it opens up other hardware options without having to change anything in the CAD - if you're sharing your STLs or whatever.

I've used internal nuts (kind of like internal magnets) as threads with really good success. You design a hex cavity inside the volume of the part. Pause the print when the depth is such that the nut fits flush with the top layer. Then continue the print, locking the nut inside the print.