3D Printed Cyclone Air/Dust Separator

Awesome video!! Pro tip: (seriously, I'm a dust collection engineer) Make sure to earth that collapsing flex hoze. The metal wire in there is not to make it springy, but to function as earth wire to avoid static buildup and discharge... I live in a country of merely 11 million people and each year we have 34 dust collection explosions (and consequent total shop losses) caused by failure to properly earth sections that build up static charge... :) I thought that might be a stat that could spark your interest ;) =P (swidt? haha)

A feature of many cyclone separators is what is termed a 'vortex finder' or 'outlet length'. The outlet pipe dips down into the inside volume of filter. This forces air from the inlet to orbit around the separator surface before exiting the top of the filter. This length is important for adjusting filter performance for pressure drop vs. fractional efficiency.
Many papers use terms designated as 1D2D, 1D3D etc to describe the cyclone separator dimensions. The numbers represent the ratio between the cyclone diameter and cone length. Many papers are published which compare filtration fractional efficiency (as a function of particle diameter), pressure drop, and flow rate through the filter for a given Mean Particle Diameter.
In general, a higher aspect ratio of cyclone with a large outlet length will filter better because it exposes the air flow stream to longer linear lengths of surface area. The principle is that at the boundary layer, air velocities are slow enough to drop out material against the surface, and the slope of the surface keeps the material from re-entering the fast air stream. Lower cyclone diameters will filter out smaller particles better, at the expense of significant pressure drop.
According to ASHRAE, saw dust has an approx mean diameter of 600 micron, and flour dust has an approx mean diameter of 50 micron, for your reference.
www.sciencedirect.com/science/article/pii/S0307904X06000291
This was a paper we used to guide our design of these separators.
You should check out papers on the subject if you really want to optimize your filter.

We used separators extensively in the lab and found through our experimentation that an inlet angle declination of 7 to 10 degrees made for the greatest debris drop-out.

"It became clear I needed to vacuum my floor more often" Even a genius needs a little help from technology to learn life skills.
Love your content and your passion for everything you do.

Hey! i've actually done these experiments myself a few months ago. I found that, as you mentioned, a steeper slope was better for larger particulates. But my results were also greatly improved when I elongated the cone and allowed the air more time to circulate. Additionally, I found that sanding the inside to be as smooth as possible helped. Great video, love ur channel.

Can't wait to see what you cut out with this magnificent thing - level up!

The velocity of the air stream, size and density of particles, and slope and diameter of the cyclone matter a LOT more than you'd think. The multi cyclone is essentially optimized for three different particle sizes, since it was done more or less randomly there's no telling what exactly those particles might be.

This is why I made two separate units in series. The first is your typical dust collector, the second is literally a giant bong. The air goes into water this making it super clean.

You should test combining the big mono and a smaller mono, since they both filter out different size particles.

If I remember my lectures correctly, you usually have the outlet not at the top but a bit further down the cyclone so the particles are slower. Maybe adding a small tube in the center will help. Would also be a quick print, if not just a cutted pipe is enough.

Point to note: the multi-stage design _should_ allow you to tune the first stage to remove big chunks at a cost of letting the fine stuff through, to be dealt with in stages 2 and 3.

I appreciate this. I've been using a 20$ Oneida cyclone for almost 10 years and it's nice to see why it works. The other attempts don't add to the science but they really do help to see why the original design is so effective.

If you look at a Dyson vacuum, each tier of cyclones has a separate collection chamber separated by a seal, also rather than multiple similar sized cyclones each one is reduced in size in order to filter different sized debris, the main shroud for large debris the subsequent in size for finer particles. The diffusion method might be effective as lower airspeed but you have to keep in mind you want maximum power rather than an obstruction on purpose as that not only reduces cleaning performance but also puts strain on the motor which in a non-shop vac vacuum relies on pass through air for cooling.

We’ve done a fair amount of research on these cyclones for our projects. There are a lot of academic papers out there which pretty thoroughly describe the performance characteristics of these things given different geometries and boundary conditions. A given geometry tends to preferentially separate out particles with a particular density. In other words, a given cyclone might perform great for steel grinding dust but not so well for sawdust. So your results will depend on what you’re trying to separate out. Fun project, thanks for sharing!

The slow motion sexy CNC and cyclone shots to the music was absolutely hilarious and I replayed it about 5 times, great video! I love 3D printing but never thought I'd sit through a video on a DIY shop vacuum, you made what should be a relatively boring thing into engaging content! Great vid!

Great to see the various configurations tested in a systematic way. Thank you.

This whole video I was screaming out loud "WHY ARE YOU TRYING TO REINVENT THE WHEEL?????
I took "Air Pollution Control" in my Master's program for Civil Engineering. Cyclone separators are very simple and easy to engineer, build, and understand. I'm sure you can find stuff online about how to design and build them and what performance to expect based on particle size and density. You could even dissect nearly any bagless vacuum cleaner to get ideas on how they work and the proper proportions.
One feature I noticed that was neglected in most if not all the designs, is that the exit pipe in the top center should extend into the cyclone chamber, a certain number of diameters of the pipe, like 1 or maybe a half, I don't remember. I think it's called a "vortex finder."
This is a great practical video, I'm glad you made it, and I mostly enjoyed watching it, but you could have started much further ahead than you did with just 5-10 minutes of reading.

So cool, how 3D printing gives "garage inventors" ability to design and test ideas. Daniel, I have a feeling that 3D printing combined with the Stepcraft router will be taking you to a whole new creative level. Go for it!

I was planning on making a cyclone for my dust collector. I'm so glad I found this video! Very helpful!

Simply routing the air through a larger tube will drop the air velocity since Q/A=V where V is velocity, A is area and Q is flowrate. If you bump up the area the velocity goes down proportionally. The middle of the tube will have a much higher velocity (especially since this is 3D printed and doesn't have a smooth surface) so it would require a series of diffusers to make sure the velocity field is uniform. You'll need the bottom to be open to the bucket for the dust particles to descend and accumulate. If you get an anemometer (they are like 20 bucks) you can measure the velocity of the flow in your vacuum tube which combined with the cross sectional area can give you an estimate of how large the dust collector tube would need to be to drop the air velocity. The surface area of the opening in the diffusers should be equal to the original (non enlarged) tubing size. Basically the particles fall downward at a fixed rate decided by gravity and their drag. The velocity inside the collector must be low enough that a large portion of particles (>95-99%) have plenty of time to fall downward out of the moving air stream.

it resonates because the tube is ribbed, if the tube was smooth it wouldn’t have made sound. You can use a smaller diameter smooth tube.

I'd love to see more experimental videos on dust separators. This was really cool

Great video!
If you look at the 2nd generation Dysons, they have over a dozen on tiny cones. The tinier the lower end of the cone the higher the speed, but also the higher the resistance to the airflow, thus the massive parallelism. As mentioned elsewhere the inside of the cones should be as smooth as possible, to keep the speed up and reduce resistance of the filter (acetone vapor might help here). Also both the low cost and industrial filters I know of, have the air outlet at the top hang down a bit, for you that would be about 2". I like your serialization, have been thinking about that, but haven't tried it yet. I think two phases with the second being much smaller might give better performances: one big cone surrounded in Dyson fashion by a dozen of tiny ones.

I'd use first a gravity based (maybe mechanical theough some big mesh) filter and then the monocyclone for the rest. So basically into a bucket for the heavy big stuff, out of it and through a tube to the monocyclone.
Pretty cool tests you did there 👌

Irrespective of Brilliant being an excellent sponsor - thank YOU for recording, editing and producing this content for us for free. It's among some of the most enjoyable content that the internet has to offer these days and I, for one, certainly appreciate it.

I appreciate the use of animation, clear acrylic, and inclusion of windows so we can literally see what's going on. Thanks!

This is AWESOME! Thanks for telling me what those cones in facilities are for! I will build a thing like that in the near future - just to have it because it's great!

Cyclone being one of my favorite songs to this day. thank you for that!

Great project, Daniel! Thought about printing one a few years ago. Was lazy, and bought one :)

Awesome job, I really like the idea of them in series!
I actually designed one of these for a project at work. I used it as part of a system that allowed us to lift sand to an elevated hopper. This was placed in the elevated hopper to force the sand to separate from the air.
I found that having a tube extending into the chamber a few inches from the exhaust port helped the efficiency dramatically. I was also using a chamber made from a piece of acrylic tub so the walls were vertical with a PVC reducer at the bottom.

It's so fun being an engineer! You go down all these rabbit holes you wouldn't have thought of and you end up learning so much! That's such an important part of being an engineer!

TH-cam has been recommending this video to me for two weeks now. Finally took the hint and watched it :D Definitely worth it and really enjoyed the video!

I think our right about the steeper sides. In your pictures at the beginning the cones are a very steep long cone. I think the mono cyclone was so effective because the larger radius allowed a greater centrifugal effect to occur. I made a dust separator with just a 5 gallon bucket and a wood lid. The entrance was at a very steep angle but still downward and at a tangent to the inside of the bucket. It separated all large items and much more of the sawdust than I though it would. Keep up the great work.

This video was actually very interesting. You make it seem so simple. Since you do planes and boats.. I would LOVE to see a GPS guided submarine, heck even a remote controlled one would be amazing (I don' think you've made a sub yet as far as I'm aware)

@12:45 you got bars!!! I see you also are channeling the spirit of Rick Flair Wooo!

The carpet in your shop gave me the shivers. Awesome video btw.

Great video!
It would be interesting to see if there is a noticeable difference between a smooth surface in the cone, compared to the ridged cone due to the printing layers.
Also, it would be interesting to see if there is a noticeable difference if the top cylinder section was a bit taller, before it becomes the cone. I've seen designs where the cylinder height is actually taller than the cone section.

Always appreciate your videos!!!
The collection efficiency of cyclones varies as a function of particle size and cyclone design. Cyclone
efficiency generally **increases** with (1) particle size and/or density, (2) inlet duct velocity, (3) cyclone body
length, (4) number of gas revolutions in the cyclone, (5) ratio of cyclone body diameter to gas exit diameter,
(6) dust loading, and (7) smoothness of the cyclone inner wall. Cyclone efficiency will **decrease** with increases
in (1) gas viscosity, (2) body diameter, (3) gas exit diameter, (4) gas inlet duct area, and (5) gas density. A
common factor contributing to decreased control efficiencies in cyclones is leakage of air into the dust outlet
(EPA, 1998).

Omgg the Cyclone outro was a throwback! Awesome video!

Love your persistence.

I use a commercially made cyclone on the input to my shop vac. Some really small stuff makes it through, but it saves on filter bags as most of the waste ends up in the bucket and not in the shop vac.
Some big bits still orbit the cyclone without falling down, I wondered whether some vertical fins around the edge to stop them rolling would work, however since my cyclone does not come apart I cannot test this idea.
However if I use it to sweep the floor and the intake get blocked, it sucks the bucket flat, so I had to make a vacuum relief valve to stop this, it also jeeps the circulation going in the cyclone. I note that Dyson do something similar.

10:19 flows always follow the path of least resistance, so adding valves to each outlet allows you to control and split that precisely. Once you know you can then design smaller nozzles for the first chamber to the larger nozzle for the last chamber

Your video is awesome, and also are the comments with tips and tricks for improving your dust cyclone separator design backed up by scientific and real world data. Just reading the comments already made me wiser by a bit. Keep up the good work and I'm also looking forward to see what stuff did you made with that nice CNC router. Cheers!

When it comes to cyclones, bigger is always better simply because you have to match the angle of the cone with the speed of the air, so having one thats bigger means you dont have to worry too much about the angle as it will slow down the air alot. At my work we have a few of them and they do very well with both very fine metal dust and metal shavings simply because they are about 7 feet tall and 3 feet wide.

This fella right here CANNOT miss

LOVED THIS VID, interesting, knowledgable and entertaining! Well done!

Great video. I use 2 different cyclone pre-collector systems in my work shop. I have both a 4" high volume low pressure dust collection system with a 40 gallon steel can with a cyclone lid as the pre-collector and a a 2" shop vac system with the 5 gallon bucket and a cyclone on the top. I found the 5 gal bucket lid a bit of a pain to get on and off to empty the bucket. So I use a double bucket system where the top bucket has the bottom cut out of it and the lid always stays attached to the top bucket. It still seals when in use but to empty I just pull the buckets apart and it's easy to empty the bottom bucket. the system is also a few inches deeper.

I think you need some more distance vertically between the inlet and outlet to the vacuum I think you need more volume between them so that the particular matter has more time to drop . Also try your three component model with three large containers that are connected by pipe to regain the volume but keep them seperate . Absolutely loved this video .

My suggestion for a future cyclone would be to print a series of spiral splines that force the particles down as they travel around the inside of the cyclone. Kind of like a thread pattern inside the cone.

Great finishing song! Very interesting builds, thanks for sharing.

cyclones are a massive help in this use case. I made one myself and had some issues with the container seal... so I put clingwrap on the container as a separator, sprayed eurathane foam into the lid and clipped it on. Cure, cut off excess and now have perfect seal. Increased rigidity to prevent vacuum collapse and perfect seal.

I find this topic fascinating. Would be interesting to see if restricting airflow to the vacuum could filter out different particel sizes and densities (like metal dust).

Большая работа проделана!!! Спасибо большое за познавательное видео!
Думал так же делать, но Вы хорошо проверили мои идеи и они оказались неэффективными, Вы сохранили мое и не только мое время, спасибо!

i cant wait to start 3d printing. that router machine and stuff looks so cool how you can carve wood and all that.

Your videos are amazing and inspire us to go curious and try things out on our own!

Interesting. Given volume in equals volume out(roughly), I would suggest your air flowing in should have a smaller hose and the bottom of the cyclone should have a bigger hole, also the hole exiting the top should be larger as this will reduce the escape velocity of the material and hopefully minimise the amount of really fine particles remaining suspended. Another really interesting way to go is utilising water. Dust hits like a water wall and then is captured. I use this for sprays.
Edited - elaborated what was implied by v originally. Mawyman below gives more of an explanation for volumetric flow. In essence your vacuum cleaner generally always pulls the same volume of air through it. If you have the straight pipe with no attachment on it you pick up some stuff, i you change it for one with a smaller opening it pick up most stuff.

You are missing a crucial part. The outlet needs to have a tube reaching down into the cyclone . About 1,5-2x the diameter of the intake . Also : the smaller the diameter of the cyclone is , the finer are the particles these get separated . Don't make it so small though that the air out of the intake smashes into the outlet tube . The upper part needs to be cylindrical and only a couple of outlet diameters under the outlet tube it needs to taper in .
There must not be an airflow from the solids-outlet into the cyclone or it won't work, airflow out of the solid outlet needs to be kept to a minimum . There are some simple Formulars for dimension ratios to get decent results out of them and there are some way over the top complicated methods of modelling them . I did a cyclone separator to separate oil from. A stream of CO2 in my thesis . If you want to go into detail on how they actually work , I would gladly give you some info .

You are just the coolest person. Clever, talented, funny, and capable. Shine on.

Good singer as well... Great job with this collectors. Thanks for sharing.

Awesome job. I’m going to add one of these to my lab setup! What kind of glue do you use for the PLA?

I absolutely love that you are testing cyclone separators! Your design skills are insane! I use a handful of these in my little machine shop, and a two cyclone setup for my floor vacuum. One thing that I've found that helps is at the port that goes from the cyclone top to the shopvac hose, to have a portion of the tube protrude a half inch to an inch into the cyclone top (down into the cyclone chamber) rather than it being a clean port into the shopvac hose. To be honest, you may have done this already, but I wanted to share this in case you hadn't tried it already. I think the idea is to give the solids a wall that needs to be hopped in order to make it into the shopvac hose. Granted, it looks like your designs are working pretty good, especially the large one. I would imagine that the shape of this barrier could play a role in how much gets past the cyclone too, as the solids mainly stick to the surfaces. (I think the original clear plastic dust cyclone has this little barrier, if you need a better visual than what I'm explaining) It may not improve the solid collection a whole lot, but any little bit that helps keep it out of that shopvac filter keeps suction as close to 100% as you can! I have managed to keep my shopvac filters nearly pristine for a few years now. Also not machining foam either though.. which is probably the toughest thing to keep out of your vac filter! Awesome stuff!!!

Great video! Other than increasing the steepness, consider making the subsequent cones with a smaller radius to increase the centrifugal force on smaller particles.

Yes, it sang to you! Love it. Great video.

Maybe try having the cyclone open up a bit at the bottom or try introducing a bend at the dust exit (2 separate ideas)

Nice video buddy 👍

I feel like the boundary layer deceleration is more important than the outward force. Definitely interesting ways to test this with different surface textures and straight sections to increase the boundary layer thickness

I would Love to see more experiments with more seperators and the affect they have on the over-all air flow

Great vid! I was just learning about James Dyson today! Too bad he didn't have a 3d printer, would have made prototyping his original design much easier! He apparently went through 5,127 prototypes!
P.S. Idea for next video: "Testing 5,128 Different Cyclone Air Dust Separators"

LOVED IT! Amazing and entertaining video [as usual]. Thanks for doing this for us. I want to see a BIGGER funnel, with STEPPER sides - Do it please!
P.S. I've been following your channel for years, and enjoyed them then and now! Keep up the hard work - I know for experience, it can be quite the grind!

what a journey! good job man
OMG those lyrics

Great video!!! Have been a subscriber to your channel for years, and do enjoy your vids, yes I fly RC, and yes I dable with F360 and my Ender3. I found this vid really interesting and wondering how many hours you had wrapped up in printing all those cones!!! Which I just finished a little project box, and gave me an idea about running a test to see if I could speed up the print on it! Thanks so much for sharing with us! I'll be looking forward to more of these and what your building with your cnc router!!!!

Have you considered changing the injection angle more downwards so the particles start with more downward momentum?

Your 3D printing skills, cnc skills, modeling skills, and videography skills are off the charts man! Holy cow what a great video!

Awesome analytic and iterative descriptions. I'd worked this very topic about 10 years ago and was struggling with many of the same issues that you were able to visually expose.
The biggest reason for 'short circuiting' or bypassing the centerfuge effect is not having the proper pressure drop in the chamber. Adding an extension tube to the clean air exit that's past the tangential entrance helps quite a bit.
Another is having the correct aspect ratio of height to width based on your entrance velocities. Scaling the cyclone up or down works to a point...when debris is being passed through the cyclone or even being sucked up the center vortex you have too little of a pressure drop...you need a larger diameter cyclone to compensate for the velocity of your system.
If you play with Dyson vacuums you'll find they have precisely scaled cyclones for their velocities. They don't have near the flow or suction of a shop vac but have near perfect separation and filtering because they tuned the entire system.
Your shop vac is your control point... The cyclone needs to be tuned for your shop vac.

Subscribed because making a song for your video shows some serious effort, good job man, two thumbs up!!

Love the video. Since the pitch of the cone changed which particle sizes it gathered most efficiently, have you thought about making a multi-stage separator, similar to the series separator except the pitch of the cones change to accommodate for the size of particles most likely not caught by the prior stage(s)?

made complete sense on how it works and ive seen this before but never completely understood it so cool vid i learned new stuff

This helped me so much to define what type of cyclone I need to build.

I love that the simplest design is also the most effective.

The music bit was classic...omg.. well done.
And it was great rabbit hole you toke....i think i do something similar to my stepcraft....

This was really fascinating to watch, especially because I was thinking of printing one for my normal vacuum, and this had some really interesting results to ideas that seemed so good on paper :o

Not only damn interesting and helpful but also awsome and beautiful footage, well done!

Excellent information, this kind of experiments are my favorites, thank you!

Wow, great walkthrough of your journey 👍😃

This is definitely one of the most informative videos in TH-cam!

Was not expecting the song near the end. Well done!

best DIY cyclone and testing I've seen yet! I want to share my thoughts how to improve it.......but I think I want to keep it to myself as Dyson's latest vacuum designs are old or quite flawed, can easily be challenged.

Awesome work Daniel!
I feel your struggle ….I’ve been designing/printing a 775 powered vortex paint mixer for my airbrush paints…….I gotta big pile of Petg so far😎

This was truly intriguing and one of my favorite videos in a long time. You earned my sub

Thank you for doing so much work!

Dude ! Loved the remix song at the end!!!
Hysterical 🤣

I have an Weird fascination with vacuums so please keep iterating!

Thank you very much! You have saved many hours of testing for other people!

While watching this video it kept reminding me of one core concept, the scientific method. What a great job! You proposed your idea, researched it, made your hypothesis, tested it, analyzed the results, refined your idea, and repeat. Gotta love the scientific method!

Great Video , very interesting how the different cyclones work 👍 I use a mono cyclone with a self made case out of wood on my CNC. Works good for me. 🙂

Glad i waited til the end to hear the re-mix.

Sweet, Just what I need. I think I'll try the single cyclone with steeper sides. Thanks

Rapidly becoming my favorite TH-cam channel

Neat! Another dimension of tests you could run is to see how it affects the volume of air being moved / CFM.

Using your highspeed camera you can see the debris angle. If you 3D print a screw spiral in the cone it may help "force" the larger debris flow down.