I 3D Printed an ELECTRIC MOTOR FAN

I'm guessing it has to do with the diameter of the intakes of the EDF and the 3d printed ones. It's the biggest difference I can see and would guess it to be very influential on both the flow rate and the static pressure delivered by the fans. But I don't know for sure, am not an engineer in this regard. Just know that I hate tomatoes too.

Hi Integza! Another cool projekt :) The close view of your impeller at 4:03 shows why… well, why it sucks at sucking anything ^^
It has the wrong, almost "reverse" geometry for such a tiny inlet (same for the second model at the end of the video). Moreover, one cannot simply "open the intake wider" as suggested elsewhere in the comments. Otherwise, the volume of the shroud would become so small that the blades would no longer compress the fluid.
The solution here is to twist and orientate the blades the opposite way:
1. At first close to the the shaft (the "hub") your impeller needs an important geometrical part that is missing in your current models: the "inducer". The inducer is shaped and acts almost like a regular PC fan or propeller. Its blades are wide, with a high incidence angle (say, about 45°). Front facing without the shroud, they should look like almost those of a colored windmill toy. However in your current model, in this place your blades are shallow and oriented normally to the incoming flow, so they can barely pump anything. The inducer once there induces a high velocity to the fluid in order to suck it inside the engine (with not so much pressure on the other hand): that is to say, this missing part acts as a PUMP.
2. Then, as the blades of the inducer expand radially outward, thinner and thinner, they really become the impeller. They straighten up, and end up at their orientation at the periphery is almost radial and completely upright (i.e. the tip at the trailing edge should be normal to the shaft and to the external flow - the one outside of the engine) a bit like the blades of a water mill this time. In this second trailing part, the impeller acts this time as a COMPRESSOR i.e. better at creating pressure than accelerating the air (but it doesn't matter then, because the fluid velocity will be already high at this point, thanks to the inducer!).
So a centrifugal compressor impeller indeed acts as you explain at 4:38 except it imparts velocity to the fluid first, then compresses it, in this order :)

I'm no engineer, but from just looking at how significant the difference is between intake diameters (EDF vs 3D print), my guess would be that you're restricting your flow rate on the 3D print. Might be able to compensate with higher RPM, but I bet that would more than likely exceed material capabilities; probably easier just to scale size, and maybe even reduce RPM?

My guess would be that it has to do with turbulence caused by the impeller, use a smoke machine (or burn some tomatoes) to see how the air forms around both the EDM fan and your impeller fan. Also, since your impeller is more structure than fan, the output thrust should be less than the EDM fan. Which is more fan than structure.

I believe that the thrust difference is down to mass flow, the EDF fan is optimized for flow rate while the Dyson impeller is optimized for pressure. It also seems to have much less blade area requiring higher RPM for the same mass flow.
A higher pressure will provide a higher thrust provided the same nozzle area but will also require more power to drive the fan and may or may not be realized depending on the rpm and the throat and nozzle shape.

Finally, something that it's perfect for the the theory I'm learning in flight lessons!
Fair warning, part of this is going to seem counterintuitive, because to move the most air possible with a propeller we actually reduce the angle of attack of the propeller so we can increase the speed of the propeller. We want the propeller to move as much air as possible in the least amount of time, cause the end of that runway is approaching pretty quick during takeoff.
We can either move a decent amount of air per rotation but rotate much slower (high propeller angle of attack), or move less air per rotation but rotate much faster (low propeller angle of attack). That last one gives us the most air moved per unit time, which is what we want during takeoff because we need to move as much air as possible as quickly as possible.
There are actually two types of propellers used in aviation, fixed pitch and variable pitch. Fixed pitch propellers are not able to have their Angle of Attack changed during flight, so we use a design that is a compromise between moving as much air as possible during takeoff and efficiently moving just enough air during cruise. Variable pitch propellers are able to change their Angle of Attack during flight, so we can get the best of both worlds. To get the best performance out of a propeller during takeoff, we have to move as much air as possible with the propeller. To do this we actually use a pretty shallow angle of attack, but as high an rpm as we can get out of the engine. We move less air per rotation of the propeller, but rotate much faster to more than make up the difference.
The exact numbers vary based on the plane engine and propeller, but these numbers are taken from the Pilots Operation Handbook for a Bonanza A36. Lowest officially recommended cruise setting is 2100 rpm during cruise vs 2700 rpm during takeoff. So a 28% increase in RPM during takeoff. Even with a small reduction in air moved per rotation, the increase in rotations per minute more than makes up for it.
By the way, I'd love it if you made some type of plane that might be used to test the idea of a gas turbine electrical generator making power for electric motors powering fans or propellers of some variety. I think that's probably where aviation will end up. Right now batteries just have too many weight problems and lack of range problems for practical, widespread use in aviation. Plus there are a lot of benefits from being able to reduce the overall weight of a plane during flight as well as changing the center of gravity while in flight. Changing the center of gravity alone can drastically increase the efficiency of aircraft because it lets us reduce induced drag from the elevators. Can't really change the center of gravity or total weight in flight with batteries, but we can with liquid fuels.

What i can recall from fluid mechanics classes is that by compresing a fluid you decrease its speed , so the centrifugal fan that you designed basically outputs a slightly compressed air but at a lower speed, in jet engines this is desired because you need a high density of air with a low moving speed and by igniting fuel you generate thrust .

Your channel is awesome I just signed up as a patron I'm 42 year old auto technician but I lost my legs and took 3 years to heal and 2 years to get up outta bed and I tried by starting to watch RUclips and this awesome stuff I've seen gave me motivation again maybe there still something I can do anyway thx being so cool

Integza make a Turbo rollerblade using its self-built engines

Some thoughts:
- Keep in mind for your deign: Modern jet engines try do move the air as slow as possible through the engine, but a lot of them. The actual fan in an jet engine has low rpm when compared to the other rotating parts in it.
- Match the overall inlet area and the ratio of free area to closed area for comparison. (Comparing apples with bananas gives reasonable results only until a certain point)
- Change the angle of attack of the leading edge of our compressor blades (There is an impedance mismatch at the very first edge - You chop of the air at the inlet with you compressor blades and rely on centrifugal forces. The speed difference is too high. Better "cut" into the air at the first edge.) The higher the velocity difference the "flatter" the first edge should be. Have a look how the slowly rotating blades of a jet engine are shaped.
- change the angle of attack of you compressor blades with radius. At the axle it should look more like an I or L, at the outer radius more like an S. This depends on the type of "fan" you try to build. Radial or axial accelleration.
- use an stator with thinner blades (impedance mismatch)
- the stator should look more or less like an inversed version of your compressor. The air flow directly after the compressor is spiraling, this reduces thrust, because the side-wise portion does not contribute much to the trust.
- reduce the distance between your rotating parts and the inner side of the hull. For example: At the red lines in your design, there is air "leaking" over from one section to another section due to the rotation of the compressor. At the back side of the blade, vortices occur which break air flow and create friction.

A centrifugal fan is more useful for static pressure into a chamber especially at those smaller sizes whereas the edf is more for linear air flow. The centrifugal fan will work better at higher rpm (dysons spin at a crazy speeds ) to create high static pressures but not huge flow

To my knowledge an EDF is biased to pushing a large mass of air at a high speed but at low pressure (this is comparable to horsepower). Whereas a ducted fan is biased to creating less airflow but much more pressure/higher PSI etc (this is comparable to torque). It's irritating when people make a motor jet engine on other youtube channels using an EDF and a combustion chamber, as they should be using a ducted fan instead or even better an electrically driven turbo charger impeller wheel (as these are compressors rather than just fans). Thank you for your videos. I feel they are actually getting even better.

That's a really neat and simple way of making a BLDC motor! I'll have to try it mmm

Is it possible that your fan is stalling? The idea there is that the static pressure behind the impeller rises to a point of being higher than what the impeller can sustain. The way out there would be to try a different outlet/nozzle geometry, maybe with a larger aperture. Or to change the impeller geometry to maximize static pressure. That may be a good topic for a future video btw 😅

The Dyson edf uses a friction fit with the duct it sits in. The body of the duct is smooth and I believe the materials used for the duct and fan are self lubricating. This allows for compression to build in the veins instead of it slipping in the turbulent zone causing drag.

One thing you could do integza to not only demonstrate your hatred of tomatoes while also using your love of creating your own stuff with a 3d printer. Use tomatoes as a crash test dummy… create a high thrust engine and mount it on something that has low friction bearings. The tomato being the cushion so as not to damage anything around it. 👍🏻 you can even put this on trial and use numerous different engines to see which of your creations do more damage to the tomato

Keep in mind an impeller and a normal fan moved different amounts of air.
Also, with the impeller, you kinda are changing the direction of the air a lot, that can slow down the air.
Dyson uses one because they want to do their bladeless fan thing, the fan itself does not have to be that efficient with power since the 'air multiplier' method already moves air much more efficiently than by using a normal bladed fan. Its main purpose was really to smoothen air flow from the fan.
Impellers are mainly good for increasing pressure, like in a turbocharger, increasing the amount of air in a fixed volume.
A turbine jet engine does not really use an impeller anyway, it's a more typical fan and the compression is advantageous in that scenario because you want to cause combustion as well.
It is mainly that process that propels a normal jet engine, modern airliners use high bypass turbofan engines, they are more efficient because the large fan itself provides propulsion, the air coming from it goes around the compressor area so it's more like an EDF or PEM but instead of a motor, you use a turbine engine to spin it. The impellers in jet engines are really for compression to promote combustion.
Essentially, you're moving the same amount of air, just at a much lower velocity, therefore the thrust is lower.
Also the tolerances and stuff, air could be bouncing back out the front.
However, if you turn the impeller sideways and add another one on the other side, you might get better results.
We did that one time to give an rc plane more thrust, there wasn't much space for an EDF with the size of the craft unless we wanted to mount it on the wings so instead, we swapped the fuselage for one that had an impeller on both sides like a double sided leaf blower, the EDF was still in the back pulling air from below and out the back but now we had another thing providing thrust right above the EDF exhaust.
Also made the plane more stable since the cg was further back. The guy who made it didn't really know what he was doing and initially put all the electronics in the front. But the centrifugal module had the electronics mount in the middle.
Took forever to print that on the school's cheap 3d printers lol.

This Friday just got better!

The way that you explain these not so easy to grasp concepts from simple steps to the whole idea is amazing.

I produced a similar shape of rotor to yours a while ago. It was part of a small 3D printed supercharger. The rotor is actually hybrid being half way between an axial and centrifugal compressor stage. I've since moved back to a 3 stage axial compressor which is a bit more predictable. In theory each axial stage should offer a 1.2 pressure rise while a centrifugal compressor will offer something around 3.0. You exist somewhere between these values. The tip clearance for the hybrid rotor may affect the performance.

Here's the 3 things that I reckon need to be optimised to get a similar thrust, likely will always make a little less thrust though because of the extra energy losses.
- Impeller blade needs to be optimised for the motor, so the blade angle needs to match the motors optimal torque/speed which would be low toque and high speed. So an impeller with very shallow blade angles.
- Making sure that the outlet cone's reduction in diameter is designed so that the all the extra pressure that the centrifugal fan creates is converted back to velocity (thrust). Pressure and velocity (thrust) are interchangeable. So you need to know how much static pressure the centrifugal fan creates to then design the outlet cone. Any extra pressure in the exhaust above atmospheric is wasted energy and any pressure less than atmospheric creates an unwanted suction effect.
- Gap between impeller blade and case needs to be real tight, high precision here.
Changing the air flow directions in the engine and adding pressure, then reclaiming it through the outlet cone to thrust will sap a fair bit of energy out of the motor which is why the thrust won't be the same as the ducted fan which is the most efficent fan for creating thrust.
Hope this helps, liking the videos!

Measuring power consumption should give you a better idea. If the EDF consumes more than your fan, it has to do with your impeller pitch either not being steep enough, if you make it steeper and it still doesn't increase velocity you need to make the fan bigger to increase mass flow.

I know you've done it before but since you have access to stronger material now I'd love to see you try your hand at a tesla turbine again. And as always, great and very educational video!
A couple things I noticed that might make up the difference in the thrust could be a weight difference between the fan vs the impeller, the blade size difference, and the restriction of airflow into the impeller

Hi Integza, first comment ever if I remember well, but as it is my job’s field, I thought I could answer your question !
The problem is that fundamentally, a compressor doesn’t produce optimal thrust. To achieve the best result, you have two choices :
- accelerate the flow but low mass flow (often military)
- high mass flow but low outlet speed (civilian turbofans)
The outlet pressure is often considered more or less equal to the ambient pressure, as a difference between them causes huge losses.
You then design the turbine and the to accelerate the flow, converting the potential energy given by the chamber to kinetic energy.
The centrifugal fan (more often named centrifugal « compressor » has the benefit of having a higher pressure ratio than an axial compressor compared in size, and giving the ability to case a compressor where axial blades would be too short (helicopter engines as example). It does increase pressure, but not really speed.
Therefore, because your losses increase due to the pressure difference, you don’t retrieve the same thrust.
And with that, I’m not even mentioning that building a fan requires what we call « velocity triangle », giving you a relation between angular speed of the fan and the inlet and outlet angles.
The magic behind the Dyson fans is that they are amazingly optimised. It’s mesmerising to see the shark teeth aspect of the trailing edge of the Dyson fan in your video. On some aspects, they are even further in technology than jet engines.
Hope it helps !

This man never fails to impress me
He's creativity amd ingenuity as a person

I think thrust is made up of mass and speed and a edf make a lot of air go fast but a centrifugal fan doesnt move a lot of air at the same size but it can push it harder so you can decrease the nozzle size to increase the speed so you lower mass but higher speed but that is less efficient but need for jet engine because combustion chambers make a lot if back pressue while mixing fuel

Hello, mechanical/mechatronic engineer here. A few things to note about the problems you are having.
1. Lower efficiency. The main reason is that (as you mentioned) there are extra steps. The process of compressing a gas is usually adiabatic, meaning that the temperature of said gas will increase as pressure increases. Likewise, the temperature also decreases as it expands (hence why propane tanks get cold). Basically, what often happens in systems like this is that the hot compressed gas will conduct heat into any object they are touching (in this case the printed fan duct), which is lost energy in the system and results in the gasses not being able to re-expand as much. This shouldn't cause a huge difference in efficiency, but enough to matter in some specific applications.
2. Centrifugal fans also spin air along the inside of the inlet (between the blades and the front cover) for some time as it is expelled outwards, which loses energy due to drag and turbulence. Unfortunately, 3D printed surfaces tend to be somewhat rough, which increases turbulence and therefore drag/resistance. 3D printed parts (especially ones that flex like you mentioned) also can't have as close of tolerances to the cover, so there is often a decent sized gap that air can settle in without being pushed down/out. The easiest way I know of improving both of these is by enclosing the top of the impeller, as the "lid" at that point is also spinning with the air and there are no gaps for air to escape through.
3. Cross sectional area. Another likely cause of the lack of thrust is the cross sectional area of the inlet. Remember that the larger inlet area will be able to move more air for each given rotation of a motor, so if the EDF inlet is twice the diameter (4 times the area) of the inlet to the centrifugal compressor, you will get a far smaller amount of airflow for the same rotational speed. This is partially why centrifugal compressors spin so fast (sometimes past 30k RPM), that way they can both displace more fluid and increase pressure differentials to more useable levels.
4. Fluid medium vs. speed. Finally, the pressure generated by a centrifugal compressor is heavily correlated to the density of the fluid that is being pumped. Since centrifugal compressors rely on the inertia of the pumping fluid to generate pressure, lower fluid densities will naturally produce lower pressures. This lower pressure will result in increased flow resistance inside the fan duct, therefore lower exhaust speeds. This is partially why centrifugal compressors spin so fast (sometimes past 30k RPM), that way they can both displace more fluid and increase pressure differentials to more useable levels.
If you would like some help designing an improved fan (I have designed a few centrifugal compressors for high pressure gas systems before) feel free to send me a message! I also have a number of high performance SLS/SLM 3D printers that are able to produce some significantly stiffer parts that would handle higher rotation speeds without warping or expanding.

I was just recently working on an impeller design for a pressure based system and not flow. I also have a background working with a million different motors, including designing my own BLDC ESCs.
If you're using the same motor, make sure the controller you use is the same as well. Long story short, different timing and/or control will result in different outcomes.
Measure *everything* I'm sure for the sake of brevity, you've left out a lot of this. But, if you're going for the same type of performance, make sure your impellers, nozzles, intakes, chambers, etc. All have the same geometry. You want to get the curve right, the thickness right, the angles right, the sizes right, just about everything. Reduce the amount of leniency for "good enough"
Shoot for the smoothest and most consistent surface finish you can get on your printed parts.
You might gain some mileage by combining your best printed parts with the stock parts as well. A printed impeller with the Dyson chamber, for example, and vice versa. You then get a comparison of what is and isnt working from your design and you can isolate where the problem truly lies.

Video Idea: cry for help while someone throws tomatoes at you

Well it could be that the nozzle could be too small which could be bottlenecking the fan and since it’s not an explosive amount of force like a jet engine it doesn’t end up making the fan explode resulting a small amount of air leaving the fan but that’s about all I can think of

A) Your pump style is adding a compression stage which is a energy loss (and the entire structure is adding extra mass so now conservation of energy is involved).
B) A wing style fan works exactly like a wing, which would be playing around with pressure differentials basicly (very efficient).
C) What exactly are you trying to do here because there's a lot of engineering and considerations that goes into aerodynamics. What media are you trying to move because each media has its own most efficient blade profile and even the temperature can interfere. Fan blades for like a house fan use a general profile, while the blades manufactured for a jet would have much finer tolerances on their profile callouts on the blueprints. Surface finish callouts would even be a factor.
Idea : If you want to make a more efficient fan, make one where blade profile can change. Like maybe have an inner metal structure with a rubber bladder over it that's inflatable. Play around with the thickness of the rubber bladder to help control the profile. (Add some stiffer rubber patches or fiberglass or something so it doesn't just turn into a big balloon.) Then have all sorts of sensors that measure the atmospheric conditions with a computer to do all complicated calculations to determine the most efficient profile. Most of logic motors have speeds their most efficient at as well so thet can also be part of the calculations.

Hi Integza! I am an aerospace engineering student at the University of Illinois U-C. I am working on an electric thruster project through the AIAA that has many similarities. There are many potential points of optimization, but the biggest problem has to do with Bernoulli's principal and subsequent equation relating pressure and velocity of flow to cross-sectional area. In other words, the impeller produces high pressure flow, and the exhaust nozzle geometry converts that high pressure flow into higher velocity flow. By decreasing the area of the nozzle, you can further increase exit velocity by converting the high pressure air from the impeller to lower pressure and higher velocity. There will be inherent limits with the power specifications of the motor and impellers (among other complex inefficiencies); so, I'd say the easiest means of optimizing your thruster would be producing an impeller you like and just playing around with different nozzle exhaust areas. Thanks for the great content!

Hello. First of all im a huge fan of your channel and sorry for the imperfect English.
I think I have the answer to your problem , in fact I even made the solution for it.
The problem is that radial fans are great for producing pressure while being Very compact. Meanwhile they are absolutely terrible at moving large volumes of air compared to their axial brother's.
Now , the axial fan does the exact opposite, its great for moving large amounts of air while being compact , but it's not great at creating pressure. Now, both can do what the other can as long as you make them "larger". For the radial fan/compressor, you basically wanne increase the inlet while not really making the base of the fan larger to prevent it compressing the air. Now you can only get so far with that without making it so large where there is no point in using a radial one over a axial fan. To solve that problem, you wanne give it a double sided intake, basically two radial fans with the base attached to each other. Pratt and withney did this with their J42 in 1948.
I recently made a 3D printed double sided radial compressor and I would like to share the files with you if you want them (so you get a better idea of the concept). In this video you can see it in a early stage, but its fully operational now and producing more thrust then my axial "jet".
ruclips.net/video/glBI2g7bvzU/видео.html

You should make a jet engine with a turbo charger from a car as a side quest for this project!
Edit: realizing that you’ve done similar things with the compressor side of the turbo charger, this idea is to also use the exhaust assembly as well to spin the compressor after a combustion stage

I will make some suggestions by looking at your impeller design and the one of the Dyson. Look at the airfoil geometry, the attack angle is everything when it comes to sucking air, so I would test different angles and check their dependency on the intake diameter and the top impeller diameter. I would also check the tolerance between the impeller and the casing because it's responsible for a stalling phenomenon or for not compressing the fluid enough. Then for the outlet, how about creating a variable-diameter nozzle to test the right diameter to produce the same trust (like the ones combat planes have).

Hi, as a Steamfitter the answer to your question is 2 fold. First a centrifugal pump works best with a perpendicular flow pattern that uses the "Centrifugal" force to release the fluid in the desired direction. Your casing requires the air to attempt to move sideways, restricts it, and forces it to change direction. I'm pretty sure a physicist could come up with an experiment that would show the losses as heat, in the casing, the air, etc. The reason a Dyson works is the very efficient turbine they use powers a very powerful force, the venturi. Because the air from the dyson comes out at a high speed thru a very small opening, and this is the important part, all around the inside opening of the ring, the air inside the ring goes along for the ride so to speak. The dyson doesn't restrict the flow like your design.

my guess is that the surface area of the blades on the impeller is much smaller than on the EDF, so the impeller moves less air. a good way to test this would be to measure amp draw for the two designs. you could also run them at full speed for a few mins and then check the temperatures of stuff.

I love this guy's videos! I also did some research on fans for selecting the most optimal off-the-shelf fan for cooling a particular battery system. What I learnt was that each fan has an important characteristic, which is it's PdV curve; volumetric flow versus pressure difference between intake and outlet. The output power is the product of these (check the units tho, if you want Watts, you have need to consider the density of air). Axial fans have a very different curve compared to radial fans. The former can produce a lot of speed, but the latter can make more pressure and maximum power. Every fan has a point of maximum power output, where P*dV/dt is the highest. This may change depending on multiple factors, such as inlet and outlet area, number of blades and pitch. You want to match the motor's optimal speed for maximum power output to the fan's characteristics to get the most power out of the fan. I hope that someone finds this helpful :)

Hey Integza :) Here are some ideas:
First of all, if you have something that generates smoke, use it to check the airflow in your Fan. Your connection of the two pieces sits right at the point of maximum compression. You could lose alot of pressure that way without knowing it. An O-Ring might help there. It would be in general intersting to print it again in a clear resin to then put smoke through the design to check the flow. maybe you have high boundry losses :D
the next obvious idea would be to check your intake. Maybe it is too small and you choke the fan (which would also increase heating). Try diffrent sizes or claculate the size you need if you are sure of the values you need/aim for.
Next, you need very thight tolerances between the impeller and the housing *at operating temprature* otherwise, you again leave alot of pressure on the table. Check your operating temps so you know what thermal expansion you need to take into account.
Good luck with the fan :)

🇪🇬I am from Egypt, I did not understand anything, but your style of speaking is amazing and beautiful. A new follower from Egypt continued

i would love to see you try the flat turbine engine concept, it basically uses a fan that has a specific profile that allows for the region closer to the center of the fan to act as a normal forward thrust fan, and the region towards the tips of the blades to push the air outwards ( like a centrifugal turbine) to copress air in a tight duct then cumbust it, this in theory should allow for a very compact turbine/turbofan engine.

The problem is "impedance matching" - the energy required to drive the ducted fan vs the impeller is different. You need to design your impeller to match the output characteristics of the motor - I can't help much there, but I do know there are significant changes in aerodynamic properties when you switch between axial and centrifugal flow, and it looks like you are not extracting enough power from the motor (in your impeller) so it reaches speed and doesn't do much

Velocity out the back matters.
Also the flow rate: Vel x Area.
Centrifugal drops velocity to raise pressure but like you said there's a lot of unnecessary steps => turbulent losses. Also lower velocities getting thrown out the back per unit area.

Dear friend, as an old modeller, we have always known that EDFs perform less than open propellers.
The problem is in losses due to turbulence due to the space between the EDF propellant and the walls of the EDF chamber.
If you manage to leave that distance to a minimum then you will not have turbulence and you will not have losses.
sorry for my bad English,
a greetings.

I feel this has something in common with the Rocket Nozzles you love.
My theory goes like this : when impellers increase the pressure of airflow, and the exhaust has the same area of cross section, more air flows radially outward from the exhaust due to pressure differences. The same way rocket engines use bell nozzles to reduce the pressure and increase the velocity of the exhaust, if you tried something to equalize the exhaust pressure with atmospheric pressure, you'd technically achieve the same amount of thrust.
Basically, you'll be converting the energy in the form of air pressure back to velocity to achieve the same thrust as the EDF. And considering EDF's don't mess with the pressure at all, it makes sense they're able to reach higher exhaust velocities than impellers at atmospheric pressure.
All the best with your project tho, looking forward to a cool video with whatever you're making...

Hi Integza. Typically, axial fans create ‘high’ flow at low pressure ratios. Impellers/centrifugal fans create ‘low’ flow at high pressure ratios. For impellers, this pressure ratio is a function of rim speed (and a bunch of other things).

You know whats better than a awesome fan? 4 awesome fans! You should really build a drone with Jet engines🔥

I didn’t go thru any of the comments, but I feel sure there is a lot of good advice. But I can tell you this for sure. First fan centrifugal fan blade open air in and out. Now using the same motor is not going to work the same with what your next design became. You basically turned into a centrifugal pump. Also the reason with the difference in flow with just the new design is this. You had two different impellers on the new design, an open impeller and a closed impeller. Meaning closed impeller not because of the outer housing it sits in. A lot of consideration goes into setting what is called your impeller clearance. Temp, metal, cold, heat etc. Closed impeller set clearance from the housing and open from what in front casing etc. This is important, a jet engine may be centrifugal but it’s what is called a turbine. Totally different dynamics than a fan or pump. Hope this helps.

Make a drone with similar propellers that you used in this video.

It seems to me that the problem may be due to the shape of the impeller, perhaps if you look at the fan you mentioned you can notice the difference, because although the vacuum cleaner may work similarly, it is not the same as what you want

Thrust is mass flow rate multiplied by exhaust velocity. So either your intake is not large enough, or you're not fully converting the pressure generated by the centrifugal fan into air velocity (by having the nozzle be too small for example). The latter could also cause your "compressor" (which it basically is) to stall, reversing the flow through it.

Hey Integza, this is a straight thermodynamics problem. We know that Kinetic energy= 1/2 M V^2. Because of the velocity squared, it means that increasing just a bit of velocity takes a lot of kinetic energy. The most efficient way to make thrust is to accelerate a huge mass of air to just above the speed of the aircraft.
This is what the EDF is doing (high mass flow rate). What you are doing is accelerating a tiny bit of air to high speed. The only advantage with doing this is that you can make an aircraft with a higher top speed compared to an EDF.

The big one: Tolerances values of the turbine vanes, to the shroud.
Other things to check: Intake, and exhaust port diameters.

Video Idea - show the difference of high Air Flow fans and Static Pressure fans. Their design is different in terms of blades and space between them. Greetings from Brazil! 🙂

The reason I've heard to as why centrifugal fans are worse is that you change the direction of the air as you push it out to the side then back instead of an axial fan which just pushes it back

I would guess a couple things.
1) the EDF will direct air liniarly through the duct to produce a given thrust (which we will consider baseline) proportional to the rpm the motor can spin the fan, the pitch of the fan blades, and the drag the blades make.
2) the PEM will have more drag for the blades as it is not accelerating the air through the fan in a single direction (air has to go out to the sides brushing against the flat plate of the fan as well as the entire legth of the blade assuming it enters from the centre). More drag- lower than baseline thrust.
3) the PEM will have more mass than that of an EDF due to the way it functions, reducing the rpm of the fan blade. Lower blade rpm- lower than baseline thrust.
4) When it comes to centrifugal fans, tip clearance is difinitive to efficiency. The tighter the tip clearance, the less air you are losing to inefficient pathways through the fan... but i leads us to 5.
5) Too tight a tip clearance will cause the blades to clash with the housing of the centrifugal fan, creating more drag. There are two fixes, losen the tip tolerances and lose efficiency, or redesign the fan blade to be less forgiving to the centrifugal forces by adding support material, making the fan blades thicker, or making them out of a more appropriate material. Either way you risk lower than baseline thrust.
None of that however, takes into account the geometries effect on air pressure, as an EDF is not as dependant on the effects of air pressure like a PEM. So we need to increase pressure and use it effectively. Despite the lower than baseline thrust properties I expressed a PEM would have, it make up in increasing pressure, so we need to keep it.
So, a suggested to do list:
Focus on increasing air presssure generated by the fan while trying to keep airflow from the front of the fan through to the back of the fan as free ass possible.
ANY mating surfaces, ANY gaps will benifit from restricting or sealing off airflow providing its viable. You want the pathway you tell the air to go to be the easiest root for it to take. Air hates congestion. It would happily take the equivalent of longer country lanes if the motorways are congested, even if the motorway is quicker.
After that, focus on the exit geometries to utilise the pressure you have generated effectively.
P.S. dont hold me to any of this, its jusst educated guess work.

Video idea - comparing the thrust from combining multiple pulse jets together vs a single scaled up pulse jet? Interested in the impulse profile differences!

Zepplins or Blimps using impellers or jets for directional force would be an awesome video!
With all of these balloons and such floating over us recently I'd love to see how you can make things nerdy and fun!

you could possibly use a centrifugal compressor design instead of an impellor, similar to Sir Frank Whittle's original jet engine or what is found in modern turbo chargers.
You could, also like modern Turbo chargers and Jet turbines, incorporate a type of "air by-pass" to add a bit of slower moving air "mass" (via ventricle shear) to increase the usable air volume at the ejection point (Exhaust).
Awesome channel, keep up the great content

a good thing to keep in mind is that with compression involved stuff like friction,air resistance, and lack of torque become problems, not to mention the centrifugal fan doesn't have anything impeding or altering its flow of air, which your aerospike both acts as a nozzle, and a cushion that will reduce the overall amount of energy in exchange for a more efficient release of air, along with the fact that compressed air is going to have a way higher friction coefficient then the low pressure air that the EDF is outputting. all in all, with my admittedly limited knowledge i cant help but feel like the problem here is the lack of simplicity. maybe if you got other things involved, like combustion, or using microwaves to heat the air as it leaves the contraption (probably with a setup similar to those plasma/microwave furnaces where you just stick it in a microwave and it melts metals), that way you can add energy to the system and vastly improve your results. at the end of the day all of this is equations. energy * efficiency = result

You should look at some fan showdowns. They went through a large number of designs and could help isolate the areas your combo may be having trouble in.

Hey Integza! My suggestion to fix the expansion of your impeller and increase RPM on the PEM is to add at least 2 more copper coils and decrease the distance in the way you coil the wire itself (it will probably create a weird hex design) I hope this helps solve your problem/idea! I'm also just now realizing I haven't subscribed or liked the video so I'm going to do both after I post this.
ps; I'm in college (ERAU) and this 3-D printer would change my life. I hope the internet helps me with this one, and Integza I hope you see this because I have so many ideas I want to share and create and I think this might be the start of making it all happen.

hey integza here's a good idea, you should make a liquid fuel thruster (possibly even one of your previous projects like the vortex rocket, I would recommend hydrogen) and then attach an aerospike nozzle to it and make the output as high pressured and high thrust as you possibly can, then attach it to your scale on a rail (hey that rhymed!) to measure the thrust output, in some of your later videos you should try attaching this to something like a model rocket or an rc plane

You blinded me with that introduction, I’m just trying to sleep and this really bright light blinds me 😭😭😭

Yoo Joel, Excellent job, i'm a big fan of the fan jokes.
If I may suggest something to help.
Is it possible that you're getting more thrust with the fan than the centrifugal thruster, because you have restricted the flow area too much in the centrifugal thruster that the mass flow rate is drastically reduced?
It would seem the fan can "scoop" a lot more air per rotation.
And while thrust is definitely velocity dependent the mass of the air being thrown backwards also makes big difference.
The the centrifugal thruster may be propelling the air out the back much faster but it may not be sending nearly as much air so the overall thrust is not nearly as much.
Also remember, and I'm sure you know this already, most in action centrifugal compressors on turbojets are just that, compressors.
When they compress the air the flow areas don't need to be as large for the same mass flow rates.
So if you're trying to make a centrifugal compressor thruster and modeling it after regular centrifugal compressors in turbojets but not also doing a high compression ratio, the mass flow rates will be restricted.
But anyway. Just a thought and random stab in the dark without knowing more details about the build.
Let me know what you do figure out in the end though. I'm very curious input this build. Stay classy!

I would love to see you make a see-through casing of a two-spool jet engine, with a high pressure and low pressure section for both the compressor and turbine. You can add a fan to the front to make it a turbofan as well if you choose. I think that the best way to understand the operation of something is to be able to see it, and with multi-spool engines (like every commercial aircraft engine being either 2 spool or 3 spool), most people have a large misunderstanding of exactly how they work. I also see a classic turbojet engine as the basis of understanding of all your other turbomachinery shenanigans which, as a "fan" of your channel, would help me appreciate your shenanigans even more!

I am apart of a 3D printing research group and we are starting to play around with Ceramic FDM Filament. It's called LAYceramic. It woudl be super interesting to see some of the jet engine parts printed with LAYceramic and compare it to the resin ceramic.

the difference in thrust is the way its designed. The impeller creates high-pressure air vs the EDF that makes fast flowing air. thats basically the main difference, also the edf has no bumps or lines that cause drag on it, unlike the impeller. that's basically the only difference that i could think of :)

Como outros já mencionaram, basicamente fans radiais produzem mais pressão e menos fluxo e fans axiais (EDF) produzem mais fluxo e menos pressao. Continua com os excelentes vídeos!

Hey integza its more than a year that i'd been watching your videos they are just incredible and that rocket series is outstanding and i really love your affection with the tomato 😂. Why shouldn't you try making cryogenic rocket engines this is missing.... Lots of support and keep on making the videos 👍👍

I think a nice video would be about a fan design for Major Hardware's Fan Showdown. I think you are able to create a very good fan with your knowledge and tools. Maybe you two can make a collab video togheter. 👍

I've got to say. I've been enjoying the ASMR and watching to process of building it.

I'm a Fan now 😂☠
Video idea : make the smallest 3d printed turbine engine(that works ) you could possible make !
However try changing the numbers of blades and ,since I m studying it at uni , I know that also the size of the blade must change from top to bottom since you are compressing air and so his density changes , so to have the same flow rate also the blades have to adapt ! I hope it might help, but you are Integza and I know you already knew it 🧐🤖

Hello Integza,
I have been watching your videos for a while now and I really enjoy watching your process. Your ingenuity and creative never cease to amaze me. Keep creating the excellent content.
Video Idea: I would like to see you make an acoustic levitation device. I would like to see the process of making the controls to adjust the frequency of the sound to levitate an object.

Is your impeller significantly heavier than the original fan?

My understanding is that ducted fans produce greater airflow in a low pressure situation, but centrifugal blowers are better creating static pressure. So fans are better for vehicles and blowers are better for inflating things.

I love your videos, so many ideas... I would love to do all these experiments and everything myself... but unfortunately I don't have the necessary materials and machines...😞

Hey Integza! I have a crazy idea for an RC car. How about making a nitrous installed version that can go even faster? Imagine being able to press a button and instantly boost the car's speed. It would be so much fun to race around with! Do you think it's possible to make this happen?

NEVER seen this channel before. Only watched up to 0:50 and heard that joke. Shut up and take my sub

Fans are axial impellers. Air flows axially. Compressors (or pump impellers) have radial flux. Axial pushes through, radial compresses. Axial deals with high volume flow, low pressure. Radial deals low flow, high pressure.
Oversimplified.
By the way, your first 3d print was a mixed axial-radial. Maybe you need a more radial design and more rpm?
Did this help?

Another possible issue could be compressor stall meaning that the angle of attack of the leading blade edges isn't appropriate for the rotational speed and airflow. I think agentjayz did a video on it.

Idea: Use the bladeless jet engine (or any other of your engines)in an actual use case, like a rocket or model plane

Dude I was litterally just doing a ton of research on 3d printers and how I can't afford any good ones lol. Anyway, what if you try to make an engine powered type fan. Like not a radial engine, rather a small sterling engine connected to a fan. It would be cool to see the rates and possibilities they can create! Or maybe you could connect a piston to a sterling engine!

As other people say, think about the relative inlet and outlet apertures. The fan is creating a pressure differential, the flow is just a secondary effect.
Also the aperture for the blower fan is a tubular surface infront of the blades. Not the circular transverse opening in front. The inlet could be choking the flow of air to the blades in the first place. Try a wider diameter ring of blades on the blower.
Also look for losses in the system (from recirculation and work done to travel through the casing to the exhaust). Normal axial fans have a little recirc around the blade tips but the housing is very open, there is no resistance to the exhaust.

Hey, loved the video as always… wondering if you need an internal cone behind the fan blade, To help act as a compressor like in a jet engine. Maybe you’re producing turbulent flow on top of the motor…keep it up!!

make a rocket bike

My guess would be that your fins have a maintained or small difference in height from the cores surface to the fin tip, so the volume in the channel between each fin doesn't change much from the inlet to outlet, and on the fan you salvaged the fin height is probably higher on the inlet vs the outlet so as the volume between the channel decreases towards the outlet the air moves faster, I don't actually know that's just this strangers intuition, can't wait to see your solution!

Couple of other observations:
Surface area of your impeller compared to surface area of your axial fan, can't judge properly, but you have the 3D model, compare it.
2nd, intake and outlet area of the suggested fan against your design.
Just trying to help you get an idea what might be the problem. Love your enthusiasm, love the channel 😁

Not an aerospace engineer or a propulsion engineer here, but I think the reason that performance is lower is this:
* A standard EDF is designed to flow as much air as possible with the least amount of restriction, as the fan motor is the entirety of the energy input to the airflow. If you restrict the airflow, you've got no way to get back your losses.
* A jet turbine (which you have half-modeled here) is designed to take in as much air as possible and reduce the area that the air occupies, thereby increasing the velocity. This velocity increase is accompanied by an increase in pressure, i.e. a higher volume of gas in a much lower cross-sectional area. When combined with a fuel like jet fuel, then ignited, the resulting gas undergoes extreme expansion. The expanded gas then blows over the exhaust end, which has an additional turbine wheel that recovers energy from the expansion to drive the input turbine. The remaining energetic gas is expelled at high velocity (in a turbine designed for it) out the back to produce thrust. The "aerospike" at the back serves as an aerodynamic shape that promotes smoother airflow, which decreases losses due to uneven gas flow.
In short, you've restricted airflow, and provided no additional way to add energy to the system, so you can expect losses. Sweeper manufacturers probably restrict flow to increase velocity for multiple reasons. My guess is that higher air velocities allow for lower overall fan speeds (and noise, wear) as well as increasing the centrifugal force on dirt particles, which makes it easier to filter out dirt from air in bag-less vacuums.

Thrust is calculated by multiplying the mass flow by the output velocity minus input velocity : qm*(Vout - Vin). The mass flow is directly linked to the input area.
In order for your thrust to remain constant, you have to increase the output velocity as much as you reduced the intake area. But because your motor remains the same, you can't.
So the only options there are either change the motor for one that is spinning much faster or make the intake much bigger.
Hope that helps !

Great video, I'm no aerodynamics expert but I spend I lot of time around jet engines. I noticed that the nozzle on your fan looks very similar to a jet engine exhaust nozzle, however I'm not sure this is the best design. The reason a jet is shaped that way is because it is a heat engine so when energy is added to the compressed air the temperature and more importantly velocity increases. Contrary to popular belief the pressure actually decreases over the combustion section of the engine. The purpose of the nozzle is to decrease the residual pressure left over after combustion turning in into axial velocity for the turbine(so the compressor spins) and linear velocity out the back of the nozzle. This is because the power of a jet engine is the difference in velocity between the air entering the engine and the air leaving the engine(in reality there are a few more variables). All that being said, if you are not adding heat energy to the compressed air then the impeller should be optimized to increase velocity rather than pressure. This is why you will see that both the EDF and the Dyson fan have very large exhaust outlets so they can achieve high velocities and not lose energy from increasing pressure.

You are on the right track looking at your impeller design. You, however, looked in the wrong dumpster. Vacuums like the Dyson are high-pressure, low volume fans. The EDF is a low-pressure, high volume fan like the ones used in dust collectors. Try looking at woodshop dust collectors. Then, narrow down the exhaust port to increase the speed of the air, leaving the fan.

dude.... the jokes, the smart way of thinking... i had to subscribe on minute 3.... what a masterpiece...

Double check your calculations on the magnetic cct. Are you slipping (coils are turning on faster than the permanent magnets, and keep up). With the air density and friction of the shaft, there is a bit of mechanical load there. So might need stronger magnets/electro magnets to create a stronger magnetic force to stop slippage. Feel free to reach out and I can explain more in detail.

With relation to your problem with thrust - Motors are rated on a kV value, meaning they can spin a certain speed proportional to the voltage of the battery you're using. The motor will draw different amperage from the battery though, depending on the size of the propeller/impeller. The edf you're using probably has larger and more aggressive blades on it, meaning it draws more power from the battery and produces more thrust.

Air compressor is for stuck in air molecules together while a fan is for pushing air
molecules

Always great stuff 👍 👏 on your channel

Try the scoops that are used in water wheels. It's a fancy blade that captures the most energy of a force. If it runs in reverse perhaps it can deliver the most force by using even less energy.

I'm noticing a couple of problems not including friction.
they are
1. Mass torque ratio
2. Inertial expansion
3. The strength of your motor
4. The strength of your power source
.
My recommendation
1. Reduce the size of the impeller
2. Reduce the mass of the impeller
3. Get a stronger motor
4. Add more power

I'm guessing that Integza already knows why the results are different, could be a number of possibilities from weight, aerodynamic shape, size, or direction of rotation. It also could come down to which end the electric motor is attached because the motor will obviously be more efficient when self rotating as opposed to sitting still and rotating the propeller/ fan 😁