Too bad he didn't notice your comment, it's brilliant. I hope he sees it seeing as you spent so much time typing it up so well and explained everything great. How do we tag him so he sees it?

@@PaulK390S90V I dunno 🤷‍♂ Let's try @Integza

@Integza ! Let's hope this works!

@Integza

@Integza

I believe you’re right. I am an aerospace engineering student and I believe there is some pressure distortion happening within the fan casing because it is not made precisely for the fan blade and the speed of the motor. When designing these type of casing MATLAB and Solidworks fluid flow models are used to determine the best design that matches with the casing. There are a lot of helpful guides online to discover more.

Your likely right. I think an added factor could be the weight of the fan relative to the original EDF. The printed fan may take more energy to rotate therefore leaving less energy for thrust. Might be completely wrong on this, but seems logical to me.

​@@judahhawi3925 not sure if the weight of the fan could make a massive difference, as it's balanced, so the rate of acceleration in the spin is all that's affected, otherwise once it's up to speed the higher weight gives it more momentum like a flywheel. I could be wrong tho :)

I may not be an aerospace engineering student, but I'm reasonably fluent in physics. Ultimately, you are correct in your assessment. You may want to know how you are correct, and how it all correlates: "There are a combination of reasons for this problem. All the physics that go into making a fan are torque, radius, radial balance, radial aerodynamic coeffecient, and mass of the impeller. -Torque is a known and unchanging factor with the motor. We have no intention of changing this, so it becomes a foundational standard. -Radius is variable. Radius referring to the radius of the impeller. This also correlates to the radius of the frame, or more specifically, how tight the tolerance is between the impeller and its ducting. Low tolerance allows back-pressure to directly 1:1 displace some of the original displacement from the impeller. -Radial balance is a personal term I'm using to describe how well balanced the impeller is along its blades. Where is the center of mass along each blade including its respective portion of the hub? The further away from the point of rotation that the center of mass is, the longer it takes to spin up and the more of an impact aerodynamic drag, or back-pressure, will have on the impeller. -Taking that same radial cross-section of an entire impeller blade and its respective portion of the hub, we then need to balance its aerodynamic coeffecient with at least two other factors. First is the velocity of the impeller blade at all points along its radius. Second is the range of operational flow of air into the impeller. So the aerodynamic coeffecient profile of every slice of the impeller cross-section from the hub to the tip needs to be balanced according to its intended operational velocity. If this doesn't happen, then you create unintended pockets of high/low pressure along the surface of the impeller blade. The blade does rely on a small high/low pressure imbalance along its surface to induce pressure displacement, but too much, little, or even inverting that balance will quickly ruin the efficacy of the impeller. You need to fluid-flow simulate this in CAD before production. Even just taking a Dyson impeller design isn't enough, because it was designed for a specific frame, intake, exhaust, RPM, torque, radius, and mass. All of these things work together. You're also working with a constant; the torque of the motor. Another facet to consider with radial aerodynamic coeffecient is how large your intake and exhaust openings are. The standard ducted EDF blower doesn't try to pressurize the air any more than needed to maximize its CFM potential. Meanwhile your centrifugal impeller is also trying to mechanically compress the air and is thus encountering resistance. The impeller design needs to be further augmented for that factor. From there, the CFM potential for the intake and exhaust each need to be considered and calculated based on the expected pressure displacement of the impeller and its frame. If the CFM potential of either the intake or exhaust is too low, then you get back-pressure again ruining the displacement balance you're trying to create. -Mass of the impeller goes without saying. However there are some subtle nuances to this that most either forget or fail to recognize. Rotational mass in a frictionless environment will only slow down how quickly a specific torque will get up to maximum rotational speed. We're not working with a frictionless environment though. You're combating the balance of ambient air pressure. You are trying to use a spinning screw of blades to dig into the air and pull it in a specific direction creating a pressure displacement. Keeping the mass of the "screw" as low as possible will allow more of the motor's torque to be applied to the air instead of the impeller's mass."

I suspect that the small impeller would allow the motor to spin it at a higher RPM under the same power load, negating the intake diameter as the issue. I wonder if instead the losses can't be attributed to back pressure when the air is compressed causing the RPM to get reduced under the same power load. In other words, either the motor gets fed more current or the impeller/casing gets scaled up with the same intake diameter. I'm also not an engineer and I personally get bloated when eating tomatoes.

Wow, Maker's Muse comment with just 4 likes! Rare!

26 now

200 now

but dont forget about iron core if it should be good

Although I am sure Angus doesn’t want your printer. He lacks space and time not 3D printers.

How would he ever get the burnt tomato smell out of his workshop? He could use the fan! :)

My thoughts exactly.

That’s what I thought also, a possible diagnostic for that would be to try running it under water since fluids don’t compress, if there’s a ton of cavitation I *think* that would point to the intake being insufficient But like yourself I’m far from an expert

Also the shape of the edf intake being curved helps with air intake as fluids tend to stick to curved surfaces. This allows the edf to pull in a much larger volume of air around it compared to the 3d printed fan

Also the housing on the one is flared outward to allow for more airflow in. The 3d printed one is tapered to almost a cone shape. Try wet sanding the 3d printed model. If the surface isnt smooth like a tomato it will cause drag and slow down the air being forced out. Think of it like your plumbing lines. If your water lines are bumpy the flow of water will slow down dramatically. If the pipes are smooth the liquid flows at a higher rate.

A higher rpm means more drag (friction is velocity^2) , lost as heat in the air, and less energy going to push air. Larger propellers are inherently more efficient because they can move more air slower and get same thrust as a smaller prop. And air flows through a large hole easier than a small hole. It is all about efficiency and that means keeping the velocity low, which means a larger intake/exit area and impeller.

exactly.

What Eru says... ^

That’s what I wanted to say! Static pressure vs. flow rate

I would note that the Dyson isn't optimized for pressure, it would be more of a true centrifugal design if it was. As a mixed flow device it is optimized for a design point that is a balance of moderate pressure and moderate flow rate.

@@videoviewer2008 Of course, I should have said "more optimized for pressure" of "optimized for pressure in comparison". Depending on how far you go down the route of optimizing for pressure, it isn't even a fan anymore.

Agreed but make it a Rollerblade suit also congrats on the win or at least what I can see

@@marksman754 integza stop using chinese tomato bearings, and you need enough rpm to make paris hilton spin

@@patrickwatkins7572 why is this in reply to someone else’s comment? 😂

@@marksman754 🔴 What Is Islam? 🔴 Islam is not just another religion. 🔵 It is the same message preached by Moses, Jesus and Abraham. 🔴 Islam literally means ‘submission to God’ and it teaches us to have a direct relationship with God. 🔵 It reminds us that since God created us, no one should be worshipped except God alone. 🔴 It also teaches that God is nothing like a human being or like anything that we can imagine. 🌍 The concept of God is summarized in the Quran as: 📖 { “Say, He is God, the One. God, the Absolute. He does not give birth, nor was He born, and there is nothing like Him.”} (Quran 112:1-4) 📚 🔴 Becoming a Muslim is not turning your back to Jesus. 🔵 Rather it’s going back to the original teachings of Jesus and obeying him. More .....👇 🔴 THE RETURN OF JESUS

​@@1islam1 Dont care 🗿

I miss the mustache! F*** tomatoes.

Yes and no, the centrifugal compressor is easy to build (tolerances can be looser) and good at increasing the pressure of the fluid (air), it's not that good at creating mass flow. Which is the reason why modern jet engines use axial compressors, as they can flow high volume/mass and compress the air enough for combustion. After the compressor you add fuel and ignite the mixture to increase the pressure again and finally you expand the high pressure fluid through a nozzle to increase the speed of the fluid and create thrust.

@@JainZar1 Bah! I forgot about mass flow. You're totally right. Thats probably the main factor. Even if you recover the pressure, you're wasting energy pressurizing gas instead of pushing mass.

Yeah I was thinking that turbofans only work if you are actually injecting fuel. Without fuel, you are just building a more complicated fan with more steps and more inefficiency.

So centrifugal is for pressure applications and normal fan for high airflow applications

@@MeesDeppe_Official In general, yes. You can get some pretty insane pressures with multi-stage axial compressors, like in modern jet engines, but you need really tight tolerances to not have spillage back to the low pressure side.

thats what i was about to say, its like comparing static pressure pc fans with high cfm pc fans

which is why they're used in combustion engines to cram as much oxygen in as possible. I work more with pumps than fans, but the principles are the same (ish). pure axial flow with always give you more flow (thrust) while radial will give pressure, and mixed, well mixed results... in jet engines the thrust comes from the combustion gases, not the compressor - in a turbo fan you have the jet engine turning an axial flow fan to generate thrust (as well as with the exhaust gases) (yes, over simplification, i know).

this is where my head was at as well

this is 100% what i wanted to say, its why centrifugal fans are often used for 3d printers since they can reliably push air to cool parts, whereas axial fans struggle much more with this.

At any rate, search terms to learn more: fan stalling, impedance mismatch.

I was thinking the same thing, essentionally causing the air pressure to overcome the airflow and move "backwards".

The quality of the print can also make a huge difference in pressure. If the walls aren't butter smooth , you're creating unnecessary drag and losing a lot of air speed .

Very nice and interesting remark! There is a difference in fans between a propeller, turbine, compressor etc. Different air flows for different purposes.

@@asakashigure yes, that's a good point. Added resistance from boundary layer vorticity will increase impedance. This is also true for the max static pressure the impeller can generate in the first place. Position, attack angle, slope, distance between the impeller vanes also influence this and need to be fine tuned to the pressure and volume flow expected. All this needs to match up such that the system is close to or at it's efficiency maximum at the desired rpm. That also means the design shown may produce better results at lower rpm.

Since the compressor is 3d printed, and he's relying on centrifugal force anyway, he could probably connect the duct to the blades and have them co-rotate

True there are multiple planetary step downs.

Sounds like someone is indeed well read with aerodynamics.

What he said

yeah, one look and the shape felt wrong, he had a dome shaped cowling that closely followed the impeller. the reason he wasn't getting much air flow was because the intake was too small vs the rest of it, also, the low air flow was simply rotating within the cowling and not going anywhere. putting a cover attached to the rotor from the intake to the impeller exhaust would massively reduce his losses, leaving air only one path to go, outward, radially, this can be captured and redirected with an outer cowling that redirects the airflow back from radially to axially. with stator blades to also redirect the spiralling airflow back to straight

Don't be fooled by the imitator, that's a fake Integza. Those "telegram" labeled accounts are a common fraud pattern.

When all else fails, more lube.

wow, I actually was right. My guess was excessive clearance between fan and duct.

That makes perfect sense! Although approaching this level of seal might be hard to achieve with 3D printers. Maybe Integza could use a slightly flexible material on the edges of the impeller? Perhaps even a bit of electrical tape taped to both sides of the blade with about 0.5 a mm overlap with the duct and some lube in the form of graphite powder would work?

PPL trainee here. Very good explanation!

Also very good point about battery powered aircraft being heavier. Avgas is 720g/l, whereas a battery pack for, say, a Tesla Model 3, weighs around 500kg. And at about 250 watt-hour per kg (870kJ) for the batteries vs 1,240 wH per litre for avgas... You can see the clear winner for energy density here. And considering how massive weight is as a factor in aviation, this would be a dealbreaker when it comes to electric planes unless they find a better means of energy storage.

(1240 wh/l is roughly equal to 1660 wh/kg)

​@@iamtheoneandonly_ it's just a guess, but I'd expect the issue being in the efficiencies - the generators, converters and motors have some losses, however small that may be. Also there's the weight of the infrastructure which would have to be present on the aircraft. I highly doubt it'd be more efficient than using the gas straight for propulsion. Perhaps a bit of an equivalent might be to check how is the efficiency with those 'hybrid' cars with small batteries and internal gas generator to provide power when the battery drains. Also, good luck with your PPL!

Haha noise goes BRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRRR

You definitely dont have enough air flow through your fan, if you have a bigger intake and expansion chamber then you will make more thrust. Video idea, build a mini dragster with a tiny rocket engine😂

Fr tho

Fr

Yes my friend

Agreed

One of the reasons it might not be working is because the type of motor you have is for speed and not torque. There are some motors that use the same type of system and are more powerful just what is needed for the project. These are used in larger edf’s such as in x-fly motors which I used in a version of your afterburner design.

Exactly my thoughts. The limit seems to be the maximum rpm of the motor right now, but te load is much smaller. So the motor has less physical resistance to push against, which is just wasted potential. It's comparable to driving in 1st gear with your car: the maximum speed won't be limited by your engine power, but by your rev limiter, while the entire motor will produce a lot less power than if you were using the correct gear. My idea: print a bigger impellar

@@lucamagni5098 Fans/Pumps produce pressure and flow, and in doing that they absorb work. You should try measuring the current (ideally the power but as esc tend to produce constant voltage so current is a good approximation) used by both models of fans, and compare. 1. If the models use different power/current, you need to scale/modify your design until they do, and then you'll probably have to look at (2) below. 1. If both models are using the same power/current but producing different flow then you have an impedance matching problem, or an efficiency problem (wasted energy). The impedance matching problem is ether the inlet or outlet of your Centrifugal fan doesn't ideally suit the pressure that it is operating at. Rule of thumb is that Centrifugal fans/pump produce higher pressures at low volumes than axial/ducted fans. I think you have an impedance matching problem.Your Centrifugal fan is producing higher pressure but at lower flow air than the axial fan, thus when you measure wind speed (flow rate) you see it as lower. This is why rockets have nozzles, high pressure gas at low flows isn't useful for propulsion, nozzles convert high pressure/low flow to lower pressure / higher flows. The fact you called it an aerospike turbo fan, I wonder if you already know this because an aerospike is a form of open nozzle, which is a impedance matching device.

@-integza1 lol

This is the reply I wanted to pile on to. You can probably run a much more aggressive pitch than the dyson due to wide tolerances around the case area.

ᴄᴏɴɢʀᴀᴛꜱ ʏᴏᴜ ʜᴀᴠᴇ ʙᴇᴇɴ ꜱᴇʟᴇᴄᴛᴇᴅ ᴀᴍᴏɴɢ ᴏᴜʀ ꜱʜᴏʀᴛʟɪꜱᴛᴇᴅ ᴡɪɴɴᴇʀꜱ ꜰᴏʀ ᴛʜᴇ ᴘᴀᴄᴋᴀɢᴇ ᴄᴏɴᴛᴀᴄᴛ ᴛʜᴇ ᴛᴇʟᴇɢʀᴀᴍ ᴀʙᴏᴠᴇ ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^🎁

From what others are saying about static pressure vs flow, this might be a good way to show how static pressure can be used with combustion to generate lots of thrust since turbo chargers use similar fans/compressors to the Dyson impeller you’re using

A turbo jet by definition does exactly what you want but better. Remember that air flow in a straight path moves faster and can transfer a sufficient amount of energy without obstructing further airflow (important). The turbo gets spun by the exhaust which creates suction. Cars don't generate thrust the same way as jets. Jets use their exhaust to create thrust cars have the thrust generated and dispose of waste through the exhaust. So jets need that speed of the exhaust while cars don't.

@@phasepanther4423yep agreed! But at the same time you see these DIY Turbo Jets with turbo chargers that generate some sort of thrust (definitely not as efficient as a straight line jet engine) Anyways, that’s why this would be more of a side quest to understand a bit more how these kinds of compressors/impellers/fans work and maybe some cool conclusion can be made from it.

@@Pscribbled I see. An informational video like this would help. As there are key differences in purpose of certain motors and of certain fans. For example, a motor designed for higher rpm won't be able to handle too much torque (within a power consumption range). And generating pressure does require some force, not just speed. Remember the basic electrical formula such as number of poles to rpm to get an idea of your torque curves. This can be seen with pumps as well (technically the design he is using is closer to an impeller as it generates flow through pressure, so a higher torque motor might suit it better). You get different head heights. The max height a pump can pump to. Separate from the flow rate.

@@Pscribbled Also I completely forgot to mention something in my last comment but can't be bothered to edit it. The other reason for the lack of thrust is that Dyson fans are made for flow not thrust. A good comparison would be rpm vs torque vs horsepower. With horsepower being your thrust and rpm being your flow. Pressure being your torque. This is just a basic concept and not a formula. Since you seem to know cars.

^ this. Measuring the current flow and voltage gives you input power, and then if you measure both thrust and exhaust velocity you can measure the jet power. Divide one power number by the other and you have efficiency, which feels useful to know. You can also measure both exhaust velocity and thrust for both fans (the EDF and your centrifugal jet) to get the power of both. I would expect your centrifugal fan would have a higher exhaust velocity and much lower mass flow at any given motor power level, which will explain where all the thrust is going. I mentioned in another comment already but for anyone who hasn’t seen that: Power = (exhaust velocity ^2) * mass flow Thrust = exhaust velocity * mass flow So trading away velocity to add mass flow increases thrust, even when power stays the same.

​@@ChrisDRimmerVery nice explanation The reson for having high velocity is being able to still produce thust while movibg quickly, but comes at the expense of power

YES!!!! THATS RIGHT!!!

@@anthonyb5279 thanks bro

Back pressure on the fan. I agree

it would just over speed if that were the case

@@anthonyb5279 I know this is a fan that we’re talking about but it’s easier to explain it if we pretend it’s a jet engine yes you’d be right the smaller The nozzle the more thrust is produced but if there isn’t a sufficient amount of energy pushing all the hot gases through the nozzle then it causes bottlenecking and in which case instead of having A increase in thrust we have an increase in pressure in the combustion chamber that will result in an explosion this is what’s happening to the fan But since compression is not in the mix when you’re talking about a fan it relies on the rotation of the propeller and I highly doubt that small engine would be able to reach high enough RPMs to create that extreme amount of force to increase the airflow so instead The fans Air pressure raises to certain extent which is not enough pressure to make the fan explode so even though the engine may have enough power to create a lot of thrust it’s possible that the 3-D printed parts it’s holding it back specifically the nozzle because it’s too small and the small nozzle is causing restriction stopping the air from going out the back into the fan and as we discussed the raise in pressure is causing all the air to go out the inlet of The Fan instead of the outlet

Bump. Also I didn't consider the inlet size, that's a pretty big deal. And I believe there are lots of (lesser used) methods of smoothing out printed parts. Aecetone, sanding, buffing, painting, etc. Painting is a particularly fun one because of surface tension xP

Damn this comment was very insightful, I learned 3 new things, that I hadn't even thought about before, even though I know the theory behind all those 3 things. I didn't know that the fluid's density mattered that much in centrifugal fans, but it does make sense, cause if you think about it in terms of steady flow energy equation, the centrifugal fan is exerting essentially a contact force on the air, and hence, the heavier the air, the slower it has the chance to lose inertia as it knocks on the insides of the fan. Next is having a large enough inlet, having a large enough inlet makes sense to me in a sense of how venturi tunnels work, there needs to be a decent enough flowrate to start with, and I think that's probably the biggest difference in an EDF, where the fan has no blockage on it's front end. I can imagine centrifugal fans do a better job if air was forced into it, like in a jet engine scenario, but if air has a hard time getting into it, I guess the flow rate just won't be big enough. I also knew that a fluid being compressed heats up, any thermodynamics module at a university covers this with how a refrigerator works, but it didn't cross my mind, that it would apply with centrifugal fans as well. But then again, I doubt that the work that is put into the air mostly goes into heating it up. It is probably something you should consider, but I doubt it affects the max pressure reached by such a large margin.

@@movin3148 Oh fluid density is super important, desnsity is related to pressure remember, which is also related to velocity. Pressure "flows" from high to low but in all directions, which also means backflow... To spin a fan means to compress a region of air, which means to create a low pressure region in front of the fan and an *even lower* region of pressure behind. Which reminds me, you can also get backflow aft of the fan exhaust. Which is... interesting...

Agree they are higher pressure and get this through tighter tolerances than other fans if you got gaps it will dramatically hinder performance.

And that's without him eating tomatoes. Shows how tomatoes are overrated 😂

Also, I forgot to add that your throat areas look significantly reduced moving from the edf to the impeller/ centrifugal fan.

Yep, was going to mention that. The dyson one he finished with is a mixed flow fan, kind of a medium pressure, medium flow type fan. Regarding the outlet area, since he has additional pressure available from this type of fan he could probably have a smaller outlet area, but not that much smaller. One thing I learned when doing some CFD work on a mixed flow fan is that you want the outlet area to gradually increase as you progress to the exhaust. We found that sudden increases in area would generate a lot of turbulence and reduce the fan flow. Also stationary vanes that "catch" the outlet flow from the fan and straighten it out also helped the performance, like the stator blades of a jet engine

Not to mention the impeller copied from a vacuum will probably be better suited to draw a vacuum than to move a lot of air....

this is what I'm thinking, I've remembered on seeing a video about jet engine saying that centrifugal turbine engine is better at building pressure then increase the air flow or something like that. Although to properly compare it, one has to make sure two motor are using same amount of power.

Damn, I was hoping I’d get to be the big hero who came along to say this. Still, my guess is what was described above (which also describes the difference between the huge thrust of a modern geared turbofan and the paltry thrust of a very high exhaust velocity turbojet) plus aerodynamic losses inside the airflow path inside the ducts. I think the term you’re looking for to fix the mass flow problem is “entrainment”, which is how you draw nearby stationary air into your high speed jet stream to add mass flow at the cost of exhaust velocity, to gain thrust. You could probably do this with - as already mentioned - a larger intake. Or you can use the method found in industrial machinery and Dyson fans, and do the entrainment after the fan, by using a duct structure in the exhaust that allows nearby air to enter the jet stream. This is probably easier, in terms of “it’s just a new exhaust” but might be harder in terms of sizing the ports and whatnot. But basically, exhaust gas goes into a tube, tube has ports that let air into it, tube expands to allow for the increased air flow, thrust goes up, exhaust velocity goes down. The equations you care about here are: power = (exhaust velocity ^ 2) * mass flow And Thrust = exhaust velocity * mass flow And that quadratic scaling on the exhaust velocity to power is why cutting velocity to add mass ends up adding thrust.

Exactilly

Also impalers are heavier soo

I think he would make a very original and interesting one :)

That would be insaneeeee

I recommend using a burning tomato as a smoke source!

Hey make a 3d printed turbocharger

@@happyjack3497a stand-alone turbocharger is just a turbojet engine

Great idea!

Best idea!

@integza could you please confirm this with your youtube main account? Thanks!

@@metschnikowia likewise with mine i have no idea if the comment i got was a scam

@@antonventura6364 It is a scam. I wrote to integza. And also report to KZbin.

ᴄᴏɴɢʀᴀᴛᴜʟᴀᴛɪᴏɴꜱ ʏᴏᴜ ʜᴀᴠᴇ ʙᴇᴇɴ ꜱᴇʟᴇᴄᴛᴇᴅ ᴀᴍᴏɴɢ ᴛʜᴇ ʟᴜᴄᴋʏ ᴡɪɴɴᴇʀ ꜰᴏʀ the 🤶 ɢɪᴠᴇᴀᴡᴀʏ ᴘᴀᴄᴋᴀɢᴇ ʜɪᴛ ᴜᴘ✉️ ᴛᴏ ᴄʟᴀɪᴍ ʏᴏᴜʀ ᴘʀɪᴢᴇ 🎁

from.... the motor?

@garetclaborn364 yes - the motor is producing rotational energy (and doing it continuously, so "power") and the fan is consuming that

i mean if u wanna destroy a drone and four engines you might as well cover it in kerosene and throw your wallet on it too

ᴄᴏɴɢʀᴀᴛᴜʟᴀᴛɪᴏɴꜱ ʏᴏᴜ ʜᴀᴠᴇ ʙᴇᴇɴ ꜱᴇʟᴇᴄᴛᴇᴅ ᴀᴍᴏɴɢ ᴛʜᴇ ʟᴜᴄᴋʏ ᴡɪɴɴᴇʀ ꜰᴏʀ the 🤶 ɢɪᴠᴇᴀᴡᴀʏ ᴘᴀᴄᴋᴀɢᴇ ʜɪᴛ ᴜᴘ✉️ ᴛᴏ ᴄʟᴀɪᴍ ʏᴏᴜʀ ᴘʀɪᴢᴇ 🎁

My theme for you next video is to mix this type of engine with combustion to increase the force it emits :) Or print your logo with every printer you have and seeing clarity and definition differences only to destroy all the tomatoes in the end lol

Best answer so far

@it's Morbin Time i hate You

ᴄᴏɴɢʀᴀᴛꜱ ʏᴏᴜ ʜᴀᴠᴇ ʙᴇᴇɴ ꜱᴇʟᴇᴄᴛᴇᴅ ᴀᴍᴏɴɢ ᴏᴜʀ ꜱʜᴏʀᴛʟɪꜱᴛᴇᴅ ᴡɪɴɴᴇʀꜱ ꜰᴏʀ ᴛʜᴇ ᴘᴀᴄᴋᴀɢᴇ ᴄᴏɴᴛᴀᴄᴛ ᴛʜᴇ ᴛᴇʟᴇɢʀᴀᴍ ᴀʙᴏᴠᴇ ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^🎁

Would probably be too brittle but the bigger problem would be controlling tolerances during the sintering process. The varying density of the filament caused by the filament inconsistency and imperfections in the print is another thing to contend with too. The vibrations won't destroy a PLA part but with more brittle SLA or ceramic parts the results tend to be explosive.

This

I would watch this

ᴄᴏɴɢʀᴀᴛꜱ ʏᴏᴜ ʜᴀᴠᴇ ʙᴇᴇɴ ꜱᴇʟᴇᴄᴛᴇᴅ ᴀᴍᴏɴɢ ᴏᴜʀ ꜱʜᴏʀᴛʟɪꜱᴛᴇᴅ ᴡɪɴɴᴇʀꜱ ꜰᴏʀ ᴛʜᴇ ᴘᴀᴄᴋᴀɢᴇ ᴄᴏɴᴛᴀᴄᴛ ᴛʜᴇ ᴛᴇʟᴇɢʀᴀᴍ ᴀʙᴏᴠᴇ ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^🎁❤

Or the biggest one ? 🤔

I assume because of the joke at the start, because you couldn't have just stumbled upon this video 7 minutes after it was posted.

He said he reached max rpm so weight isn't a problem since both rpm are the same . Weight affects acceleration.

Most RC cars with a combustion engine are already using nitro fuel

@@boudewijnb I understand , but you know ones we see in the fast and furious ones , a click gives extra power(other than a engine)

Issue 2: is it compressing or simply moving air? Outlet nozzle may be too big. Smaller outlet may give more velocity, and that helps with k = .5 * m * v^2

Issue 3: a tuned rocket nozzle is more efficient than an aerospike at its appropriate atmospheric pressure, but you don't have combustion and supersonic flow, so this is minimal.

the only issue ive had with sterlings are they dont like to speed up or down and the ramp up from starting is quite brutal. may i suggest a few different size motors connected to a mainshaft with an isolator and reduction gears. i have built a canoe motor with 16 sterlings and a reduction gear connected to 2 impellors on the same shaft (feed in-feed out). worked ok but it was too risky for anything more than a still lake

Fr

Further explanation in case I wasn't properly clear: The air accelerated by the EDF fan rubs against the air around it and pulls it along, producing more thrust. The air accelerated by the 3D printed fan rubs against the 3D printed housing and produces heat. My hypothesis is that this causes the difference in thrust.

ᴄᴏɴɢʀᴀᴛᴜʟᴀᴛɪᴏɴꜱ ʏᴏᴜ ʜᴀᴠᴇ ʙᴇᴇɴ ꜱᴇʟᴇᴄᴛᴇᴅ ᴀᴍᴏɴɢ ᴛʜᴇ ʟᴜᴄᴋʏ ᴡɪɴɴᴇʀ ꜰᴏʀ the 🤶 ɢɪᴠᴇᴀᴡᴀʏ ᴘᴀᴄᴋᴀɢᴇ ʜɪᴛ ᴜᴘ✉️ ᴛᴏ ᴄʟᴀɪᴍ ʏᴏᴜʀ ᴘʀɪᴢᴇ 🎁🎉