Building Nikola Tesla's Bladeless Turbine [video](youtube.com)
youtube.com
Building Nikola Tesla's Bladeless Turbine [video]
https://www.youtube.com/watch?v=Tuzh9mHvzkk
52 comments
I think the limiting factor on this type of turbine is the material you use to make the disks. As the disks get bigger the rotational stresses increase. To be practical the stress induced would need to be below the ultimate tensile strength of the material. Since these turbines need to spin at extremely high rpms and need to be fairly large to be efficient, there's no practical material that they can be made of.
> and need to be fairly large to be efficient
This statement is not true. Actually the inverse is true, the smaller you can make the disks, the better the efficiency.
See https://onlinelibrary.wiley.com/doi/full/10.1002/ese3.1417
> As disc outer diameter decreases from 100 to 50 and 20 mm, the isentropic efficiency of the miniaturized turbines increases significantly from 21.46% to 30.78% and 32.21%, respectively.
This statement is not true. Actually the inverse is true, the smaller you can make the disks, the better the efficiency.
See https://onlinelibrary.wiley.com/doi/full/10.1002/ese3.1417
> As disc outer diameter decreases from 100 to 50 and 20 mm, the isentropic efficiency of the miniaturized turbines increases significantly from 21.46% to 30.78% and 32.21%, respectively.
Not Op, but I suspect the use of "efficient" here is used more in terms of "usefulness of output" rather than pure turbine efficiency.
For example, you might have a VERY efficient turbine, but if they're constrained to be small (and therefore low-output), you then need to have a squillion of them, which is not an efficient use of money or effort expended, in terms of output power total.
For example, you might have a VERY efficient turbine, but if they're constrained to be small (and therefore low-output), you then need to have a squillion of them, which is not an efficient use of money or effort expended, in terms of output power total.
Given that the point he makes is that they've got high torque at low RPMs and that's what makes them interesting, I'm not sure that's relevant here. Frustratingly it doesn't go into any more details than that.
It seems like while the turbine works great, the rpm output is too high, with too little torque, and you loose most of the gains when gearing it down, which is also difficult to do
That’s what I’ve read, haven’t built one
That’s what I’ve read, haven’t built one
Lesics (another Youtube channel) argues that current turbines are already 90% efficient. For Tesla Turbines to reach the same efficency it needs to spin in really high rpm (maybe 50 000), which makes it impossible to built disks for it. Those disks would have to be 2-3 meters in diameters for industrial applications and couldn’t withstand the forces.
This wouldn't surprise me.
Modern turbines are very, very optimized, because they are used in systems like power plants. Here, every fraction of a percent of efficiency is massive. Hence, modern turbines are optimized as much as many, many smart people can do. This in turn means, even if Tesla just designed something pretty efficient many years back (which would be really impressive), it just loses in modern, industrial applications.
Like, people have been looking at better ways to generate electricity from nuclear or fusion reactors. But current steam and steam turbine systems have been optimized so hard and far, it's extremely challenging to find anything better than just heating water and jamming it through a turbine. Because current steam turbine systems are just that good.
It reminds me of the recent thread about hypothetical usages of the recently discovered and not yet confirmed room temperature super conductor. So many people are just arguing that a potential material that was discovered 2 or 3 months ago would be worse than silicon based electronics we've been optimizing for 40 - 50 years, or steel-based long range transfer we've been optimizing for longer.
Modern turbines are very, very optimized, because they are used in systems like power plants. Here, every fraction of a percent of efficiency is massive. Hence, modern turbines are optimized as much as many, many smart people can do. This in turn means, even if Tesla just designed something pretty efficient many years back (which would be really impressive), it just loses in modern, industrial applications.
Like, people have been looking at better ways to generate electricity from nuclear or fusion reactors. But current steam and steam turbine systems have been optimized so hard and far, it's extremely challenging to find anything better than just heating water and jamming it through a turbine. Because current steam turbine systems are just that good.
It reminds me of the recent thread about hypothetical usages of the recently discovered and not yet confirmed room temperature super conductor. So many people are just arguing that a potential material that was discovered 2 or 3 months ago would be worse than silicon based electronics we've been optimizing for 40 - 50 years, or steel-based long range transfer we've been optimizing for longer.
Also, people forget that Tesla was more of a “throw together until it works” inventor, not a scientist. He didn’t believe in goddamn electrons, even though that was already the accepted theory of the time! While many of his inventions are fascinating and genius, I think there is an unhealthy mythicism and hype around him.
As for current turbines, I remember they are grown from a single crystal, as any kind of joint would be a breaking point in the material. They also have to abide by very strict size restrictions, at that RPM a single millimeter wobble can have catastrophic damage.
As for current turbines, I remember they are grown from a single crystal, as any kind of joint would be a breaking point in the material. They also have to abide by very strict size restrictions, at that RPM a single millimeter wobble can have catastrophic damage.
How does lesics arrive at that figure? In my turbine design course we were taught that the absolute maximum is around 57% else the outgoing fluid won’t have enough kinetic energy to get out of the way of the incoming
I don't know. Here is the Video: https://www.youtube.com/watch?v=AfCyzIbpLN4
And here with timestamp: https://youtu.be/AfCyzIbpLN4?t=448
Tesla invented this because he wasn't happy that cavitation was reducing the life of bladed turbines.
A plastics injection molding mechanical designer in China told me rotational blades are the hands down most irritating thing to try to injection mold because conventional tolerance factors that are very well suited to the production of most other products will often result in imbalance, noise, vibration, wear and failure in rapidly rotating bodies.
I've seen a five axis mill that is used to cut turbine blades (in Poland, through an industry contact of mine), it was an absolute work of art and I totally believe the injection mold designer. Everything was compensated for, including tool wear and heat injection. the whole thing was cut in one run without any tool changes or re-registering. One set of tools for one blade.
I used to work at a plant like this, we were acquired by Siemens. The machining process itself is less critical than the balancing and even the welding of these components, which is highly engineered and controlled.
I can imagine. Manufacturing tolerances will have some minor effect on balance and efficiency, failure of a weld or large imbalance or resonance would be fatal. Even so, the machining process itself was quite impressive to someone who is used to 'regular' CNC machining without working to such close tolerances. The movement of the cutter was very interesting too, hypnotizing if you will :) I forgot what the material was, these blades were for aircraft turbines.
What kind of turbine blades did you work on? Gas turbines for stationary applications or for aircraft or something else? Do you remember what material they were made out of?
What kind of turbine blades did you work on? Gas turbines for stationary applications or for aircraft or something else? Do you remember what material they were made out of?
That is the kind of process engineering and fabricating that is fascinating to me.
It is. The company that built the system makes very nice stuff.
This is the Chinese parent company with subsidiary in Germany:
https://www.inovance.eu/industries/cnc-machine-tools
And this is the notice about them acquiring Powerautomation, the German company that designed and manufactured those controllers:
https://www.inovance.eu/news/details/inovance-technology-eur...
PA was a fantastic company but like many such specialist producers they didn't have a clear succession path laid out so they eventually got sold.
This is the Chinese parent company with subsidiary in Germany:
https://www.inovance.eu/industries/cnc-machine-tools
And this is the notice about them acquiring Powerautomation, the German company that designed and manufactured those controllers:
https://www.inovance.eu/news/details/inovance-technology-eur...
PA was a fantastic company but like many such specialist producers they didn't have a clear succession path laid out so they eventually got sold.
I’m similarly interested. Does anyone know of an introductory book on modern production technology? It somehow seems to be an impenetrable topic to me without actually doing a major in some kind of engineering.
This would be a great start but it is a pretty large book:
https://books.industrialpress.com/9780831136369/the-cnc-hand...
Also, the materials science and engineering handbook. It's floating around on the web in PDF form if you just want to skim it but if you really need it you should probably buy a copy (warning: huge book):
https://www.amazon.com/Materials-Science-Engineering-Handboo...
https://books.industrialpress.com/9780831136369/the-cnc-hand...
Also, the materials science and engineering handbook. It's floating around on the web in PDF form if you just want to skim it but if you really need it you should probably buy a copy (warning: huge book):
https://www.amazon.com/Materials-Science-Engineering-Handboo...
The problem there is almost certainly people using "efficient" when they mean "fast" or "productive." Easiest example for that, in the past, was people mistakenly thinking gas stoves were more efficient than electric. Not even getting into induction, which can also be fast, the standard electric stove tops were far more efficient than the gas counterparts.
So, my guess on why people don't use this is that they can get more output from other designs. Even if they are "less efficient."
So, my guess on why people don't use this is that they can get more output from other designs. Even if they are "less efficient."
This reminds me of how annoying “efficient” appliances are. To comply with increasingly strict energy and water regulations, modern washing machines have small capacities. But that just means I have to do two loads. It’s not actually efficient at all. Certainly not time efficient. Each load probably has some energy and water overhead as well, so more is worse. Also, since agitators require energy, they are becoming less common, so the clothes are less clean, too, and that probably leads to extra loads being done.
The way we talk about and regulate efficiency is all messed up.
The way we talk about and regulate efficiency is all messed up.
I think we do use this turbine but with thicker liquids and in reverse as a pump -- maybe it was in oil or some of the chemical industries?
It has terribly low stall torque. Basically it spins really fast and really efficiently, until you actually try to put any kind of load on it and make it do anything. The load slows down the disks, which disrupts the boundary layer and causes a negative feedback loop which makes it less and less efficient.
So load it with an electrical generator and use power electronics to present a constant load. Problem solved.
Many old high efficiency engine designs were discarded because they had poor torque characteristics at the bottom end of their speed range. This is because they were coupled directly to the load through gears. That does not have to be a requirement any more.
Many old high efficiency engine designs were discarded because they had poor torque characteristics at the bottom end of their speed range. This is because they were coupled directly to the load through gears. That does not have to be a requirement any more.
A constant load is only useful under limited circumstances, you would need to be either constantly starting and stopping your generator or wasting energy with a dummy load for this to work.
Could you do it? Sure. Does it completely negate the advantages of the turbine? Absolutely.
Could you do it? Sure. Does it completely negate the advantages of the turbine? Absolutely.
depends who you ask. If you watch these characters they come and go. They often argue with each other. Charlie is the latest and certainly the least ridiculous.
The best argument might be that current manufacturing techniques have caught withe requirements.
I plan to build one.
The best argument might be that current manufacturing techniques have caught withe requirements.
I plan to build one.
You cannot have very high torque on this thing.
Correct.
The size of the disks compared to a traditional turbine would easily consume a four to six story building for, say, steam energy generation. They would also need to spin at 50k+ rpm to reach their claimed 90% efficiency. Thats a blade tip speed of mach 13. Not easy.
The size of the disks compared to a traditional turbine would easily consume a four to six story building for, say, steam energy generation. They would also need to spin at 50k+ rpm to reach their claimed 90% efficiency. Thats a blade tip speed of mach 13. Not easy.
Narrator: "I know Charlie seems like your average Nikola Tesla fanboy, but he's not (...)". Not sure what part he is referring to that he is not, but we're definitely seeing some Nikola Tesla fanboyism there, looking at the live size Tesla poster and the man himself which looks like a Tesla replica :D
Cool video.
Maybe it’s meant as not an average fanboy but a much bigger one :D
Integza is one of the few channels where I will watch every single video and be both educated and entertained regardless of the subject matter.
It’s so fun to watch these builder-youtubers develop over time.
If they just keep on releasing videos and building stuff, even if they are not so skilled in the beginning eventually they become really skilled! It really shows that practice yields mastery.
Tom Stanton is another on my list.
If they just keep on releasing videos and building stuff, even if they are not so skilled in the beginning eventually they become really skilled! It really shows that practice yields mastery.
Tom Stanton is another on my list.
Indeed! I'll pile on some of mine just in case:
https://www.youtube.com/@HyperspacePirate
https://www.youtube.com/@AirCommandRockets
https://www.youtube.com/@LesLaboratory
https://www.youtube.com/@harrisonlow
https://www.youtube.com/@michaelrechtin
https://www.youtube.com/@HuygensOptics
https://www.youtube.com/@jdflyback
Not builders per se but really informative still:
https://www.youtube.com/@Lantertronics (great electronics vids, especially analog guitar pedal stuff)
https://www.youtube.com/@machinethinking (machining history)
https://www.youtube.com/@AgentJayZ (in-depth about jet engines)
https://www.youtube.com/@HyperspacePirate
https://www.youtube.com/@AirCommandRockets
https://www.youtube.com/@LesLaboratory
https://www.youtube.com/@harrisonlow
https://www.youtube.com/@michaelrechtin
https://www.youtube.com/@HuygensOptics
https://www.youtube.com/@jdflyback
Not builders per se but really informative still:
https://www.youtube.com/@Lantertronics (great electronics vids, especially analog guitar pedal stuff)
https://www.youtube.com/@machinethinking (machining history)
https://www.youtube.com/@AgentJayZ (in-depth about jet engines)
> It really shows that practice yields mastery.
100% true, but I'd like to change the word "practice" to "interested and intentional pursuit".
Practice is rigid and structured. You can be told to practice piano for years, but you may never become great at it.
When you find something you love, you drill into it yourself. Vertically, horizontally. It absorbs you. Expertise accrues through playful exploration and repetition.
That's not to say you don't have to drill certain things. Professional piano players, professional athletes, professional gamers -- they all wind up doing "boring" drills of the same moves. But the craft isn't all technical all the time, and the endurance to withstand drills is greatly enhanced when you're hooked on playing.
100% true, but I'd like to change the word "practice" to "interested and intentional pursuit".
Practice is rigid and structured. You can be told to practice piano for years, but you may never become great at it.
When you find something you love, you drill into it yourself. Vertically, horizontally. It absorbs you. Expertise accrues through playful exploration and repetition.
That's not to say you don't have to drill certain things. Professional piano players, professional athletes, professional gamers -- they all wind up doing "boring" drills of the same moves. But the craft isn't all technical all the time, and the endurance to withstand drills is greatly enhanced when you're hooked on playing.
FWIW another design tried ~15 years ago was humdinger energy.
http://web.archive.org/web/20100305210816/http://www.humding...
Later on before they shut down they were selling kids kits of the windbelt idea: https://www.vernier.com/files/kidwind/humdinger_windbelt_man...
http://web.archive.org/web/20100305210816/http://www.humding...
Later on before they shut down they were selling kids kits of the windbelt idea: https://www.vernier.com/files/kidwind/humdinger_windbelt_man...
Watch about 1 minute starting at 03:00 and you'll see all the useful content.
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When I was a kid this thing was legendary, most people had never heard of it and most of those who had thought it was a hoax. An engine with one moving part...
The only place that had actual information on it was an obscure service that advertised in the classified ads section in the back of Popular Science, Rex Research: http://www.rexresearch.com/1index.htm
It's wild to see videos about it today.
(Also, check Rex Research for other cool obscure tech. Much of it is crackpot, of course, but some of it is not. E.g. the vaneless ion wind generator, a wind-to-electricity generator with no moving parts. https://en.wikipedia.org/wiki/Vaneless_ion_wind_generator There's more...)
The only place that had actual information on it was an obscure service that advertised in the classified ads section in the back of Popular Science, Rex Research: http://www.rexresearch.com/1index.htm
It's wild to see videos about it today.
(Also, check Rex Research for other cool obscure tech. Much of it is crackpot, of course, but some of it is not. E.g. the vaneless ion wind generator, a wind-to-electricity generator with no moving parts. https://en.wikipedia.org/wiki/Vaneless_ion_wind_generator There's more...)
This is not an engine. In the linked video it has 75 distinct moving parts. It also looks like a maintenance nightmare with particulate and deposits getting into every crevice including direct access to the bearings.
I absolutely love this channel. I went ahead and ordered the 4.5" prototype. I've wanted to get my hands dirty in this space for a long time now. There are several pieces of turbo machinery scattered about my garage that were never integrated into anything interesting.
Starting with something that mostly already works is probably more healthy for my side-project time budget & attention span.
Starting with something that mostly already works is probably more healthy for my side-project time budget & attention span.
Some great Tesla turbine builds on this channel. This is my favorite channel for anything Tesla turbine related https://www.youtube.com/@iEnergySupply
definitely a lot of great builds but they desperately need an editor and should drop the big promises.
The video frustratingly says, "People think it's inefficient. It's not." End of story.