What if I stalk myself and post novel length comments here?? 😂😂

I agree.. but I have to mention, I am one of those people you mentioned who has spent almost 22 years designing a vane powerplant.. There is well over 70 iterations on my design table and shelves. Most of them run, but the one problem that I run into and many others must cross, is the pressure relief on the back sides of each vane. If it is only air behind the vanes, that is okay, and helps keep the vanes outwards in addition to the rotational forces that naturally fling the vanes outwards. But, once you start to collect any liquids, behind the vanes, that is where me and so many others run into crashes, or failure of the machine. We have tried to vent this trapping system to both the intake side to suck any liquids out of on the exhaust side to be pushed out from the linear motion of the vanes telescopic travel in a pumping action... Even tried to just vent these trapping areas to external areas, for collection just to try to get past the issue... I have tried through holes vents long wise in the vanes themselves to allow the trapped liquids to relieve into the front side of the vanes for additional lubrication on the walls, and likewise on the aft side of the vanes in efforts to lubricate the next following vane.... In either of those, we get hovering of the vanes at higher rpms as the edge is trying to either collect/scrape/scoop up the previously laid oil/fuel and grit and results in HP and rpm loss, and after extended periods of endurance runs, hammering effect of the walls, does what we call "catipillar walling" of harmonic wearing in a sign wave and that creates a nasty problem that compounds on itself to destruction very quickly.... These units are so much fun, but I am personally burnt out.. the math mathematics that goes into the volume of the wedges to intake/exhaust to the dimensions of the vanes length, width, height and or length to thickness issue. Based on over 200 material iterations in some base models, and discover some work great some not, but it just keeps the battle of wear factor to life expectancy of the vanes and housing wall(s).. the saving grace is the ease of machining, as compared to the exceptionally tight tolerance of the Wankle housing to rotor dimensions to aid in prevention wedging or crashing.. these vane motors are pretty forgiving in manufacturing... Allot of work, (as you stated) is still needed by somebody who has more money then me.. I am just a guy in a machine shop playing part time on these, in fact, I haven't touched them in about a year or so... I am not saying anything you said is wrong, but more over, agreeing with you, there is allot of potential for these designs, but somebody who has more money then me can play with more specialized materials / alloys, and simulation software better then mine to hone every bit of active and passive friction out of the entire rotational cycle while incorporating balance as a whole.. Oh, and another crazy issue, leeching, from a combusted chamber, leeching under the wiping edge to the yet not combusted air/fuel ... With a mass damper damage happens in the idea to just carry the rotation on over past the preignition leeched chamber with bent vanes, or snapped axle shaft or ruptured wall.. that is always a fun day and loud too... With out a flywheel aid to dampen things out harmonically, the motors rattle themselves into shavings and scrape themselves to death. Smaller power tools vane pumps are stable, but the moment they step up to combustion, a whole other character of issues happens... Which is what the one photo of the multi-vane rotor was trying to deal with I think it was a (20 vane rotor) also trying even number of vanes and odd number of vanes all trying to calm down the harmonics or vibrations that rattle these into destruction... I wish more people could put more effort and money into this, venture.. The biggest unit I have that is still working is 5 inches, and offer (0.2 HP) @15,000 rpm .and is on a bicycle and geared super low and allot of backfiring from unspent fuel but does work just not very good but is on the threshold of not ripping itself apart.. Maybe this winter, I can get back on these

I think that the REAL solution is not to eliminate reciprocation, but eliminate rotation. Instead of wheels, we should have large legs that hammer the car down the road.

Your video caught my attention as I designed this exact engine 40 years ago while in high school. I grew up on a farm and we fixed everything and I knew every part in every engine we had. I liked the idea of the rotary engines and first is how to lub it. I tossed that aside and though do it like a two stroke. Ok that will work now how long will it last. After seeing OIL pumps fail that just pumps oil I began to have doubts that it would last any time. Now the emissions have be be cleaned up. Best is cylinder and odd shaped combustion chambers do not burn well in the wedges and they are just there. I lost interest in it and have lost my original drawings somewhere in the many places I have been. Thanks for the video.

as an engineer, i see problems with it: 1. wane reliability 2. lubrication 3. crosschamber isolation

"What if we push fluid into a pump, and make it explode too"-type-engine I love it

For a few minutes I was thinking this was a beautifully simple concept. Then the issues of lubrication and stresses on the vanes brought me back to earth. Nice mental exercise.

Excellent video! I’m a mechanical engineer and have been involved in compressors and gas pumping equipment for use in chemical plants and oil refineries for 50 years. The achilles heel for vane pumps is not just vane wear against the compression housing, but also vane blade failure, spring fatigue, and the buildup of combustion byproducts and sludge in the vane slots on the rotor causing the vanes to stick. Though not a thing for automotive use, vane compressors are still used in industry with some regularity and many attempts have been made to make them more reliable. But still, this technology takes a backseat to more reliable designs - with all their weaknesses - such as reciprocating compressors. Even in aviation, most light aircraft use vane style vacuum pumps to generate vacuum for flight instruments. But, they too are quite prone to failure which requires two pumps to be installed for backup. Someone may solve these problems with materials and reciprocating vane design improvements, but it is still on the horizon and not here yet.

Rx7 owner: the apex seals were a major problem in a wankel. Vane engine: "hold my beer"

17:07 When you said "Roy Hartfield", that caught me off-guard for a second - because I'm currently a student at Auburn University, and I thought "wait, THAT Dr. Hartfield??" Sure enough, it's the same guy, and I walk past his office every day! He's one of the aerospace engineering professors in Davis Hall. If you want to ask him some questions, perhaps you could reply with them here and I can stop by his office to pass them on in-person to get his response!

The Wankel engine has one crown the sliding vane hasn't taken yet: It worked to the point it reached production level to be used on real life, day to day applications.

Well, this is the first mention of this type engine I have seen. I am all for this mechanical technology.

The Vane engine, now with 33% more apex seals flying out of your exhaust

I checked with my step-son who is highly regarded in the field of engine design. He agreed with the multiple potential benefits. He also agreed with you flagging the seals as the unsolved problem. He said no-contact gas seals using ceramic piezo-electric actuators in jet engines seal a constant-size gap. That is trivial compared to sealing the variable-diameter vanes. It would be difficult to extend the vanes outward to a consistent length at a um tolerances. In addition, they would have to do this while being exposed to both the full heat of combustion and the full speed of the rotor. I learned a lot from this episode. Keep'm com'n.

There are three things to look for in any new miracle engine technology: 1- How is it cooled. 2- How is it sealed. 3- How is it lubricated. Cooling this thing would be similar to a Wankle so not that big an issue. Sealing this thing would likely be exponentially more difficult than with a Wankle which already has issues with apex seals. In addition to the issues faced by Wankels the amount of travel of the vanes at any significant RPM would likely get into the same issues as seen with early valve springs. Lubrication would require some oil burning (bad for emmisions) and lubrication of the sliding vanes under high temperature and pressure.

About 2 decades ago as a mechanical design draftsman with equivalent of 2nd year mech eng and also obsessed with the idea of a better ICE with lower weight, smoother operation and torque, I came up with several iterations (unfortunately only in digital form, no contacts, money or time to do what I wanted to do which was get a prototype built). There were some differences between mine and the design shown in this video. One being that the rotor isn’t circular but elliptical and the vanes in mine were located not in the spinning rotor but in the casing which solves quite a few problems and allows for a sturdier, precision cam-operated vane with lighter sliding seals against the rotor. Also, the exhaust gases vent through ports that open in the side of the housing, ensuring almost complete venting of exhaust gases. One problem with this type of engine is that combustion always occurs in the same location, and the housing will get extremely hot there, but modern materials and cooling systems should cope. I’d also love to see this type of engine happen. I honestly think that this is one of the many things that humanity has failed to exploit to our advantage.

I had exactly the same idea when I tore down a refrigeration compressor 30 years ago. When I delved deeper I discovered a fella in Rochester NY fitted one to a motorcycle in the 1930s & ran it for a week before concluding that it wore out too quickly. It could be made to work but you'd have to lubricate it the same way as a 2 stroke engine, but then you'd have problems with exhaust emissions.

I have been looking for a analysis on this engine for almost 5 years now, thanks

"Things tend to not exist and not be used.... before they are.... existing... and used...." This is the kind of wisdom that brings me back to d4a, thank you 😂

I love your channel and you are so gifted at helping the average mechanic understand the concepts of so many different designs that I can’t help but think you could design something to overcome the obstacles to the vane engine…

Actually, the best type of internal combustion engine is neither a Wankel nor a Rotary Vane engine. It's a Turbine engine, for all the reasons you described. A Rotary Vane engine is interesting, but I'm wondering what the wear characteristics would be like. The vane being a long lever arm is good for torque, but it also means it will need to resist a lot of side-load forces while still moving smoothly in and out to maintain the seal with the sidewall. They work fine for air tools because the pressurized air is providing a steady pressure with a low impact compared to the shock front of a fuel detonation. No contact seals work for Turbines because the blades aren't moving in and out. There's no travel, just thermal expansion to compensate for. It's not feasible to maintain a gap like that while the vanes are moving in and out at the rotation speed of the engine.

As a machinist, I have to say this: this design is neat on paper but would absolutely grenade itself. Anytime you add a spring loaded dragon into a rotating assembly, the centripetal forces will cause problems, in addition to the fact that there is not enough structural material to keep those fins from bending themselves out of the central assembly. It is wildly impractical.

Sometimes it scares me how much in sync we are ! I’m literally working on a Rotary Vane design, a pneumatic one for now. It is so hard to seal it properly!

Back in school we designed and built a rough prototype of a compressed air powered scooter. Our motor was based on a rotory vane pump and built into the wheel hub. It was kind of inside-out for lack of a better term, with the ouside rim acting as the rotor. We had 3 different rings, the two outer rings were higher torque for acceleration, and the smaller one on the inside was for cruising.

I am 76 years old engineering designer, I designed an engine like that when I was 15 years old. Then later I found out thats how positive displacement hydraulic pumps works

D4E talking about unconventional looking engine designs? Sign me up!! Every time you upload a video about neat little engines and stuff like this it makes my day :)

I'm not a physicist or engineer, but the first thing that jumps out to me on this is that a vane type oil pump doesn't have to address heat from combustion. That floating vane will have the full heat from combustion, and it looks to me like it has a very limited time to shed that heat. That means the metallurgy of the vane and rotor must be able to deal with that heat without the vane expanding and binding in the rotor. As soon as you introduce contactless sealing such as an air gap or some piezo sealing, you've further reduced ability to shed heat because you no longer have contact with the mass of the static housing.

I love this guy. I wish he was my next door neighbor. He'd be cool at barbeques.

Big problem is the lateral forces on the vanes are so large that a great spring force would be required to overcome the friction caused in the slots and prevent binding and premature failure . As the vanes extend , even the smallest gap between them and the slots will cause the vanes to lean forward and bind . This “rocking “ motion of the vanes would be worst at full vane extension . I can’t imagine any lubrication system that could counter this , even with ridiculously oil rich fuel . Springs strong enough to reduce binding must lead to gouging of the combustion chamber. The thing would chatter like crazy under any real load .This design can only work in CAD with theoretical materials , lubrication and zero tolerances

"There is zero reciprocation" The vanes reciprocate in their slots.

I think this reveals one of the big dilemmas of engineering: Do you start with something fundamentally inefficient but easier to make and then work to optimize it as much as possible, or do you try to make the theoretically optimal solution, even if it is extremely hard to make it work, let alone work reliably? Going down the first path can leave you in a technological dead-end, while the latter could result in a project being dead in the water.

My first car purchase for myself was a used Mazda Rx3 station wagon and it was so fun to drive with it's manual transmission, that a couple years later, I bought a brand new Mazda Rx4 pickup truck, the first year they were released, again with a manual transmission. I doubt anything could have been more fun to drive for an 17 year old teen, with it's yellow paint and black racing stripes, N50 x 14 inch diameter fat tires and soft bed cover. It looked great, and ran like a top, until it started burning a quart of oil with almost every tank of gas I put into it due to worn rotor tip seals, and trying to find mechanics outside of the dealership to rebuild rotary engines, was almost impossible and cost about $1,500 in 1977. If Masda came out with another rotary engine vehicle with even just slightly longer lasting rotor tip seals, and a bit cheaper rebuild price, I would buy a rotary again. They are just that much fun to drive, because the horsepower curve is so different than a piston engine engine.

I designed a few engines like this... and for several reasons, they don't work well. #1- inherently low duty cycle, due to dedicated combustion/exhaust surfaces. Heat build-up in these surfaces presents an issue with both degradation and uneven expansion across the radial plane #2- surface area to volume ratio makes thermal efficiency a challenge #3- lubrication issues abound... with the only reasonable solution being vanes made of a self-lubricating wear material, and requiring frequent inspection/service/replacement Of all the issue presented, there were a few I resolved. 1- utilizing technical ceramic (zirconia) for the casing and central rotor, relieved numerous cooling/friction issues... but the expense isn't feasible for mass production, and thermal shock limitations all but eliminate the possibility of use in frigid climates #2- using arched vanes made of dense carbon graphite, and contouring the outer casing to permit the movement, such that one side is extending while the other is retracted, significantly mitigated vane control issues. Conversely, this created a tuning issue, as it altered the displacement volume between alternate vanes. It also did nothing to mitigate the load induced on the outer case friction surfaces, which increases at the square of RPM. All this being said, a number of well-funded projects have addressed the fool's folly of the rotary vane engine. Most recently, RadMax Rand Cam engine oriented vane actuation along the axis of the engine, as opposed to radial extension. This allowed engineering around the dynamic load of the vanes in a far more manageable window. The engine ran, and was very smooth... but required more vanes to allow more efficient compression ratios. This presented two problems... spark management/delivery for gasoline, and injection issues for diesel operation. To my knowledge, only one successful prototype was built, and progress halted for numerous reasons. Nearly every internal surface required precision machining, thermal management still created issues of uneven expansion, serviceability of nearly any component required complete disassembly, and packaging for any reasonable duty cycle proved non-beneficial. As stated, numerous companies have seen significant success in pneumatic expansion applications... but expansion motors don't face the thermal management issues of an ICE. To my knowledge, the most successful private attempt at creating a viable rotary vane engine, was documented on the KZbin channel by RotaryICEman. Despite numerous running designs, and favorable efficiency readings, reasonable success was never found.

"If it is so good why isn't it being used already?" Goddamn right. This is the first question to ask and 99.9% of the time the answer is out there, and has been for decades. More efficient, smoother, yup. No quibble there. The problem arises when you try to keep an internal combustion vane engine alive long enough to make it to the grocery store and back. Vanes make decent pumps and air motors as you noted. The problem is for a given vane depth/length from hub to chamber wall there are pressure limitations. Vane engines kill the actual vanes with heat, lack of lubrication, and side loading of the vane in the hub/crankshaft. Sealing the outer diameter (like an apex seal) is not too tough as compared to keeping the vane from killing itself in a hostile work environment. No doubt on paper it is great, and it has its advantages, but the real world is harsh.

I drew a picture of that engine in the 12th grade when I first read about sliding vane supercharger's. It's just a sliding vane supercharger run backward, and there's actually a more workable version which attaches the vanes to an offset hub instead of having them drag on the walls. But they problem is the vanes still need to drag on the slotted hub that they are pushing around.

Ever heard of the Quasiturbine? I has the benefits of the vane engine but improves upon many of it's drawbacks.

It feels like we’re just getting closer and closer to turbine engines but refusing to admit it

My Grandfather, Robert Williams, designed and patented several of these in the 1960s and 1970s. It was difficult to get vanes which would seal and also resist wear, not just at the tips, but in the slots where they slid. They got a lot of leverage pressure on them, too.

I wouldn't be surprised if some obscure motorcycle engine builder from Thailand would try to replicate this engine.

Before I make a comment, I want to say that I love your videos. You do an excellent job of explaining things. As others have noted the flywheel needs to be better balanced or it will shake itself apart. The flywheel is setup for only a single ignition event per rotation and you need at least six ignition events per rotation. What I haven’t seen anyone else mention is that it looks like the output of the exhaust is aimed near the top of the carburetor. The problem with this is, as the engine is still experimental, you will probably have incomplete combustion inside of the engine meaning that at a minimum you will have hot exhaust gases hitting the top of the carburetor. This is dangerous. It needs a exhaust pipe to direct the exhaust gases in a safer direction. A six inch long tube of the proper diameter would probably do.

I designed but never built a similar engine in 1976. It had 7 vanes with combustion occurring in them every other cycle. This would have kept the engine temperature stable. Projected HP around 250, at 8K rpm. My father passed before we could build it, together.

as soon as I saw the design I thought the big problem is going to be the vane system, sealing and friction, also the lateral force on the vanes, I wish I could research this Idea since i'm in my last year of mechanical engineering bachelor and I'm searching for new ideas in the industry. this channel has been a great learning source for me.

Those springs are already screaming: POINT OF FAILURE

As a professor who has tried to design a real-world vane engine, you have correctly identified the main problem - centrifugal force on the vanes. I vividly recall drawing up what would be a great little 5 lb 50 horsepower engine - and then calculating that each of my 24 vanes would have 5 tons of tangential force on the outer chamber. Why 24 vanes? You touched on, but did not develop the side forces on the vanes. The high pressure in one chamber compared to low pressure in the next makes sealing hard and it also will deflect the vanes or make them :stick" in their slots. Going to more vanes solves both of these issues because it reduces the pressure differential on the vanes. This also allows the use of thinner vanes - with less centrifugal forces resulting. Vane pumps work well if they are pumping lubricating fluid. They work poorly if not. Combustion is the enemy of lubrication. But yes, I agree that if you can solve the vane engine, the piston engine will die! One more thing. The active clearance on a jet engine is against a round, constant radius surface. The non-constant radius outer surface on a vane engine is an almost infinitely more complex problem.

A few things I have to say to the last part, the why it is not done yert: The combustion side excerts pressure on the vane holding cylinder in the middle. This results in asymetrical pressure on the shaft. Wich means asymetrical wear on the shafts bearings. Wich leads to the whole thing not being able to hold a 3 micrometer seal after just a few hours of running at most. Even with hightech ceramic bearings and so on. You would need at least a 4 disc version with 90° staggered combustion chambers to balance out the pressure on the shaft overall. But it would still lead to deformation of the shaft in the long run, again for the whole thing not being able to hold its seal. And it would be no issue if the piezo actuors could be used to pull the vanes in, and push them out, and basically hold them at the correct position all the time. The "problem" here is, that the forces acting on the vanes are vastly asymetrical, and thus holding a balancing act of 3 micrometers would be all but impossible, especially if you factor in external vibration sources like a rough road surface, the rough tire surface and the suspension and engine mounts directing miniscule (but larger than 3 micrometers) vibrations into the engine block. The acutors would have to get input signals and center these vanes at a rate, that can not be achieved if you factor in a sensor to detect them, a processor to calculate the movement, signal traveling speed at 80% the speed of light, and the acutuator acting on the vane to compensate externally induced vibration. Also the shaft in the middle must run in its bearing basically without any kind of tolerances, maybe in the nanometer range, to not translate any lateral movement onto the spinning disc and the vanes. The reason why it works so well in a Wankel is the excentric shaft and the moving contact point on the gearing of the rotor. In theory, this could be built at an anstronomic cost (3 micrometers are higher tolerances than in F1 engines or the most sophisticated Jet Turbines, a modern car engine has 50 - 100 micrometers of tolerance between the piston and the cylinders, and the sprung ring running a oil film to center it dynamically constantly), and run as a single disct for hours, as a quad disc for maybe days until the warping of the shaft creates imbalance, and suspended on fluid seals or something, because the people walking by this engine would cause enough vibration to decenter the vanes and make them impact or leak gas. Or a truck driving by the whole building. Thus: nice in theory, but with current technology and most likely ever physically achieveable technology (signly travel time at light speed as limit) not achievable for a vehicle engine. And since the buffins at large motor corperations would also be able to think of that in a heartbeat, its the reason why none of them ever tried, and most likely never will. The only way I can imagine to get the thing practial is pretty huge gaps, and a hydroseal by having the tips of the vanes expell high pressure liquid like oil or fuel, wich would be lost quiet a lot, and create a high torque, compact engine with horrible fuel economy or if you use oil, economic impact. But it would work (with piezo actuators holding a few hundret micrometer gap filled with fluid, wich can handle the warping of the shaft and shaft bearing for a longer time, and compensate vibrations).

Just FYI, pumps at gas stations are typically NOT vane pumps. Vane pumps do exist in what are known as suction systems, where the pump is in the dispenser (as opposed to the tank), but these are usually really old systems with 1 or 2 dispensers, and you will recognize them by the caucophany of noise and vibration coming from them. The vast majority of public gas stations use submerged centrifugal pumps in the tanks.

*16:40** I WAS LITERALLY SHOUTING "ROLLS ROYCE DO THIS WITH JET ENGINES"* at the computer when you said it - I had a personal tour of the RR Derby factory in about 2004 The single best thing ever in my life - utterly amazing. The grow the compressor blades as a single crystal

Ok this channel has achieved one more subscriber. Really liked the content, keep it up, not much people talking about potential tech like this

look at this guy, looking down at piston and wankel engines like he's so much better.. so... vane :p

The main problem with the Rotary Vane and the Wankel engines? Lubrication. The reciprocating engine has survived because it is easier to keep the "bang" away from the oil.

After thinking about this for a while, the biggest issue is going to be lubricating the vanes. Some people have already mentioned that one of the major issues here is getting debris and fluids in the vane channels. However, since the 'crank shaft' (if we want to call it that) does not spin in the compressor wheel, you have a lot of freedom to use it to supply oil as well as a provide weep holes. The key here is that you will need pretty high oil pressure to stabilize the vane in it's channel and to keep combustion from trying to escape through the weep hole. You basically have to make a hydrostatic bearing that also acts as a seal. Immensely tricky, but not impossible.

Nice video, good explanations. I bit of load can be added by turning on the ac on defog and also electric defrost, while you're at it. Then again, you can install a diesel parking heater. I did this on my L200/triton and on my old beater dacia Logan. That way you raise the temp close both of the engone and quickly defrost the cabin.

1:09 If you would have arranged those circles just a little differently you would have had a wankel rotor!!!

I see three problems: 1.) Seal reliability. You have to seal around the rotor as well as the vanes. This is a huge perimeter compaered to that of a cylinder/piston seal. 2.) Friction. Keeping a tight seal along this long perimeter is likely to cause more friction. And all of of this is going the be difficult to successfully lubricate, especially where the vane slide in and out. 3.) Heat build up. There is going to have to be a way to cool the rotor and the vanes.

the wankel knew where it was because it knew where it wasnt

Fantastic video! Thank you for explaining rotational vane engines so clearly. It really got me thinking about miniaturizing and mounting them like electric motors to minimize gyroscopic effects in vehicles. I'm excited about the potential improvements in handling, stability, and engine efficiency this could bring. Keep up the awesome work - looking forward to your next insights!

3:40 check out "The how and why of mechanical movements" from 1967, page 206: 1964 Renault supplied a rotary vane motor with valves to American motors. 1967 P.R. Mallory made a rotary vane engine. patented by Wallace Linn and Gianni Dotto. Other weird engine designs you haven't covered yet are mentioned there.

Congratulations! You just reinvented the wheel, er, water pump. Bazillion guys have tried to develop this since Ramelli invented it in the mid 16th century. That would include some major players including guys from GM, Deere, MTU, RPI, and "other" entities. I was on one of those teams. In short, it doesn't work, for numerous reasons mostly centered on the sealing mechanism, or lack thereof. Brick walls - vane deflection, supersonic tip speed, cooling, lubrication. Usable power requires either high compression or displacement, both of which vane devices do exceptionally badly. However, if you build a "vane engine" the size of a Ferris wheel and turn it at Ferris wheel speeds, it'll work but will still produce a fraction of the power and efficiency of an equivalent sized two stroke or turbine, both of which are multifuel. BTB - there are many SAE papers on this topic going back 40+ years for anyone who has a few thousand hours to kill. Oh, and, Felix Wankel likely didn't invent the engine which bears his name, he likely "borrowed" the concept from one of his assistants.

Despite your voiced disgust for "range extender" engines, that seems like the perfect use case for a rotary vane engine. Working essentially as a generator, it can be designed to run at a constant RPM. This eliminates the issue of the centrifugal force on the vanes, because that can be taken into consideration when designing the springs. It may have a bit of leakage while it's getting up to speed, but that would be a minimal time if the load isn't coupled immediately.

I actually like it when you explain secondary engine balance all the time, actually.

Pros: it's efficient Cons: it's inefficient 🤣

Saying it's "pure" rotation while showing the vanes not rotating and instead moving in and out. Based.

Can you make a video about Pneumatic Valve Spring? I think it is a fascinating technology

Pretty much a Sarich orbital engine. Made good boat anchors

What explaining secondary balance a million times does to a man:

It's a vane-type supercharger. They have been around for 90 years.

Amazing job explaining this. Very interesting. I enjoy learning anything new about engine concepts

6:40 This thing looks ridiculous. You want an apex seal that extends via a spring? I’m sorry, we already have valve float issues on piston engines. We gonna have to worry about seal float now?

2:07 I love more pah

18:05 I'm no engineer, hell I've got 2 brain cells left fighting for 3rrd place. But i see a couple challenges: First is exhaust, I can see potential power losses from the combustion phase pushing out the exhaust. Second would be ensuring the compressed air doesn't overpower fuel flow into the chamber and timing the spark for combustion. Like I said, I'm no engineer but at higher revolutions wouldn't we see a decline in efficiency at higher RPM if we're also pushing the exhaust out? Furthermore, I suspect there's some serious material science behind getting the seals right on the vanes, that's a lot of potential friction, little room for error, and if you're talking such tolerances for gapped seals how does it compensate for material elasticity?

3:26 you know what else does that? Electric motors!

The more I think about it, the more convinced I am that this is the kind of engine that Wankle envisioned when he first had the idea of making a rotary engine, but the main problem lies in the vane, this is why rotary engines have a shape like a dorito with a strange engine room shape, Wankle wants to eliminate the vane but still ensure that the rotor is always attached to the engine wall so that it is easy to seal. (And we all know wankle still failed to do a perfect seal) Additions: If what you say about seals is applicable to this engine then shouldn't it also be applicable to the Wankle?

My farther and I discussed the vane rotary engine in the 1960's and we also discussed the friction and wear problems thus putting the idea aside until technology could catch up, maybe it has and now is the time. It would be nice for an old timer engineer to see this before I go.

"Zero reciprocation" - d4a *Reciprocating vanes in background"

As a physicist a small note. To say there are zero vibrations when substances are set on fire is impossible. But yes, the design idea would have probably quite reduced vibrations, depending on how the problems are tackled listed by the engineers. All in all an interesting video, thanks.

@15:30 The problem of friction at higher speeds due to centrifugal forces acting on the blades could be overcome by electromagnets at the bottom of the blades that would compensate these forces proportional to the rotational speed. The blades could be made out of ceramic, their base out of magnetic materials.

I have nearly 40 years experience in hydraulics. Vane pumps have been tried in industrial hydraulics but cannot compete durably at the pressures that piston pumps operate at. And there you have fantastic lubrication at all times. I cannot see vanes lasting under the conditions during combustion typically found in an internal combustion engine. Nice theory but converting ir to practice is something else.

I'm only a minute and 44 seconds into this video and I have already seen 3 examples of D4A's legendary ability to explain complex engine concepts and features for any layman to understand. Bravo. I've subed to this channel nearly 5 years ago and the consistency and increasing quality of your videos always astounds me. I truly hope this channel never dies.

About 2 decades ago as a mechanical design draftsman with equivalent of 2nd year mech eng and also obsessed with the idea of a better ICE with lower weight, smoother operation and torque, I came up with several iterations (unfortunately only in digital form, no contacts, money or time to do what I wanted to do which was get a prototype built). The 😮mdifference between mine and the design shown in this video is that the

As a hydraulic pump/motor this works well. The drive/driven fluid provides lubrication. As a gas pump/motor this still requires lubrication to be added to the gas. Much like the wankel rotary engine, I don't see this meeting pollution standards.

I love how a vane engine looks like such a great engine.

12:53 *near vibration free, those vane springs will vibrate at a certain rpm

6:58 So, this is like an ICE version of an electric motor then...

Range extenders may not be sexy, but, since the 1940s, Diesel-electric locomotives have used internal combustion engines that generate electricity to power electric drivetrains.

We use these type of motors as waste pumps on our fleet of septic trucks.they work great until the vanes jam up and we have to tear apart the pump and replace them. Ours are also centrifugal and the central hub is offset in the housing so that at the top the vanes are pushed in and drop down at the bottom.

Apparently, in the mitochondria in our cells, the last step to ATP generation, ATP Synthase, works like a microscopic rotary engine, turning ADP and a free phosphate into ATP, powered by the electron transport chain.

Great desine , hope to see more about it , i have used the hivac pumps in the cleaning industry , it can suck and blow gasses , even watercooled and lubricated systems

Piezoelectric actuators don't move centimeters. They don't move even millimiters. The move like 200 micrometers... Which means 0.0002mm You just CAN'T control those veins with those. R&R uses them, true, but the turbin blades are not supposed to move like the veins at all, they use them to just compensate the microscopic play or the termal elongation... This has the very same problems of the Wankel: it's a dry run and it destroyes apex seals...

From a thermodynamic perspective, theres a TON of surface area there that would conduct heat away from combustion and leave a ton of unburnt fuel along the rotor and rotor walls. This is why DI in piston engines makes so much more efficiency. You keep the fuel in a column in the center of the cylinder where things are the hottest, and keep fuel away from the cylinder walls. You cant help as much the head and piston but it is what it is. Now that all the fuel is in the center of the cylinder, you can keep its temp much higher than the flash point so more of the fuel in the cylinder burns. Rotaries have too much surface area and the fuel stops burning because the heat gets conducted away too quickly. This is why they are dirty and fuel inefficient. What you need is a dedicated burn chamber where you can accurately control the fuel and air flow, and hopefully keep everything above the flashpoint of the fuel. This means more complication of a pds supercharger to bring air into the engine. I've already worked out a lot of the missing details but have taken no action to making a test unit because i just dont have the tooling or drive atm. I have a pretty sneaky automated start up sequence for said engine as well. Wish i could share it without someone trying to steal it. Lol

this engine does have a flaw, which is durability. the metal attached the the springs would be under HEAVY stress at all times and will become dialoged/break if left unchecked. What I think would be a better replacement would be using two circles and putting two rods in. The engine would be at the bottom whist whilst the the combustion happens at the top of the compartment. why not add compressed air and fuel directly? have the engine power a compressor which in turn force feeds itself. you may ask "but how would you get it to start?" its simple, its a circle, slap a "electric engine" on the main rod (just to start the rotation). heck, you could even make it a hybrid all within one engine compartment.

Thanks for your video. I love your enthusiasm and clear explanation of traditional internal combustion designs and major issues. The comments say it all. I taught engineering for many years and came to the conclusion a long time ago that the electric motor just had so many advantages, the world would be better spending it's time, money and energy on cracking battery tech. .... And in the mean time maybe the 'range extender' is not a bad compromise.

I'm ready to be bamboozled again.

Cavitation destroys hydraulic impact hammers. You think a vane is gonna hold up to millions of combustion events? 😂

Sometimes a connecting rod can see a combustion occurring once..

my grandfather made this design back in the 60's. He used a glo plug to try and start the combustion and had a tube on the outside for increased combustion {i think} neat how families can have so many near misses

First thought @4:04: Those "vanes" would make a seal difficult! They'd either have to wear at the tip or have oil feed to the tip (and sides for a good seal). Think starter motor brushes. Secondly, you couldn't completely stop the vanes from wobbling on the combustion as there would be a huge pressure bias. I think this could limit power. You could have a roller on the tip of the vane, but you'd still need to seal the inner side of the roller and the sides, too, and you're just adding complexity and lowering the life-span. I don't see this doing well because of these vanes.

About 1972 when I was 12, I drew up a plan for a vane motor like this one. After contemplating it for a while, I concluded that the vanes would be very difficult to seal properly, would have excessive wear on the power stroke and would probably float at higher RPMs due to inadequate springs. I still see the same problems.

you could connect the vanes to an external raceway with bearings, converting sliding friction to rolling OR rotate the elliptic housing around a fixed rotor thus removing centrifugal force from the vanes

The Venn Diagram while begging for a break is hilarious

At 5:24, you said zero reciprocating parts--don't the seals reciprocate? Remind me, what were the problems with side-loading seals again? I don't understand how you can look at a Wankel, understand that thin-walled structures loaded in shear are a problem, and then add reciprocation on top of it and call it better. Face it, until you get to turbines, crankshaft-driven engines are what peak combustion technology looks like.