Why It’s Almost Impossible to Rev to 21,000 RPM
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- เผยแพร่เมื่อ 22 ส.ค. 2024
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With an engine revving at 20,000 RPM this piston has a mass of 2.5 tonnes. It accelerates from 0-60 miles per hour in 0.003 of a second. And it pulls 10,000 G.
And this is what 20,000 RPM sounds like - it’s Mark Webber driving a 2006 Williams with a Cosworth CA2006 and it’s the highest revving F1 engine ever.
It’s been almost 20 years since this engine was released, so why haven’t F1 engines - or any engines for that matter - gone above this magical 20,000 rpm?
Well, it’s more difficult than you might think, so today I’m going to explain why it’s almost impossible to engines to rev over 21,000 RPM.
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#F1Engine #Piston #Revs
NONE of the thermal or stress issues are a deal breaker. Having worked in F1, analysing stresses in pistons and conrods and crankshafts and valves, I'm quite sure everything could easily run much faster - 30,000rpm would be no problem, particularly if exotic materials are allowed (like aluminium - beryllium). Turbochargers in humble road cars can hit 100k rpm while red hot...
The killer factor is time. Higher RPM means less time per cycle, but the physics of fuel combustion are "fixed", in that flame fronts take finite time to propagate. The flame-shooting injection is a great idea - an advance on Alfa Romeo's "Twinspark" idea that used two spark plugs to start two flame fronts in the combustion chamber.
The second problem is keeping everything synchronised. While the components can be designed to survive the loads and stresses, keeping the valve timing synchronised with the piston motion is harder than it might seem. (Quite apart from the problem of "when to start combustion" to get an optimal power output from the cylinder (fire too early, combustion works against you. Fire too late, most of the power goes out the exhaust. Ignition advance is a huge field all to itself. But I digress.)
Because, nothing is rigid, and everything is flexible. And twistable.
V12s and V16s have much longer crankshafts and camshafts, and will twist along their length, resulting in some very serious timing errors in the cylinders remote from where the shafts are linked together. Various efforts to deal with this include using link gears at both ends of the engine, or putting them in the middle. Which brings their own problems with "forced" positional control, that can induce their own breaking loads. This can all be engineered around, not least via novel valve technologies.
But to even be aware that everything is flexible, and avoid the typical "rigid body" thinking that seemed to afflict everyone else working in the field, is a challenge in itself.
For those that doubt if I know what I'm talking about, take a closer look at the bending crankshaft animation at 8:03. That is NOT showing "stress" (so, we don't even have to debate whether it is Maximum Principle Stress, or Von Mises stress, or some value of fatigue alternating stress - ALL of which MIGHT be the one dominating "failure".)
It is showing a colour contour map of DISPLACEMENT. Because, the entire "red" part of the crank does NOT have similar stress - that would be concentrated at the fillet between crank web and big end... certainly not distributed equally over the whole section.
Worse than that, the deformation is created by moving the centre main bearing while holding the mains at each end - a totally false load case that simply never happens in reality. At least, not to the extent it is shown here. Some movement is possible because these bearings are oil film (journal) bearings, and the oil film thickness allows a small amount of movement. But this animation is not intended to show that, since displacement at the centre WOULD cause movement in the end bearings too - the crankshaft stiffness forces that.
One of the reasons I gave up doing what I did, was the disparaging remarks about being "the pretty pictures department" by folk that did not bother to look at my track record of "ZERO in-service failure" of any part I ever worked on. Sigh.
But sadly, even 20 years later in 2024, it seems not only has nothing changed, but the "pretty picture" is not even a valid picture at all, but something created purely to look pretty. Sigh.
TMI but for those still interested, "zero in-service failure" means inifinite life while in use in the engine. NOT "unbreakable parts" (you just have to subject them to loads they never see in service, to get them to break).
This included redesigning finger followers that broke in 10 minutes, and conrods that snapped in an hour. All of these became "infinite life" parts that could last forever, just by fettling design details. And, making them lighter for better performance at the same time. For me, durability usually meant removing redundant material, and sometimes redistributing material, to better disperse loads (and hence stresses) throughout the structure.
I never had to fix anything by adding any material to it. Which is contrary to intuition, and is the "go-to" response of about 99% of others doing this kind of work. "Beef up the weak bit" is NOT a good thing to hear.
Just like the crankshaft that drew envy because it NEVER broke, not only lasting an entire race season, but also having the smallest main bearings of any crankshaft on the racetrack. (and smaller mains meant less parasitic torque was drained from the power output, giving more BHP at the flywheel...)
But smaller bearings mean a huge increase in stress concentration, making it much more difficult to endure the loads any crankshaft has to survive.
Anybody else that even tried to match our bearing size, never finished one race.
When you get a handle on engineering, and materials, and stresses and strains, and loads, and resonance, and vibration, and heat transfer and temperatures, and... then designing engine parts for conditions thought impossible, becomes quite possible.
There certainly are limits. Yield strengths of materials, for one. And when you factor in that the strength depends on temperature, too... But rather than get sidetracked further on "strain rate sensivity" and why F1 pistons survive stresses more than four times higher than their yield strength at operational temperature, just know that we are still quite far from reaching those boundaries with designs at 20k rpm.
I mean, 99% of the piston is not even close to failure. It is the 1% detail problem where stresses concentrate that start the cracks that lead to failure.
Same with that crankshaft. The challenge is fettling the details WHERE THEY MATTER.
Sorry for the essay. Thanks for reading.
Thanks for the writing. Fellow mechanical engineer here... one that knows why adding material to the most stressed point of a part doesn't work ;)
Thanks for the essay. I appreciate the insight.
Thank you for your insight. It appears we not only have to deal with stress on engines - but also the stress on engineers!
Thank you for your essay. I'm not an engineer but I really enjoyed reading it.
at the end its the same as with the diesel engines cant do more as 8000 rpm due to mixture burn time. maybe going with detonation burning? :D
The fact that this video is still live after all the inaccuracies and wrong information speaks louder than the mistakes themselves.
I didn't even reach 15 seconds. Usually, I am sloppy myself, and it might be a minor thing, but I wonder how the piston can change its mass to 2.5 tonnes. Of course, I would also say that my weight changes at the moon, but that sentence sounds too wrong to count as colloquial. Maybe my 8th-grade Physics teacher trained me enough. But even before, I would have said that my weight changes, not my mass.
I didint realize it was misinformation untill I was halfway into the video. I feel so dumb bruh
@@Brushyip I can understand. It's TH-cam, and you are here to relax and not to concentrate on details.
Maybe, I wouldn't roast him too much, too, although I stopped watching the video, and decided he might be not the right channel for me. Many TH-camrs are sometimes sloppy, and to a degree the algorithm forces them to have high throughput. In the end, its not a physics channel and short headlines always sound good.
Watching it, is like reading an article of the rainbow press and noticing halfway through the article, it's not a reliable source ^^. I guess, usually the channel is not that bad, though.
@@merkatorix Don't be too hard on Scott Mansell he's not an engineer, he's a former racing driver.
@@jamiecloughgaming25387 I agree, and he probably does a good job.
I just think, I'm not his target audience. I like the history summaries of Aidan Millward, I think, but mostly, I'm the target audience of engineers. I also agree, that it might have been better to not write that, because it probably sounds too negative.
If you want a job in F1 and racing, I don't know, if there is a better channel.
The main reasons are actually the speed of the flamewall starts to be too slow, the combination of high compression and ultrashort stroke reaches mechanical limits, and the extremely narrow gap between head and piston at TDC prevents a clean burn. The mechanical load is a problem that is solvable.
Yep deflagration is too slow of a combustion method at this point. Detonation could help if an internal combustion engine could make it work like a pulse detonation or rotating detonation engine in aerospace.
Yes, absolutely correct. There is a thermodynamic limit to how fast the fuel mixture can burn and expand.
Honda did 22500 in the 60s with the rc116. Try again
@@brynfisher8019 Read what I wrote again. And then you can answer for yourself why the RC116 might have just worked. While the 300cc cylinder of an F1 V8 or V10 would not.
@@brynfisher8019 Formula 1 engines are much larger than 50 cc. Try again.
The video never actually answered the question. It pointed out the difficulties of running at 20,000 rpm, but did not actually tell us why it could not go higher.
That's because it isn't a real limit.
- You could make the pistons smaller to reduce their mass.
- Materials science is constantly developing.
- So are design analysis techniques.
Velocity and size of charge of the air fuel mixture can also limit how high the rpm can go. I had always heard they couldn’t go beyond 20k rpm because they couldn’t get the air fuel mixture in the chamber any faster. I had heard at 20k rpm they couldn’t over come the pressure wave the intake generated to go beyond that limit.
@@rednezzHonda did 22500 in the 60s with the rc116
@@brynfisher8019 Yes, for sure. I was just stating the 20k limit for the formula one engines was not due to G forces but more due to intake limitations. I am sure without any rules that put boundaries on the engine, intake and exhaust design those F1 V10’s would surpass 20k rpm.
The answer is still regulations.
You still have things like budget, fuel flow limit, reliability, etc.
I remember being under the grandstand during USGP practice when Williams was very nearly 21,000 rpm. What a thrilling sound. Menacing, spine chilling, and the Mercedes McLaren engine still sounded more violent than the rest. Miss those V10s
Mass doesn't change with velocity, the piston doesn't magically become 2.5 tons. If you're talking engineering you absolutely have to be precise with your terms, man
Technically, mass does change with speed, but not by much
It's still sorta accurate, tons is a weight which is a force not a mass.
Are you asking too much, they use Imperial to talk about a sport that is metric standard.
Short ton, long tonne or metric ton?
He's not explaining things for engineers to understand. He's explaining things for the layman to understand. No need to be pedantic.
Is this a challenge on how to get as many details wrong as possible in 13 minutes?
Ooh, -burn-...
Do you think he can win you ?
The only problem is that they DID 20K rpm...
It CAN be done. Honda had a roadrace bike that would rev to 22K rom in the '60s.
yes, as stated in the video but never 21000 RPM
@@Noise-Bomb but if it went to 22k rpm, I am sure it must have been doing 21 on the way up...
thing is the bike pistons are smaller and lighter, so higher rpm is possible.
@@AndrewTSq a bike engine went to 22K, NOT an F1 engine as was specified
@@AndrewTSq nope, according to this video there's a discontinuity in the graph at 21000 and no where else
An interesting side note: it's not uncommon for the massive diesel engines on cargo ships to be 2-cycle, but that's at least in part because they run slow enough to be able to effectively replace the exhaust with fresh air via blowers (which they have the room for) and that also allows them to not run oil mixed with the fuel (which might not be as big a deal given the fuel they run isn't that much different in weight than motor oil).
Also means you can run them in reverse easily so can dispense with a gearbox.
I digress....
In weight? What does that mean?
@@filipruml think they're referring to the viscosity of the oil.
They used to run "better"/lighter grade for manouvering for better stop/start/response and then something almost akin to tar for once at sea and full speed.
They're also very efficient
@filipruml e.g. "30 weight" oil is a common motor oil. It mostly refers to viscosity.
Short answer: mechanical stress
but we had 2 strokes rev higher?
Thank you
short simple answer: to much "brrrrrrrrt" engine goes "boooom"
@@AndrewTSq a common misconception. 2 strokes sound faster but typically rev less. Honda's RC116 50cc 4-stroke (from 1966!) can rev to 21.5kRPM.
@@AndrewTSq 2 strokes traveled half the distance before combustion
Frame front velocity of the fuel is what determines rpm limit. Different fuels have different flame front velocities, and thus different rpm limits for the same engine.
You made it out to seem that there was a reason that specifically 20,000 rpm is the limit.
Right? Like a sound barrier.
All of things in the video create that barrier.
Taken to the limits across the board , its the rev speed where you cant get any higher.
Driving something at speed with a reciprocating mass tops out around there.
You can goi a little faster with a rotary engine but heat soak becomes a big issue and your limited ti around 20000 for anything resembling reliability.
@@deadprivacy no they dont
No mention of the Honda air cooled, conventional valve springs, sixes of their racing bikes in the 60's, that routinely reved to 23k rpm? Relevant as they won at least 2 world championships and remained reliable. Also no mention of the, again Honda, CVICC system of the 70's? Strange because it is exactly the system you describe as new in 2015...
it was actually the CVCC system :), but I was thinking the same !
That only works because of the smaller size/capacity. There are lots of engines that can rev way more than 20k ... they are in model aeroplanes. This is because they are very small. By the time you get up to the sizes needed for an F1 engine you are reaching the limits.
@@MrAdopado This destroys the argument about thermodynamic limits of combustion they were having above doesn't it?
@@jasonsmith4902 There is a limit of combustion ... the speed of the flame front is fixed so though it has time to zip across a small combustion chamber it doesn't have time to completely fill a large combustion chamber so only a partial burn is achieved and efficiency is lost. That's why it's possible in small engines but not in engines of the size needed for Formula One.
Yes, Japanese bike engines have always been far ahead of car engines. Car manufacturers have always gone for image, no matter what the image.
15 seconds in and you're killing me. Mass isn't changing, force is changing. There's no extra "stuff" just because it's accelerating so quickly.
The faster Usain Bolt runs, the more obese he becomes
He was referring to inertial load on the connecting rod, effective weight of the piston when changing directions. He is most surely reading a script which was poorly written to exclude this detail.
What he was referring to was the amount of force being exerted on the crankshaft and the connecting rods due to acceleration of the piston,The higher your acceleration, all of that momentum needs to return and go the opposite direction so what you run into is more RPM means more additional stored energy via momentum, compare it to locking up the brakes on a car at 60 miles an hour versus 120 miles an hour, or falling down on the ground vs a 10 story building
@@ericpedigo685 yeah but it's not "mass"
F1 engines were touching 22,000rpm in c.2006. Saw it on TV. The tach touched 22K from time to time,
Same idk why the media acts like it never happened.
@JTTTTT850 thanks. I was wondering this.
Was that under acceleration or because of downshifts? I don't remember seeing 22k engines at the time.
@@chuckschillingvideos They were Reving and Shifting. Vrooom. Find some F1 races from the time, the sound alone is therapeutic....
@@TheHypnotstCollector Oh, I know all too well what F1 once sounded like and what they abandoned. I was just never a tach watcher back in the day. Don't know what you've got till its gone, right?
My little Honda CBR250RR will rev to 21,000, it's stopped making power at 19,000 but I've seen it as high as 23,000 on the track. And that's 1990 technology and it's still going strong.
0:10 Mass of... Beg pardon? You need to look up the definition of mass. I'll give you a hint, acceleration doesn't change it.
You are right of course ... but in a speedy presentation intended for mere mortals you often get these detail errors. If he had used some wording similar to "a force equivalent to pulling and pushing x tons" perhaps we could live with it ... we are not all familiar with talking Newtons!
@@MrAdopado Because it matters. By not using correct terms, you propagate incorrect ones.
To quote von Braun "I have become very careful about using the word 'Impossible'."
@@spacecadet35 there is always at least one who can do it.
A couple of things that I noticed in the video.
Engine friction wasn't mentioned but is a key reason for not increasing engine speed further.
The NA F1 engines used port-fuel injection, direct injection came along in 2014.
Current F1 engines do not use TJI as described in the video, they use a passive pre-chamber as only one injector per cylinder is allowed.
The stoichiometric air-fuel ratio of gasoline isn't 14.7:1, it depends the formulation of the particular fuel.
"The stoichiometric air-fuel ratio of gasoline isn't 14.7:1"
- Generally speaking is it.
@@dirtygarageguy generally speaking it's not, which is why most people would use lambda or equivalence ratio to describe the chemistry of the air-fuel mixture, as it's formulation agnostic.
When you explained the actions of the four stroke I was taken back many years, to when I started work at a Ford engine plant (I was 17. God that was so long ago!). My dad explained it using the "suck, squeeze, bang, blow" saying. It really helped me visualise it. And as you went from one part to the next, I was hearing those words in my mind just before you used the more technical ones 😂
Fascinating stuff!
The more power strokes you can squeeze into a minute,( rpm ) the more power you make -But - the volumetric efficiency gets worse as you try to speed things up ( that whole getting the air and fuel into the cylinder and mixed , thing ) . There’s a point at which at which the gains by higher rpm get overtaken by the loss in volumetric efficiency . Had a tutor who said “ at 20,000 rpm pistons don’t go up and down - they just vibrate “ 😂
Renault and BMW both managed 21k in the V10 era of F1 before the FIA issued an order limiting engine RPMs to 19k.
6:25 Massive blunder here, con-rod length does not influence stroke and therefore the bore/stroke ratio and engine „squareness“, only the crank can influence stroke. Rod length to stroke ratio is a whole other matter.
How about a episode on F-1 pre-chamber ignition?
Possibly, Micah McMahan as a resource?
I did some ball park math years ago. A high reving engine, the piston can travel up to 80 MPH. Fairly impressive, but it changes
direction (up-down) about 500 times PER SECOND.
Internal combustion piston engines are just insane, I mean 20,000 rpm means each piston is changing direction 666.6 times *EVERY SECOND* (at BDC and TDC, i.e. twice per rotation). Pretty mind-boggling.
That's pretty satanic, I'm not going above 19.990 then 😂
@@henriklmao Yeah, I really should've rounded up 🤣
@@henriklmao nothing beats the devil🤣🤣 not even f1 engines.
I rarely post comments like this but... At 8:18 - Aluminum has a better strength to weight ratio than steel, but is more vulnerable to fatigue, not less. Strength and weight are completely unrelated to fatigue in general. You actually picked the two most extreme examples to be wrong about - in that some steels will literally never fail due to fatigue as long as they aren't overloaded, but with aluminum any repeated load will eventually cause a fatigue failure no matter how small. Some ferrous titanium alloys can behave more like steel - but it's because they're ferrous, not because they're titanium.
20k is amazing, heck 9000 peak on an average car or truck defies belief. Into the realm of 10, 12, 15, and 18,000 RPM's is astonishing.
3:55 ah yes, rice.
Yeah, doesn't really work when rotary ICE engines also abbreviate to rice...
I find it kind of funny that they just created prechamber ignition for F1 even though this is ancient diesel technology where early Cat diesel engines used precups or Pre-combustion chambers that would start the burn before entering the cylinder .
I remember back when I was kart racing. I started off with 100cc karts but I never raced them. While racing with TKM and Rotax engines, I always had older 100cc engines laying about. I remember my Vortex VR / CW rotary valved engine. That engine would SCREAM. Highest I ever had it was 23,000rpm. Although I never raced it. Occasionally I'd stick on a larger rear sprocket on the colder dry days and let it sing. You really seen the temp go up. If I managed 5 laps in a row achieving 22k rpm, water temp would easily go over 70c and you'd struggle getting 20k. It was all about managing the carb and temp. Leaner engine, more power, more temp. On the really hot days I kept it rich but it was still achieving 18k to 20k. Really loved those days... I miss the smell and noise.
*Rotary engines made by Mercedes Benz in the 1980's have recorded speeds of 60,000 RPM and could theoretically power a car up to 600 miles per hour.*
🤔
Because they don't want or need to.
Everything about F1 is rules and limitations, if they had to rev to 21000, they'd figure it out. ( and we'd probably see some new rotary designs because pistons are horrifically inefficient when scaled with speed, because the reciprocating load scales with revs )
Problem is that rotaries, due to low compression ratios, massive conbustion chambers, are terribly inefficient, which is the opposite direction the FIA wants for F1
Exactly. Physics wouldn’t apply if the rules required them not to. We would have faster than light travel now too if the FIA made it a rule.
@@c-ro311That's precisely the problem. The clowns dictating the technical parameters are, in the depths of their evil black hearts, accountants and politicians.
Real galaxy brain take here
@@chuckschillingvideos nah they aren't clowns: almost any numbskull can make a 1000 hp engine, making them efficient at the same time is what advances technology
I’m fairly certain that Honda had an engine revving to 22000 rpm in the early 60s. They didn’t believe the riders claim of 22k rpm but then took it home and ran it for an hour at 22k
Standard Kawasaki ZXR250, 19,000rpm redline, but happy to rev higher. The speed of flame front is so slow an engine would not work above a reasonably low rpm. However, there's something called "squish velocity". In performance 2-strokes it's critical to get it just right. I suspect it's the same in 4-strokes. The velocity of the gas in the chamber is what reduces the burn time to allow high rpm and efficiency. It makes enough difference that ignition timing can be backed off at least 5°. I'd imagine modern materials and manufacturing techniques would allow for higher rpm if allowed.
........except Ferrari had F1 engines running at 24.000 rpm ....and could have raced them. Paolo Martinelli was in charge at that time from 2002 - 2012 and was only limited by supply of pistons. Mahle delivered the best material....but quantities were limited. So at races with high full throttle mapping the full power was executed. At the rest of the races standard engines up to 21.000 revs were employed. The glorious years of "rev festivals" are over for the moment. But are coming back as " electric turbines" , brushless inrunner with easily 30.000 revs maybe soon...but of course mainly silent as efficiency is king!
At 06:29
The length of the conrod has nothing to do with the stroke.
The stroke is determined by the offset of the taps on the crankshaft only.
peak cylinder pressure in a race engine 1500psi. probably even more win a race engine, so with 80mm bore that's over 15000kgf pushing on the piston
No mention of volumetric efficiency and the laws of diminishing returns, nor a whole host of other factors such as resonance and column inertia tuning.
RC model engine regularly run around 30.000 rpm, and some even higher, i've seen up to 45k being suggested. Granted they run on nitromethane, which burns fast, but the mechanical aspect is still here.
Just a little info to temper the "absolut limit" idea that seems to be played here
Quit common on nitromethane piston engines for model cars I have one that revs to 33,000 RPM
Impossible? Nearly impossible? All of the RX8 guys are laughing right now.
Very effective explanation about engines in general especially 2 vs 4 stroke
Except he was explaining a petrol (gas) 2-stroke, and showed a schematic of a diesel 2-stroke 🤦🏻😂
Just commenting to support the channel and video. Keep up the great work Scott. I really hope you keep getting good viewer numbers. I’m concerned you took a major hit from the algorithm after the overdrive debacle.
A great vid! And it's not only about the final answer, but about all we learn in between.
We want 20,000 RPM engines back in F1. They sound powerful and made for some great racing. Who cares if the hybrid cars are slightly quicker, it's a show and we want the music to go with it. These modern cars sound like shit.
Larger bore is more important, as it allows for larger valves, larger ports, larger intakes, and larger exhaust.
Stroke is important, as it determines piston travel per minute.
Thanks for making this video. Many times people blaming MGU for less screaming on current PU, whereas it's actually it's rev/minutes, as current PU rarely reach 13000 rpm.
At 10:13
A complete 4-stroke cycle takes 2*60/20000 = 0.006 s
You forgot that a full 4-stroke cycle takes 2 revolutions of the crankshaft. Still a very short time...
Honda 50 cc twin cilnder racing engine and the 125cc 5 cilinder were able to run at 35000 rpm in tests in races at around 30.000 max this in 1967
My first bike was a 1987 Yamaha FZR250R. It had a 19k recline and while not particularly fast, it was absolutely glorious. F1 sounds at reasonable speeds. I miss the simplicity of youth.
Nothing says you can't ride a 'screamer' motorbike when you're old too, just try not to croak on it!
ICE are fundamentally air pumps that you squirt fuel into. For a given displacement higher rpm means more air flow and more capacity to burn fuel. They are limited by mechanical loads and flame speed. At very high rpm both of those factors come into play even for very oversquare engines. Two strokes move something approaching twice as much “effective air” for a given rpm. Turbo and superchargers pressurize the input air and effectively increase displacement for a given rpm.
Yes, flame speed exactly. He didn’t talk too much about that. The thermodynamic limit of the expanding gas.
It's mind boggling to me that they can even work at such high revs. Engineers who design and make these are insanely talented.
My remote control car with a nitro engine does 37,000 rpm. When I run it with the exhaust pipe off its like 10 times louder than a full sized car.
I've seen this video on every car and engineering channel on TH-cam already but welcome to the party.
Saw the thumbnail and got confused thinking I was at work 😂
I have a theory: If you use a powerful enough electric fuel pump, you can move the pistons just by squirting fuel really hard at them. 🙂
Well, mechanical constraints do not limit you to 20k RPM, if going above that RPM is your only goal. What limits your RPM is time. It takes time to exchange gasses, build a flammable mixture, ignite the mixture, and then you want time for the mixture to push the cylinder down. A longer power stroke will extract more energy inside the engine and send less energy down the exhaust. So it's a design balance between energy sent to the turbo/MGU-H and energy kept inside the engine.
Air exchange can happen close to the speed of sound, which is close to 350m/s at ambient and close to 700m/s at exhaust temperature. Reaction time is a view µsec. The speed of the flame of 0.5-3.5 m/sec is the limiting factor.
So you don't want to rev higher because it would reduce the amount of energy you get at your crankshaft at a certain point, and you want to rev even lower to avoid heat and save on mass you would otherwise need for cooling.
PreChamberIgnition (PCI) was also designed to save a lot of weight. With it, you only need a flammable mixture inside the prechamber. That flame can travel through mixtures that would be too rich or too lean to ignite. In an engine, the mixture is way too lean. So you get much more air to a slightly lower temperature and pressure. An engine that runs rich to stay cool at high rpm would burn 2-4x as much fuel. Which does not work with the current fuel limit and would still be irrelevant if you could use as much fuel as you would like.
It would only be interesting if the cars would be significantly (200kg
This is nonsense - 30 seconds on a calculatr will tell you that, in an ordinary car engine producing peak power at 6000RPM you have 5 ms for the entire power stroke if you maximum flame speed is 3.5 m/s then the flame will have progressed a whole 17.5mm in that period. What you are quoting is the flame speed through a quiescent, homogeneous mixture. What we have in an engine (even those with a "quiescent" chamber design) is a gas and fuel mixture which is anything but quiescent - we have very rapid gas movement which rips and tears at the flame front, streching it, pulling pockets of flame into the unburnt mixture and shoving misure through the flame - it's chaos! This effect speeds up combustion by orders of magnitude - and, the faster the engine runs the more energy is imparted to the gas so the energy that goes into "stirring that pot" increases with engine speed now at more conventional engine speeds and engine geometries (bore:stroke ratio) it is a happy accident that the effect of more energetic stirring almost perfectly matches the the reduced time available for combustion - so the combustion period, measured in crank degrees - which is what counts for these purposes, remains remarkably constant as engine speed changes. now I can imagine that, as over-squareness gets to extreme levels, like in a 20,000 RPM F1 engine, 2 things start to happen: the inlet gas velocity is atypically low because the mass of gas induced in comparison to the bore size is relatively low- big valves low mean inlet gas velocity - so the "stirring energy" will be lower and the flame speed could start to drop - hence the success of a pre-chamber.
Similarly (and the video is talking rubbish here too) Stoichiometric is NOT where you want an F1 engine running - max power is at about 12.5:1 so there or a little richer is where you want to be - richer does give a petrol cooling effect but you can't go anywhere near "2-4x" as much without passing the flammability limit - which means the mixture would not fire. You also loose power as well as fuel consumption if you go richer. It is true that a pre-chamber can exploit the possibility of different A:F ratios in the chamber and in the main body and that is exactly what the Honda CVCC system did - nice and rich in the pre-chamber and lean, lean lean in the cylinder - to give overall a leaner mixture that you could reliably ignite with a sark and drop the NOx levels - that is not what is happening in an F1 engine.
The speed of sound - ah, yes, it matters but not in the way implied and, honestly, life is too short.
45 years an engine design, development engineer - cars, bikes, F1, loco/marine, consumer industrial, you name it. I sympathise very much with @bythelee whose comments I thought excellent (Do I know you I wonder???? - it's a small world) and whose comments on current practice with respect to piston rings and their materials I would be fascinated to see - gas force vs TDC inertia force is a tricky area for very high speed applications.
@MrHaggy, apologies if I have flamed you - there are many posts here that could have sparked (pun intended) my ire but you just happened to be " the one" - and it's a crappy video too - trying to make things clear for the layman does not excuse sloppy practices or spouting nonsense
You stated with 2 strokers combine intake and exhaust in a single stroke and compression and power in a single stroke. It’s actually exhaust/compression then power/intake.
Watching this is like going back to college
I miss it
its the mass and strength of the reciprocating parts that define the acceleration and deceleration of the piston and connecting rod that limits the max rpm, just like a helicopter rotor and blade cannot exceed a certain speed because the rotary wing aircraft is already moving in air at a certain speed while the machine is also adding to that speed while the other hemisphere of the rotor is doing just the opposite so there is a point of imbalance so that a helicopter cannot go over 2-3 hundred knots. However, if the reciprocating mass is smaller, rpms can exceed 20k, it just depends on the balancing of the crankshaft and pistons so there are no harmonic imbalances.
I remember when 11,200 rpm was the theoretical maximum limit of a 4 stroke reciprocal engines, that was in the early in 1970 s.
It would be interesting if that TGI ignition could be applied to old cars. What effect it would has on performance and efficiency.
Ive never learnt so much about engines before. Your Videos are awesome.
Thank you for fixing the voiceover sound. Both room treatment and the microphone
so much cool things i learn from your videos :D
Scobby rev'd his dad's Astra Belmont above that one night, when dad took it to church on Sunday the engine fell out.
Is it possible to watch an entire F1 race without falling asleep?
I used to have a nitro RC car with a tiny aluminum single cylinder engine that did 29,000 RPM. That thing was awesome!!! HPI has a 3.0cc 2 stroke engine that will max out at 32,000 RPM!!!
Time for f1 to move to Rotary engines.
That would be wild and stupid
@@nidhisingla7880 as with most interesting things in life.
@@jowarriorAs much as I want to agree with you, adding rotary engines would be the worst f1 regulation of all time.
@@henryhallam5270 I’m not saying to force Rotary engines, just allowing them to the engine options.
@@jowarrior But it would be pointless then because nobody would use them 🤷♂️
There is an upper limit, but I think it's controlled by gas dynamics, not by kinetics of the metal rotating parts. I'm pretty sure that they could make a machine that will rev faster than pressure disturbances can travel through a gas medium.
Would it be it be possible to premix and inject the complete quantity of fuel and air instead of having an injector and an air inlet valve? This would ensure perfect mixing of air/fuel when it’s injected, and reduce the need for one valve?
Wrong. My 1992 Kawasaki ZXR250 revved to 21K. Admittedly the redline was 19k, but that was just a bit of ink on a dial face. The engine went to 21K. On a road vehicle. That survived at least 20 years - I sold it early 2012 with no known issues. 4 stroke. 4 cyl. 16 valves. 4 carbs.
what if you ceramic coat the pistons and block and use rotary valves in the head this is more air to
I remember 37k rpm 2stroke nitromethane fueled engines in 2.5 cc displacement. Was used in control line airplanes.
fantastic video thank you for making it🎉
I would like to see a top fuel dragster engine running in two stroke configuration along the lines of the RR Crecy.
I understand it is a slow project to accomplished but I am eager to hear an update on the tunnel upside down driving video
Ironic how the pre-chamber that was the bain of the diesel engine has now found its way into the spark-ignition engine...
0:12 Pretty sure the mass doesn't change because the piston is experiencing G forces.
Yes, I know what he meant, but it was just wrong and this is seemingly meant to be an engineering video.
Edit: I see in the other comments I wasn't the only one disappointed.
I'm a minute in and I'm gna guess the sponsor today is brilliant.
Edit at 3 mins in....nailed it.
I was looking for a track guide for Cadwell park from you but couldn't find one?
My stock 1999 Honda CBR250RR with 55,000km on the odometer routinely hits 21,000rpm and they are known to hit 23,000rpm without issue. Redline starts at 19,000rpm
Very interesting! Thanks!
A lot of talk in the comments about "mass" vs "weight" but not a lot about how that "0.003s" figure in the opening line of the video is for a full rotation of the crank and not the acceleration of the piston. That's a shame because the actual 0-60 time of the piston is even more impressive than 0.003s!
Was it less compression/ratio in the earlier days? Just imagining “heat” produced with 20.000 rpm
I think you got the temperature of an F1 engine wrong. You said it can get up to 2600C 8:34 Titanium melts at 1668C, and aluminum, iron and steel all melts at lower temperatures than titanium. I might be wrong, but imo 2600 is impossible.
The strict theoretical limit is friction.
At some RPM frictional losses in the moving assembly, *but more fundamentally in intake and exhaust gasses* become the limit aka 'pumping losses'
and pumping losess increase faster than power gain as RPM increases.
Friction *cannot be zero* for gases as gasses can't be Bose condensates. So theoretical RPM limit is when Power = Friction Power.
Flame front v, material strength etc.. are all practical engineering limits, but only engineering limits...
If you get rid of valve springs,RPM is much easier. My ''street'' Ducati Panigale revs to 16500 RPM daily.)))
Yeah, but your Pangale engine is only half the capacity of the F1 engines that were revving to 20k, and the F1 engines used pneumatic valve closure, not springs.
"Why hasn't any engine gone over 20k?"
Have you ever heard of motorcycle engines? There are a multiple ROAD going motorcycles with engines revving higher
You forget the one thing that actually IS the limiting factor. Flame front speed!
You talked about increasing RPM and therefore increasing power leading to faster laps. So it's logical to conlude that power makes the car faster... I believe it's something that needs to be explained in videos more often to people.
So basically, in 2006 they were pushing the physical limits of natural combustion engines in terms of material strength and the combustion itself.
TGI sounds like an advancement of stratified charge which Ricardo was experimenting with in the 30s or perhaps even earlier
The 2-stroke diesel which appears at 5.15 is fundamentally different to a 2-stroke petrol engine. Moreover, in the context of efficiency they are opposite ends of the scale: 2-stroke diesels are THE most efficient internal combustion engines ever built.
@Driver61 you may also wish to licence the Phil M Karting clip at 4.42 instead of treating it as a free resource
Still trying to figure out, why he held the toothbrush to the camera at 8:14
😂😂
At work, I'm designing something to spin at 15-20kRPM with an oil bath and it's got tons of issues - and it's not even reciprocating! I can't imagine designing an engine to go that fast
Back when they were running those ridiculous RPMs, they used injection similar to throttle body injection. Fuel and air had plenty of time to mix
So it's for the same kinds of reasons CPUs have a clock speed ceiling: physical limits of the materials.
There is no magical RPM ceiling. It's always a compromise between maximum RPM/HP, reliability, fuel and oil chemistry, cost, necessary fuel mileage and materials technology. All of these factors have to be weighed against each other in light of whatever technical rules the engine is subject to.