Why not make plane-tires spin, before landing?!

Wouldn't compressed air (or bleed air) work as, not driving the wheels, but shoot them up to speed, any speed would lessen the wear and tear more or less, doesn't have to be exactly the airplane speed.

thank God, someone who knows what he's talking about ... I'm not an engineer , but I've been working for a major airline for the past 30 years or so , and still am ... I must tell you that from my point of you , the biggest issue would be the huge gyroscopic effect , generated by large spinning wheels, especially on big aircrafts like B-747 or AB -380 ...
imagine trying to land in countries during the monsoon season ... there is no way the pilots could manage a landing with strong cross winds ...

Your reply and your point of view about this matter was very interesting and very professional.
Many times people comment only about the superficial not seeing the technical part of the subject. Congrats for your detailed information. Also I believe that you should be the person to publish videos about the technology of the landing gear.

The LG of any a/c is what seems to be one of the major issues in a/c design ... and the correct functioning ( maintenance + correct use, within parameters ) is mandatory ... think about the Concorde : it's the chain of events that led to catastrophe , and the key role was a non correctly rebuilt LG ... they forgot to put the spacer between the ballbearing ...

What would stop the addition of small fins to the wheel hubs so that they spin up in the airflow?

That, and passenger plane tires are really damn heavy and to "pre-spin" them would require really tough and heavy motors or engines, which means less payload, OR additional complexity to make the wheel spin using the turbine engines, which means more points of failure.
Edit: Both of which of would require additional maintenance procedures, which defeats the purpose.

@@grenzviel4480 i don’t think Motors would be necessary, some baffels to catch the air could start some spinning of the tires with less need for maintenance but i guess it would also add weight.

I can totally imagine that. 6 or 8 huge spinning wheels!

How interesting?

@@macflod I had the same idea

Good point about the gyroscopic forces, I hadn't considered that.

do you mean that it will make pitch down !!!

@@tarekelgeidy1492 No, it would pitch it up ;)
But given the small mass of the tires I can't imagine that the torque would be that much (at least for a passenger plane)

The forces would negligible.. truth is airplane tires do spin up before landing. Its a Bush flying option to prevent rock/gravel ingestion

@@miallo What you discussed is a different effect, the angular momentum conservation when spinning up the wheel. It indeed is a minor effect. I believe what the F-4 pilot's point was that you need a very large twisting from the landing gear to change the heading direction of the fast-spinning tire (changing the direction of rotational axis of the wheel when turning the aircraft).

Ha. See my comment......

But now youre increasing drag even more than the landing gear already does and probably mess with the pitch of the aircraft

That´s not well enough thought thru, first a spinning wheel is not good for aerodynamics, second the problem with the speed is still there since the speed of the wind is not the same as the ground speed and third it still needs to be fail prof.

Not sure if the airspeed would have enough force to spin up the wheels at the cost of the drag. However some bleed air could help

That´s it! Adding that you do not need match ground speed, if it goes just half the speed, tyre useful life will double. Being passive, L/G will not "drive" the aircraft out of lane in case of crosswind. Added drag is not an issue during landing. Tractors (remote controlled or not) shold be driving airplanes to and from runways since last century.

But how are you solving that problem today? Retracting spinning tires into closed planes today is the same problem I guess.

I was wondering about this for years. Spinning tires can keep spinning inside the body, once retracted. If there is enough space. Small vanes to spin the tires a bit?

@@Deontjie I think small vanes are a good idea. But it does not work with Boeing 737. Tires and vanes are visible. Maybe you just could use special rills ... a profile like a tesla valve. It is almost a normal rill with small changes. This will bring a tire to turn by just using the speed of air (>250km/h). In a closed body they then are able to slowly stop without problems. (But probably they did test something like the tesla valve already.)
Probably tires are generating the moment of contact with the ground that much heat rubber is just burning. Slowing down the speed difference a bit could result in just getting hot tires but no destruction of the rubber molecules. This is science a series of tests should give you better knowledge.

​@@Deontjie That is exactly the thing - There isn't space to retract spinning wheels - if you look at a gear well on a plane it is covered in hydraulic and power lines
The brakes are required to be engaged and the tyres decelerated as if they retract a fraying tyre into the well you have now pulled in a circuloar saw blade if you look they don't retract spinning wheels - they engage the brakes as part of the gear up
This increases brake wear as you can't turn off the vanes meaning after take off the wheels will still be spinning up to flight speed when you are trying to slow them to retract
Any vanes attached would need to be sizable to catch enough wind to spin them up - if a manufacture defect causes a vane to break free due to microfractures and fatigue you may have just catastrophicly compromized the plane
Say a wheel has a brake failure? Now you have a wheel runnaway which will be constantly accelerating to the speed the wind allows that you will never be able to retract - burning out the wheel bearings and runing faster until the vanes are thrown off as shrapnel
Finally, you have introduced an unknown variable in the flight controls - The mass of the spinning wheels while in the air generates a gyroscopic effect you can't account for - as the ammount of the effect will vary radically between and approch as you aren't going to be able to guarentee the speed of the wheels - as it's inherently a function of wind speed, altitude ASL and the fact that several wheels are partially or fully occluded from direct wind
This effect will be being added with very little possible control during the late stage of a stablized approch, which is specificly designed to reduce variables for safety

@@bengrogan9710 All very good points I hadn't thought about!

How has a comment from a channel with 2M subs been able to go 9 months without a reply? lol

you are correct. When working in the wheel shop the tires are inflated to pressure using normal shop air. However the shop air must be 100% free of moisture. We use helical air compressor with gas fired air dryer. Now the easiest way to add air in the line environment is to use nitrogen bottles. This guarantees moisture free air.

Also the more rubber on the ground the more traction you get as I understand

Good points. His understanding of physics is a little rough around the edges.

The use of nitrogen became law in FAA Airworthiness Directive AD 87-08-09. It requires that all transport category aircraft braked wheel tires contain no less than 95 percent nitrogen or other inert gas. The inertness of nitrogen has nothing to do with its physical properties. It expands and contracts with temperature just like any other gas. The required inertness is chemical. The AD was issued upon a report of a Mexicana 727 (flight 940) that crashed after having taken off with a dragging brake. The heat decomposed the tire rubber into flammable compounds, which combined with the oxygen in the tire to cause an internal fire and subsequent tire explosion. Google Mexicana flight 940 for details.

Indeed, oxygen gas and other gases (or mixes) follow the basic rule of temperature having a linear relationship with pressure. One problem with normal atmospheric air when it's subjected to large swings in temperature or pressure is that it contains water vapor, which could easily turn into liquid or solid under the temperature and pressure conditions that affect jet aircraft; liquid or solid water in the tires being undesirable for multiple reasons. I assume the process they use to separate nitrogen from air is sufficient to remove all significant impurities including water present in ordinary air.

Not true. The chemistry use isn't the definitive use of the word. Inert just means inactive. So his use here was appropriate.

What are you the inert gas police?

Inert gas must be non flammable is why gas lines are nitrogen purged as well as non corrosive etc

kefsound it’s about not supplying oxygen to burning brakes and tires following an aborted takeoff and consecutive pressure relieve valves releasing the gas rapidly. Every tire is equipped with a pressure release valve to avoid tires “exploding”. The Nitrogen released won’t feed the flames after such event.

It is true Petter insisted too much about matching the exact speed (when even only 25% of it would be already better than no speed at all), but he ended with saying this is not the main problem anyway. The main problem of spinning the wheels would be when crab-landing.

@@akseli9 Adding motors to the wheels doesn't decrease their abilities in any way. If it's safer, you can not use them when crab landing.

Dannick Giguère what’s it like being in the .01%?
Most of us will never fly let alone study in Switzerland, and my wife is Swiss.

Syudo Nem it might be fun feeling virtuous and blasting people online but I am unfortunately not a multimillionaire. I am in studying there only for a year, paying canadian tuition fees. I worked for many months saving up money while doing my degree at home and I live with minimal expenses in a small village so I do not pay crazy rents like in Zurich. Living 10 months in Switzerland plus all of my small travels in Europe will cost me less than 40% of the average yearly salary in Canada (or 25% of median family income).
No hard feelings, I just wanted to reply so you can see that it is not unachievable for most middle class Westerners, when you work hard and find different programs like student exchanges. If you or someone else has any questions, I will gladly answer them, but somewhere else, as this is unfair to Mentour. (It does boost interaction but not the type he wants I guess ahahaha)

good (overlooked ) point. quite a lot of KE would be transferred to rotational. a/c tires have a large radius (squared) and therfore loads of MI. I imagine theres also a bit of "differential feedback cotrol" in having wheels on both sides of the aircraft - effect like a car differential?

but i think they wont take much energy, considering the momentum of a 65 tonne machine coming at 300kmph.

@@abcdefgh6121 Every meter less in breaking distance is worth - not spinning up the tires prior to touchdown.

Small flaps like in ww2 would do the job

On the other hand if you mount electric motors on the wheels you could use them to charge the batteries onboard, and decelerate the aircraft at the same time! Using bleed air is probably much simpler. and just speeding up the wheels to 50% of normal landing speed would decrease tire wear a lot.

@@ErikssonTord_2 Electromotors are heavy and you need a lot of them. Also you need a large battery storage. And big batteries and planes don't go well together.

@@KneppaH what do you think the motors and batteries would be used for? traveling in the plane but on ground? how heavy do you think a motor and a battery needs to be to spin a wheel a little bit?

@@KneppaH no they are not. Jaguar has 350hp electric motor that weighs 16kg. The weight of a fat cat is not heavy

Which type of glue would be better for that application- Elmers or Gorilla?

@@kamakaziozzie3038kamakazi glue!

@@kamakaziozzie3038flex seal will work best

They tried it... but to retract the wheels after takeoff... the wheels need to be stopped. The added wear on the brakes costs more.

@@wolphin732 That's a great argument against having vanes on the sidewalls. how about a shroud that covers part of the top of the wheel but not the bottom, spinning the bottom. The shroud wouldn't be deployed on take-off.

Plus it added weight & created maintenance issues. The idea sounds great but it was scrapped because it wasn't worth the trouble.

It was actually the Lockheed Constitution - a large cargo plane that never made it into production - that had this feature......

@Ian Brown was done, patented, dropped....safety issues

That's it exactly. Your can't sodding land. The tyres spinning up take enough energy out of the aircraft to stop it flying. Without which it just keeps skipping down the runway.

Actually, this concept was tried on the U.S. Army Air Force B-18, which was different from the B-17. This was probably around 1940. The concept was dropped, as I understand the facts, because little significant improvement in the landing procedure was found, and only a few B-18's were built.

that's how i see it too..
some of the explanations don't really make sense to me as to why not implement wheel spinning.. the added weight most likely does not make sense, fuel consumption vs tire wear.
anyways,
~there's no need for "huge batteries by the gas tanks"
~the plane would not veer off the runway in case of cross-winds, as the wheel rotation ca be controlled to account for the 'side-ways' touchdown

Agreed. It's all about "attutude". Yes, more pun .. (cough)

I think he is over blowing the technical difficulty in implementing wheel spin. It definitely can be implemented and we have the technology to do so. But the things that he listed do make it less worthwhile to do so. So at the end of the day, there's no motivation to implement it.
The cost of development isn't cheap. It's not as simple as just spinning the wheel. A computer need to know the ground speed and crab angle which then actively adjust each individual wheel as the plane approach the runway. Then they need to fit the motors and batteries and computing systems somewhere safe without adding too much weight. Weight is a big deal because aviation fuel is really expensive, so any unnecessary weight will make each flight more expensive. Each addition need to have enough reasons to justify the added weight. TV screens for every seat attract passengers and that additional income justify the added weight and increased fuel consumption for example. Wheel spin is by all means possible but far from simple and so cost lots of money. Retrofitting would also means going through the regulatory bodies again.
New designs might be able to do it since they will have to go through a safety check anyways and the design can accommodate the system from the ground up instead of redesigning and retrofitting. But the airlines need to actually care and want that feature in the first place. If all else is the same, wheel spin feature might be nice, but more likely than not, fuel economy, seating and other features will not be the same and get most of the focus from potential buyers. If wheel spin isn't a attractive enough feature, designers won't incorporate it because it just adds development time and money. Instead that effort will be placed on better fuel economy and other more attractive design considerations.

I like the way you think

During WW-II many of the tires on the larger bombers were made with small flaps facing forward in the sidewall at the bottom of the rotation to use the airstream to start the wheels rotating before landing.

@@JimForeman so it's has already been done?

I guess it will add a lot of drag, thus making it harder to take off?

@@HenrikOlander But less wear on the brakes during landing.

I think... but I'm getting on in years these days that I had a professor that told us airlines (at least back in his day) leased the tires and they were rated for X number of take offs and landings which we all agree should be equal... but it was a physics class a long time ago and he said fuel load at take off is way worse on the tires than landing... he was a former bomber pilot so I can't support or refute his supposition

That huge thickness holds a lot of technology also. A 767 main gear tire is a 32 ply tire, the nose gear is 24 plies (ratings… ply numbers can vary by manufacturer). Their limiting factor is heat absorption during braking.

Bugatti charges ~U$20,000 per set for the Veyron

Standardization and big batches.
Car tires cost more because they are all custom made with lots and lots of different sizes and treads and compounds.
For one model of aircraft they essentially make a ONE SIZE FITS ALL tire and that can even go across a whole series of models or even a whole brand.

He said 15 000 per tire not 1500.

@키코kiko: That's not just the cost of the tires though. It's true that Bugatti charges that much but that includes picking up your Veyron from your home, flying it back to the factory in France for a full service of all the mechanical stuff, changing all the all oils, fluids and of course the tires, before delivering it back to your home. The tires themselves are only a small part of the cost.

@@niconico3907 Wrongo Wrongo

Air is 78 % nitrogen anyway.

pV=nRT applies to "ideal gas" which is hypothetical construct, not something existing in reality. "Real gas" is affected by multiple factors ideal gas equation doesn't consider, including various reactions on molecular level, compressibility of gas (or gas mixture as it would be in relation to air), varios molecular forces, and thermodynamics of it all. In other words pressure of pure nitrogen and nitrogen/oxygen/argon/CO2/various trace elements mixture (AKA air) do change differently with temperature. For most application that doesn't really matter mind you, ideal gas equation is reasonable approximation, but that doesn't make your statement any more true I'm affraid.

@@maciejkornatowski3026 actually, every element in gas form expands in the same way

@@maciejkornatowski3026 Oh my, I knew there was going to be someone pointing out that ideal gas is just an approximation. I know that. Nitpicking aside, the ideal gas model is absolutely fine for the point I wanted to make.

Yes. The bigger issue is that using Nitrogen instead of Air means you'll be using a _dry_ gas. Air has lots of water-vapor in it, and water changes its pressure and volume quite a lot compared to other gases (especially as you go through phase transitions). Therefore a tire filled with pure nitrogen will change pressure and shape _less_ than a tire filled with air. Its not just because its Nitrogen though - its the lack of water vapor that makes the bigger difference. [This is also why nitrogen is used for many auto-racing tires where the overall diameter and pressure is a very important component of the suspension system and the car's handling around the track]

thanks

Thanks!

Thank!

thx mate

he is just busy pumping up his ego.

I remember that some 20-30 years ago a young girl suggested small flaps on the wheel in a youth competion ....

@@robertlaudensack376 tire industry is too powerful, i guess

@@robertlaudensack376 I heard 25 years ago that a patent like you describe was filled but immediately bought by a tire supplier and hidden. (Little curved blades or grooves on the rim that spin the wheel at high speeds)

Two problems. He mentioned that when landing with a crab angle, if the tires were spinning @ 200mph they would tend to push the aircraft in the direction of crabbing - towards the side of the runway not down the centerline. Could be dangerous. But probably most importantly, the fins would cause drag on takeoffs also, not just landings. That's potentially dangerous. If the fins were adjustable and made not a factor on takeoffs, that adjustable mechanism would be a potential point of mechanical failure.

Joe Sternhagen in my opinion angle landing with spinning tires is a negligible problem when you take the torque energy of small spinning wheels agains the linear Momentum of a 65+ tons Airplane. The second mentioned concern about the extra drag on takeoff doesn’t barely apply as the wheel spin on takeoff anyway and then soon disappear in the gearboxes.
Think outside the box folks and turn on the logic ;-)

My father told me the exact same thing. He retired from USAF/SAC in 1965. Did not effectively extend the tire life cycle to be worth the bother.

Main reason for using nitrogen is to exclude moisture which stabilizes pressure over temeprature (nitrogen pressure will scale linearly with temperature while humidity can condense and evaporate and add a nonlinear characteristic over the service temperatures). The exclusion of oxygen is a side benefit which helps keep the rubber supple longer

Did you have to use 2 decimal places on the price? I read it as $20,000 with U as another 0.

Best comment of 2019!! xD

Yea, those major airline pilots barely make ends meet! He really has to do the paid advertisements in his videos to help pay the bills...

Just double click a few times on the right of the clip and skip 30 seconds a few times.. Skill share problem gone in two seconds and pilot still gets paid for the ad.

@@pickyourday joke mate chill out

@@pickyourday honestly, that is a positive joke to uplift people

All I can say is Great Mines think alike.

@@cvhawkeye6255 Yes. They all produce gold. (See what I did there?!)

@@ananda_miaoyin Sorry for the typo! Greater Mind! All Good.

@@cvhawkeye6255 I thought it was a brilliant play on words, if even by accident!

Right because the dude with hard accent is an aircraft.

Is that with respect to the viewer, or the pilot?

Sean Whelan
There is a white tail pillow but you can’t see from here.

I freaked for a second when the pillow in the left background moved.

ha never noticed :)

It sounds good on paper but aircraft needs the APU on board as well to have it there in case of emergency to keep power for flight instruments and create pressure for engine start up if air flow is not enough. You could use tugs to make the pull and have jet engines just idle and warm up while going to runway, not taking extra fuel to actually move the plane, this would also remove some break heating up if tug can provide braking forces on the ground, but to have them fully autonomous is kinda bad idea in my mind. Much rather have mentioned remote control by pilots and then ground operator takes control of it to get it back to gate. Having it being autonomous would cause dangers of thing deciding to just wroom on the runway while plane is coming in or stuff like that. There needs to be very least human operator supervising them even if its remotely, but even after that there must be system in place where by cutting power it can roll freely if there is no plane attached and another drone to be able to tow it away in case on malfunction all with in minutes to clear the paths. There is good ideas to this, but its needs further development to iron out any issues that can rise from it. For electrification of aviation... maybe when batteries can hold much power as fuels we use today. Electric systems are always bit iffy and i would not trust them specially in planes. EV's as ground vehicles, maybe, but even that is pretty horrid idea.. If you have seen how much effort it takes to extinguish EV fire... now add tons of fuel to that... then add row of 737's next to it.. yeah that is bad bad idea...

@@Hellsong89 further to your comments if you had a tug to tow the aircraft to the end of the runway then needed someone to return it to the gate you would need a tug and driver for lots of aircraft as opposed to one guy doing a quick push back then moving to the next plane, plus some of the taxi distances are pretty long and aircraft can end up in queues at the runway, so once again it would probably end up more expensive than a few thousand/hundred pounds of fuel, and would be far more complex to organise.

Me also

Tires are at take off speed on every take off. Most airplanes take off at a higher speed than on touchdown. So the argument of speed on tires is bad is just BS. I suspect paybacks from the tire makers and BS "Studies" by the tire makers too. Corruption.

molding scallops into the sidewalls could act as vanes to help spin the tire when in the airstream.

I don´t thik the passagers would like arest wire landings. It´s kind of brutal. i read it´s like going 110km/h in to your driveway and make a compleat stop before you hit the garage wall.

The polar inertia of the landing gear is probably insignificant to other circumstances that make landing unpredictable.

@@exploatores There's no reason you'd have to have a brutal arrested landing, you could specify any amount of time or distance over which to reduce the speed. The wire may be impractically long though. :)

I had basically the same idea about using the airflow to spin the tires many many years ago then I learned about gyroscopic forces and how any force applied to a gyroscope will result in a force 90 degrees in the direction of rotation.

@@OpusBuddly if a puny motorcycle engine spinning backwards (normally they spin forwards) changes the handling of the motorcycle so much as to be VERY noticeable, imagine the gyroscopic forces all those enormous wheels will create. All in all a very bad idea.

Good post but only the tip of the iceberg so to speak. What are all the issues1-Out side air temp. is -50 degrees F and the bearing grease is solidified. Fix with preheated lube oil at 50 degrees f with seal by pass and circulate with a small air turban pump.and pencil heater. Install push back springs in wheel disc brake cylinders This will help in free spinning. Wheel spin up via Pelton wheel hub caps and or tire cups in the moldings. Pilots can apply breaks until just before touch down to deal with Giro effect in cross winds. This is somewhat of a copy I use on Boat Trailers to prevent water intrusion. Pat pending?
dellori3

I have discussed this with a commercial pilot I know and he agrees this could work. The speed that would be achieved by rotors wouldn’t be as fast as the plane was travelling, in fact nowhere near as fast, but they would very much reduce the impact speed and tyre stress. The wheels are heavy despite the materials used and giving the wheels kinetic energy is like racing cars flooring the accelerator from a rolling start as apposed to a standing start, it’s difficult to get wheel spin from a rolling start! Speed of the wheel’s rotation could be controlled by computer slightly touching brakes to provide even speed. The centrifugal forces of the wheels would be minimal, given the weight of the plane.

I would think that would be the case, my seat-of-my-pants feel is it would not be terrifically significant. I certainly could be wrong.

Static friction is higher than dynamic friction. You get more friction between the tires if they are rolling along with the ground than skidding along it. This is why we have Anti-lock Braking Systems in cars - to stop the wheels locking up and skidding.

@@AtreidesOne0000 In cars it also helps with control while braking, as a sliding tire does not steer effectively (if you have driven cars without anti-lock brakes on snow or ice you are probably familiar with this).

This is an actual idea I'd been working on for a few years now. But I can see why they will NOT be developed in my lifetime. Too many hoops to jump through to have them certified for aircraft use. But Imma keep trying.......

I have a different idea, just leave it the way it is.

machine doctor just a hypothetical suggestion, but thanks for your valuable input.

Years ago I saw an inventor's program in which someone had invented a turbine style add-on for plane wheels, so they would spin up from air resistance. It was shot down (pun intended) down as being an extra component and thus extra risk, plus the extra wear of tyres screeching at landing is less expensive than fitting new tech with all its drawbacks.

Also thought about by many non-engineers over the years - why not mold little protrusions on the rubber tire sidewalls directly? Bottom line: it wouldn't nearly be enough to get the wheel spinning fast enough for the typical landing. And as he noted, landing speed varies from one time to the next due to many factors.

he already said that changing tires on airplane cost pennies compared to other maintenance and running costs.

Crew Chief. Respect. However he just explained nothing to you or I. Ask yourself this. Has Boing Aircraft asked this question? Yep. They actually have. It is in the math that we don't spin tires. Hello Democrats.

And cause drag at takeoff or landing

Umut ATÇALIOĞLU fins

Oto You’re overthinking it. The wind-resistance of the gear is already significant; in fact, I believe most pilots use the deployment of the gear as additional air-braking during Approach. So the additional drag the modified wheels would add would be more helpful than harmful.
The drag on Takeoff would be nearly eliminated by the fact that the wheels are already rotating as the aircraft is propelled along the runway, and since the gear are retracted almost immediately after becoming airborne, the slight increase in drag as they lose contact with the ground (immediately losing frictional rotation and thus requiring airflow rotation) quickly becomes a moot point.
So really, it’s a non-issue. 👍🏼

Cessna citation actuation has nose wheel spin up before landing on airplanes that are designed for gravel runways

Tell me, how would you do that? You couldn't set them up as a turbine set up because you would have pressure on both sides of the circumference of the rim there for pretty much cancelling out it's usefulness. Plus the fact that you don't really have enough clearance between the tires and the wheel struts either. The forces involved would be enormous and building something onto the rims would again add to the cost and probably not do much. Another thought is how you would be able to stow the landing gear during flight and bring them down for landing? There's not much space for the gear as it is in the body of the plane. What you would need is something like a windmill so that the wind is in the same direction as the shaft of that windmill. Bottom line? It's more trouble than it's worth. If you want a perfect example, get one of those kid's pinwheels, take two water hoses or air sources and blow out at the edge on both the bottom and top from the same direction (air flow) and see what happens.

The braking force is insignificantly small for a static wheel. We are talking a 80 tonne aircraft against a (what? guess) 250 kg wheel. Even when you multiply those wheels by six you only get 1,500 kg which is but a fraction of the total mass of the aircraft. And they will not be a constant stopping force as they start spinning rather quickly.
From the wheels perspective however... They are literally SCREAMING as they touch the ground.

Thats remould of the tyre, that is not what mentour means by retread. Retreading is using a heat cut and cutter to cut the groves in the existing tyre deeper. I've done this on lorries.

@@RealCadde
I know a static wheel isn't going to provide all the force necessary to slow the aircraft down, but every little helps!
I also know this isn't happening by design, more as a by-product of the reasons mentioned in the clip

@@miyahollands6136 You have a point. I see it now. Having pre- rolling tires would make the plane more tricky to stop since it will need more runnway.

@@GeordieBoy69 No, they're not cuts added to the tire. A retread for aircraft involves trimming the tire, then melting new rubber onto it. It is then placed in a hot mold to create the new tread.

damn - that was my idea decades ago, but with a small permanent feature on the tyres. I knew I should have patented it :)

How would you build a mechanism to retract these blades into a rubber tire that has 200 PSI or pressure in it? I can imagine it would require multiple holes in the tire which would seem to add a huge risk of tire failure. Would you make this mechanism something that is purchased with each tire? That would seem to add to the cost. Removing and reinstalling would add cost too. And whatever mechanism would have to be taught to withstand the tires flexing, and would also have to survive some huge centrifugal forces as the tired rotated at landing speed.
I may be missing your point though, if so, the idea sounds interesting absent a few problems.

Until you're retracting the gear after takeoff, when you want the wheels to have stopped spinning...

Why not spin them backwards then!

That's actually a good point. Tires spinning at landing speeds would indeed increase the landing roll.

No it isnt. The less tyre slip, the better the braking performance.

I had the same thought years ago, and even built a prototype with the blade from a squirrel cage fan mounted to the rim of a small tire.
I then tested it using my truck at 60 mph and it did indeed spin up, I dont think it matched my ground speed, but would have reduced the burn patch of the tire considerably.
I also thought of adding rubber vanes to the tire sidewalls themselves.
The one thing I didnt think of thats mentioned in the video, is how the spinning tires affect the crabbing maneuver.
Great minds think alike, even if not successful it can lead to huge innovations.
Keep that brain gearbox, well oiled

@@scottk6659 I take my lion's mane mushroom extract every day...or I would if I could figure out how to open the bottle.

Most aeroplanes do not have shrouds or fenders around the wheels, the Canberra had a shrouded nose wheel but that was to reduce stuff getting thrown towards the engines. A few GA aircraft do have guards around the wheels but most military and civil aircraft don't. Once again it is adding weight to the aircraft and its simply un-neccessary, even on the GA aircraft with guards they are more for aerodynamic effect on fixed undercarriages.

@@scottk6659 Absolutely agree. This seems like a no-brainer. And I think you could approach the actual landing speed by planning the geometry of the wind vanes. Even if it is half the landing speed, that would make a big difference in the stress and wear on the tires. If the vanes are built into the wheel, it would probably cost very little.

Exactly what what was thinking

Nitrogen also used in fuel tanks.

But why does he call Nitrogen an inert gas when it isn't? Also for all gasses pressure is directly proportional to temperature so he has got that completely wrong too.

Probably because it doesn't support combustion, in the case of a brake unit fire

@Gareth H
Nitorgen gas is mostly used as an inert atmosphere...
He didn't say all just Nitrogen... and again just earth atmosphere and "normal" surface. So nitrogen pressure varies in these conditions is
negligible

@@garethhanby NITROGEN is the gas that its thermal expansion is the LEAST of all the gases... so between -55C in cruise, an then in approach perhaps -15degC ant then in an instant go to 120-150degC.... it must be VERY well controlled. NITROGEN is very stable and final tire pressure varies VERY LITTLE!

Poopie isn't interested in all of this talk.

​@@geoffdearth7360 UA-cam won't allow you to make content unless you have a dog or cat.

Mi 28 and regular air contains oxygen which in combination with moisture is a very bad thing to have in an area that can’t be inspected regularly. Nitrogen is inert and contains no oxidizing agents. That’s why we use it as a shielding gas for welding.

snee regular compressed air is also non flammable so that doesn’t seem to be a necessary argument. The second part of your response is what he explained in the video so good job

They use nitrogen because the FAA requires it to eliminate the possibility of explosions. From the FAA:
"This amendment to the Federal Aviation Regulations (FAR) requires that an inert gas, such as nitrogen, be used in lieu of air, for inflation of tires on certain transport category airplanes. This action is prompted by at least three cases in which the oxygen in air-filled tires combined with volatile gases given off by a severely overheated tire and exploded upon reaching auto-ignition temperature. The use of an inert gas for tire inflation will eliminate the possibility of a tire explosion."

Andrew Snow I think commentors on this thread are saying the same thing. Water in air freezes. And that causes problems that pure nitrogen doesn't have. The FAA requirements are based on simple physics, as well as accidents.

George W there are also a few that seem to be confusing explosions(needing a fuel and oxidizer) with rupturing(due to altitude change) nitrogen doesn’t expand at high altitude as much as compressed air. A ruptured tire in flight could cause an explosion just simply because of is location in the wing box.

Ah but see..you could have a section for passengers that have to run on a treadmill that would transfer the spin to the tires. It would be less than the economy and the passengers would have to stand up.

As somebody trained in physics and engineering, I'll can say this intuition of yours is wrong. The amount of energy to be gained and the time available to accelerate means it's essentially just the same as landing that 2 or 3 mph slower.

Sounds wise from every point of view, and just spinning up the wheels to 50% of normal rotational speed at landing would lower the wear a lot. Using bleed air to spin the wheels off could also cool the brakes, I guess.

as for your idea that wheels don't vibrate because they are balanced, yep when initially fitted they are but after use they can become out of balance, or shed a weight or...
These aren't as you say bicycle wheels, we are talking about a wheel up to several feet in diameter and a mass of several hundred pounds, in the case of a 747 there are 18 of them all spinning at various rates, why take the chance of spinning them up to high speed at THE critical point in the flight.. landing.
Spinning the brakes up.. brakes often bind quite hard so that wheel might be slow giving different forces than the others, why bother taking the risk for something that might only last one landing, you've probably seen the video of landings where they hit one leg first then slam the other down while the aircraft is sorting out which direction it wants to go, tyres are worked hard. As someone else said there are some aircraft where various systems may be initiated by the wheels spinning up to speed, like the brakes for instance, spinning them up early puts the brakes on before you land. Spinning them up is of course possible its just pointless.

@Ummer Farooq They would likely burst or the plane would slide off the no stability.

Not just a feeling

he has it so he can share that info with people like you and i

You do know that every pilot is risking their own life too every time they land, right?

You mean “even less accidents”.

@@alfeberlin Well, ACKtually, he means "even fewer accidents."

We are all learning. Great thing you pointed that out

I understand where you are coming from (I studied chemistry in university as well), but nitrogen is often used as a substitute for the noble gases. While it is true that in certain situations it is reactive, most of the time nitrogen does not easily react with other substances (this requires breaking the triple bond in the N2 molecule - not easy to do). Guaranteed nobody would be using nitrogen in aircraft tires if there was any risk that it would be unsafe.

@@JustSomeCanuck you are 100% correct I was just commenting on the term "inert" which is a whole different group that is very difficult to react even in a lab and pushing the reaction towards it, I just wanted everyone to not get confused with the 18th group but you're absolutely right that triple bond is quite difficult to break in normal conditions. Thanks for your feedback 😊.

The video digresses a little from the title which is about pre-spinning aircraft tyres to reduce wear when touching down.
However the discussion about tyres is interesting. Filling tyres with nitrogen because nitrogen is 'inert' I think is a bogus point. The gas mixture of regular air is 78% nitrogen anyway. Removing the 21% oxygen that is in air might be advantageous, but I think removing moisture is an even bigger deal, particularly given the range of temperatures these tyres need to operate over.
I was lead to believe that dry nitrogen was advantageous because the nitrogen molecule was relatively large and diffusion through the rubber was reduced.
I think Mentour Pilot assumes that the motors to spin up the tyres are powerful (large enough to taxi with?) and you need to accurately match the rotation speed to the ground speed on landing. But even motors just large enough to spin the tyres up to 80% of the ground speed would reduce the tyre wear on landing. No need for a battery since the engines are running anyway (hopefully) when landing.
The point about costs and the relatively low cost of a tyre is the clincher though. If you get 300 landings from a $1500 tyre, that is just $5 per landing. Peanuts in the bigger scheme of things.

@@fredlodden1538 thank you for the physics behind that I really didn't know that like I said I'm the Chemist here lol, but you are right if it's $5 for each landing that's pocket change to the remainder of the costs to operate a passenger airliner.

Jack it up. Easy that.

It's simple. They just fly at a lower speed with the landing gear down. A tyre change plane comes in underneath and they switch the tyres out.

They jack up the affected wheel assembly. Not that different to replacing a flat tyre on your car, along the raodside.

@@ashleymalamute No, they fly it in a wind tunnel.

They use jetliner jacks. Gargantuan, immensely powerful hydraulic jacks. They jack up a plane and change the tire like you'd do on a motor vehicle.

3: Rubber is cheep. Only because of modern day slave labor

"if it ain't broke, don't fix it" must always be balanced with "there is always room for improvement".

Aldis Berjoza The guys to work at these plants are union and get paid fine.

@@mog882 "The guys to work at these plants are union and get paid fine."
He isn't talking about the guys at the tyre factory, but the ones producing the latex. They are commonly suffering.

Nothing beats simplicity

You could have used capital o as zero, just like this: 2O15.
Looks almost the same as 2015. 😉

U can write 2k15

@@JobFarming true true. Good point well made :D

if you don't want to change the keyboard... there is a little tool called keyremaper... and can turn any key you want to do whatever you want...

He's also mentioned in other videos that there are times when you may want that high-friction tire hit to eat up some of your momentum.

Now multiply it to the number of tires

@@pahom2 With 6 tires that's still just $30, small potatoes compared to other costs.
Even with 32 tires (Antonov AN-225) it's still "just" $160 where they are paid roughly $30,000 per hour for operating the aircraft.

Tyre not tire.

@@GeordieBoy69 Learn English mate. Both words mean the same thing, just different countries.

@@RealCadde mmnn Cadde, tyre is English, which usually equate to British ( and may I say, rest of the English speaking world ).
tire is American, difficult to quantify here, is American English? Do Americans want to be pigeon holed as "English".
a real dilemma here actually ie American butchering the English language as it is.
is it colour or color, Lift or elevator, tomato, tomaeto..
never mind, it's a big world out there, we can live with it, me think... 😁😃😅

verdatum it’s the same for me too, it’s kind of hurting my braid

I'll never accept it lol

But where would paddles go when wheels are retracted?

@@flyingark173 they'd remain parallel to the wheels at all time. The orientation relative to the wheels and the diameter of the turbine would be designed such that there's no chance of them scraping the tarmac, no matter how much the wheel is compressed on landing.

@@flyingark173 in the same place as the wheels??
Maybe the doors would need to be a bit wider.

@SuperCorrector1 maybe

Look at a video of a top fuel dragster on a full power run, their tires are engineered to handle several different distortions based on the different forces based on how hard they run and the expansion is even used almost like a gear change during the run where they can reach speeds over 330mph in under 4 seconds, there's MASSIVE gyro force on a tire at high speed

@William Burns And at a 747 there are 18 of these gyroscopes working..... !!

The testing, criteria and requirements to put tires on anything aviation is SUCH high tech and unless you see an aviation tire testing facility for yourself (as I have) the word "cheap" would not be in your vocabulary while you were discussing aviation tires. It's a whole different animal so to speak.

Michael W. Perry
with of inflation rising which comes back as the cost of a ticket to ✈ fly by adding on extra weight & maintenance cost I think I can put up with burn off little rubber to insure my safety upon landing, good info chap.

Where's your sense of adventure?

Meh, I feel as though you can sufficiently test out the engine on the ground in a manner that burns a little less than 200kg of jet fuel. And besides, takeoff is practically a test in itself. Aborting a takeoff is a perfectly common thing that pilots are trained for. Also, jets can cope with a damaged engine, and nearly always, on the ground, you'll only have fault with at most one engine

The engines are reliable enough and both would be on (to power up cockpit systems and cabin pressure); the engines would be set to idle, until the tug disengages, vs using thrust to move the aircraft around the taxiways. Most turbofan engine failures do not occur on taxi, and if there is a critical issue, those are typically identified during preflight, not during taxi.
How often do airplanes taxi back to the gate because of an engine issue, before taking the runway? I've never heard of any incidents to indicate this is a concern.

Except MOST engine problems happen on TOGA anyways or when already rotated. It's very rare for engines to fail on the ground, only when used near their max performance.
How often have your cars engine died in idle vs when loaded?

@@RealCadde They may fail on ground due to FOD.

Most dictionaries don't agree with you.

Yup, good idea, already patented though ;) the position on the casing and deflection an aircraft tyre has to handle make this difficult to implement, aside from production challenges of course

I also had this idea. I think something would work. The problem though may be slowing the tires down while retracting them after takeoff. It may be a safety issue, that it’s better to wear tires out than risk problems from spinning retracted tires.

Haha, I was looking is somebody suggested this already! Good one!

@@ice320 do you have a source or link to patent?

nicholas flamegun nice idea

Reading other comments, sounds like a good guess!

I'm guessing that huge engines rotating way faster also create a gyroscopic effect.

Nitrogen is not a completely inert gas, however, it is a fairly inert gas. N2 is a pretty stable molecule and it tends to take a decent amount of energy and/or catalysts to get it to chemically react. But yeah, it's cheap, uniform, and dry.

@@verdatum I routinely keep my car tyres about 80% Nitrogen filled.

@John Fisher All gasses are bound by the ideal gas law. PV=nRT, and thus temperature changes will cause identical corresponding pressure changes in all gasses in a confined volume, with the exception of phase changes (which is the issue here with water vapor). 100% fluorine gas would have the same amount of pressure change as 100% nitrogen, and fluorine is as far from inert as a gas can be. An inert gas is one that won't facilitate rapid oxidation of fuels. In other words, it's one that won't feed a fire, should one occur, and that's probably the major reason for using it in aircraft. Either that, or it's easier to ensure there's no water vapor in tires if nitrogen is used as opposed to air that's been dehumidified. Another minor reason is that N2 is a larger molecule than O2 by a couple percentage points, and is thus ever-so-slightly less likely to seep through the pores of the rubber over time.

All gasses expand and contract with temperature and all gasses will slowly leak from your tire. The nitrogen fill is a scam unless it's gratis.

Nitrogen is used to prevent tire explosions. From the FAA:
"This amendment to the Federal Aviation Regulations (FAR) requires that an inert gas, such as nitrogen, be used in lieu of air, for inflation of tires on certain transport category airplanes. This action is prompted by at least three cases in which the oxygen in air-filled tires combined with volatile gases given off by a severely overheated tire and exploded upon reaching auto-ignition temperature. The use of an inert gas for tire inflation will eliminate the possibility of a tire explosion."

*BANG*

It's obvious that filling them with helium will make the aircraft lighter too lol

@@AnnualDegree99 too true, but perhaps it introduces a hindenberg element I was trying to avoid... 😁

This is why I fill my car tyres with a mix.
78.09% nitrogen, 20.95% oxygen, 0.93% argon, 0.04% carbon dioxide.

@@twig3288 with a tyre you have to use a mix like that. with tires, we just use air.

Suggested this to a tech in the airline where I work, but he responded it was undoable because of dangerous gyro effect from the rotating wheels before touch-down.

Øystein Jakobsen

@@thatfeeble-mindedboy Air driven spin up of tires has been around for 50 years. It doesnt really change tire wear notably, and it adds mass and weight to the aircraft.. Also, the potential to have explosive fail of these components creates additional maintenance. All together, the spin up idea by air fins DOES NOT PAY FOR ITSELF historically, and aircraft outfitted with these devices usually have them removed due to maintenance cost. Whereas this sounds like a good idea, in reality, it isnt. Also, aircraft rarely land straight, and usually land with some misalignment which causes a lot of the tire wear. It's all about cost and safety. If it improves either it survives in aviation. Air driven spin up didnt survive.

Because of crabbing, even if the tires are at speed, they still undergo significant wear on touch down. Since it's rare for the wind to be blowing directly down the runway heading, that means there is little savings in spinning the wheel. By the time you add the cost of carrying the weight and the cost of maintenance, it turns out to be cheaper to just go ahead and retread and eventually replace the tires a little more often.
While that might feel like "wasting" tires, the alternative is to "waste" fuel and "waste" the time of your maintenance people. TANSTAAFL.
One thing people forget when proposing simple vanes on the rims is that you want to be able to retract them during takeoff, where you don't want the extra drag. Then, what happens when one side retracts and the other doesn't? Or, when both sides deploy during takeoff? Suddenly, it becomes much less simple.

To share an explanation I saw in a different comment-thread on this video: The gyroscopic effect of pre-spinning the tires while the aircraft is in the air is apparently quite substantial. Anything that makes it harder to tilt the aircraft left-to-right will make it harder to land safely.

@SuperCorrector1 still cheaper

Both of you people are stupid af lmao your mother should be ashamed haha

It's a solution in search of a problem. For mechanical simplicity and weight reduction, it's easier and more cost effective to make tires that will withstand the expected stresses on it for a reasonable amount of time.

rolocz Aircraft tires are seldom changed, thus no money is saved

@@ammaarrh They are changed quite often. Do you think they just have the attitude of let's see what happens?

Just land the plane on a gigantic conveyor belt

Spoken like a 'Carrier-based Navy pilot ' !!!

That would make crosswind landings a lot easier, too!
You wouldn't need to roll the whole runway, mind you. All you need to do is have a plane-sized piece of runway, that travels along at the same speed of the plane, directly under the plane, as it lands. It would also help inexperienced pilots that don't know the layout of a complicated airport like O'Hare, because the "moving runway piece" could, in theory, take the plane all the way to the gate.

Proper Starboard and Port

He is coming right at you!!!

Wow, we are blind

and the walls are white

I too thought the port and starboard cushions were a nice touch, had also thought about using the airflow to spin the tyres up, hadn't thought about the gyroscopic effect effecting landing, so the puff of smoke lives to fight another day.

it's actually aquaplaning, so that's with one 'n'

@@nicksegers7768 It's a good thing this is an airplane channel because the joke flew over your head at flight level 380.

Also, maybe you can google the correct spelling of goggles.

@Ian Brown What's that got to do with it?

@Ian Brown Yes but on takeoff and because of debris on the runway.
So what they should be is to employ people with brooms to clean up the runway