Awesome!

how do dampers switch the damping intensity/viscosity of fluid medium for fast vs slow bump, rebound. Is it possible to have a suspension that will be gentle on the drivers' bottoms (and allow for easier vision without porpoising shakiness) and still maintain stable aero platform (kinda like how f1 drivers would like the 2022 cars to be)?

Is it possible to run a high aero car very high off the ground and (highly) effectively use vortex generators to seal the underbody/tunnels/floor and also prevent rear tire squirt with the same vortex?

I should have put in some rod ends in bending for good measure

I wonder why they dont follow the same hydrolic system in motorcycles its just front vs back to control wheelies and endos It will be extremely simple for a motorcycle

Killed me 😂👌🏼 and never forget to put the pushrod to damper ratio to 1:10 or sth and have fun with loads and rideheight setup

@@FirstLast-tx3yj I strongly suspect that there are minimal gains on offer. By which I'm suggesting you couldn't increase the leverage required sufficiently enough to overcome the torque produced by a modern race bike anyway.

mclaren use it on his cars too. the supplier company is the american tenneco

@@AaaBbb-ff1pn I thought that McL makes everything in-house.

​@@jareknowak8712maybe they have a holiday home over there? Idk

I'm curious which degree do they learn about something this? Mechanical engineering? (I have no idea)

@@rizkiyoist AMZ is the Formula Student Team from ETH Zürich. They build prototype single seaters for the series. The team consists of students from different field and they have probably come up with it on their own (not sure)

I didn't understand any of that, but that probably means you have an advanced understanding of your subject material, and I can be glad there's another smart person somewhere in the world lol

@@rizkiyoist mechanical engineering will teach you how to create these systems but it just takes some clever person to think of such a incredible suspension idea

Got a link to that?

@@mixalisstathis274 it's the second video Kyle linked in the description.

On a 1 min 40 sec lap, 0.1% is one tenth. That's a pretty big chunk in F1.

​@@EmyrDerfel yeah, but not everything is formula 1 If I am building my own car, to race at a time attack, should I invest money in such a complicated design? Or should I spend the money on better aero? this is the kind of question would be nice to be answered. Not everyone has unlimited budget such as F1

www.researchgate.net/publication/242269184_MODE_DECOUPLING_IN_VEHICLE_SUSPENSIONS_APPLIED_TO_RACE_CARS The authors of this paper simulated a ~2006 F1 car with both traditional and mode decoupled suspension and found that over a 750 m sequence of short straights and 25m corners, the mode decoupled car was ~1 second faster, which amounts to about a 5% improvement. There were also clear benefits to platform stability.

@@satanaz I think the decoupling would have even greater benefits in a road car. F1 drives on extremely smooth surfaces (any motorsport that takes place on a track for that matter), and sure you get some mechanical grip benefits, but as another poster pointed out this is not hugely far from what Citroen introduced with the DS. it's all about controlling how the body mass behaves relative to the road, and today's roads in many places are extremely shit. The comfort benefit is hard to overstate.

@@satanaz Find a street legal and manual Cobra with the Pinto frontend and the Ford 9 rear axle. Overhaul suspension,add fox shocks with external reservoir, add stiffer swaybars and relocate Dedion downwards. Dry sump the SBC lower and move engine rearward by 5 inches and 3 inches down. Move tank forward and lower tank. 335/15 MT and 215/14 MT on Bassets. This gets you a though and durable chassis capable of hill climbs, slalom, drift, circletrack and, depending on gearing and engine HP, ...360kph or more topspeed, 2 secs 0-60 and 60000 miles between engine overhauls.

that's aero grip

While it is most likely superior how reliable would this suspension be? If X suspension lasts Y laps then failure and potential wreck granting DNF for race results. I bring this up as I admired the Citroen hydro-pneumatic suspension which you could remove a rim from the vehicle and it would sustain being level with wheel hub floating capable of being driven as is being freaky as hell. Yet, it was far from reliable and discontinued. The entire design Kyle detailed reminds me of the Citroen system.

@@Cerberus984 I guess it just depends on how robust you build it. The Electro-Hydraulic thing is just normal hydraulics, but using a more efficient electric pump instead of a purely mechanical one. Meanwhile, the harmonic dampers and linear dynamos are more of just useful add-ons than anything else.

Yeah, I misspoke a little sorry, pitch and heave coupling was definitely the bigger question! All good, I cover it anyway :)

@@KYLEENGINEERS Righto, explains it. Speaking of that, considering how different ends of most racing cars are used for different things (front does most of the steering and braking, rear does the accelerating), and how you usually end up with a stiffer front than rear (again, in racing cars, stiffer rear for "flat ride" in road cars being another subject entirely), would you say that splitting the pitch mode into specifically dive and squat would also be important? We'll leave lateral asymmetry out of this, since it usually isn't desirable in road racing, but is of course a big thing in oval stuff.

@@jubuttib To some extent you can control the squat/dive split in terms of damping, as it is effectively the bump and rebound of the pitch damper. You can also make the springing change through a dual rate/position sensitive springing system, so that all can be covered off in terms of mode there. Now aero requirements front/rear is a different kettle of fish, particularly if you're trying to maintain a low front ride but don't care so much for rear, and this would definitely be a struggle to tune with this specific system. But that's a full extra video worth of content!

@@KYLEENGINEERS Right. I was thinking more in terms of lower (or even no) aero cars, how for example the McLaren MP4-12C GT3 car on its main spring set (softest FIA homologated for the 2013 season, nominally 1000 lbf/in front and 1200 lbf/in rear) ends up with about 125 N/mm front springs and 90 N/mm rear springs when measured at the wheel, which translates to roughly 3.5 Hz at the front and 2.7 Hz at the rear (not taking into account the sway bars). The different requirements between wanting a responsive and sharp feeling front end with enough pliability in the rear to allow you to put the power down. Looking at a lot of GT3 and GT4 car setup sheets I tend to see them set up with something like 20-35% higher front frequencies than rear (before sway bars). Was thinking if this would be something to take into account when designing a fully decoupled suspension. FWIW I work with racing simulators. =)

@@jubuttib I'm not a suspension expert, so can't be 100% sure, but I would've thought those handling characteristics can largely be achieved using forwards pitch/rearwards pitch control and a bit of roll stiffness biasing to cover off the rest of the wheel rate difference. Beyond that I know that typically in most cars I've worked on that we've ended up with stiffer corner springs on the front that the rear to get the aero platform control right (essentially a per axle heave stiffness approach), as the front ride height is significantly more sensitive than the rear (and we want the rear to drop under higher aero load), but not sure how much that would play a factor in your simulation (hopefully plays some role!). Perhaps some more of my viewers who are more knowledgeable in suspension tuning than myself would like to chime in at this point?

He could have given that example, but the 2CV doesn't have the functionality desired.

is already on the market, with mclaren supply by american company tenneco. previously was brillianty use by citroen with their hydroactive system

hard to change up suspension mounting points mid race plus it puts more force on the suspension pickup points. best to us spring systems but if you cant then use geometry

They would be mounted to the chassis. I'm surprised I haven't seen anyone mention this, but Mclaren uses a VERY similar setup on their cars that are above the sports series (like the 720s). Many people say in comfort mode that it rides almost as smooth as a Rolls Royce, and stiffens right up whenever it's in track it sport mode. You can check out a video made by engineering explained where he explains it in detail.

yes, the Williams f1 car from the 90s is a good example of this but be aware pretty much every other team who try doing this cost the driver their lives.

Probably warp is beneficial for off road axle twist, and the pitch control and roll control would greatly benefit such vehicle on road driving dynamics to improve braking and cornering.

I think they started using it quite a long time ago and they still do.

Yeah, but that's prolly gonna change in 2022 with the tiny sidewall height tires

They used it to dampen the nose movement, but will get banned.

@@Sysiphus1981 why would it get banned?

@@fillman86 kzbin.info/www/bejne/qmabop2Zg9x4mNE

AFAIK, FRIC isn't fully mode decoupled.

After watching AMZs video their hydraulic circuits do not share fluid between different wheels so it makes sense now.

He talks about the need to fix it to remove "weird hydraulic interactions), but you're right - as it is illustrated here it just wouldn't work.

No.

Bose has done this before. They found that, while the ride quality of the car was amazing, it would be too heavy, too inefficient, and too costly/complicated to realistically implement in a car. The electromagnets would have to be quite powerful, meaning that they'd draw a lot of current. Maybe it could work better with assistance from some other device.

It would be tuned accordingly. So the damping and spring affect between the corners could be relatively light. It all depends on the type of car and conditions. I very high cog vehicle on rough terrain would benefit the most. I’d like to see a baja race car with and without it compared.

I would recommend the second half of the video

@@hunterhach7533 sorry, watching from offshore and only managed to get the first few minutes - 144p…

@@smellysam oh goodness, yes it can! :)

the fluid doesn't actually flow into the same reservoir in each cylinder, they are separated, i.e. you might have a cylinder with 4 chambers, pairs of 2 chambers are connected and each pair works against the other

@@bilaltariq7819 thanks!

it was banned around 2014. look at what is called the FRIC suspension

The hydraulic fluid won't have to flow very far and you want hydraulic fluid as you want to keep the expansion of the hydraulic lines down as the system would be harder to predict the needed spring rates. And possibly by the time the air starts to create enough pressure to move the piston it's too late. In sense the air is a spring and you don't want that, same as expansion of the hydraulic lines. You could possibly use valves to control the hydraulic fluid flow but it would lead to minimal gains if any. Active shock absorbers on each individual piston setup would be best but it's unclear how much of a gain it would give. Your are correct that suspension design is the most important thing but a torsion bar is just another spring and they use them in F1. You should have said torsion beam suspension which in that case you would be correct that it is not ideal. Williams has kept their suspension a secret in case active suspension resturns in case you didn't know and that's why there is no info on it. Some people believe it's close to what is called the FRIC suspension which was used until 2014.

that is gonna introduce active suspension system. the hydraulics system is reactive

My guess is there would need to be compressed gas reservoirs at both ends to accept the necessary displacement ?

You get your "head space" in the heave piston, which can always move up and down. All the other pistons lock up by design when they are pressurized on both sides, that's what allows each one to control only one mode: they will only move for the mode that creates unequal pressure in that piston. You don't want, e.g., the pitch piston to move under heave, you want 100% of that motion controlled by the heave piston alone. Under pure heave every other piston will remain stationary.

In the FSAE example he mentions at the end of the video, the plumbing is a little more complicated to prevent that from happening. It's way too complicated to explain in words but you can find a writeup here: blogs.mathworks.com/student-lounge/2018/02/01/hydraulic-decoupled-suspension-part1/

@@5thearth Thanks. It seems to be the reason why in the FSAE example the main cylinders for each mode have seperate fluid chambers for each connected wheel cylinder, even if they act in the same direction.

No. They are only dampers. Dampers can only affect transient response.

No, its totally passive. Active suspension had a pump that added energy to the system/fluid to control the attitude of the car. This is a passive system, the car still rolls and pitches as if it had springs, we are just using the hydraulic fluid to carry and/or redirect the loads going through the suspension.

Yes and no. It's not prohibited but the best ways anyone has thus far come up with to do it (hydraulics) have been prohibited.

1)the heave would still be ideal to in essence carry the cars weight. 2) it would be the same size to package as a conventional setup around the wheels but you are correct everything else can be moved around where there is space but it is best to minimize the length of lines as you would have less control from the expansion of lines.3) yes a single hydraulic piston of sufficient size and rated for the forces is all you need along with one line that would go to a distribution module where the other lines would be connected. so you would only have a single line from each wheel and then close to the pistons you have the distribution blocks where you would have mess of hydraulic lines to the proper pistons. currently only prototype vehicles use this as no professional series allows it and it is just too untested and costly for a road car as of right now.4) assuming you are using air springs and dampeners on the pistons it would just give you a different characteristic but i would be cautious of excess heat messing with your spring pressures. in sense regular springs are linear and follow F=K(x) where f is the force needed to compress X distance and K is the spring coefficient. Air follows a different trend where is easier to compress at first but as the pressure increases its spring coefficient dramatically stiffens. on a road car its better to stay with normal springs as they are easier to predict, but air suspension is big in off road where you want the wheels to articulate easily at first and to get much harder as they come to the end of travel so you don't bottom out. suspension geometry also does this especially using a cantilever suspension as the angles of the pushrod and the dampener can change the forces acting and being acted by the wheel. This is where you spend millions in engineering.

as far as I know they have no interlink front to rear, and basically just use the hydraulic system as an anti-roll bar.

yes and no as its not near as complex, if im correct they only connect the front and rear for pitch control. they also use valves at the top and bottom of the wheels dampener. the mclaren setup still doesnt control heave or really anything independently. he has a vid on his channel about the 720s suspension

@@jacksonblanks8038 thank you for clarification. I drove 720S, its ride is smooth as butter, nevertheless 😉

@@bartekb5074 yep it's suspension is very good for a road car. If possible try driving a real professionally built race car. There is nothing like it

@@jacksonblanks8038 I would love to!

Current F1 tires say Pirelli horizontally, not in an arc.