It's rarely if ever the other way around. F1 is just the top level of open wheel racing, has nothing necessarily to do with pinnacle of automotive engineering.Vortex347 wrote:Shouldn't it be the other way round?
Aren't formula 1's supposed to be the pinnacle of automotive engineering? How come they're not using the latest and greatest?
I think you misinterpreted my statement.That statement is incorrect. Heavier cars do not absorb forces they create a bigger one to stop! Use the good ol physics formula f = ma. a heavier car has more mass so it creates a bigger force which means it is harder to stop! Why do you think a truck takes longer to pull up then a car does!
So really your adding weight in the form of absorbing masses to absorb the forces a car is subjected to when it hits a wall. But in doing that your increasing the force a car is subjected to in a crash because Force = mass * acceleration. Why don't you just remove the absorbing mass structures, this will make the car lighter and it will hit the wall with less force (a bearable amount for the strength of carbon fiber), so you don't need absorbing structures.
Key to surviving is indeed the acceleration rate. Lowering the acceleration rate is done by progressive failing structures usually conical in shape like the nose or the side impact cones. But I think in this discussion there is one dimension missing.turbof1 wrote: I think you misinterpreted my statement.
Let's first talk about why these absorbing structures are there and why they are so important to keep a driver alive during a crash. Let's go from a chassis without these structures: a very stiff structure which indeed is lighter. However, when it hits a wall, almost every bit of kynetic energy will be transferred to the driver's body (the so called G forces, or jut force going from the formula), just because the structure is that stiff it actually stays intact and the whole deal deaccelerates way too fast. I even like to take the example of Jules Bianchi in here (RIP, Jules), who suffered his severe brain damage due the instant deacceleration. This was caused by the fact the car was hit in a position with no crash structure.
However, with a crash structure you dissipate the force through lowering the deacceleration. these structures literally turn to dust and by that it reduces the deacceleration in a very controlled way. For instance let's take your formula:
F(1)=Ma(1)*A(1) --> let's take this for a car which has no crash structures.
F(2)=Ma(2)*A(2) --> Let's take this for a car which has crash structures.
Suppose the structures add 100kg on top of original 500kg car, but reduce the deacceleration from 10m/s² to 5m/s². This might sound illlogical since with you see is a car almost coming to a stop instantly in both cases. However what actually is happening is that the nose is vaporized and moving forward, again in a controlled way. Halving the deacceleration is actually an underestimation.
So:
F(1)=500kg*10m/s²=5000
F(2)=600kg*5m/s²=3000
In this instance the added weight made the structure safer, and I did not broke physics in any way. The mistake you made is assuming that mass is just mass, while the type of mass has a direct impact on acceleration.
I don't think this is what actually happened.... if you watch a backshot video link here:turbof1 wrote:I even like to take the example of Jules Bianchi in here (RIP, Jules), who suffered his severe brain damage due the instant deacceleration. This was caused by the fact the car was hit in a position with no crash structure.
You're not considering very many variables here! Sandpits are generally present on all high speed corners and a lighter car will not have as much momentum. p = mv or momentum = mass*velocityturbof1 wrote:Suppose the structures add 100kg on top of original 500kg car, but reduce the deacceleration from 10m/s² to 5m/s². This might sound illlogical since with you see is a car almost coming to a stop instantly in both cases. However what actually is happening is that the nose is vaporized and moving forward, again in a controlled way. Halving the deacceleration is actually an underestimation.
So:
F(1)=500kg*10m/s²=5000
F(2)=600kg*5m/s²=3000
???turbof1 wrote:However what actually is happening is that the nose is vaporized and moving forward, again in a controlled way.
The cars are designed to fall apart anyways without all this added weight.... This has been in effect since the 80's and is the reason why the body of the car is made from a larger number of pieces.Edax wrote:Bottom line. If you have a survival cell of 150kg it does not matter whether the rest of the car is 500kg or 1000 kg. If it breaks off at first impact it does not contribute to the survival rate of the driver. So it is very dodgy to lay a relation between car weight and safety.
Little to do with that. When carbon fibre chassis were introduced by mclaren, there was indeed this fear. It however turned out you could manipulate the layering. For instance the survivall cell will stay intact to keep the driver safe from any objects penetrating it. And no, the vaporizing at the front during the crash has not always happened. Only since a front crash structure has been introduced.This is because the nose is made from carbon fiber. Furthermore, this has always happened to the front of the car since carbon fiber was first used in the f1 cars in the early eighties (benefit of constructing the car from that material really).
No Edax is right. A F1 engine for instance will remain attached to the chassis since it's a stressed member of the car, even during a crash. Whatever that falls off is not out of safety, but to safe weight to reinforce it. With the exception of the crash structures of course, which has sideway tests it doesn't fall off (which was a very valid point from Edax, because if it does fall off it will not have an impact anymore on the survival rate).The cars are designed to fall apart anyways without all this added weight.... This has been in effect since the 80's and is the reason why the body of the car is made from a larger number of pieces.
A sandpit will limit the impact in both cases. I don't know you want to bring this is into the equation since this has nothing to do with the structure of a car. Whether you have 5000vs3000 force or 2500vs1500 force. I don't know why you include those variables since they they simple do not matter in the debate of crash structures vs no crash structures. A crash structure will in the end of the day be extra weight since it has mass, but makes the car much safer. Don't ask me, just compare crashes from earlier era's vs nowadays. Also, do know that a lighter car with the same horsepower will have a higher speed, so a higher velocity.You're not considering very many variables here! Sandpits are generally present on all high speed corners and a lighter car will not have as much momentum. p = mv or momentum = mass*velocity
I disagree, but I don't want to drag that part of the discussion any further out of respect for Jules.I think you'll find his head hit the back of the loader actually
So you're proposing to use the driver as a safety catch for the engineturbof1 wrote: @Edax: Do note that while a car shedding mass during a crash is generally, not always due the open cockpit, safer for the driver, it is not for others in close proximity of the car. A sharp piece of carbon fibre being flung into a grandstand would be a nightmare. It's this very same reason why tyres have to remain attached to the monocoque through tetters. It'll still dissipate quite a bit of energy in the tyres since they can still bounce, twist and rotate around, but they remain attached to the survival cell. Together with the engine, which is a stressed member of the car. It's comes with quite a bit of irony in this debate since the engine is part of the chassis solely to safe overall weight. If it were to detach, I think other structures would need to be reinforced first thus adding weight. Which as you explained would infact be safer since the kynetic energy from the engine would no longer play a role. Again only for the driver since nobody can predict what'll happen with the engine.
It sounds cruel if you put it like thatSo you're proposing to use the driver as a safety catch for the engine
. No I am not proposing any of the sort.carbon fibre fragmenting and apparently turning to dust is showing that it has a very low fracture workturbof1 wrote: ....... We already talked about carbon fibre almost literally vaporizing and being a good material for crash structures (if properly layered of course).
What I think F1 is looking at is at high speed impact testing of nose cones etc.Tommy Cookers wrote:carbon fibre fragmenting and apparently turning to dust is showing that it has a very low fracture workturbof1 wrote: ....... We already talked about carbon fibre almost literally vaporizing and being a good material for crash structures (if properly layered of course).
the rules require a crash structure around the driver that includes fibre with very high fracture work
