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Let's say there's a string connected to the tail of the plane. The instant (remember, I said no lag in the control system) the plane starts moving forward, it tugs on the string. As soon as the treadmill detects the string tug, it starts moving forward until there's no tugging. (this all happens instantaneously, or there's a good predictive algorithm that rapidly adjusts for dynamic fluctuations in string tension.)Quote:
Originally Posted by DJSapp
If the forces aren't matched the plane will accelerate and not maintain position on the treadmill.Quote:
Originally Posted by Big Blue
Then plane moving has nothing to do with imperfections in the control system. The plane moves forward with respect to a fixed point (say a tree on the edge of the runway). The runway moves backward at an equal speed. So, as the plane is doing 50 mph with respect to the tree, the runway is doing negative 50 mph with respect to the tree. So the wheels are spinning at 100mph. The fact that the wheels have to spin a little faster doesn't mean that the plane can't take off.Quote:
Originally Posted by Cornholio
This is true.Quote:
Originally Posted by cj001f
In all reality, as I read and re-re-read the problem, it's stated too poorly to decide anything.
But, as I read it, the treadmill functions to make the plane's velocity, relative to the control tower, zero.
I feel like I'm taking crazy pills. This is so mind-bogglingly retarded. I've completely lost respect for some individuals here.
What this thread needs is a big snapper.
http://adv.alsscan.com/alsscan/tya5/trish179.jpg
So have weQuote:
Originally Posted by Big Blue
Quote:
Originally Posted by Big Blue
There are too many unstated vaiables, ie: weight of the plane, power generated by the engines, frictional resistance between the wheels of the plane and the conveyor belt, whether or not there is an instantaneous reaction by the belt, etc.
Beaver's got it all correct, absolutely. Everyone who says, oh try jumping on a treadmill and see what happens when speeds change is missing the fact it is the friction force of your feet to the treadmill that will send you flying backwards.
The only contact the jet has to the treadmill is wheels that spins essentially freely and without friction (relative to the massive thrust force the jet can generate). Apply X million pounds of force to something that can roll freely and it will move. The only change that occurs by being on a treadmill that rolls backwards at same speed the jet moves forwards is that it's wheels will spin at double speed.
Oh my god, some of you are really fucking stupid. :nonono2:
Quote:
Originally Posted by DJSapp
I've only read up to DJ's post and I don't have any time to read any further right now. But...
My physics prof would have ripped everyone, who posted up to this point, a new one for even attempting to answer a question without having enough information to answer it. Too many assumptions, too many unknowns. DJ has provided examples that do have enough information to come up with an answer.
That is all.
This conveyor has a control system that tracks the planes speed and tunes the speed of the conveyor to be exactly the same (but in the opposite direction).Quote:
Originally Posted by Cornholio
It says nothing about making the speed zero. the plane has to have some velocity for the treadmill to have a velocity. If the plane stays still, the treadmill doesn't move.
C'mon, Beav - this thread beat any of the Ogre threads to hell and now I can't participate...
Seconded. I've only made one post and I give up already.Quote:
Originally Posted by Big Blue
I dunno, it took the Science Teachers forum 133 pages :nonono2:Quote:
Originally Posted by MeatPuppet
Forward Force doesn't produce lift; airflow over the wing does. You need to be moving relative to the air to acheive lift. As long as the plane is never moving relative to the air (and if it's on a treadmill, it's position is stationary) it has no lift - it stays on the ground. It's speed relative to the treadmill will approach the speed of light/failure speed of the treadmill because there is no friction, BUT IT WON'T FUCKING TAKE OFF!
Heh.Quote:
Originally Posted by MeatPuppet
I think you'll find that you never have all the information you need to solve a problem. Assumptions are the only way we find the mathematical approximations that we do.
Beaver is right. I had to think about it for a bit. Imagine a 3 wheeler with the front (middle, non-drive) wheel on a treadmill and two rear wheels (drive wheels) on the regular ground.
You need to be moving relative to the air to acheive lift. As long as the plane is never moving relative to the air (and if it's on a treadmill, it's position is stationary) it has no movement relative to air. Therefore no lift - it stays on the ground. It's speed relative to the treadmill will approach the speed of light/failure speed of the treadmill because there is no friction, BUT IT WON'T FUCKING TAKE OFF!Quote:
Originally Posted by mcsquared
There's no need to yell.Quote:
Originally Posted by cj001f
It's just a different reading of the problem.
I think it's all relative to the stationary object, like the control tower.
They think differently. (although I still don't see what they're measuring speed against.)
The more I think about it, the more feasible Beaver's assessment of this problem seems to be. Imagine if the treadmill were rotating in the opposite direction, it wouldn't make it any easier to take off (assuming 0 friction in the wheel bearings). The plane would just sit motionless on the treadmill until it throttled up at which time the jets would push against the air causing it to move forward until eventually reaching takeoff speed.
:rolleyes:
Lets think about this for a second... If you have EVER studied the premise on which modern airplanes manage to stay in the air you know that it is due to the shape of the wing. The straight bottom of the wing creates high air pressure whilst the rounded top of the wing creates low pressure because the air takes longer to get over it. Without airflow, that bitch is going no where. Unless of course you strap an ariane 5 to it :eek:
Since there is no air flow over the wing (which, btw is what an airplane requires to takeoff, not just thrust. That's also why gliders fly!!!) You are technically doing the same thing as parking a 747 at the start of a run way and flicking the thrust onto max, is the plane gonna take off right then and there? nope. It needs to get up to a FORWARD MOVING speed so that there is enough airflow over the wing to create lift. unless we are talking rocket or space-shuttle type thrust on the 747 (which it simply does not have, sorry) it still needs to roll. And if you COULD theoretically get the conveyor belt to work, don't you think that your local international airport would have implemented that already (or at least Japan)?
Here's your sign.
OK, this doesn't make much sense.Quote:
Originally Posted by belgian
We all agree that if there's no airflow (forward velocity) then there's no takeoff.
The question is if there's forward velocity.
I say no, because that's how I read the problem.
clap clap clap clap clap clap,Quote:
Originally Posted by SnowRider4Life
and for the people that think that the plane will not take off, what are the JET engines pushing against?
that is the treadmill pushing against?, no its not the plane.
this question has caused so much chaos all over the internet, im glad it is doing the same here.