Yes, at the point of impact. The dust probably doesn't tell us if it is the bottom of an anticlockwise vortex (viewed from the front) flicking the dust up and outward (like a cyclone vacuum cleaner) , or a simple outward jet.n smikle wrote:Richard you said the exhaust kicks up the dust(and as seen in the video), So can we all agree that the initial velocity of the gas is outwards and away from the car?
Yepn smikle wrote:Richard you said the exhaust kicks up the dust(and as seen in the video), So can we all agree that the initial velocity of the gas is outwards and away from the car?
n smikle wrote: OK.. so, this is a two part problem...
1) Proving that the exhaust gasses can turn such a tight radius - From pipe exit at 600mph at a trajectory of say 30 degrees, then in about 1 meter distance it turns back under the car..
(It has to turn because there is irrefutable proof that it is shot out sideways from the car)... Sounds crazy already.. but it can be worked out.
It's not even close. Not a good example.shelly wrote:I think the bullet example is good even if we do not take into account reversed flow. It shows that the gases do not reach as far as the bulet. It is the same as the feather- ball example I posted.
I think you can not disagree that heavy and light particles have different trajectories in a flow field.
Draw it please. Which trajectory does it take. Trajectory is different than magnitude of trajectory. The dust follows the gas, which in fact goes further than the dust because of the magnitude of the velocity.shelly wrote:Let us break the argument.
Do dust go under the diffuser? No
Do exhausts and dust follow the same trajectory? No (maybe only ringo has not got it yet)
Where do exhausts go? We can discuss it, but dust gives very little answer to this question
I have understood the push-pull issue, which is blown away (pun!) if we consider negative relative pressure (so the vaccum cleaner example fits)
shelly wrote:I think the bullet example is good even if we do not take into account reversed flow. It shows that the gases do not reach as far as the bulet. It is the same as the feather- ball example I posted.
I think you can not disagree that heavy and light particles have different trajectories in a flow field.
What is the goal in that case. Tell me.malcolm wrote:1) My stance isn't that the diffuser is some mega-powerful super-vacuum that sucks marshals' hats off their heads as the car drives by.
2) People are saying that dust will follow the air/exhaust stream precisely. I disagree, as it's impossible since the air/exhaust is what is propelling said dust.
3) Even looking at those photos, ignoring the potential effects of turning, inertia of dust particles, drag forces experienced by dust particles, etc, the inner part of the exhaust stream may still end up going under the diffuser (maybe 5%...?). Sure, the majority may shoot wide of the car, but since the exhaust stream widens as it mixes with the cross-flowing air, it's not some far-fetched miracle that some exhaust could end up being drawn under the diffuser.
Also, Ringo, your jokes aren't very obvious (to me, at least), and more often than not, it seems more like an insulting sarcastic comment than a joke. Just my two cents.
Richard here is a straight:richard_leeds wrote:My first thought on seeing the video is that the car is turning, the exhaust is kicking up the dust, and we are looking at a trace of the car's path around that bend.
We can't discount that the car is turning. The exhaust kicks up some dust, the car travels forward and turns right, so the point at which the dust is kicked up is then offset to the side of the car.
There is also some merit in the water splash analogy. The initial impact of the exhaust would be outward. However, would the dust continue on that path if the exhaust formed a vortex down the edge of the car? Is it reasonable to expect the dust to form a nice vortex like smoke in a wind tunnel, or would the dust kick up and get flung out as the vortex hit the ground?
Finally, how long had the dust lain there? Had it previously been stored in a bucket, open to the damp sea air?
ringo wrote:shelly wrote:I think the bullet example is good even if we do not take into account reversed flow. It shows that the gases do not reach as far as the bulet. It is the same as the feather- ball example I posted.
I think you can not disagree that heavy and light particles have different trajectories in a flow field.
ringo, do you read others' post or do you just reread yours? Dust is blown outward, while gases are inward. I have written it several times and all the others here agree on that.
The fact that gas and dust mix does not imply they have to stick together forever.
That pretty much closes the dust issue, leaving open the discussion on trajectory. What do you mean by "magnitude of trajectory"?
The probelem seems that you have not realized that whta you put forward as proof of your points on trajectory lend themseles to strong objections for which you have not given answer (maybe because is not there).
You call for dust and rain patterns as proof, but they are too heavy so they are not; you call for opticla distortions due to density, but they can not be visible under the shadow of the floor; you post cfd picture, but this level of detail is beyond what can be realised with homemade cfd.
So you can not rely on these things as evidence to prove your point; you should try something differnt, like smikle is doing. For exampleasking for evidence abot where does th outward momentum of the exhausts go, and expecting it to go outward if there s not some force to nullfy it and invert it. And so on.
Don't think you should add speed of exhaust to the speed of the car. Along the axis of the car they subtract, perpendicular to the axis it doesn't change (at least at the straights).n smikle wrote:Ok, honestly I think the theory of the gasses curling under is not realistic, but I am open minded and I created this diagram for you and the supporters of the diffuser sucking in the air. You figures, i am not sure what they are based on, but put it on this diagram.. maybe a momentum diagram if you want.
I am working the maths and I will try to fill it out.. I will see I can come up with a net force needed to bend the gas, which is going 315 m/s, within a radius of about 3 meters...
That is the whole deal.malcolm wrote: So what do I think? Probably an attempt at an elegant solution to increase downforce by creating a diffuser effect behind the leading edge of the splitter and front of the floor, lowering drag by filling in the wake of the front wheel, and a bit of that exhaust either ends up going through the diffuser, or it heats up some of the air that goes under it.
shelly wrote:
ringo, do you read others' post or do you just reread yours? Dust is blown outward, while gases are inward. I have written it several times and all the others here agree on that.
2 things can move along the same exact line and not have the same displacement or speed. Differing magnitudes.That pretty much closes the dust issue, leaving open the discussion on trajectory. What do you mean by "magnitude of trajectory"?
No shelly it's proof. Don't try to downplay it. There have been no strong objections. In fact I am yet to see any thing put on the table that adds up.The probelem seems that you have not realized that whta you put forward as proof of your points on trajectory lend themseles to strong objections for which you have not given answer (maybe because is not there).
They are not too heavy. Only by your standard. That homemade CFD just silenced many know it all journalists. So much so they can't show their face in the thread again.You call for dust and rain patterns as proof, but they are too heavy so they are not; you call for opticla distortions due to density, but they can not be visible under the shadow of the floor; you post cfd picture, but this level of detail is beyond what can be realised with homemade cfd.
Smikle isn't doing anything different. He's just giving you a chance to expose your reasoning. He well knows the solution.So you can not rely on these things as evidence to prove your point; you should try something differnt, like smikle is doing. For exampleasking for evidence abot where does th outward momentum of the exhausts go, and expecting it to go outward if there s not some force to nullfy it and invert it. And so on.
The Renault team have said the exhaust blow the floor. I know you all think that's to throw everyone off, but In the picture it looks like the exhaust and mist go back under the car to me.ringo wrote:Richard here is a straight:richard_leeds wrote:My first thought on seeing the video is that the car is turning, the exhaust is kicking up the dust, and we are looking at a trace of the car's path around that bend.
We can't discount that the car is turning. The exhaust kicks up some dust, the car travels forward and turns right, so the point at which the dust is kicked up is then offset to the side of the car.
There is also some merit in the water splash analogy. The initial impact of the exhaust would be outward. However, would the dust continue on that path if the exhaust formed a vortex down the edge of the car? Is it reasonable to expect the dust to form a nice vortex like smoke in a wind tunnel, or would the dust kick up and get flung out as the vortex hit the ground?
Finally, how long had the dust lain there? Had it previously been stored in a bucket, open to the damp sea air?
This a snap shot from the car moving straight for quite a while.
Ringo, take some time to consider what Shelly actually means. You briefly read what is said, jump to a conclusion, and then begin arguing without taking a moment to consider that what was said may actually mean something else.ringo wrote:shelly wrote:
ringo, do you read others' post or do you just reread yours? Dust is blown outward, while gases are inward. I have written it several times and all the others here agree on that.
This is not possible IMO. I've asked you to sketch how it is possible and you have not responded. Ever used a leaf blower to blow dust?
It would be a useless tool if the dust went the opposite of the blowing direction.
