Good to hear! We should never assume that we know everything of anything. This video was indeed quite intersting.

It seems to make more sense for me to realize the air being blown is sticky and grabs the air from the side tube and pulls it along. Mayne not correct but hey I'm just a regular joe

Yes, that’s a good way to think of it. It makes more logical sense to me the way you’ve described the ‘sticky air’. I’ll remember that.

This is literally what I study in Highschools. This principle is one of the basics.

Physics is the discipline where math proves common sense totally wrong.

The TV series Connections is superb, as well. I highly recommend it.

What, it pushes your balls together? (sorry; couldn't resist)

Unfortunatly, it is WRONG. Please make corrections or remove it. .. The statements about Bernoulli's Principle are correct, but the demonstrations are very poor. The balls, spoon and funnel are a result of the Coanda effect. . The tube inserted into the wall of the neck is protruding into the flow (seen at time 2:57) This causes the air to curve around the end and sides of the tube. This curved flow is the cause of the lowered pressure. This will work with no pipe around it; just the air blowing across the vertical tube. .. To correctly measure the static pressure inside your narrow neck, the end of hat tube MUST be flush with the inside surface. .. At time 4:51 we see that the two pressure sensing tubes appear to be more like flush, but it is difficult to see clearly. For that to truly sense the static pressures, there must be NOTHING protruding into and disturbing the flow.

Damb it you beat me to it lmao

And an air brush.

I thought it was a bong. But I ain’t that smart. 😂

Merge collector 😎

Syphon hose

But WRONG. The statements about Bernoulli's Principle are correct, but the demonstrations are very poor. The balls, spoon and funnel age a result of the Coanda effect. . The tube inserted into the wall of the neck is protruding into the flow (seen at time 2:57) This causes the air to curve around the end and sides of the tube. This curved flow is the cause of the lowered pressure. This will work with no pipe around it; just the air blowing across the vertical tube. .. To correctly measure the static pressure inside your narrow neck, the end of hat tube MUST be flush with the inside surface. .. At time 4:51 we see that the two pressure sensing tubes appear to be more like flush, but it is difficult to see clearly. For that to truly sense the static pressures, there must be NOTHING protruding into and disturbing the flow.

Comical. EVERY video on this topic has the exact same explanation: "narrower the pipe section, the lower the pressure" because equations . What happens is equations due to more equations . HOW does it work? By equations .

@@billshiff2060 Buddy, the equations explain exactly why this occurs. The velocity of the fluid increases as it travels from a wider region to a narrower region, as the work done by the fluid is down a pressure gradient. Therefore, the fluid must flow from a region of a higher cross-sectional area to a narrow cross-sectional area in order to increase its velocity, and this would naturally cause the pressure exerted by the fluid to decrease. Mathematical equations simply explain this phenomenon through variables instead of words.

@@weltschmerzistofthaufig2440 So your explanation is, it is caused "naturally" + equations. No mention of particle velocity, which IS the cause of pressure, is ~ mach 1.5 regardless of where it is and yet the pressure decreases in smaller passages.

@@billshiff2060 Are you saying that Bernoulli’s principle doesn’t work? I could use kinetic particle theory to explain it, but I instead focused on macroscopic observations and mathematical evaluation to explain this. Also, who told you that particle velocity remains the same? In fact, in a narrower section, the total number of collisions between particles and the container would decrease as the work done by the fluid occurs in the direction of movement. Thus, a pressure gradient must exist to ensure that there is an increase in kinetic energy in a narrower region.

@@weltschmerzistofthaufig2440 Who told you that particle velocity varies?

Kind of. The higher pressure on the outsides push the balls together. There's no "pulling".

Fantastic use of the word _thus._ 😄

A pressure difference in stead of a vacuum.

Yeah i think it's also due the the specific shape of the sphere.

it's not the vacuum that pulls the balls. You've said it: it's the atmospheric pressure that pushes them. __ for a 3 cm radius sphere we get about 1 N: P=f/A; f=PA = 101 Pa * 4Pir^2 =101*0.0113=~1 N

I love this!! ❤

ChatGPT?

Me, using ChatGPT 😄@@bindum7178

This felt like something straight out of Ace Combat. ❤

Yes, very obviously ChatGPT

I agree that the ball in the running water was not explained right or enough. But I think they meant that the change in the pressure of AIR around the running water causes the movement of the ball, not the pressure of the water. For some years now I have wanted to know why the spoon is pulled by the running water. And to me it looks like the curved shape plays the major role. I doesn't happen when you rinse a knife.

@@sylwiagotzman5422 Have a look at the video: Why are so many pilots wrong about Bernoulli’s Principle? by Fly with Magnar (kzbin.info/www/bejne/q6q1qWVrgriKpMk). IMO he explains quite well what you're describing, it is the same as for an airfoil. Spoiler: it is also Bernoulli's Principle, and has indeed to do with acceleration of the fluid at the convex part of the spoon

It's the Coanda effect, not Bernoulli's Principle, that pulls the spheres or spoons together in a liquid or gas flow. The experiment would not be able to be replicated with cubes instead of spheres.

What ? Hiwnplz

I mean how plz

I honestly hope nobody is watching this video for Education purposes. Because my soul died in the first 2 minutes

That name is popularly known by people. You can get the same equation by cancelling viscous terms and triple integrating Navier-Stokes' momentum equation. If I can do that, then it should be called the Navier-Stokes-Bernoulli equation, and it's not that A name is just that, a name, so people can easily recognize the equation

Glad you enjoyed it

that's hilarous

now this got my interest, you explained it better sir 👌

The exit or diffuser has been measured (not estimated) countless times to have increase in pressure, the negative peak of pr3ssure coefficient is at most right before it, if your brainstorm was close to right the entire racing industry would be incorrect.

That happens at supersonic speeds

This video is WRONG. The statements about Bernoulli's Principle are correct, but the demonstrations are very poor. The balls, spoon and funnel age a result of the Coanda effect. . The tube inserted into the wall of the neck is protruding into the flow (seen at time 2:57) This causes the air to curve around the end and sides of the tube. This curved flow is the cause of the lowered pressure. This will work with no pipe around it; just the air blowing across the vertical tube. .. To correctly measure the static pressure inside your narrow neck, the end of hat tube MUST be flush with the inside surface. .. At time 4:51 we see that the two pressure sensing tubes appear to be more like flush, but it is difficult to see clearly. For that to truly sense the static pressures, there must be NOTHING protruding into and disturbing the flow.

This video is WRONG. The statements about Bernoulli's Principle are correct, but the demonstrations are very poor. The balls, spoon and funnel age a result of the Coanda effect. . The tube inserted into the wall of the neck is protruding into the flow (seen at time 2:57) This causes the air to curve around the end and sides of the tube. This curved flow is the cause of the lowered pressure. This will work with no pipe around it; just the air blowing across the vertical tube. .. To correctly measure the static pressure inside your narrow neck, the end of hat tube MUST be flush with the inside surface. .. At time 4:51 we see that the two pressure sensing tubes appear to be more like flush, but it is difficult to see clearly. For that to truly sense the static pressures, there must be NOTHING protruding into and disturbing the flow.

Good analogy

You have to embrace pressure to reach your full potential.

You are right.

Finally someone pointed it out! There are so many misinterpretation regarding Bernoulli's Principle. It has rather strict assumptions for the fluid and the system (closed system, inviscid, incompressible, irrotational, no external force other than gravity etc.) and is not what people think it is. Another wide spread rumor is that lifting force of a plane can be explained by Bernoulli's Principle. It is so wrong that NASA specifically wrote an article titled "Incorrect Lift Theory" for it: www.grc.nasa.gov/www/k-12/VirtualAero/BottleRocket/airplane/wrong1.html Most videos claiming to be showing Bernoulli's Principle are NOT doing it under correct assumptions. Sigh.

Thank you for your effort, but you're assuming the surface is (or that it even could) pulling the air towards itself which is blatantly false, Coanda is a mere observation that air tends to follow the surfaces which is false as soon as flow separates, and it works on water because 1- surface tension and 2- water is much denser than air. All aerodynamics forces are pressure driven, like Newton on fluids, which is the correct way of visualising it.

​@@davidaugustofc2574, the Coanda effect also occurs with air (not just water) flowing over a curved surface, and is the reason for the spheres being pulled together with air flowing in between and for the sphere being pulled into the water flow. The same result does not occur if you use cubes instead of spheres. Those experiments do not exemplify Bernoulli's Principle, which applies to a single fluid flow. It is the pressure difference that causes the velocity difference, not the other way around.

@@mattcarter1797 My problem with the Coanda effect is that it is a gross oversimplification of the entire thing. You need to understand a little bit from several topics to understand what it really means, and those topics are more helpful than the conclusion. Air is mostly neutrally charged, as gas molecules usually are, so the external electron layers will repel each other, a gas would expand to Infinity if it had a chance and enough time. However, due to the local, gravitational effects from the Earth, the air is squeezed together, and the balance of those is the atmospheric (sometimes known as static) pressure. Gravity makes it so that pressure is very even for the same height all across the globe (temperature changes aside), so when a moving body is going through air and changing the pressure around itself, there will be a restoring force acting on the fluid to bring the new pressure value back to the original one. That is pressure will flow from high to low until there's negligible difference between the areas. When the air gets close the surface it's pushed away by the first layer, that's attached to the surface due to friction, and when the surface curves away from the direction of flow it forms low pressure pockets that will exert less force on the surface and nearby molecules that the air surrounding it, thus guiding the air towards the surface. (Greatly helps if you have a way of visualising it) And that's very simplified in it's own rights, since vorticity is a humongous topic on it's own, that I haven't even touched. I cannot understand how we're helping people by telling them about the Coanda effect and not the reasons behind it, you can't really learn anything from it. Okay, it was a great discovery for their time, but we're now at a stage where computers can generate airfoils from a set of requirements, we need to point out that air tends to follow surfaces and move on to deeper topics and not keep hanging on to it as explanation for anything.

Yes that was a mistake. The fluid is considered incompressible so no change in volume (capital V) occurs. Only changes in its velocity and pressure. Also the volume disappear entirely from the equation, as shown.

Now it's clear. Thank you very much for your generous activities.

👑for you my unsung hero

It's not true that faster air flow implies lower air pressure. Bernoulli's Principle only says that a faster section of flow within the same fluid flow must have lower pressure than a slower section within that same flow. If you stick your head out of a fast moving car and face forward, it should be easy to inhale.

"the lungs volume is wrenched from ones throat" Maybe the wind was pressing against your chest too and that forced the air out of your mouth.

It does an oil fire.