striphe said:
Water is then forced out of this hose, by running a rolling pin from the stitched end to the nozzle. As the water runs through the hose, does the decrease in pressure reduce the volume of the hose and assist in forcing water out of the hose?
In the initial state, the pressure of the water is slightly higher than ambient depending on how high the water level in the nozzle is compared to the water in the hose. This would correspond to the gravitational potential component (density x gravity x height) in Bernoulli's equation. The rolling pin increases the pressure a bit in front of it, just enough to overcome friction and viscosity required for the water to flow up and out of the nozzle. The pressure behind the pin would be ambient, since the only force on the hose would be ambient pressure from the air (unless internal forces in the hose caused it to retain some non-flat state which would result in slightly lower than ambient pressure).
striphe said:
I remember years and years ago in a school experiment blowing air through a straw and having two balloons move towards each other.
See similar experiment:
That could also be explained by coanda effect. Because of friction and viscosity. The flow going between and then around the far side of the balloons remains attached for a brief moment on the aft surfaces, and is diverted outwards, resulting in the balloons exerting an outwards force on the airstream, coexistant with that air stream exerting an inwards force on the balloons, causing them to converge.
Although mis-labled as Bernoulli effect, this video demonstrates Coanda effect, you can clearly see the water stream is diverted to the left, which means the ball (and string) exert a left force on the water, coexistant with the water exerting a right force onto the ball (and string).
But isn't the pressure different in different directions.
Static pressure is independent of direction. It's the pressure that would be sensed by an object inside of the stream moving at the same velocity as the stream (like a hovering balloon in a wind). Dynamic pressure occurs when the speed of the air is changed. In the case of a pitot tube, the relative air flow is accelerated (or decelerated) to the speed of the pitot tube, and the change in momentum causes the pressure inside the pitot tube to be higher if oriented into the direction of the wind. Similarly the pressure just aft of a moving bus will be lower than ambient.
It is possible to sense static pressure with a static port oriented perpendicular to a relative air flow, but that static port has to be flush mounted on a flat surface, and be hiding in a shear "boundary layer" where friction and viscosity create a thin zone (the shear boundary layer) where the air flows at zero relative speed at the surface and increases in speed with distance from the surface. By definition the outer part of the shear boundary layer occurs when the relative speed is 99% of the relative speed between the unaffected air stream and the flat surface.
If an open ended tube is oriented perpendicular to an air flow, the air flow is diverted away from the open end of the tube, creating a vortice and reducing the pressure at the opening of the tube. Carburetors will often use a 1 or 2 stage venturi section combined with a tube protuding into the inner venturi pipe so it's open end is perpendicular or aft of the air flow in the venturi pipe to take advantage of this effect. Some sprayers, such as the old hand pump Flit Gun (insecticide sprayer) use this principle also.
