So the 1/2 factor is because ρ(b∆x∆z) is the weight of the whole cuboid and we need the weight of the only one half along the diagonal from upper left point to lower right point? Am I correct? Because if you place another identical triangular volume upside down on the already existing triangular volume, we get a cuboid. Right? So we include the 1/2 into get the desired area.Chestermiller said:
Yes. That's how we arrived at the equation in geometry for the area of a right triangle = (1/2) bh.andyrk said:
Pressure can only exert forces perpendicular to surfaces.andyrk said:
So what happens to the forces which are not perpendicular. They definitely exist. But then why aren't they shown in the diagram? If you say that they cancel out when we divide them into components, then we are assuming that they are of same magnitude. Otherwise they won't cancel out. But does this assumption have any basis?Chestermiller said:
andyrk said:
Yes. Where do these alleged forces come from?SteamKing said:
Pascal's Law states that pressure is exerted equally in all directions. This means that at a given depth of fluid, the static pressure produced by the fluid will be the same in all parts of the fluid's container.andyrk said:
That physical interpretation works great for an ideal gas, but not all fluids are ideal gases. For liquids, it might be less convincing to andyrk.Puma said:
SteamKing said:
Even if they exist on the atomic level, they cancel each other on average, because they are uniformly distributed in all directions parallel to the surface.andyrk said:
So why doesn't the perpendicular one also cancel out too? Why does it remain intact despite the fact that all others get completely canceled out?A.T. said:
Because along that axis the colliding molecules are all coming from one direction: from the fluid.andyrk said:
So along the opposite direction also the colliding molecules are coming from the fluid. There aren't any other particles in this other than the fluid.A.T. said:
No idea what you mean. You should draw yourself some diagrams. It's all quite obvious from geometry.andyrk said:
I don't think so. Hence the advice to draw a diagram, with forces from the fluid on a surface point, uniformly distributed along a hemisphere.andyrk said:
Hey, I think I get what you mean. The only area of contact is the wedge. That includes one side of all the 180 degrees where the forces could hit the wedge. The other 180 degrees don't matter because there isn't any area there (and since F = PA, therefore F = 0). But my question is, we assume that pressure is exerted equally in all directions. But this is what we set out to prove in the first place. Then how can we assume it?A.T. said:
Even if the force from a single collision had a component parallel to the wall, those parallel components from many collisions at the same point would average to zero, because they are uniformly distributed along all directions parallel to the wall.Tom_K said:
The vector always points perpendicular to the surface.
Pressure in a fluid is the force per unit area that is exerted by the fluid on its surroundings. It is a measure of how much force is being applied over a given area.
The pressure in a fluid can be calculated using the formula P = F/A, where P is pressure, F is force, and A is the area over which the force is applied.
Pressure in a fluid is caused by the random motion of molecules within the fluid. As the molecules collide with each other and with the walls of the container, they exert a force which results in pressure.
Pressure increases with depth in a fluid because the weight of the fluid above exerts a greater force on the molecules at lower depths. This results in an increase in the number of collisions and therefore an increase in pressure.
The direction of pressure in a fluid is always perpendicular to the surface it is exerted on. This means that it is directed towards the center of the object or container in which the fluid is contained.