A storage tower supplies water, as shown in the figure. If `P_(0)` is the atmospheric pressure h = height of water level, g = acceleration due to gravity, `rho=` density and v = velocity of flow in the horizontal pipe at B, then the pressure at B is -

The absolute pressure at a depth h below the surface of a liquid of density rho is [Given P_(a) = atmospheric pressure, g = acceleration due to gravity]

The pressure at a depth h in a liquid of density d is given by pressure = __ , where g is the acceleration due to gravity.

A small air bubble of radius r in water is at depth h below the water surface. If P_0 is the atmospheric pressure, rho is the density of water and T is the surface tension of water, what is the pressure inside the bubble?

A small air bubble of radius r in water is at a depth h ( r lt lt h ) . If P_(o) is the atmospheric pressure, rho is the density of water and T is the surface tension of water, the excess pressure inside the bubble over the pressure outside it is

According to Bernoulli's theorem (p)/(d) + (v^(2))/(2) + gh = constant is ( P is pressure, d is density, h is height, v is velocity and g is acceleration due to gravity)

The velocity of water wave v may depend on their wavelength lambda , the density of water rho and the acceleration due to gravity g . The method of dimensions gives the relation between these quantities as

A liquid of density rho is in a vessel rotating with angular velocity omega as shown in figure. If P_0 is the atmospheric pressure, find pressure at a radial distance r from the axis. .

A tube of uniform cross section is used to siphon water from a vessel V as shown in the figure. The pressure over the open end of water in the vessel is atmospheric pressure (P_(0)) . The height of the tube above and below the water level in the vessel are h_(1) and h_(2) , respectively. Determine the velocity v_(B) of the water issuing out at B .

A tube of uniform cross section is used to siphon water from a vessel V as shown in the figure. The pressure over the open end of water in the vessel is atmospheric pressure (P_(0)) . The height of the tube above and below the water level in the vessel are h_(1) and h_(2) , respectively. Given h_(1) = h_(2) = 3.0 m , the gauge pressure of water in the highest level CD of the tube will be

The resistance R to the motion of a ship depends on the velocity v of the ship, l the length of ship, rho the density of sea water and g the acceleration due to the gravity.Show that R is proportional to l^3 .