A liquid of density p is coming out of a hose pipe of radius a with horizontal speed `upsilon` and hits a mesh . 50 % of the liquid passes through the mesh unaffected . 25 % comes back with the same speed .The resultant pressure on the mesh will be:

An engine pumps a liquid of density 'd' continuously through a pipe of area of cross-section A. If the speed with which the liquid passes through a pipe is v, then force exerted on liquid.

An engine pumps liquid of density ρ continuously through a pipe of cross-section area A. If the speed with which liquid passes through the pipe is v, then the rate at which kinetic energy is being imparted to the liquid by the pump is

A liquid of density rho is flowing with a speed V through a pipe of cross sectional area A. What force does the liquid stream exert on wall in x direction if it splashes in the form of a circle after it hits the wall?

A liquid of density rho is filled in a vessel up to height H and a hole of cross section area A is made at a depth h below the free surface of liquid. The speed of liquid coming out of the hole is independent of

A stream of a liquid of density p flowin horizontally with speed v rushes out of a tube of radius r and hits a verticla wall nearly normally. Assumi g that the liquid does not rebound from the wall, the force exerted o the wall by the impact of the liquid is given by

A horizontal jet of water coming out of a pipe of area of cross - section 20 cm^(2) hits a vertical wall with a velocity of 10 ms^(-1) and rebounds with the same speed. The force exerted by water on the wall is,

A cylindrical tube with a frictionless piston ends in a small hole of area of cross–section 2xx10^(-6)m^(2) , which is very small as compared to the area of cross-section of the tube. The tube is filled with a liquid of density 10^(4)kg//m^(3) . The tube is held horizontal and the piston is pushed at a constant speed so that liquid comes out of the hole at a constant rate 'Q' m^(3)//s . No liquid leaks around the piston. The material of the tube can bear a maximum pressure 6xx10^(5) Pa. The maximum possible value of Q so that the tube does not break is __________ xx10^(-5)m^(3)//s . [Atmospheric pressure = 10^(5) Pa]

Artificial satellites go round the earth in their respective orbits. Astronauts are able to float in side the satellite. Inside space of the satellite could be treated as gravity free space. If a beaker filled with a liquid upto height h having a small hole in the bottom is placed in such a satellite, you will wonder te liquid does not come out of the hole. You have to squeeze or force the liquid to come out. suppose a constant pressure p is applied on the liquid through piston to force it out through the hole. Out side pressure could be neglected in comparison with p Cross-sectional area of beaker is too greater than that of hole (Agtgta)

A bus can be stopped by applying a retarding force F when it is moving with speed v on a level road. The distance covered by it before coming to rest is s . If the load of the bus increase by 50% because of passengers, for the same speed and same retarding force, the distance covered by the bus to come to rest shall be

In the adjacent figure a cylindrical vessel of mass M and cross - sectional area A is placed inverted on a fixed smooth piston of same cross - sectional area fixed to the ground . The space between the cylinder and priston is completely filled with liquid of density rho . There is a small office of cross - sectional area a ( a lt lt A) at the top top portion of this vessel . ( intially length of the liquid column in the vessel is H ) Speed of the liquid with which it comes out of the vessel is