A cylindrical tank having cross-sectional area `A = 0.5 m^(2)` is filled with two liquids of density `rho_(1)=900 kg m^(-3)` and `rho_(2)=600 kgm^(-3)`, to a height `h=60cm` each as shown in the figure. A small hole having area `a=5cm^(2)` is made in right vertical wall at a height `y = 20 cm` from the bottom. A horizontal force `F` is applied on the tank to keep it in static equilibrium. The tank is lying on a horizontal surface. Neglect mass of the cylindrical tank in comparison to mass of the liquids (`ake g = 10 ms^(-2)`).

The velocity of efflux is

A cylindrical tank having cross - sectional area A = 0.5 m^(2) is filled with two liquids of density rho_(1)= 900 " kg "m^(-3) and rho_(2) = 600 " kg "m^(-3) , to a height h = 60 cm^(2) each.A small hole having area a=5 cm^2 is made in right vertical wall at a height y = 20 cm from the bottom . A horizontal force F is applied on the tank to keep it in static equilibrium . The tank is lying on a horizontal surfaces . Neglect mass of cylindrical tank camparison to mass of liquids ( take g = 10 ms^(-2) ) Horizontal force F to keep the cylinder in static equilibrium , if it is placed on a smooth horizontal thrust exerted by fluid jet . But that is equal to mass flowing per second xx change in velocity of this mass :. " " F = (avrho) (v-0) = a rho v^(2) or F = 7.2 N

A cylindrical tank having cross - sectional area A = 0.5 m^(2) is filled with two liquids of density rho_(1)= 900 " kg "m^(-3) and rho_(2) = 600 " kg "m^(-3) , to a height a = 6 cm^(2) is made in right vertical wall at a height y = 20 cm from the bottom . A horizontal force F is applied on the tank to keep it in static equilibrium . The tank is lying on a horizontal surfaces . Neglect mass of cylindrical tank camparison to mass of liquids ( take g = 10 ms^(-2) ) Minimum and maximum values of F to keep the cylinder in static just after the water starts to spill through the hole . If the co - efficient of static friction between contact surfaces is 0.01

A cylindrical vessel of a very large cross sectional area is containing two immiscible liquids of density rho_(1)=600kg//m^(3) and rho_(2)=1200kg//m^(3) as shown in the figure. A small hole having cross sectional area 5cm^(2) is made in right side vertical wall as shown. Take atmospheric pressure as p_(0)=10^(5)N//m^(2), g=10m//s^(2) . For this situation mark out the correct statement (s). Take cross sectional area of the cylindrical vessel as 1000cm^(2) . Neglect the mass of the vessel.

A vessel is filled with two different liquids of densities rho and 2 rho respectively as shown in the figure. The velocity of flow of liquid through a hole at height (h)/(2) from bottom is

Water is filled in a container upto height 3m. A small hole of area 'a' is punched in the wall of the container at a height 52.5 cm from the bottom. The cross sectional area of the container is A. If a//A=0.1 then v^2 is (where v is the velocity of water coming out of the hole)

A large vessel of height H is filled with a liquid of density rho upto the brim. A small hole of radius r is made at the side vertical face, close to the base. The horizontal force is required to stop the gushing of liquid is

A cube of 1 kg is floating at the interface of two liquids of density rho_(1) = 3//4 gm//cm^(3) and rho_(2) = 2.5 gm//cm^(3) The cube has (3//5)^(th) part in rho_(2) and (2//5)^(th) part in rho_(1) .Find the density of the cube .

A long cylindrical tank of cross-sectional area 0.5m^(2) is filled with water. It has a small hole at a height 50cm from the bottom. A movable piston of cross-sectional area almost equal to 0.5m^(2) is fitted on the top of the tank such that it can slide in the tank freely. A load of 20 kg is applied on the top of the water by piston, as shown in the figure. Calculate the speed of the water jet with which it hits the surface when piston is 1m above the bottom. (Ignore the mass of the piston)

Oil is filled in a cylindrical container up to height 4m. A small hole of area 'p' is punched in the wall of the container at a height 1.52m from the bottom. The cross sectional area of the container is Q. If p/q = 0.1 then v is (where vis the velocity of oil coming out of the hole)