A tube `1 cm^2` in cross- section is attached to the top of a vessel 1 cm high and of cross - section 100 `cm^2` Water is poured into the system filling it to a depth of 100 cm above the bottom of the vessel as shown in fig. Take g =10 `ms^(-2)` .

A cylindrical vessel open at the top is 20cm high and 10 cm in diameter. A circular hole of cross-sectional area 1cm^(2) is cut at the centre of the bottom of the vessel. Water flows from a tube above it into the vessel at the rate of 10^(2)cm^(3)//s . The height of water in the vessel under steady state is (Take g=10m//s^(2)) .

The area of base of a cylindrical vessel is 300 "cm"^2 . Water (density= 1000 "kg/m"^3 ) is poured into it up to a depth of 6 cm. Calculate the thrust of water on the base. (g = 10 "m s"^(-2)) .

In a hydraulic machine, a force of 2 N is applied on the piston of area of cross section 10 "cm"^2 . What force is obtained on its piston of area of cross section 100 "cm"^2 ?

The area of base of a cylindrical vessel is 300 "cm"^2 . Water (density= 1000 "kg/m"^3 ) is poured into it up to a depth of 6 cm. Calculate the pressure . ( g = 10 "m s"^(-2) ).

For a toroid N = 500, radius = 40 cm, and area of cross section =10cm^(2) . Find inductance

The area of base of a cylindrical vessel is 300 cm^(2) . Water ("density"=1000 kg m^(-3)) is poured into it up to a depth of 6 cm. Calculate : (a) the pressure and (b) the thrust of water on the base. (g=10ms^(-2)) .

An open vessel contains water upto height 50 cm in it. What is the velocity of efflux through an orifice at height 30 cm above the bottom level ? [Take g = 10 m//s^(2) ]

The level of water in a tank is 5 m high. A hole of area of cross section 1 cm^(2) is made at the bottom of the tank. The rate of leakage of water for the hole in m^(3)s^(-1) is (g=10ms^(-2))

A water hose pipe of cross-sectional area 5cm^(2) is used to fill a tank of 120L . It has been observed that it takes 2 min to fill the tank. Now, a nozzel with an opening of cross-sectional area 1cm^(2) is attached to the hose. The nozzel is held so that water is projected horizontally from a point 1m above the ground. The horizontal distance over which the water can be projected is (Take g=10m//s^(2)) .

The two femurs each of cross-sectional area 10 cm^(2) support the upper part of a human body of mass 40 kg. the average pressure sustained by the femurs is (take g=10 ms^(-2))