A spherical tank of radius 0.35m is half filled with oil of relative density 0.8. if the tank is moving with a horizontal acceleration of `10(m)/(s^(2))`. The surface of oil is at rest with respect to sphere. The maximum gauge pressure of oil in the tank is `nxx10^(3)Pa`, the value of n is approximately equal to (take `g=10(m)/(s^(2))`

A spherical tank of 1.2 m radius is half filled with oil of relative density 0.8 . If the tank is given a horizontal acceleration of 10 m//s^(2) , the maximum pressure on the tank is sqrt(2P) pascal. Find the value of P .

(a) A spherical tank of 1.2m radius is half filled with oil of relaive density 0.8 . If the tank is given a horizontal acceleration of 10m//s^(2) . Calculate the inclination of the oil surface to horizontal and maximum pressure on the tank. (b) The volume of an air bubble is doubled as it rises from the bottom of a lake to its surface. If the atmospheric pressure is H m of mercury & the density of mercury is n times that of lake water. Find the depth of the lake.

The velocity of kerosene oil in a horizontal pipe is 5 m//s . If g = 10m//s^(2) then the velocity head of oil wlill be

An open rectangular tank 1.5 m wide 2m deep ad 2 m long is half filled with water. It is accelerated horizontally at 3.27m//s^(2) in the direction of its length determine the depth of water at each end of tank.

A cylindrical tank having radius R is half filled with water having density rho . There is a hole at the top of the tank. The tank is moved horizontally. Perpendiular to its length, with a constant acceleration equal to the acceleration due to gravity (g). Find the maximum pressure exerted by water at any point on the tank. Atmospheric pressure is P_(0) . Assume that there is no spillage.

An iron ball of radius 0.3 cm falls through a column of oil of density 0.94 g cm^(-3) . If it attains a terminal velocity of 0.54 m s^(-1) , what is the viscosity of oil? Density of iron is 7.8 g cm^(-3)

A solid sphere of mass m=2 kg and density rho=500kg//m^(3) is held stationary relative to a tank filled with water. The tank is acceerating upward with acceleration 2m//s^(2) . Calculate (a) Tension in the thread connected between the sphere and the bottom of the tank. (b) If the thread snaps, calculate the acceleration of sphere with respect to the tank. (Density of water =1000kg//m^(3),g=10m//s^(2))

A solid sphere of mass m = 2 kg and specific gravity s = 0.5 is held stationary relative to a tank filled with water. The tank is accelerating upward with acceleration 2 m//s^2 . Calculate (a) Tension in the thread connected between the sphere and the bottom of the tank. (b) If the thread snaps, calculate the acceleration of sphere with respect to the tank. (Density of water = 1000 kg m^-3, g = 10 ms^-2 ). .