A large open top container of negligible mass and uniform cross-sectional area A has a small hole of cross-sectional area A/100 in its side wall near the bottom. The container is kept on a smooth horizontal floor and contains a liquid of density `rho ` and mass ` m_0`. Assuming that the liquid starts flowing out horizontally through the hole at t = 0.
Calculate the acceleration of the container at `t = 0` :

A large open top container of negligible mass and uniform cross sectional area A a has a small hole of cross sectional area A//100 in its side wall near the bottom. The container is kept on a smooth horizontal floor and contains a liquid of density rho and mass M_(0) . Assuming that the liquid starts flowing out horizontally through the hole at t=0 , calculate a the acceleration of the container and its velocity when 75% of the liquid has drained out.

A large open top container of negligible mass and uniform cross sectional area A has a small uniform cross sectional area a in its side wall near the bottom. The container is kept over a smooth horizontal floor and contains a liquid of density rho and mass m_(0) . Assuming that the liqud starts flowing through the hole A the acceleration of the container will be

The velocity of the liquid coming out of a small hole of a vessel containing two different liquids of densities 2rho and rho as shown in the figure is

The velocity of the liquid coming out of a small hole of a vessel containing two different liquids of densities 2rho and rho as shown in the figure is

A liquid is flowing through a pipe of non-uniform cross-section. At a point where area of cross-section of the pipe is less, match the following columns.

A body of uniform cross-sectional area floats in a liquid of density thrice its value. The portion of exposed height will be :

A fixed container of height H with large cross-sectional area A is completely filled with water. Two small orifice of cross-sectional area a are made, one at the bottom and the other on the vertical side of the container at a distance H/2 from the top of the container find the time taken by the water level to reach a height of H/2 from the bottom of the container.

In the bottom of a vessel with mercury of density rho there is a round hole of radius r. At what maximum height of the mercury layer will the liquid still not flow out through this hole. (Surface tension = T)–

A container has a small hole at its bottom. Area of cross-section of the hole is A_(1) and that of the container is A_(2) . Liquid is poured in the container at a constant rate Q m^(3)s^(-1) . The maximum level of liquid in the container will be

A container of cross-section area A resting on a horizontal surface, holds two immiscible and incompressible liquid of densities rho and 2 rho as shown in figure. The lower density liquid is open to the atmosphere having pressure P_(0) . The pressure at the bottom of the container is