The vessel shown in the figure has two sections of area of cross-section `A_(1)` and `A_(2)`. A liquid of density `rho` fills both the sections, up to a height h in each. Neglect atmospheric pressure.

The vessel shown in the figure has two sections of areas of cross-section A _ 1 and A _2 . A liquid of density rho fills both the section, up to a height h in each. Neglect atmospheric pressure. Choose correct options.

The vessel shown in the figure has a two sections of areas of cross-section A_1 and A_2 . A liquid of density rho fills both th sections, up to a height h in each Neglect atmospheric pressure. Choose the wrong option. .

A liquid flows through a horizontal tube as shown in figure. The velocities of the liquid in the two sections, which have areas of cross-section A_(1) and A_(2) and v_(1) and v_(2) respectively. The differnece in the levels of the liquid in the two vertical tubes is h . then

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

A liquid flows through a horizontal tube. The velocities of the liquid in the two sections, which have areas of cross section A_(1) and A_(2) are v_(1) and v_(2) respectively. The difference in the levels of the liquid in the two vertical tubes is h . Then

The U -tube shown in the figure has a uniform cross section. A liquid is filled up to heights h_(1) and h_(2) in the two arms and they are allowed to move. Neglecting viscosity and surface tension, find the state of the liquid when the levels equalize in the two arms. Find the correct statement.

Some liquid is filled in a cylindrical vessel of radius R. Let F_(1) be the force applied by the liquid on the bottom of the cylinder. Now the same liquid is poured into a vessel of uniform square cross-section of side R. Let F_(2) be the force applied by the liquid on the bottom of this new vessel. (Neglect atmosphere pressure). Then

A metal sphere connected by a string is dipped in a liquid of density rho as shown in figure. The pressure at the bottom of the vessel will be, (p_(0) =atmospheric pressure )

A portion of a tube is shown in the figure. Fluid is flowing from cross-section area A_(1) to A_(2) . The two cross-sections are at distance 'l' from each other. The velocity of the fluid at section A_(2) is sqrt((gl)/(2)) . If the pressures at A_(1) & A_(2) are same, then the angle made by the tube with the horizontal will be:

A liquid of density rho is filled in a beaker of cross section S to a height H and then a cylinder of mass m and corss section s is made to float in it as shown in figure. It the atmospheric pressure is p_(0) , find the pressure a at the top face A of the cylinder b at the botom face C of the cylinder and c. at the base B of the beaker. Can ever these three pressures be equal?