A thin triangular glass tube containing immiscible liquids A, B, C of densities `rho, 2rho, 3rho` is at rest in vertical plane. Find x.

Find out pressures at point A and B . Also find angle theta . A zig zag tube open at n , having liquis of densities rho_(1), rho_(2) and rho_(3) is placed in a vertical plane as shown in figure. (The pressue at M is equal to atmospheric pressure).

A cylinder stands vertical in two immiscible liquids of densities rho and 2rho as shown. Find the difference in pressure at point A and B:

Two immiscible liquids of densities rho and 2rho and thickness (heights) h and 2h , respectively, push a vertical plate. Find the total side thrust given by the liquids on the vertical plate.

A triangular lamina of area A and height h is immersed in a liquid of density rho in a vertical plane with its base on the surface of the liquid. The thrust on the lamina 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 thin uniform tube is bent into a circle of radius r in the vertical plane. Equal volumes of two immiscible liquids, whose densities are rho_(1) and rho_(2) (rho_(1) gt rho_(2)) fill half the circle. The angle theta between the radius vector passing though the common interface and the vertical is :

A narrow U-tube placed on a horizontal surface contains two liquids of densities rho_(1) and rho_(2) . The columns of the liquids are indicated in the figure. The ratio (rho_(1))/(rho_(2)) is equal to :

A vertical pole of length l , density rho , area of cross section A floats in two immiscible liquids of densities rho_(1) and rho_(2) . In equuilibrium possition the bottom end is at the interface of the liquids. When the cylinder is displaced vertically, find the time period of oscillation.