Equal mass of three liquids are kept in three identical cylindrical vessels A, B and C. the densities are `rho_A, rho_B, rho_C with rho_Altrho_Bltrho_C`. The force on the base will be

Three liquids of equal masses are taken in three identical cubical vessels A, B and C. Their densities are rho_(A), rho_(B) " and " rho_(C ) respectively but rho_(A) lt rho_(B) lt rho_(C ) . The force exerted by the liquid on the base of the cubical vessel is

Three different liquids are filled in a U-tube as shown in figure. Their densities are rho_(1), rho_(2) and rho_(3) respectively. From the figure we may conclude that

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

A solid uniform ball having volume V and density rho floats at the interface of two unmixible liquids as shown in Fig. 7(CF).7. The densities of the upper and lower liquids are rho_(1) and rho_(2) respectively, such that rho_(1) lt rho lt rho_(2) . What fractio9n of the volume of the ball will be in the lower liquid.

A cubical block of steel of each side equal to 1 is floating on mercury in vessel. The densities of steel and mercury are rho_(s) " and " rho_(m) . The height of the block above the mercury level is given by

Equal masses of two substance of densities rho_(1) and rho_(2) are mixed together. What is the density of the mixture?

A thin uniform circular tube is kept in a vertical plane. Equal volume of two immiscible liquids whose densites are rho_(1) and rho_(2) fill half of the tube as shown. In equilibrium the radius passing through the interface makes an angle of 30^(@) with vertical. The ratio of densities (rho_(1)//rho_(2)) is equal to

A solid sphere having volume V and density rho floats at the interface of two immiscible liquids of densites rho_(1) and rho_(2) respectively. If rho_(1) lt rho lt rho_(2) , then the ratio of volume of the parts of the sphere in upper and lower liquid is

A wide vessel with a small hole at the bottom is filled with two liquids. The density and height of one liquid are rho_1 and h_1 and that of the other are rho_2 and h_2(rho_1 gt rho_2) . The velocity of liquid coming out of the hole is: