Two identical cylindrical vessels with their bases at the same level each, contain a liquid of density `rho`. The area of either base is A but in one vessel the liquid heigth is `h_(1)` and in the other liquid height is `h_(2)(h_(2)lth_(1))`. If the two vessel are connected, the work done by gravity in equalizing the level is

Two identical cylindrical vessels with their bases at the same level each contain a liquid of density 1.30 xx 10^(3) kg//m^(3) . The area of each base is 4.25 cm^(2) , but in one vessel the liquid height is 0.854 m and in the other it is 1.560 m. Find the work done by the gravitational force in equalizing the levels when the two vessels are connected

Two identical cylindrical vessels have the same base area but are filled with different volumes of water . The forces on the bases of the two vessels are same .

Two identical cylindrical vessels are kept on the ground and each contain the same liquid of density d. The area of the base of both vessel is x_(1) and in the other, x_(2) . When both cylinders are connected through a pipe of negligible volume very close to the bottom, the liquid flows from one vessel to the other until it comes to equilibrium at a new height. The change in energy of the system in the process is :

A uniformly tapering vessel is filled with a liquid of density 900 kg // m . The force that acts on the base of the vessel due to the liquid is (g = 10 ms^(-2))

A uniformly tapering vessel of height h whose lower and upper radii are r and R is completely filled with a liquid of density rho The force that acts on the base of the vessel due of the liquid is

A conducting liquid is filled in a vessel of area of cross section A upto height h then resistance of the liquid is

A uniformly tapering vessel is filled with a liquid of density 900 km//m^3. The force that acts on the base of the vessel due to the liquid is (g = 10 ms^(-2))