The vessel shown in the figure contains water, take `rho_("water")=1000kg//m^(2), g=m//s^(2)`). For this arrangement, answer the following questions:

The net force acting on the base of the vessel is

A cylindrical object of cork of mass 15 g and cross-sectional area A_(1) = 10 cm^(2) floats in a pan of water as shown in the figure. An aluminum, cylinder of mass 25 g and cross-sectional area A_(2) = 2 cm^(2) is attached 4 cm below the cork and slides through a watertight frictionless hole in the bottom of the pan. Take density of the cork, rho = 0.2 g//cm^(3), rho_("aluminium") = 2.7 g//cm^(3), g = 10 m//s^(2) . Based on the above information, answer the following questions. The length of the cork cylinder inside the water in equilibrium is

A cylindrical object of cork of mass 15 g and cross-sectional area A_(1) = 10 cm^(2) floats in a pan of water as shown in the figure. An aluminum, cylinder of mass 25 g and cross-sectional area A_(2) = 2 cm^(2) is attached 4 cm below the cork and slides through a watertight frictionless hole in the bottom of the pan. Take density of the cork, rho = 0.2 g//cm^(3), rho_("aluminium") = 2.7 g//cm^(3), g = 10 m//s^(2) . Based on the above information, answer the following questions. The tension in the string joining the cork and aluminium cylinder is

A cylindrical vessel of a very large cross sectional area is containing two immiscible liquids of density rho_(1)=600kg//m^(3) and rho_(2)=1200kg//m^(3) as shown in the figure. A small hole having cross sectional area 5cm^(2) is made in right side vertical wall as shown. Take atmospheric pressure as p_(0)=10^(5)N//m^(2), g=10m//s^(2) . For this situation mark out the correct statement (s). Take cross sectional area of the cylindrical vessel as 1000cm^(2) . Neglect the mass of the vessel.

In the arrangement as shown, tension T_(2) is (g=10m//s^(2))

A mass m of volume V=10cm^(2) is tied with a string to the base of a container filled with a liquid of density (P_(l)=10^(3)kg//m^(3)) as shown in the figure. The container is then accelerated with acceleration (a_(x)=9m//s^(2)) and (a_(y)=2m//s^(2)) a shown in the figure. [ g=10((m)/(s^(2))) acceleration due to gravity] the net buoyancy force acting on the mass is

In two identical communicating vessel we poured water (see picture). In one of them we put an ice ball of volume V=100 cm^(3) which gets exactly half immersed in the water. The density of water rho_(w)=1000kg//m^(3) the density of ice rho_(i)=900kg//m^(3) Select the correct statement (s). Soon after placing the ice ball in left vessel.

A solid cylinder of height h and mass m is floating in a liquid of density rho as shown in the figure. Find the acceleration of the vessel (in m//s^(2) ) containing liquid for which the relative downward acceleration of the completely immersed cylinder w.r.t. vessel becomes equal to one-third of that of the vessel. (Take g = 10 m//s^(2))

A solid cylinder of height h and mass m is floating in a liquid of density rho as shown in the figure. Find the acceleration of the vessel (in m//s^(2) ) containing liquid for which the relative downward acceleration of the completely immersed cylinder w.r.t. vessel becomes equal to one-third of that of the vessel. (Take g = 10 m//s^(2))

Three vessels A,B,and C of different shapes contain a water upto the same height as shown in the figure . P_(A) ,P_(B) ,and P_(C) be the pressure exerted by the water at the bottom of the vessels A ,B and C respectively . Then

A wooden rod weighing 25N is mounted on a hinge below the free surface of water as shown. The rod is 3m long and uniform in cross section and the support is 1.6m below the free surface. At what angle alpha rod is in equilibrium? The cross-section of the rod is 9.5 xx10^(-4)m^(2) in area. Density of water is 1000kg//m^(3) . Assume buoyancy to act at centre of immersion. g=9.8m//s^(2) . Also find reaction on the hinge in this position. .