Water flows out of a big tank along a horizontal tube Ab of length L and radius R and bends at right angle at the other end as shown in the figure. Find moment of force exerted by water on the tube about the end A (Assume that the radius of the tube is small )

Water (density rho ) is flowing through the uniform tube of cross-sectional area A with a constant speed v as shown in the figure. Find the magnitude of force exerted by the water on the curved corner of the tube is (neglect viscous forces)

A tube in vertical plane is shown in figure. It is filled with a liquid of density rho and its end B is closed. Then the force exerted by the fluid on the tube at end B will be: [Assume the radius of the tube to be negligible in comparison to l]

Water flows out of a big tank along a tube bent at right angles, the inside of the tube is of radius r . The length of the horizontal portion is l . The rate of water flow is Q . Find the moment of reaction forces of flowing water, acting on the tube walls relative to point O .

Water flows out of a big tank along a tube bent at right angles, the inside radius of the tube is equal to r (figure). The length of the horizontal section of the tube is equal to l . The water flow rate is Q litres per second. Find the moment of reaction forces of flowing water, acting on the tube's walls, relative to the point O.

A liquid of density rho flows along a horizontal pipe of uniform cross-section A with a velocity v through a right angled bend as shown in fig. What force has to be exerted at the bend to hold the pipe in equilibrium ? .

Match the Moment of inertia of a solid cylinder of mass m, radius R and length l along various axis as shown in figure.

Water rises to a height h in a capillary tube lowered vertically into water to a depth l as shown in the figure. The lower end of the tube is now closed, the tube is the taken out of the water and opened again. The length of the water column remaining in the tube will be .

A glass tube of radius 0.8 cm floats vertical in water, as shown in figure. What mass of lead pellets would cause the tube to sink a further 3 cm ?

One end of a horizontal thick copper wire of length 2L and radius 2R is weded to an end of another horizontal thin copper wire of length L and radius R .When the arrangement is stretched by applying forces at two ends , the ratio of the elongation in the thin wire to that in the thick wire is

A rod AB of mass M and length L is shown in figure. End A of rod is hinged and end B is lying on the ground. Find the Horizontal component of the force applied by the hinge