A massless conical flask filled with a liquid is kepth on t a table in a vacuum the force exerted by the liquid on the bse of the flask is `W_(1)`. Th force exerted by the flask on the table is `W_(2)`

Explain with a simple illustration that viscous force exerted in liquid.

A uniform chain of mass m and length l hangs on a thread and touches the surface of a table by its lower end. Thread breaks suddenly. Find the force exerted by the table on the chain when half of its length has fallen on the table. The fallen part does not form heap

A closed of length l containing a liquid of variable density rho(x)=rho_(0)(1+alphax) find the net force exerted by the liquid on the axis of rotation. (take the cylinder to be massless and A= cross sectional area of cylinder) (a). rho_(0)Aomega^(2)l^(2)[(1)/(2)+(1)/(3)alphal] (b). rho_(0)Aomega^(2)l^(2)[(1)/(2)+(2)/(3)alphal] (c). rho_(0)Aomega^(2)l^(2)[(1)/(2)+alphal] (d). rho_(0)Aomega^(2)l^(2)[(1)/(2)+(4)/(3)alphal]

Figure shows two flasks connected to each other. The volume of the flask 1 is twice that of flask 2 . The system is filled with an ideal gas at temperature 100 K and 200 K respectively. If the mass of the gas in 1 be m then what is the mass of the gas in flask 2

A uniform solid cylinder of density 0.8g//cm^3 floats in equilibrium in a combination of two non-mixing liquids A and B with its axis vertical. The densities of the liquids A and B are 0.7g//cm^3 and 1.2g//cm^3 , respectively. The height of liquid A is h_A=1.2cm. The length of the part of the cylinder immersed in liquid B is h_B=0.8cm . (a) Find the total force exerted by liquid A on the cylinder. (b) Find h, the length of the part of the cylinder in air.

A plate of area 2m^(2) is made to move horizontally with a speed of 2m//s by applying a horizontal tangential force over the free surface of a liquid. If the depth of the liquid is 1m and the liquid in contact with the bed is stationary. Coefficient of viscosity of liquid is 0.01 poise. Find the tangential force needed to move the plate.

Newton's laws of motion can be applied to a block in liquid also force due to liquid (e.g. upthrust) are also considered in addition to toher forces. A small block of weight W is kept inside. The block is attached with a string connected to the bottom of the vessel. Tension in the string is W//2 Q. If weight of the block is doubled then tension in the string becomes x times and the time calculated above becomes y times then

A tank is filled with a liquid upto a height H, A small hole is made at the bottom of this tank Let t_(1) be the time taken to empty first half of the tank and t_(2) time taken to empty rest half of the tank then find (t_(1))/(t_(2))

Newton's laws of motion can be applied to a block in liquid also force due to liquid (e.g. upthrust) are also considered in addition to toher forces. A small block of weight W is kept inside. The block is attached with a string connected to the bottom of the vessel. Tension in the string is W//2 Q. The string is cut. find the time when it reaches the surface of the liquid

A gun which fires small balls of mass 20 g is firing 20 balls per second on the smooth horizontal table surface ABCD . If the collision is perfectly elastic and balls are striking at the centre of table with a speed of 5 m//s at an angle of 60^(@) with the vertical just before collision, then force exerted by one of the legs on ground is (assume total weight of the table is 0.2 kg )