Two `U-`tube manometers are connected to a same tube as shown in figure. Datermine difference of pressure between `X` and `Y`. Take specific gravity of mercury as `13.6. (g = 10 m//s^(2), rho_(Hg) = 13600 kg//m^(3))`

Pressure 3 m below the free surface of a liquid is 15KN//m^(2) in excess of atmosphere pressure. Datermine its density and specific gravity. [g = 10m//sec^(2)]

A liquid of specific gravity 0.8 rises up in a capillary tube up to a height of 10 cm, while mercury falls down by 4 cm in the same tube. If the angle of contact between surface of the tube and liquid is zero and it is 135^(@) for mercury, calculate the ratio of surface tension of mercury and the liquid. Take, specific gravity of mercury =13.6 cos 135^@=-0.71

The height of mercury column in a barometer in a Calcutta laboratory was recorded to be 75 cm. Calculate this pressure in SI and CGS units the following data, Specific gravity of mercury = 13.6, Density of water = 10^3 kg/m^3, g=9.8 m/s^2 at Calcutta. Pressure =h rho g in usual symbols.

A U - tube filled with mercury is connected to bulb containing a gas as shown . If atmospheric pressure is 1.013 xx10^(5) Pa and H = 0.05 m , then

Mercury has an angle of contact of 120^(@) with glass. A narrow tube of radius 1.0mm made of this glass is dipped in a through containig mercury. By what amount dies the mercury dip down in the tube relative to the liquid surface outside. Surface tension of mercury at the temperature of the experiment os 0.5 N//m and density of mercury is 13.6xx10^(3) kg//m^(3) . (Take g = 9.8 m//s^(2)) .

76 cm of mercury column is a measure of atmospherice pressure. Express it is N//m^2 Given density of mercury is 13.6xx10^3 kg//m^3

Two block A and B of mass 50 kg and 300 kg respectively are placed as shown in figure. Coefficient of friction between all surface is (1)/(2) Then (take g = 10 m//s )

A 100 cm long wire of mass 40 g supports a mass of 1.6 kg as shown in figure . Find the fundamental frequency of the portion of the string between the wall and the pulley. Take g=10m//s^(2) .

A glass tube has several different cross-sectional areas with the values indicated in the figure . A piston at the left end of the tube exerts pressure so that mercury within the tube flows from the right end with a speed of 8.0 m/s . Three points with in the tube are labeled A , B and C . (Atmospheric pressure is 1.01 xx 10^(5) N//m^(2) , Density of mercury is 13600 kg //m^(3) ) . At what speed is mercury flowing past the point labeled A ?

A glass tube has several different cross-sectional areas with the values indicated in the figure . A piston at the left end of the tube exerts pressure so that mercury within the tube flows from the right end with a speed of 8.0 m/s . Three points with in the tube are labeled A , B and C . (Atmospheric pressure is 1.01 xx 10^(5) N//m^(2) , Density of mercury is 13600 kg //m^(3) ) . At what speed is mercury flowing past the point labeled B ?