Water of density '`rho`' flows with a linear speed v through a horizontal tube in the form of a ring of R. If the diameter of the tube is `dlt lt R`. The tension in the rubber tube is `T= (1)/(n)pi rho v^(2)d^(2)` . Then the value of n is ……….

Water is flowing through two horizontal pipes of different diameters which are connected together. The diameters of the two pipes are 3 cm and 6 cm respectively. If the speed of water in the narrower tube is 4 ms^(-1) . Then the speed of water in the wider tube is

Water flows through a horizontal tube as shown in figure. If the difference of height of water column in the vertical tubes in 2cm and the areas of corss-section at A and B are 4 cm^(2) and 2 cm^(2) respectively. Find the rate of flow of water across any section. .

Water is flowing through a tube of radius r with a speed v. If this tube is joined to another tube of radius r/2, what is the speed of water in the second tube?

Water flows through a horizontal tube as shown in figure. If the difference of heights of water colun in the vertical tubes is 2 cm and the area of cross section at A and B are 4cm^2 and 2cm^2 respectively, find the rate of flow of water across any section.

A liquid of density rho and surface tension sigma rises in a capillary tube of diameter d. Angle of contact between the tube and liquid is zero. The weight of the liquid in the capillary tube is:

A narrow U-tube placed on a horizontal surface contains two liquids of densities rho_(1) and rho_(2) . The columns of the liquids are indicated in the figure. The ratio (rho_(1))/(rho_(2)) is equal to :

The rate of steady volume flow of water through a capillary tube of length ' l ' and radius ' r ' under a pressure difference of P is V . This tube is connected with another tube of the same length but half the radius in series. Then the rate of steady volume flow through them is (The pressure difference across the combination is P )

A liquid flows in a tube from left to right as shown in figure. A_(1) and A_(2) are the cross-section of the portions of the tube as shown. Then the ratio of speeds v_(1)//v_(2) will be

Air flows over the top of an aeroplane wing of area A with speed v_1 and past the under side of the wing of area A with speed v_2 Show that the magnitude of the upward in force on the wing L is L = (1)/(2) rho A ( v_1^(2) - v_2^(2)) where rho is the density of the alr.

An ideal liquid of density rho is pushed with velocity v through the central limb of the tube shown in fig. What force does the liquid exert on the tube? The cross sectional areas of the three limbs are equal to A each. Assume stream-line flow.