A non-viscous fluid of constant density of `1000kg//m^(3)` flows in stream line motion along a tube of variable cross-section
The area of cross-section at two P and Q at lengths 5m are `40 cm^(2) and 20 cm^(2)` respectively. If velocity of fluid at P is `3 m//s` then find velocity of fluid at Q.

A non-viscous liquid of constant density 500 kg//m^(3) flows in a variable cross-sectional tube. The area of cross section of the tube at two points P and Q at heights of 3 m and 6 m are 2 xx 10^(-3) m^(3) and 4 xx 10^(-3) m^(3) , respectively. Find the work done per unit volume by the forces of gravity as the fluid flows from point P to Q .

A non viscous liquid of constant density 10^(3) kg//m^(3) flows in stream line motion along a vertical tube PQ of variable cross-section. Height of P and Q are 2m and 2.5m respectively. Area of tube at Q is equal to 3 times the area of tube at 'P'. Then work done per unit volume by pressure as liquid flows from P and Q. Speed of liquid at 'P' is 3 m//s .

A pipe of non uniform cross section has two distinct section 1 and 2 with areas 2cm^(2) and 4cm^(2) respectively. If the velocity of flowing liquid at section 1 is 5cm//s , determine the velocity at section 2 .

A non-viscous liquid of constant density 1000kg//m^3 flows in a streamline motion along a tube of variable cross section. The tube is kept inclined in the vertical plane as shown in Figure. The area of cross section of the tube two point P and Q at heights of 2 metres and 5 metres are respectively 4xx10^-3m^2 and 8xx10^-3m^2 . The velocity of the liquid at point P is 1m//s . Find the work done per unit volume by the pressure and the gravity forces as the fluid flows from point P to Q.

(i) Air (density= rho ) flows through a horizontal venturi tube that discharges to the atmosphere. The area of cross section of the tube is A_(1) and at the constriction it is A_(2) . The constriction is connected to a water (density =rho_(0) ) tank through a vertical pipe of lenght H. Find the volume flow rate (Q) of the air through tube that is needed to just draw the water into the tube. (ii) A non viscous liquid of constant density rho flows in a stremline motion along a tube of variable cross section. The tube is kept inclined in the vertical plane as shown in the figure. The area of cross section of the tube at two points P and Q at heights of h_(1) and h_(2) are respectively A_(1) and A_(2) . The velocity of the liquid at point P is v. Find the work done on a small volume DeltaV of fluid by the neighbouring fluid as the small volume moves from P to Q.

A liquid of density 800 kg//m^3 flowing steadily in a tube of varying cross-section. If area of cross-section at A is 4 cm^2 and at B is 2 cm^2 . If speed of liquid at A is 10 cm//s , calculate (i) the rate of flow (ii) the difference in pressures at A and B .

An ideal liquid (water) flowing through a tube of non-uniform cross section area at A and B are 40 cm^2 and 20 cm^2 respectively. If pressure difference between A & B is 700 N/(m^2) then volume flow rate is

Water flows through the tubes shown in figure. The areas of cross-section of the wide and the narrow portions of the tube are 5 cm^(2) and 2 cm^(2) respectively. The rate of flow of water through the tube is 500 cm^(3)//s . Find the difference of mercury levels in the U-tube.

Water flows through a non-uniform tube of area of cross section A, B and C whose values are 25, 15 and 35cm^(2) resprectively. The ratio of the velocities of water at the sections A,B and C is

Water flows through a vertical tube of varible cross-section. The area of cross-section at A and B 6 and 3 mm^(2) respectively. If 12c c of water enters per second through A, find the pressure difference P_(A)-P_(B).(g=10 m//s^(2)) . The separation between the cross-section at A and B is 100 cm.