Water from a tap emerges vertically downwards with an initial velocity `V_(0)`. Assume pressure is constant throughout the stream of water and the flow is steady. Find the distance form the tap at which cross-sectional area of stream is half of the cross-sectional area of stream at the tap.

Water from a tap emerges vertically downwards with an initial spped of 1.0ms^-1 . The cross-sectional area of the tap is 10^-4m^2 . Assume that the pressure is constant throughout the stream of water, and that the flow is steady. The cross-sectional area of the stream 0.15 m below the tap is

Water from a tap emerges vertically downward with an initial speed of 3.0 m/s. The cross-sectional area of the tap is 10^(-4)m^2 . Assume that the pressure is constant throughout the stream of water and that the flow is steady. The cross-sectional area of the stream 2 m below the tap is:

Water from a tap emerges vertically downwards an intial speed of 1 m/s . The cross-sectional area of the tap is 10^(-4)m^(2) . Assume that the pressure is contant throughout the stream of water and that the flow is steady . The cross-sectional area of the steam. 0.15 m below the tap is

Water from a tap emerges vertically downwards with iitial velocity 4ms^(-1) . The cross-sectional area of the tap is A. The flow is steady and pressure is constant thorughout the stream of water. The distance h vertically below the tap, where the cross-sectional area of the stream becomes ((2)/(3))A is (g=10m//s^(2))

Water from a tap emerges vertically downward with an initial speed of 1.0ms^(-1) . The cross-sectional area of the tap is 10^(-4) m^(2) . Assume that the flow is steady. What is the cross-sectional area of the stream 0.15 m below the tap? Use g=10 ms^(-2) .

In the previous question, at the mouth of the tap the area of cross-section is 2.5 cm^2 and the speed of water in 3 m//s . The area of cross-section of the water column 80 cm below the tap is.

The water flowing through the same tube having two different cross section areas has different flow rates .

A laminar stream is flowing vertically down from a tap of cross-section area 1cm^(2) . At a distance 10 below the tap, the cross-section area of the stream has reduced to 1//2cm^(2) . Find the volumetric flow rate of water from the tap.

Water rises to a height h in a capillary tube of cross-sectional area A. the height to which water will rise in a capillary tube of cross-sectional area 4A will be

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.