A vessel, whose bottom has round holes with diameter of 0.1 mm , is filled with water. The maximum height to which the water can be filled without leakage is (S.T. of water =75 dyne/cm , g=1000 cm/s)

A vessel whose , bottom has round holes with diameter 0.1 mm , is filled with water. The maximum height up to which water can be filled without leakage is

A container, whose bottom has round holes with diamter 0.1mm is filled with water. The maximum height in cm upto which water can be filled without leakage will be what? Surface tension =75xx10^(-3)N//m and g=10m//s^(2)

A vessel whose bottom has round holes with a diameter of d=0.1mm is filled with water. The maximum height of the water level h at which the water does not flow out, will be (The water does not wet the bottom of the vessel). [ST of water=70 "dyne"//cm]

A vessel whose bottom has round holes with diameter of 1 mm is filled with water Assuming that surface tenstion acts only at holes, then the maximum height to which the water can be filled in vessel without leakage is (given surface tension of water is 75xx10^(-3)N//m) and g=10m//s^(2)

If a vessel has a small hole at the bottom of radius 4 mm, then the rise of water in a vessel without leakage will be (S.T = 72 dyne/cm , g = 1000 "cm/s"^(2) rho = 1 g //cm^(3) )

A capillary tube of uniform bore is dipped vertically in water which rises by 7 cm in tube . Then the radius of capillary tube is (S.T of water is 70 dyne/cm , g = 1000 "cm/s"^(2) theta = 0^(@))

A cylindrical tank has a hole of 2cm^(2) at its bottom if the water is allowed to flow into tank from a tube above it at the rate of 100cm^(3)//s then find the maximum height upto which water can rise in the tank (take =g=10ms^(-2) )

An inverted conical vessel whose height is 10 cm and the radius of whose base is 5 cm is being filled with water at the uniform rate of 1.5cm^(3)//min . Find the rate at which the level of water in the vessel is rising when the depth is 4 cm.