If velocity of efflux is v and area of orifice is `A_(0)` then

The area of hole (1) is A_(1) and of hole (2) is A_(2) . The velocity of efflux and range of liquid is v_(1), v_(2) and x_(1), x_(2) for holes (1) and (2) respectively. The time taken by liquid, jet to reach the ground from holes (1) and (2) are t_(1) and t_(2) respectively. Cross section of tank is very very large compared to size of holes. {:(,"Column-I",,"Column-II"),((A),v_(1):v_(2),(p),2 : 1),((B),x_(1) : x_(2),(q),1 : 2),((C),t_(1) : t_(2),(r),1 : 1),((D),"if"A_(1) : A_(2) = 2 : 1",then"v_(1) : v_(2) =,(s),4 : 1):}

The velocity of efflux of a liquid through an orifice in the bottom of a tank does not depend upon

The velocity of efflux of a fluid through an orifice 15 cm below the fluid surface (which is open to the atmosphere) is [Take g = 10 m s^(-2) ]

A container filled with a liquid of density 4p as shown in the figure. The velocity efflux through orifice is ( rho is density of water and g = 10 ms^(-2) )

An open vessel contains water upto height 50 cm in it. What is the velocity of efflux through an orifice at height 30 cm above the bottom level ? [Take g = 10 m//s^(2) ]

If cross- sectional area of limb I is A_(1) and that of limb II is A_(2) then velocity of the liquid in the tube will be, (cross- sectional area of tube is very small)

A rocket ejects the fuel (hot gases) of density rho from the chamber which is maintained at a pressure P_(1) , say. The atmospheric pressure is P_(0) . If the base area of the cylindrical chamber is A_(1) and the area of the hole through which hot gases escape from the rocket is A_(2) find (a) velocity of efflux of the fuel, (b) thrust exerted on the rocket given by the escaping fuel.

A liquid is filled in a vessel and a hole is made at a depth h below the free surface of the liquid. Statement-1 : Greater is the distance of the hole form the free surface of liquid, greater will be the velocity of efflux. And Statement-2 The speed of the liquid coming out of the orifice depends on the quantity of liquid in the vessel.

Equal volume of two immiscible liquids of densities rho and 2rho are filled in a vessel as shown in the figure. Two small holes are punched at depths h//2 and 3h//2 from the surface of lighter liquid. If v_(1) and v_(2) are the velocities of efflux at these two holes, then v_(1)//v_(2) is

Equal volumes of two immiscible liquids of densities rho and 3rho are filled in a big vessel. Two small holes are punched at depth h//3 and 4h//3 from upper surface of lighter liquid. If v_(1) and v_(2) are velocities of efflux at these two holes, then v_(1)//v_(2) is