A : Equation ofcontinuity is `A_(1) v_(1) rho_(1) = A_(2) v_(2) rho_(2)` (symbols have their usual meanings).
R : Equation of continuity is valid only for incompressible liquids.

In the derivation of P_1-P_2=rhogz it was asumed that the liquid is incompressible. Why will this equation not be stictly valid for a compressible liquid?

Three liquids of densities rho_(1), rho_(2) and rho_(3) (with rho_(1) gt rho_(2) gt rho_(3) ), having the same value of surface tension T, rise to the same height in three identical capillaries. The angles of contact theta_(1), theta_(2) and theta_(3) obey

From energy conservation principle prove the relations, A_r = ((v_2-v_1)/(v_1 +v_2))A_i and A_t = ((2v_2)/(v_1 +v_2))A_i Here, symbols have their usual meanings.

A solid sphere of radius r is floating at the interface of two immiscible liquids of densities rho_(1) and rho_(2)(rho_(2) gt rho_(1)) , half of its volume lying in each. The height of the upper liquid column from the interface of the two liquids is h. The force exerted on the sphere by the upper liquid is (atmospheric pressure = p_(0) and acceleration due to gravity is g):

A solid sphere having volume V and density rho floats at the interface of two immiscible liquids of densites rho_(1) and rho_(2) respectively. If rho_(1) lt rho lt rho_(2) , then the ratio of volume of the parts of the sphere in upper and lower liquid is

Assertion : A solid is floating in a liquid of density rho_(1) . When the solid melts its density becomes rho_(2) in liquid state. If rho_(1) gt rho_(2) level of liquids will increase after melting. Reason : In liquid state volume always increases after a solid melts.

Find the equation of locus of point equidistant from the points (a_(1)b_(1)) and (a_(2),b_(2)) .

Derive following equations for a uniformly accelerated motion : (i) v = u + at (ii) S = ut+(1)/(2) at^(2) (iii) v^(2)= u^(2) +2aS Where the symbols have their usual meanings .

A body weighs W_(1) in a liquid of density rho_(1) and W_(2) in a liquid of density rho_(2) . What is the weight of body in a liquid of density rho_(3) ?

A solid uniform ball having volume V and density rho floats at the interface of two unmixible liquids as shown in Fig. 7(CF).7. The densities of the upper and lower liquids are rho_(1) and rho_(2) respectively, such that rho_(1) lt rho lt rho_(2) . What fractio9n of the volume of the ball will be in the lower liquid.