A glass tube of uniform internal radius ( R ) has a valve separating the two identical ends . Initially , the valve is in a tightly closed position . End 1 has hemispherical soap bubble of radius r. End 2 has sub-hemispherical soap bubble as shown in figure. just after opening the valve,

Two spherical soap bubbles of radii r_1 and r_2 in vacuume coalesce under isothermal condition. The resulting bubble has radius R such that

Two spherical soap bubbles of radii r_1 and r_2 in vacuume coalesce under isothermal condition. The resulting bubble has radius R such that

A uniform solid sphere of radius R has a hole of radius R//2 drilled inside it. One end of the hole is at the centre of the sphere while the other is at the boundary. Locate centre of mass of the remaining sphere..

A soap buble of radius 1.0 cm is formed inside another soap bubble of radius 2.0 cm . The radius of an another soap bubble which has the same pressure difference as that between the inside of the smaller and outside of large soap bubble , in metres is

Two soap bubbles of radii r_1 and r_2 equal to 4cm and 5 cm are touching each other over a common surface S_1S_2 (shown in figure.) Its radius will be

One end of a glass capillary tube with a radius r is immersed into water to a depth of h The surface tension of water is s and atmospheric pressure is p_0 . What pressure is required to blow an air bubble out of the lower end of the tube? Density of water is rho

The value V in the bent tube is initailly kept closed. Two soap bubbles A(smaller ) and B (larger )are formed at 2 open ends of the tube. V is now opened .and air can flow freely between the bubbles

A glass capillary of length l and inside radius r(r lt lt l) is submerged vertically into water. The upper end of the capillary is scaled. The atmospheric pressure is p_(0) . To what length h has the capillary to be submerged to make the water levels inside and outside the capillary coincide. Assume that temperature of air in the capillary remains constant. (given, surface tension of water = T, angle of contact between glass water interface = 0^(@) )

The cylindrical tube of a spray pump has radius R , one end of which has n fine holes, each of radius r . If the speed of the liquid in the tube is V , the speed of the ejection of the liquid through the holes is:

A particle moves along a circle of radius'r' with constant tangential acceleration. If the velocity of the particle is 'v' at the end of second revolution , after the revolution has started then the tangential accleration is