The terminal velocity of small sized spherical body of radius r falling vertically in a viscous liquid is given by the following proportionality

The terminal velocity V of a spherical ball of lead of radius R falling through a viscous liquid varies with R such that

The terminal velocity of a sphere of radius R, falling in a viscous fluid, is proportional to

The terminal velocity v of a small steel ball ofradius r fal ling under gravity through a column ofa viscous liquid of coefficient of viscosity eta depends on mass of the ball m, acceleration due to gravity g, coefficient of viscosity eta and radius r. Which of the following relations is dimensionally correct?

A small lead ball is falling freely in a viscous liquid The velocity of the ball

Define terminal velocity. Show that the terminal velocity upsilon of a sphere of radius r, density rho falling vertically through a viscous fluid of density sigma and coefficient of viscosity eta is given by upsilon = 2 / 9 ((rho - sigma)r^2 g) / eta Use this formula to explain the observed rise of air bubbles in a liquid.

Draw a graph between terminal velocity of a spherical body and square of its radius?

From amongst the following curves, which one shows the variation of the velocity v with time t for a small sized spherical body falling vertically in a long column of a viscous liquid

A spherical body of diameter D is falling in viscous medium. Its terminal velocity is proportional to

After terminal velocity is reached the acceleration of a body falling thorugh a viscous fluid is: