Obtain dimension of `rho gv`
where, `rho` = density, g = acceleration, v = velocity

Which equation are dimensionally valid out of following equations (i) Pressure P= rho gh where rho = density of matter, g= acceleration due to gravity. H= height. (ii) F.S =(1)/(2) mv^(2)-(1)/(2) mv_(0)^(2) where F= force rho = displacement m= mass, v= final velocity and v_(0)= initial velocity (iii) s=v_(0)t+(1)/(2) (at)^(2) s= dispacement v_(0)= initial velocity, a= accelration and t= time (iv) F=(mxx a xx s)/(t) Where m= mass, a= acceleration, s= distance and t= time

A capillary of the shape as shown is dipped in a liquid. Contact angle between the liquid and the capillary is 0^@ and effect of liquid inside the mexiscus is to be neglected. T is surface tension of the liquid, r is radius of the meniscus, g is acceleration due to gravity and rho is density of the liquid then height h in equilibrium is:

Assume that the largest stone of mass 'm' that can be moved by a flowing river depends upon the velocity of flow v, the density d & the acceleration due to gravity g.mass 'm' varies as the K^(th) power of the velocity of flow, then find the value of K.

The helicopter has a mass m and maintains its height by imparting a downward momentum to a column of air defined by the slipstream boundary as shown in figure. The propeller blades can project a downward air speed v_0 , where the pressure in the stream below the blades is atmospheric and the radius of the circular cross section of the slipstream is r . Neglect any rotational energy of the air, the temperature rise due to air friction and any change in air density rho . If the power is doubled, the acceleration of the helicopter is :-

The helicopter has a mass m and maintains its height by imparting a downward momentum to a column of air defined by the slipstream boundary as shown in figure. The propeller blades can project a downward air speed v, where the pressure in the stram below the blades is atmospheric and the radius of the circular cross section of the slipstream is r. Neglect any rotational energy of the air, the temperature rise due to air friction and any change in air density rho . If the power is doubled, the acceleration of the helicopter is :-

The Bernoulli's equation is given by P+1/2 rho v^(2)+h rho g=k . Where P= pressure, rho = density, v= speed, h=height of the liquid column, g= acceleration due to gravity and k is constant. The dimensional formula for k is same as that for:

A sealed tank containing a liquid of density rho moves with horizontal acceleration a as shown in the figure. The difference in pressure between two points A and B will be

Let us consider an equation (1)/(2)= mv^(2)= mgh where m is the mass of the body, v its velocity, g is the acceleration due to gravity and it is the height. Check whether this equation is dimensionally correct.

A U -tube of base length l filled with the same volume of two liquids of densities rho and 2rho is moving with an acceleration 'a' on the horizontal plane. If the height difference between the two surfaces (open to atmosphere) becomes zero, then the height h is given by

Let us consider an equation (1)/(2)mv^(2)=mgh Where m is the mass of the body. V its velocity , g is the acceleration due to gravity and h is the height . Check whether this equation is dimensionally correct.