A vertical `U`-tube is spinned about the vertical axis passing through the left hand limb, with an angular speed `omega` such that the liquid columns in the limbs have heights `h` and `3h`, as shown in the figure. Find the value of to `omega`.

Length of the horizontal arm of a uniform cross - section U - tube is l = 5 cm and both ends of the vertical arms are open to the surrounding pressure of "7700 N m"^(-2) . A liquid of density rho=10^(3)" kg m"^(-3) is poured into the tube such that the liquid just fills the horizontal part of the tube. Now, one of the open ends is sealed and the tube. Now, one of the open ends is sealed and the tube is then rotaed about a vertical axis passing through the other veritcal arm with angular velocity omega due to which the liquid rises up to half the length of the vertical arm. If length of each vertical arm is a = 6 cm. What is the value of omega("in rad s"^(-1)) ?

A vertical U -tube has a liquid up to a height h . If the tube is slowly rotated to an angular speed omega=sqrt(g/h) find the (i) heights of the liquid column, ii pressures at the points 1, 2 and 3 in the limbs in steady state.

A rod of mass M and length l attached with a small bob of mass m at its end is freely rotating about a vertical axis passing through its other end with a constant angular speed omega . Find the force exerted by the system (rod and bob) on the pivot. Assume that gravity is absent.

Length of a horizontal arm of ends of both the vertical arms pressure P_(0) = 10^(5) N//m^(2) . A liquid of density rho = 10^(3) kg //m^(3) is poured in the tube such that liquid just fills the horizontal part of the tube as a shown in Fig. Now one end of the open ends is sealed and the tube is then rotated about a vertical axis passing through the other vertical arm with angular speed omega_(0)=sqrt(40//3)rad//sec . If length of each vertical arm is a = 1 m and in the sealed end liquid rises to a height y = 1//2 m , find pressure in the sealed tube during rotation. (in xx 10^(5) N//m^(2))

A small wedge whose base is horizontal is fixed to a vertical rod as shown in fig . The sloping side of the weidgeis frictionless and the wedge is span with a constant angular speed omega about vertical axis as shown in the fig find the a. value of angular speed omega for which the block of mass m just does not slide down the wedge. b. normal reaction on the block by wedge when block does not slip relative to wedge.

A pendulum bob of mass m hangs from one end of a horizontal rod which is rotating about vertical axis with an unknown angular speed omega such that the light inextensible string of length l of the pedulum makes a constant angle theta with vertical. Find the Q. angular speed omega

Length of horizontal arm of a uniform cross section U -tube is l= 21 cm and ends of both of the vertical arms are open to surrounding of pressure 10500 N//m^(2) . A liquid of density rho = 10^(3) kg//m^(3) is poured into the tube such that liquid just fills the horizontal part of the tube. Now one of the open ends is sealed and the tube is then rotated about a vertical axis passing through the other vertical arm With angular velocity omega_(0) = 10 rad//s . If length of each vertical arm is a = 6 cm , calculate the length of air column in the sealed arm. (in cm)

A thin uniform rod of length l and mass m is swinging freely about a horizontal axis passing through its end. Its maximum angular speed is omega . Its centre of mass rises to a maximum height of -

A horizontal thin tube of length 2L completely filled with a liquid of density delta rotates about a vertical axis passing through one of its end and along the diameter of its side face with an constant angular velocity omega . Two vertical thin long tubes are fitted with the horizontal tube to measure the pressure difference between points A and B which are at same horizontal level as shown. Neglect viscous forces and surfaces tension of liquid. The difference in the heights (h) of the liquid column in the two vertical thin tubes is :

A ring of radius r is rotating about a vertical axis along its diameter with constant angular velocity omega.A read of mass m remains at rest w.r.t. ring at the position shown in figure. Then w^(2) is: