Figure shows a string stretched by a block going over a pulley. The string vibrates in its tenth harmonic in resonance with a particular tuning fork. When a beaker containing water is brought under the block so that the block is `d "gram"//"cm"^(3)` then find greatest integer of `d`. (node is formed at the pulley)

Figure shows a string stretched by a block going over a pulley. The string vibrates in its tenth harmonic in unison with a particular tuning fork. When a beaker containing water is brought under the block so that the block is completely dipped into the beaker, the string vibrates in its eleventh harmonic. Find the density of the material of the block. .

A string is stretched by a block going over a pulley . The string vibrates in its fifth harmonic in unison with a particular tuning fork . When a beaker containing a liquid of density rho is brought under the block so that the block is completely dipped into the beaker , the string vibrates in its seventh harmonic in unison with the tuning fork . Find the density of the material of the block.

Figure shows two blocks of mass m and m connected by a string passing over a pulley. The horizontal table over which the mass m slides is smooth. The pulley (uniform disc) has mass m and it can freely rotate about this axis. Find the acceleration of the mass m assuming that the string does not slip on the pulley.

A string passing over a smooth pulley carries a stone at one end, while its other end is attached to a vibrating tuning fork and the string vibrates forming 8 loops. When the stone is immersed in water 10 loops are formed. The specific gravity of the stone is

The linear mass density of the string shown in the figure is mu = 1 g//m . One end (A) of the string is tied to a prong of a tuning fork and the other end carries a block of mass M. The length of the string between the tuning fork and the pulley is L = 2.0 m . When the tuning fork vibrates, the string resonates with it when mass M is either 16 kg or 25 kg. However, standing waves are not observed for any other value of M lying between 16 kg and 25 kg. Assume that end A of the string is practically at rest and calculate the frequency of the fork.

Figure shows two blocks of masses m and M connected bky a string pasing over a pulley. The horizontal table over which the mass m slides is smooth. The pulley has a radius r and moment of inertia I about its axis and it can freely rotte about this axis. Find the accelerationof the mass M asuming that the string does not slip on the pulley.

A block of mass m and alpha pan of equla mass are connected by a string going over a smooth light pulley as shwon in figure. Initially the systemis at rest when a particle of mass m falls on the pan and sticks to it. If the particle strikes thepan witha speed v find the speed with which the system moves just after the collision.

Figure shows a wheel pivoted at its centre in a water tank containing 1 kg water. A light string is wound on the shaft of the wheel and its other end is connected to a hainging block of mass 12 kg as shown. It is observed that the block falls slowly by a distance 0.7 m. Find the rise in temperature of the water. Also find the amount of theat supplied to the water. Give that the specific heat fo water is 4200J//kg^(@)C and that of wheel is negligible.