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.
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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 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)

The string AB vibrates in two loops with a tuning fork when block hasngs in air. Now block is completely immersed in water, the string vibrates in three loops with same tuning fork. The specific gravity of block is :

A uniform solid cylinder of mass M and radius 2R rests on a horizontal table top. A string attached to it runs over a pulley (disc) of mass M and radius R thatis mounted on a frictionless axle through its centre. A block of mass M is suspended from the free end of the string. The string doesn't slip over the pulley surface, and the cylinder rolls without slipping on the, table top. Find the acceleration of the block. [g/3]

Three identical blocks each of mass m = 1 kg and volume 3 xx 10^(-4) m^(3) are suspended by massless strings from a support as shown. Underneath are three identical containers containing the same amount of water that are placed over the scales. In Fig. (a), the block is completely out of the water, in Fig. (b), the block is completely submerged but not touching the beaker and in Fig. (c), the block rests on the bottom of the beaker. The scale in Fig (a) reads 14 N .

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

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 uniform solid cylinder of mass m and radius 2R rests on a horizontal table. A string attached to it passes over a pulley (disc) of mass m and radius R that is mounted on a fricitonaless axle through its centre . A block of mass m is suspended from the free end of the spring . The string does not slip over the pulley surface and the cylinder rolls without slipping on the table. Acceleration of the block is