Advertisements
Advertisements
प्रश्न
The following figure shows a small spherical ball of mass m rolling down the loop track. The ball is released on the linear portion at a vertical height H from the lowest point. The circular part shown has a radius R.
(a) Find the kinetic energy of the ball when it is at a point A where the radius makes an angle θ with the horizontal.
(b) Find the radial and the tangential accelerations of the centre when the ball is at A.
(c) Find the normal force and the frictional force acting on the if ball if H = 60 cm, R = 10 cm, θ = 0 and m = 70 g.
Advertisements
उत्तर
(a) Let the velocity and angular velocity of the ball at point A be v and ω, respectively.
Total kinetic energy at point A \[= \frac{1}{2}m v^2 + \frac{1}{2}I \omega^2\]
Total potential energy at point A \[= mg\left( R + R\sin\theta \right)\]
On applying the law of conservation of energy, we have
Total energy at initial point = Total energy at A
Therefore, we get
\[mgH = \frac{1}{2}m v^2 + \frac{1}{2}I \omega^2 + mgR\left( 1 + \sin\theta \right)\]
\[ \Rightarrow mgH - mgR\left( 1 + \sin\theta \right) = \frac{1}{2}m \nu^2 + \frac{1}{2}I \omega^2 \]
\[ \Rightarrow \frac{1}{2}m v^2 + \frac{1}{2}I \omega^2 = mg\left( H - R - R\sin\theta \right)........(1)\]
\[\text{Total }K . E . \text{ at } A = mg\left( H - R - R\sin\theta \right)\]
(b) Let us now find the acceleration components.
Putting \[I = \frac{2}{5}m R^2 \text{ and } \omega = \frac{v}{R}\] in equation (1), we get
\[\frac{7}{10}m v^2 = mg\left( H - R - R\sin\theta \right)\]
\[ \Rightarrow v^2 = \frac{10}{7}g\left( H - R - R\sin\theta \right).........(2)\]
Radial acceleration,
\[a_r = \frac{v^2}{R} = \frac{10}{7}\frac{g\left( H - R - R\sin\theta \right)}{R}\]
For tangential acceleration,
Differentiating equation (2) w.r.t. `'t'`,
\[2v\frac{dv}{dt} = - \left( \frac{10}{7} \right)gR\cos\theta\frac{d\theta}{dt}\]
\[ \Rightarrow \omega R\frac{dv}{dt} = - \left( \frac{5}{7} \right) gR\cos\theta\frac{d\theta}{dt}\]
\[ \Rightarrow \frac{dv}{dt} = - \left( \frac{5}{7} \right) gcos\theta\]
\[ \Rightarrow a_t = - \left( \frac{5}{7} \right) gcos\theta\]
(c) At \[\theta = 0,\] from the free body diagram, we have
Normal force = \[N = m a_r\]
\[N = m \times \frac{10}{7}\frac{g\left( H - R - R\sin\theta \right)}{R}\]
\[= \left( \frac{70}{1000} \right) \times \left( \frac{10}{7} \right) \times 10 \left\{ \frac{0 . 6 - 0 . 1}{0 . 1} \right\}\]
\[= 5 N\]
At \[\theta = 0,\] from the free body diagram, we get
\[f_r = mg - m a_t..........\left(f_r=\text{ Force of friction}\right)\]
\[\Rightarrow f_r = m\left( g - a_t \right)\]
\[= m\left( 10 - \frac{5}{7} \times 10 \right)\]
\[ = 0 . 07\left( 10 - \frac{5}{7} \times 10 \right)\]
\[= \frac{1}{100} \left( 70 - 50 \right) = 0 . 2 N\]
APPEARS IN
संबंधित प्रश्न
Two bodies make an elastic head-on collision on a smooth horizontal table kept in a car. Do you expect a change in the result if the car is accelerated in a horizontal road because of the non inertial character of the frame? Does the equation "Velocity of separation = Velocity of approach" remain valid in an accelerating car? Does the equation "final momentum = initial momentum" remain valid in the accelerating car?
A van is standing on a frictionless portion of a horizontal road. To start the engine, the vehicle must be set in motion in the forward direction. How can be persons sitting inside the van do it without coming out and pushing from behind?
A bullet hits a block kept at rest on a smooth horizontal surface and gets embedded into it. Which of the following does not change?
A shell is fired from a cannon with a velocity V at an angle θ with the horizontal direction. At the highest point in its path, it explodes into two pieces of equal masses. One of the pieces retraces its path to the cannon. The speed of the other piece immediately after the explosion is
A block moving in air breaks in two parts and the parts separate
(a) the total momentum must be conserved
(b) the total kinetic energy must be conserved
(c) the total momentum must change
(d) the total kinetic energy must change
A ball hits a floor and rebounds after an inelastic collision. In this case
(a) the momentum of the ball just after the collision is same as that just before the collision
(b) the mechanical energy of the ball remains the same during the collision
(c) the total momentum of the ball and the earth is conserved
(d) the total energy of the ball and the earth remains the same
A neutron initially at rest, decays into a proton, an electron, and an antineutrino. The ejected electron has a momentum of 1.4 × 10−26 kg-m/s and the antineutrino 6.4 × 10−27kg-m/s.
Find the recoil speed of the proton
(a) if the electron and the antineutrino are ejected along the same direction and
(b) if they are ejected along perpendicular directions. Mass of the proton = 1.67 × 10−27 kg.
A ball of mass 50 g moving at a speed of 2.0 m/s strikes a plane surface at an angle of incidence 45°. The ball is reflected by the plane at equal angle of reflection with the same speed. Calculate (a) the magnitude of the change in momentum of the ball (b) the change in the magnitude of the momentum of the ball.
A gun is mounted on a railroad car. The mass of the car, the gun, the shells and the operator is 50 m where m is the mass of one shell. If the velocity of the shell with respect to the gun (in its state before firing) is 200 m/s, what is the recoil speed of the car after the second shot? Neglect friction.
A ball of mass 0.50 kg moving at a speed of 5.0 m/s collides with another ball of mass 1.0 kg. After the collision the balls stick together and remain motionless. What was the velocity of the 1.0 kg block before the collision?
A 60 kg man skating with a speed of 10 m/s collides with a 40 kg skater at rest and they cling to each other. Find the loss of kinetic energy during the collision.
Consider a head-on collision between two particles of masses m1 and m2. The initial speeds of the particles are u1 and u2 in the same direction. the collision starts at t = 0 and the particles interact for a time interval ∆t. During the collision, the speed of the first particle varies as \[v(t) = u_1 + \frac{t}{∆ t}( v_1 - u_1 )\]
Find the speed of the second particle as a function of time during the collision.
A block of mass 200 g is suspended through a vertical spring. The spring is stretched by 1.0 cm when the block is in equilibrium. A particle of mass 120 g is dropped on the block from a height of 45 cm. The particle sticks to the block after the impact. Find the maximum extension of the spring. Take g = 10 m/s2.
A bullet of mass 25 g is fired horizontally into a ballistic pendulum of mass 5.0 kg and gets embedded in it. If the centre of the pendulum rises by a distance of 10 cm, find the speed of the bullet.
The friction coefficient between the horizontal surface and each of the block shown in figure is 0.20. The collision between the blocks is perfectly elastic. Find the separation between the two blocks when they come to rest. Take g = 10 m/s2.
A small block of superdense material has a mass of 3 × 1024kg. It is situated at a height h (much smaller than the earth's radius) from where it falls on the earth's surface. Find its speed when its height from the earth's surface has reduce to to h/2. The mass of the earth is 6 × 1024kg.
A uniform rod pivoted at its upper end hangs vertically. It is displaced through an angle of 60° and then released. Find the magnitude of the force acting on a particle of mass dm at the tip of the rod when the rod makes an angle of 37° with the vertical.
The following figure shows a rough track, a portion of which is in the form of a cylinder of radius R. With what minimum linear speed should a sphere of radius r be set rolling on the horizontal part so that it completely goes round the circle on the cylindrical part.
A thin spherical shell of radius R lying on a rough horizontal surface is hit sharply and horizontally by a cue. Where should it be hit so that the shell does not slip on the surface?
