A particle of mass 2 kg located at the position m has a velocity of 2 m/s. Its angular momentum about z-axis in kg- is :
1. +4
2. +8
3. -4
4. -8
A cylinder of mass 'M' is suspended by two strings wrapped around it as shown. The acceleration 'a' and the tension T when the cylinder falls and the string unwinds itself are, respectively,
1.
2.
3.
4.
An automobile engine develops 100 kW when rotating at a speed of 1800 rev/min. What torque does it deliver ?
1. 350 N-m
2. 440 N-m
3. 531 N-m
4. 628 N-m
In an orbital motion, the angular momentum vector is
1. Along the radius vector
2. Parallel to the linear momentum
3. In the orbital plane
4. Perpendicular to the orbital plane
A particle of mass m moves with a constant velocity along 3 different paths, DE, OA and BC. Which of the following statements is not correct about its angular momentum about point O?
1. | It is zero when it is at A and moving along OA. |
2. | The same at all points along the line DE. |
3. | Of the same magnitude but oppositely directed at B and D. |
4. | Increases as it moves along the line BC. |
A sphere is rolling down a plane of inclination to the horizontal. The acceleration of its centre down the plane is
1. g sin
2. less than g sin
3. greater than g sin
4. zero
A bob of mass m attached to an inextensible string of length l is suspended from vertical support. The bob rotates in a horizontal circle with an angular speed about the vertical. About the point of suspension.
1. | Angular momentum is conserved |
2. | Angular momentum changes in magnitude but not in the direction |
3. | Angular momentum changes in direction but not in magnitude |
4. | Angular momentum changes both in direction and magnitude |
In free space, a rifle of mass \(M\) shoots a bullet of mass \(m\) at a stationary block of mass \(M\) at a distance \(D\) away from it. When the bullet has moved through a distance \(d\) towards the block, the centre of mass of the bullet-block system is at a distance of:
1. \(\frac{D-d}{M+m}~\text{from the bullet}\)
2. \(\frac{md+ MD}{M+m}~\text{from the block}\)
3. \(\frac{2md+ MD}{M+m}~\text{from the block}\)
4. \(\frac{(D-d)M}{M+m}~\text{from the bullet}\)
Blocks A and B are resting on a smooth horizontal surface given equal speeds of 2 m/s in the opposite sense as shown in the figure.
At t = 0, the position of blocks are shown, then the coordinates of centre of mass at t = 3s will be
1. (1, 0)
2. (3, 0)
3. (5, 0)
4. (2.25, 0)