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• 5 Concept Lectures • 20 Solved Videos • 3 Hours of Learning • Certificate of Completion

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- Bendy Axis Method: Introduction
- Solved Video Example 1
- Solved Video Example 2
- Solved Video Example 3
- Solved Video Example 4
- Inclined Planes
- Solved Video Example 5
- Solved Video Example 6
- Solved Video Example 7
- Solved Video Example 8

In the diagram shown, assume the pulley is smooth and fixed and the ropes are massless. The mass of
each block is marked on the block in the diagram. Assume g = 10 m/s^{2}. Find the magnitude of the
acceleration of block M immediately after the system is released from rest.

7.3 m/s^{2}

6.66 m/s^{2}

8.5 m/s^{2}

5.43 m/s^{2}

Video Solution:

In the diagram shown, assume the pulleys are smooth and fixed, all surfaces are smooth and the ropes are massless.
The mass of each block is marked on the block in the diagram. Assume g = 10 m/s^{2}.
Find the magnitude of the acceleration of block 4M immediately after the system is released from rest.

7 m/s^{2}

6 m/s^{2}

2 m/s^{2}

5 m/s^{2}

Video Solution:

In the diagram shown, assume the pulleys are smooth and fixed, all surfaces are smooth and the ropes are massless.
The mass of each block is marked on the block in the diagram. Assume g = 10 m/s^{2}.
Find the magnitude of the acceleration of block 3M immediately after the system is released from rest.

5 m/s^{2}

6 m/s^{2}

8 m/s^{2}

3 m/s^{2}

Video Solution:

In the diagram shown, assume the pulleys are smooth and fixed, all surfaces are smooth and the rope is massless.
The mass of each block is marked on the block in the diagram. Assume g = 10 m/s^{2}.
Find the magnitude of the acceleration of block 3M immediately after the system is released from rest.

3.33 m/s^{2}

6.66 m/s^{2}

2.5 m/s^{2}

5.43 m/s^{2}

Video Solution:

Bendy Axis for Inclined Planes

In the diagram shown, assume the pulley is smooth and fixed, all surfaces are smooth and the ropes are massless.
The mass of each block is marked on the block in the diagram.
Assume g = 10 m/s^{2} and sin 37° = 0.6, sin 53° = 0.8.
Find the magnitude of acceleration of the 5M block immediately after the system is released from rest.

7.3 m/s^{2}

6 m/s^{2}

8.5 m/s^{2}

5 m/s^{2}

Video Solution:

In the diagram shown, assume the pulley is smooth and fixed, all surfaces are smooth and the rope is massless.
The mass of each block is marked on the block in the diagram.
Assume g = 10 m/s^{2} and sin 37° = 0.6, sin 53° = 0.8.
Find the magnitude of the acceleration of block M immediately after the system is released from rest.

7.3 m/s^{2}

4.5 m/s^{2}

3.2 m/s^{2}

5.43 m/s^{2}

Video Solution:

In the diagram shown, assume the pulleys are smooth and fixed, all surfaces are smooth and the ropes are massless.
The mass of each block is marked on the block in the diagram.
Assume g = 10 m/s^{2}.
Find the magnitude of the acceleration of the block M immediately after the system is released from rest.

7.5 m/s^{2}

6.56 m/s^{2}

8.5 m/s^{2}

5.43 m/s^{2}

Video Solution:

In the system shown, five blocks are connected by massless strings passing over smooth pulleys that are fixed.
The mass of each block is marked on the block in the diagram.
Assume g = 10 m/s^{2} and all surfaces are frictionless.
Find the magnitude of the acceleration of block 6M immediately after the system is released from rest.

7.5 m/s^{2}

4.66 m/s^{2}

2.5 m/s^{2}

5.43 m/s^{2}

Video Solution:

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