Imagine there is a painter, weighing $180$ $lbs$, that is working from a bosun's chair hung down the side of a tall building. [![enter image description here][1]][1] Suppose that he pulls down on a fall rope with such a force that he presses against the chair with a force of $100$ $lbs$. You can assume that the chair's weight is $30$ $lbs$. I want to use the given information to find the acceleration of the painter and the chair. # ========================================== For finding the acceleration, I took into account that the **weights** of the painter and the chair are 180 lbs and 30 lbs respectively. I used this idea to perform the following step: $$\text {Total mass of the painter and the chair} = \left(\frac{(180 + 30) \rm lbs}{g}\right) $$ He exerts a **downward** force of 100 lb on the chair. His net motion will be **upwards**. I think the 100 lbs force the person exerts on the chair is transferred to the rope he is pulling on. [![enter image description here][2]][2] But that is just the string he is pulling on. The diagram shows that only one end of the rope is attached to the bosun chair. That end will have an upwards force of (100 + 180 + 30) lbs (as shown in the picture). This way, one end will have a y lbs force and other a force of (100 + 180 + 30) lbs. I don't know if this is possible and I am not totally convinced that the rope is experiencing a force of 100 lbs due to the painter pulling on it. **How is the 100 lbs downwards force affecting the overall system (the painter and bosun's chair)?** [1]: https://i.sstatic.net/ZfP4b.jpg [2]: https://i.sstatic.net/w7hQ5.jpg [3]: https://i.sstatic.net/tSfDD.jpg [4]: https://i.sstatic.net/aE6OU.jpg