Wait, check: If A moves down 1 m, rope segment from fixed pulley to A shortens by 1 m. That rope length change must come from two places: (1) horizontal movement of B, (2) change in diagonal length from left fixed point to B. That diagonal length change rate = ( v_B \cos\theta ) (because only horizontal motion of B changes the diagonal length at rate ( v_B \cos\theta )).
Constraint: Total rope length ( L = \underbrace{y_B} {\text{horizontal top left to B}} + \underbrace{\sqrt{y_B^2 + H^2}} {\text{diagonal from B up to fixed pulley?}} ) — This gets messy. Let's do the : Two movable pulleys. Wait, check: If A moves down 1 m,
Better: Known result — for a 2:1 mechanical advantage system where B moves horizontally and A moves vertically/incline, velocity relation often is ( v_B = v_A / (2\cos\theta) ) etc. Constraint: Total rope length ( L = \underbrace{y_B}
This example focuses on a common but subtle topic: and relative velocity , which often trips students up. Sample Problem (Inspired by Bedford & Fowler, Ch. 2-3) Problem: Block A is pulled down the inclined plane at a constant speed ( v_A = 2 \text{ m/s} ). The rope system shown (a single continuous rope, fixed at the top left, passing through a movable pulley attached to block B, and then down to block A) causes block B to move horizontally. Determine the velocity of block B when the rope segment between the fixed pulley and block B makes an angle ( \theta = 30^\circ ) with the horizontal. The rope is always taut and inextensible. This example focuses on a common but subtle
Thus: Rope from fixed pulley to A shortens at rate ( v_A ). Rope from left fixed point to B lengthens at rate ( v_B \cos\theta ). Since total rope length constant: ( v_A = v_B \cos\theta ).
For ( \theta = 30^\circ ), ( \cos 30^\circ = 0.866 ):