In the last problem, the rope is placed on the cylinder as shown. Find maximum tension in the rope.

A uniform rope ABCDE has mass M and it is laid along two incline surfaces (AB and CD) and two horizontal surfaces (BC and DE) as shown in figure. The four parts of the rope AB, BC, CD and DE are of equal lengths. The coefficient of friction (mu) is uniform along the entire surface and is just good enough to prevent the rope from sliding. (a) Find mu (b) x is distance measured along the length of the rope starting from point A. Plot the variation of tension in the rope (T) with distance x. (c) Find the maximum tension in the rope.

A bus is moving with a constant acceleration a=3g//4 towards right. In the bus, a ball is tied with a rope and is rotated in vertical circle as shown. The tension in the rope will be minimum, when the rope makes an angle theta=________

A block of mass M is attached to a uniform rope of mass m . This arrangement is pulled by applying a force F at the rope as shown. Find the tension in the rope (a) at the junction of the rope and the block (b) at the mid point of the rope.

A mountain climber, in the process of crossing between two cliffs by a rope, pauses to rest. She weighs 535 N. As the drawing shows, she is closer to the left cliff than to the right cliff, with the result that the tensions in the left and right sides of the rope are not the same. Find the tensions in the rope to the left and to the right of the mountain climber (see given figure).

A smooth cylinder is fixed with its axis horizontal. Radius of the cylinder is R. A uniform rope (ACB) of linear mass density lambda (kg/m) is exactly of length pi R and is held in semicircular shape in vertical plane around the cylinder as shown in figure. Two massless strings are connected at the two ends of the rope and are pulled up vertically with force T_(0) to keep the rope in contact with the cylinder. (a) Find minimum value of T_(0) so that the rope does not lose contact with the cylinder at any point. (b) If T_(0) is decreased slightly below the minimum value calculated in (a), where will the rope lose contact with the cylinder.

A weight mg is suspended from the middle of a rope whose ends are at the same level. The rope is no longer horizontal. Find the minimum tenstion required to completely straighten the rope.

A rope holds a 10 kg rock at rest on a frictionless inclined plane as sown in the figure. Datermine the tension in the rope.

A block is lying on the horizontal frictionless surface. One end of a uniform rope is fixed to the block which is pulled in the horizontal direction by applying a force F at the other end. If the mass of the rope is half the mass of the block. The tension in the middle of the rope will be