Concept explainers
A belt of negligible mass passes between cylinders A and B and is pulled to the right with a force P. Cylinders A and B weigh, respectively, 5 and 20 lb. The shaft of cylinder A is free to slide in a vertical slot and the coefficients of friction between the belt and each of the cylinders are
i.
If there is any slipping between the belt and the cylinders and the angular acceleration of two cylinders.
Answer to Problem 16.39P
There is slipping between cylinder b and belt.
Angular acceleration of cylinder a =
Angular acceleration of cylinder A =
Explanation of Solution
Given:
weight of Cylinder A, wa = 5 lb radius of cylinder A = 4 in.
weight of cylinder B, wb = 20 lb
radius of cylinder B, rB = 8 in.
Magnitude of Force pulling the belt = 3.6 lb
Coefficient of static friction = 0.5
Coefficient of kinetic friction = 0.4
Concept used:
Condition of non-slipping,
Friction force due to static friction must be greater than the pulling force on each cylinder.
Fs> FA, Fs>FB
Mass moment of inertia for a disk is given by-
The tangential force acting on a cylinder will provide the angular acceleration to the cylinder. Therefore,
Calculation:
Mass of cylinder A =
Mass of cylinder B =
Mass moment of inertia of cylinder A =
Mass moment of inertia of cylinder B =
For cylinder A,
For cylinder B,
the net force on the belt should be summation of P, force by cylinder B and force by cylinder C, all equals to 0.
Maximum friction force to avoid slipping Fs =
Condition of slipping is
Conclusion:
There is slipping between cylinder b and belt.
ii.
As there sliping, find the angular acceleration of two cylinders.
Answer to Problem 16.39P
Angular acceleration of cylinder a =
Angular acceleration of cylinder A =
Explanation of Solution
Given:
weight of Cylinder A, wa = 5 lb radius of cylinder A = 4 in.
weight of cylinder B, wb = 20 lb
radius of cylinder B, rB = 8 in.
Magnitude of Force pulling the belt = 3.6 lb
Coefficient of static friction = 0.5
Coefficient of kinetic friction = 0.4
Concept used:
Condition of non-slipping,
Friction force due to static friction must be greater than the pulling force on each cylinder.
Fs> FA, Fs>FB
Mass moment of inertia for a disk is given by-
The tangential force acting on a cylinder will provide the angular acceleration to the cylinder. Therefore,
Calculation:
Mass of cylinder A =
Mass of cylinder B =
Mass moment of inertia of cylinder A =
Mass moment of inertia of cylinder B =
Assuming slipping,
For cylinder B,
Next, for the belt,
Since
There is no slipping on cylinder A
Conclusion:
Angular acceleration of cylinder a =
Angular acceleration of cylinder A =
Want to see more full solutions like this?
Chapter 16 Solutions
Vector Mechanics For Engineers
- Two identical chairs, each weighing 14 lb, are stacked as shown. The center of gravity of each chair is denoted by G. The coefficient of static friction is 0.2 at B (the contact point between the chairs) and 0.35 at A, C, and D. Determine the smallest force P that would cause sliding.arrow_forwardThe 60-lb plank rests on a frictionless roller at A, and the 20-lb triangular support BD. Both bodies are homogenous. The coefficients of static friction are 0.4 at B and 0.3 at D. Determine the largest force P that can be applied to the plank without initiating motion.arrow_forwardParvinbhaiarrow_forward
- 4. A 300-lb cabinet is mounted on casters that can be locked to prevent their rotation. The coefficient of static friction between the floor and each caster is 0.23. Assuming that the casters at both A and B are locked, determine (a) the force Prequired to move the cabinet to the right, (b) the largest allowable value of h if the cabinet is not to tip over. В 24 in.arrow_forwardSITUATION 2: A packing crate of mass 40 kg is pulled by a rope as shown. Knowing that the coefficient of static friction between the crate and the floor is 0.35, answer the following questions: 4. If α = 40°, determine the magnitude of the force P required to move the crate, in N. (ANSWER: 139) 5. If the crate must be moved to the left along the floor without tipping, determine the largest allowable value of α in degrees. (ANSWER: 58)arrow_forwardA 16-lb spool is at rest on an inclined surface. Around its center a cable is wound which travels with the same inclination of the ramp, passes through a frictionless pulley, and is attached to a block B at its other end.The coefficient of static friction between block B and the floor is 0.25. For the position shown, with the given value of α, determine: R (in) = 11,1 in r (in) = 7 in α (°) = 16° 1. The minimum coefficient of static friction that must exist between the reel and the floor of the ramp, so that the reel does NOT slide on the ramp (does not slip). 2.The minimum weight that block B must have for the reel to NOT roll down the ramp dragging block B. Do not allow for the possibility of the block turning or tipping over.arrow_forward
- Please show the correcr solutionarrow_forward1. The coefficients of static and kinetic friction between the 100 – kg block and the inclined plane are 0.30 and 0.20, respectively. Determine (a) the friction force F acting on the block when P is applied with a magnitude of 200 N to the block at rest (b) the force P required to initiate motion up the incline from rest, and (c) the friction force F acting on the block if P = 600N P 100 kg 20° Hs = 0.30 Hk = 0.20 15°arrow_forwardThree packages each of weight m = 9 kg A, B, and C are placed on a conveyor belt that is at rest. Between the belt and both packages A and C, the coefficients of friction are Ms = 0.30 and Mk = 0.20; between package B and the belt, the coefficients are Ms = 0.10 and Mk = 0.08. The packages are placed on the belt so that they are in contact with each other and at rest. Determine which, if any, of the packages will move and the friction force acting on each package. The frictional force acting on A is N The frictional force acting on B is N The frictional force acting on C is N Note: please show correct step by step working out. And double check final answers. Also for frictional force A, B & C show their directions as well. Thanks!arrow_forward
- A block with weight W is pulled up a plane forming an angle a with the horizontal by a force P directed along the plane. μ If is the coefficient of friction between the block and the plane, derive an expression for the mechanical efficiency of the system. Show that the mechanical efficiency cannot exceed 1/2 if the block is to remain in place when the force P is removed.arrow_forward3. A block of mass m = 2.00 kg rests on the left edge of a block of mass M = 8.00 kg. The coefficient of kinetic friction between the two blocks is 0.300, and the surface on which the 8.00 %3D kg block rests is frictionless. A constant horizontal force of magnitude F = 10.0 N is applied to the 2.00-kg block, setting it in motion as shown in Figure. The distance L that the leading edge of the smaller block travels on the larger block is 3.00 m. L M m M (a) Draw a separate free-body diagram for each block. (b) In what time interval will the smaller block make it to the right side of the 8.00-kg block? as (Note: Both blocks are set into motion when the force is applied.) (c) How far does the 8.00-kg block move in the process?arrow_forward3. A vehicle, mass 1400 kg, passes a bend at a speed of 54 km/hr. The radius of curvature of the road is 60 m. Determine the minimum coefficient of static friction between the car tires and the road, so that the car can pass through corners safely.arrow_forward
- International Edition---engineering Mechanics: St...Mechanical EngineeringISBN:9781305501607Author:Andrew Pytel And Jaan KiusalaasPublisher:CENGAGE L