1) At the instant shown, the system is at rest and the k=4 kipn spring is...
Question 7 (5 marks): At the instant shown in figure below, the block has a velocity of 8 ft s-1. a) Find the maximum value of the deflection of the spring. b) Find the distance l through which the block travels, after rebound, before it comes to rest. 30 in 8 ft/s 8 lb/in - 4 lb mono- - M = 0.15
Question 7 (5 marks): At the instant shown in figure below, the block has a velocity of 8 ft s-1 a) Find the maximum value of the deflection of the spring. b) Find the distance I through which the block travels, after rebound, before it comes to rest. 30 in 8 lb/in M0.15
Dynamics:
17. For the system shown, determine the velocity of block B after it has dropped 1.75 ft. The system is at rest when weight B is dropped and the spring is at its free length. (i.e. unloaded) k = 60 lb/ft 4.0 ft Dia le 20 slug-ft B 2.0 ft Dia 45 lb
17. For the system shown, determine the velocity of block B after it has dropped 1.75 ft. The system is at rest when weight B is...
2. The spring with spring constant k = 40 Lb/ft is initially comp when the 12 Lb block is released from rest on the smooth hor K-40 Lb/ft is initially compressed 1.5 ft Find: a. P.E.s, the initial elastic potential energy stored in the spring in (ft lb) b. Vmax, the maximum velocity of the block. 1266 JO00001000
A slender 9 lb rod can rotate in a vertical plane about a pivot at B. A spring of constant k-30 lb/ft and of unstretched length 6 in. is attached to the rod as shown. The rod is released from rest in the position shown. 1) Determine its angular velocity after the rod has rotated through 45.(1 point) 2) Determine the reaction force at pivot point B after the rod rotated through 45. (1 point) 24 in 5 in. 4...
Q.1. For the system shown in Figure 1, the spring constant = 200 N/m. a) Write the complete Energy Equation for the solution to the problem (all terms must be included) b) If the system is initially at rest and the weight and inertia of the pulley are neglected, determine the angular velocity of A after Block B has dropped 600 mm. c) Calculate the maximum displacement of block B when it is lowered slowly. (Use Work, Power, Energy Method)....
The 50-10 block rests on the rough surface for which the coefficient of kinetic friction is 0.2. A force F = (40 + s2) lb, where s is in ft, acts on the block in the direction shown. If the spring is originally unstretched (s = 0) and the block is at rest, determine the power developed by the force the instant the block has moved s = 1.5 ft. F. 30° k = 20 lb/ft
Problem 3: The 50-1b block rests on the rough surface for which the coefficient of kinetic friction is 0.2. A force F = (40 + s2) lb, where s is in ft, acts on the block in the direction shown. If the spring is originally unstretched (s = 0) and the block is at rest, determine the power developed by the force the instant the block has moved s = 1.5 ft. F 30° k = 20 lb/ft
The system is released from
rest with the spring initially stretched 5.8 in. Calculate the
velocity v of the cylinder after it has dropped 1.5 in. The spring
has a stiffness of 3.5 lb/in. Neglect the mass of the small
pulley.
Chapter 3, Problem 3/142 (video solution to similar problem attached) XIncorrect The system is released from rest with the spring initially stretched 5.8 in. Calculate the velocity v of the cylinder after it has dropped 1.5 in. The spring...
1. (a) The 7-kg block is moving with an initial speed of 8 m/s. If the coefficient of kinetic friction between the block and plane is 0.3, determine the compression in the spring when the block momentarily stops JkA - BONm 8 m/s (b) The 50 lb block rests on the rough surface for which the coefficient of friction is pl = 0.25. A force F= (30+2s) Ib, where s is in ft, acts on the block in the direction...