You pull on a string with a horizontal force of magnitude Fyb = 69 N that is attached to a block of mass mb 6 kg, then to the axle of a solid cylinder of mass m = 4.4 kg and radius r = 0.5 m, then to a spring of spring constant k = 115 N/m. This is all done on an inclined plane where there is friction (μs = 0.65 and μk = 0.36), and the incline angle is 0 = 30 degrees. Everything starts at rest, and the spring is unstretched. The block slides down the plane, the cylinder rolls down the plane (without slipping), and the spring stretches. k lllllllll Fyb b 0+ ▾ Speed First, what is the speed of the block and cylinder after you have pulled the block and cylinder 172 cm down the plane? V=

You pull on a string with a horizontal force of magnitude Fyb = 69 N that is attached to a block of mass mb 6 kg, then to the axle of a solid cylinder of mass m = 4.4 kg and radius r = 0.5 m, then to a spring of spring constant k = 115 N/m. This is all done on an inclined plane where there is friction (μs = 0.65 and μk = 0.36), and the incline angle is 0 = 30 degrees. Everything starts at rest, and the spring is unstretched. The block slides down the plane, the cylinder rolls down the plane (without slipping), and the spring stretches. k lllllllll Fyb b 0+ ▾ Speed First, what is the speed of the block and cylinder after you have pulled the block and cylinder 172 cm down the plane? V=

Name: You pull on a string with a horizontal force of magnitude Fyb = 69 N
Uploaded: 2024-03-20T06:58:04.000Z
Channel: Bartleby
Description: You pull on a string with a horizontal force of magnitude Fyb = 69 N that is attached to a block of massm 6 kg, then to the axle of a solid cylinder of mass me = 4.4 kg and radius r = 0.5 m, then to a spring ofspring constant k = 115 N/m. This is al

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter1: Units, Trigonometry. And Vectors

Section: Chapter Questions

Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...

See similar textbooks

Similar questions

A mathematical pendulum of mass 1.0 kg and length 1.0 m is moved by an angle 60° from the vertical axis and then let go. How fast does the wight move at the moment the rope encloses an angle of 30° with the vertical axis?
This relates the initial speed of the pendulum box to the height that it goes: V =squr 2 g h . The numbers: g = 9.81 m/s2 h = 3.6 cm V = squr 2 × 9.81 × 3.6 = 8.4 Correct the calculation or the answer
A block of mass m = 3.5 kg is attached to a spring with spring constant k= 720 N/m. It is initially at rest on an inclined plane that is at an angle of θ = 23° with respect to the horizontal, and the coefficient of kinetic friction between the block and the plane is μk = 0.13. In the initial position, where the spring is compressed by distance of d = 0.19 m, the mass is at its lowest position and the spring is compressed the maximum amount. Take the initial gravitational energy of the block as zero. a) If the spring pushes the block up the incline, what distance, L in meters, will the block travel before coming to rest? The spring remains attached to both the block and the fixed wall throughout its motion.
We are looking at an elastic pendulum which is constructed by suspending a weight of mass m = 0.100 kg in a spring with spring constant k = 2.00 N/m. At the start of the task we will consider the spring as ideal, meaning that the spring force can be described as F = −ky. Determine the value of the parameters y0, A, δ and ω if we start up the pendulum with y(0) = 0.100 m and v(0) = 0. What is the interpretation of the various parameters?
A block of mass M is pressed up against a spring of spring constant k. The block is not attached to the spring. It can slide along a board tilted at an angle 0 to the horizontal. Initially the block is released from rest when the spring is compressed a distance d. a) Find the highest point that the block reaches b) Take the mass to be 3.0 kg, the spring constant to be 240 N/m, d=0.03 m, and the angle to be 37°. Find the highest point that the block reaches. oooo Relaxed Here
You pull on a string with a horizontal force of magnitude F = 40 N that is attached to a block of mass m, = 7.5 kg, then to the axle of a solid cylinder of mass m. = 4.8 kg and radius r = 0.4 m, then to a spring of spring constant k = 140 N/m. This is all done on an inclined plane where there is friction ( 4s = 0.68 and , = 0.31 ), and the incline angle is e = 25 degrees. Everything starts at rest, and the spring is unstretched. The block slides down the plane, the cylinder rolls down the plane (without slipping), and the Cylinder, Spring, and Block on Ramp spring stretches. 000000000- b yb First, what is the speed of the block and cylinder after you have pulled the block and cylinder 86 cm down the plane?
When s = 0, the spring on the firing mechanism is unstretched. If the arm is pulled back such that s = 103 mm and released, determine the speed of the 0.39-kg ball when θ = 60°. The spring constant is k =1,518 N/m. Assume all surfaces of contact to be smooth. Neglect the mass of the spring and the size of the ball.
A block with mass 6.00 kg sliding on a horizontal frictionless surface is attached to one end of a horizontal spring (with constant 110.0 N/m) which has its other end fixed. If the maximum distance the block slides from the equilibrium position is equal to 22.0 cm, what is the speed of the block (in cm/s) at the instant when it is a distance of 11.0 cm from the equilibrium position? Round your answer to 1 decimal place.
The force required to compress a non-standard spring as a function of displacement from equilibrium x is given by the equation F(x) = ax2 - bx, where a = 55 N/m2, b = 8 N/m, and the positive x direction is in the compression direction of the spring.
Fish are hung on a spring scale to determine their mass (most fishermen feel no obligation to report the mass truthfully). (a) What is the force constant (in N/m) of the spring in such a scale if it stretches 8.40 cm for a 13.0 kg load? N/m (b) What is the mass (in kg) of a fish that stretches the spring 5.50 cm? kg (c) How far apart (in mm) are the half-kilogram marks on the scale? mm Additional Materials O Reading 2. [-/2 Points] DETAILS OS 05. MY When a 66.8 kg man stands on a pogo stick, the spring is compressed 0.174 m. (a) What is the force constant of the spring? (Enter your answer in N/m.) N/m (b) Will the spring be compressed more when he hops down the road? O Yes MacBook Air F2 E3 D00 F4
5. 0 m feeeee A mass m = 25 kg is sitting on a slope with = 20°. There is no friction between the mass and the slope. The mass is attached to a spring with rest length lo = 5 cm that is mounted at the top of the slope. When the mass is released, the spring stretches an amount Ax = 6.2 cm (as measured along the slope, total length is now 11.2 cm) when the system reaches static equilibrium. a.) Draw the free-body diagram of the mass, showing all forces acting on the mass. b.) Calculate the value of the spring constant, k.
A spring AB of natural length 0.5 m and modulus of elasticity 25 N is fixed at A. The other end is joined to another spring BC of natural length 0.8 m and modulus of elasticity 40 N. A weight WN is attached at C and the system hangs vertically in equilibrium so that AC=2m. (i) Find the extension of the two springs. (ii) Find W. Answer: (i) (ii) 0.35 m, 0.35m 17.5 N