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Springs and Hooke’s Law

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1 Springs and Hooke’s Law
Physics 11

2 Springs A mass-spring system is given below. As mass is added to the end of the spring, how would you expect the spring to stretch?

3 Springs

4 Springs 2 times the mass results in a 2 times of the displacement from the equilibrium point… 3 time the mass… 3 times the displacement…

5 What kind of energy is this?
Potential Energy Elastic Potential Energy to be exact!

6 What else besides springs has elastic potential energy?
Diving boards Bows (bow and arrows) Bungee cord

7 Hooke’s Law Fspring: Applied force
X : displacement of the spring from the equilibrium position (units: m) K: the spring constant (units: N/m)

8 Hooke’s Law the restoring force is opposite the applied force. (negative sign) Gravity applied in the negative direction, the restoring force is in the positive direction

9 Example An archery bow requires a force of 133N to hold an arrow at “full draw” (pulled back 71cm). Assuming that the bow obeys Hooke’s Law, what is its spring constant?

10 F = kx 133 = k(0.71) k = 133/0.71 k = N/m  190 N/m

11 Restoring Force The restoring force is the force that is needed to put the spring back to equilibrium. Example: If you stretch a spring by 0.5m and you had to use 150N of force, the restoring force is -150N.

12 Practice Problems Textbook Page 258 35-37

13 Elastic Potential Energy of a Spring
Formula: Ee = ½ kx2 Units: Joules (J)

14 Example: A spring with spring constant 75 N/m is resting on a table.
A) If the spring is compressed a distance of 28cm, what is the increase in its potential energy? B) What force must be applied to hold the spring in this position?

15 Answer: A) Ee = ½ kx2 Ee = ½ (75)(0.28)2 Ee = 2.9 J B) F = kx
F = 21 N

16 Practice Problems Page 261, questions 38, 39, 40
Page 261 (Section Review) 1, 2, 3, 4, 7

17 Conservation of Energy with a Spring
Ex. 1: A 4.0 kg block slides across a frictionless table with a velocity of 5.0m/s into a spring with a stiffness of 2500 N/m. How far does the spring compress?

18 Answer X = 0.20m

19 Example 2: A 70. kg person bungee jumps off a 50.m bridge with his ankles attached to a 15m long bungee cord. Assume the person stops at the edge of the water and he is 2.0m tall, what is the force constant of the bungee cord?

20 Answer: 64 N/m Conservation of Energy Worksheet

21 Practice Problems Textbook Page 261 38-40 Section review (p 261) 1-10

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