1. Elastic Potential Energy & Simple Harmonic Motion
Robert Hooke
Hooke’s Law
Applications
Elastic Potential Energy
Energy Transfer
Simple Harmonic Motion
Practice

2. TeachWithFergy Preview File
If you decide to purchase and the lesson isn't exactly what you need or thought it was, I will refund you 100% via PayPal.
Some slides appear blank because they have been removed.
Other slides may have on them, this represents writing that has been removed.
Please note that the Entire Unit Package can also be purchased at a steep discount from my Store.

3. Sir Robert Hooke ( )
Hooke's Law gives the relationship between the force applied to a spring and the amount the spring is stretched.

4. Hooke’s Law
The amount of stretch or compression (x) for a given force is determined by the Spring Constant, “k”, of the spring.

5. This Slide Has Been Removed

6. Check Your Understanding
A student stretches a spring horizontally a distance of 15 mm by applying a force of 0.18 N [E].
Determine the …………..
What ……………..

7. Check Your Understanding
A ball of mass kg is hung from a vertical spring that is allowed to stretch slowly from its unstretched equilibrium position until it comes to a new equilibrium position 0.15 m below the initial one.
Determine the force constant of the spring.
If the ball is returned to the spring’s unstretched equilibrium position and then allowed to fall, what is the net force on the ball when it has dropped m?
Determine the acceleration of the ball at the position specified in (b).

8. Check Your Understanding
In a tire pressure gauge, the pressurized air from the tire exerts a force F Applied that compresses a spring.
The force constant of the spring in the gauge is 3.2 x 102 N/m. Determine the magnitude of the force ………….

9. This Slide Has Been Removed

10. Elastic Potential Energy
Ee - ________________

11. Elastic Potential Energy
The energy stored can be calculated with the following expression:

12. Energy Transfer
Elastic potential energy can be transformed into other forms of energy, such as:
the kinetic energy of an arrow shot by a bow
the gravitational potential energy of a pole-vaulter at the top of the jump.
Minimum Elastic Energy, Maximum Potential Energy
Maximum Elastic Energy, Minimum Potential Energy

13. This Slide Has Been Removed

14. Elastic Potential Energy
You can use the graph of Hooke’s Law to determine the quantity of potential energy stored in the spring.
Calculate the …………..

15. Simple Harmonic Motion
The repetitive movement back and forth through an equilibrium, or central position, so that the maximum displacement on one side of this position is equal to the maximum displacement on the other side.
The force responsible for the motion is always directed toward the equilibrium position and is directly proportional to the distance from it.
Equilibrium Position

16. Simple Harmonic Motion
______________
The velocity is at a maximum at the equilibrium point as spring compression (causes acceleration in the opposite direction) hasn’t started yet.

17. This Slide Has Been Removed

18. Check Your Understanding
A 0.45-kg mass is attached to a spring with a force constant of 1.4 x 102 N/m. The mass-spring system is placed horizontally, ……………

19. Check Your Understanding
A 0.25-kg mass is attached to the end of a spring that is attached horizontally to a wall. When the mass is displaced 8.5 cm and then released, it undergoes SHM. The force constant of the spring is 1.4 x 102 N/m. The amplitude remains constant.
How far does the mass move in the first five cycles?
What is the period of vibration of the mass-spring system?

20. Energy in Simple Harmonic Motion
________________
According to the law of conservation of energy, when the mass is released, the total energy (ET) of the system ………..

21. This Slide Has Been Removed