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Physics 11 Mr. Jean May 14th, 2012.

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Presentation on theme: "Physics 11 Mr. Jean May 14th, 2012."— Presentation transcript:

1 Physics 11 Mr. Jean May 14th, 2012

2 The plan: Video clip of the day Bouncing ball collisions

3 Bouncing Collisions: Bouncing Collisions: When two objects collide and bounce off each other, there are two possible energy interactions. Kinetic energy can be conserved or not conserved. If it is conserved, then we have a perfectly elastic collision. The other possibility is that some of the kinetic energy is transformed into other forms of energy. This is mostly what happens in the real world.

4 The type of problem you will be tasked with solving will have two objects bouncing off each other.
You will know three of the four velocities and solve for the fourth. You may be asked whether kinetic energy is conserved and, if it isn’t, how much kinetic energy is lost.

5 Perfectly Elastic collision with conserved Energy:
Example: Two balls hit head on as shown, what is the final velocity of the second ball if the first one’s final velocity is –1.50 m/s?

6 The general conservation of momentum equation is:
All we have to do is solve for v2’

7 Example #2: Two balls roll towards each other and collide as shown. The second’s ball velocity after the collision is 3.15 m/s. (a) What is the velocity of the first ball after the collision? (b) How much kinetic energy is lost during the collision?

8 A) Velocity:

9 (b) Difference in kinetic energy before and after collision

10 Question #3: Wow this looks just like a test question. A 2
Question #3: Wow this looks just like a test question. A 2.0 kg block is sliding on a smooth table top. It has a totally inelastic collision with a 3.0 kg block that is at rest. Both blocks, now moving, hit the spring and compress it. Once the blocks come to rest, the spring restores itself and launches the blocks. They slide off the right side of the table. The spring constant is 775 N/m. Find: (a) the velocity of the two blocks after the collision. (b) The distance the spring is compressed. (c) The velocity of the blocks after they leave the spring. (d) The distance the blocks travel before they hit the deck after the leave the tabletop. (e) The kinetic energy of the blocks just before they hit the deck.

11 Solutions:

12 C) If energy is conserved in the spring, they should have the same speed when they leave as they had going into the spring. So they should be moving at 4.0 m/s to the right. D) Distance they fall from table:

13 (e) The kinetic energy of the blocks at the bottom (just before they hit) must equal the potential energy at the top of table plus the kinetic energy the blocks had before they began to fall.

14 To do: Order of importance: Questions from Text Work on Science Fair
Presentations begin May 24 & 25th Work on Chapter #7 Review Sheet Practice these questions DO NOT SAVE THIS for the last minute

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