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Conservation of Energy November 21 2014. The conservation of energy.  In a closed system, energy is neither created nor destroyed. Energy simply changes.

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Presentation on theme: "Conservation of Energy November 21 2014. The conservation of energy.  In a closed system, energy is neither created nor destroyed. Energy simply changes."— Presentation transcript:

1 Conservation of Energy November 21 2014

2 The conservation of energy.  In a closed system, energy is neither created nor destroyed. Energy simply changes from one form to another. E initial = E final

3 The conservation of energy.  In a closed system, energy is neither created nor destroyed. Energy simply changes from one form to another. E initial = E final  Mostly, we will use this in situations without friction to say: PE initial + KE initial = PE final + KE final

4 The conservation of energy.  In a closed system, energy is neither created nor destroyed. Energy simply changes from one form to another. E initial = E final  Mostly, we will use this in situations without friction to say: PE initial + KE initial = PE final + KE final  We can also use this in situations where energy is converted to heat due to friction or air resistance to say: E initial – E heat = E final

5 The conservation of energy.  In a closed system, energy is neither created nor destroyed. Energy simply changes from one form to another. E initial = E final  Mostly, we will use this in situations without friction to say: PE initial + KE initial = PE final + KE final  We can also use this in situations with friction / air resistance to say: E initial – E friction = E final Conservation of energy is a very useful tool to solve physics problems! Many problems that can be solved using Newton’s laws can be solved much easier by applying conservation of energy.

6 h=0 N 30 0 h=0.5m v=?u=0 Method 1: Newton’s law d Determine the final velocity of a block that slides down a frictionless ramp. What steps would you have to take?

7 h=0 N 30 0 B A h=0.5m v=?u=0 Method 1: Newton’s law d Determine the final velocity of a block that slides down a frictionless ramp. What steps would you have to take? Step 1: Draw FBD Step 2: Write F net equation and solve for a Step 3: Use motion equations to solve for v

8 h=0 N 30 0 B A h=0.5m v=?u=0 Method 1: Newton’s law v f 2 = v i 2 + 2ad = 2gsinθ d v = 3.2 m/s v = 3.2 m/s Determine the final velocity of a block that slides down a frictionless ramp. What steps would you have to take? Step 1: Draw FBD Step 2: Write F net equation and solve for a Step 3: Use motion equations to solve for v

9 h=0 N 30 0 B A h=0.5m v=?u=0 Method 1: Newton’s law v f 2 = v i 2 + 2ad = 2gsinθ d v = 3.2 m/s v = 3.2 m/s Determine the final velocity of a block that slides down a frictionless ramp. What steps would you have to take? Step 1: Draw FBD Step 2: Write F net equation and solve for a Step 3: Use motion equations to solve for v Method 2: Energy conservation As the object slides down the plane its PE becomes transformed into KE.

10 h=0 N 30 0 h=0.5m v=?u=0 Method 1: Newton’s law v f 2 = v i 2 + 2ax = 2gsinθ d v = 3.2 m/s v = 3.2 m/s Determine the final velocity of a block that slides down a frictionless ramp. What steps would you have to take? Step 1: Draw FBD Step 2: Write F net equation and solve for a Step 3: Use motion equations to solve for v Method 2: Energy conservation As the object slides down the plane its PE becomes transformed into KE. PE initial = KE final mgh = ½ mv 2

11 h=0 N 30 0 h=0.5m v=?u=0 Method 1: Newton’s law v f 2 = v i 2 + 2ad = 2gsinθ d v = 3.2 m/s v = 3.2 m/s Determine the final velocity of a block that slides down a frictionless ramp. What steps would you have to take? Step 1: Draw FBD Step 2: Write F net equation and solve for a Step 3: Use motion equations to solve for v Method 2: Energy conservation As the object slides down the plane its PE becomes transformed into KE. PE initial = KE final mgh = ½ mv 2 v = 3.2 m/s v = 3.2 m/s We get the same answer, but the energy conservation answer is much easier.

12 Examples of Energy Conservation Free fall in the absence of air resistance. A 10 kg ball is dropped from a height of 102 m. What is its velocity when it hits the ground? Initial E = mgh = 10kg * 9.8 m/s 2 *102 m = 10000J Final E = ½ mv 2 = 10000J v = √ (2000) = 45 m/s Free fall with air resistance. A 10 kg ball is dropped from a height of 102 m. When it hits the ground, it has a final velocity of 40m/s. How much energy was ‘lost’ due to air resistance? Initial E = mgh = 10kg * 9.8 m/s 2 *102 m = 10000J Final E = ½ mv 2 = 0.5*10kg*(40m/s) 2 = 8000 J E heat = Initial E – Final E = 10000J – 8000 J = 2000 J

13 A child of mass m is released from rest at the top of a water slide, at height h = 8.5 m above the bottom of the slide. Assuming that the slide is frictionless because of the water on it, find the child’s speed at the bottom of the slide. You Do mgh = ½ mv 2 m cancels on both sides a baby, an elephant and you would reach the bottom at the same speed !!!!!

14 Other examples of conservation of energy: Up and down the track A B C D Assuming that the track is frictionless, at what point(s) is the total energy of the system the same as in point A ? 1. B 1. B 2. C 2. C 3. D 3. D 4. All of the above 4. All of the above 5. none of the above 5. none of the above

15 Other examples of conservation of energy: Up and down the track A B C D Assuming the track is frictionless, at what height will the ball end up? 1. same height as A 1. same height as A 2. lower height than A 2. lower height than A 3. higher height than A 3. higher height than A 4. impossible to determine 4. impossible to determine

16 Other examples of conservation of energy: Up and down the track A B C D If the track does have friction, at what height will the ball end up? 1. same height as A 1. same height as A 2. lower height than A 2. lower height than A 3. higher height than A 3. higher height than A 4. impossible to determine 4. impossible to determine

17 Other examples of conservation of energy: Up and down the track A B C D At what point(s) does the ball have a combination of PE and KE? 1. A 1. A 2. B 2. B 3. C 3. C 4. D 4. D 5. B and C 5. B and C

18 Other examples of conservation of energy: Up and down the track A B C D At what point does the ball have the greatest speed? 1. A 1. A 2. B 2. B 3. C 3. C 4. D 4. D

19 Three balls are thrown from the top of the cliff along paths A, B, and C with the same initial speed (air resistance is negligible). Which ball strikes the ground below with the greatest speed? 1. A 2. B 3. C 4. All strike with the same speed 1. A 2. B 3. C 4. All strike with the same speedh Think about it for a minute … then when I say to, show which answer is correct with a show of fingers #4 is correct All balls have the same initial energy, so all have the same KE when they hit the ground. It depends ONLY on HEIGHT and initial SPEED, not mass, not path !!!!!

20 A pendulum swings back and forth. At which point or points along the pendulum’s path … 1)Is PE greatest? 2)Is KE greatest? 3)Is speed greatest? An ideal pendulum would keep going forever. Why do real pendulums eventually stop? Because some energy is ‘lost’ due to friction and air resistance. G & A D D

21 A car (toy car – no engine) is at the top of a hill on a frictionless track. What must the car’s speed be at the top of the first hill if it can just make it to the top of the second hill? 40m v1v1v1v1 v 2 = 0 20m We Do What is our strategy?

22 A car (toy car – no engine) is at the top of a hill on a frictionless track. What must the car’s speed be at the top of the first hill if it can just make it to the top of the second hill? 40m v1v1v1v1 mgh 1 + ½ mv 1 2 = mgh 2 + ½ mv 2 2 v 2 = 0 PE 1 + KE 1 = PE 2 + KE 2 20m We Do

23 A car (toy car – no engine) is at the top of a hill on a frictionless track. What must the car’s speed be at the top of the first hill if it can just make it to the top of the second hill? m cancels out ; v 2 = 0 40m v1v1v1v1 mgh 1 + ½ mv 1 2 = mgh 2 + ½ mv 2 2 gh 1 + ½ v 1 2 = gh 2 v 1 = 22 m/s v 2 = 0 PE 1 + KE 1 = PE 2 + KE 2 20m v 1 2 = 2g( h 2 – h 1 ) We Do

24 A simple pendulum consists of a 2.0 kg mass attached to a string. It is released from rest at A as shown. Its speed at the lowest point B is: 1.85 m A B PE A + KE A = PE B + KE B You Do

25 A simple pendulum consists of a 2.0 kg mass attached to a string. It is released from rest at A as shown. Its speed at the lowest point B is: 1.85 m A B You Do

26 ● Example: An object of mass 4.0 kg slides 1.0 m down an inclined plane starting from rest. Determine the an inclined plane starting from rest. Determine the speed of the object when it reaches the bottom of speed of the object when it reaches the bottom of the plane if the plane if a. friction is neglected b. constant friction force of 16 N acts a. friction is neglected b. constant friction force of 16 N acts on the object as it slides down. on the object as it slides down. What happens to energy in each case?

27 ● Example: An object of mass 4.0 kg slides 1.0 m down an inclined plane starting from rest. Determine the an inclined plane starting from rest. Determine the speed of the object when it reaches the bottom of speed of the object when it reaches the bottom of the plane if the plane if a. friction is neglected b. constant friction force of 16 N acts a. friction is neglected b. constant friction force of 16 N acts on the object as it slides down. on the object as it slides down. all PE was transformed into KE Friction converts part of KE of the object all PE was transformed into KE Friction converts part of KE of the object into heat energy. This energy equals to into heat energy. This energy equals to the work done by the friction. We say that the work done by the friction. We say that the frictional force has dissipated energy. the frictional force has dissipated energy.

28 ● Example: An object of mass 4.0 kg slides 1.0 m down an inclined plane starting from rest. Determine the an inclined plane starting from rest. Determine the speed of the object when it reaches the bottom of speed of the object when it reaches the bottom of the plane if the plane if a. friction is neglected b. constant friction force of 16 N acts a. friction is neglected b. constant friction force of 16 N acts on the object as it slides down. on the object as it slides down. all PE was transformed into KE Friction converts part of KE of the object all PE was transformed into KE Friction converts part of KE of the object into heat energy. This energy equals to into heat energy. This energy equals to the work done by the friction. We say that the work done by the friction. We say that the frictional force has dissipated energy. the frictional force has dissipated energy. initial energy = final energy initial energy – F fr d = final energy W fr = – F fr d decreases KE of the object W fr = – F fr d decreases KE of the object

29 ● Example: An object of mass 4.0 kg slides 1.0 m down an inclined plane starting from rest. Determine the an inclined plane starting from rest. Determine the speed of the object when it reaches the bottom of speed of the object when it reaches the bottom of the plane if the plane if a. friction is neglected b. constant friction force of 16 N acts a. friction is neglected b. constant friction force of 16 N acts on the object as it slides down. on the object as it slides down. all PE was transformed into KE Friction converts part of KE of the object all PE was transformed into KE Friction converts part of KE of the object into heat energy. This energy equals to into heat energy. This energy equals to the work done by the friction. We say that the work done by the friction. We say that the frictional force has dissipated energy. the frictional force has dissipated energy. initial energy = final energy initial energy – F fr d = final energy W fr = – F fr d decreases KE of the object W fr = – F fr d decreases KE of the object PE A = KE B PE A – F fr d = KE B PE A = KE B PE A – F fr d = KE B

30 ● Example: An object of mass 4.0 kg slides 1.0 m down an inclined plane starting from rest. Determine the an inclined plane starting from rest. Determine the speed of the object when it reaches the bottom of speed of the object when it reaches the bottom of the plane if the plane if a. friction is neglected b. constant friction force of 16 N acts a. friction is neglected b. constant friction force of 16 N acts on the object as it slides down. on the object as it slides down. all PE was transformed into KE Friction converts part of KE of the object all PE was transformed into KE Friction converts part of KE of the object into heat energy. This energy equals to into heat energy. This energy equals to the work done by the friction. We say that the work done by the friction. We say that the frictional force has dissipated energy. the frictional force has dissipated energy. initial energy = final energy initial energy – F fr d = final energy W fr = – F fr d decreases KE of the object W fr = – F fr d decreases KE of the object PE A = KE B PE A – F fr d = KE B PE A = KE B PE A – F fr d = KE B mgh = ½ mv 2 mgh – F fr d = ½ mv 2 mgh = ½ mv 2 mgh – F fr d = ½ mv 2 20 – 16 = 2.5 v 2 20 – 16 = 2.5 v 2 v = 1.4 m/s v = 1.4 m/s

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