Mechanical Energy

Got a Lot of Potential

K + P = M

K to the E

Rollercoaster

Concepts

100

Which has the highest PE?

A 1.1 kg squirrel in a tree 10.0 m from the ground

A 0.22 kg bird in a tree 20.0 m from the ground

A 2.0 kg chipmunk in a tree 5.0 m from the ground

Mr. G (65 kg) who is levitating at 15 cm from the ground

The squirrel

100

How much mechanical energy in Joules does an object have if it has 0.50 kJ potential and 10 J kinetic energy?

510 J

100

Mr. G drops a 1.0 kg ball from 1.0 m high, what is its max KE during the fall?

9.8 J

100

Solve for original ME at station 1 (3SF)

1,960 J (or 1.96 KJ)

100

Consider a roller-coaster as we do, neglecting air resistance, rolling friction, weight shifting... Then describe what happens to ME after the coaster has began its trip downwards, after reaching the apex

ME remains constant for a system without forces to oppose / change its motion

200

SI base units for PE (the answer is not Joules)

kg*m²/s²

200

A 750 g object is pushed off a 175 m cliff. When it is 75 m from the bottom, how much ME does the object have?

1,300 J (or 1.3 kJ)

200

Mr. G drops a 1.0 kg ball from 1.0 m high, what is its max velocity during the fall?

4.4 m/s

200

Calculate the velocity at station 3 (3SF)

8.85 m/s

200

What happens when Mr. G falls out of a tree & is halfway down (regarding ME, KE & PE)?

ME is constant

PE = KE (both are 1/2 the value of ME)

300

PE of a 10 kg object that is on a ledge 10 m from the ground

980 J

300

How much mechanical energy does an object have if it is 10.0 kg, 10.0 m above the ground and is freefalling at a velocity of 10.0 m/s?

1,480 J

300

A 55 kg cliff diver is halfway to the ocean surface. If her ME = 23,716 J, Calculate her KE at this point

11,858 J

300

Calculate the KE at station 4

900 J

300

Consider a roller-coaster in a real world situation, facing air resistance, rolling friction, weight shifting & describe what happens to ME as it continues through its course after it has already plunged down the initial drop from its apex

ME decreases, until it becomes 0, so it can go again with the assistance of a chain / pulley to take it back up to the apex (sometimes assisted via braking systems)

400

An object is hanging from a hook 15 m above the ground. If it has a PE of 970 J, what is its mass?

6.6 kg

400

A 55 kg cliff diver is halfway to the ocean surface. If her ME = 23,716 J, Calculate her velocity at this point

20.8 m/s

400

A 5.0 kg projectile has 36 J of KE & a ME of 73 J, calculate the velocity

3.8 m/s

400

Calculate the velocity at station 2 (3SF)

4.43 m/s

400

Mr. G is climbing a tree at a relatively constant velocity.

At the top, he stops and the branch breaks & he falls out

Eventually he lands on the ground knocked unconscious

Explain ME during the 4 situations (climbing, just before the branch breaks, falling, & on the ground 💀)

While climbing ME increases (PE increasing, KE unchanging)

At the top, just before the branch breaks, ME = maximum, KE = 0

Falling: Increasing KE, Decreasing PE

On the ground, ME & KE = 0

500

An empty 3,300 kg elevator is 24 m above the ground level when its cables snap. What will be its maximum velocity as it falls down?

22 m/s

500

A 55 kg cliff diver is halfway to the ocean surface. If her ME = 23,716 J, Calculate her hang time up to this point

2.12 s

500

A 750 g object is pushed off a 175 m cliff. When it is 75 m from the bottom, what is the velocity of the object?

44 m/s

500

Calculate the height at station 4 (3 SF)

What is 2.16 m

500

Show (by manipulating formulas) that an object's velocity falling off a cliff that is halfway down to the ground level is mass independent, but height (and gravity) dependent

ME = PE + KE

At 1/2 h, PE = KE

mgh=1/2mv^2

2gh=v^2

v = (2gh)^1/2