Conservation of Mechanical Energy

Mechanical Energy

Mechanical energy is the sum of kinetic energy, gravitational potential energy and elastic potential energy

Mechanical energy = $E_{k} + ∆ E_{p} + E_{H}$

An example of a system that has mechanical energy is a spring and mass system
The change in the total mechanical energy of a system should be interpreted in terms of the work done on the system by any non-conservative force
- A non-conservative force is one that dissipates energy away from the system, such as friction

When a vertical spring is extended and contracted, its energy is converted into other forms
Although the total energy of the spring will remain constant, it will have changing amounts of:
- Elastic potential energy (E_H or EPE)
- Kinetic energy (E_k or KPE)
- Gravitational potential energy (E_p or GPE)

When a vertical mass is hanging on a spring and it moves up and down, its energy will convert between the three in various amounts

Change in Spring Energy, downloadable AS & A Level Physics revision notes

Position	GPE	KE	EPE
A	Maximum	Zero	Some
B	Some	Maximum	Some
C	Minimum	Zero	Maximum

For a horizontal mass on a spring system, there is no gravitational potential energy to consider because this is constant
- The spring would only convert between kinetic and elastic potential energy

In the absence of frictional, resistive forces, the total mechanical energy of a system is conserved
- This means the total kinetic, gravitational potential and elastic potential energy is the same throughout the motion of the system
- Because the total energy of a system is always conserved
There are many scenarios that involve the transfer of kinetic energy into gravitational potential, or vice versa
Some examples are:
- A swinging pendulum
- Objects in freefall
- Sports that involve falling, such as skiing and skydiving

Using the principle of conservation of energy, and taking any drag forces as negligible:

Loss in gravitational potential energy = Gain in kinetic energy

Another example is if a ball on a spring oscillates vertically
In this case:

Loss in gravitational potential energy = Gain in elastic potential energy

The change in energy is the work done on the system. The types of changes depend on the system

Worked example

The diagram below shows a skier on a slope descending 750 m at an angle of 25° to the horizontal.

Kinetic GPE Transfer Worked Example, downloadable AS & A Level Physics revision notes

Calculate the final speed of the skier, assuming that he starts from rest and 15% of his initial gravitational potential energy is not transferred to kinetic energy.

Answer:

Step 1: Write down the known quantities

Vertical height, h = 750 sin 25°
E_k = 0.85 E_p

Kinetic GPE Transfer Worked Example Ans, downloadable AS & A Level Physics revision notes

Step 2: Equate the equations for E_k and E_p

E_k = 0.85 E_p

½ mv² = 0.85 × mgh

Step 3: Rearrange for final speed, v

Step 4: Calculate the final speed, v

Examiner Tip

Exam questions often ask about the 'work done' in the process. This means how much energy is transferred. You must consider all the energy changes in the system and remember that mechanical energy is always conserved. This is essentially the conservation of energy.

Conservation of Mechanical Energy (HL IB Physics)

Revision Note

Mechanical Energy