Mechanical Power

1. What can you remember from P3 in Y11? • Definition • Formula • Derived Units • Actual units Mechanical Power

2. To understand how to successfully complete mechanical power problems To apply these skills to the slightly more involved questions at AS Mechanical Power Book Reference : Pages 153-154

3. Some further thoughts on work done from last lesson.... Mechanical Power • Two people each shifting boxes up a flight of stairs... One at a full sprint, while the other takes all day. Currently, through our view of work done, we would calculate the work done by each to be the same • Clearly this conflicts with our everyday definition of “working hard”

4. Definition : • Power is defined as the rate of energy transfer • Formula : • Power = Energy • Time • And when energy is transferred by a force doing work... • Power = Work done • time taken to do that work • Units: • Derived : Js-1 = called Watts (capital W) Mechanical Power

5. Worked Example: A person with a mass of 48kg (480N) climbs a flight of stairs with a height of 10m in 12s Power = Work done time taken to do that work Power = 480N x 10m 12s Power = 400W Mechanical Power

6. Looking at the power Equation again: Power = Work done time taken to do that work Power = Force x distance moved etc... t However, d/t is a very familiar concept..... Power = Force x velocity Engine Power

7. Engines produce motive power. A powered vehicle can be found in different scenarios: • Moving at constant speed & height • Moving & gaining speed • Moving & gaining height • No reason why we couldn’t mix and match! Engine Power

8. Moving at constant speed & height • All of the resistive forces, (friction, air resistance etc) are equal and opposite to the motive force. • The work done by the engine is lost to the surroundings (heat, sound etc) • PowerEngine = ForceResistive x velocity Engine Power Scenario 1

9. Moving & gaining speed • The motive force from the engine exceeds the resistive forces. We have an unbalanced force and so we accelerate • The work done by the engine is the sum of the energy lost to surrounding and the gain in kinetic energy due to the increase in speed • PowerEngine = ForceResistive x velocity + K.E gain per sec • Note K.E. = ½mv2 coming soon..... Engine Power Scenario 2

10. Moving & gaining height • If we are driving up an incline we are gaining height.... If we are gaining height we are gaining gravitational potential energy (GPE) • The work done by the engine is the sum of the energy lost to the surroundings and the gain in gravitational potential energy • PowerEngine = ForceResistive x velocity + GPE gain per sec • Note G.P.E. = mgh coming soon..... Engine Power Scenario 3

11. Show that a juggernaut lorry with an output power of 264kW moving at a constant speed of 70 mph (31 m/s). What are the resistive forces experienced? • PowerEngine = ForceResistive x velocity • ForceResistive = PowerEngine / velocity • ForceResistive = 264,000 / 31 • ForceResistive = 8516N Worked example

12. Power is the rate of energy transfer and can be calculated using: • Power = Work done • time taken to do that work • When powered motion is involved we can use: • Power = Force x velocity • This can be applied to scenarios with either constant level velocity or where there are gains in kinetic energy and/or potential energy due to increases in velocity and height respectively. Summary