A cyclist is riding a bicycle at a steady velocity of 12 m/s. The cyclist and bicycle have a total mass of 68 kg. (a) Calculate the kinetic energy of the cyclist and bicycle. Use the equation KE = $ \frac{1}{2} \times m \times v^2 $ (b) Describe the energy transfers that happen when the cyclist uses the brakes to stop. (c) The cyclist starts to cycle again. The cyclist does 1600 J of useful work to travel 28 m. Calculate the average force the cyclist exerts. (d) An athlete uses a training machine in a gym. The display on the machine shows the time spent on the machine and the amount of energy transferred during a training session. Figure 5 shows the displays for two different sessions by the same athlete. Explain what the displays show about the average power of the athlete in each of these two sessions.

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A cyclist is riding a bicycle at a steady velocity of 12 m/s - Edexcel - GCSE Physics - Question 3 - 2018 - Paper 1

Question 3

A cyclist is riding a bicycle at a steady velocity of 12 m/s. The cyclist and bicycle have a total mass of 68 kg. (a) Calculate the kinetic energy of the cyclist an... show full transcript

Worked Solution & Example Answer:A cyclist is riding a bicycle at a steady velocity of 12 m/s - Edexcel - GCSE Physics - Question 3 - 2018 - Paper 1

Step 1

Calculate the kinetic energy of the cyclist and bicycle.

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Answer

To calculate the kinetic energy (KE), we use the formula:
$KE = \frac{1}{2} \times m \times v^2$
Where:

m = 68 kg (mass of cyclist and bicycle)
v = 12 m/s (velocity)
Substituting the values:
$KE = \frac{1}{2} \times 68 \times (12)^2$
$KE = \frac{1}{2} \times 68 \times 144$
$KE = 4896 J$
Thus, the kinetic energy of the cyclist and bicycle is approximately 4900 J.

Step 2

Describe the energy transfers that happen when the cyclist uses the brakes to stop.

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Answer

When the cyclist uses the brakes, the kinetic energy of the cyclist and the bicycle decreases. This kinetic energy is then transformed into thermal energy due to friction between the brake pads and the wheels. As a result, the thermal energy of the brakes increases, causing them to heat up. This process essentially converts mechanical energy into thermal energy.

Step 3

Calculate the average force the cyclist exerts.

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Answer

To find the average force exerted by the cyclist, we use the formula:
$ext{Force} = \frac{\text{Work}}{\text{Distance}}$
In this case,

Work = 1600 J
Distance = 28 m
Substituting the values:
$\text{Force} = \frac{1600}{28}$
$\text{Force} \approx 57.14 N$
Thus, the average force exerted by the cyclist is approximately 57 N.

Step 4

Explain what the displays show about the average power of the athlete in each of these two sessions.

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Answer

To calculate the average power for each session, we use the formula:
$\text{Power} = \frac{\text{Energy}}{\text{Time}}$
For Session 1:

Energy = 45.2 kJ = 45200 J
Time = 300 s
Thus,
$\text{Power}_{1} = \frac{45200}{300} \approx 150.67 W$
For Session 2:
Energy = 37.9 kJ = 37900 J
Time = 300 s
Thus,
$\text{Power}_{2} = \frac{37900}{300} \approx 126.33 W$
In summary, the athlete developed more power in Session 1 (approximately 150.67 W) compared to Session 2 (approximately 126.33 W).

A cyclist is riding a bicycle at a steady velocity of 12 m/s - Edexcel - GCSE Physics - Question 3 - 2018 - Paper 1

Worked Solution & Example Answer:A cyclist is riding a bicycle at a steady velocity of 12 m/s - Edexcel - GCSE Physics - Question 3 - 2018 - Paper 1

Calculate the kinetic energy of the cyclist and bicycle.

Describe the energy transfers that happen when the cyclist uses the brakes to stop.

Calculate the average force the cyclist exerts.

Explain what the displays show about the average power of the athlete in each of these two sessions.

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