a) A motorcyclist is climbing a hill at a constant speed of 13 m/s. Calculate the time it takes for the motorcyclist to travel 29 m. (2) b) The picture shows a railway that carries passengers up and down a cliff at the seaside. The top ends of the two passenger cabins are joined by a steel cable around a pulley at the top of the cliff. When one cabin goes down, the other cabin goes up. Explain how this design makes good use of energy transfers in the system. (2) c) A car is travelling along a level road when the driver applies the brakes to stop it. The work done to stop the car is 510 000 J. The car has a mass of 1400 kg. (i) State the value of the kinetic energy of the car when the brakes were first applied. (1) (ii) Calculate the velocity of the car when the brakes were first applied. (3) (iii) The brakes applied an average force of 15 000 N. Calculate the distance it takes for the brakes to stop the car. (2)

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a) A motorcyclist is climbing a hill at a constant speed of 13 m/s - Edexcel - GCSE Physics - Question 3 - 2017 - Paper 1

Question 3

a) A motorcyclist is climbing a hill at a constant speed of 13 m/s. Calculate the time it takes for the motorcyclist to travel 29 m. (2) b) The picture shows a ra... show full transcript

Worked Solution & Example Answer:a) A motorcyclist is climbing a hill at a constant speed of 13 m/s - Edexcel - GCSE Physics - Question 3 - 2017 - Paper 1

Step 1

Calculate the time it takes for the motorcyclist to travel 29 m.

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Answer

To calculate the time taken for the motorcyclist to travel 29 m at a speed of 13 m/s, we use the formula:

t = \frac{d}{v}

where:

$d$ is the distance traveled (29 m)
$v$ is the speed (13 m/s)

Substituting the values:

t = \frac{29}{13} \approx 2.23 \, \text{s}

Thus, the time taken is approximately 2.23 seconds.

Step 2

Explain how this design makes good use of energy transfers in the system.

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Answer

The design of the railway system allows for effective energy transfer between the two passenger cabins. When one cabin descends, it utilizes gravitational potential energy, which is then transferred to the other cabin that ascends, converting that potential energy into kinetic energy. This means that the energy lost by the descending cabin aids the ascent of the opposite cabin, thereby conserving energy within the system and minimizing the need for additional power inputs.

Step 3

State the value of the kinetic energy of the car when the brakes were first applied.

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Answer

The work done to stop the car, which is 510,000 J, is equal to the kinetic energy of the car when the brakes were first applied. Therefore, the kinetic energy is 510,000 J.

Step 4

Calculate the velocity of the car when the brakes were first applied.

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Answer

To find the velocity of the car, we can use the kinetic energy formula:

KE = \frac{1}{2} mv^2

Here, we already know:

$KE = 510,000 \, \text{J}$
$m = 1400 \, \text{kg}$

Rearranging the formula to solve for $v$ gives us:

v = \sqrt{\frac{2 \times KE}{m}}\n$$ Substituting the values:

v = \sqrt{\frac{2 \times 510,000}{1400}} \approx 27 , \text{m/s}

Thus, the velocity of the car is approximately 27 m/s.

Step 5

Calculate the distance it takes for the brakes to stop the car.

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Answer

To calculate the stopping distance, we can use the work-energy principle:

Work = Force \times Distance

The work done to stop the car is equal to the force applied multiplied by the distance. Given that the average force from the brakes is 15,000 N, we rearrange the formula to solve for distance:

Distance = \frac{Work}{Force} = \frac{510,000}{15,000} = 34 \, \text{m}

Hence, the distance it takes for the brakes to stop the car is 34 m.

a) A motorcyclist is climbing a hill at a constant speed of 13 m/s - Edexcel - GCSE Physics - Question 3 - 2017 - Paper 1

Worked Solution & Example Answer:a) A motorcyclist is climbing a hill at a constant speed of 13 m/s - Edexcel - GCSE Physics - Question 3 - 2017 - Paper 1

Calculate the time it takes for the motorcyclist to travel 29 m.

Explain how this design makes good use of energy transfers in the system.

State the value of the kinetic energy of the car when the brakes were first applied.

Calculate the velocity of the car when the brakes were first applied.

Calculate the distance it takes for the brakes to stop the car.

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