Syllabus Edition

First teaching 2020

Last exams 2024

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Energy: Conservation, Work, Power & Efficiency (CIE AS Physics)

Exam Questions

2 hours40 questions
1a
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2 marks

A small child is does work on a large suitcase by pushing it a along as smooth floor, as shown in Fig. 1.1. 

5-1-1a-e-work-done-child-suitcase

Fig. 1.1. 

State the definition of work done and write the equation.

1b
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2 marks

The suitcase is moved back to its original position by an adult who pulls it at an angle of 70° to the floor, as shown in Fig. 1.2.

5-1-1b-e-work-done-adult-suitcase

Fig. 1.2.

Write an expression for the work done on the suitcase by the adult in terms of force F, distance d and the angle 70°.

1c
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4 marks

In moving the suitcase the child and adult both exerted equal forces of 20 N. They each move the suitcase a distance of 2.5 m.

Calculate the work done by

(i)
the child
[2]
(ii)
the adult.
[2]

1d
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3 marks

State whether the child or the adult are more efficient at moving the suitcase, explaining your reasoning.

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2a
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2 marks

A block of weight 4.25 × 103 N is placed on a frictionless slope inclined at 30° to the horizontal as shown in Fig. 1.1.

5-1-2a-e-vector-block-on-a-slope

Fig. 1.1.

The block is moved up the slope at constant speed by applying a force parallel to the slope.

Calculate the component of the weight of the block which acts parallel to the slope.

2b
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2 marks

Calculate the work done in moving the barrel a distance of 6.0 m up the slope.

2c
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2 marks

The block in part (a) is pushed 6.0 m up the slope in 18 s.

Calculate the power needed to move the block in this amount of time.

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3a
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2 marks

A beaker is filled with ice and then an electric heater placed into it, as shown in Fig. 1.1. The heater is turned on and heats up until it glows red.

5-1-3a-e-melting-ice

Fig. 1.1.

A student states that when the ice is being heated up the total amount of energy in the ice remains the same.

State the principle of conservation of energy.

3b
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3 marks

Explain whether the student is correct, giving your reason.

3c
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3 marks

Identify the energy transfers involved in heating the ice by filling in the missing words below.

5-1-3c-e-conservation-of-energy-transfers

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1a
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1 mark

Define work done by a force.

1b
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2 marks

A heavy bag is pulled across a rough surface at a constant speed. 

Describe and explain how work is done in this situation.

1c
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3 marks

A crane is used to lift the bag from the ground onto the loading area of a truck.

Fig. 1.1 shows the crane moving the bag from the ground to the truck.

5-1-1c-m-5-1-work-bag-crane-lift-cie-ial-sq

The mass of the bag is 64 kg. The crane takes 0.1 minutes to lift the bag from the ground to the loading area of the truck.

Calculate the rate of work done by the crane when moving the bag.

1d
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6 marks

The crane is powered using an electric motor. The efficiency of the crane is 74 %.

The crane is used to load approximately 400 bags with an average mass of 60 kg each day.

(i)
Calculate the power used by the crane's motor to lift the bag in part (c).
[1]
(ii)
The typical working efficiency of a crane is 80%. 
    
Explain how the difference in efficiency may affect the number of bags the crane can lift in a day.
[3]
   
(iii)
Suggest one change which could increase the efficiency of the motor and explain how it would achieve this.
[2]

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2a
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1 mark

Engineers around the world are working on ways to provide enough energy to sustain human activity.

Off-shore wind farms use the kinetic energy of strong offshore winds to generate electricity.

Fig. 1.1 shows an offshore wind power installation.

5-1-2b-m-offshore-wind-farm-cie-ial-sq

State the definition of power and give the units used to measure power output.

2b
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3 marks

The UK is a world leader in the installation of offshore wind power.

Located in the North Sea off the east coast of England, the Hornsea Phase 2 (Hornsea Two) offshore wind farm was the largest wind farm in the world when it opened in 2022.

It uses 165 turbines rated at 8 MW each, to generate 1.4 GW of energy, enough to supply more than 1.3 million homes. Each turbine has blades of length 81 m.

The power output of a single turbine can be calculated using

               P space equals space 1 half space rho A v cubed

where ρ is the density of the air, A is the area swept out by the blades and v is the wind speed.

Calculate the average wind speed at Hornsea Two.

The density of air is 1.225 kg m−3.

2c
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5 marks

The Hornsea wind turbines are found to have an efficiency of 40%.

   
(i)
Calculate the energy required from the wind every second to achieve the desired power output.
[2]
 
(ii)
Explain why it is impossible to transfer all the energy available from the wind.
[3]

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3a
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5 marks

A hybrid electric bike is fitted with both pedals and a battery. The cyclist can use pedals only, pedals and battery, or battery only as they ride. Fig 1.1 shows a cyclist riding a hybrid electric bike up an inclined road.

At one hill the cyclist switches to battery only. A road sign at the base of the hill states that it has an incline of 5%, meaning that for every 100 m travelled horizontally, the height increases by 5 m.

The bike travels at a steady speed of 6.0 m s−1

5-1-3a-m-bike-incline-cie-ial-sq

The mass of the rider and bike combined is 72.8 kg. The distance from the base to the top of the hill is 35 m.

Calculate the minimum power required from the battery. Assume that there is no energy loss due to friction.

3b
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5 marks

Near the top of the hill, the cyclist stops pedalling and the bicycle freewheels for 1.6 s until coming to a stop.

The frictional forces which slow down the motion are constant.

  
(i)
Show that the bicycle travels about 5 m before coming to a stop.
[2]
  
(ii)
Calculate the magnitude of the frictional force which slows the bicycle down.
[3]

3c
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7 marks

Once the cyclist reaches the top, they turn off the motor and head back down to the bottom. At the bottom of the hill, they reach a velocity of 8.8 m s−1.

   
(i)
Calculate the energy the cyclist has at the top of the hill.
[2]
(ii)
Calculate the energy the cyclist has at the bottom of the hill.
[2]
(iii)
Compare the two values you have calculated and suggest a reason for the difference.
[3]

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4a
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3 marks

Fig. 1.1 shows a ride at a water park. Customers are seated in a circular glider which is subject to an accelerating force at point A.

5-1-4a-m-rollercoaster-gpe-ke-cie-ial-sq

The first part of the ride is horizontal. In this section, the glider is accelerated from rest at point A to 30 m s−1 at point B.

At point B, the track is angled at 30° to the horizontal for 2.5 m.

The total mass of the glider and passengers is 350 kg.

Calculate the work done by the glider against gravity when it travels through point B.

4b
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4 marks
(i)
Calculate the maximum height above A that the passengers and glider could reach.
[3]
(ii)
Point C is 28 m above A.
 
Suggest why the ride is built to this height instead of the maximum height calculated in (i).
[1]
4c
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3 marks

At point C, the glider stops momentarily before sliding down the incline until it lands in the water pool at point D with a speed of 22 m s−1.

Determine the efficiency of the energy transfer between points C and D.

4d
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3 marks

Once the glider reaches point D, the water applies a decelerating force until it comes to a stop after 8.5 m.

Calculate the decelerating force exerted on the glider by the water.   

State any assumptions you made in your calculation.

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5a
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2 marks

Pumped hydroelectric systems store large bodies of water behind a dam. When electricity is needed in the grid, the dam is lifted, allowing water to flow from the upper reservoir.

One such power station, known as the Cruachan power station, is shown in Fig. 1.1. This facility has been producing hydroelectric power since 1965.

5-1-5a-m-5-1-energy-sources-power-station-cie-ial-sq

The vertical distance between the base of the upper reservoir and the turbine is 396 m. This arrangement allows Cruachan power station to produce a power output of 0.62 GW with an efficiency of 76%.

Determine the energy transferred by the water each second in order to achieve this power output.

5b
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5 marks

Water is made to flow out of the upper reservoir through connecting pipes at a rate of 200 m3 per second. The density of water is 1.0 × 103 kg m−3

(i)
Use this flow rate to determine the energy transferred by the water each second.
[4]
(ii)
Explain why this value is not consistent with the energy transfer rate calculated in (a).
[1]
5c
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3 marks

Estimate the depth of the water held in the upper reservoir. State any assumptions made.

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