gcse physics electricity calculations students should be ......gcse physics electricity calculations...
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 1
1. Calculate the amount of charge that flows when a current of 3.8 A flows for 9 minutes.
2. Calculate the current when 1.9 C of charge flows in 18 seconds.
3. Calculate the potential difference across a component with a resistance of 260 Ω when a current of 35 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 1.5 V causes a current of 23 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 10.5 A.
6. Calculate the current through a 3.1 kW appliance when a potential difference of 200 V is applied.
7. Calculate the energy transferred when a 4.6 kW appliance is turned on for 30 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 24 V transfers 2.7 kJ of energy.
9. Calculate the power output of a component with a resistance of 170 kΩ when a 1700 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1600 Ω is reduced from 18 A to 7 A.
11. Calculate the power output of an appliance that has a charge flow of 280 C in 3 minutes when a 230 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 2
1. Calculate the amount of charge that flows when a current of 3.7 A flows for 9 minutes.
2. Calculate the current when 1.9 C of charge flows in 13 seconds.
3. Calculate the potential difference across a component with a resistance of 240 Ω when a current of 22 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 2.5 V causes a current of 15 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 6 A.
6. Calculate the current through a 4.8 kW appliance when a potential difference of 160 V is applied.
7. Calculate the energy transferred when a 3 kW appliance is turned on for 40 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 28 V transfers 1.9 kJ of energy.
9. Calculate the power output of a component with a resistance of 220 kΩ when a 800 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2400 Ω is reduced from 16 A to 9 A.
11. Calculate the power output of an appliance that has a charge flow of 400 C in 9 minutes when a 231 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 3
1. Calculate the amount of charge that flows when a current of 5.4 A flows for 6 minutes.
2. Calculate the current when 0.3 C of charge flows in 23 seconds.
3. Calculate the potential difference across a component with a resistance of 450 Ω when a current of 47 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 3.5 V causes a current of 40 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 6 A.
6. Calculate the current through a 7.2 kW appliance when a potential difference of 120 V is applied.
7. Calculate the energy transferred when a 3.8 kW appliance is turned on for 35 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 14 V transfers 1.3 kJ of energy.
9. Calculate the power output of a component with a resistance of 210 kΩ when a 1300 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1700 Ω is reduced from 23 A to 4 A.
11. Calculate the power output of an appliance that has a charge flow of 470 C in 2 minutes when a 232 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 4
1. Calculate the amount of charge that flows when a current of 6.1 A flows for 7 minutes.
2. Calculate the current when 0.6 C of charge flows in 14 seconds.
3. Calculate the potential difference across a component with a resistance of 190 Ω when a current of 34 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 1 V causes a current of 31 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 11.5 A.
6. Calculate the current through a 4.7 kW appliance when a potential difference of 80 V is applied.
7. Calculate the energy transferred when a 3.4 kW appliance is turned on for 25 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 26 V transfers 0.5 kJ of energy.
9. Calculate the power output of a component with a resistance of 190 kΩ when a 900 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1400 Ω is reduced from 17 A to 6 A.
11. Calculate the power output of an appliance that has a charge flow of 280 C in 8 minutes when a 233 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 5
1. Calculate the amount of charge that flows when a current of 4.1 A flows for 9 minutes.
2. Calculate the current when 2.4 C of charge flows in 33 seconds.
3. Calculate the potential difference across a component with a resistance of 420 Ω when a current of 46 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 2.5 V causes a current of 31 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 11.5 A.
6. Calculate the current through a 8.1 kW appliance when a potential difference of 60 V is applied.
7. Calculate the energy transferred when a 2.9 kW appliance is turned on for 20 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 24 V transfers 1.1 kJ of energy.
9. Calculate the power output of a component with a resistance of 110 kΩ when a 1900 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2000 Ω is reduced from 21 A to 10 A.
11. Calculate the power output of an appliance that has a charge flow of 480 C in 7 minutes when a 234 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 6
1. Calculate the amount of charge that flows when a current of 2.4 A flows for 6 minutes.
2. Calculate the current when 1.6 C of charge flows in 19 seconds.
3. Calculate the potential difference across a component with a resistance of 310 Ω when a current of 24 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 4.5 V causes a current of 40 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 5.5 A.
6. Calculate the current through a 7.6 kW appliance when a potential difference of 180 V is applied.
7. Calculate the energy transferred when a 2.3 kW appliance is turned on for 10 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 30 V transfers 2 kJ of energy.
9. Calculate the power output of a component with a resistance of 230 kΩ when a 900 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1800 Ω is reduced from 20 A to 7 A.
11. Calculate the power output of an appliance that has a charge flow of 320 C in 6 minutes when a 235 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 7
1. Calculate the amount of charge that flows when a current of 4.6 A flows for 2 minutes.
2. Calculate the current when 0.9 C of charge flows in 19 seconds.
3. Calculate the potential difference across a component with a resistance of 230 Ω when a current of 35 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 4 V causes a current of 37 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 3 A.
6. Calculate the current through a 3.6 kW appliance when a potential difference of 240 V is applied.
7. Calculate the energy transferred when a 4.7 kW appliance is turned on for 35 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 32 V transfers 1.9 kJ of energy.
9. Calculate the power output of a component with a resistance of 150 kΩ when a 800 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2400 Ω is reduced from 17 A to 7 A.
11. Calculate the power output of an appliance that has a charge flow of 210 C in 8 minutes when a 236 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 8
1. Calculate the amount of charge that flows when a current of 3.3 A flows for 6 minutes.
2. Calculate the current when 0.4 C of charge flows in 32 seconds.
3. Calculate the potential difference across a component with a resistance of 340 Ω when a current of 28 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 2 V causes a current of 29 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 2.5 A.
6. Calculate the current through a 3.9 kW appliance when a potential difference of 40 V is applied.
7. Calculate the energy transferred when a 4.8 kW appliance is turned on for 20 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 30 V transfers 1.9 kJ of energy.
9. Calculate the power output of a component with a resistance of 230 kΩ when a 1700 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2300 Ω is reduced from 19 A to 8 A.
11. Calculate the power output of an appliance that has a charge flow of 470 C in 6 minutes when a 237 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 9
1. Calculate the amount of charge that flows when a current of 4.7 A flows for 3 minutes.
2. Calculate the current when 2.8 C of charge flows in 30 seconds.
3. Calculate the potential difference across a component with a resistance of 470 Ω when a current of 24 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 3 V causes a current of 38 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 7 A.
6. Calculate the current through a 7 kW appliance when a potential difference of 40 V is applied.
7. Calculate the energy transferred when a 4.3 kW appliance is turned on for 25 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 26 V transfers 0.7 kJ of energy.
9. Calculate the power output of a component with a resistance of 190 kΩ when a 1600 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2200 Ω is reduced from 16 A to 8 A.
11. Calculate the power output of an appliance that has a charge flow of 200 C in 8 minutes when a 238 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 10
1. Calculate the amount of charge that flows when a current of 5.1 A flows for 7 minutes.
2. Calculate the current when 2.5 C of charge flows in 13 seconds.
3. Calculate the potential difference across a component with a resistance of 460 Ω when a current of 30 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 1.5 V causes a current of 35 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 2.5 A.
6. Calculate the current through a 10 kW appliance when a potential difference of 120 V is applied.
7. Calculate the energy transferred when a 2.6 kW appliance is turned on for 15 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 12 V transfers 0.7 kJ of energy.
9. Calculate the power output of a component with a resistance of 150 kΩ when a 1800 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1600 Ω is reduced from 16 A to 4 A.
11. Calculate the power output of an appliance that has a charge flow of 480 C in 6 minutes when a 239 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 11
1. Calculate the amount of charge that flows when a current of 7.1 A flows for 3 minutes.
2. Calculate the current when 2.8 C of charge flows in 32 seconds.
3. Calculate the potential difference across a component with a resistance of 430 Ω when a current of 28 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 3.5 V causes a current of 40 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 4.5 A.
6. Calculate the current through a 5.2 kW appliance when a potential difference of 80 V is applied.
7. Calculate the energy transferred when a 4.1 kW appliance is turned on for 20 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 22 V transfers 2.6 kJ of energy.
9. Calculate the power output of a component with a resistance of 240 kΩ when a 1500 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1800 Ω is reduced from 15 A to 6 A.
11. Calculate the power output of an appliance that has a charge flow of 500 C in 3 minutes when a 240 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 12
1. Calculate the amount of charge that flows when a current of 1.7 A flows for 7 minutes.
2. Calculate the current when 2.1 C of charge flows in 13 seconds.
3. Calculate the potential difference across a component with a resistance of 370 Ω when a current of 27 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 3 V causes a current of 12 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 11 A.
6. Calculate the current through a 5.1 kW appliance when a potential difference of 220 V is applied.
7. Calculate the energy transferred when a 2.7 kW appliance is turned on for 40 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 22 V transfers 1.7 kJ of energy.
9. Calculate the power output of a component with a resistance of 110 kΩ when a 1000 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1600 Ω is reduced from 17 A to 5 A.
11. Calculate the power output of an appliance that has a charge flow of 260 C in 5 minutes when a 241 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 13
1. Calculate the amount of charge that flows when a current of 2.2 A flows for 7 minutes.
2. Calculate the current when 1.5 C of charge flows in 15 seconds.
3. Calculate the potential difference across a component with a resistance of 440 Ω when a current of 28 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 1 V causes a current of 31 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 5.5 A.
6. Calculate the current through a 9 kW appliance when a potential difference of 20 V is applied.
7. Calculate the energy transferred when a 4.8 kW appliance is turned on for 15 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 28 V transfers 2 kJ of energy.
9. Calculate the power output of a component with a resistance of 200 kΩ when a 1400 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1300 Ω is reduced from 15 A to 8 A.
11. Calculate the power output of an appliance that has a charge flow of 230 C in 4 minutes when a 242 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 14
1. Calculate the amount of charge that flows when a current of 3.3 A flows for 2 minutes.
2. Calculate the current when 1.3 C of charge flows in 19 seconds.
3. Calculate the potential difference across a component with a resistance of 160 Ω when a current of 43 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 1.5 V causes a current of 34 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 10 A.
6. Calculate the current through a 4.3 kW appliance when a potential difference of 160 V is applied.
7. Calculate the energy transferred when a 4.7 kW appliance is turned on for 15 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 24 V transfers 2.1 kJ of energy.
9. Calculate the power output of a component with a resistance of 210 kΩ when a 1100 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1800 Ω is reduced from 23 A to 7 A.
11. Calculate the power output of an appliance that has a charge flow of 430 C in 4 minutes when a 243 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 15
1. Calculate the amount of charge that flows when a current of 3.3 A flows for 8 minutes.
2. Calculate the current when 1.9 C of charge flows in 35 seconds.
3. Calculate the potential difference across a component with a resistance of 270 Ω when a current of 47 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 2 V causes a current of 32 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 8 A.
6. Calculate the current through a 6.4 kW appliance when a potential difference of 140 V is applied.
7. Calculate the energy transferred when a 4.7 kW appliance is turned on for 15 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 32 V transfers 0.7 kJ of energy.
9. Calculate the power output of a component with a resistance of 120 kΩ when a 1100 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2000 Ω is reduced from 15 A to 4 A.
11. Calculate the power output of an appliance that has a charge flow of 490 C in 8 minutes when a 244 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 16
1. Calculate the amount of charge that flows when a current of 1.6 A flows for 2 minutes.
2. Calculate the current when 2.9 C of charge flows in 27 seconds.
3. Calculate the potential difference across a component with a resistance of 480 Ω when a current of 45 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 3 V causes a current of 18 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 1.5 A.
6. Calculate the current through a 9.7 kW appliance when a potential difference of 80 V is applied.
7. Calculate the energy transferred when a 3.2 kW appliance is turned on for 20 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 26 V transfers 2 kJ of energy.
9. Calculate the power output of a component with a resistance of 120 kΩ when a 900 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2300 Ω is reduced from 17 A to 8 A.
11. Calculate the power output of an appliance that has a charge flow of 480 C in 3 minutes when a 245 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 17
1. Calculate the amount of charge that flows when a current of 4.8 A flows for 3 minutes.
2. Calculate the current when 2.6 C of charge flows in 36 seconds.
3. Calculate the potential difference across a component with a resistance of 150 Ω when a current of 27 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 2 V causes a current of 34 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 4 A.
6. Calculate the current through a 8.5 kW appliance when a potential difference of 120 V is applied.
7. Calculate the energy transferred when a 2.9 kW appliance is turned on for 35 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 30 V transfers 1.9 kJ of energy.
9. Calculate the power output of a component with a resistance of 170 kΩ when a 1600 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1200 Ω is reduced from 19 A to 6 A.
11. Calculate the power output of an appliance that has a charge flow of 370 C in 6 minutes when a 246 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 18
1. Calculate the amount of charge that flows when a current of 6.6 A flows for 9 minutes.
2. Calculate the current when 1.5 C of charge flows in 37 seconds.
3. Calculate the potential difference across a component with a resistance of 310 Ω when a current of 27 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 4 V causes a current of 17 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 1 A.
6. Calculate the current through a 6.2 kW appliance when a potential difference of 220 V is applied.
7. Calculate the energy transferred when a 3 kW appliance is turned on for 20 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 34 V transfers 0.6 kJ of energy.
9. Calculate the power output of a component with a resistance of 140 kΩ when a 1700 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2400 Ω is reduced from 17 A to 5 A.
11. Calculate the power output of an appliance that has a charge flow of 230 C in 3 minutes when a 247 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 19
1. Calculate the amount of charge that flows when a current of 1.1 A flows for 9 minutes.
2. Calculate the current when 1.5 C of charge flows in 25 seconds.
3. Calculate the potential difference across a component with a resistance of 460 Ω when a current of 50 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 1.5 V causes a current of 28 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 11.5 A.
6. Calculate the current through a 7.7 kW appliance when a potential difference of 220 V is applied.
7. Calculate the energy transferred when a 4.1 kW appliance is turned on for 40 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 20 V transfers 1.7 kJ of energy.
9. Calculate the power output of a component with a resistance of 140 kΩ when a 2000 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1400 Ω is reduced from 18 A to 10 A.
11. Calculate the power output of an appliance that has a charge flow of 470 C in 8 minutes when a 248 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 20
1. Calculate the amount of charge that flows when a current of 3.4 A flows for 6 minutes.
2. Calculate the current when 2.4 C of charge flows in 13 seconds.
3. Calculate the potential difference across a component with a resistance of 390 Ω when a current of 24 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 1 V causes a current of 29 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 4.5 A.
6. Calculate the current through a 5.3 kW appliance when a potential difference of 40 V is applied.
7. Calculate the energy transferred when a 3.3 kW appliance is turned on for 15 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 28 V transfers 2.3 kJ of energy.
9. Calculate the power output of a component with a resistance of 110 kΩ when a 1800 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1700 Ω is reduced from 16 A to 6 A.
11. Calculate the power output of an appliance that has a charge flow of 330 C in 6 minutes when a 249 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 21
1. Calculate the amount of charge that flows when a current of 5.9 A flows for 3 minutes.
2. Calculate the current when 1.8 C of charge flows in 20 seconds.
3. Calculate the potential difference across a component with a resistance of 350 Ω when a current of 50 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 3 V causes a current of 19 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 10 A.
6. Calculate the current through a 5.4 kW appliance when a potential difference of 80 V is applied.
7. Calculate the energy transferred when a 3.4 kW appliance is turned on for 10 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 36 V transfers 1 kJ of energy.
9. Calculate the power output of a component with a resistance of 240 kΩ when a 1300 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2400 Ω is reduced from 15 A to 7 A.
11. Calculate the power output of an appliance that has a charge flow of 350 C in 5 minutes when a 250 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 22
1. Calculate the amount of charge that flows when a current of 5.3 A flows for 9 minutes.
2. Calculate the current when 2.2 C of charge flows in 18 seconds.
3. Calculate the potential difference across a component with a resistance of 400 Ω when a current of 42 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 2 V causes a current of 16 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 11 A.
6. Calculate the current through a 6.8 kW appliance when a potential difference of 180 V is applied.
7. Calculate the energy transferred when a 4.2 kW appliance is turned on for 20 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 34 V transfers 2.4 kJ of energy.
9. Calculate the power output of a component with a resistance of 100 kΩ when a 900 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1600 Ω is reduced from 24 A to 8 A.
11. Calculate the power output of an appliance that has a charge flow of 450 C in 4 minutes when a 251 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 23
1. Calculate the amount of charge that flows when a current of 3.1 A flows for 7 minutes.
2. Calculate the current when 0.6 C of charge flows in 27 seconds.
3. Calculate the potential difference across a component with a resistance of 360 Ω when a current of 23 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 2 V causes a current of 23 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 3 A.
6. Calculate the current through a 8.5 kW appliance when a potential difference of 120 V is applied.
7. Calculate the energy transferred when a 4.3 kW appliance is turned on for 25 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 16 V transfers 1.8 kJ of energy.
9. Calculate the power output of a component with a resistance of 130 kΩ when a 1800 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2200 Ω is reduced from 24 A to 8 A.
11. Calculate the power output of an appliance that has a charge flow of 450 C in 7 minutes when a 252 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 24
1. Calculate the amount of charge that flows when a current of 7.5 A flows for 5 minutes.
2. Calculate the current when 1.9 C of charge flows in 25 seconds.
3. Calculate the potential difference across a component with a resistance of 210 Ω when a current of 24 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 2.5 V causes a current of 36 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 5.5 A.
6. Calculate the current through a 9 kW appliance when a potential difference of 140 V is applied.
7. Calculate the energy transferred when a 3.8 kW appliance is turned on for 20 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 34 V transfers 2.6 kJ of energy.
9. Calculate the power output of a component with a resistance of 150 kΩ when a 1600 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1600 Ω is reduced from 21 A to 9 A.
11. Calculate the power output of an appliance that has a charge flow of 460 C in 9 minutes when a 253 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 25
1. Calculate the amount of charge that flows when a current of 4.3 A flows for 2 minutes.
2. Calculate the current when 1.5 C of charge flows in 37 seconds.
3. Calculate the potential difference across a component with a resistance of 240 Ω when a current of 25 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 1 V causes a current of 17 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 9 A.
6. Calculate the current through a 2.1 kW appliance when a potential difference of 100 V is applied.
7. Calculate the energy transferred when a 2.4 kW appliance is turned on for 25 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 30 V transfers 2 kJ of energy.
9. Calculate the power output of a component with a resistance of 220 kΩ when a 1000 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2300 Ω is reduced from 22 A to 4 A.
11. Calculate the power output of an appliance that has a charge flow of 270 C in 8 minutes when a 254 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 26
1. Calculate the amount of charge that flows when a current of 3.3 A flows for 5 minutes.
2. Calculate the current when 1.6 C of charge flows in 19 seconds.
3. Calculate the potential difference across a component with a resistance of 180 Ω when a current of 42 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 4 V causes a current of 31 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 3 A.
6. Calculate the current through a 9.7 kW appliance when a potential difference of 160 V is applied.
7. Calculate the energy transferred when a 2.3 kW appliance is turned on for 20 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 16 V transfers 0.9 kJ of energy.
9. Calculate the power output of a component with a resistance of 180 kΩ when a 2000 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1800 Ω is reduced from 22 A to 9 A.
11. Calculate the power output of an appliance that has a charge flow of 360 C in 4 minutes when a 255 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 27
1. Calculate the amount of charge that flows when a current of 3.4 A flows for 4 minutes.
2. Calculate the current when 1.5 C of charge flows in 37 seconds.
3. Calculate the potential difference across a component with a resistance of 280 Ω when a current of 47 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 3 V causes a current of 25 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 8.5 A.
6. Calculate the current through a 7.3 kW appliance when a potential difference of 140 V is applied.
7. Calculate the energy transferred when a 3.5 kW appliance is turned on for 10 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 22 V transfers 2.3 kJ of energy.
9. Calculate the power output of a component with a resistance of 240 kΩ when a 1000 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2200 Ω is reduced from 20 A to 5 A.
11. Calculate the power output of an appliance that has a charge flow of 430 C in 8 minutes when a 256 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 28
1. Calculate the amount of charge that flows when a current of 3.3 A flows for 9 minutes.
2. Calculate the current when 3 C of charge flows in 32 seconds.
3. Calculate the potential difference across a component with a resistance of 320 Ω when a current of 46 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 3.5 V causes a current of 18 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 6 A.
6. Calculate the current through a 8.4 kW appliance when a potential difference of 180 V is applied.
7. Calculate the energy transferred when a 2.8 kW appliance is turned on for 20 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 34 V transfers 2.4 kJ of energy.
9. Calculate the power output of a component with a resistance of 140 kΩ when a 1600 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2000 Ω is reduced from 16 A to 4 A.
11. Calculate the power output of an appliance that has a charge flow of 260 C in 9 minutes when a 257 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 29
1. Calculate the amount of charge that flows when a current of 7.3 A flows for 8 minutes.
2. Calculate the current when 1.6 C of charge flows in 18 seconds.
3. Calculate the potential difference across a component with a resistance of 420 Ω when a current of 23 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 2 V causes a current of 12 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 9.5 A.
6. Calculate the current through a 5.6 kW appliance when a potential difference of 200 V is applied.
7. Calculate the energy transferred when a 3.2 kW appliance is turned on for 15 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 22 V transfers 3 kJ of energy.
9. Calculate the power output of a component with a resistance of 180 kΩ when a 1400 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1300 Ω is reduced from 24 A to 10 A.
11. Calculate the power output of an appliance that has a charge flow of 300 C in 4 minutes when a 258 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 30
1. Calculate the amount of charge that flows when a current of 2 A flows for 6 minutes.
2. Calculate the current when 1 C of charge flows in 35 seconds.
3. Calculate the potential difference across a component with a resistance of 430 Ω when a current of 22 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 1 V causes a current of 15 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 10.5 A.
6. Calculate the current through a 9.7 kW appliance when a potential difference of 160 V is applied.
7. Calculate the energy transferred when a 3.8 kW appliance is turned on for 30 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 24 V transfers 0.9 kJ of energy.
9. Calculate the power output of a component with a resistance of 210 kΩ when a 1100 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2400 Ω is reduced from 23 A to 10 A.
11. Calculate the power output of an appliance that has a charge flow of 300 C in 7 minutes when a 259 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 31
1. Calculate the amount of charge that flows when a current of 5.1 A flows for 7 minutes.
2. Calculate the current when 2.4 C of charge flows in 10 seconds.
3. Calculate the potential difference across a component with a resistance of 240 Ω when a current of 23 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 3 V causes a current of 36 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 9.5 A.
6. Calculate the current through a 3.8 kW appliance when a potential difference of 80 V is applied.
7. Calculate the energy transferred when a 4.5 kW appliance is turned on for 40 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 26 V transfers 2.5 kJ of energy.
9. Calculate the power output of a component with a resistance of 120 kΩ when a 1500 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2100 Ω is reduced from 15 A to 8 A.
11. Calculate the power output of an appliance that has a charge flow of 210 C in 3 minutes when a 260 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 32
1. Calculate the amount of charge that flows when a current of 3.8 A flows for 5 minutes.
2. Calculate the current when 1.3 C of charge flows in 29 seconds.
3. Calculate the potential difference across a component with a resistance of 360 Ω when a current of 21 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 3 V causes a current of 16 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 8 A.
6. Calculate the current through a 7.5 kW appliance when a potential difference of 200 V is applied.
7. Calculate the energy transferred when a 4.6 kW appliance is turned on for 30 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 14 V transfers 0.5 kJ of energy.
9. Calculate the power output of a component with a resistance of 200 kΩ when a 1000 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1400 Ω is reduced from 17 A to 5 A.
11. Calculate the power output of an appliance that has a charge flow of 240 C in 3 minutes when a 261 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 33
1. Calculate the amount of charge that flows when a current of 2.5 A flows for 5 minutes.
2. Calculate the current when 2.7 C of charge flows in 23 seconds.
3. Calculate the potential difference across a component with a resistance of 360 Ω when a current of 45 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 2.5 V causes a current of 14 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 6 A.
6. Calculate the current through a 6.5 kW appliance when a potential difference of 180 V is applied.
7. Calculate the energy transferred when a 3.8 kW appliance is turned on for 20 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 34 V transfers 0.8 kJ of energy.
9. Calculate the power output of a component with a resistance of 240 kΩ when a 1600 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1300 Ω is reduced from 21 A to 4 A.
11. Calculate the power output of an appliance that has a charge flow of 340 C in 8 minutes when a 262 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 34
1. Calculate the amount of charge that flows when a current of 5.5 A flows for 8 minutes.
2. Calculate the current when 1.4 C of charge flows in 23 seconds.
3. Calculate the potential difference across a component with a resistance of 410 Ω when a current of 28 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 5 V causes a current of 13 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 7.5 A.
6. Calculate the current through a 9.2 kW appliance when a potential difference of 120 V is applied.
7. Calculate the energy transferred when a 2.5 kW appliance is turned on for 40 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 34 V transfers 2.5 kJ of energy.
9. Calculate the power output of a component with a resistance of 120 kΩ when a 800 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2400 Ω is reduced from 23 A to 7 A.
11. Calculate the power output of an appliance that has a charge flow of 290 C in 3 minutes when a 263 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 35
1. Calculate the amount of charge that flows when a current of 5.9 A flows for 3 minutes.
2. Calculate the current when 1.4 C of charge flows in 40 seconds.
3. Calculate the potential difference across a component with a resistance of 340 Ω when a current of 36 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 4 V causes a current of 12 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 8.5 A.
6. Calculate the current through a 3.3 kW appliance when a potential difference of 80 V is applied.
7. Calculate the energy transferred when a 4.4 kW appliance is turned on for 30 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 20 V transfers 1.9 kJ of energy.
9. Calculate the power output of a component with a resistance of 160 kΩ when a 900 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1300 Ω is reduced from 20 A to 8 A.
11. Calculate the power output of an appliance that has a charge flow of 260 C in 7 minutes when a 264 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 36
1. Calculate the amount of charge that flows when a current of 5.9 A flows for 8 minutes.
2. Calculate the current when 0.7 C of charge flows in 25 seconds.
3. Calculate the potential difference across a component with a resistance of 290 Ω when a current of 24 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 1.5 V causes a current of 17 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 9 A.
6. Calculate the current through a 8.9 kW appliance when a potential difference of 240 V is applied.
7. Calculate the energy transferred when a 2.6 kW appliance is turned on for 30 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 32 V transfers 2.9 kJ of energy.
9. Calculate the power output of a component with a resistance of 190 kΩ when a 1400 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1800 Ω is reduced from 24 A to 5 A.
11. Calculate the power output of an appliance that has a charge flow of 300 C in 5 minutes when a 265 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 37
1. Calculate the amount of charge that flows when a current of 1.8 A flows for 5 minutes.
2. Calculate the current when 0.3 C of charge flows in 37 seconds.
3. Calculate the potential difference across a component with a resistance of 370 Ω when a current of 20 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 2.5 V causes a current of 28 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 3.5 A.
6. Calculate the current through a 6.8 kW appliance when a potential difference of 80 V is applied.
7. Calculate the energy transferred when a 2.9 kW appliance is turned on for 35 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 28 V transfers 1.4 kJ of energy.
9. Calculate the power output of a component with a resistance of 120 kΩ when a 2000 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2400 Ω is reduced from 18 A to 9 A.
11. Calculate the power output of an appliance that has a charge flow of 480 C in 8 minutes when a 266 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 38
1. Calculate the amount of charge that flows when a current of 7.6 A flows for 8 minutes.
2. Calculate the current when 2.1 C of charge flows in 34 seconds.
3. Calculate the potential difference across a component with a resistance of 300 Ω when a current of 42 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 3 V causes a current of 30 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 7.5 A.
6. Calculate the current through a 8.2 kW appliance when a potential difference of 200 V is applied.
7. Calculate the energy transferred when a 3.7 kW appliance is turned on for 10 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 16 V transfers 1.8 kJ of energy.
9. Calculate the power output of a component with a resistance of 220 kΩ when a 1000 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1900 Ω is reduced from 15 A to 6 A.
11. Calculate the power output of an appliance that has a charge flow of 280 C in 7 minutes when a 267 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 39
1. Calculate the amount of charge that flows when a current of 1 A flows for 2 minutes.
2. Calculate the current when 3 C of charge flows in 25 seconds.
3. Calculate the potential difference across a component with a resistance of 200 Ω when a current of 44 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 4 V causes a current of 15 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 5 A.
6. Calculate the current through a 8.1 kW appliance when a potential difference of 220 V is applied.
7. Calculate the energy transferred when a 4.8 kW appliance is turned on for 25 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 12 V transfers 1.4 kJ of energy.
9. Calculate the power output of a component with a resistance of 150 kΩ when a 1200 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2400 Ω is reduced from 17 A to 6 A.
11. Calculate the power output of an appliance that has a charge flow of 450 C in 6 minutes when a 268 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 40
1. Calculate the amount of charge that flows when a current of 1.6 A flows for 6 minutes.
2. Calculate the current when 0.3 C of charge flows in 20 seconds.
3. Calculate the potential difference across a component with a resistance of 390 Ω when a current of 49 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 3.5 V causes a current of 24 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 11.5 A.
6. Calculate the current through a 2.8 kW appliance when a potential difference of 60 V is applied.
7. Calculate the energy transferred when a 4.9 kW appliance is turned on for 10 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 26 V transfers 0.5 kJ of energy.
9. Calculate the power output of a component with a resistance of 130 kΩ when a 2000 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1600 Ω is reduced from 19 A to 10 A.
11. Calculate the power output of an appliance that has a charge flow of 340 C in 3 minutes when a 269 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 41
1. Calculate the amount of charge that flows when a current of 2.8 A flows for 2 minutes.
2. Calculate the current when 1.2 C of charge flows in 31 seconds.
3. Calculate the potential difference across a component with a resistance of 290 Ω when a current of 20 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 1 V causes a current of 17 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 4 A.
6. Calculate the current through a 3.9 kW appliance when a potential difference of 120 V is applied.
7. Calculate the energy transferred when a 3.7 kW appliance is turned on for 10 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 16 V transfers 2.4 kJ of energy.
9. Calculate the power output of a component with a resistance of 120 kΩ when a 1800 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2300 Ω is reduced from 18 A to 6 A.
11. Calculate the power output of an appliance that has a charge flow of 390 C in 8 minutes when a 270 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 42
1. Calculate the amount of charge that flows when a current of 1.1 A flows for 4 minutes.
2. Calculate the current when 2.5 C of charge flows in 26 seconds.
3. Calculate the potential difference across a component with a resistance of 310 Ω when a current of 24 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 1.5 V causes a current of 23 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 4.5 A.
6. Calculate the current through a 1.5 kW appliance when a potential difference of 240 V is applied.
7. Calculate the energy transferred when a 3.8 kW appliance is turned on for 20 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 26 V transfers 0.5 kJ of energy.
9. Calculate the power output of a component with a resistance of 160 kΩ when a 1200 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2300 Ω is reduced from 21 A to 5 A.
11. Calculate the power output of an appliance that has a charge flow of 200 C in 5 minutes when a 271 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 43
1. Calculate the amount of charge that flows when a current of 2.7 A flows for 2 minutes.
2. Calculate the current when 2.3 C of charge flows in 24 seconds.
3. Calculate the potential difference across a component with a resistance of 420 Ω when a current of 45 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 5 V causes a current of 26 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 9 A.
6. Calculate the current through a 3.6 kW appliance when a potential difference of 100 V is applied.
7. Calculate the energy transferred when a 2.2 kW appliance is turned on for 10 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 28 V transfers 1.6 kJ of energy.
9. Calculate the power output of a component with a resistance of 140 kΩ when a 1100 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1400 Ω is reduced from 20 A to 7 A.
11. Calculate the power output of an appliance that has a charge flow of 440 C in 7 minutes when a 272 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 44
1. Calculate the amount of charge that flows when a current of 7.9 A flows for 9 minutes.
2. Calculate the current when 1.8 C of charge flows in 24 seconds.
3. Calculate the potential difference across a component with a resistance of 300 Ω when a current of 43 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 4.5 V causes a current of 39 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 8 A.
6. Calculate the current through a 7.7 kW appliance when a potential difference of 20 V is applied.
7. Calculate the energy transferred when a 2.9 kW appliance is turned on for 20 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 24 V transfers 1 kJ of energy.
9. Calculate the power output of a component with a resistance of 190 kΩ when a 1300 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1700 Ω is reduced from 17 A to 6 A.
11. Calculate the power output of an appliance that has a charge flow of 230 C in 4 minutes when a 273 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 45
1. Calculate the amount of charge that flows when a current of 3 A flows for 6 minutes.
2. Calculate the current when 2.1 C of charge flows in 11 seconds.
3. Calculate the potential difference across a component with a resistance of 450 Ω when a current of 49 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 4.5 V causes a current of 31 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 6.5 A.
6. Calculate the current through a 3.8 kW appliance when a potential difference of 200 V is applied.
7. Calculate the energy transferred when a 3.2 kW appliance is turned on for 35 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 26 V transfers 1.8 kJ of energy.
9. Calculate the power output of a component with a resistance of 150 kΩ when a 1500 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1700 Ω is reduced from 23 A to 8 A.
11. Calculate the power output of an appliance that has a charge flow of 420 C in 5 minutes when a 274 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 46
1. Calculate the amount of charge that flows when a current of 3.3 A flows for 9 minutes.
2. Calculate the current when 2.2 C of charge flows in 15 seconds.
3. Calculate the potential difference across a component with a resistance of 450 Ω when a current of 30 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 3.5 V causes a current of 22 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 3.5 A.
6. Calculate the current through a 3.6 kW appliance when a potential difference of 100 V is applied.
7. Calculate the energy transferred when a 2.2 kW appliance is turned on for 30 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 28 V transfers 1.5 kJ of energy.
9. Calculate the power output of a component with a resistance of 140 kΩ when a 1000 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1200 Ω is reduced from 24 A to 4 A.
11. Calculate the power output of an appliance that has a charge flow of 460 C in 7 minutes when a 275 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 47
1. Calculate the amount of charge that flows when a current of 4.4 A flows for 3 minutes.
2. Calculate the current when 2 C of charge flows in 33 seconds.
3. Calculate the potential difference across a component with a resistance of 360 Ω when a current of 44 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 1.5 V causes a current of 14 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 2.5 A.
6. Calculate the current through a 1.9 kW appliance when a potential difference of 100 V is applied.
7. Calculate the energy transferred when a 4.5 kW appliance is turned on for 25 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 32 V transfers 2.1 kJ of energy.
9. Calculate the power output of a component with a resistance of 210 kΩ when a 1400 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1900 Ω is reduced from 18 A to 8 A.
11. Calculate the power output of an appliance that has a charge flow of 280 C in 2 minutes when a 276 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 48
1. Calculate the amount of charge that flows when a current of 5.1 A flows for 4 minutes.
2. Calculate the current when 1.2 C of charge flows in 24 seconds.
3. Calculate the potential difference across a component with a resistance of 380 Ω when a current of 25 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 3 V causes a current of 19 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 9 A.
6. Calculate the current through a 8.3 kW appliance when a potential difference of 120 V is applied.
7. Calculate the energy transferred when a 4.4 kW appliance is turned on for 15 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 18 V transfers 1.7 kJ of energy.
9. Calculate the power output of a component with a resistance of 140 kΩ when a 1100 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1400 Ω is reduced from 15 A to 10 A.
11. Calculate the power output of an appliance that has a charge flow of 420 C in 3 minutes when a 277 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 49
1. Calculate the amount of charge that flows when a current of 3.2 A flows for 4 minutes.
2. Calculate the current when 2.1 C of charge flows in 23 seconds.
3. Calculate the potential difference across a component with a resistance of 400 Ω when a current of 35 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 3 V causes a current of 31 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 5.5 A.
6. Calculate the current through a 6.5 kW appliance when a potential difference of 220 V is applied.
7. Calculate the energy transferred when a 3.3 kW appliance is turned on for 15 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 30 V transfers 0.5 kJ of energy.
9. Calculate the power output of a component with a resistance of 190 kΩ when a 1300 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1500 Ω is reduced from 19 A to 6 A.
11. Calculate the power output of an appliance that has a charge flow of 440 C in 2 minutes when a 278 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 50
1. Calculate the amount of charge that flows when a current of 6.3 A flows for 3 minutes.
2. Calculate the current when 0.8 C of charge flows in 14 seconds.
3. Calculate the potential difference across a component with a resistance of 270 Ω when a current of 20 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 4.5 V causes a current of 33 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 2.5 A.
6. Calculate the current through a 8 kW appliance when a potential difference of 80 V is applied.
7. Calculate the energy transferred when a 2 kW appliance is turned on for 20 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 34 V transfers 2.1 kJ of energy.
9. Calculate the power output of a component with a resistance of 220 kΩ when a 1700 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1200 Ω is reduced from 16 A to 10 A.
11. Calculate the power output of an appliance that has a charge flow of 450 C in 6 minutes when a 279 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 51
1. Calculate the amount of charge that flows when a current of 2.6 A flows for 6 minutes.
2. Calculate the current when 2.8 C of charge flows in 32 seconds.
3. Calculate the potential difference across a component with a resistance of 200 Ω when a current of 33 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 2 V causes a current of 28 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 7.5 A.
6. Calculate the current through a 6 kW appliance when a potential difference of 40 V is applied.
7. Calculate the energy transferred when a 3 kW appliance is turned on for 30 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 36 V transfers 1.9 kJ of energy.
9. Calculate the power output of a component with a resistance of 240 kΩ when a 2000 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1500 Ω is reduced from 20 A to 10 A.
11. Calculate the power output of an appliance that has a charge flow of 350 C in 5 minutes when a 280 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 52
1. Calculate the amount of charge that flows when a current of 4.4 A flows for 9 minutes.
2. Calculate the current when 2.6 C of charge flows in 20 seconds.
3. Calculate the potential difference across a component with a resistance of 150 Ω when a current of 40 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 3.5 V causes a current of 21 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 11.5 A.
6. Calculate the current through a 6.8 kW appliance when a potential difference of 220 V is applied.
7. Calculate the energy transferred when a 4.7 kW appliance is turned on for 35 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 12 V transfers 0.9 kJ of energy.
9. Calculate the power output of a component with a resistance of 220 kΩ when a 1400 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1400 Ω is reduced from 23 A to 10 A.
11. Calculate the power output of an appliance that has a charge flow of 310 C in 9 minutes when a 281 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 53
1. Calculate the amount of charge that flows when a current of 5.4 A flows for 3 minutes.
2. Calculate the current when 2.5 C of charge flows in 39 seconds.
3. Calculate the potential difference across a component with a resistance of 150 Ω when a current of 30 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 3.5 V causes a current of 17 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 1 A.
6. Calculate the current through a 8.3 kW appliance when a potential difference of 220 V is applied.
7. Calculate the energy transferred when a 4.7 kW appliance is turned on for 30 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 34 V transfers 2.5 kJ of energy.
9. Calculate the power output of a component with a resistance of 200 kΩ when a 1400 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2200 Ω is reduced from 23 A to 8 A.
11. Calculate the power output of an appliance that has a charge flow of 320 C in 8 minutes when a 282 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 54
1. Calculate the amount of charge that flows when a current of 7.4 A flows for 2 minutes.
2. Calculate the current when 0.8 C of charge flows in 31 seconds.
3. Calculate the potential difference across a component with a resistance of 320 Ω when a current of 49 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 3 V causes a current of 32 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 9.5 A.
6. Calculate the current through a 9.3 kW appliance when a potential difference of 100 V is applied.
7. Calculate the energy transferred when a 2.8 kW appliance is turned on for 25 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 34 V transfers 1.8 kJ of energy.
9. Calculate the power output of a component with a resistance of 180 kΩ when a 1500 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2200 Ω is reduced from 21 A to 5 A.
11. Calculate the power output of an appliance that has a charge flow of 370 C in 3 minutes when a 283 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 55
1. Calculate the amount of charge that flows when a current of 2.2 A flows for 6 minutes.
2. Calculate the current when 2.8 C of charge flows in 27 seconds.
3. Calculate the potential difference across a component with a resistance of 290 Ω when a current of 23 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 4.5 V causes a current of 30 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 3 A.
6. Calculate the current through a 9 kW appliance when a potential difference of 100 V is applied.
7. Calculate the energy transferred when a 3.6 kW appliance is turned on for 25 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 24 V transfers 2.8 kJ of energy.
9. Calculate the power output of a component with a resistance of 240 kΩ when a 1800 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2100 Ω is reduced from 19 A to 10 A.
11. Calculate the power output of an appliance that has a charge flow of 200 C in 2 minutes when a 284 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 56
1. Calculate the amount of charge that flows when a current of 5.1 A flows for 3 minutes.
2. Calculate the current when 1.2 C of charge flows in 37 seconds.
3. Calculate the potential difference across a component with a resistance of 490 Ω when a current of 44 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 2.5 V causes a current of 18 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 6 A.
6. Calculate the current through a 5.7 kW appliance when a potential difference of 160 V is applied.
7. Calculate the energy transferred when a 3.5 kW appliance is turned on for 25 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 32 V transfers 0.6 kJ of energy.
9. Calculate the power output of a component with a resistance of 170 kΩ when a 1700 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1600 Ω is reduced from 19 A to 5 A.
11. Calculate the power output of an appliance that has a charge flow of 350 C in 2 minutes when a 285 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 57
1. Calculate the amount of charge that flows when a current of 6.7 A flows for 8 minutes.
2. Calculate the current when 2.8 C of charge flows in 10 seconds.
3. Calculate the potential difference across a component with a resistance of 250 Ω when a current of 32 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 3 V causes a current of 21 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 4 A.
6. Calculate the current through a 9.1 kW appliance when a potential difference of 220 V is applied.
7. Calculate the energy transferred when a 2.4 kW appliance is turned on for 10 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 18 V transfers 0.6 kJ of energy.
9. Calculate the power output of a component with a resistance of 180 kΩ when a 1900 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1500 Ω is reduced from 22 A to 5 A.
11. Calculate the power output of an appliance that has a charge flow of 490 C in 3 minutes when a 286 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 58
1. Calculate the amount of charge that flows when a current of 1.6 A flows for 2 minutes.
2. Calculate the current when 0.4 C of charge flows in 40 seconds.
3. Calculate the potential difference across a component with a resistance of 210 Ω when a current of 22 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 2 V causes a current of 25 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 11 A.
6. Calculate the current through a 8.6 kW appliance when a potential difference of 20 V is applied.
7. Calculate the energy transferred when a 4.4 kW appliance is turned on for 10 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 12 V transfers 1.4 kJ of energy.
9. Calculate the power output of a component with a resistance of 100 kΩ when a 1600 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2000 Ω is reduced from 18 A to 4 A.
11. Calculate the power output of an appliance that has a charge flow of 410 C in 6 minutes when a 287 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 59
1. Calculate the amount of charge that flows when a current of 3.1 A flows for 3 minutes.
2. Calculate the current when 1.3 C of charge flows in 23 seconds.
3. Calculate the potential difference across a component with a resistance of 210 Ω when a current of 34 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 1.5 V causes a current of 38 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 240 V and a current of 3.5 A.
6. Calculate the current through a 9.1 kW appliance when a potential difference of 120 V is applied.
7. Calculate the energy transferred when a 4.7 kW appliance is turned on for 15 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 32 V transfers 1.2 kJ of energy.
9. Calculate the power output of a component with a resistance of 110 kΩ when a 1700 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2200 Ω is reduced from 24 A to 10 A.
11. Calculate the power output of an appliance that has a charge flow of 470 C in 4 minutes when a 288 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 60
1. Calculate the amount of charge that flows when a current of 2.9 A flows for 4 minutes.
2. Calculate the current when 3 C of charge flows in 21 seconds.
3. Calculate the potential difference across a component with a resistance of 350 Ω when a current of 30 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 2.5 V causes a current of 30 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 1.5 A.
6. Calculate the current through a 1.7 kW appliance when a potential difference of 220 V is applied.
7. Calculate the energy transferred when a 3.7 kW appliance is turned on for 15 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 34 V transfers 0.9 kJ of energy.
9. Calculate the power output of a component with a resistance of 230 kΩ when a 1100 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2400 Ω is reduced from 19 A to 10 A.
11. Calculate the power output of an appliance that has a charge flow of 340 C in 9 minutes when a 289 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 61
1. Calculate the amount of charge that flows when a current of 2.6 A flows for 7 minutes.
2. Calculate the current when 2.5 C of charge flows in 11 seconds.
3. Calculate the potential difference across a component with a resistance of 330 Ω when a current of 42 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 4 V causes a current of 38 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 9 A.
6. Calculate the current through a 7.1 kW appliance when a potential difference of 200 V is applied.
7. Calculate the energy transferred when a 2.3 kW appliance is turned on for 35 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 12 V transfers 0.6 kJ of energy.
9. Calculate the power output of a component with a resistance of 170 kΩ when a 1100 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1300 Ω is reduced from 24 A to 8 A.
11. Calculate the power output of an appliance that has a charge flow of 320 C in 4 minutes when a 290 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 62
1. Calculate the amount of charge that flows when a current of 3.8 A flows for 2 minutes.
2. Calculate the current when 0.2 C of charge flows in 32 seconds.
3. Calculate the potential difference across a component with a resistance of 500 Ω when a current of 22 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 1 V causes a current of 27 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 10 A.
6. Calculate the current through a 10 kW appliance when a potential difference of 20 V is applied.
7. Calculate the energy transferred when a 2.8 kW appliance is turned on for 10 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 14 V transfers 2.9 kJ of energy.
9. Calculate the power output of a component with a resistance of 150 kΩ when a 1100 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 2200 Ω is reduced from 18 A to 5 A.
11. Calculate the power output of an appliance that has a charge flow of 500 C in 9 minutes when a 291 V potential difference is applied.
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GCSE Physics Electricity Calculations “students should be able to…” Sheet 63
1. Calculate the amount of charge that flows when a current of 5 A flows for 8 minutes.
2. Calculate the current when 0.2 C of charge flows in 32 seconds.
3. Calculate the potential difference across a component with a resistance of 450 Ω when a current of 50 mA flows through it.
4. Calculate the resistance of a component when a potential difference of 1.5 V causes a current of 36 mA to flow.
5. Calculate the power output of an appliance with a potential difference of 230 V and a current of 10.5 A.
6. Calculate the current through a 9.6 kW appliance when a potential difference of 220 V is applied.
7. Calculate the energy transferred when a 4.2 kW appliance is turned on for 20 minutes.
8. Calculate the amount of charge that flows through an appliance when a potential difference of 26 V transfers 1.5 kJ of energy.
9. Calculate the power output of a component with a resistance of 160 kΩ when a 1500 V potential difference is applied.
10. Calculate the decrease in power loss when the transmission of electrical energy through a power line with a resistance of 1800 Ω is reduced from 21 A to 5 A.
11. Calculate the power output of an appliance that has a charge