2011 EdExcel Unit 1 W Richards 20/04/2017 2011 EdExcel Unit 1 This PowerPoint supports Topic 5 (Generating and transmitting electricity) from the 2011 EdExcel Physics Unit 1 module W Richards

Topic 5 – Generation and Transmission of Electricity 20/04/2017 Topic 5 – Generation and Transmission of Electricity

Electric Current Electric current is a flow of charge around a circuit 20/04/2017 Electric current is a flow of charge around a circuit Note that electrons go from negative to positive and are “pushed” by the voltage - + e- By definition, current is “the rate of flow of charge” e-

Words: volts, amps, ohms, voltage, ammeter, voltmeter Basic ideas… 20/04/2017 Electric current is when electrons start to flow around a circuit. We use an _________ to measure it and it is measured in ____. Potential difference (also called _______) is how big the push on the electrons is. We use a ________ to measure it and it is measured in ______, a unit named after Volta. Resistance is anything that resists an electric current. It is measured in _____. Words: volts, amps, ohms, voltage, ammeter, voltmeter

More basic ideas… 20/04/2017 If a battery is added the current will ________ because there is a greater _____ on the electrons If a bulb is added the current will _______ because there is greater ________ in the circuit

Electrical Power 20/04/2017 Power is defined as “the rate of transferring energy” and is measured in units called “Watts” (W). P I V The amount of power being transferred in an electrical device is given by: Power = voltage x current in W in V in A How much power is transferred by a 230V fire that runs on a current of 10A? An electric motor has a power rating of 24W. If it runs on a 12V battery what current does it draw? An average light bulb in a home has a power rating of 60W and works on 230V. What current does it draw?

Fuels 20/04/2017 A “fuel” is something that can be burned to release heat and light energy. The main examples are: Coal, oil and gas are called “fossil fuels”. In other words, they were made from fossils.

Some definitions… 20/04/2017 A renewable energy source is clearly one that can be _______ (“renew = make again”), e.g. _____, solar power etc. A ___________ energy source is one that when it has been used it is gone forever. The main examples are ____, oil and gas (which are called ______ ____, as they are made from fossils), and nuclear fuel, which is non-renewable but NOT a fossil fuel. Words – non-renewable, coal, fossil fuels, wood, renewed

Using non-renewable fuels in power stations 20/04/2017 1) A fossil fuel is burned in the boiler 2) Water turns to steam and the steam drives a turbine 3) The turbine turns a generator 4) The output of the generator is connected to a transformer 5) The steam is cooled down in a cooling tower and reused

Efficiency of Power Stations 20/04/2017 Heat Heat Heat 15J Boiler Turbine Generator 100J 50J 5J 85J 35J 30J Heat Kinetic Electrical

Pollution 20/04/2017 When a fuel is burned the two main waste products are _____ dioxide and ________ dioxide. Carbon dioxide is a _________ ___ and helps cause _______ _________. This is produced when any fossil fuels are burned. Sulphur dioxide, when dissolved in ________, causes ______ _____. This is mainly a problem for ___ power stations. Nuclear power stations do not produce these pollutants because they don’t ____ fossil fuels. Words – sulphur, coal, global warming, carbon, acid rain, greenhouse gas, rainwater, burn

Nuclear power stations 20/04/2017 These work in a similar way to normal power stations: The main difference is that the nuclear fuel is NOT burnt – it is used to boil water in a “heat exchanger”

Start up times Different power stations have different start up times: 20/04/2017 Different power stations have different start up times: Gas Oil Coal Nuclear Quick Slow

Non-renewable energy sources 20/04/2017 Advantages Disadvantages Pollution – CO2 leads to global warming and SO2 leads to acid rain Cheap fuel costs Coal, oil, gas and nuclear Generate a lot of energy Fuel will run out Easy to use

Renewable energy sources 20/04/2017 Advantages Disadvantages Often depend on the weather – is it sunny??? Clean Wind, tidal, solar etc Won’t run out Look ugly Energy is “dilute” – in other words, it’s very spread out Easily accessible

Other ways of generating electricity 20/04/2017 Can we drive the turbine directly without burning any fossil fuels?

20/04/2017 Wind Power

Tidal Power 20/04/2017 High tide Low tide

Wave Power 20/04/2017

Hydroelectric Power 20/04/2017

20/04/2017 Biomass

Words – alcohols, cleaner, burnt, renewable, methane, carbon dioxide Biofuels 20/04/2017 Biomass can be used as a fuel in a number of ways: Fast-growing trees that can be ____ Manure or other waste that can be used to release _______ (biogas) Corn or sugar cane that can be broken down in a fermenter to produce ______ like bio-ethanol. Biofuels have two main advantages over traditional fuels – they are ______ and ________. However, they still release ______ _______. Words – alcohols, cleaner, burnt, renewable, methane, carbon dioxide

Solar Energy 20/04/2017 Solar panels – convert sunlight directly into electricity. Sunlight knocks electrons loose from the crystal structure and the loose electrons form an electric current. The amount of power depends on the area of the panel and the light intensity. Heating for homes – these pipes carry water that absorbs heat energy and transfers it to the house.

20/04/2017 Geothermal Energy

Words – steam, Iceland, volcanic, turbines, hot rocks Geothermal Energy 20/04/2017 Geothermal energy can be used in _______ areas such as ______. In a geothermal source cold water is pumped down towards ____ _____. The water turns to steam and the steam can be used to turn ______. In some areas the _____ rising at the surface can be captured and used directly. Words – steam, Iceland, volcanic, turbines, hot rocks

Solar Panels and Thermal Towers 20/04/2017 Solar Panels and Thermal Towers

Using Solar Energy in remote places 20/04/2017 Using Solar Energy in remote places

Electromagnetic Induction 20/04/2017 N The direction of the induced current is reversed if… The wire is moved in the opposite direction The field is reversed The size of the induced current can be increased by: Increasing the speed of movement Increasing the magnet strength

Electromagnetic induction 20/04/2017 Electromagnetic induction The direction of the induced current is reversed if… The magnet is moved in the opposite direction The other pole is inserted first The size of the induced current can be increased by: Increasing the speed of movement Increasing the magnet strength Increasing the number of turns on the coil

AC Generators 20/04/2017 S N Voltage Time

Other generators A dynamo works by the same principle. 20/04/2017 A dynamo works by the same principle. 1) How can you make its output bigger? 2) How can you reverse the direction of its output current?

Large-scale production of Electricity 20/04/2017 A generator at Drax power station in England

DC and AC 20/04/2017 V DC stands for “Direct Current” – the current only flows in one direction: Time 1/50th s AC stands for “Alternating Current” – the current changes direction 50 times every second (frequency = 50Hz) 230V T V

Words – step down, high, power, low, high The National Grid 20/04/2017 Electricity reaches our homes from power stations through the National Grid: Power station Step up transformer Step down transformer Homes If electricity companies transmitted electricity at 240 volts through overhead power lines there would be too much ______ loss by the time electricity reaches our homes. This is because the current is ___. To overcome this they use devices called transformers to “step up” the voltage onto the power lines. They then “____ ____” the voltage at the end of the power lines before it reaches our homes. This way the voltage is _____ and the current and power loss are both ____. Words – step down, high, power, low, high

Power Lines 20/04/2017 Here’s my new shed. I want to connect it to the electricity I my house. Should I use an overhead cable or bury the cable underground?

Transformers 20/04/2017 Transformers are used to _____ __ or step down _______. They only work on AC because an ________ current in the primary coil causes a constantly alternating _______ ______. This will “_____” an alternating current in the secondary coil. Words – alternating, magnetic field, induce, step up, voltage We can work out how much a transformer will step up or step down a voltage: Voltage across primary (Vp) No. of turns on secondary (Ns) Voltage across secondary (Vs) No. of turns on primary (Np)

Some transformer questions 20/04/2017 Primary voltage Vp Secondary voltage Vs No. of turns on primary Np No. of turns on secondary Ns Step up or step down? 12V 24V 100 ? 400V 200V 20 25,000V 50,000V 1,000 23V 230V 150

Some example questions 20/04/2017 Primary voltage Vp Secondary voltage Vs No. of turns on primary Np No. of turns on secondary Ns Step up or step down? 6V 24V 100 ? 400,000V 200V 1,000 25,000V 20,000 20 230V 150 1,500 A transformer increases voltage from 10V to 30V. What is the ratio of the number of turns on the primary coil to the number of turns on the secondary coil? A step-down transformer has twice as many turns on the primary coil than on the secondary coil. What will be the output (secondary) voltage if the input voltage is 50V?

The Cost of Electricity 20/04/2017 Electricity is measured in units called “kilowatt hours” (kWh). For example… A 3kW fire left on for 1 hour uses 3kWh of energy A 1kW toaster left on for 2 hours uses 2kWh A 0.5kW hoover left on for 4 hours uses __kWh A 200W TV left on for 5 hours uses __kWh A 2kW kettle left on for 15 minutes uses __kWh

The Cost of Electricity 20/04/2017 To work out how much a device costs we do the following: Cost of electricity = Power (kW) x time (h) x cost per kWh (p) For example, if electricity costs 8p per unit calculate the cost of the following… A 2kW fire left on for 3 hours A 0.2kW TV left on for 5 hours A 0.1kW light bulb left on for 10 hours A 0.5kW hoover left on for 1 hour 48p 8p 8p 4p

Reducing Energy Consumption 20/04/2017 60W older bulb, roughly 70p, to be banned in the EU from 2012. 25W “energy efficient” light bulb, £7.30 on Amazon Which one is more cost-effective? Jane wants to replace all the bulbs in her house with energy-efficient ones. If she has 10 light bulbs in her house calculate the following: How much will it cost her to buy the bulbs? What will the total power consumption be reduced by? If she uses the bulbs for 5 hours per day and electricity costs 10p per unit how much money will she save? How long will it take her to repay the cost of the bulbs?

In other words, 1 Watt = 1 Joule per second Energy and Power 20/04/2017 The POWER RATING of an appliance is simply how much energy it uses every second. In other words, 1 Watt = 1 Joule per second E T P E = Energy (in joules) P = Power (in watts) T = Time (in seconds)

Some example questions 20/04/2017 What is the power rating of a light bulb that transfers 120 joules of energy in 2 seconds? What is the power of an electric fire that transfers 10,000J of energy in 5 seconds? Farhun runs up the stairs in 5 seconds. If he transfers 1,000,000J of energy in this time what is his power rating? How much energy does a 150W light bulb transfer in a) one second, b) one minute? Shaun’s brain needs energy supplied to it at a rate of 40W. How much energy does it need during a physics lesson? Damien’s brain, being more intelligent, only needs energy at a rate of about 20W. How much energy would his brain use in a normal day?

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