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Question 1) You have one light which offers 12 Ω of resistance and has 2 A of current running through it. Another light offers 6 Ω of resistance, with.

Published byPhilip Ferguson Modified over 8 years ago

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Presentation on theme: "Question 1) You have one light which offers 12 Ω of resistance and has 2 A of current running through it. Another light offers 6 Ω of resistance, with."— Presentation transcript:

1 Question 1) You have one light which offers 12 Ω of resistance and has 2 A of current running through it. Another light offers 6 Ω of resistance, with the same amount of current running through it. Find the voltage of each of the two lights.

2 First light = 48 W·hr Second light = 24 W·hr 3)What if the first light is used in the bathroom of your house and the second is used in your kitchen? Which would use more electricity?

3 Power, Electric Consumption and Efficiency Rate of Energy Use Electrical Efficiency

4 Energy Defined as the ability to do work Measured in joules (J) Electrical energy is represented by “E” – Can be calculated with E = V x I x Δt E= Electrical energy (J) V = voltage drop (V) I = electric current (A) Δt = time interval (s)

5 Calculating the Amount of Energy If the time interval is in seconds, we end up getting a large number. Since one joule (J) measures a very small amount of energy—enough to light a light bulb in a hundredth of a second—we use watt hour or kilowatt hour (W·hr or kW·hr) E = V x I x ΔtE= Electrical energy (W·hr) V = voltage drop (V) I = electric current (A) Δt = time interval (hr)

6 Watt is Power? Measured in watts (W) or kilowatts (1 kW = 1000 W) It measures the rate at which electrical energy is being used. Represented by the letter “P” Can be solved by: P = V x I V = Voltage drop I = Electric current

7 Energy Consumption Once we calculate our power, we can easily further calculate the energy consumption (EC). – Time interval in seconds = energy consumption in joules (J). – Time interval in hours = energy consumption in watts·hour (W·hr). EC = P x Δt P = Power used Δ t = time interval

8 Calculating Energy Efficiency Recall from the lesson on resistors: – Energy cannot be created or destroyed – It can be changed from one form to another. No change is 100% efficient. Some energy is often “lost” to unusable forms.

9 Calculating Energy Efficiency Let’s take the example of burning coal in power plants – Chemical energy in fossil fuels would be considered our input energy (E in ) – Electrical energy produced by the conversion is refered to as output energy (E out )

10 Calculating Energy Efficiency Efficiency = Energy Output Energy Input % Efficiency = Energy Output x 100% Energy Input

11 Efficiency from Non-Renewable Energy Sources Fuel Used for GenerationPercentage of Energy from Fuel Available as Energy Nuclear20.0 Petroleum20.2 Natural Gas20.7 Coal22.2 Advanced Natural Gas Turbine 26.4 Why do we use low efficiency methods when wind generators are 30 %

12 Exercise With Efficiency An incandescent bulb produces 5 J of light energy from 100 J of electrical energy. A fluorescent bulb produces 400 J of light energy from 2000 J of electrical energy. Find the percent efficiency of each bulb and propose which is the best one to use.

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