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SPH3U Unit #5 Electricity & Magnetism Unit Overview Electric Power & Energy The watt (W) is a unit of power. Power is the rate at which energy moves or is used. – PowerPoint PPT presentation

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Title: SPH3U


1
SPH3U Unit 5
  • Electricity Magnetism

2
Unit Overview
  • Electric Energy Circuits
  • Electric Charge Electrical Structure of Matter
  • Electric Potential
  • Elementary Charge (The Millikan Experiment)
  • Electric Current
  • Resistance
  • Electric Power Energy
  • Series Circuits
  • Parallel Circuits
  • Complex Circuits
  • Magnetism
  • Natural Magnetism
  • Magnetic Fields
  • Electromagnetism (RHR1 2)
  • The Motor Principle (RHR3)
  • Electromagnetic Induction
  • Lenzs Law
  • The Generator Effect
  • Transformers

3
Electric Power Energy
  • The watt (W) is a unit of power.
  • Power is the rate at which energy moves or is
    used.
  • Since energy is measured in joules, power is
    measured in joules per second.
  • One joule per second is equal to one watt.
  • One watt is a pretty small amount of power.
  • In everyday use, larger units are more convenient
    to use.
  • A kilowatt (kW) is equal to 1,000 watts.

4
Reviewing Terms
5
Defining Power
6
Example 1
  • In North America, the standard electric outlet
    has a potential difference of 120 V. In Europe,
    it is 240 V. What would be the power output of a
    100W 120 V light bulb if it was connected to a
    240 V system? What would happen to the light bulb?

7
Practice
  • Pg. 65541, 42
  • Pg. 65843-45

8
Another Relationship for Power
9
Example 2
  • An electric kettle is rated at 1500 W for a 120 V
    potential difference.
  • What is the resistance of the heating element of
    the kettle?
  • What will be the power output if the potential
    difference falls to 108V?

10
Practice
  • Pg. 66246-50

11
Energy Consumption
  • A seemingly unusual unit for energy is used when
    talking about electrical energy consumption The
    kilowatt-hour (KW-h).
  • One kilowatt-hour is the energy transformed by
    1000 W in one hour (3.6x106J).
  • A typical charge by an energy company for
    consumed energy is roughly 0.07 per Kw-h. That
    means that for 7 cents you can buy enough energy
    to lift 360 kg a vertical distance of more than 1
    km!

12
Example 3
  • A family has its television set on for an average
    of 4.0 h a day. If the television set is rated at
    80 W and energy costs 0.07per Kw-h, how much
    would it cost to operate the television for 30
    days?

13
Practice
  • Pg. 66451-53

14
Series Circuits
  • In series circuits, current can only take one
    path.
  • The amount of current is the same at all points
    in a series circuit.

15
Resistance in Series
  • Each resistance in a series circuit adds to the
    total resistance of the circuit.

Rtotal R1 R2 R3...
16
Resistance in Series
  • Light bulbs, resistors, motors, and heaters
    usually have much greater resistance than wires
    and batteries.

17
Example 1
  • How much current flows in a circuit with a
    1.5-volt battery and three 1 ohm resistances
    (bulbs) in series?

18
Voltage in a Series Circuit
  • Each separate resistance creates a voltage drop
    as the current passes through.
  • As current flows along a series circuit, each
    type of resistor transforms some of the
    electrical energy into another form of energy.
  • Ohms law is used to calculate the voltage drop
    across each resistor.

19
Kirchoffs Voltage Law
20
Parallel Circuits
  • In parallel circuits the current can take more
    than one path.
  • Because there are multiple branches, the current
    is not the same at all points in a parallel
    circuit.

21
Parallel Circuits
  • Sometimes these paths are called branches.
  • The current through a branch is also called the
    branch current.
  • When analyzing a parallel circuit, remember that
    the current always has to go somewhere.
  • The total current in the circuit is the sum of
    the currents in all the branches.
  • At every branch point the current flowing out
    must equal the current flowing in.
  • This rule is known as Kirchhoffs current law.

22
Kirchoffs Current Law
23
Kirchoffs Current Law
24
Voltage Current in a Parallel Circuit
  • In a parallel circuit the voltage is the same
    across each branch because each branch has a low
    resistance path back to the battery.
  • The amount of current in each branch in a
    parallel circuit is not necessarily the same.
  • The resistance in each branch determines the
    current in that branch.

25
Example 2
  • Two bulbs with different resistances are
    connected in parallel to batteries with a total
    voltage of 3 volts.
  • Calculate the total current supplied by the
    battery.

26
Advantages of Parallel Circuits
  • Parallel circuits have two big advantages over
    series circuits
  • Each device in the circuit sees the full battery
    voltage.
  • Each device in the circuit may be turned off
    independently without stopping the current
    flowing to other devices in the circuit.

27
Short Circuit
  • A short circuit is a parallel path in a circuit
    with zero or very low resistance.
  • Short circuits can be made accidentally by
    connecting a wire between two other wires at
    different voltages.
  • Short circuits are dangerous because they can
    draw huge amounts of current.

28
Resistance in Parallel Circuits
  • Adding resistance in parallel provides another
    path for current, and more current flows.
  • When more current flows for the same voltage, the
    total resistance of the circuit decreases.
  • This happens because every new path in a parallel
    circuit allows more current to flow for the same
    voltage.

29
Resistance in Parallel Circuits
30
Example 3
  • A circuit contains a 2 ohm resistor and a 4 ohm
    resistor in parallel.
  • Calculate the total resistance of the circuit.

31
Analysis of Circuits
  • All circuits work by manipulating currents and
    voltages.
  • The process of circuit analysis means figuring
    out what the currents and voltages in a circuit
    are, and also how they are affected by each
    other.
  • Three basic laws are the foundation of circuit
    analysis.

32
The 3 Circuit Laws
33
Solving Circuits Problems
  • Identify what the problem is asking you to find.
    Assign variables to the unknown quantities.
  • Make a large clear diagram of the circuit. Label
    all of the known resistances, currents, and
    voltages. Use the variables you defined to label
    the unknowns.
  • You may need to combine resistances to find the
    total circuit resistance. Use multiple steps to
    combine series and parallel resistors.

34
Solving Circuits Problems
  1. If you know the total resistance and current, use
    Ohms law as V IR to calculate voltages or
    voltage drops. If you know the resistance and
    voltage, use Ohms law as I V R to calculate
    the current.
  2. An unknown resistance can be found using Ohms
    law as R V I, if you know the current and the
    voltage drop through the resistor.
  3. Use Kirchhoffs current and voltage laws as
    necessary.

35
Example 4
  • A bulb with a resistance of 1O is to be used in a
    circuit with a 6-volt battery. The bulb requires
    1 amp of current. If the bulb were connected
    directly to the battery, it would draw 6 amps and
    burn out instantly. To limit the current, a
    resistor is added in series with the bulb. What
    size resistor is needed to make the current 1
    amp?

36
Combined Circuits
  • Key Question
  • How do we analyze network circuits?

37
Combined (Network) Circuits
  • In many circuits, resistors are connected both in
    series and in parallel.
  • Such a circuit is called a network circuit.
  • There is no single formula for adding resistors
    in a network circuit.
  • For very complex circuits, electrical engineers
    use computer programs that can rapidly solve
    equations for the circuit using Kirchhoffs laws.

38
Example 5
  • Three bulbs, each with a resistance of 3O, are
    combined in the circuit in the diagram
  • Three volts are applied to the circuit.
  • Calculate the current in each of the bulbs.
  • From your calculations, do you think all three
    bulbs will be equally bright?
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