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2.4.  A practical way to describe a circuit is to draw a circuit diagram  Uses standard symbols to represent the components and their connections.

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Presentation on theme: "2.4.  A practical way to describe a circuit is to draw a circuit diagram  Uses standard symbols to represent the components and their connections."— Presentation transcript:

1 2.4

2  A practical way to describe a circuit is to draw a circuit diagram  Uses standard symbols to represent the components and their connections

3 SYMBOLCOMPONENTSYMBOLCOMPONENT Connecting wireCell SwitchBattery

4 SYMBOLCOMPONENTSYMBOLCOMPONENT ResistorVoltmeter BulbAmmeter

5  Draw a simple circuit (using symbols) that includes:  2 cells  A switch  A resistor  A light bulb

6

7  There are essentially 2 types of circuits:  Series  Parallel

8  Only 1 pathway for current to flow  Simple  Electrons only have one path to follow  Each electron must go through each load, in turn  Current (I) is the same at each point in the circuit

9  More than 1 pathway for current to flow  Charges flow around 2 or more different “loops”  Current is not the same at all points  Some electrons will take one path and others will take a different path  Most circuits are a combination of series and parallel

10  Ammeter measures current (in amperes, A) at a particular location in the circuit  Where the ammeter is located!  Ammeter is always connected in series

11  Voltmeter measures potential difference (in volts, V) between 2 points  Electric potential on one side of a load, such as a bulb or resistor, is greater than the electric potential on the other side  Voltmeter measures this difference  Always connected in parallel

12  What if one of the bulbs was burnt out?  Bulbs must be connected in parallel  How do we turn the lights on?  1 switch  Power source and switch must be connected in series

13  The current is the same at all points in a series circuit  I T = I 1 = I 2 = I 3 …

14  Loads transform electrical energy into other forms of energy  The total energy transformed must equal the work that is done by the cell (power source) .: The potential difference of the cell must equal the sum of the potential differences of each load

15  V T = V 1 + V 2 + V 3 …

16  The total resistance of the circuit will increase as more loads are added in series  R T = R 1 + R 2 + R 3 …  What would happen if we added more loads (i.e. light bulbs) in series?

17  There is more than one path for electrons to flow  The current entering a parallel connection divides  The sum of the currents through each path equals the total current  I T = I 1 + I 2 + I 3 …

18  Voltage is the same across all loads in the circuit  Equivalent to the potential difference across the cell  V T = V 1 = V 2 = V 3 …

19  The total resistance of loads connected in parallel, is less than the resistance of any of the loads individually  R T < R 1 ; R T < R 2 ; R T < R 3 ; …

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