1. Electricity and Ohm’s Law Completing the Circuit The flow of electrons is called electric current The unit of electric current is the ampere or amp for short The symbol for amp is A An amp is the measure of how many electrons flow per second Electricity

2. Electricity and Ohm’s Law Completing the Circuit For electricity to flow in a circuit it must have: 1.A complete pathway for the electrons to flow through eg connected wires 2.An energy supplier eg a battery 3.An energy user eg a lamp Electricity

3. Electricity and Ohm’s Law Completing the Circuit Draw the 3 circuits Under each one say why you think they will work or won’t work. AB C

4. Electricity and Ohm’s Law Completing the Circuit Voltage (Potential Difference) A potential difference occurs when there are more electric charges in one location than in another The unit of potential difference is a volt The symbol for volt is V Example: excess electrons will be attracted to the positive plate because of the potential difference + + + + + + + - - - - - - - - - - - - - - - - - - - e-

5. A More Relevant Example In a household electric outlet, the potential difference (voltage) between the two slots is 240 volts Because of a power plant many miles away, electrons are under “pressure” to move from one slot to the next

6. Electrical Circuits An electrical circuit is formed when electrons are given a path to move across a potential difference Generally, conducting (metal) wires are used to “complete” the circuit

7. Electrical Circuits A circuit like this where the electrons have only one path is called a series circuit.

8. Bomb Circuit Pretend a bulb is a bomb and a switch is a key to detonate it. Draw a circuit where the key will set off the bomb

9. What type of Circuit is it? A series circuit

10. Emergency Now the evil powers of the world rewired the circuit so two keys would detonate the bomb Draw this circuit

11. What Type of Circuit is this? A parallel circuit

12. Electrical Components An electric current is a movement of charged particles. Draw, name and give the main function of the following components Name: cell Function: source of electrical energy +- Name: Lamp Function: turns electrical energy to light Name: resistor Function: to slow current flow Name: fuse Function: to melt when short circuit occurs or too much power is drawn

13. Name Function: Ammeters must be placed in circuits in V Name Function: Voltmeters must be placed in circuits in ammeter to measure current series voltmeterTo measure voltage parallel diodelets current flow in one direction only Copy out and complete the following A

14. Draw the following in symbol form 3 cells joined in series power pack open switch variable power pack

15. Electrical Components An electric current is a movement of charged particles. Draw, name and give the function of the following components Name: Rheostat Function: to vary resistance Or variable resistor

16. Draw a series circuit with a 6volt cell 2 lamps and two ammeters If both lamps are the same comment on their brightness Draw voltmeters to measure the voltage of each lamp If 4 amps was applied to the circuit, what would each ammeter read lamp + - A A V V

17. Now make the circuit with the gear provided. Use the multimeters to: + - A1 Measure the voltage across each lamp Lamp 1 = Lamp 2 = Measure the current at 2 different places in the circuit A1 = A2 = V A2 V

18. Voltage Voltage (also called potential difference) measures: 1. The energy lost across a component 2. Energy supplied by the power supply or battery The unit of voltage, the volt (symbol V) represents the energy change each second for every amp of current If a lamp uses 1.5 volts this means that for every amp of current 1.5 joules of energy is lost every second. Voltage is measured with a voltmeter. Voltmeters must always be connected in parallel to the component for which the voltage is being measured

19. Current in a Series Circuits In a series circuit the current flow is along the same path Current in a series circuit is the same at any point of a series circuit Current is measured by an ammeter and must always be added to a circuit in series + - A1 A2 If 4 amps is supplied to the series circuit A1 = 4 amps A2 = 4 amps + - A1 A2

20. Voltage in a Series Circuit If there is only one component in a circuit the voltage across the power supply is equal to the voltage across the components + - V V 6V In a series circuit the voltage across the components add up to the supply voltage

21. Voltage in a Series Circuits + - V V1V1 4V + 2V= 6V 2V In a series circuit the voltage across the components add up to the supply voltage, what is the voltage at V1? What does the voltage drop over each component depend on? V 4V The resistance of the component which is related to the energy usage

22. Voltage in a Series Circuits What’s an advantage of a series circuit? What’s a disadvantage of a series circuit? Where are series circuits used?

23. Home Wiring: Series Circuits If lights or appliances are connected in series they will not experience the same voltage Since most lights and appliances are designed to work at a specific voltage, they cannot be connected in series The resistance of lights or appliances connected in series is the sum of their resistances Voltage Lights Switch Fuse

24. + - 6 V Parallel Circuits These are circuits where the lamps are in parallel with each other in separate branches All the lamps glow with same brightness. Why? Because the voltage over each lamp is the same as the supply voltage V V 6 V

25. + - Current in Parallel Circuits Current splits over each branch of a parallel circuit A2 A1 A3 A4 If the current supplied to the parallel circuit at ammeter A1 = 6 amps then: A1 = ____amps A2 = ____ amps A3= ____ amps A4= ____amps 6 6 3 3

26. Home Wiring: Parallel Circuits A single switch can be used to turn on multiple lights or appliances if they are connected in parallel The voltage is the same for each light or appliance, although the current increases with each new addition A fuse is designed to break if the current gets too large Voltage Lights Switch Fuse

27. Series circuit Parallel circuit Current splits over each branch in a parallel circuit VoltageCurrent Voltage in a parallel circuit stays the same as the supply voltage Current stays the same at all points in a series circuit Voltage drops over each component in a series circuit Starter – draw the grid then make a statement

28. How can two switches work lights in a hallway? switch

29. Conventional Current Conventional current is the flow of positive charges from the positive terminal of a power supply to the negative terminal of a power supply – we will use conventional current when looking at the direction of current flow in a circuit Conventional current (I) Electron flow moves this way through the wire This is important when looking at diodes!

30. Resistance Resistance is anything that slows the flow of charged particles Resistance is measured in ohms (symbol  )

31. Ohm’s Law Voltage, current and resistance in an electric circuit can be related using Ohm’s Law Ohm’s law states that V = I x R where –V is the voltage (in volts) –I is the current (in amps) –R is the resistance (in ohms)

32. V IR X Task: Rearrange the formula (V= I x R) using ohms law to find the formula for: I = V =R =

33. Using Ohms law Example If a lightbulb in a 240volt circuit is connected and has a resistance of 60 , what current is flowing through the bulb? Answer: Rearrange V = I x R

34. Example 1 If 4 amps of current are flowing through a toaster connected to a 120 V outlet, what is the resistance of the toaster? Answer: Rearrange V = I x R

35. 12 V Level one Questions – draw the following circuit L1 L2 L3 With both switches closed the current in L1 is 2A 1. Draw the symbol for the component that could measure the voltage across L2 2. What would the device measure? 3. Calculate the resistance of lamp L1 show your working and state the unit 4. Describe the brightness of lamp L2 compared with the brightness of lamp L1 and lamp L3

36. Investigating voltage – current relationships We will investigate the R = V/I relationship in a circuit to see if resistance changes when voltage and current is changed at constant temperature. Method Set up a series circuit with a heat sync resistor (designed to dissipate heat) a variable voltage supply and an ammeter. Vary the voltage supply, read current and fill in the chart below. Voltage Current Now plot your results on the provided graph paper Voltage on the ‘Y” axis and Current on the “X” axis

37. Investigating voltage – current relationships Once you have plotted the points draw a straight line graph and find the gradient of the line The gradient of the line gave us the r________ of the circuit which = ____ ( )? Ohmic conductors Because the resistance did not change when both current and voltage were changed the resistor is an ohmic conductor This is because the temperature of the heat sync resistor remained constant Non Ohmic Conductors (conductors whose temperature increases with voltage and current) Now plot the figures from a circuit with a lamp (a non Ohmic conductor) on page 167 What do you notice?

38. Investigating voltage – current relationships The gradient of the ohmic voltage vs current graph gave us the ________ of the circuit. Ohmic conductors Because the resistance did not change when both current and voltage were changed the resistor is an ohmic conductor This is because the temperature of the heat sync resistor remained constant V I

39. Non Ohmic conductors NonOhmic Conductors (conductors whose temperature and therefore resistance increases with increasing voltage and current) Examples of non ohmic conductors are lamps and resistors V I

40. Power In an electrical circuit power (P) is the rate at which electrical energy is : In an electrical circuit power (P) is the rate at which electrical energy is : a. Used by a component eg a lamp or … b. Supplied by a power source eg battery

41. Power continued Power is measured in Watts (W) Power is measured in Watts (W) One watt = 1 joule of energy used per second Larger amounts of energy use the unit kilowatts One kilowattt = 1000 watts

42. Examples A 100 W lamp uses 100 joules of energy per second. A motor which uses 2,500 joules of electrical energy each second has a power rating of 2,500W or 2.5 Kw

43. Starter – Question Where are parallel circuits used and why?

44. Calculating Power Power can be calculated using the voltage and current in the circuit. Using the following formula. P = V x I Where: P = power (Watts) V = volts I = current Can you put these in a triangle to help remember them P VI X

45. A V 12V 5A Calculate the following power supplied to the lamp P = V I = 12v x 5A = 60 W

46. Use the following circuit to answer the questions A3 A2 A4 A1 V 1. If each of the cells is rated at 2.5 volts what would the voltmeter read? 2.5v + 2.5v + 2.5v = 7.5v (A) 2. If each lamp had a resistance of 1.25 ohms calculate the total resistance in the circuit 1.25  + 1.25  + 1.25  = 3.75  (A) 3. How much power would the circuit use? (M/E)

47. 8 V The resistors are identical I= 1.5A 4V 1. What is the voltage across the bulb? 4V 2. What is the current through the bulb? 3 Amps

48. Radio (100 W) Fridge (200 W) TV (500 W) Heater (1000 W) Fuse 10A 240 V AC a.What is the purpose of a fuse? To break the circuit if too much current is drawn b. If all the appliances are turned on at once will the fuse blow? 0.416A 0.83A 2.08A 4.16A No the fuse would not blow Draw the circuit

49. Read Page 168 Complete questions – 3, 4 a & 4b on page 169 These are important questions

50.  R= 3  V 3V What is the current through the resistor? V 3V A 0.5 A A car battery supplies a current of 200A to a starter motor at a voltage of 10V. What is the resistance of the starter motor What is the resistance of a bulb if a 240V supply causes a current of 2A to flow through it when it is heated to constant temperature.

51. QUESTION THREE: ELECTRICITY Amanda connected a light bulb in series to a variable power supply and an ammeter. A voltmeter was connected in parallel to the light bulb. (a)Draw a circuit diagram of this set-up in the space below. (b)Comment on the positions of the ammeter and voltmeter in the circuit.

52. Voltage (V) 24681012 Current (I)0.20.40.60.80.90.95 The power supply voltage was gradually increased and the readings on the voltmeter and ammeter were recorded in the chart below. (c)Draw a graph of these results on the grid below.

53. (d) Use the equation V = I x R to calculate the resistance of the light bulb when it is operating on 6 Volts. R =V/I = 6/0.6 = 10 Ohms (e) Describe what happens to the resistance of the light bulb at higher voltages, and give a reason for this behaviour. The resistance of the bulb increases at higher voltages. At higher voltages the temperature of the filament increases. As the temperature increases so does the resistance of the circuit.

54. (f) (i) Show that the light bulb uses 90J of electrical energy when it is operated at 10V for 10 seconds. One of the two steps attempted. P =V x I = 10 x 0.9 = 9W E = P x t = 9 x 10 = 90J

55. (f) (ii) Comment on whether you think the light bulb will produce 90J of light energy in 10 seconds at this voltage setting. It will produce less than 90J of light energy. As energy is lost as heat energy

56. Task 1 : Use the wires and bulbs to make a series circuit with one bulb + _ Transformer on 6 volts

57. Task 1 : Use the wires and bulbs to make a series circuit with one bulb

58. Task 2 : Use the wires and bulbs to make a series circuit with two bulbs Write down how the brightness of the bulb in Task 1 compares the brightness of the bulbs inTask 2 + _ Transformer on 6 volts

59. Bulbs in series When the current flowed through just one bulb the lamp was b________. When another lamp was added both lamps went d________. This showed us that the voltage dropped each time it went through a lamp.

60. Adding Voltmeters Voltmeters are always added to a circuit in parallel Task Now make a circuit with one lamp and measure the voltage over it using the voltmeter (remember voltmeters always go in parallel as I showed you) + - V1 Draw the diagram The voltmeter reading V1 = ______ volts

61. Read parallel and series circuits page ____ in text + - V1 V2 Now draw the series circuit below The 2 voltmeter readings are V1 = ______ volts V2 = _____ volts

62. Read parallel and series circuits page ____ in text Write Heading in book Current in Series circuits

63. + - A1 Now draw the series circuit below Use an ammeter to measure the current at A1 and A2 A1 = ______ amps A2 = _____ amps A2

64. + - A1 Now draw the series circuit below and copy the text Complete the following Current in a series circuit s____ the s_____ at all points A2 Ammeters are always added in series (that is one behind each other) to all circuits

65. Starter : On the sheet of paper place your name then draw a series circuit with a cell two lamps and a switch between the two lamps Now mark it + - 1 mark each for Lamp symbol Switch symbol Cell symbol All wires connected Give mark out of 5

66. + - A1 Current in a series circuit If current at A1 = 3 Amps then the current at A2= 3 amps Current in a series circuit stays the same at all places A2 Ammeters are always added in series (that is one behind each other) in all circuits If the current was changed so A1 = 4 Amps what would A2 = 4 Amps

67. + - V1 V2 Voltage in a Series circuit If the battery supplies 6 volts to the circuit and the voltage drops evenly over both bulbs then the voltmeter readings are V1 = ___ and V2 = _____ In a series circuit voltage drops over each lamp 6 V

68. Read parallel and series circuits page ____ in text

69. + - 6 V Voltage in Parallel Circuits These are circuits where the lamps are in parallel with each other in separate branches All the lamps glow with same brightness because the voltage over each lamp in a parallel circuit is the same as the cell voltage V1 V2 This means if the supply voltage is 6 volts then: V1= ____ volts V2= ____ volts

70. Series circuit Parallel circuit Current splits over each branch in a parallel circuit VoltageCurrent Voltage in a parallel circuit stays the same as the supply voltage Current stays the same at all points in a series circuit Voltage drops over each component in a series circuit Summary – remember this

71. Task 1 : Make a series circuit with 2 bulbs and a switch that turns both bulbs off. Draw the circuit diagram Task 2 : Make a parallel circuit with two bulbs in it Draw the circuit diagram Task 3 : Place a switch in the circuit that turns off one lamp at a time place a variable resistor in it to dim the lights Draw the circuit diagram

73. Electric Current The flow of electrons is called electric current The unit of electric current is the ampere or amp for short The symbol for amp is A An amp is the measure of how much charge flows by per second

74. 09/11/2015 The structure of the atom ELECTRON – negative, mass nearly nothing PROTON – positive, same mass as neutron (“1”) NEUTRON – neutral, same mass as proton (“1”)

76. Electrical Circuits An electrical circuit is formed when electrons are given a path to move across a potential difference Generally, conducting (metal) wires are used to “complete” the circuit

77. Electrical Resistance Electrical resistance is the measure of the resistance of part of a circuit to the flow of electricity (current) Electrical resistance is measured in ohms Ohms are often represented by the symbol omega (  ) Example: the filament of a 100 W lightbulb presents a resistance of about 140  to the flow of electricity

78. The Water Pressure Model A helpful way of thinking about current, voltage and resistance is to compare electricity to the flow of water –voltage (i.e. potential difference) is similiar to the water pressure –current is similar to the flow of water –resistance is similar to the diameter of the pipe (e.g. a small pipe allows much less water to flow than a large pipe)

79. Ohm’s Law Voltage, current and resistance in an electric circuit can be related using Ohm’s Law Ohm’s law states that V = I x R where –V is the voltage (in volts) –I is the current (in amps) –R is the resistance (in ohms)

80. Example 1 If 4 amps of current are flowing through a toaster connected to a 120 V outlet, what is the resistance of the toaster? Answer: Rearrange V = I x R to get R = V/I Thus, R = (120 V)/(4 A) = 30 

81. Example 2 If a lightbulb connected to an outlet has a resistance of 144 , what current is flowing through the bulb? Answer: Rearrange V = I x R to get I = V/R Thus, I = (120 V)/(144  ) = 0.83 A

82. Home Wiring: Parallel Circuits A single switch can be used to turn on multiple lights or appliances if they are connected in parallel The voltage is the same for each light or appliance, although the current increases with each new addition A fuse is designed to break if the current gets too large Voltage Lights Switch Fuse

83. Home Wiring: Series Circuits If a lights or appliances are connected in series they will not experience the same voltage Since most lights and appliances are designed to work at a specific voltage, they cannot be connected in series The resistance of lights or appliances connected in series is the sum of their resistances Voltage Lights Switch Fuse

84. Example What is the total resistance of three 100 W light bulbs (each 144  ) in series? Answer: 144 + 144 = 432  What is the total current through three 100 W light bulbs? Answer: I = (120 V)/(432  ) = 0.27 A Note: this is significantly less than the 0.83 A that will flow through a single bulb (i.e. the bulbs will be dimmer)