1. “Electrical Fundamentals”

2. Always Remember, Safety is #1 and Everyone’s Business!

3. Use Safety Equipment

4. Remove Jewelry

5. Do not wear rings or jewelry when working on electrical circuits.
ELECTRICAL BURNS
Do not wear rings or jewelry when working on electrical circuits.
Never use screwdrivers or other conductive tools in an electrical panel when the power is on.

6. Lift and Move Correctly

7. High voltage is always dangerous.
Electric Shock
BE CAREFUL!
High voltage is always dangerous.
Even 40 volts can be lethal if skin is wet or damaged.

8. Current is the killing factor in electrical shock.
Currents between 100 and 200 mA generally cause the heart to fibrillate.
A 110 volt power circuit will generally cause between 100 and 200 mA current flow through the bodies of most people.

9. LOCKOUT – TAGOUT PROCEDURES
Whenever a piece of equipment is being worked on, it should be disconnected from the power source and locked.
The person working on the equipment should carry the only key to prevent accidental activation.

10. DO NOT WORK ALONE
If you must test a live circuit, have someone with you ready to turn off the power, call for help, or give cardiopulmonary resuscitation (CPR).

11. LEARN FIRST AID
Anyone working on electrical equipment should take the time to learn CPR and first aid.

12. NON-CONDUCTING LADDERS
Aluminum ladders can be hazardous if they come in contact with power lines.
Fiberglass or wood ladders should be used.

13. Fuses and breakers are used to protect wires, not people.
CIRCUIT PROTECTION
Fuses and circuit breakers are used to protect a circuit against over current.
The amperage rating of a fuse must not be greater than the ampacity of the wires being protected.
Fuses and breakers are used to protect wires, not people.

14. “Power is the rate at which work is done.”

15. Calculating Electrical Power
“Power is the rate at which work is done.”
Power = Intensity x Electromotive force
P = IE
Power (watts) = Amps x Volts

16. Power (watts) = Amps x Volts Power = Intensity x Electromotive force
What is the power consumption of an electric circuit using 15 amperes and 120 volts?
Power (watts) = Amps x Volts
Power = Intensity x Electromotive force
P = IE
P = 15 amps x 120 volts
P = 15 x 120
P = 1800 Watts

17. Power (watts) = Amps x Volts Power = Intensity x Electromotive force
What is the current of an electric heater rated at 4800 watts on 240 volts?
Power (watts) = Amps x Volts
Power = Intensity x Electromotive force
P = IE solve for I
P  E = I
4800 watts  240 volts = I (amps)
4800  240 = 20 Amps

18. Ohm’s Law Wheel
All applications of Ohm’s Law formulas can be represented as the spokes of a wheel.

19. E is Electromotive force in Volts
Ohms Law Wheel
P is Power in Watts
I is Intensity in Amps E2 R E R
I2 R P E IE P R P E I R E .I PR P .I E2 P P I2 IR
R is Resistance in Ohms
E is Electromotive force in Volts

20. Resistance & Loads Resistance: Loads:
Opposition to electron flow in the circuit
Measured in ohms (Ω)
Loads:
Must have some resistance
Provide a path for electron flow

21. Compare Resistance To Crossing A River
Resistance is the open space between the shores
Cars represent electrons
Bridges represent loads
Without bridges there is no way the cars can cross
This is known as “infinite” resistance

22. Infinite
Resistance

23. A Load Is Added The load provides a path for electrons
There is still high resistance to flow
But it is no longer infinite resistance

24. A small load provides a path for some of the electrons
But there
is still
High Resistance

25. More Load Is Added
Less resistance
More electron flow

26. Lower resistance means more electrons, or current flow.
The
resistance
is lower

27. Low Or No Resistance Can Be Bad
The lower the resistance,
The higher the electron flow
If the current flow is out of control,
The circuit is overloaded

28. OVERLOAD If
resistance
is too low,
electron flow
will be too high.

29. Resistance, Watts, And Amps
Load resistance affects amps and watts
The lower a load’s resistance
The higher it’s amps and watts

30. How Resistance Affects Amps and Watts
(Note: approximate values in an alternating current 120v circuit)
OPEN L1 N
Infinite Resistance
∞ Ohms
(R)
No Watts
(P)
No Amps
(I)
1500 Ohms
.08 A
10 W
150 Ohms
.8 A
100 W
15 Ohms
1000 W
8 A
BOOM
High Watts & High Amps
Circuit Breaker
Trips
0 Ohms

31. Direct Current Moves in one direction Negative to positive
Can be produced through chemical action
Chemical electrolyte produces electrons
Negative cathode gives away electrons
Positive cathode collects electrons

32. Direct Current (DC) Electrolyte Zinc Case (Negative Electrode)
Carbon Rod
(Positive Electrode)
Dry Cell Battery
When load is attached the chemical reaction in the electrolyte causes current flow

33. Alternating Current (AC)
Moves in one direction, then the other
Produced by a generator

34. Alternating Current (AC)
Generator
Generators produce Alternating Current
First, the current goes in one direction
Then it reverses, or alternates, in the opposite direction

35. Alternating Current (AC)
Generator
In the U.S. there are 60 complete cycles per second

36. Cycles and Frequency Cycle: Frequency Measurement of frequency:
One complete electrical alternation
Frequency
Number of cycles in a second
Measurement of frequency:
Hertz (Hz)
Cycles
U.S. frequency is 60 hertz, or 60 cycles

37. Generating Alternating Current (AC)
Passing a conductor through a magnetic field.
A generator uses many conductors and a large magnetic field to produce electrical current.

38. Generating Alternating Current (AC)
Passing a conductor through a magnetic field.
A generator uses many conductors and a large magnetic field to produce electrical current.

39. Generating Alternating Current
Magnet
NORTH
Passing a conductor between two magnets causes electrons to flow in the wire.
This produces electrical current in the wire.
SOUTH
Magnet
Conductor

40. Expressing AC with a Sine Wave
A sine wave shows how alternating current flows in one direction, then reverses to flow in the opposite direction.

41. Sine Wave of Alternating Current
Magnet 0º
90º
180º
270º
360º
NORTH
Positive
Negative
SOUTH
Magnet
One cycle
Conductor

42. Alternating current starts at 0, reaches a peak, then returns to 0
Effective voltage
Alternating current starts at 0, reaches a peak, then returns to 0
Peak voltage at 90° (electrical degrees)

43. Generating 3 Phase Alternating Current
3Ø current is generated by passing three conductors through a magnetic field

44. Generating 3Ø Current
Magnet
NORTH
Current is generated in each conductor as it passes through the magnetic field.
SOUTH
Magnet

45. Sine Wave of 3 Phase Current
Magnet 0º
120º
240º
360º
NORTH
90º
180º
270º
SOUTH
Magnet
Each sine wave starts 120° after the other.

46. Sine Wave of 3 Phase Current
Magnet 0º
120º
240º
360º
NORTH
90º
180º
270º
SOUTH
Windings 120° out of phase give 3Ø motors their high starting torque.
Magnet

47. Meter Types Voltmeter – measures voltage
Ohmmeter – measures resistance (ohms)
Ammeter – measures current (amps)
Multimeter – a combination meter that measures volts, ohms, & amps

48. Voltmeters Measure electromotive force of a circuit in volts
Always set meter at the highest voltage scale to prevent meter damage
1 Volt = 1,000 millivolts (mV)

49. Using a Voltmeter
Line Voltage 120V
Load

50. Ohmmeter
The meter uses an internal battery to push voltage through a device. The resistance encountered by the battery’s current is measured in ohms. Open: Infinite resistance (∞ or OL) Example: Switch open, broken wire, etc. Closed or Short: No resistance (0) Example: Switch closed, wires connected, or shorted winding Measurable resistance: Any value between 0 - ∞ Example: Resistance of a motor winding or heater wire

51. How to Read an Ohmmeter How to Read an Ohmmeter No Resistance
(Short or closed circuit)
Infinite Resistance
(Broken wire or open switch)
Measurable resistance
Good for loads (coils, heaters, and motors)

52. Using a voltmeter to check switch contacts
Checking switches with power on the circuit
The voltmeter can show whether they are open or closed

53. Checking Switches with a Voltmeter
Line Voltage 240V
Switch
Open
? Or ?
Closed
Switch
Load
Switch
Closed
Switch
Open

54. Checking for “Continuity”
Determine if the wiring within a load is continuous Example: Checking a resistance heater

55. Prove heater wire is broken
Checking Continuity
Prove heater wire is broken
Disconnect wires
Neutral
120 v
Power OFF
1200 Watt Heater
COM
V/  V AC DC
Hot
Disconnect wires
An open circuit has infinite resistance

56. Current flow creates a magnetic field
Ammeters (Amp Meters)
Current flow creates a magnetic field
Ammeters measure the intensity of the field

57. Measuring Current in Amperes
Power In
Current produces a magnetic field
OFF V
AMPS Ω
Ammeter measures the intensity (I) of the magnetic field
AMPS

58. Using an Ammeter Current intensity is measured in amperes
1 Amp = 1,000 milliamps (mA)
Most common ammeter is a “Clamp-on” type
Meter jaws must encircle only one wire

59. Measuring Current Flow
Neutral
120 v
COM
V/  V AC DC
Power ON
Power OFF
Heater energized
Hot
Current flow
No current
OFF V
AMPS Ω

60. Determining Circuit Resistance
An ohmmeter measures resistance
Ohm’s law calculates resistance
Measuring and calculating work together

61. Measuring and Calculating Resistance
Check voltage first
Disconnect wires
Now Check resistance
Neutral
120 v
Power OFF
Power ON
1200 Watt Heater
120 v
1200W
COM
V/  V AC DC
Hot
Heater resistance is 12Ω
Disconnect wires
Calculating Resistance using Ohm’s Law:
P = E I
or Watts = V x A
E = IR
120v =
I = P E E I
R = =
= 10A (amps)
10A
= 12Ω (ohms)

62. Series Circuit
Only one path for electrons to flow.
Current must be able to go through one device before it can go to the next device.

63. Series Circuits
A string of "old-fashioned " Christmas tree lights is an example of a series circuit.
120v

64. Resistance in Series Circuits
The more loads in a series circuit, the more resistance in the circuit
Total resistance is the sum of all the resistances in the circuit.

65. Calculating Series Circuit Resistance
Rtotal = R1 + R2 + R3 + R4 + … L1
R1 = 4 Ω
4 Ω
R2 = 10 Ω
10 Ω
R4 = 14 Ω
14 Ω
R3 = 12 Ω
12 Ω N
Rt =
Rt = + + +
= 40 Ω
40 Ω

66. Amperage in series circuits
The more loads in a series circuit, the greater the total resistance
The greater the resistance, the lower the total amperage (I = E/R or A = V/R)
The amperage will be the same everywhere in the circuit

67. Bulb dims as more bulbs are added
COM
V/  V AC DC
COM
V/  V AC DC
COM
V/  V AC DC L1
120v N
Why does adding bulbs to the circuit make them all dimmer?
Because there is less voltage available to each bulb.

68. What happens when a series circuit is opened?
Why?
All loads are de-energized because the flow of current is interrupted.
120v
120v
No current flow
Circuit is open L1 N L1 N
120v
That is why switches and controls are in series with the loads they control.

69. Parallel Circuits Loads are parallel to each other, not in series
There is more than one path for electrons to flow
Therefore:
Each load receives full voltage
Each load can operate independently

70. Measuring voltage in parallel circuits
COM
V/  V AC DC
COM
V/  V AC DC
COM
V/  V AC DC L1 L2
R1=4Ω
R2=10Ω
Each load receives the same voltage

71. Amperage in Parallel Circuits
The resistance of each load determines the amperage of each circuit.
Additional loads increase total amperage.

72. Simple Diagram of Parallel Circuits
The following slide shows how the loads in an air conditioning unit with electric heat might be sketched into a simple diagram.

73. A/C-Heating Unit Parallel Circuits
Load 1
Electric
Heater
Load 2
Load 3
Load 4
Evap
Mtr
Comp
Cond

74. A schematic diagram is also called a “ladder diagram”
Diagram Development
A schematic diagram is also called a “ladder diagram”
The rungs of the ladder are parallel circuits

75. A/C-Heating Unit Parallel Circuits
(Ladder Diagram)
Load 2
Load 3
Load 4
Evap
Mtr
Comp
Cond L2 L1
Load 1
Electric
Heater
Schematic Diagram
Load 2
Load 3
Load 4
Evap
Mtr
Comp
Cond L2 L1
Load 1
Electric
Heater

76. Diagram Set-Up
The lift side is usually considered the main power
The right side is usually considered common

77. Schematic Diagram (Ladder Diagram) Electric Heater Evap Mtr Comp Cond
Load 2
Load 3
Load 4
Load 1
Evap
Mtr
Comp
Cond
Electric
Heater
The left side (L1) is the “hot” side
The right side (L2) is the “common” side.
On a 120v circuit this side would be the “neutral”.

78. Series – Parallel Circuits
Controls and switches are in series with loads
An open switch stops current to any load in that one circuit.
A disconnect switch in the main power line stops current to all circuits after it.

79. Series - Parallel Circuits
Load 2
Load 3
Load 4
Load 1
Evap
Mtr
Comp
Cond
Electric
Heater
A disconnect switch
A heating thermostat in series with the heater
A cooling thermostat and pressure control in series with the compressor

80. Electrical Loads Loads Examples: Consume electricity Do work Motors
Solenoids
Heaters
Lights

81. (Letters tell what motor is represented)
Motors
Common symbols:
(Letters tell what motor is represented)
COMP
EFM
IFM
COMP
EFM
IFM
COMPressor
Evaporator Fan Motor
Indoor Fan Motor
COMP
CFM
OFM
CFM
OFM
COMP
Condenser Fan Motor
Outdoor Fan Motor

82. Solenoid
When current flows through a coil of wire it creates a magnetic field.
This will cause an action in a relay or valve.
Electrical symbol for a solenoid coil:

83. Magnetic coil energized
Solenoid Valve
Magnetic coil energized
Plunger pulled up
Power off
Plunger drops
This solenoid valve is in the NC (normally closed) position. The flow of liquid or vapor is stopped.
When the magnetic coil is energized the plunger is raised and fluid passes under the disk and through the pipe in the direction of the arrow stamped on the side of the valve.
Fluid flows
Plunger
Fluid stops
Seat

84. Heaters Convert electrical energy to heat
Symbol for resistance heaters:
Examples of heaters:
Auxiliary strip heaters
Crankcase heaters

85. Signal Lights B R G R Red B Blue G Green, etc.
Used to show when something is operating,
or when there is a problem.
Symbol for signal lights: B R G
Letter in the center denotes bulb color:
R Red
B Blue
G Green, etc.

86. Contactor It is a mechanical switch, operated by a magnetic coil
Energizing the coil closes the contacts
Power flows through the contacts to the load

87. Contactor Cutaway LINE 1 Power In CONTROL CIRCUIT 2 Coil 3 Contacts
LOAD
CONTROL CIRCUIT
LINE
1 Power In
2 Coil
3 Contacts
4 Power Out

88. Symbols for Contactors
Coil
Contact
Single pole
Double pole
Triple pole
115v
, 1
, 3
Symbols are shown “de-energized” (no power) with contacts “normally open”.
© 2005 Refrigeration Training Services - E1#4 Symbols and Wiring Diagrams v1.0

89. Visualizing Symbols With Power On
The following slide illustrates what happens when the power is turned on.

90. Contactor coil “Energized”
Contacts close
Coil
Contact
Single pole
Double pole
Triple pole
115v
, 1
, 3

91. Relays Similar to contactors Usually under 20 amp capacity
Contacts may be:
Normally open (NO)
Normally closed (NC)
Or a combination of NO and NC

92. Coil “de-energized” (no power)
Symbols for RELAYS
Coil “de-energized” (no power)
Normally Open
“NO”
1 2
Single pole
Double pole
Triple pole
#1 NO
#2 NC
#1 NC
#2 NO
#3 NC
Normally Closed
“NC”

93. Visualizing Symbols With Power On
The following slide illustrates what happens when the power is turned on.

94. Coil “energized” (powered up)
Symbols for RELAYS
Coil “energized” (powered up)
Normally Open
“NO”
1 2
Single pole
Double pole
Triple pole
#1 NO
#2 NC
#1 NC
#2 NO
#3 NC
Normally Closed
“NC”

95. Introduction to Switches
Switches open and close contacts to control a load
Contact:
the conducting part of a switch
Poles:
the number of contacts in a switch
Throw:
the number of closed contact positions per pole.

96. Single Throw Switch Symbols
Switch open
Switch closed
Single Pole – Single Throw
(SPST) L1
Switch open
Switch closed L2
Double Pole – Single Throw
(DPST)

97. Double Throw Switches
Each switch position closes a circuit

98. Single Pole - Double Throw (DPDT)
Contacts 1-2 closed
Contacts 1-2 open 2 1
Contacts 1-3 open
Contacts 1-3 closed 3

99. Double Pole – Double Throw (DPDT)
Contacts 1-2 closed
Contacts 1-3 closed 2 1 3 5
Contacts 4-5 closed 4 6
Contacts 4-6 closed

100. Thermostats
COOL
OFF
HEAT ON
FAN
AUTO B O W Y G R 70 80 60 50
Symbol depicts a bimetal spring which closes and opens the contacts.
Tstats are usually shown in their “normal” position, which is open.

101. Symbols for Thermostats
Cooling thermostat
In actual operation
As the temperature goes up
the rise in temperature causes the bimetal to expand
the expanded bimetal raises the arm
the raised arm closes the contacts

102. Symbols for Thermostats
Heating thermostat
In actual operation
As the room temperature falls
the fall in temperature causes the bimetal to contract
the contracted bimetal pulls down on the arm
the arm closes the contacts

103. Pressure Controls
Symbol depicts a bellows which operates the contacts.
Pressure safety controls are usually shown in their “normal” position, which is closed.

104. Symbols for Pressure Controls
Low pressure control
In actual operation
As the system pressure falls
the fall in pressure causes the bellows to deflate
the deflated bellows pulls down on the arm
the arm opens the contacts

105. Symbols for Pressure Controls
High pressure control
In actual operation
As the system pressure rises
the rise in pressure causes the bellows to inflate
the inflated bellows raises the arm
the raised arm opens the contacts

106. Fuses and Overloads
Symbols for safety devices, such as fuses and overloads, are usually shown closed.

107. Safety Device Symbols Fuses Overloads Bimetal overload:
High heat and high amperage open this overload switch.
Thermal overload relay:
Excessive amperage heats the thermal element, which opens the switch.
Magnetic overload relay:
Excessive amperage creates a magnetic field, which opens the switch.

108. Next Month – Understanding & Troubleshooting Wiring Diagrams
Schematic Diagrams
Next Month – Understanding & Troubleshooting Wiring Diagrams

109. It’s Time for Questions & Answers

110. Please Pass Your Business Cards Up
Thank You For Your Business for 2009!!