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Electricity

Learn about the fundamental concepts of electricity, including atoms, subatomic particles, electric charges, and electric circuits. Understand how electricity flows, the types of currents, Ohm's Law, and power calculations.

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Electricity

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  1. Electricity

  2. Atoms have 3 subatomic particles Protons = positive Electrons = negative Neutrons = neutral Neutral Atom “Normal” state # Protons = # Electrons Charged Atom (atom with a positive or negative charge) Object must gain or lose electrons ONLY THE ELECTRONS MOVE Measured in Coulombs Let’s Review…

  3. + + + - Charge & Force “Opposites Attract” Attraction Forces pull together Repulsion Forces push apart Rules of Charge Like charges repel (+/+ or -/-) Opposite charges attract (+/-)

  4. Electricity Definition: Electricity is the energy associated with charged particles as they move from place to place The type of material determines how charges move through them Conductors • Materials that allow electric charges to move easily • Metals Insulators • Materials that do NOT allow electrons to flow freely • Rubber, plastic

  5. Forms of Electricity Static • Due to build up of charges in or on an object Current • The flow of electrons in a circuit

  6. Static Electricity • Static electricity is electricity “AT REST” • Occurs between 2 objects that become oppositely charged • Objects involved have unequal electric charges • Examples • Clothes sticking together in the dryer (if no dryer sheet is used) • Hair standing up after being brushed (on days with low humidity)

  7. Lightning • Large discharge of static electricity (electrons transferred from a cloud to the Earth) • Friction from movement of water drops in a cloud build up positive and negative charges • Bolts can deliver 100 million volts • Safest place to be in a lightning storm is inside • Lightning rods are grounded to Earth to distribute the charge

  8. Electric Circuit An electric circuit is a path for the electrons to flow • Flowing Electrons = current Electricity can only flow through a CLOSED circuit (not an open one) Hi-Lite This!

  9. Voltage (Potential Difference) • The PUSH that makes electrons flow (electrons have potential to flow but won’t on their own) • A difference between energy levels is needed for flow • Electrons flow in a circuit when there is an energy difference from one end of the energy source to the other end of the energy source (like a battery) • Units = VOLTS (V) • Symbol = V (capital) • Measured with a Voltmeter

  10. Electric Current • The FLOW of electric charges in a circuit • Units = Amperes (amps) • Symbol = I • Speed of Current is affected by • Type, length, & thickness of wire • Voltage • When Voltage , Current 

  11. 2 Types of Electric Current Direct Current (DC) • Electron flow is always in the same direction • Ex: Batteries Alternating Current (AC) • Electrons reverse the direction of flow 60 times per second • Ex: Electricity in the Home

  12. Resistance • Opposition to the flow of electrons • Unit = Ohm (Ω) • Symbol = R • Highest resistance in: • Poor conductors • Thin wires • Long wires

  13. Ohm’s Law Relates Electric Current, Voltage, & Resistance V = I x R Voltage (volts, V) Current (amps) Resistance (ohms, Ω)

  14. Ohm’s Law Example Calculate the voltage across a 3Ω resistor if a 0.5 amp current is flowing through it. V = I x R

  15. Ohm’s Law Example Calculate the voltage across a 3Ω resistor if a 0.5 amp current is flowing through it. V = I x R V = ? R = 3 Ω I = 0.5 amp

  16. Ohm’s Law Example Calculate the voltage across a 3Ω resistor if a 0.5 amp current is flowing through it. V = I x R V = ? R = 3 Ω I = 0.5 amp V = (0.5 amp)*(3 Ω )

  17. Ohm’s Law Example Calculate the voltage across a 3Ω resistor if a 0.5 amp current is flowing through it. V = I x R V = ? R = 3 Ω I = 0.5 amp V = (0.5 amp)*(3 Ω ) V = 1.5 v

  18. Ohm’s Law Example 2 A radio with a resistance of 240 Ω is plugged into a 120 v outlet. What is the current flowing through the outlet? V = I x R

  19. Ohm’s Law Example 2 A radio with a resistance of 240 Ω is plugged into a 120 v outlet. What is the current flowing through the outlet? V = I x R V = 120 v I = ? R = 240 Ω

  20. Ohm’s Law Example 2 A radio with a resistance of 240 Ω is plugged into a 120 v outlet. What is the current flowing through the outlet? V = I x R V = 120 v I = ? R = 240 Ω 120 v = I * 240 Ω

  21. Ohm’s Law Example 2 A radio with a resistance of 240 Ω is plugged into a 120 v outlet. What is the current flowing through the outlet? V = I x R V = 120 v I = ? R = 240 Ω 120 v = I * 240 Ω I = 120v / 240 Ω

  22. Ohm’s Law Example 2 A radio with a resistance of 240 Ω is plugged into a 120 v outlet. What is the current flowing through the outlet? V = I x R V = 120 v I = ? R = 240 Ω 120 v = I * 240 Ω I = 0.5 amp I = 120v / 240 Ω

  23. Power • RATE at which energy is flowing • The measure of the RATE at which electricity does work or provides energy • Symbol = P • Units = Watts (W) P = I x V

  24. Power Example If a CD player uses 4.5v with 0.2 amp current, how much power does it use? P = I x V

  25. Power Example If a CD player uses 4.5v with 0.2 amp current, how much power does it use? P = I x V P= ? I = 0.2 amp V= 4.5 v

  26. Power Example If a CD player uses 4.5v with 0.2 amp current, how much power does it use? P = I x V P= ? I = 0.2 amp V= 4.5 v P = I * V

  27. Power Example If a CD player uses 4.5v with 0.2 amp current, how much power does it use? P = I x V P= ? I = 0.2 amp V= 4.5 v P = I * V P = (0.2amp)(4.5v)

  28. Power Example If a CD player uses 4.5v with 0.2 amp current, how much power does it use? P = I x V P= ? I = 0.2 amp V= 4.5 v P = I * V P = (0.2amp)(4.5v) P = 0.9 W

  29. ELECTRICAL Energy • Home use of electric energy is based on the AMOUNT OF ELECTRICAL POWER used per hour • Measured in kilowatt hours (1000 Watts per hour) = kWh E = P x t

  30. Electrical Energy Example You use your hairdryer for 20 minutes everyday. The hairdryer uses 1000 kW. How many kilowatt-hours does your hairdryer use in 6 days? t = 20min/day*6days = 120min = 2hr E = 1000 kW*2Hr E = 2000 kWh

  31. Circuits • Closed loop made up of at least two electrical elements • Consists of at least a power source, wire, and a device that uses electrical energy (like a light bulb)

  32. Symbols for Circuit Diagrams Positive Side of Power Source • Wire • Power Source • Bulb • Resistance • Switch (open) (closed) Negative Side of Power Source

  33. Open Circuit • Light will not go on because the wire IS NOT CONNECTED to the battery on both sides; current will NOT flow

  34. Closed Circuit • Light bulb turns on because the electrical current CAN now flow through the complete circuit

  35. Series Circuit • All parts of the circuit are connected one after another in a loop • There is only one path for the electrons to follow • If one part goes out • The circuit goes from closed to open • Electricity will not flow • All parts go out • The voltage is split through each part of the circuit • The current is the same throughout the circuit • Example: Christmas Tree Lights

  36. Series Circuit Examples A complete circuit turns the light bulbs on

  37. Series Circuit Examples This Light Bulb is Burnt Out The burnt bulb stops the electron flow to the rest of the circuit

  38. Parallel Circuit • There is more than one path or branch for the electrons • If a break occurs in one branch, the electrons can still flow in the other • The voltage is the same throughout each branch • The current is split through each branch • Example: Household Wiring

  39. Parallel Circuit Examples B A PATH #1 PATH #2 Current divides and has more than one path

  40. Parallel Circuit Examples This Light Bulb is Burnt Out A B Even though Bulb “B” is burnt out, the current still goes through the other circuit and Bulb “A” remains lit

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