2. Good Day! 3/11/2016 Starter: What is electricity all about? How do we measure it? Starter: What is electricity all about? How do we measure it? Today we will be learning more about electricity. Today we will be learning more about electricity. Before we get to that we need to Before we get to that we need to Turn in the worksheet from yesterday (Charge and Static Electricity) Turn in the worksheet from yesterday (Charge and Static Electricity) When we have gotten to a certain point on the worksheet we will finish the demos on charge (Play with the fun stuff from yesterday) When we have gotten to a certain point on the worksheet we will finish the demos on charge (Play with the fun stuff from yesterday)

3. Answer Electricity is the movement of electrons. Electricity is the movement of electrons.

4. What is current like? That is what we are going to be talking about today. We will compare electric current to something that is very familiar to you. That is what we are going to be talking about today. We will compare electric current to something that is very familiar to you. The answer is Water : ) The answer is Water : )

5. Electric Current

6. Answer the questions on your paper using what you see. lightbulb

7. The Pump is like the Battery Battery

8. The wire is like The pipe The pipe

9. The Light bulb is like A narrow part of the pipe A narrow part of the pipe

10. The water is like the electrons

11. The voltage is like the water Pressure Pressure It measures the force that the water/electrons can have or the work they can do. It measures the force that the water/electrons can have or the work they can do.

12. If you were using the battery to power a small motor rather than a light bulb what do you think would be a good analogy for a motor? Waterwheel Waterwheel

13. Electric Current The rate at which electrons flow. The rate at which electrons flow. I Amperes (A) = Coulomb/Sec Amperes (A) = Coulomb/Sec A Coulomb is an amount of charge. A Coulomb is an amount of charge.

14. Current measures how many charges go by in one second.

15. Voltage The force the electrons have The force the electrons have V Volts (V) Volts (V) That one is an easy one. That one is an easy one.

16. Resistance An objects ability to resist the flow of the electrons An objects ability to resist the flow of the electrons R Ohms (Ω) (it was a guys name) Ohms (Ω) (it was a guys name)

17. What is the difference between parallel and series circuits. Parallel has more than one path for electrons to flow. Parallel has more than one path for electrons to flow.

18. Series and Parallel Circuits Circuits usually include three components. One is a source of voltage difference that can be provided by a battery or an electrical outlet. Another is one or more devices that use electrical energy. 7.3 Electrical Energy Circuits also include conductors such as wires that connect the devices to the source of voltage difference to form a closed path.

19. Series Circuits One kind of circuit is called a series circuit. In a series circuit, the current has only one loop to flow through. 7.3 Electrical Energy Series circuits are used in flashlights and some holiday lights.

20. Open Circuit How can one faulty bulb cause a whole string of lights to go out? When any part of a series circuit is disconnected, no current flows through the circuit. 7.3 Electrical Energy This is called an open circuit. The burned- out bulb causes an open circuit in the string of lights.

21. Parallel Circuits Houses are wired with parallel circuits. 7.3 Electrical Energy Parallel circuits contain two or more branches for current to move through. The current can flow through both or either of the branches.

22. Parallel Circuits Click here to play movie Parallel circuits have several advantages. When one branch of the circuit is opened, such as when you turn a light off, the current continues to flow through the other branches.

23. Household Circuits The wiring in a house must allow for the individual use of various appliances and fixtures. This wiring is mostly a combination of parallel circuits connected in an organized and logical network. 7.3 Electrical Energy

24. Household Circuits The main switch and circuit breaker or fuse box serve as an electrical headquarters for your home. 7.3 Electrical Energy

25. Household Circuits Parallel circuits branch out from the breaker or fuse box. Many of these branches have are series circuits, for example the wall sockets are in series.

26. Household Circuits 7.3 Electrical Energy This means that household wiring ends up having a combination of parallel and series circuits.

27. Fuses An electrical fuse contains a small piece of metal that melts if the current becomes too high. When it melts, it causes a break in the circuit, stopping the flow of current through the overloaded circuit. 7.3 Electrical Energy

28. Fuses To enable current to flow again in the circuit, you must replace the blown fuse with a new one. Too many appliances in use at the same time is the most likely cause for the overheating of the circuit. 7.3 Electrical Energy

29. Circuit Breaker A circuit breaker contains a piece of metal that bends when the current in it is so large that it gets hot. The bending causes a switch to flip and open the circuit, stopping the flow of current. 7.3 Electrical Energy Circuit breakers usually can be reset by pushing the switch to its "on" position.

30. Electric Power The reason that electricity is so useful is that electrical energy is converted easily to other types of energy. The rate at which electrical energy is converted to another form of energy is the electric power. 7.3 Electrical Energy

31. Calculating Electric Power Electric power can be calculated from the following equation. The unit for power is the watt (W). Because the watt is a small unit of power, electric power is often expressed in kilowatts (kW). One kilowatt equals 1,000 watts.

32. Electrical Energy Electric companies charge by the amount of electrical energy used, rather than by the electric power used. Electrical energy usually is measured in units of kilowatt hours (kWh) and can be calculated from this equation: 7.3 Electrical Energy

33. The Cost of Using Electrical Energy The cost of using the appliance can be computed by multiplying the electrical energy used by the amount the power company charges for each kWh. 7.3 Electrical Energy For example, if a 100-W lightbulb is left on for 5 h, the amount of electrical energy used is

34. The Cost of Using Electrical Energy The cost of using some household appliances is given in this table, where the cost per kWh is assumed to be $0.09/kWh.

35. 7.3 Section Check Question What is an open circuit? Answer An open circuit is a series circuit in which one part is disconnected. This prevents current from flowing through the circuit.

36. 7.3 Section Check Question The rate at which electrical energy is converted to another form of energy is called __________. A. electrical fuse B. electrical switching C. electric power D. thermal energy

37. 7.3 Section Check Answer The answer is C. Electric power is the rate of energy conversion and is measured in watts.

38. 7.3 Section Check Question Which of the following equations is used to calculate electric power? A. P = IV B. P = I/V C. P = V/I D. P = AV

39. 7.3 Section Check Answer The answer is A. Electric power is equal to the current, I, multiplied by the voltage difference, V.