400 likes | 427 Views
Unit 7, Chapter 19. CPO Science Foundations of Physics. Unit 7: Electricity and Magnetism. Chapter 19 Electricity. 19.1 Electric Circuits 19.2 Current and Voltage 19.3 Electrical Resistance and Ohm’s Law. Chapter 19 Objectives. Describe the difference between current and voltage.
E N D
Unit 7, Chapter 19 CPO Science Foundations of Physics
Unit 7: Electricity and Magnetism Chapter 19 Electricity • 19.1 Electric Circuits • 19.2 Current and Voltage • 19.3 Electrical Resistance and Ohm’s Law
Chapter 19 Objectives • Describe the difference between current and voltage. • Describe the connection between voltage, current, energy, and power. • Describe the function of a battery in a circuit. • Calculate the current in a circuit using Ohm’s law. • Draw and interpret a circuit diagram with wires, battery, bulb, and switch. • Measure current, voltage, and resistance with a multimeter. • Give examples and applications of conductors, insulators, and semiconductors.
Chapter 19 Vocabulary Terms • electricity • electric current • voltage • resistance • Ohm’s law • battery • open circuit • closed circuit • short circuit • switch • circuit diagram • electrical conductivity • potentiometer • wire • volt • electrical symbols • amperes (amps) • multimeter • ohm • resistor • ammeter • electrical insulator • semiconductor • conductor • electric circuit
Key Question: What is an electric circuit? 19.1 Electric Circuits *Students read Section 19.1 AFTER Investigation 19.1
19.1 Electric Circuits • Electricity refers to the presence of electric current in wires, motors, light bulbs, and other devices. • Electric current is similar to a current of water, but electric current flows in solid metal wires so it is not visible. • Electric current can carry a lot of power.
19.1 Electric Circuits • An electric circuit is something that provides a complete path through which electricity travels. • Wires in electric circuits are similar in some ways to pipes and hoses that carry water.
19.1 Electric Circuits • When drawing a circuit diagram, symbols are used to represent each part of the circuit. • These electrical symbols are quicker and easier to draw than realistic pictures of the components.
Key Question: How does current move through a circuit? 19.2 Current and Voltage *Students read Section 19.2 AFTER Investigation 19.2
19.2 Current and voltage • Electric current is measured in units called amperes, or amps (A) for short. • One amp is a flow of a certain quantity of electricity in one second. • The amount of electric current entering a circuit always equals the amount exiting the circuit.
19.2 Current and voltage • Conventional current was proposed by Ben Franklin in the 1700’s. • Scientists later discovered that the particles that carry electricity in a wire actually travel from negative to positive. • Today, we still use Franklin’s definition.
19.2 Voltage • Voltage is a measure of electric potential energy, just like height is a measure of gravitational potential energy. • Voltage is measured in volts (V). • A voltage difference of 1 volt means 1 amp of current does 1 joule of work in 1 second.
19.2 Voltage • Since 1 joule per second is a watt (power), you can interpret voltage as measuring the available electrical power per amp of current that flows.
19.2 Voltage • The positive end of a 1.5 volt battery is 1.5 volts higher than the negative end. • If you connect batteries positive-to-negative, each battery adds 1.5 volts to the total. • Three batteries make 4.5 volts. • Each unit of current coming out of the positive end of the three-battery stack has 4.5 joules of energy.
19.2 Measuring voltage of a cell • Set the meter to DC volts. • Touch the red (+) lead of the meter to the (+) battery terminal. • Touch the black (-) lead of the meter to the (-) battery terminal. • Adjust the meter dial as necessary.
19.2 Measuring voltage in a circuit • Measure the voltage across the battery exactly as before. • DO NOT DISCONNECT THE CIRCUIT. NOTE: Since voltage is measured from one point to another, we usually assign the negative terminal of a battery to be zero volts (0 V).
19.2 Current and voltage • A battery uses chemical energy to create a voltage difference between its two terminals. • In a battery, chemical reactions provide the energy to pump the current from low voltage to high voltage. • A fully charged battery adds energy proportional to its voltage.
A battery uses chemical energy to move charges. If you connect a circuit with a battery the charges flow out of the battery carrying energy. 19.2 What does a battery do?
19.2 How do these batteries differ? • Some are smaller and don't store as much energy. • Other batteries made with Ni and Cd can be recharged. • Which battery above has the greatest voltage capacity?
19.2 Measuring Current • In practical electricity, we still label current flowing from plus to minus or HIGH voltage to LOW voltage. • Current can't be measured unless the charges flow through the meter.
Key Question: How are voltage, current, and resistance related? 19.3 Electrical Resistance and Ohm’s Law *Students read Section 19.3 AFTER Investigation 19.3
Resistance measures how difficult it is for current to flow. 19.3 Electrical resistance
19.3 Electrical Resistance • The total amount of electrical resistance in a circuit determines the amount of current that in the circuit for a given voltage. • The more resistance the circuit has, the less current that flows.
Set the meter to measure resistance (W). Set the black and red leads on opposite ends of the objects. 19.3 Measuring resistance
Resistance is measured in ohms (W). One ohm is the resistance when a voltage of 1 volt is applied with a current of 1 amp. 19.3 The ohm
German physicist Georg Ohm experimented with circuits to find an exact mathematical relationship between voltage, current and resistance. Ohm's law can be used to predict any one of the three variable if given the other two. 19.3 Ohm's law
A light bulb with a resistance of 2 ohms is connected in a circuit that has a single 1.5-volt battery. Calculate the current that flows in the circuit. Assume the wires have zero resistance. 19.3 Calculate current
The resistance of electrical devices ranges from very small (0.001 Ω) to very large (10×106 Ω). Each device is designed with a resistance that allows the right amount of current to flow when connected to the voltage the device was designed for. 19.3 The resistance of electrical devices
The resistance of many materials, including those in light bulbs, increases as temperature increases. A graph of current versus voltage for a light bulb shows a curve. A device with constant resistance would show a straight line on this graph. 19.3 Changing resistance
19.3 Electrical Conductivity • The electrical conductivity describes a material’s ability to pass electric current.
A material such as copper is called a conductor because it can conduct, or carry, electric current. Materials that insulate against (or block) the flow of current are classified as electrical insulators. Some materials are neither conductors nor insulators. These materials are named semiconductors. 19.3 Conductors and insulators
Electrical components called resistors can be used to control current. Resistors have striped color codes to record their "values" (writing on them is difficult). 19.3 Resistors
Potentiometers are a type of "variable" resistor that can change from low to high. They are wired so that as you turn the knob, it changes the distance the current has to flow. 19.3 Potentiometers