Electricity and Magnetism

38
Electricity and Magnetism 1 Static electricity 2 Electric Circuits and Electric Current 3 Ohm’s Law and Resistance 4 Series and Parallel Circuits 5 Electric Energy and Power 6 Alternating currents and Household Current 7 Electromagnetic Induction

description

Electricity and Magnetism. 1Static electricity 2Electric Circuits and Electric Current 3 Ohm’s Law and Resistance 4 Series and Parallel Circuits Electric Energy and Power Alternating currents and Household Current Electromagnetic Induction. Lightning. Atomic Particle. Charge. Mass. - PowerPoint PPT Presentation

Transcript of Electricity and Magnetism

Page 1: Electricity and Magnetism

Electricity and Magnetism

1 Static electricity

2 Electric Circuits and Electric Current

3 Ohm’s Law and Resistance

4 Series and Parallel Circuits

5 Electric Energy and Power

6 Alternating currents and Household Current

7 Electromagnetic Induction

Page 2: Electricity and Magnetism

Lightning

Page 3: Electricity and Magnetism

Atom

Atomic Particle Charge Mass

Electron –1.6 10-19 C 9.11 10-31 Kg

Proton +1.6 10-19 C 1.673 10-27 Kg

Neutron 0 1.675 10-27 Kg

Page 4: Electricity and Magnetism

Charging Ebonite Rod & Fur

Page 5: Electricity and Magnetism

Charging an Object

Ebonite rod & Fur Negatively charged ebonite rod

Glass rod & Silk Positively charged glass rod

Page 6: Electricity and Magnetism

LAW OF CONSERVATION OF ELECTRIC CHARGE

During any process, the net electric charge of an isolated system remains constant (is conserved).

Page 7: Electricity and Magnetism

Like charges repel and unlike charges attract each other.

Page 8: Electricity and Magnetism

Conductors and Insulators

Substances that readily conduct electric charge are called electrical conductors. Conductors have free electrons, which conduct the electricity.

Examples: Metals such as copper, aluminum, silver, and gold.

Materials that conduct electric charge poorly are known as electrical insulators.

Examples: Rubber, plastics, and wood.

Page 9: Electricity and Magnetism

Charging by Contact and by Induction

An object can be charged by two methods:

-By contact.

-By induction.

Page 10: Electricity and Magnetism

Charging By Contact

Page 11: Electricity and Magnetism

Charging By Induction

Page 12: Electricity and Magnetism

How to Get the Bulb to Light?

Page 13: Electricity and Magnetism

How to Get the Bulb to Light?

Page 14: Electricity and Magnetism

Electric Current

The electric current is the amount of charge per unit time that passes through a surface that is perpendicular to the motion of the charges.

The SI unit of electric current is the ampere (A), after the French mathematician André Ampére (1775-1836). 1 A = 1 C/s. Ampere is a large unit for current. In practice milliampere (mA) and microampere (μA) are used.

.t

qI

Page 15: Electricity and Magnetism

Direction of Current Flow

Electric current is a flow of electrons. In a circuit, electrons actually flow through the metal wires.

Conventional electric current is defined using the flow of positive charges.

It is customary to use a conventional current I in the opposite direction to the electron flow.

Page 16: Electricity and Magnetism

Direction of Current Flow

Page 17: Electricity and Magnetism

What Limits the Flow of Current?

Page 18: Electricity and Magnetism

What Limits the Flow of Current?A: Resistance

Page 19: Electricity and Magnetism

Electric Current Is Analogous to Water Flow

Page 20: Electricity and Magnetism

Ohm’s LawGeorg Simon Ohm (1787-1854), a German physicist, discovered Ohm’s law in 1826.

This is an experimental law, valid for both alternating current (ac) and direct current (dc) circuits.

When you pass an electric current (I) through a resistance (R) there will be a potential difference or voltage (V) created across the resistance.

Ohm’s law gives a relationship between the voltage (V), current (I), and resistance (R) as follows:

V = I R

Page 21: Electricity and Magnetism

What Is the Current?

Page 22: Electricity and Magnetism

Electromotive Force (emf)

The energy needed to run electrical devices comes from batteries.

Within a battery, a chemical reaction occurs that transfers electrons from one terminal (leaving it positively charged) to another terminal (leaving it negatively charged).

Because of the positive and negative charges on the battery terminals, an electric potential difference exists between them. The maximum potential difference is called the electromotive force* (emf) of the battery.

The electric potential difference is also known as the voltage, V.

The SI unit for voltage is the volt, after Alessandro Volta (1745-1827) who invented the electric battery. 1 volt = 1 J/C.

Page 23: Electricity and Magnetism

Circuits

Page 24: Electricity and Magnetism

Series Circuit

Page 25: Electricity and Magnetism

Parallel Circuit

Page 26: Electricity and Magnetism

Electrical Energy

Page 27: Electricity and Magnetism

Electrical Energy and Power

Our daily life depends on electrical energy. We use many electrical devices that transform electrical energy into other forms of energy. For example, a light bulb transforms electrical energy into light and heat. Electrical devices have various power requirements. Electrical power, P is defined as the electrical energy transfer per unit time,

.time

EnergyP

Page 28: Electricity and Magnetism

Electric Power:.

time

EnergyP

Since the electrical energy is charge times voltage (QV), the above equation becomes,

.t

QVP

Since the current is charge flow per unit time (Q/t), the above equation becomes,

.VIVt

Q

t

QVP

Since V = IR, the above equation can also be written as,

.2

2

R

VRIIVP

Page 29: Electricity and Magnetism

Killowatt-hour (kWh)

The SI unit of power is watt, after James Watt (1736-1819), who developed steam engines.

Utility companies use the unit kilowatt-hour to measure the electrical energy used by customers. One kilowatt-hour, kWh is the energy consumed for one hour at a power rate of 1 kW.

.sec s

J

ond

jouleWwatt

Page 30: Electricity and Magnetism

Exercises

1. State Ohm’s law in an equation form in terms of voltage and current.

2. Define power in an equation form in terms of voltage and current.

3. When an appliance is plugged in a 120-volt outlet, it draws a current of 8 amperes. Calculate the power of the appliance.

4. If the above appliance is used 10 hours a day for 28 days per month, and if the cost of electricity is 12 cents per kilowatt‑hour, how much does it cost to operate the appliance for a year?

Page 31: Electricity and Magnetism

Electrical Power Transmission

Page 32: Electricity and Magnetism

AC adapter

                      

INPUT: AC 120 V, 60 Hz, 15 W

OUTPUT: DC 9V, 1A

Page 33: Electricity and Magnetism

Alternating Current

Page 34: Electricity and Magnetism

Alternating Voltage

Effective voltage = 115 V

Page 35: Electricity and Magnetism

Household Circuits

Page 36: Electricity and Magnetism

Power and Current Ratings of some common Appliances

Appliance Power (W) Current (A)

Stove 6000 (220V) 27

Clothes dryer 5400 (220V) 25

Water heater 4500 (220V) 20

Clothes washer 1200 10

Dishwasher 1200 10

Iron 1100 9

Coffeemaker 1000 8

TV 100 0.8

Page 37: Electricity and Magnetism

Faraday's Law of Electromagnetic Induction

Michael Faraday found experimentally that the magnitude of the induced emf is proportional to the rate at which the magnetic flux changed. Faraday’s law can be written as,

.; ABt

N

where N is the number of turns in the loops, A is the area of one loop, ξ is the induced emf, and B┴ is the perpendicular component of the magnetic field.

Page 38: Electricity and Magnetism

Lenz’s Law

.; ABt

N

The SI unit for the induced emf is the volt, V. The minus sign in the above Faraday’s law of induction is due to the fact that the induced emf will always oppose the change. It is also known as the Lenz’s law and it is stated as follows,

The current from the induced emf will produce a magnetic field, which will always oppose the original change in the magnetic flux.