Tuesday, January 12, 2010

Work, Energy and Power

Justify FullWork:

A man pushing a car along a level road is said to be doing work. The amount of work done depends on the force exerted and the distance through which the force acts.

UNIT OF WORK: Since W = F x s, Unit of work = (unit of F) x (unit of s) = newton x metre (N m) = Joule

This unit is called the joule in honour of James Joule (1818—89) who did much early research in the area of work and the related of energy.

One Joule is the work done when a force of 1 Newton acts over a distance of 1 metre in the direction of the force: 1J = 1Nxm

Energy:

Energy is the ability to do work. The amount of energy something has is the amount of work it can do.

The unit of energy is the Joule.

Power:

A bulb in a desk lamp can convert electrical energy into heat and light at the rate of 40 joules per second; a bulb in a floodlight can convert electrical ener

gy into heat and light at the rate of 500 joules per second. The second bulb is more powerful than the first.

A builder brings 1000 blocks each of mass 20 kg from the ground, up a ladder, to the top of a house. It takes him 5 hours to do so. A crane lifts all the blocks

together from the ground to the top in a time of 10 seconds. Even though the man and the crane do the same work the crane does it

in a much shorter time. The cra

ne is much more powerful than the man.

Power is defined as the rate at which work is done. That is Power = Energy/time

UNIT OF POWER Since the U nit of Energy = joule and the Unit of time is the Second;

P = 1J / 1s

This unit is called the W

att (W) in honour of the English s

cientist James Watt.

DIFFERENT FORMS OF ENERGY

Since a body can do work for different reasons it can have energy for different reasons. It is useful to classify energy a ccording to the reasons that bodies have it.

KINETIC ENERGY: All moving objects have energy due to their motion. The energy a body has due to its motion is called kinetic energy.

POTENTIAL ENERGY: Potential energy is the energy a body

has due to its position in a force field.

In the picture shown on the right, a cyclist with Kinetic energy is moving up the hill and transforming the en

ergy into Potential energy

ELECTROMAGNETIC ENERGY: This i

s the energy transmitted from one point to another in the form of electromagnetic waves that travel at the speed of light. Example of a electromagnetic energy producer i

s a microwave.

INTERNAL ENERGY or heat energy: The molecules of every substance, whether solid, liquid or gas are in perpetual motion. If heat is supplied to a substance, the motion (the vibration) of its molecules increases as its temperature

rises. The kinetic energy of the molecules therefore increases. Thus heat is

a form of energy.

SOUND ENERGY: Any source of sound is always some object vibrating. As sound travels through a substance, the vibration from the source is passed on from molecule to molecule in that substance. Each molecule acquires energy in kinetic and potential form as the sound wave passes.

CHEMICAL ENERGY: The energy given out (or sometimes taken in) in the form of heat, light or kinetic energy during a chemical reaction is called chemical energy. For example, when something is burned, some of the chemical energy stored in it is changed into heat and light energy.

ELECTRICAL ENERGY When an electric current flows in a metal wire subatomic particles called electrons move in the wire. As they move, they lose energy called electric potential energy. This potential energy appears as

heat and other forms of energy in the wire.

NUCLEAR ENERGY The energy given out from the nuclei of certain atoms during nuclear reactions (fission or f

usion for example) is called nuclear energy

. This energy is used practically in the nuclear reactor

THE PRINCIPLE OF THE CONSERVATION OF ENERGY

Energy cannot be created or destroyed but can only be transferred from one body to another or changed from one for m to another. In every chemical or physical reaction, there is no net gain or loss of energy; any loss is always accompanied by an equal gain.

RENEWAB

LE AND NON-RENEWABLE SOURCES OF ENERGY

Every day we use energy for many purposes, e.g. transport and heating. The sources of this energy are many, e.g. oil, coal and hydroelectricity.

Sources of energy are classified as renewable or non-renewable. Examples of renewable energy sources are wind energy and solar energy, hydroelectric energy, wave energy and biomass. Non-renewable s

ources include oil, coal, peat and natural gas.

Energy is said to be renewable if the source of the energy is still there after energy is taken from it, and non-renewable if the source of the energy is gone after energy is taken from it.

Renewable energy sources will not run out. A problem with renewable energy sources is generating enough reliable energy to meet all our requirements. A lot of research is being done to find practical ways of using these ‘altemative

’ sources for the future.

Non-renewable ener

gy sources are fossil fuels, oil, gas, coal, peat or nuclear. They are usually easier to get energy from and store, but have a bigger environmental impact.

Energy pl

ant.

We need electrical energy to run all our appliances at home. We know that energy is everywhere around us, but how can we get it? There are several ways to transform energy into electrical energy. Energy plants have all these components to produce energy. Let's see a very simple one.

HYDROELECTRIC ENERGY

The store water behind an enormous dam flows through the intake and into a pipe called a penstock. The intake remains closed when no energy is asked for, for example, at night, as everybody is in bed. The water pushes against blades (the arms of the rotary mechanism), causing them to turn. The turbine spins and its shaft is connected to a generator that changes the mechanical spinning energy into electrical energy ( electricity ).

Advantage: Water power is reasonably easy to store ( in a reservoir ). Renewable energy.

Disadvantages: A lot of water is needed

P = V x I

If we want to transfer high power from the electric plant to the town where it can be used, we need high Voltage and Current ( Amps )values.

Remember that Amps mean electrons moving through conductors which, because of their collisions with atoms, produce heat.

The cables of transmission lines are made of aluminium ( cheaper ) or copper ( more expansive )


because they have a low resistance. So the higher the current, the higher the energy lost in the wires.

It is not good. All this work just to warm the bird's foot.

By the way, do you know how birds can sit safely on electric power lines?.

The answer is simple. Because the bird only touches one line, so electrons flow through the path of least resistance, the wire, and not its body.

So, the trick is to reduce the Current and increase the voltage. There is an electrical device that does just this. Its name is the transformer.

Electrical transformers are widely used to "transform" voltage from a lower voltage to a higher voltage or vice versa ( normally in appliances ). The principle of magnetic induction between coils makes it possible.

A transformer basically consists of a ferromagnetic core and two coils called "windings".

A changing current in the primary winding generates an alternating magnetic field in the ferromagnetic material.

The alternating magnetic field "goes and comes back" through the magnetic core ( the green line).

There is a relationship between voltage and electric field, so if a voltage is applied in the primary winding with 10 turns it generates a Magnetic field of value X , the same magnetic field generates a voltage in the secondary winding.

The voltage in the Secondary winding will be the same if N2 = 10

The voltage will be less if the secondary winding has less turns than the primary winding

In general, the simple formula that relates both voltages is:

V1 X N1 = V2 X N2

Example: If the output voltage in an alternator is 20000 volts and we want 200000 for the transmission lines, in a transformer with 100 turns in its primary winding:

20.000 X 100 = 20000 X N2 .....N2 = 2.000.000 / 20.000 = 1000 turns.

As Power is a constant, the current in the secondary winding will be less.

Now, everything is ready for the electricity to travels long distances to a substation. Substations are situated near factories and homes. Here transformers do their work in a inversely. I mean, they change the very high voltage electricity back into lower voltage electricity. In this case, the secondary winding will have less turns than the Primary Winding.

The next image illustrates the different elements of a transmission power system.

1º Step, The power plant, in this case a Hydroelectric plant.2º The transmission substation where the transformer increases the voltage 3º High voltage transmission, using long thick cables made of copper or aluminium with voltages from 200.000 v to 400.000 v4º The power substation, which will decrease the voltage from 400.000 to 20.000 5º Power poles take electricity to the Transformer Drum and from this element to homes with tension of 220 v

floodlight: light that is a source of artificial illumination having a broad beam; used in photography.

Crane: a device for lifting and moving heavy weights in suspension.

Blade: the arm of a propeller or other similar rotary mechanism, such as an electric fan or turbine.

shaft: a rotating, straight bar for transmitting motion, usually supported on bearings and carrying gears, wheels, such as a propeller shaft on a ship

Core: The piece of iron, or other ferrous material forming the central portion in an transformer .

Solar power. How to use the sun's energy


What are Electrical Transformers?



Electrical transformers are used to transform electrical energy. How electrical transformers do so is by altering voltage, generally from high to low. Voltage is simply the measurement of electrons, how many or how strong, in the flow. Electricity can then be transported more easily and efficiently over long distances.

While power line electrical transformers are commonly recognized, there are other various types and sizes as well. They range from huge, multi-ton units like those at power plants, to intermediate, such as the type used on electric poles, and others can be quite small. Those used in equipment or appliances in your home or place of business are smaller electrical transformers and there are also tiny ones used in items like microphones and other electronics.

Probably the most common and perhaps the most necessary use of various electrical transformers is the transportation of electricity from power plants to homes and businesses. Because power often has to travel long distances, it is transformed first into a more manageable state. It is then transformed again and again, or “stepped down,” repeatedly as it gets closer to its destination.

When the power leaves the plant, it is usually of high voltage. When it reaches the substation the voltage is lowered. When it reaches a smaller transformer, the type found on top of electric poles, it is stepped down again. It is a continuous process, which repeats until the power is at a usable level.

You have likely seen the type of electrical transformers that sit on top of electric poles. These, like most electrical transformers, contain coils or “windings” that are wrapped around a core. The power travels through the coils. The more coils, the higher the voltage. On the other hand, fewer coils mean lower voltage.

Electrical transformers have changed industry. Electric power distribution is now more efficient than ever. Transformers have made it possible to transfer power near and far, in a timely, efficient, and more economical manner. Since many people do not wish to live in close proximity to a power plant, there is the added benefit of making it possible for homes and businesses that are quite a distance from power plants to obtain dependable, affordable electricity. Much of the electricity used today will have passed through many electrical transformers before it reaches users.

Electrical transformers are used to "transform" voltage from one level to another, usually from a higher voltage to a lower voltage. They do this by applying the principle of magnetic induction between coils to convert voltage and/or current levels.







Electrical transformers are used to "transform" voltage from one level to another, usually from a higher voltage to a lower voltage. They do this by applying the principle of magnetic induction between coils to convert voltage and/or current levels.

Electrical transformers can be configured as either a single-phase or a three-phase configuration. There are several important specifications to specify when searching for electrical transformers. These include: maximum secondary voltage rating, maximum secondary current rating, maximum power rating, and output type. An electrical transformer may provide more than one secondary voltage value. The Rated Power is the sum of the VA (Volts x Amps) for all of the secondary windings. Output choices include AC or DC. For Alternating Current waveform output, voltage the values are typically given in RMS values. Consult manufacturer for waveform options. For direct current secondary voltage output, consult manufacturer for type of rectification.

Cores can be constructed as either a toroidal or laminated. Toroidal units typically have copper wire wrapped around a cylindrical core so the magnetic flux, which occurs within the coil, doesn't leak out, the coil efficiency is good, and the magnetic flux has little influence on other components. Laminated refers to the laminated-steel cores. These steel laminations are insulated with a nonconducting material, such as varnish, and then formed into a core that reduce electrical losses. There are many types. These include autotransformer, control, current, distribution, general-purpose, instrument, isolation, potential (voltage), power, step-up, and step-down. Mountings include chassis mount, dish or disk mount, enclosure or free standing, h frame, and PCB mount.