How electricity is generated Reviews Exercises

5.10 How electricity is generated Reviews Exercises


1. Define the term “generator."
2. State the three major parts of a direct current generator.
3. With the aid of a sketch, explain how e.m.f. is induced in a direct current generator.
4. Explain how a simple direct current generator may be improved for greater e.m.f. induction.
5. Define the term ''piezoelectricity."
6. With the aid of sketches, explain how thermocouples may be used to produce a higher voltage.
7. Explain how solar cells produce electricity.
8. List three applications of solar cells in everyday life.
9. State two uses of geothermal energy.

How electricity is generated Key points

5.9 How electricity is generated Key points


1. A D.C. generator produces a unidirectional voltage and current.
2. The three major parts of a D.C. generator are stator, rotor and commutator.
3. The direction of the induced e.m.f. in straight conductor is determined by the Right-Hand Rule.
4. The direction of the induced e.m.f. in coil conductor or solenoid is determined by the Right-Hand Grip Rule.
5. Electrical energy may be generated by ways other than magnetism and chemical action.
6. A piece of electric crystal can generate electricity when subjected to a changing pressure across two of its sides (compressed or released).
7. A steady pressure applied to a piece of electric crystal will not generate electricity.
8. The most frequently used piezoelectric crystals are quartz, Rochelle salt and barium titanate.
9. Electricity is produced whenever there is a relative motion between two materials such as a glass rod and silk. This is called static electricity. We can simply say that electricity is produced by friction.
10. Radiant energy is another source of electricity:
a. a photovoltaic cell converts light energy into electricity,
b. all photovoltaic cells are composed of two layers of dissimilar semi-conductor materials.
11. When a light ray strikes the junction between the two layers of a photovoltaic cell, electrons are forced across it.
12. Modern solar cells are made of silicon and germanium semi-conductor material.
13. Geothermal energy is heat energy produced within the Earth.
14. Geothermal power is renewable and environmentally friendly.

What is geothermal power

5.8 What is geothermal power

Geothermal energy is heat energy produced within the Earth.

This form of energy is formed in two ways:
(a) When the earth was originally created (very small fraction of about 20 %)
(b) When radioactive elements disintegrate within the earth crust (about 80 %)

Even though the geothermal may occur deep within the earth crust, heat conduction can take place up to the earth’s surface or should there be liquids like water on the way, these may easily signify the earth’s internal heat existence in terms of geysers (hot springs) or vapours.   If the temperatures are high, as much 4000  0C, internal elements may melt and float on their parent solid elements.  Water on the other hand, is superheated to high as 370 0C.  .  The heat energy so produced is used heat water at the heat exchanger.  This has kinetic energy that is in turn directed to spin turbine.  The turbine converts kinetic energy to electrical energy.  A part from electrical energy supply, heat from geothermal can also be regulated for heating in homes.

Geothermal power is renewable and environmentally friendly.  The number of users has incredibly increased due to advancement in technology, however it suffers from limitation of its location and dear cost of construction of power plants.

It is believed theoretically, geothermal power if highly exploited, will eventually lower the impact the global warming.

The reliability of geothermal power has enabled this form of energy to be injected into the national grid to boost national power distribution.

Photovoltaics

5.7 Photovoltaics

A photovoltaic or solar cell consists of a rectangular or round piece of metal covered with a thin, transparent layer of oxide as shown in Fig. 5.7.1 The light rays striking the oxide layer penetrates this layer and then the junction between the oxide and the copper. The light rays force the electrons to flow across the junction, and so generating electricity.


When the light rays are interrupted, the e.m.f. generated by them disappears at the same instant. A photovoltaic cell made of copper and copper oxide is very inefficient. Modern solar cells are made of silicon which is a semi-conductor. These are more effective than those made of copper, Fig. 5.7.2.


Photovoltaics are used in a wide variety of modern electrical and electronic devices. A few applications are:
(a) Spacecraft power supplies.
(b) Light meters.
(c) Automatic-operated switches.
(d) Burglar alarms.
(e) Cellphone chargers.
(f) Home lighting.

Although photovoltaics depend on light for their operation, exposure to heat may damage them.

What is a thermocouple

5.6 What is a thermocouple

If the junction of two dissimilar metals is heated, the heat energy forces the free electrons of one metal into the other, thus generating an e.m.f., see fig 5.6.1.  This e.m.f. produced depends on two factors:
a) The type of metal used in forming the junction.
b) The temperature difference between the hot and the cold junctions.
A single pair of junctions (cold and hot) produces very little electrical energy.  The pair is what forms the thermocouple.

thermocouple_junction

To produce measurable electricity from thermocouples, individual thermocouples are sequentially arranged to form a thermopile.  During usage all the hot junctions are collectively placed close the area or substance whose temperature is being determined whereas the cold junctions are collectively placed within the fixed cold temperature.  This means that the cold junction is a reference or control temperature.  A simple hot and cold junctions’ circuit is shown in Fig. 5.6.2 for clarity.
Thermocouple_circuit


Typical applications of thermocouples are: flame detectors, furnace controls and heat detectors.

Static electricity

5.5 Static electricity

This is a mechanical method of producing electricity by friction.
When a plastic rod is rubbed with a cat's fur or a glass rod is rubbed with silk, electric charges are produced on the rods and on the materials they are rubbed with. While most of the mechanical energy used in the charging process is transformed into heat, a small amount is converted to electric energy.

electricity_by_friction
Electricity by friction


Electricity generated by friction is often undesired and from time to time can be dangerous to human beings and equipment. In printing shops, newspaper plants, static electricity is generated by friction and can give severe shocks unless special measures are made to conduct these charges to the ground. In nature, static electricity is produced when clouds move through the atmosphere and is known to cause a lot of damage to houses and trees by setting them on fire. Lightning is a form of static electricity and is known to have killed human beings and animals and damaged vegetation since time immemorial.

Piezoelectricity

5.4 Piezoelectricity

Electricity can be generated by exerting pressure on a crystal. A special kind of substance, the piezo electric crystal, converts mechanical energy into electric energy when pressure is exerted on it. Once a piezo electric crystal that is connected to a neon lamp is struck with a mallet, the neon lamp will emit a brief flash of light. A small portion of the mechanical energy is converted into electricity. Most of the energy is again transformed into heat. Fig. 5.4.1 illustrates the set-up.
Piezoelectricity_crystal


Piezo is a Greek word for pressure. Piezo electric crystals are made of such compounds as quartz, Rochelle salt, tour-maline and barium titanate. Usually the opposite sides of the crystal are silver plated and thin, flexible copper leads soldered to the plated area. When a steady pressure is applied, no electric energy is generated. The voltage produced by piezo electric crystal is very small and cannot be measured by a voltmeter. It requires to be amplified.

Piezo electric crystals are used in record players and microphones. The piezo electric crystal in the cartridge of the pickup arm is vibrated by the record groove. These vibrations produce varying degrees of pressure on the piezo electric crystal which in turn produces varying electrical signals. These are then amplified in order to operate the speaker. Piezo electric crystals are also used to deduce pressure changes in industries and production of spark in gas lighters e.g. cigarette lighter.

Lenz's law

5.3 Lenz's law

Lenz’s law deals with the direction of induced e.m.f. in a conductor.  To find out this, it good to know in which direction current will flow using a cell as show below.
direction_of_induced_emf_cell


A coil of known direction of wiring is shown below. In turn, if we plunge each pole of a magnet into and out of the coil; and we get the results shown figures 5.3.1b, 5.3.1c, 5.3.1d and 5.3.1e.

direction_of_induced_emf_in_a_coil_N_in


direction_of_induced_emf_in_a_coil_S_in

direction_of_induced_emf_in_a_coil_S_out

The above is generalized by Lenz’s law which states that the direction of the induced e.m.f. is such that it opposes the change causing it.  Approach by plugging N pole the end of the coil opposes it with the same pole and vice versa.
The direction of the flow in the coil can predicted by Right Hand Grip Rule.  This is done by gripping the coil with the thumb pointing N-pole and is perpendicular the fingers.  The fingers indicate the flow induced current.
On the other hand should it be a straight conductor be considered, fig. 5.3.1f, then employ the Right Hand (Dynamo) Rule which merely calls for taking the thumb, first finger and second finger being aligned to make right angles to each other as in fig. 5.3.1g and elaborated in fig. 5.3.1h.

Fleming's_right_hand_rule_cube


From the above laws, it will be evident that we need two basic components in order to generate an e.m.f. i.e.
a) a magnetic field,
b) a moving conductor.

A magnetic field can be produced in two ways:
a) By permanent bar magnets.
b) By electromagnets.
A more practical d.c. generator consists of a commutator connected to both ends of the conductor, as illustrated as a simple generator in Fig 5.3.1i. The purpose of a commutator is to change the direction of the current or voltage induced in the conductor. This always makes the meter to deflect in one direction and we can say the generator produces a d.c. induced e.m.f.
simple_dc_generator


When the conductor is horizontal or parallel to the flux, no e.m.f. is induced. When it is moved in a clockwise direction, the B side of the conductor moves upwards and the A side downwards. Using the Right-Hand Rule, it can be shown that the e.m.f. generated is in the same direction. When the conductors change positions, the split rings (commutators) also change positions and, therefore, the current in the external circuit does not change direction.
Hence the d.c. induced e.m.f. is only in one direction in the external circuit. This is how all d.c. generators function.
In a practical d.c. generator, there are many conductors forming many loops. Both ends of the conductors are soldered to the commutator segments. A commutator can be thought of as many slip rings mounted together, see Fig 5.3.1j.
The permanent bars of magnets are replaced by electromagnets in a practical generator. These improvements of the generator increase the d.c. e.m.f. induced.

practical_d.c._generator



A practical d.c. generator machine consists of three parts; namely:

A stator

This is the non-rotating part and can be made of permanent magnets or electromagnets.

A rotor

Is the rotating part of the machine and consists of loops of wire (insulated from each other) connected to the commutator segments.

A commutator

Is the part which converts the e.m.f. generated in a direct current and direct voltage (unidirectional). It consists of the commutator segments which are connected to the various loops of wire in the rotor. The brushes attached to the commutator send the generated e.m.f. to the external circuits.

Lenz’s law deals with the direction of induced e.m.f. in a conductor.  It states that the direction of the induced e.m.f. is such that it opposes the change causing it.
To determine the direction of the induced e.m.f. for conductor cutting magnetic flux, the following general rules apply:
for a straight conductor, use Right Hand (Dynamo) Rule (Fig 5.3.1g and Fig 5.3.1h), and
for a coil conductor use Right Hand grip Rule (Fig 5.3.1e)
Three major parts of a dc generator are stator, rotor and commutator.
Commutator can also be called split ring or current reverser.

Conditions for induced emf in a conductor

5.2 Conditions for induced e.m.f. in a conductor

This can only take place in the conductor when
1. there is relative motion between conductor (coil) and magnet (fig. 5.2.1b and fig 5.2.1c)
2. magnetic field lines are being cut by the conductor
3. cutting of the field lines must be perpendicularly to get maximum effect
4. the direction of e.m.f. depends on the direction of relative motion between conductor and direction of magnetic field lines (approach, fig. 5.2.1b and retreat, fig 5.2.1c)

Conditions_for_induced_e.m.f._in_a_conductor
Conditions for induced e.m.f. in a conductor


Summarizing, relative motion is needed between a magnet and a coil to produce induced e.m.f.s.  The induced e.m.f. increases when the relative velocity increases and when a soft iron core is used inside the coil.  The soft iron core concentrates magnetic field lines.





How electricity is generated

5 How electricity is generated

5.1 Direct Current Generator

A generator is a machine that converts mechanical energy into electrical energy. A direct current generator, thus, converts mechanical energy into electrical energy. It produces two electrical components:
(a) Direct voltage.
(b) Direct current.
A direct voltage is that which does not reverse direction. It can be represented by a continuous line above a certain point (reference point). This direct voltage is either positive or negative.

dc generator voltage vs reference point
dc generator voltage vs reference point


A direct voltage can be steady if is constant with respect to time or it may be term unsteady if it fluctuates with respect to time as shown below:
dc voltage vs time
dc voltage vs time


All the above voltages are direct voltage because they are all positive with respect to y=0 axis when drawn from the origin.
Like the direct voltage, direct current is also represented similarly as shown below.
dc generator current vs reference point
dc generator current vs reference point



Steady and unsteady current is represented below:
dc voltage vs time
dc voltage vs time