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Types of solar cell
There are three main cell types that classified by its manufacturing
technology and the semiconductor.
- Two types of crystalline silicon solar cell are single
crystalline silicon solar cell, which is known as monocrystalline
silicon solar cell, made by slicing wafers and polycrystalline
silicon solar cell, made by sawing a block of silicon
first into bars and then wafers. The crystalline silicon
solar cell is very hard and thin.
- Amorphous silicon solar cell is the most well developed
of the thin film technology, which its thickness is 0.5
micron (0.0005 millimeter) and light weight with its efficiency
of 5-10%.
- Other semiconductors such as gallium arsenide, cadmium
telluride and copper indium diselenide, etc. have both
of single crystalline and of polycrystalline. The solar
cell which made by gallium arsenide is high efficiency
about 20-25%.
The solar cell structure
The most type of semiconductor currently in use is silicon
crystal, which is the inexpensive and most available semiconductor.
Because silicon crystals are laminated into p-type and n-type
region, it is used to make the solar cell. The silicon has
been smelt and purified until it becomes crystals. Then
doping atoms are to create a p-type and n-type region. P-type
doping, the creation of excess holes, is achieved by incorporating
and atoms with the boron and n-type doping, the creation
of excess electrons, is achieved by incorporating an atom
with the phosphorus. Once a p-n junction is created, electrical
contacts are made to the front and the back of the cell
by evaporation or screen printing metal onto the wafer.
The rear of the wafer can be completely covered by metal,
the front has a grid pattern or thin lines of metal and
the back has the metal, which block out the sun from the
silicon.
How solar cell works
When the sunlight strikes the solar cell surface, which
consists of two types of materials, p-type and n-type semiconductor,
and the cell creates charge carrier as electrons and holes.
The internal field produced by junction separates some of
the positive charges (holes) from the negative charges (electrons).
The holes are swept into the positive or p-layer and the
electrons are swept into the negative or n-layer. When a
circuit is made, the free electrons have to pass through
the load to recombine with the positive holes, current can
be produced from the cells under illumination.
| For example, |
a silicon solar cell, which its diameter is 4 inch
typically, produces from 2 to 3 amperes and approximately
0.6 volts. Because the output current of each cell
is very low, a number of cells are wired together
to make a module to reach the required current. And
these modules are wired into large arrays. The solar
arrays wiring depend on current and voltage requirement.
- If the solar arrays are wired in parallel, the
output current increases.
- If the solar arrays are wired in series, the output
voltage increases.
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Manufacture solar cells
- The single crystal or monocrystalline solar cell
has the process as below
- The melt silicon has been grown at 1400 °C then
drawn the crystal from the melted silicon by slowly
decreasing the temperature until become a large single
crystal ingot. The large single crystal ingots are sliced
into the single crystal wafers.
- The single crystal wafers were doping atoms to create
a p-type and n-type region and thereby producing a p-n
junction. This doping can be done by high temperature
diffusion (900-1000 °C), where the wafers are placed
in a furnace with the dopant to introduced as a vapour.
- The polycrystalline solar cell has the process
as below
- The molten silicon is poured into a mould and allowed
to set. Then it is sliced into the wafers.
- The polycrystalline wafers were doping to create a
p-type, n-type region and p-n junction same as the single
crystal solar cell process.
- The amorphous solar cell has the process as below
- The silane gas (SiH4) is reacted by Plasma
Chemical Vapor Deposition device. The amorphous silicon
is made by depositing silicon onto glass or another
substrate material from a reactive gas. The layer thickness
amounts to less than 1 micron (0.001 millimeter).
- When the silane gas reaction the dopants as phosphine
and diborane are included to create a p-type, n-type
region and p-n junction.
- The p-n junction is made up of translucent junction
as indium tin oxide.
- The gallium arsenide solar cell has the process
as below
- The gallium arsenide crystal has been grown by a
Liquid Phase Epitaxy furnace.
- The p-type and n-type region are created by Molecular
Beam Epitaxy device.
Main features of solar cell
- Use the natural power, sunlight, which is clean and
non-polluting
- Efficiently use a renewable power source and no limiting
- Able to be installed anywhere to produce and take direct
current
- Use no fuel other than sunlight
- No burning and therefore no air and water pollution
- Give off no waste and therefore harmless environment
- No moving parts so there is no mechanical noise being
operation
- Minimal maintenance requirement
- Long lifespan and stable efficiency
- Light weight, easy to install and transportable
- With the modular characteristic, it can be constructed
any sizes as required
- Reduce collection of gases such as carbon monoxide,
sulfur dioxide, hydrocarbon and nitrogen, etc., which
generated from fuel, coal and fossil fuel burning power
plants. All decrease the impacts of energy on the environment
like greenhouse effect, global warming, acid rain and
air pollution, etc.
Main components of solar system
The solar cells produce direct current, therefore they are
only compatible with the DC equipments. If users want to
use for AC equipments or store backup energy for other applications,
the solar systems require other components in addition to
the solar modules. These components are the followings.
- Solar Module is to convert sunlight into DC current
and usually stated in watt. If more than one solar module
is used, they are interconnected to produce the required
current, which called "solar array".
The solar arrays can be wired in series to increase the
voltage or in parallel to increase the current. The different
geographic locations receive the quantities of peak sun
hours per day, and as the temperature increase, the output
decrease.
- Charge controller is to regulate the current
from the solar arrays, charge the batteries and prevent
the batteries from overcharging. The function of charge
controller is to charge the batteries. When the batteries
are fully charged, the charge controller will stop or
decrease the charging. Most solar charge controllers also
include a Low Voltage Disconnect feature, which will disconnect
the power supply to the load when the battery voltage
drops too far. The solar system needs the charge controller
in case of the power storage in the batteries is necessary.
- Battery is to store current that produce from
the solar arrays for use during the sunlight is not visible,
nighttime or other purposes.
- Inverter is to convert the DC current that produce
from the solar arrays to AC current for operation AC equipments.
There are two types inverter, sine wave inverter
is compatible with all AC equipments, and modified
sine wave inverter is used with any electrical equipment,
which no has motor and florescent with electronic ballast
- The Lightning Protection is to prevent the electrical
equipment damages caused by lightning or induction of
high voltage surge. This component is required for the
large size and critical solar systems, which include the
efficient grounding.
The solar cell applications
The sun is the most attractive renewable power source and
more widely use. It can be applied to many purposes in everyday
life and environmental-friendly. For example,
| Residential homes |
Lighting systems, outdoor lighting systems (such
as garden lights, garage lights and fence lanterns,
etc.), electrical equipments, electric gate openers,
security systems, ventilators, water pumps, water
filters, and emergency lights, etc. |
| Water pumping |
Consumption, public utility, livestock watering,
agriculture, gardening and farming, mining and irrigation,
etc. |
| Lighting systems |
Bus stop lightings, telephone booth lightings, billboard
lightings, parking lot lightings, outdoor lightings
and street lightings, etc. |
| Battery charging systems |
Emergency power systems, Batteries charging centers
for rural villages and power supplies for household
use and lighting in remote area, etc. |
| Agriculture |
Water pumping and thrashing machines, etc. |
| Cattle |
Water pumping, Oxygen filling systems for fish-farming
and insect trapped lightings, etc. |
| Health centers |
Refrigerators and cool boxes for keeping medicines
and vaccines, and medical equipments, etc. |
| Communication |
Air navigational aids, air warning lights, lighthouses,
beacon navigation aids, illuminated road signs, road
signs, railway crossing signs, street lightings and
emergency telephones, etc. |
| Telecommunication |
Microwave repeater stations, telecommunication equipments,
portable communication equipments (such as communication
radio for service and military exercises, etc.) and
weather monitoring stations, etc. |
| Entertainment and recreation |
Power supplies for remote leisure homes, portable
battery charging systems and entertainment equipments,
etc. |
| Remote area |
Hills, islands, forests and remote areas that the
utility grids are not available, etc. |
| Space |
Satellites |
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The Basics of Solar Cell
