Thursday, 25 August 2016
Chapter 4 ̶ Solar Energy
Chapter
4 ̶ Solar Energy
Solar
energy is the largest available energy on earth. The life on the earth is due
to Sun, directly or indirectly. All the plants make their food through
photo-synthesis in presence of Sunlight. In turn this food is eaten by humans
and animals. For harnessing solar energy effectively and efficiently various
methods have been proposed. In the following these methods will be discussed.
Solar energy may be harnessed in terms of heat, warm water, electricity etc.
About half of the energy in the world is utilized as heat. Heat is required in
industry for chemical processes and in residential sector for heating the space
and as warm water.
4.1 Solar Ponds
Solar
pond contains water or any other liquid, which absorbs solar radiation to heat
the water/liquid present in the pond. The thermal energy stored in the pond in
this manner is exchanged with heat exchanger to transfer heat energy to other
place for specific application. This thermal energy can be used for heating the
space and building, in industries for specific reaction or for electricity
production. The pond may be natural or artificial. The size of the pond ranges
from few hundred sq metre to few thousand sq metre, depending on the
requirement and application. The temperature of water/liquid rises in the pond
after absorbing solar radiation. Due to convection currents and conduction
process this heat reaches at the surface of pond. From there heat losses
through evaporation by the surface. To prevent the thermal energy and thus to
store heat inside the solar pond special mechanism is adopted. On this basis it
can be broadly divided into two category; Convective solar ponds and
non-convective solar ponds.
4.1.1
Convective Solar Ponds
This
is a normal pond containing water/liquid of homogeneous density. The surface is
covered with transparent sheet to prevent the loss of heat through evaporation.
The depth of such a pond is not large. It is a shallow pond with depth of 4 to
15 cm.
4.1.2
Non-Convective Solar Ponds
These
are further divided into two category; Salt-gradient solar ponds and Viscosity
stabilised solar ponds.
4.1.2.1
Salt-Gradient Solar Ponds
In this pond,
salt is dissolved in water, such that it divides the layers of ponds in three
different zones. The density of salt water increases with depth. The upper zone
is the layer of fresh water. Middle zone maintains the salt-gradient. The
lowest layers form storage zone, which has saturated salt concentration. When
solar radiation is absorbed, the temperature of water increases. As the density
of water layer with high temperature is less, it rises up due to convection
currents. In absence of salt gradient,
this heat goes to the surface, and is lost because of evaporation. In the salt̶
gradient solar pond, the density of hot water is decreased, but it is still
higher than the layer above it due to presence of salt. In storage zone the
molecules are so heavy because of saturated solution that they cannot move in
upward direction. Hence the heat is preserved in the storage zone. The
temperature may rise up to 90° C to 100°C in the storage zone. As one moves
towards the surface the temperature is decreased. If the surface is covered with transparent
sheet, it will further prevent the heat loss and maintain the high temperature
in solar pond. However, some of the heat losses due to conduction and salt&gradient is
disturbed in the pond. To maintain the salt&gradient,
salt is added and fresh water is replaced at the upper layer. Common salts
which are utilised in the solar pond is sodium chloride (NaCl) and magnesium chloride (MgCl2). Additional
alternatives are potassium chloride (KCl), Calcium chloride (CaCl2),
Ammonium nitrate (NH4NO3), Potassium nitrate (KNO3),
Borax (Na2B4O7) and Sodium sulphate (Na2SO4),
which are widely available from the waste product of flue gases produced from
coal-fired power plants.
4.1.2.2
Viscosity&stabilised
Solar Ponds
In this method
instead of salt, gel is mixed with water in an amount which can prevent
precipitation. It is not much common.
4.1.3
Factors affecting the performance of solar pond
· Wind
free condition: Climate must be wind free to prevent the
heat loss from evaporation.
· Dust
free atmosphere: Dust dissolved in water will stop the
solar radiation to penetrate into the
depth of pond.
· Water
clarity: Water of the pond must be free from external
particles and algae.
· Ground
water level: Water level must be deep, so that heat
cannot loss from the ground of storage zone.
· High
solar radiation: The intensity of solar radiation must be
high.
· Replacement
of fresh water: There must be another nearby pond where
the water can be replaced to maintain the salt&gradient
and fresh water can be added to the top layer.
· Application
Site: The site of application should be close to solar
pond.
4.1.4
Removal of heat from the solar pond
This is done by
heat exchanger. Heat may be exchanged through submerged
heat exchanger and the brine withdrawal method.
4.1.4.1
Submerged Heat Exchanger
In this method a pipe containing liquid
(internal heat exchanger) is inserted inside the storage zone. The liquid in
the pipe becomes hot due to high temperature of storage zone. Then this hot
liquid is transferred to another place of application, where it is again
submerged in the water or liquid (external heat exchanger) which has to be heated.
4.1.4.2
Brine Withdrawal Method
In this method hot brine (salt water) is
pumped directly from the storage zone by using
an extraction diffuser. The heat from the brine is extracted and the brine is
then returned to the bottom of the pond by using a return diffuser. This method
of heat exchange is considered more effective than the submerged heat
exchanger. For better efficiency and to maintain salt&gradient the
suction diffuser is placed just below the salt&gradient
zone. The return stream is injected on opposite side of extraction diffuser and
at the bottom of storage zone.
4.2
Solar Water Heater
In solar water heater,
there is a collector of black painted metal, on which metal pipes containing
fluid is attached. Solar radiation is absorbed by collector and metal pipes.
Heat is also transferred from collector to the metal pipe. The whole assembly is
covered with glass to minimize the heat loss from the system. The fluid present
in the pipes get heated. This heat is exchanged in heat exchanger, where the
pipe containing the hot fluid is submerged in tank containing another liquid at
low temperature. In this way heat is exchanged from solar collector to the
application point. In the solar water heater, there are three parts; collector,
heat exchanger and storage tank of hot water/liquid. Amount of hot water supply
depends on the size of collector array, the fluid used in the pipe and
intensity of solar radiation. The temperature may be reached up to 100°C.
4.2.1
Type of solar water heater
When the fluid used in
the collector is same as the fluid for utility, it is known as direct or open
loop. If the fluid in application is different from the fluid used in collector
and heat exchanger is used, it is called indirect or close loop.
The solar water heater
may also be categorized in a different way. If no pump is used for
transportation of heat, it is called passive system. Heat is transferred
through natural convection method. When pump is used for circulation of hot
fluid, it is known as active method. In passive method flow rate is low and in
active method flow rate can be maintained at better rate.
4.2.2
Types of collectors
Collector may be of
three varieties; covered, uncovered and vacuum. If the temperature difference
between collector and surrounding is more, the transparent cover is necessary
to stop heat loss to the surrounding. However, transparent covered collector
receives less radiation in comparison to uncovered collector due to reflection
loss. Vacuum covering stops the heat loss but is expensive. It depends on the
application that which type of collector is required. Vacuum collector may provide
high temperature.
Collectors may be flat
plate type or concentrating. In flat plate collector solar radiation is
absorbed directly from the sun. In concentrating system, an optical device is
placed in between the sun and collector, which concentrate the solar radiation
on the collector. In this method size of collector is small, so heat loss is
also less. High temperature is achieved in comparison to flat plate collector.
Sun tracking system is necessary in concentrating collector, which increases
the cost of the system.
4.2.3
Array of collectors
Collectors may further
be attached with each other in an array. This array may be parallel or series.
In parallel array collector, the input and output temperature of each collector
is same. In series array, the output of first collector is the input for
second. Therefore in series array high temperature may be achieved. The
combination of both parallel and series may also be used. The choice of array
depends on the application and the requirement of temperature.
4.3
Solar Distillation
Solar distillation is a
system to get fresh distilled water from salty water (brine). For this a
shallow basin is constructed with black inner surface and covered with sloping
air-tight plastic or glass sheet. The basin is filled with brine. The solar radiation
heats the water to evaporate and the vapours condense on the slope and get
collected in a storage tank.
4.4
Solar Cooker
Solar cookers are the
devices, in which foods are cooked by the heat of solar radiation. In solar
cookers foods are kept in pots and pots receive sunlight, such that the
temperature of the food increases and it is cooked without the supply of any
extra heat. On the basis of the construction of solar cooker it is categorized
in three varieties.
4.4.1
Solar Box Cookers
These are the simplest
type of solar cookers. There are two boxes, one of diminished size from
another. Smaller box is placed inside and the gap between the two is filled
with insulating material. Outer box may be of insulating material like wood, so
that heat can be retained inside the box. Black paint may be applied on the
inner side to absorb more heat. The box is covered with transparent glass or
plastic. It will insure the minimum loss of heat from the cooker. A reflector
of aluminium may be attached to it to concentrate the solar radiation on the
pot containing the food. In box type solar cooker, temperature may rise up to
140°C.
4.4.2
Panel Type of Solar Cookers
In this type of solar
cookers, four panels are used and the black painted pot containing the food is
placed at the center. The food pot is kept inside heat resistant plastic bag or
glass bowl. The panels are covered with reflecting sheets like aluminum. Thus
panels reflect the sun rays on the food and increase the temperature of the
food. This is not a very good system as it is open and may not work during wind
blowing season.
4.4.3
Parabolic solar Cookers
In this system a
reflector of parabolic shape is used and food vessel is kept at the focal
point. The shape of the reflector must be very precise so that it can
concentrate the solar radiation at the food. The larger the panel, the more
heat it will absorb. In this type of solar cooker temperature of 200°C to 300°C
may be reached. It is the fastest cooking solar cooker. It is suitable for
baking, roasting and grilling.
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4.5
Solar Greenhouse
Generally greenhouses
are built to maintain the climate inside the greenhouse to grow vegetables. The
atmosphere outside the greenhouse may not be suitable for a particular type of
vegetables. Therefore an artificial climate is produced inside the greenhouse
for growing a specific vegetable or any other plant. In an ordinary or
conventional greenhouse a frame is created on the ground which is covered with
plastic sheet. It traps the solar heat and does not allow it to escape. There is arrangement of air ventilation inside
the greenhouse. Temperature is maintained artificially inside the greenhouse.
Although conventional
greenhouses are inexpensive, they are not safe in extreme weather condition
like, snow, wind, intense sun and frost
zone. Hence another design is required to overcome the difficult weather
conditions. The best option is specifically designed solar greenhouses. Solar
Greenhouse is based on following principles:
1.
Orientation
of greenhouse should be in such a direction that it can collect most of the solar
heat.
2.
The
incident solar radiation might be stored as heat inside the greenhouse.
3.
Insulation
should be done from all other areas.
4.
There
should be minimum heat loss through leakage.
5.
There
should be mechanism of maximizing the natural ventilation.
4.5.1 Orintation
The
direction of greenhouse is such that, the axis of roof is in east-west
direction. Both side of roof, north and south face solar radiation. South roof
receives many times more radiation than north roof. Roof and covering sheet may
be of any material given below:
·
Glass
(regular or tempered)
·
Polyethylene
sheeting (single or double layer)
·
Acrylic
·
Polycarbonate
(single, double, triple wall)
·
Fiberglass
4.5.2 Heat Storage
For
heat storage inside the greenhouse, dark non-reflective water tanks and soil is
used. Heat is stored in shallow soil depth and in deep soil depth. Thus
the heat is stored when sun is shining and it is emitted when sun is not
shining in the night. For
active solar heating systems, solar liquid collectors, fan convectors and solar air collectors
may be used.
4.5.3 Insulation
Walls,
floor and foundation must be insulated. North, east and west walls should be
well insulated. Insulating curtains may also
be used. Greenhouse is sealed to prevent air infiltration.
4.6 Solar Air-conditioning and Refrigeration
Solar
energy can also be used for cooling space inside the building i.e.,
air-conditioning and for refrigeration purposes. There are three modes of solar
cooling.
4.6.1
Evaporative Cooling
It
is a passive cooling system and used in hot and dry climate. Its principle is
that when hot air is used to evaporate water, the air itself becomes cool. Thus
it cools the space inside the building.
4.6.2 Absorption
cooling system
This
system has four parts:
i.
Generator- The generator contains a solution
mixture of absorbent and refrigerant. Suitable mixtures are (i) NH3-H2O,
where NH3 is the working fluid and (ii) LiBr-H2O, where H2O
is working fluid. This mixture in the generator is heated with solar energy
derived from flat plate collector. Because of this heat, refrigerant vapour is
boiled-off at a high pressure and flows into condenser.
ii.
Condenser-
In condenser
the refrigerant
vapours condense rejecting heat and becomes liquid at high pressure. After
this, refrigerant liquid passes through expansion valve and goes into
evaporator.
iii.
Evaporator- This refrigerant liquid
evaporates in evaporator and cools the space.
iv.
Absorber-
This low pressure
vapour of refrigerant goes
into absorber where it is absorbed in the solution mixture taken from
generator, in which refrigerant concentration is low. This solution rich in
refrigerant concentration is pumped back into generator.
4.6.3 Passive desiccant cooling
This method is used in
warm and humid climate. The moisture is removed from room air using absorbent
or adsorbent. After this, evaporation technique is used to cool the space.
4.7
Solar Cell (Solar Photovoltaic System)
In active solar system, solar energy can
be utilized by three methods;
·
PV system- When solar radiation is
converted directly into electrical energy.
·
Thermal solar system- In this method
solar radiation is first converted into heat. This heat can be directly used
for heating purposes or thermal energy can be further changed into electricity.
·
Solar fuels- In this system solar energy
are converted into chemical energy.
The
term photovoltaic consists of the greek word phos, which means light, and
-volt, which refers to electricity and is a reverence to the Italian physicist
Alessandro Volta (1745-1827) who invented the battery. Solar cells use p-n junction semiconductor materials to
produce photovoltaic effect. Typical efficiencies of the most commercial solar modules
are in the range of 15-20%.
4.7.1
The Working Principle of a Solar Cell
Generation
of potential difference at the junction of two different materials in response
to absorption of electromagnetic radiation (solar radiation/ photon) is known
as photovoltaic effect. This effect is closely related to the photo electric
effect, in which electrons are emitted by a surface after absorbing photons. The
energy of such a photon is given by E = hn, where h is Planck’s constant and n is the frequency of the photon.
For photoelectric effect, Einstein received the Nobel Prize in Physics in 1921.
The photovoltaic effect consists
of three basic processes:
1. Creation of charge
carriers due to the absorption of photons in the materials that form a
junction.
When photon of energy higher than band gap is incident on the
semiconductor p-n junction, electron from valence band goes into conduction
band, leaving behind a hole. Thus an electron hole pair of opposite charges is
created in the material. If the maximum of valence band and minimum of
conduction band is at the same k-value (wave vector), the excitation is done
without changing crystal momentum (ђk). This semiconductor is called direct
band gap material. If there is change in crystal momentum during excitation, it
is known as in-direct semiconductor. The
absorption coefficient in a
direct band gap material is much higher than in an indirect band gap material, thus the absorber can be much thinner.
In this way the radiative energy of the
photon is converted to the chemical energy of the electron-hole pair. The
maximal conversion efficiency
from radiative energy to chemical energy
is limited by thermodynamics. This thermodynamic limit lies in between 67% for
non-concentrated sunlight and 86% for fully concentrated sunlight.
2. Subsequent separation of
charge carriers created due to absorption of photons at the junction.
After
production of electron-hole pair, they usually recombine i.e. electron goes to
its initial energy level and energy is emitted in the form of electromagnetic
radiation (photon) or transferred to
other electrons or holes or to the lattice as non-radiative emission of energy.
Hence it is required to separate electrons and holes before they could
recombine with each other. This is done by creating junction of n and p type
semiconductors.
3. Collection of the electrons
and holes at the terminals of the junction.
When electrons and holes
reach at their respective terminals, they are extracted from the solar cell
into external circuit to perform electrical work. Electrons flow in external
circuit and on reaching at another terminal recombines with holes. Thus,
finally the chemical energy of electron-hole pair is converted in electrical
energy.
4.7.2 Solar
Cell Parameters
Performance
of solar cells are depicted by parameters like, the peak power Pmax, the
short-circuit current density Jsc, the open-circuit voltage Voc, and the fill
factor FF. These parameters are determined from the illuminated J-V
characteristic. The conversion efficiency η can be determined from these
parameters.
The
short-circuit current Isc is the current that flows through the external
circuit when the electrodes of the solar cell are short circuited. The
short-circuit current of a solar cell depends on the photon flux density
incident on the solar cell, which is determined by the spectrum of the incident
light The Isc depends on the area of the solar cell. In order to remove the
dependence of the solar cell area on Isc, often the short-circuit current
density is used to describe the maximum current delivered by a solar cell. In
laboratory c-Si solar cells the measured Jsc is above 42 mA/cm2,
while commercial solar cell has a Jsc exceeding 35 mA/cm2.
When no current flows through the external circuit, the voltage is
measured as Open-circuit voltage. It is the maximum voltage
that a solar cell can deliver. Voc is a measure
of the amount of recombination in the device. Laboratory crystalline silicon
solar cells have a Voc of up to 720 mV, while commercial solar cells typically
have Voc exceeding 600 mV.
The fill factor (FF) is the ratio between the maximum power (Pmax
= JmpVmp) generated by a solar cell and the product of Voc with Jsc. FF =(JmpVmp/JscVoc).
For a silicon laboratory device and a typical commercial solar cell FF is about
0.85 and 0.83, respectively. However, the variation in maximum FF can be
significant for solar cells made from different materials. For example, a GaAs
solar cell may have a FF approaching 0.89.
The conversion efficiency is
calculated as the ratio between the maximal generated power and the incident power.
η = Pmax/Pin = Jmp Vmp/Pin = Jsc Voc FF/Pin
Typical external parameters of a
crystalline silicon solar cell are; Jsc » 35 mA/cm2,
Voc up to 0.65 V and FF in the range 0.75 to 0.80. The conversion efficiency lies
in the range of 17 to 18%.
4.7.3 The equivalent circuit
of Solar Cell
The J-V characteristic of an
illuminated solar cell that
behaves as the ideal diode
is given by Eq. (8.27),
J (Va) = Jrec
(Va) &Jgen (Va)& Jph
= J0 [exp(eVa/kT)&1]&Jph
Where,
Va = applied
voltage
Jrec =
recombination current density
Jgen = thermal generated current density
Jph = photo
generated current density
This behaviour can be
described by a simple equivalent
circuit, in which a diode and
a current source are connected in parallel. The diode is formed by a p-n
junction.
Equivalent
circuit of an (a) ideal solar cell and a (b) solar cell with a series
resistance Rs and a
shunt resistance Rp.
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4.7.4 Loss mechanism in solar cell
Loss in the efficiency of
solar cell is due to following reasons:
1. Loss due to non-absorption of long
wavelengths,
2. Loss due to
thermalisation of the excess energy of photons,
3. Loss due to
the total reflection,
4. Loss by incomplete absorption due to
the finite
thickness,
5. Loss due to recombination,
6. Loss by metal electrode coverage,
shading losses,
7. Loss due to voltage factor,
8. Loss due to fill factor.
4.7.5 Design Rules for Solar Cells
For
better efficiency three factors may be taken into account.
1.
Utilisation of the band gap energy,
2.
Spectral utilisation,
3.
Light trapping.
4.7.6 Classifications of Solar Cell
Solar cells can be classified on the basis of :
i.
Cell size
ii.
Thickness of active material
iii.
Type of junction structure
iv.
Type of active material
4.7.7 Components of a Solar PV System
A single solar cell can produce only 0.1 to 3 watt of power and 0.5
to 0.55 volt of voltage. Actually for practical purposes more power and more
voltage are needed. Therefore many solar cells are connected in series or
parallel to give required output for the specific applications. In such a
manner solar PV module is prepared.
Generally 36 solar cells are connected in series to give 12 volts. PV modules
prepared in this way are further arranged in series or parallel to form an array to give more output. When modules
are connected in series, voltage is increased and if connected in parallel,
current is increased. This is done according to the requirement for specific
application.
Solar panels are the main
part of a PV system, but few other components are also required according to
the applications.
· Mounting structure- A mounting structure is needed to fix the panel and to direct it
towards solar radiation.
· Energy storage- Battery is required to store the solar energy to assure that it
can deliver the energy in night and bad weather condition also, when no solar
radiation is present.
· DC Converters- It is used to convert the panel output to a fixed voltage, as the actual voltage may have
fluctuations due to weather condition.
· DC-AC converters
(Inverters)- It is required to convert DC
electricity produced by solar PV system to AC electricity to feed the output
voltage of solar panel to the electricity
grid.
· Cables- Cables are used to connect different components of the system.
· Load- Loads are not the direct part of the system, but they affect very
much the design of the whole system.
4.7.8 Types of PV systems
PV systems may be very simple or may contain many components, depending
on the required applications. It can be divided into three categories:
4.7.8.1
Stand alone system- This system
gain power only by solar PV system itself. Hence the whole system contains only
solar panel and load. It may also contain a battery for energy storage. Charge
regulators are used to prevent batteries from over-charging and over-discharging.
4.7.8.2
Grid-connected systems- In this
system the whole DC electricity produced by solar panels are converted to AC
electricity and it is fed to electricity grid to supply electricity in houses.
In this system storage batteries are not required as the whole power is
transferred to the grid. For this purpose, solar parks are established, where a
large number of solar panels are mounted to produce large amount of
electricity.
4.7.8.3
Hybrid system- This system
contains solar panels for producing electricity and a complementary method of
electricity generation, like diesel, gas or wind generator.
4.8 Sun Tracking
Systems
Solar panels are used in remote areas to get
electricity. For best efficiency, solar panels must get maximum solar radiation
at all the time. For this purpose, special sensors are attached with solar
panels, which track the direction of sun and accordingly rotate the panel in
the direction of sun. In a typical sun tracking system, following components
are attached.
· Computer hardware and software
· Sun Tracking Sensors (STS)
· Night Time
Fault Detector (NTFD)
· Day Time
Fault Detector (DTFD)
· Night and
Cloud Detection
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