Transcript
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Always Focus Your Attention At The Center of The Solar System
Where The Sun , The Supreme Power of The Universe , Resides .
INTRODUCTION
Multipurpose Distillation it is an instrument which is made up for
Distillation water. Which is made of using metallic body we are using the fiberglass thus, it can be used as a roof. Because of fiber glass body we get lighteniry
effect.
Looking to words scarcity of electricity it saves electricity & also
save cost of manufacturing a roof.
And make possible of use sea water for producing a distilled water.
1
Water Vapor
Fiber Glass
Water
Condensed water in the
form of Droplet
Distilled water
Collector
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AIM
It is a phenomena of solar energy by which getting a distilled water
& save the electricity with the help of fiber glass.
WORKING PRINCIPLE
Dropwise Condensation
In dropwise condensation, vapour condenses on the surface in the
form of drops, and consequently a large part of cooling surface is always bare to
vapour for undergoing consideration. ( Fig.) The rate of heat transfer is many
times larger than what is achieved in firm condensation. Dropwise condensation
occurs on a nonwettable cooling surface where the liquid condensate drops do not
spread.
Let us explain briefly what is wettable or a nonwettable surface. The
surface of liquid always tends towards a minimum. A freely suspended drop of
liquid always takes the shape of sphere which is of the geometrical shape having
the minimum surface area for the same volume. This is due to the effect of
surface tension. Surface tension always exists whenever there is a discontinuity in
2
Liquid condensatedrops
Bare surface
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the material medium. Mercury in contact with air has a certain surface tension.
With water, mercury has another surface tension. Let us consider the equilibrium
of a liquid drop on a solid surface ( Fig. ) being the surface tension as shown.
Fig. : Equilibrium of a liquid drop on a solid surface
If 1 cos + 3 = 2, the liquid iron drop remains in equilibrium
and does not spread. The surface is nonwettable ( e.g. mercury in glass )
2 - 3cos 1 = = - cos
1
2 - 3cos = = where is the angle of contact.
1
If ( 1 cos + 3 ) > 2, the liquid drop spreads and the surface is wettable
( e.g. water in glass ). When is obtuse, he surface is nonwettable, and if is
acute, the surface is wettable.
Dropwise condensation is much desirable because of its higher heat
transfer rates. However, it hardly occurs on a cooling surface. When the surface
is coated with some promoter like mercaptan, oleic acid and so on, drop
3
Liquid Drop
1
1
2
3Solid
Air
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condensation can occur for some time. But the effectiveness of the promoter
gradually decays due to fouling, oxidation or its slow removal by the flow of the
condensate. Condensers are usually designed on the basis that film condensation
would prevail.
Greenhouse Effect
Glass transmits over 90 % of radiation in the visible range and is
almost opaque to infrared wavelengths ( > 3 m ). Thus, glass allows the
solar radiation to enter, but does not allow infrared radiation from the interiorsurfaces to exit. This causes a rise in the interior temperature, with heat thus being
trapped. This heating effect due to the nongray characteristic of glass or clear
plastics is known as the greenhouse effect. (Fig.)
Fig. : Greenhouse which traps energy by allowing the solar radiation to come
in, but not allowing the infrared radiation to go out.
The greenhouse effect is also experienced on a larger scale on earth.
The surface of the earth, which warms up during the day as a result of the
absorption of solar energy, cools down at night by radiating its energy into deep
space as infrared radiation. The gases CO2 and H2O vapour in the atmosphere
4
Solar Radiation
Greenhouse
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transmit the bulk of the solar radiation during the day, but absorb infrared
radiation emitted by the surfaces to the earth at night. Thus, the energy trapped on
earth by the atmosphere causes global warming, and drastic changes in whether
conditions.
Absorptivity, Reflectivity And Transmissivity
Matter can emit, absorb, reflect and transmit radiant energy. If Q is
the total radiant energy incident upon the surface of a body, some part of it ( Q A)
will be absorbed, some part ( QR) reflected and some part ( QTr ) transmitted
through the body ( Fig. ). By energy balance,
QA + QR + QTr + = Q
QA + QR + QTr
or, = 1
Q Q Q
+ + = 1
Where is the fraction of incident radiation which is absorbed, called
absorptiviti, is the fraction which is reflected, called reflectivity, and is the fraction
which is transmitted through the body, called transmissivity or transmittance.
A body is said to be opaque if = 0 and + = 1. Most solids
do not transmit any radiation and are opaque. If is reduced, increases. The
reflectivity depends on the character of the surface. Therefore, the absorptivity of
an opaque body can be increased or decreased by appropriate surface treatment.
When the surface is highly polished, the angle of incidence 1 is
equal to the angle of reflection r , and the reflection is said to be specular. When
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the surface is rough, the incident radiation is distributed in all directions, and the
reflection is said to be diffuse. ( Fig. )
Most gases have high value of and low values of and . Air
at atmospheric pressure and temperature is transparent to thermal radiation for
which = 1 and = = 0. Gases like CO2 and H2O vapour are highly
absorptive at certain ranges of wavelengths.
Fig : Radiant incident on a surface
6
QA Absorbedradiation
QTr
Transmittedradiation
QRQ
Incident radiation Reflected radiation
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Fig. : Types of reflection a surface; (a) actual or irregular (b) diffuse and
(c) specular or mirror
7
Incident
rays
Normal
Reflected
rays
( a )
Incidentrays
Normal
Reflected
rays
( b )
Incidentrays
Normal
Reflected
rays
( c )
i r
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Power Density
The insolation is the power incident on a unit area of surface. Near
equatorial regions the radiant power density is about 1.4 kW/m2 on a horizontal
surface at noon. This quantity varies with time of day and with latitude in two
time cycles : the day ( 8.64 x 104 sec. ) and the year ( 3.15 x 107 sec. ). At the
higher latitudes, the lower thermal input results in a colder climate. At any time,
solar power is attenuated by the atmosphere and its components molecular gases,
clouds, and dust. The fraction absorbed or reflected by the atmosphere depends on
meteorological, geological ( e.g., volcanoes ), and geometric aspects. The
geometric factors result in variations in the solar power over time and location as
shown in Fig.
An important aspect of solar power is that a large surface area is
required to collect amounts of it which compare to that currently provided by
fossil fuels. Consider each persons continuous need for 1-10 kW the range of
which depends on economic status from Third World inhabitant to industrial man.
The atmosphere absorbs on average 30 % of the solar power ( this fractiondepends strongly on the local climate ), which is available only about 35 % of the
time ( the rest of the time is twilight and night ), and can be collected for present
or later use with an efficiency of say 10 %. These considerations alone dictate
that, on a per capita basis, the surface area requirement of the order of 30-300 m2
( 300-3000 ft2). This area requirement is significantly larger than that required for
food production alone. Setting aside the question of cost for this area, it is
doubtful that is would even be available where it is needed: in or near cities and
towns. If one takes the view that solar energy is to be used for supplying all of the
needs of US inhabitants ( 200-300 million ), then the land area required is about
one entire large western state. The environmental impact is certainly severe. Even
if such power-gathering systems were distributed throughout the land, it would be
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difficult to have a place where it would not have at least a visual impact. The
ocean surface has been suggested for such a purpose. If such numbers are applied
to western Europe or some regions of Asia, where the population density is large,
the difficulty of replacing present fossil fuel exploitation with solar power
becomes apparent.
Fig : Variation of solar energy incident on the surface of the Earth as a
function of time of year for three latitudes.
9
10
0
Jan Mar May Jul Sep Nov
Solarpower
kWhours
perday Equator = 0
0
400
800
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It can also give cooling effect into factory because some of the heat
is absorbed by water and fiber glass sheet rest of the heat is reflected thus it gives
cooling effect to the area coming under the aforesaid instrument.
You know that the precision machinery viz. CNC machine &
computer system are kept in totally packed controlled room as there is a need of
Air-conditioned system to make temperature at about 250C & humidity 50 %.
Thus if we use this instrument as a roof then it will automatically save electricity
in the form of light source. And some electricity use for Air conditioning .
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1
Time
9.00 am to 12.00 am
Time
12.00 am to 3.00 pm
Time
3.00 pm to 6.00 pm
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Distilled Water Calculation
Approximately it require, one electric tube of 40 watt for 12 X 12 sq.
ft. room. And the consumption of electric current for 9 am to 6 am as below.
40 w X 9 hrs = 360 Watts hr / day
for 30 days of month
360 X 30 = 10800 watts hr / month
for 1 year of 10 months
10800 X 10 = 1,08,000 watts hr / yrs.
For 1000 watts hr there is an charge Rs. 4 /- in an average, which differs in
use.
108000 / 1000 = 108 units
The electric current save in rupees are
108 X 4 = Rs. 412 / - for one room only.
Water Distilled from Distillator Per Month.
If you take a room of 12 X 12 Sq. ft.
Then it will be in meter is 3.65 X 3.65 = 13.2 m 2
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Behind every 1 m2 area 3 liter distilled water / day of 9 hrs between it will
produced.
13.2 X 3 = 39.96 liter / day
40 liter / day.
For one months 40 X 30 = 1,200 liters.
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USE OF FIBERGLASS
Fiberglass Production
The production of glass fibers starts with dry mixing of silica sand
and limestone, boric acid and a number of other products such as clay, coal and
fluorspar. These materials are melted in a high-refractory furnace, the
temperature of the melt being dependent on the glass composition, but s generally
about 12600 ( 23000 ). The molten glass then flows directly to the fiber-drawing
furnace in a direct melt flow process or into a marble making machine. These
marbles can be sorted and can eventually be remelted and drawn into fibers.
Continuous glass fibers are produced when molten glass from the
fiber-drawing furnace is gravity fed through numerous tiny openings in a platinum
alloy tank called a bushings. The droplets of molten glass that extrude from each
of the bushings openings are gathered together, mechanically attenuated to the
correct dimensions, passed through a water spray and over a revolving belt that
applies a protective and lubricating coating known as a size or binder. The fibers
are then gathered together in a suitably shaped shoe to form a bundle called a
strand which is wound onto a core at approximately 190 / km / h ( 120 mile / h ).
This package of fibers is then dried or conditioned prior to further processing and
eventually sold as a continuous filament yarn.
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Staple fibers are produced by passing a jet of air across the openings
at the base of the bushing, which pulls individual fibers of approximately
20 40 cm ( 8-15 in ) long from the molten glass that is extruding from each
opening. These filaments are collected on a collected on a rotating vacuum drum,
sprayed with size and gathered into a strand. This package of filaments is again
conditioned or dried prior to processing into a specific product for further use.
Each individual fiber is drawn from the bushing opening and must
be controlled so that responducible filaments, strand dimensions and properties are
obtained. This control is achieved by the regulation of the melt viscosity,
temperature and drawing speed. It is possible, therefore, to obtain a large number
of filament diameters by varying the number of openings in the bushing and the
drawing conditions.
As demand has dictated over the years, the fiberglass industry has
established a number of standard filament diameters.
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Glass Composition
Glass is generally defined as an amorphous material, being neither
solid or liquid. Chemically glass is made up of elements such as silicon, boron
and phosphorus that are converted into glass when combined with oxygen, sulfur,
tellurium and selenium. The molecular arrangement is conducive to formation
of an intricate three-dimensional network of oxygen tetrahedral with a silicon
atom in the middle, bonded to each oxygen atom. Silicon by itself requires
extremely high temperatures for liquefaction. Therefore, other elements are added
to the mix to reduce temperatures and to produce a viscosity in the molten glass
that will allow easy drawing.
A number of glass compositions are available depending on the
properties desired from the resulting fibers.
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FIBER GLASS COMPOSITION ( wt. %)
ComponentsA
( high alkali )
Grade of glass
C
( chemical )
E
( electrical )
S
( high strengt
Silicon oxide
Aluminum oxide
Ferrous oxide
Calcium oxide
Magnesium oxide
Sodium oxide
Potassium oxide
Boron oxide
Barium oxide
Miscellaneous
72.0
0.6
-
10.0
2.5
14.2
-
-
-
0.7
64.6
4.1
-
13.2
3.3
7.7
1.7
4.7
0.9
-
54.3
15.2
-
17.2
4.7
0.6
-
8.0
-
-
64.2
24.8
0.21
0.01
10.27
0.27
-
0.01
0.2
-
Types of Fiberglass
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1) A-glass : A high alkali or soda glass is made into fibers for use in
application where good chemical resistance is needed.
2) E-glass : A low alkali glass, based on aluminum borosilicate. This glass
possesses excellent electrical insulation properties and is the premium fiber
used in the majority of textile fiberglass production.
3) C-glass : A material based on soda borosilicate that produces a fiber that
offers excellent chemical resistance.
4) S-2 glass : This glass is made up of magnesium, aluminum silicate and
offers higher physical strength. Fibers produced from this glass have an
approximate forty percent tensile strength improvement over those of E-
glass composition.
5) D-glass : This fiber made from a low dielectric composition has dielectric
loss properties ( dielectric constant of 3.8 at 1 mc s-1 ) superior to that of E-
glass ( 6.0 at 1 mc s-1 ).
6) R-glass : A special glass composition that produces fiber that is alkali
resistant and is used in reinforcing concrete.
7) Low K : An experimental fiber produced to improve dielectric loss
properties in electrical applications ( similar in performance to D-glass ).
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8) Hollow fiber : Special glass whose fibers are tube-like or hollow; the
material has specific applications in reinforced aircraft parts where weight
could be significant.
9) Te glass : A Japanese manufactured S-glass, for higher strength structural
application.
A - Glass fiber for acid resistance.
C - Glass fiber for improved acid resistance.
D - Glass fiber for electronics applications.
E - Glass fiber for electrical insulation.
S - Glass fiber for high strength.
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Fiberglass Properties
1) High tensile strength : Fiberglass has an exception ally high tensile
strength compared with other textile fibers. Its strength to weight
ratio exceeds steel wire in some applications.
2) Heat and fire resistance : Because fiberglass is inorganic it does
not burn or support combustion.
3) Chemical resistance : fiberglass has excellent resistance to most
chemicals and is impervious to fungal, bacterial or insect attack.
4) Moisture resistance : Because fiberglass does not absorb water, it
neither swells, stretches nor disintegrates. Fiberglass does not
readily rot and continues to maintain its mechanical strength in
humid environments.
5) Thermal properties : Due to its low coefficient of thermal linear
expansion and high coefficient of thermal conductivity, fiberglass
exhibits excellent performance in thermal environments.
6) Electrical properties : Fiberglass being nonconductive is an ideal
choice for electrical insulation, where designers can make use of the
high dielectric strength and low dielectric loss properties.
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Application of Fiber Glass
Depends on strength & stiffness
1) Aircrafts surfaces wing, flaps elevators.
2) Helicopter blades & Aircraft doors.
3) Racing car bodies.
Based on thermal properties.
1) Heat shields for missiles & rockets.
2) Aircrafts breaks.
3) Aerospace antennas.
4) Space telescope platforms.
Based on chemical properties
1) Storage tank.
2) Nuclear industries.
Depending on rigidity & good dumping
1) Musical instrument, audio speaker.
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Glass and glass ceramic composites are classic examples for use to
1) Replace super alloys in gas turbines and jet engines, and in other
high temperature or high wear situations such as compressors.
2) Replace metals in gas and diesel engines as well as in shafts, seals
and business for motors and engines of all types.
3) Develop a new breed of components for chemical processing
systems.
4) Resides consumer products from lawnmowers to cook wares.
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SCARCITY OF CONVENTIONAL ENERGY SOURCES
The need for Alternatives
Based on the preceding survey, it will now be possible to make some
observations and draw some conclusions for the world as a whole.
Fossil Fuels :-
1. The production of oil appears to have touched a maximum
around 1980 and is now slowly declining. On the other hand, the
production of natural gas is still increasing. Present indications are
that most of the reserves of oil and natural gas are likely to be
consumed in another 50 years.
2. As oil and natural gas become scarcer, a greater emphasis will
fall on coal. It is likely that the production of coal will touch a
maximum some where between the years 2030 and 2060 and that 80
percent of the amount available could be consumed by 2250 AD.
3. It should also be noted that in addition to supplying energy,
fossil fuels are used extensively as feedstock material for the
manufacture of organic chemicals. As reserves deplete, the need for
using fossil fuels exclusively for such purposes may become greater.
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Water Power :-
There is considerable scope for increasing the capacity of water
power all over the world. Water power is indirectly obtained from solar energy
and has the advantage of being a renewable source of energy.
Nuclear Power :-
The position regarding uranium is serious if we continue to use it as
at present in burner rectors.
It is thus fairly evident that a need exists for developing alternative
energy sources. The immediate need would be to alleviate the problems caused by
the depletion of oil and natural gas, while the long term need would be to develop
means to replace presently used nuclear fusion technology and then coal. These
conclusions are applicable for India also.
The primary sources of alternative energy which hold potential for
the future can be broadly classified under four categories. These are
1. The solar option.
2. The nuclear option.
3. Tar sands and oil shale.
4. Miscellaneous sources.
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Work is in progress in many parts of the world on all these
alternatives.
In the remaining part of this chapter, we shall briefly describe the
various energy alternatives. It is hoped that these descriptions will help the reader
to acquire a broad perspective of the energy problem, before we focus our
attention from the next chapter on wards on the solar energy option and more
specifically direct thermal methods for utilizing solar energy.
The Solar Option :-
Solar energy is a very large, inexhaustible source of energy. The
power from the sun intercepted by the earth is approximately 1.8 X 10 MV,
which is many thousand of times larger than the present consumption rate on the
earth of all commercial energy could supply all the present and future energy
needs of the most promising of the unconventional energy sources.
In addition to its size, solar energy has two other factors in its favor.
Firstly, unlike fossil facts and nuclear power, it is an environmentally clean source
of energy. Secondly, it is free and available in adequate quantities in almost all
parts of the world where people live.
However, there are many problems associated with its use. The
main problem is that it is a dilute source of energy. Even in the hottest regions on
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earth, the solar radiation flux available rarely exceeds 1 kwh / m2 and the total
radiation over a day is at best about 7 kwh / m
2
. These are low values from the
point of view of technological utilization . consequently, large collecting areas are
required in many applications and those result in excessive costs.
A second problem associated with the use of solar energy is that its
availability varies widely with time. The variation in availability occurs daily
because of the day-night cycle and also seasonally because of the earths orbit
around the sun. in addition, variations occur at a specific location because of
local weather conditions. Consequently, the energy collected when the sun is
shining must be shored for use during periods when it is not available. The need
for storage also adds significantly to the cost of any system. Thus, the real
challenge in utilizing solar energy as an energy alterative is of an economic nature
methods of collection and storage so that the large initial investments required at
present in most applications per reduced.
A broad classification of the various methods of solar energy
utilization is given in table. It can be seen that the energy from the sun can be
used directly and indirectly. The direct means include the use of water power.
The winds, biomass, wave energy and the temperature difference in the ocean.
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Classification of Methods of SolarEnergy Utilization
Direct Methods Indirect Methods
Thermal Photovolatic
Water Power Wind Wave Energy Oscan Temperatu
Difference
Biomass
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Radiation of sun rays :-
Based on measurement made up to 1910 a standard value of 1353
W/m2 was adopted in 1971 However based on subsequent measurements, a revised
values of 1367 W/m2 has been recommended.
The diameter of sun 1.39 X 106 km &
The diameter of earth 1.27 X 104 km
The mean distance between earth & sun is 1.49 X 108 km
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Annual Production of Energy In India :-
Energy Production from Commercial Energy sources in India year
1985.
Energy Source
Production /
Consumption
Energy Equivalent
( in 1015 J )
Percent
Contribution
Coal
Oil
Natural Gas
Water Power
Nuclear Power
157 mt
42 mt
4.688 X 10 9 m 3
58001 Gwh
4505 Gwh
3221
1758
183
246
65
58.85
32.12
3.34
4.49
1.19
Total 5475 100.00
HOW MULTIPURPOSE DISTILLATOR
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AN ECONOMICAL
1. The cost of shed / roof is totally removal. For 12 x 10 s.q. ft. room the cost
of slap is near about Rs. 10,000/- & for steel roof near about Rs. 2,000/- &
above. The cost multipurpose distillation roof is near about Rs. 18 20
thousand.
2. But :- it gives 40 litre /day & for one month it gives 1200 litre distilled
water in general the cost of distilled water is in bet Rs. 8 10 / litre. So we
save Rs. 96,00/-. Thus we replaced the manufacturing cost of multipurposeDistillation in next 2-3 month only.
The electricity utilized in artificial light source nearly Rs. 432 /- per year.
Which is totally saved by the this instrument.
APPLICATION OF DISTILLED WATER
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1) For making jewelry from gold.
2) For medicine use ( manufacturing ).
3) For chemical laboratory.
4) Battery charging & etc.
ADVANTAGES & DISADVANTAGES
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MULTIPURPOSE DISTILLATOR
Advantages
1) Life Long Use :-
As the fiber glass can not corrode or deformed in other shape because it
sustain at about 2000 C & no reaction with water or any other aquarium
particles. Also has good strength and it will withstand at 2000 C.
2) Low Maintenance :-
Only for cleaning the water impurities deposited in the term of scale are to
remove there will be some expense then after that there is no maintenance
expenditure.
3) Save Electricity :-
As we required light source in fully packed room currently we are using
electric tubes or bulbs. Thus we can use this instrument in day time then we
can save electricity. And you should know that the rate of electricity per
1000 watt / hr is increases day by day.
4) Use of Unconventional Energy Without Any Uneconomical
Investment :-
We know that the age of sun is more than the earth so the solar energy
source is life long source. And this instrument is not an costly as compared
to other electricity developer instrument.
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5) Distilled Water / Pure Water :-
The clouds are from sea water vapor and thus the rain water is pure water.
Hence we can use the Saline water or Hard water in this instrument for
Distilled water / pure water production. As you know that the water for
drinking on earth is only few percentage as compared to whole water on
earth.
6) Cooling Effect :-
The sun rays are firstly transferred from fiber glass & then to water so the
part percentage of solar heat is absorbed by the water and fiber glass
respectively. Thus, we feel cooling effect.
Disadvantages
1) For Indian climate preferable use for 8 to 9 months only ( Oct to May ).
2) High cost of manufacturing as
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i) Cost of fiber glass @ Rs. 50 / Sq ft.
ii) High labour charges.
iii) Precise or leaked proof production.
3) Un even source of solar energy it will effect on.
i) Production rate distilled water.
ii) Uneven light effect.
4) Dilute form of solar energy.
FUTURE DEVELOPMENT
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1. Manhole :- You will use this instrument in wide range then there is a need of
one man hole for cleaning purpose. After prolonged use of maltidistilatar. The
improves and the scales are form in the inner side a instrument which should
be clean per weak.
2. Blow off cock :- There is a need of blow off cock for taking out the muddy
particles and impurities. The blow off cock should be apply at evening, after
sun set.
CONCLUSION
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As in future the oil & natural gas will be consumed totally in coming
50 years. It is likely that the production of coal stock will likely to touch maximum
some where between the year 2030 and 2060.
Thus, the future need is to developed the sources of energy for
getting electricity or the replacing instrument.
Hence, this instrument Multipurpose Distillator will be the future
need. Although not for yet but for the future trend it will be an essential.
As it is always said :-
Need is the mother of invention .
REFERENCES
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1. Solar Energy.
By - S. P. Sukhatme.
2. Hand Book of Composition .
By - Peter.
3. Physics
By - Bhandarkar
4. Heat Transfer
By - P. K. Nag. Tata McGraw Hill Publishing
5. Energy Conversion
By - Reiner Decher Oxford University Press.
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