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1. Introduction
Health and social communities in developing countries are institutes that daily use large quantities of hot
water. When such communities are situated in areas that are hardly accessible, they mainly use wood fuel for
water heating. Because firewood supply becomes an ever-growing problem, it is sensible to look for an
alternative source of energy. Given the fact that solar radiation is present in abundance, it seems justified to
manufacture self-made hot water systems.
Manual and Videotape
This manual is based on experiences gained during many years of building solar powered hot water systems
in developing countries. It may be helpful in constructing solar collectors and building hot water systems
especially for communities using large quantities of hot water.
By means of existing technical facilities, a selected group of skilled technicians and locally available
materials, it is possible to produce zigzag collectors and to build up sustainable hot water systems. By using
clear explanations and many pictures we hope to be of service to those who are motivated to build a hot
water system all by themselves.
Since 1997 a videotape entitled “Heated by the sun” has been composed as an additional illustration of the
manual. It shows all activities as described in the manual. Therefore it is advisable to use the manual and
videotape jointly. The videotape can be acquired from the BACIBO-foundation.
1.1. Using solar energy
The pluriform influence of solar radiation on life on earth can be used for several purposes. Proven
applications for among other things generating electricity, water heating, cooking, and crop drying with solar
energy exist. Small amounts of electricity can be generated with so-called P.V.-systems (Photo-Voltaic).
These systems can be reliable energy providers for remote areas (in which sometimes hospitals and clinics
are situated). P.V.-systems are rather expensive. For maintenance and repair you need the manufacturers
assistance. P.V.-systems can be used for:
· Lighting;
· Cooling boxes for storing medicines and blood plasma;
· Radio communication and T.V.
For solar powered water-heating
technical appliances are rather
simple and much cheaper than
P.V.-systems. Institutions like
hospitals require a substantial
supply of hot water 24 hours a
day. Because the use of solar
radiation is limited to the daily
hours of sunshine, it is necessary
to construct a hot water system
that collects as much heat as
possible during the daytime and
preserves the collected heat as
much as possible after sunset. For
this reason a hot water system
has been figured out which is
named the thermo-syphon
system, or the system based on
natural circulation.
1.2. Parts of the solar water heater
The solar water heater consists of the following parts, see the figure;
1. The solar collector, in which water is heated by solar radiation.
2. An insulated storage tank, in which the heated water from the collector is stored. The storage tank must
be put higher than the top of the collector.
3. An insulated pipe connecting the lower part of the collector and the upper part of the storage tank.
4. An insulated pipe connecting the lower part of the storage tank and the bottom of the collector.
5. A cold water inlet connecting an existing water supply system to the storage tank. Usually the cold
water inlet runs via a buffer tank with a floating gauge.
6. An insulated hot water outlet running from the storage tank to the tap.
7. A vent (air escape pipe) to prevent overpressure, caused by air or steam.
1.3. Working principle of the solar hot water system
When solar radiation heats the collector, the water inside will be heated as well. The heated water starts
rising through the connection on top of the collector to the insulated storage tank. Heated water entering the
storage tank displaces cooler water that is in turn forced via the connection to the bottom of the collector. In
this way a circulation comes into being. We call it natural circulation or thermo-syphon principle. The cold
water -entering the collector- will be heated again by solar radiation. Because the water temperature inside
the collector becomes much higher than inside the storage tank, the natural circulation continues as long as
the sun heats the collector. Consequently, the water inside the storage tank will get hotter and hotter.
Depending on the amount of solar radiation and insulation, the system can produce water temperatures
between 40 and 70 degrees Celsius.
1.4. The use of hot water systems
If we want to use the hot water in the storage tank, we have to tap it. When hot water is tapped, the storage
tank must be refilled. Therefore the storage tank is connected via a buffer tank to an existing water supply
system (for instance a big rainwater tank or a borehole). The buffer tank is provided with a floating-gauge or
ball-valve. When tapping a bucket of hot water, the system will be refilled automatically via this floating
gauge.
The efficient use of a hot water system depends on the daily need. For various institutions like hospitals,
rehab centres, children homes etc. different quantities of hot water at different temperatures and for different
purposes are required. The efficiency of the hot water supply depends on the way in which it is organised
and controlled by the management of the concerning institute. The average heating up period per system per
day can be put at 6 hours. When a system is properly insulated, hot water can be drawn 24 hours a day. So
even at night hot water can be used. Practice has shown that solar powered hot water systems are especially
useful for laundries and washing patients. With optimal use of a solar powered hot water system, a saving of
up to 70% of the usual firewood consumption can be achieved.
2. Construction of the solar collectors
A solar collector consists of 4 parts:
1. The absorber
This is a dull-black painted metal body on which the zigzag
pipe containing the water is fixed. The black coating
absorbs almost all the solar radiation that falls on it. The
collected radiation is transformed into heat and
simultaneously heats the water inside. Temperatures of 100
ºC or more can be reached.
2. The casing or collector box
The absorber is put into a box made of wood with a depth
of 10 to 15 cm. The absorber is adjusted about half way the
total depth so that there is sufficient space underneath as
well as above the absorber.
3. The insulation layer
The space underneath the absorber is filled with insulation
material that retains the heat of the absorber. Usually the
insulation layer should be about 5 cm thick.
4. The cover sheet
To retain the heat in the collector, the box is covered by
glass. Thickness of the glass-sheet must be at least 4 to 5
mm. The glass-sheet allows sunshine to pass through
without absorbing too much solar radiation. Also, it
prevents the cooling of air by wind.
2.1. Constructing the absorber
The absorber consists of 2 items:
1. A half-inch galvanised pipe at standard length of 6
metres. The pipe must be shaped into 7 bends and 2
squared ends.
2. A galvanised sheet with a length of 110 cm, a width of
80 cm and a thickness of 0,5 to 1 mm. The zigzag-pipe
is fixed to the sheet and then painted dull-black.
2.1.1. Preparing the ½” galvanised pipe
The following tools are needed:
- a pipe-holding clamp
- a pipe-cutter or hacksaw
- a thread-cutter
- a folding ruler or measuring rod
- a marker (felt pen)
The following materials are needed:
- 3 half-inch galvanised pipes (for 3 collectors)
For 1 hot water system 3 absorbers are needed. So we start
to prepare 3 pipes at once. Normally each pipe has 2
sockets fixed at both ends. Remove the sockets and put the
pipes parallel to one side against a wall. (see picture
alongside).
Take the shortest pipe as standard and mark all pipes at the same length. Cut the pipes straight at the
indicated length by means of a pipe-cutter or hacksaw. On the shortened ends we make a half-inch thread by
means of a thread-cutter. Check the screw thread of all pipes at both sides by means of a half-inch socket. If
the socket can be screwed on by hand, it’s ok. Keep the socket on to protect the thread while bending the
pipe. Mark the middle of each pipe with a folding ruler. Mark it all around. Now the pipes are ready to be
bent.