Difference between pages "How to Preserve Food with a Solar Dryer" and "How to Refrigerate Vaccines with Solar Photovoltaic Energy"

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=Solar Drying - Technical Brief=
+
<div class="booktext">
 +
 
 +
<center>'''PRACTICAL ACTION'''<br />'''Technology challenging poverty'''</center>
  
 +
</div>
  
 
==Introduction==
 
==Introduction==
Line 6: Line 9:
 
<div class="booktext">
 
<div class="booktext">
  
Agricultural and other products have been dried by the sun and wind in the open air for thousands of years. The purpose is either to preserve them for later use, as is the case with food; or as an integral part of the production process, as with timber, tobacco and laundering. In industrialised regions and sectors, open air-drying has now been largely replaced by mechanised dryers, with boilers to heat incoming air, and fans to force it through at a high rate. Mechanised drying is faster than open-air drying, uses much less land and usually gives a better quality product. But the equipment is expensive and requires substantial quantities of fuel or electricity to operate.
+
Extensive immunisation programmes are in progress throughout the developing world in the fight against the common communicable diseases. To be effective these programmes must provide immunisation services to rural areas.
 +
 
 +
Solar radiation tends to be high in climates that have great needs for cooling, a great deal of effort has been directed to develop solar powered refrigerators. Although some solar absorption (thermal) refrigerators have been developed only solar photovoltaic (electric) refrigerators have so far proved reliable.
  
'Solar drying' in the context of this technical brief, refers to methods of using the sun's energy for drying, but ''excludes'' open air 'sun drying'. The justification for solar dryers is that they may be more effective than sun drying, but have lower operating costs than mechanised dryers. A number of designs are proven technically and while none are yet in widespread use, there is still optimism about their potential.
+
Solar photovoltaic power for refrigerators has great potential for lower running costs, greater reliability and a longer working life than kerosene refrigerators or diesel generators, which have been generally used in remote areas. Over the past five years, at least 3000 photovoltaic medical refrigerators have been installed.
  
 
</div>
 
</div>
  
==How solar dryers work==
+
==The need==
  
 
<div class="booktext">
 
<div class="booktext">
  
One well-known type of solar dryer is shown in Figure 1. It was designed for the particular requirements of rice but the principles hold for other products and design types, since the basic need to remove water is the same.
+
All vaccines have to be kept within a limited temperature range throughout transportation and storage. The provision of refrigeration for this, known as the Vaccine 'Cold Chain', is a major logistical undertaking in areas where electricity supplies are non-existent or erratic. The performance of refrigerators fuelled by kerosene and bottled gas is often inadequate. Diesel powered systems frequently suffer fuel supply problems. Solar power is therefore of great importance to health care.
  
Air is drawn through the dryer by natural convection. It is heated as it passes through the collector and then partially cooled as it picks up moisture from the rice. The rice is heated both by the air and directly by the sun.
+
</div>
  
Warm air can hold more moisture than cold air so the amount required depends on the temperature to which it is heated in the collector as well as the amount held (absolute humidity) when it entered the collector.
+
==Relative merits of using photovoltaic refrigerators==
  
<center>
+
<div class="booktext">
 
 
[[Image:Solardrying01.gif]] Figure 1: Rice solar dryer
 
  
</center>
+
Compared to kerosene or bottled gas fuelled refrigerators, photovoltaic systems have the following advantages:
  
The way in which the moisture absorption capability of air is affected by its initial humidity and by the temperature to which it is subsequently heated is shown in Table 1.
+
'''Improved vaccine storage facilities as a result of:'''<br />
  
<center>Air enters at 20°C and leaves at 80% RH</center>
+
<blockquote>
  
<div align="left">
+
• elimination of fuel supply problems<br /> • elimination of fuel quality problems<br /> • greater refrigerator reliability<br /> • better refrigerator performance (and temperature control).
  
{| border="1" cellpadding="5"
+
</blockquote>
|- valign="top"
 
| valign="top" |
 
Initial relative humidity
 
| colspan="3" valign="top" |
 
Moisture absorption capability (grammes of water/m° of air)
 
|- valign="top"
 
| valign="top" |
 
Not heated
 
| valign="top" |
 
Heated to 40°C
 
| valign="top" |
 
Heated to 60°C
 
|- valign="top"
 
| valign="top" |
 
40%
 
| valign="top" |
 
4.3g/m°
 
| valign="top" |
 
9.2g/m°
 
| valign="top" |
 
16.3g/m°
 
|- valign="top"
 
| valign="top" |
 
60%
 
| valign="top" |
 
1.4g/m°
 
| valign="top" |
 
8.2g/m°
 
| valign="top" |
 
15.6g/m°
 
|- valign="top"
 
| valign="top" |
 
80%
 
| valign="top" |
 
| valign="top" |
 
7.1g/m°
 
| valign="top" |
 
14.9g/m°
 
|}
 
  
</div>
+
<br />'''Reduced running costs as a result of:'''<br />
  
Table 1: The drying process
+
<blockquote>
  
The objective of most drying processes is to reduce the moisture content of the product to a specified value. Moisture content (wet basis) is expressed as the weight of water as a proportion of total weight. The moisture content of rice has typically to be reduced from 24% to 14%. So to dry one tonne of rice, 100kg of water must be removed.
+
• elimination of kerosene fuel costs<br /> • elimination of kerosene transportation costs<br /> • reduced vaccine losses<br /> • lower refrigerator maintenance costs<br /> • reduced needs for back-up refrigerators where there are fuel supply or repair problems.
  
If the heated air has a 'absorption capacity' of 8g/m<sup>3</sup> then 100/0.0008 = 12,500/m<sup>3</sup> of air are required to dry one tonne of rice.
+
</blockquote>
  
The heat required to evaporate water is 2.26kJ/kg. Hence, approximately 250MJ (70kWh) of energy are required to vaporise the 100kg water. There is no fixed requirement for solar heat input to the dryer. This is because the incoming ambient air can give up some of its internal energy to vaporise the water (becoming colder in the process). Indeed, if the ambient air is dry enough, no heat input is essential.
+
<br />'''Cold chain management benefits due to:'''<br />
  
Nevertheless, extra heat is useful for two reasons. First, if the air is warmer then less of it is needed. Second, the temperature in the rice grains themselves may be an important factor, especially in the later stages of drying, when moisture has to be 'drawn' from the centres of the grains to their surfaces. This temperature will itself depend mainly on the air temperature but also on the amount of solar radiation received directly by the rice.
+
<blockquote>
  
In a natural convection system, the flow of air is caused by the fact that the warm air inside the dryer is lighter than the cooler air outside. This difference in density creates a small pressure difference across the bed of grain, which forces the air through it. This effect increases, the greater is the height of the bed above the inlet (h1) and the outlet above the bed (h2). The effect of an increased h2 is less than that of an increased h1 because the air is cooled as it passes through the bed.
+
• longer equipment life (photovoltaic array 15 years, battery 5 years refrigerator 10 years)<br /> • reduced logistical problems arising from non-availability of working refrigerators<br /> • reduced logistical problems arising from lower vaccine losses.
  
Approximate densities for a variety of cases are shown in Table 2.
+
</blockquote>
  
<center>Air enters at 20 °C and leaves at 80% RH</center>
+
<br /> The above operational advantages of introducing solar refrigerators into the cold chain indicate that solar refrigerators can provide a more sustainable vaccine cold chain.
  
<div align="left">
+
It should be noted however, that as each system is site specific, more time is necessary for planning and implementing a project with solar refrigerators.
  
{| border="1" cellpadding="5"
+
User training demands are also higher since a new technology is being introduced.
|- valign="top"
 
| valign="top" |
 
Initial relative humidity
 
| colspan="4" valign="top" |
 
Density of the air (kg/m<sup>3</sup>) (Drop in density, in brackets)
 
|- valign="top"
 
| valign="top" |
 
Not heated
 
| valign="top" |
 
Heated to
 
|- valign="top"
 
| valign="top" |
 
30 °C
 
| valign="top" |
 
40 °C
 
| valign="top" |
 
60 °C
 
|- valign="top"
 
| valign="top" |
 
40%
 
| valign="top" |
 
Ambient 1.19
 
| valign="top" |
 
1.19
 
| valign="top" |
 
1.19
 
| valign="top" |
 
1.19
 
|- valign="top"
 
| valign="top" |
 
Below bed 1.19 (.00)
 
| valign="top" |
 
1.15 (.04)
 
| valign="top" |
 
1.12 (.07)
 
| valign="top" |
 
1.05 (.14)
 
|- valign="top"
 
| valign="top" |
 
Above bed 1.21 (-.02)
 
| valign="top" |
 
1.19 (.00)
 
| valign="top" |
 
1.17 (.02)
 
| valign="top" |
 
1.14 (.05)
 
|- valign="top"
 
| valign="top" |
 
60%
 
| valign="top" |
 
Ambient 1.19
 
| valign="top" |
 
1.19
 
| valign="top" |
 
1.19
 
| valign="top" |
 
1.19
 
|- valign="top"
 
| valign="top" |
 
Below bed 1.19 (.00)
 
| valign="top" |
 
1.15 (.04)
 
| valign="top" |
 
1.11 (.08)
 
| valign="top" |
 
1.05 (.14)
 
|- valign="top"
 
| valign="top" |
 
Above bed 1.20 (-.01)
 
| valign="top" |
 
1.18 (.01)
 
| valign="top" |
 
1.16 (.03)
 
| valign="top" |
 
1.13 (.06)
 
|- valign="top"
 
| valign="top" |
 
80%
 
| valign="top" |
 
Ambient 1.18
 
| valign="top" |
 
1.18
 
| valign="top" |
 
1.18
 
| valign="top" |
 
1.18
 
|- valign="top"
 
| valign="top" |
 
Below bed 1.18 (.00)
 
| valign="top" |
 
1.14 (.04)
 
| valign="top" |
 
1.11 (.07)
 
| valign="top" |
 
1.04 (.14)
 
|- valign="top"
 
| valign="top" |
 
Above bed 1.18 (.00)
 
| valign="top" |
 
1.16 (.02)
 
| valign="top" |
 
1.15 (.03)
 
| valign="top" |
 
1.11 (.07)
 
|}
 
  
 
</div>
 
</div>
  
Table 2: Air density variation in a natural convection dryer
+
==Comparative costs==
  
It can be seen that if the incoming air is heated by only 10-30°C then the presence of a chimney on top of the dryer would make little or no difference, unless it acted efficiently as a solar collector and raised the temperature of the air significantly.
+
<div class="booktext">
 
 
It should be noted that even if the difference in densities is as much as .05kg/m<sup>2</sup>, then the resulting pressure difference is only 0.5 Pa (5 millionths of atmospheric pressure) per metre of chimney. For comparison, forced convection systems commonly operate with pressure differences of 100-500 Pa.
 
  
Many products are damaged by excessive temperatures. The most severe constraints are on beans (35°C), rice (45°C), and all grains if they are to be used for seed (45°C).
+
A true comparison of solar refrigerators and comparable kerosene and bottled gas fuelled refrigerators can only be made through a life-cycle cost analysis.
  
Other types of dryers and their performance
+
A solar photovoltaic refrigerator cabinet only is likely to cost around US $1300 - 2600 (with the complete system costing around US $3000 - 5000) and will cost more to install than a kerosene unit. A kerosene refrigerator will cost only US $650 - 1300 but will use 0.5 - 1.4 litres of fuel per day, require frequent maintenance and have a shorter life. In general, life-cycle costs are approximately the same for solar and kerosene refrigerators, but because of their greater reliability and resultant savings in wasted vaccine, solar refrigerators are the preferred option.
  
 
</div>
 
</div>
  
==Forced convection solar dryer==
+
==The technology==
  
 
<div class="booktext">
 
<div class="booktext">
  
(Figure 2)
+
'''Refrigerator'''
 +
 
 +
Photovoltaic refrigerators operate on the same principle as normal compression refrigerators but incorporate low voltage (12 or 24v) dc compressors and motors, rather than mains voltage ac types. A photovoltaic refrigerator has higher levels of insulation around the storage compartments to maximise energy efficiency, a battery bank for electricity storage, a battery charge regulator and a controller which converts the power from the battery to a form required by the compressor motor.
  
By using a fan to create the airflow, drying time can be reduced by a factor of 3. Also, the area of collector required is reduced by up to 50%. Therefore, the area of collector required for a given throughput of product could be reduced by a factor of 5-6. The initial cost of a one tonne per day dryer is in the region of £1500-2000. The fan would consume about 500 watts for 6 hours, and so electricity cost (at 0.07/kWhr) would be about 0.20 per tonne of rice dried
+
A typical refrigerator layout is as shown below (Figure 1). Most refrigerators include a freezer compartment for ice pack freezing. Other systems have separate units to provide solely for refrigeration or freezing. Available sizes range between 10 and 85 litres of vaccine storage capacity with ice production rates of up to 6.4 kg per 24 hours.
  
 
<center>
 
<center>
  
[[Image:p04a.gif]]<br /> Figure 2: Forced convection solar dryer
+
[[Image:Refrigeration_Vaccines_1.gif]]<br /> Figure 1: A typical refrigerator layout
  
 
</center>
 
</center>
  
'''Tent dryer'''
+
'''Batteries'''
 +
 
 +
The battery most commonly used is the lead acid type, long life, deep cycle batteries are preferred. A capacity to run the refrigerator for five days without sun is recommended.
  
The distinguishing feature of tent, box and cabinet dryers is that the drying chamber and the collector are combined into one, see Figure 3. This allows a lower initial cost. Drying times are however not always much lower than for open-air drying. (Probably, insufficient attention has so far been paid to utilising natural convection.) The main purpose of the dryers may be to provide protection from dust, dirt, rain, wind or predators and they are usually used for fruit, fish, coffee or other products for which wastage is otherwise high. There are numerous other types. Greenhouse dryers are a more sophisticated version of tent dryers. Box dryers may incorporate thermal insulation to achieve higher temperatures. Storage bin dryers combine the functions of drying and long-term storage. Solar timber kilns may include hot water storage to enable the necessary control of drying rate.
+
'''Charge regulator'''
  
<center>
+
The charge regulator maintains the power supply within the current and voltage range tolerated by the refrigerator and prevents overcharge of the battery. Some models include an audible alarm or warning light to signal when battery voltage becomes low. Lightning surge protection must be provided for tropical areas.
  
[p04b.gif [[Image:p04b.gif]]]<br /> Figure 3: Tent dryer
+
'''Array and support structure'''
  
</center></div>
+
The solar array can be for roof or ground mounting. The array size for a refrigeration system is calculated to meet the power requirements of the system, given the solar irradiance data for the proposed site. The typical requirement is 150 - 200 Wp of photovoltaic modules.
  
==Solar drying or open-air drying?==
+
</div>
 +
 
 +
==Performance==
  
 
<div class="booktext">
 
<div class="booktext">
  
The great advantage of open-air drying is that it has little or no equipment costs. It is labour-intensive but this may not involve much economic cost in rural areas in developing countries. It requires about three times as much land (100m<sup>2</sup> per tonne of rice) compared to solar drying, but this may not matter too much in many cases.
+
The energy consumption of a photovoltaic vaccine refrigerator is typically 400 - 800 watt-hours per 24 hours for a 100-litre refrigerator without icepack freezing and at +32°C ambient temperature. At +43°C ambient temperature and freezing 2kg of ice packs per 24 hours the energy consumption of the same refrigerator would rise to about 900 - 1900 watt-hours per 24 hours. It is very important not to overload a solar refrigerator as this increases energy consumption considerably.
  
Firstly, one important advantage of solar drying is that the product is protected from rain, insects, animals and dust that may contain faecal material. Some systems also give protection from direct sunlight. Second, faster drying reduces the likelihood of mould growth. Third, higher drying temperatures mean that more complete drying is possible, and this may allow much longer storage times (but only if rehumidification is prevented in storage). Finally, more complex types of solar dryers allow some control over drying rates.
+
A good vaccine refrigerator should be able to maintain correct internal temperatures for at least ten hours in the event of being disconnected from the battery and solar array.
  
 
</div>
 
</div>
  
==Solar dryers or fuelled dryers?==
+
==Costs==
  
 
<div class="booktext">
 
<div class="booktext">
  
The choice between using solar radiation or fuel, to heat the air is mainly one between a higher initial cost and continuing fuel costs which needs to be analysed for each location.
+
The output of a photovoltaic array will vary according to the location at which it is to be installed and the refrigerator energy consumption will depend on local climate. Therefore the size of the solar array, the battery storage capacity and hence the system cost will vary depending on location. Typical system costs are in the range of US $3,500 - 7500 excluding transport and installation.
 
 
In some circumstances, it may be possible to burn rice husks or other fuel with low opportunity cost. One tonne of rice gives 200kg of husks.
 
 
 
Fuel heating usually allows better control of the drying-rate than solar heating; it also enables drying to be continuous. If either of these is required, a combined system may be appropriate with pre-heating of air by solar energy.
 
  
 
</div>
 
</div>
  
==Which solar dryer?==
+
==Products available==
  
 
<div class="booktext">
 
<div class="booktext">
  
The choice between alternative types of solar dryer will depend on local requirements and in particular on the scale of operation. If intended for peasant farmers then initial capital cost may be the main constraint and plastic-covered tent or box dryers may be appropriate.
+
The Department of Vaccines and Biologicals of the World Health Organisation, in its Immunisation Systems Series publishes, every two years, a document entitled 'Product Information Sheets'. This catalogues equipment that has undergone tests to verify their performance is of a standard acceptable to the World Health Organisation (WHO) and United Nations Children Fund (UNICEF). The document may be obtained from: The V & B Document Centre, Department of Vaccine and Biologicals, World Health Organisation, CH-1211 Geneva 27, Switzerland. (Website: http://www.who.int/vaccines-documents, email: [mailto:vaccines@who.int vaccines@who.int])
 +
 
 +
'''Suppliers'''
  
There may however be a trend towards more centralised drying to enable more intensive usage of the equipment. The greater initial cost of glass covers may then be affordable, and grid electricity may be available to run fans and obtain much faster throughput for a given collector area.
+
Note: This is a selective list of suppliers and does not imply Practical Action endorsement or promotion.
  
For intermediate scale and capital cost the natural convection rice dryer is a well proven design.
+
BP Solar Ltd., PO Box 191, Chertsey Road,<br /> Sunbury-on-Thames, Middlesex TW16 7XA,<br /> United Kingdom<br /> Tel: +44 1932 779 543<br /> Fax: +44 1932 762 686
  
</div>
+
Dulas Ltd., Dyfi Eco Park, Machynlleth, Powys<br /> SY20 8SX, U.K.<br /> Telephone: +44 1654 705 000<br /> Fax: +44 1654 703 000
  
==References and further reading==
+
Comesse Soudure SA, 88390 Chaumousey,<br /> France<br /> Tel: +33 3 2966 8548<br /> Fax: +33 3 2966 8094<br /><u>Note</u><nowiki>: The unit supplied is solar thermal and</nowiki><br /> not solar photovoltaic
  
<div class="booktext">
+
Electrolux (Luxembourg) SARL, 14 op der Hei,<br /> L-9808 Hosingen, Luxembourg<br /> Telephone: +352 920 731<br /> Fax: +352 920 731 300
  
'''A survey of solar agricultural driers''' - Brace Research Institute - 1975<br />'''Preparing grain for storage''' - Action/Peace Corps and VITA - 1976<br />'''Solar driers''' - Commonwealth Science Council - 1985<br />'''Solar drying''' - Practical methods of food preservation - ILO 1988<br />''Producing Solar Dried Fruit and Vegetables for Small-scale Enterprise Development'' - NRI 1996<br />''Try Drying It!: Case studies in the dissemination of tray drying technology'' - IT Publishing 1991
+
NAPS Norway A/S, Strandvein 50, N-1366<br /> Lysaker, Norway<br /> Tel: +47 67 112 550<br /> Fax: +47 67 112 545
  
</div>
+
Solamatics (Pvt) Ltd., 31 Edison Road,<br /> Graniteside, Harare, Zimbabwe<br /> Tel: +263 4 749 930<br /> Fax: +263 4 771 212
  
==Useful contacts==
+
TATA BP Solar India Ltd., Plot No. 78,<br /> Electronic City, Hosur Road,<br /> Bangalore 561 229, India<br /> Tel: +91 80 852 1016<br /> Fax: +91 80 852 0116
  
<div class="booktext">
+
Norcoast Refrigeration Co, 50 Grigor Street,<br /> Caloundra, Queensland 4551, Australia<br /> Tel: +61 7 9491 1849<br /> Fax: +61 7 5491 7627<br /> Website: http://www.norcoast.com.au
  
NR International<br /> Central Avenue<br /> Chatham Maritime<br /> Kent<br /> ME4 4TB<br /> United Kingdom<br /> Tel: +44 1634 880088<br /> Fax: +44 1634 880066/77<br /> Email: [mailto:info@nrint.co.uk info@nrint.co.uk]<br /> Website: http://www.nrinternational.co.uk/
+
Sun Frost, PO Box 1101, 824 St Ste # 7,<br /> Arcata, California 95518, USA<br /> Tel: +1 707 822 9095<br /> Fax: +1 707 822 6213
  
 
'''Practical Action, The Schumacher Centre for Technology & Development'''<br />'''Bourton Hall, Bourton-on-Dunsmore, Rugby, Warwickshire CV23 9QZ, UK'''<br />'''Tel: +44 (0)1926 634400 Fax: +44 (0)1926 634401 E-mail: [mailto:infoserv@practicalaction.org.uk infoserv@practicalaction.org.uk] Web: http://www.practicalaction.org'''
 
'''Practical Action, The Schumacher Centre for Technology & Development'''<br />'''Bourton Hall, Bourton-on-Dunsmore, Rugby, Warwickshire CV23 9QZ, UK'''<br />'''Tel: +44 (0)1926 634400 Fax: +44 (0)1926 634401 E-mail: [mailto:infoserv@practicalaction.org.uk infoserv@practicalaction.org.uk] Web: http://www.practicalaction.org'''
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</div>
 
</div>
  
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==References and further reading==
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<div class="booktext">
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This Howtopedia entry was derived from the Practical Action Technical Brief ''Energy from the Wind''. <br />To look at the original document follow this link: http://www.practicalaction.org/?id=technical_briefs_energy'''<br />
[[Image:spacer.gif]]<br />
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[javascript:openWindow2('/collect/gtzinti/static/feedback.htm',750,600) Please provide your feedback]
 
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<span class="langmeniuactiv"> English </span><nowiki>|</nowiki>[gsdl?e=d-00gtzinti---000--1-0--010---4----0--0-10l--1en-5000---50-about-0---01131-0011w%40JSsg%28%29c0a8013000000ef044f171ee-0utfZz-8-0-0&cl=CL3.13&d=Js7714e&az=A&gt=2&gc=&ihs=0&l=fr&az=A&p=about  French ]<nowiki>|</nowiki>[gsdl?e=d-00gtzinti---000--1-0--010---4----0--0-10l--1en-5000---50-about-0---01131-0011w%40JSsg%28%29c0a8013000000ef044f171ee-0utfZz-8-0-0&cl=CL3.13&d=Js7714e&az=A&gt=2&gc=&ihs=0&l=es&az=A&p=about  Spanish ]
 
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Revision as of 11:31, 27 August 2006

PRACTICAL ACTION
Technology challenging poverty

Introduction

Extensive immunisation programmes are in progress throughout the developing world in the fight against the common communicable diseases. To be effective these programmes must provide immunisation services to rural areas.

Solar radiation tends to be high in climates that have great needs for cooling, a great deal of effort has been directed to develop solar powered refrigerators. Although some solar absorption (thermal) refrigerators have been developed only solar photovoltaic (electric) refrigerators have so far proved reliable.

Solar photovoltaic power for refrigerators has great potential for lower running costs, greater reliability and a longer working life than kerosene refrigerators or diesel generators, which have been generally used in remote areas. Over the past five years, at least 3000 photovoltaic medical refrigerators have been installed.

The need

All vaccines have to be kept within a limited temperature range throughout transportation and storage. The provision of refrigeration for this, known as the Vaccine 'Cold Chain', is a major logistical undertaking in areas where electricity supplies are non-existent or erratic. The performance of refrigerators fuelled by kerosene and bottled gas is often inadequate. Diesel powered systems frequently suffer fuel supply problems. Solar power is therefore of great importance to health care.

Relative merits of using photovoltaic refrigerators

Compared to kerosene or bottled gas fuelled refrigerators, photovoltaic systems have the following advantages:

Improved vaccine storage facilities as a result of:

• elimination of fuel supply problems
• elimination of fuel quality problems
• greater refrigerator reliability
• better refrigerator performance (and temperature control).


Reduced running costs as a result of:

• elimination of kerosene fuel costs
• elimination of kerosene transportation costs
• reduced vaccine losses
• lower refrigerator maintenance costs
• reduced needs for back-up refrigerators where there are fuel supply or repair problems.


Cold chain management benefits due to:

• longer equipment life (photovoltaic array 15 years, battery 5 years refrigerator 10 years)
• reduced logistical problems arising from non-availability of working refrigerators
• reduced logistical problems arising from lower vaccine losses.


The above operational advantages of introducing solar refrigerators into the cold chain indicate that solar refrigerators can provide a more sustainable vaccine cold chain.

It should be noted however, that as each system is site specific, more time is necessary for planning and implementing a project with solar refrigerators.

User training demands are also higher since a new technology is being introduced.

Comparative costs

A true comparison of solar refrigerators and comparable kerosene and bottled gas fuelled refrigerators can only be made through a life-cycle cost analysis.

A solar photovoltaic refrigerator cabinet only is likely to cost around US $1300 - 2600 (with the complete system costing around US $3000 - 5000) and will cost more to install than a kerosene unit. A kerosene refrigerator will cost only US $650 - 1300 but will use 0.5 - 1.4 litres of fuel per day, require frequent maintenance and have a shorter life. In general, life-cycle costs are approximately the same for solar and kerosene refrigerators, but because of their greater reliability and resultant savings in wasted vaccine, solar refrigerators are the preferred option.

The technology

Refrigerator

Photovoltaic refrigerators operate on the same principle as normal compression refrigerators but incorporate low voltage (12 or 24v) dc compressors and motors, rather than mains voltage ac types. A photovoltaic refrigerator has higher levels of insulation around the storage compartments to maximise energy efficiency, a battery bank for electricity storage, a battery charge regulator and a controller which converts the power from the battery to a form required by the compressor motor.

A typical refrigerator layout is as shown below (Figure 1). Most refrigerators include a freezer compartment for ice pack freezing. Other systems have separate units to provide solely for refrigeration or freezing. Available sizes range between 10 and 85 litres of vaccine storage capacity with ice production rates of up to 6.4 kg per 24 hours.

Refrigeration Vaccines 1.gif
Figure 1: A typical refrigerator layout

Batteries

The battery most commonly used is the lead acid type, long life, deep cycle batteries are preferred. A capacity to run the refrigerator for five days without sun is recommended.

Charge regulator

The charge regulator maintains the power supply within the current and voltage range tolerated by the refrigerator and prevents overcharge of the battery. Some models include an audible alarm or warning light to signal when battery voltage becomes low. Lightning surge protection must be provided for tropical areas.

Array and support structure

The solar array can be for roof or ground mounting. The array size for a refrigeration system is calculated to meet the power requirements of the system, given the solar irradiance data for the proposed site. The typical requirement is 150 - 200 Wp of photovoltaic modules.

Performance

The energy consumption of a photovoltaic vaccine refrigerator is typically 400 - 800 watt-hours per 24 hours for a 100-litre refrigerator without icepack freezing and at +32°C ambient temperature. At +43°C ambient temperature and freezing 2kg of ice packs per 24 hours the energy consumption of the same refrigerator would rise to about 900 - 1900 watt-hours per 24 hours. It is very important not to overload a solar refrigerator as this increases energy consumption considerably.

A good vaccine refrigerator should be able to maintain correct internal temperatures for at least ten hours in the event of being disconnected from the battery and solar array.

Costs

The output of a photovoltaic array will vary according to the location at which it is to be installed and the refrigerator energy consumption will depend on local climate. Therefore the size of the solar array, the battery storage capacity and hence the system cost will vary depending on location. Typical system costs are in the range of US $3,500 - 7500 excluding transport and installation.

Products available

The Department of Vaccines and Biologicals of the World Health Organisation, in its Immunisation Systems Series publishes, every two years, a document entitled 'Product Information Sheets'. This catalogues equipment that has undergone tests to verify their performance is of a standard acceptable to the World Health Organisation (WHO) and United Nations Children Fund (UNICEF). The document may be obtained from: The V & B Document Centre, Department of Vaccine and Biologicals, World Health Organisation, CH-1211 Geneva 27, Switzerland. (Website: http://www.who.int/vaccines-documents, email: vaccines@who.int)

Suppliers

Note: This is a selective list of suppliers and does not imply Practical Action endorsement or promotion.

BP Solar Ltd., PO Box 191, Chertsey Road,
Sunbury-on-Thames, Middlesex TW16 7XA,
United Kingdom
Tel: +44 1932 779 543
Fax: +44 1932 762 686

Dulas Ltd., Dyfi Eco Park, Machynlleth, Powys
SY20 8SX, U.K.
Telephone: +44 1654 705 000
Fax: +44 1654 703 000

Comesse Soudure SA, 88390 Chaumousey,
France
Tel: +33 3 2966 8548
Fax: +33 3 2966 8094
Note: The unit supplied is solar thermal and
not solar photovoltaic

Electrolux (Luxembourg) SARL, 14 op der Hei,
L-9808 Hosingen, Luxembourg
Telephone: +352 920 731
Fax: +352 920 731 300

NAPS Norway A/S, Strandvein 50, N-1366
Lysaker, Norway
Tel: +47 67 112 550
Fax: +47 67 112 545

Solamatics (Pvt) Ltd., 31 Edison Road,
Graniteside, Harare, Zimbabwe
Tel: +263 4 749 930
Fax: +263 4 771 212

TATA BP Solar India Ltd., Plot No. 78,
Electronic City, Hosur Road,
Bangalore 561 229, India
Tel: +91 80 852 1016
Fax: +91 80 852 0116

Norcoast Refrigeration Co, 50 Grigor Street,
Caloundra, Queensland 4551, Australia
Tel: +61 7 9491 1849
Fax: +61 7 5491 7627
Website: http://www.norcoast.com.au

Sun Frost, PO Box 1101, 824 St Ste # 7,
Arcata, California 95518, USA
Tel: +1 707 822 9095
Fax: +1 707 822 6213

Practical Action, The Schumacher Centre for Technology & Development
Bourton Hall, Bourton-on-Dunsmore, Rugby, Warwickshire CV23 9QZ, UK
Tel: +44 (0)1926 634400 Fax: +44 (0)1926 634401 E-mail: infoserv@practicalaction.org.uk Web: http://www.practicalaction.org

Intermediate Technology Development Group Ltd Patron HRH - The Prince of Wales, KG, KT, GCB
Company Rag. No 871954, England Rag. Charity No 247257 VAT No 241 5154 92

References and further reading

This Howtopedia entry was derived from the Practical Action Technical Brief Energy from the Wind.
To look at the original document follow this link: http://www.practicalaction.org/?id=technical_briefs_energy