The power in the wind

The wind systems that exist over the earth's surface are a result of variations in air pressure. These are in turn due to the variations in solar heating. Warm air rises and cooler air rushes in to take its place. Wind is merely the movement of air from one place to another. There are global wind patterns related to large scale solar heating of different regions of the earth's surface and seasonal variations in solar incidence. There are also localised wind patterns due the effects of temperature differences between land and seas, or mountains and valleys.

Windspeed data can be obtained from wind maps or from the meteorology office. Unfortunately the general availability and reliability of windspeed data is extremely poor in many regions of the world. However, significant areas of the world have mean windspeeds of above 3m/s which make the use of windpumps an economically attractive option. It is important to obtain accurate windspeed data for the site in mind before any decision can be made as to its suitability. Methods for assessing the mean windspeed are found in the relevant texts (see the 'References and resources' section at the end of this fact sheet).

The power in the wind is proportional to:

• the area of windmill being swept by the wind
• the cube of the wind speed
• the air density - which varies with altitude

The formula used for calculating the power in the wind is shown below:

P_W = ½ ρ A V³

The fact that the power is proportional to the cube of the wind speed is very significant. This can be demonstrated by pointing out that if the wind speed doubles then the power in the wind increases by a factor of eight! It is therefore worthwhile finding a site which has a relatively high mean wind speed.

Wind into watts

Although the power equation above gives us the power in the wind, the actual power that we can extract from the wind is significantly less than this figure suggests. The actual power will depend on several factors, such as the type of machine and rotor used, the sophistication of blade design, friction losses, the losses in the pump or other equipment connected to the wind machine, and there are also physical limits to the amount of power which can be extracted realistically from the wind. It can been shown theoretically that any windmill can only possibly extract a maximum of 59.3% of the power from the wind (this is known as the Betz limit). In reality, for a windpump, this figure is usually around 30% to 40% and for a large electricity producing turbine around 45% maximum (see the section on coefficient of performance below)

So, modifying the formula for 'Power in the wind' we can say that the power that is produced by the wind machine can be given by:

P_M = ½.C_p ρ A V³

where:

• P_M is power (in watts) available from the machine
• C_p is the coefficient of performance of the wind machine

Matching rotor and pump

When installing a windpump it is important to match the characteristics of the pump and the wind machine. A good interaction between pump and rotor is essential. The most common type of pump used for water pumping (especially for borehole water pumping) in conjunction with a windmill is the reciprocating or piston pump. The piston pump tends to have a high torque requirement on starting because, when starting, the rotor has to provide enough torque to overcome the weight of the pump rods and water in the rising main - once the rotor is turning, the torque requirement decreases because of the momentum of the revolving rotor. The windspeed can then drop to about 2/3 of the start-up windspeed before the windpump will stop.

Other common pump types used for windpumping are the progressive cavity or 'Mono' pump and the centrifugal pump. Both have advantages in certain circumstances but both also tend to be expensive and less commonly used.

Figure 3. illustrates a typical example of a modern multi-bladed windpump. The high solidity means high starting and running torque and low running speed which is desirable for use with the piston pump.

It is obviously important to match the water pumping demand with the available wind and hence decide upon a suitable rotor size. To calculate the demand we need to know the following data:

• The head to which the water is to be pumped - in metres
• volume of water to be pumped per day - in metres cubed

For water at sea level the approximate energy requirement can be calculated using the following equation:

E = 0.002725 x volume x head (in kilowatt-hours)

Typically pumping heads can vary between a few metres and 100m (and occasionally more), whilst the volume of water required can vary from a few cubic metres a day for domestic use to a few hundred cubic metres for irrigation.

Anatomy of windpump

A borehole is by far the most common water source from which the windpump will draw water. A classic multiblade farm windpump has a piston pump pumping to an elevated storage tank. There are many other configurations possible, depending on the nature of the water source and the demand. These machines have rotor diameters of between 1.5 and 8 metres but seldom exceed 4 or 5 metres. The power is transmitted from the rotor to the pump rods via a gearing system or via a direct drive mechanism. The movement of the pump rods cause the pump to lift water to the tank. Water can then be fed into the distribution network from the tank. The function of the tail vane is to keep the rotor orientated into the wind. Most windpumps have a tail vane, which is designed, for automatic furling (turning the machine out of the wind) at high wind speeds to prevent damage.

Windpumping with electricity

Although the multiblade windpump is by far the most common windpump in use, it is not the only option available. Another option, especially where there is a requirement for the pump to be sited remote from the wind machine, is to use an aerogenerator to provide electricity for an electric pump. Although they tend to be more expensive, they do have the advantage that the electricity can be used for other applications when not pumping and also that the electricity can be stored in batteries for use when the windspeed is insufficient for direct electricity supply.

Ressource Management

• Deep water sources might be of fossile nature ( water reserves that consituted over thousand of years) or renewable nature ( water table that reconstitutes /refills with the rainy season).
  

In the first case, it is a finite ressource that should be managed extremely carefully.
In the second case, it might be very helpful to improve the rainwater infiltration on the whole valley, the water catchment area, with retention pits, small barrages that slow down the rain run-off or with contour hedges like vetiver grass hedges that retain the top soil nutrients and help the water infitrate along their roots during the rainy season, in order to replenish regularly the groundwater.

• An important issue for both type is the pollution risk of the underground water by organic material or chemicals like detergents, pesticides or fertilizers.
  

Local manufacture

Windpumps are manufactured in small numbers in various countries throughout the world. There are manufacturers producing windpumps in Europe, Australia, South Africa and the USA for export, but there are also commercial enterprises in developing countries manufacturing windpumps. One such manufacturer, RIIC (the Rural Industries and Innovations Centre) is mentioned below.

There have been several projects over the last couple of decades with the aim of transferring windpump technology to manufacturers in the South, and there has been some success. One such success story is the Kijito windpump (See figure 3), manufactured in Kenya. This windpump was originally developed by the Intermediate Technology Development Group - ITDG (now known as Practical Action) based in the UK in conjunction with Bobs Harries Engineering Ltd. (BHEL), Kenya. BHEL have further developed the Kijito design and currently produce about 25 windpumps a year with a capacity to produce up to 50 machines.

Source: Mosimanyane et al 1995 (cited in Karekezi & Ranja 1997)

1. P. Fraenkel, R. Barlow, F. Crick, A. Derrick and V. Bokalders: Windpumps - A guide for development workers. ITDG Publishing, 1993

2. David, A. Spera: Wind Turbine Technology, fundamental concepts of wind turbine engineering. ASME Press, 1994

3. E. W. Golding: The Generation of Electricity by Wind Power. Redwood Burn Limited, Trowbridge, 1976

4. Hugh Piggot: Windpower Workshop, building your own wind turbine. Centre for Alternative Technology, 1997

5. S. Karekezi and T. Ranja: Renewable Energy Technologies in Africa. AFREPREN / SEI, 1997

6. C. Borg, and H. Oden: The Kijito Windpump - A Private Initiative in Kenyan Rural Water Supply, Master's Thesis, Chalmers University of Technology, Goteborg, 1995

7. Paul T. Smulders and Jan de Jongh: Wind Pumping: Status, Prospects and Barriers, Article, Renewable Energy, Vol. 5 Part 1, pp. 587-594, 1994

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

Bosman Watermanagement BV,www.bosman-water.nl ,The Netherlands, Manufacture and supply watermill with high volume centrifugal pump.

Neale Consulting Engineers Ltd., Highfield,
Pilcot Hill, Dogmersfield, Hants. RG27 8SX,
United Kingdom
Tel: +44 (0)1252 629199
Fax: +44 (0)1252 815625
Website:
http://www.tribology.co.uk/poldaw.htm

Manufacture the Poldaw 3.5m Windpump.
Southern Cross Industries (Pty.) Ltd.,
P.O. Box 627, Bloemfontein 9300,
South Africa.
Tel: +27 (0)51 4343861
Fax: +27 (0)51 4343575
Manufacture and supply windpumps.

Bobs Harries Engineering Ltd. - Kijito Windpumps
- Designing, manufacturing & installing Wind Energy Solutions in Kenya and abroad since 1979 -
Karaimani Estate, Harries Road,
P.O.Box 40,
01000 Thika, Kenya.
Tel: +254 67 24207 or 24238,
Cel: +254 (0) 724 255 250 or 733 247 694,
Tel/Fax: + 254 (0) 20 2022821,
Email: info@kijitowindpower.com,
http://www.kijitowindpower.com

The Rural Industries Innovations Centre,
(Subsidiary of Rural Industries Promotions Company. Website: http://www.ripco.co.bw),
P/Bag 11, Kanye, Botswana.
Tel: +267 340392
Fax: +267 340642

Abachem Engineering Ltd., Jessop Way,
Newark, Notts. NG24 2ER, UK.
Tel: +44 (0)1636 676483
Fax: +44 (0)1636 708632.
Manufacture and supply windpump and 'submerged control leakage pump'.

Stewarts & Lloyds, 37 Leopold Takawira St.,
Harare, P.O. Box 784, Zimbabwe.
Tel: +263 4 708191
Fax: + 263 4 790972
Manufactures of the IT Windpump.

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