Difference between revisions of "Small-Scale Wind"
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| − | ! scope="col" | Application | + | ! scope="col" | Application |
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| Oesao, Timor, Indonesia<br> | | Oesao, Timor, Indonesia<br> | ||
| − | | Small plot irrigation | + | | Small plot irrigation |
| 1.5 kW Wind Turbine with 18m Tower; 10 Stage Pump<br> | | 1.5 kW Wind Turbine with 18m Tower; 10 Stage Pump<br> | ||
| ~ 150 m3 of water per Day<br> | | ~ 150 m3 of water per Day<br> | ||
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| − | + | ==== Village Power: Pre-Electrification <br> ==== | |
Pre-electrification means installing a small source of electricity for basic needs like lighting. Thus the costs for candles, kerosene or dry-cell batteries can be safed. The systems often work with micro wind turbines (25-120 Watts per household), have no grid connection, but generate a direct current that can be used for charging batteries. High efficiency fluorescent bulbs are often used to make the most advantage from the small lighting systems.<br> | Pre-electrification means installing a small source of electricity for basic needs like lighting. Thus the costs for candles, kerosene or dry-cell batteries can be safed. The systems often work with micro wind turbines (25-120 Watts per household), have no grid connection, but generate a direct current that can be used for charging batteries. High efficiency fluorescent bulbs are often used to make the most advantage from the small lighting systems.<br> | ||
{| cellspacing="1" cellpadding="1" border="1" align="left" width="760" | {| cellspacing="1" cellpadding="1" border="1" align="left" width="760" | ||
| + | |+ '''Table 3: Project examples - pre-electrification''' | ||
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! scope="col" | Site<br> | ! scope="col" | Site<br> | ||
Revision as of 14:03, 10 June 2011
Small wind turbines generally have a lower energy output than large commercial wind turbines, but their size can differ significantly: So called Micro wind turbines may be as small as a fifty watt generator and generate only about 300 kWh per year. They are used for boats, caravans, miniature refrigeration unit, but also for fence-charging and other low-power uses. In comparison to that household-size turbines reach diameters of 9-meter, can have a rated power of 20kW and produce about 20000 kWh per year for homes, farms, ranches and small businesses.[1]
Small units often have direct drive generators, Direct current output, aeroelastic blades, lifetime bearings and use a vane to point into the wind. Larger, more costly turbines generally have geared power trains, alternating current output, flaps and are actively pointed into the wind. Direct drive generators and aeroelastic blades for large wind turbines are being researched.[2]
Small wind turbine technology
Nearly all small wind turbines today are upwind, horizontal-axis turbines, which means the rotor is spinning in front of the tower. There are some turbines using two blades, while the majority of the recent turbines comes supplied with a three-blade rotor, which in general terms makes the turbine run more smoothly and last a longer time. The prevalent blade materials are composite materials as fiberglass, while only a few products in this class still use wood. Instead of the yaw motors of the big wind turbines, small wind turbines often use tail vanes to point the rotor to the wind.
Because of the sometimes demanding environmental conditions, the robustness of a turbine is a very important parameter, which can be estimated only very roughly: Experience has shown, that the weight of the turbine in relation to the area swept by the rotor can be used as a criterium. For example a turbine with a relative mass of 10 kg/m2 should be more robust than a turbine with 5 kg/m2.[3]
Common applications
Village Power: Potable Water
Small mechanical wind turbines have been used to drive pumps for potable water for a very long time. Today small electric wind turbines are a efficient alternative which can be used to supply people and livestock with underground water from a well. Creating a village water tap eliminates the need to carry water from distant sources and using underground water generally avoids common health problems. The size and capacity of the needed generator is proportional to population served and pumping height. For example a turbine with a capacity of 1 kW can supply approximately 200 people.[4] An example for this application is given in the following table.
| Site |
Application |
Equipment |
Performance |
Cost |
Installation |
|---|---|---|---|---|---|
| Niama, Morocco |
Community Water Supply |
Two Sites: 10 kW Wind; 18 & 24 m Towers; 15 & 26 Stage Submersible Pumps |
70 m3 & 30 m3 of Water per Day |
~$100.000, Including Tech. Assist. and Training, US-AID Funded |
February 1990 |
| Results: Supplies 4,000 people with 220% more water than original diesel pumps. Population decline has been reversed. | |||||
Village Power: Productive uses
Examples for productive uses rural areas are irrigation, agroprocessing or ice-making. Small wind systems can be an excellent foundation for electrification, which at the same time increases income and chances for cost recovery of the system. The previously mentioned uses require more energy than pumping for drinking water. A turbine with a 1 kW generator can approximately support the work of 10 people in this case.[5]
| Site |
Application | Equipment |
Performance |
Cost |
Installation |
|---|---|---|---|---|---|
| Oesao, Timor, Indonesia |
Small plot irrigation | 1.5 kW Wind Turbine with 18m Tower; 10 Stage Pump |
~ 150 m3 of water per Day |
~$11,000 |
July, 1992 |
| Results: ~ 25 Additional Systems Installed, JICA & US-AID Funding | |||||
Village Power: Pre-Electrification
Pre-electrification means installing a small source of electricity for basic needs like lighting. Thus the costs for candles, kerosene or dry-cell batteries can be safed. The systems often work with micro wind turbines (25-120 Watts per household), have no grid connection, but generate a direct current that can be used for charging batteries. High efficiency fluorescent bulbs are often used to make the most advantage from the small lighting systems.
| Site |
Application |
Equipment |
Performance |
Cost |
Installation |
|---|---|---|---|---|---|
| Tomenas, Timor, Indonesia |
Battery Charging Station |
7.5 kW BWC Wind Turbine with 30m Tower |
Charges batteries for ~40 homes, plus powers productive uses (freezers, shop tools) |
~$60,000 |
1997 |
| Results: Sustainable electrification which costs each family ~$2.40 per month. | |||||
References
- ↑ Gipe P. (1999) Wind Energy Basics - A Guide to Small and Micro Wind Systems, Chelsea Green Publishing Company
- ↑ Wikipedia (2011) Small Wind turbine, Retrieved 9.6.2011
- ↑ Gipe P. (1999) Wind Energy Basics - A Guide to Small and Micro Wind Systems, Chelsea Green Publishing Company
- ↑ Bergey M. (2000) Small Wind Systems for Rural Energy Supply, Village Power 2000, Bergey WindPower Co.
- ↑ Bergey M. (2000) Small Wind Systems for Rural Energy Supply, Village Power 2000, Bergey WindPower Co.
