Difference between revisions of "Underground tank"
(→Construction, operations and maintenance) |
(→Construction, operations and maintenance) |
||
Line 28: | Line 28: | ||
==Construction, operations and maintenance== | ==Construction, operations and maintenance== | ||
− | Consider five main factors when designing your underground tank. | + | Consider five main factors when designing your underground tank.<br> |
− | '''1. Seepage''' | + | '''1. Seepage'''<br> |
− | It is very important to store rainwater and not to lose it! The tank should have a durable, watertight, opaque exterior and a clean, smooth interior. Below ground tanks must also be plastered well and correctly installed, otherwise they can collapse. | + | It is very important to store rainwater and not to lose it! The tank should have a durable, watertight, opaque exterior and a clean, smooth interior. Below ground tanks must also be plastered well and correctly installed, otherwise they can collapse.<br> |
− | '''2. Evaporation''' | + | '''2. Evaporation'''<br> |
− | All storage tanks should have a roof made from locally available materials. A tight fitting top cover prevents evaporation, mosquito breeding and keeps insects, rodents, birds and children out of the tank. A suitable overflow outlet(s) and access for cleaning are also important. | + | All storage tanks should have a roof made from locally available materials. A tight fitting top cover prevents evaporation, mosquito breeding and keeps insects, rodents, birds and children out of the tank. A suitable overflow outlet(s) and access for cleaning are also important.<br> |
− | '''3. Length of the dry spell''' | + | '''3. Length of the dry spell'''<br> |
− | This is important in determining the size and number of tanks to be constructed. The longer the dry spells the more water you would need. Sometimes sophisticated calculations are involved, but these tend not to take into account human behaviour and the willingness to use water if it is available and not to conserve it for future use, in the hope that the dry spell will soon be over. | + | This is important in determining the size and number of tanks to be constructed. The longer the dry spells the more water you would need. Sometimes sophisticated calculations are involved, but these tend not to take into account human behaviour and the willingness to use water if it is available and not to conserve it for future use, in the hope that the dry spell will soon be over.<br> |
− | '''4. Daily usage''' | + | '''4. Daily usage'''<br> |
− | This is related to the above factor but ensure that the crops are hardened to withstand some stress during the dry spell. Determine how much area you would want to save in case of a very long dry spell lasting more than three weeks. | + | This is related to the above factor but ensure that the crops are hardened to withstand some stress during the dry spell. Determine how much area you would want to save in case of a very long dry spell lasting more than three weeks.<br> |
Revision as of 19:06, 13 April 2012
Where access to groundwater is limited, rainwater harvesting in underground tanks can be an effective and low-cost alternative. Water stored in the wet season can be used in the dry season and lifted from the tank with a rope pump or with a deep well pump, which can elevate water up to 30 m.
These tanks can be constructed of concrete blocks. The tanks are partly (1.5 m) built below the soil surface. These tanks can store up to 20 000 liters of water, used for domestic use, cultivation.
With regard to the concrete block tanks, 40 community water tanks (supporting a few families each) were implemented successfully. Following this success, another 80 concrete block tanks will be build at household level.
Practica foundation is testing various options for low-cost storage and groundwater recharge like the "Reed cement tank" and the "Tube recharge".
Suitable conditions
The area should be suitable for rainwater harvesting. Depending on the design the capacity of the tank varies from 3 500 to 20 000 liters.
Advantages | Disadvantages/limitations |
---|---|
- Low cost alternative to metal or ferrocement tanks. - Good for areas where ground would otherwise be permeable. |
- Sub-surface tanks often cannot hold enough water for whole dry season. Making bigger berkeds is possible but more difficult and cost is high (unaffordable tank is not replicable on larger scale). - Flotation of the tank may occur in areas with a high groundwater table. |
Construction, operations and maintenance
Consider five main factors when designing your underground tank.
1. Seepage
It is very important to store rainwater and not to lose it! The tank should have a durable, watertight, opaque exterior and a clean, smooth interior. Below ground tanks must also be plastered well and correctly installed, otherwise they can collapse.
2. Evaporation
All storage tanks should have a roof made from locally available materials. A tight fitting top cover prevents evaporation, mosquito breeding and keeps insects, rodents, birds and children out of the tank. A suitable overflow outlet(s) and access for cleaning are also important.
3. Length of the dry spell
This is important in determining the size and number of tanks to be constructed. The longer the dry spells the more water you would need. Sometimes sophisticated calculations are involved, but these tend not to take into account human behaviour and the willingness to use water if it is available and not to conserve it for future use, in the hope that the dry spell will soon be over.
4. Daily usage
This is related to the above factor but ensure that the crops are hardened to withstand some stress during the dry spell. Determine how much area you would want to save in case of a very long dry spell lasting more than three weeks.
Maintenance
- Removal of debris and overhanging vegetation from gutters and the roof (preventing stagnation of water in the gutters) is required. Physical inspection and repairing cracks with cement is also needed.
- Basic water quality testing is recommended during the first year, with further testing when water quality is in doubt. E.g. the 'HACH' pillo test, costing about US$ 1 per test. Treatment to manage microbiological quality is also recommended.
Costs
- Material costs for EMAS tanks consist of sand and four 50 kg bags of cement for each tank.
- Subsurface ferrocement tanks of 60 m3 costs about US$ 1,900.
- Underground tanks can be high and variable in cost per m3 of storage (averages around US$30-40 per m3 of storage, sometimes a lot more depending on various factors). Sub-surface hemispherical tanks made from stone masonry and bricks/cement in Ethiopia cost in the range of 113 - 219 Euro per m3 of storage including all costs such as trucked water for construction and solidity of construction (more solidly built tanks in clay areas cost more). Therefore costs currently limit the replicability of the technology for poorer families and potential to scale things up.
Field experiences
The Brazilian government, with support from organisations such as UNICEF and IRCSA (International Rainwater Catchment Systems Association) started a programme to construct one million rainwater tanks in Brazil.
Reference manuals, videos, and links
This Underground tank installation Manual by Tankmasta explains all the steps needed to build an underground tank.
- Video: Large collection of EMAS movies on different subjects.
- General www.rainwaterharvesting.org www.unep.or.jp www.rainfoundation.org
- Recharge www.practicafoundation.nl
- Storage www.emas-international.de