Traditional hand-dug wells

Revision as of 00:14, 12 April 2012 by Winona (talk | contribs) (Reference manuals, videos, and links)

Revision as of 00:14, 12 April 2012 by Winona (talk | contribs) (Reference manuals, videos, and links)

These are shallow wells which draw water from a natural aquifer or man-made aquifer, e.g. near sand dam or around ponds, but which are not located inside a riverbed. It can include wells that are far from a river, or wells that receive water from shallow aquifers hydraulically connected to the river. Sometimes the holes dug are very large, allowing people and sometimes animals who are able to walk into the well to where the water is located.

Suitable conditions

  • Layers of sand and gravel tend to provide good locations for wells and boreholes. Other good locations are in weathered rock in granite areas, along the edges of valleys in mountainous areas or in a river valley where there may be sandy deposits under the banks.
  • Care should be taken to avoid siting wells in perched aquifers (shallow aquifers with limited recharge capacity and water storage).

Avoid contamination

Site wells at a sufficient distance away from sources of contamination. For microbiological contamination, the distance from the source of contamination (e.g. latrine) to the water intake (screen) needs to be sufficient so as to pose a “low” to “very low” risk – this translates into a minimum of 25 days of potential travel of pathogens in the ground. Travel time is influenced by porosity, hydraulic conductivity (permeability) and hydraulic gradient. For medium size sand with an average porosity, the distance equivalent to 25 days is around 30 metres, but this can increase to over 100 metres for coarser sediments. However, the distance from contamination to water intake can reduce significantly where the screen intake is at a sufficient depth – this is due to greater variation of aquifer properties in vertical directions than lateral, meaning that a borehole with handpump could be placed very close to a latrine with low risk. However, screen depth must increase with increased extraction rate.

Advantages Disadvantages/limitations
- Manual access, that can be deepened or maintained easily at a later date

- Can be privately owned/operated
- Circumstances which make the construction of large diameter wells necessary:

  1. Inability to obtain or maintain pumps or special buckets necessary for small diameter wells
  2. Water lifting device requires more space (than is available in a small diameter well), e.g. continuous chain and buckets
  3. Desire to improve or repair existing large diameter wells
  4. Where the aquifer (water storage) is of extremely low permeability
  5. Low cost labour and skills are available
- Greater effort and longer construction time

- Greater safety hazards during and after construction
- Difficulty in preventing contamination
- Generally lower rate of inflow for the effort involved
- Smaller wells can dwindle in supply during long dry periods and heavy use, especially in perched aquifer areas
- All disadvantages related to handpumps also relate to boreholes, including operation and maintenance issues, lack of ownership, and spare parts availability
- Hand-dug wells near a river can be contaminated by pollution from agricultural runoff in river water
- High cost of construction ($1,000 USD or more) – due to construction materials and labour to make a well (about 1 month depending on depth and ease of digging)
- Can be difficult to sink to required depth especially in areas of flowing sand
- Water levels in the aquifer can drop over time, resulting in possible mining (where aquifer is compressed and cannot hold water any longer afterwards)


Construction, operations and maintenance

Hand-dug wells have a tendency to have very little water or even dry up in the dry season. This is largely to do with the fact that the intake area is not deep enough inside the dry season water table. Shallow aquifers tend to reflect recharge more sharply than deeper aquifers, resulting in water table fluctuations of several metres between seasons – these fluctuations need to be accounted for in the construction method. Several techniques can ensure that wells are sunk deep enough:

  • Construct wells using a telescopic system, where an a permanent lining is created above the water table, together with a smaller diameter telescopic lining that enters the water table. The advantage of this system is that the smaller lining can be deepened at a later date without affecting the permanent lining and slab, e.g. in case the well was not sunk deep enough the first time. Another advantage is that the shaft has less chance to go out of vertical alignment during caissoning (where a shaft is sunk by digging).
  • Use an effective method of de-watering during caissoning within the water table. Many hand-dug wells are dug without using a de-watering pump – consequently, the limit of penetration into the water table is about only 1 metre. Providing a de-watering pump will allow the shaft to be sunk deeper into the water table, but note:
  1. Type of pump depends on the height from ground level to water table – for a suction pump, the limit will be 6-7 metres, after which a submersible pump and generator needs to be considered. The type of pump should allow a certain amount of solid particles to be pumped.
  2. Attention needs to be given to safety considerations when using a motorized pump with someone digging in the well – engines should be located downwind so fumes do not enter the well, a 100 – 150mm vent pipe can be temporarily tied to the crossbeam to ventilate the well (in similar way to a VIP latrine), submersible pumps should be fitted with circuit breakers in case of electrical shortcuts to avoid electrocution, digger should be wearing construction harness attached to rope, and rescue & recovery action should be in place and practised regularly.
  • Where using a de-watering pump results in subsidence around the well (in the case of flowing sands), another idea is to use a bailer instead of a pump. A bailer is normally used in percussion drilling, and consists of a heavy hollow metal tube with a valve on the bottom. When the bailer is dropped, sediment enters which does not come out when the bailer is removed. This method takes longer, but can be performed at ground level without a de-watering pump – since the water is not being pumped, flowing sand has less incentive to enter and the well shaft can sink slowly.
  • Aim to dig wells during the latter half of the dry season when water table will be at their lowest.

Where deepening the well further is not possible due to water/sand ingress, jetting in the bottom of the well can provide a means of faster recharge into the well from deeper in the aquifer, meaning the well dries up less quickly. In this case a larger diameter screen (can be wrapped with geotextile) is jetted into the well base with the end protruding above the bottom of the well, after which it is plugged using a small bag of gravel.

Where wells still dry up in the dry season, recharge techniques could be used upstream of the well.

The use of porous concrete in part of the section of the well shaft which is underwater can help increase flow velocity into the well. Porous concrete is made using a of 1 : 1 : 4 (cement : sand : aggregate) and can be used for curved blocks or also for a central portion of any pre-cast concrete ring. Also perforated pointed steel pipes can be driven horizontally into the aquifer using a jack – this can also increase flow velocity into the well.

Simplify construction methods while getting a more robust end product in a safer fashion. Using lining & telescopic lining has the advantage that heavy lifting equipment for pre-cast rings is obsolete while procedures are inherently safer. Lining is made using one-skin moulds that hold concrete against the dug wall of the hole, while the telescopic shaft can be made from curved blocks built onto a foundation cutting ring – the blocks can be extended as and when necessary.

Costs

Field experiences

Reference manuals, videos, and links

Acknowledgements

  • CARE Nederland, Desk Study Resilient WASH systems in drought prone areas. October 2010.
  • Collins, Seamus, Hand dug shallow wells (SKAT). Swiss Centre for Development Cooperation in Technology and Management.