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Drip Irrigation - Pepsi and Nica

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Field experiences
__NOTOC__<small-title />[[Image:Pepsi_drip_icon.png‎|right|80px]][[Image:Nica_drip_icon.png‎ ‎|right|80px]][[Image:Pepsi_drip.PNG|thumb|right|300px200px|Pepsi drip. Low cost plastic hose, used for drip irrigation.]][[ImagePhoto:Nica_drip.PNG|thumb|right|300px|Nica drip system working with 1 m pressure and made of local produced plastic hoseNetherlands Water Partnership.]]
Drip irrigation provides farmers the most efficient way to grow crops in water scarce areas through providing water at a controlled and regular rate to the root zone. Historically it has been too expensive for small-plot farmers, but now it is available at low cost and also adapted for small-scale farming and can reduce water losses by 30 - 70% when compared to conventional methods of crop irrigation, while greatly reducing labour and accurately delivering fertilizers. This makes cultivation during the dry season possible, with resulting yield increases of up to 30%. Drip irrigation is thus less vulnerable to drought than other irrigation systems.
To make drip irrigation affordable for small farmers, the [[Chapin ]] bucket or IDE bucket and drum kits were developed and are now being promoted in many countries. A bucket kit costing US$ 5 can irrigate 25 m2 and a drum kit five times as much. Based on this principle, farmers in India started to make their own drip system, made of plastic hose that is normally used to package ice-lollies. Hoses can only be used for one growing season (generating plastic waste) but investment costs are so low that it is not a risk for poor families to invest in it. This technology now more or less promotes itself.
'''Easy drip irrigation''' is an improvement of the Pepsi drip that consists of sun resistant lay-flat hoses and micro tubes that have a lifetime of 1-2 years. This option is being developed by IDE and applied in Asia. Practica foundation is testing different options in Nicaragua, Tanzania, Zambia and Ghana.
===Suitable conditions ===
* Drip irrigation is often the favoured method of irrigation, for example on steep and undulating slopes, for porous soils, for shallow soils, fields having widely varying soils, where water is scarce, where water is expensive, and where water is of poor quality.
* Drip irrigation is suitable for any plot under 0.4 hectare (one acre), but their modular design allows for expansion above that.
* The Pepsi drip has a capacity of 0.1 - 2 ha.
{{procontable | pro=
- Reduces water consumption. <br>
| con=
- Hoses have a short lifetime (generating plastic waste).<br>
}}
{| border="1" cellpadding="5" cellspacing="0" align="center"|-! width="50%" style="background:#efefef;" | Advantages! style="background:#f0f8ff;" | Disadvantages|-| valign="top" | - Reduces water consumption. <br>- Storage tanks do not have to be elevated. <br>- Uses commonly extruded plastic pipes, so low-cost systems are replicable in many countries.<br>- Salt concentration in root zone is reduced due to regular application of water.<br>- Improved yields and quality of crop due to regular watering intervals: plants have better metabolism and produce a better quality / more numerious crop.<br>- Roots develop well when using drip irrigation: great soil-air-water ratio for root respiration (good for cash crops too).<br>- Labour-saving.<br>- Saves fertilizer.<br>| valign="top" | - Hoses have a short lifetime (generating plastic waste).<br>- Possibilities of theft.<br>- Damage by rodents.<br>|} <br>[[Image:Nica_drip.PNG|thumb|right|200px|Nica drip system working with 1 m pressure and made of local produced plastic hose. Photo: Netherlands Water Partnership.]] ===Construction, operations and maintenance===[[Image:ChapinBucketSystem.jpg|thumb|right|200px|The Chapin bucket drip system.]][[Image:DrumIrrigation.jpg|thumb|right|200px|Pouring water into the drum for drip irrigation.]] Drip irrigation systems consist of water storage, water filtration, water conveyance and distribution, and water application sub-systems. Common preparation requirements and features are as follows:* Prepare the area to be irrigated. This could be simple land preparation or involve the formation of planting beds.* For best results, drip systems are used to irrigate level beds. If the drip tubes go uphill, downhill or around corners, the system will not give equal water flow from each dripping outlet.* Construct the water container stand. Ensure that it can support the weight of the container and water when full.* Mount the water container on the stand so that the water outlet is at the height necessary to provide the water pressure required to operate the system.* Mount the container water outlet, water filtration and flow regulator fittings. * Lay the water distribution system components that connect the water container to the individual drip lines. Make sure that the open ends are closed to avoid foreign material entering the pipe. * Unroll the drip lines and lay them along the full length of each row of plants to be irrigated. * Connect the drip lines with the water distribution system (header pipes). * Flush the system to remove any foreign matter that may have entered the pipeline. * Close the end of the drip lines. It must be emphasized that any training or advice on the use of drip kit systems should not only cover actual kit installation and maintenance, but also all aspects of growing vegetables under drought conditions since the purpose is to increase farmers’ yields. Thus training and advice should include lessons about bed preparation and composting, transplanting, irrigation-water management and pest and disease control. ====Save money and other considerations====
Use the most economical system possible that will give results. [http://www.ideorg.org/OurTechnologies/DripIrrigation.aspx# iDE] in Cambodia lowered the cost of drip systems by:<br>
#Replacing conventional emitters with holes and micro tubes.
# Reducing cost of water storage – the use of a hanging plastic water storage bag also lowers the cost. Experience shows that costs are reduced by three quarters by doing this, resulting in cost of about US$5 for a 200 litre bag that will cover 20 m2.
* The water tank capacity should be equal to one day retention of the daily water requirement. It should be placed at sufficient height to allow flow by gravity – approximately 1 metre height for an area of 100m2, 1.5 metres for 500 m2, and 2 metres for 1,000m2.
* A filter is needed prior to water entering the pipes in order to keep them clean from clogging.
* Pipes vary in size and are made from varieties of polyethylene (PE) and soft PVC.
* The emitter is the most important part of a drip system because it delivers water at the desired rate to the plant and maintains water application uniformity over the entire irrigated area. An emitter should match particular field conditions including type of crop, spacing of the plants, terrain, water requirement, water quality, operating time and pressure head. At the same time, the emitters cause the most problems through blockages (particles, salts or algae) and need to be maintained.
* Try to bury main pipes underground to reduce visibility for theft.
 
====Water management tips====
* Maintain an optimum soil-moisture regime by applying the required amount of water at the right frequency. Shallow sandy soils require more frequent (1–2 day interval) irrigation; deep clay loam soils allow less frequent (3–7 day) irrigation.
* During the early stages of crop growth the plant roots are shallow and therefore there is a need for more frequent irrigation and less water per irrigation event.
* During the flowering or late vegetative stage of the crop, water consumption is highest so an adequate water regime is vital. Ensure that the crop does not experience moisture stress during this period.
* Crop water use will vary from 3 to 7 mm/ day. Ensure that adequate amounts (depending on the area and crop growth stage) are applied.
* All leaks should be mended quickly to prevent water wastage.
 
====Maintenance====
Ensure that only clean water is used in order to minimize the chances of clogging the filtration system. A filter screen will keep coarse particles from entering the drip lines. If there is fine silt in the water, or blowing sand in the air, a piece of cloth can be tied over the top of the bucket. Water can be poured through the cloth to keep the fine particles from entering the bucket.
* Clean the filtration system at least twice a month.
* Inspect the emitters to identify clogged emitters at least once a week and unblock or replace any clogged emitters. Clogged drip emitters cause non-uniform application of water and result in non-uniform growth of the plants.
* Flush the system at least once a month. The frequency can be increased or reduced depending on the amount of impurities in the irrigation water.
* Check and repair leaks frequently.
* Take extra care during field operations, particularly weeding, to avoid cutting the drip lines.
* Take precautions to minimize the destruction of drip lines by termites and rodents.
* When no longer in use, uninstall the components of the system and store them in a safe place.
====Estimated Lifespan====
Pepsi drip: 1-2 years<br>Nica drip: 3-5 years.
==Cost=Costs===* Cost/ha: Pepsi drip: US$ 60 (plastic hose only). Easy drip: US$ 200 ­ ­to 400.
* Nica drip: (Nicaragua) US$ 300 to­ 600, depending on crop and material use.
* In Nepal, costs ranged between $0.11 and $0.17 per m2 of irrigated area, depending on the scale of irrigation.
===Field experiences===* Zimbabwe study[[Image:solar market garden.jpg|thumb|right|250px|Solar Market Garden project hooks up solar panels to a drip-system. Photo: [http://wwwself.google.comorg/url?sa=t&rct=j&q=&esrc=s&source=web&cd=2&ved=0CF4QFjAB&url=http%3A%2F%2FwwwSolar Electric Light Fund.icrisat.org%2Fjournal%2Fvolume5%2Faes%2Faes3.pdf&ei=or6IT_v6F4SRiQKtttjRCw&usg=AFQjCNGn3_ShgoWdh07v0N9SF3hjGVo94Q&sig2=hTcIVLO36LI3yuvdDXmGlg Can drip irrigation improve the livelihoods of smallholders? Lessons learned from Zimbabwe].]]
* Zimbabwe study: [http://oar.icrisat.org/2386/1/Can_drip_irrigation_improve1.pdf Can drip irrigation improve the livelihoods of smallholders? Lessons learned from Zimbabwe].<br>{|style="border: 2px solid #e0e0e0; width: 20%; text-align: justify; background-color: #e9f5fd;" cellpadding=Reference manuals"2"<!--rsr logo here-->|- style="vertical-align: top"|[[Image:akvorsr logo_lite.png|center|60px|link=http://akvo.org/products/rsr/]]<!--project blocks here-->|- style="vertical-align: bottom"|[[Image:project 819.jpg |thumb|center|140px|<font size="2"><center>[http://rsr.akvo.org/project/819/ RSR Project 819]<br>Water, Food & Sanitation for School + Community</center></font>|link=http://rsr.akvo.org/project/819/]] |} <br>====Solar Market Garden Project====For the first time, women farmers in the rural villages of Bessassi and Dunkassa, in northern Benin, are able to grow vegetables and fruits during the six month dry season, improving food security and nutrition for themselves and their families. Farmers are also increasing their income by selling excess crops in the market. Now entering its third year, [http://web.stanford.edu/group/solarbenin/data/SolarMarketGardenInfo/Solar%20Market%20Garden.pdf SELF's Solar Market Garden project] has proved that solar energy can provide long term solutions to hunger, malnutrition and poverty in developing nations. In addition, since December 2010, the villagers of Bessassi and Dunkassa now have access to clean drinking water via water wells powered by custom arrays of solar-panels ranging from 1.2 - 4 kW. This particular combination is not only a long-term solution, but can also be replicated all over the African continent. ====Scampis micro-irrigation project====The IFAD-supported Scampis project (2009–2012) changed the lives of 30,000 vulnerable farmer households after they adopted low-cost, user-friendly technologies. Old flip-flop sandals were collected by otherwise unemployed people and used as material to make parts for micro-irrigation equipment in Madagascar. As well as providing a local source of materials for irrigation, this activity promoted recycling and created jobs for street workers who collect the old sandals, and for small businesses that make the irrigation parts. ===Manuals, videos, and links===
* This [http://www.arrakis.nl/reports/ShortManual_drip_irrigation_June_07_lr.pdf Drip Irrigation manual] is set up by Arrakis.
* [http://www.cgiar.org/iwmi wwwconsortium-news/micro-irrigation-beats-hunger/ Micro-irrigation shows new ways to beat hunger.cgiar] CGIAR, August 2011.org/iwmi ] * [http://www.ideorg.org www/OurTechnologies/DripIrrigation.ideorgaspx An Entryway Into High Value Produce Markets.org ] iDE. ====Videos==== {| style="border:1px solid #fofofo; font-size: 125%"|-|{{#ev:youtube|9DfdtG6Yf14|200|auto|On the Farm: <br>Drip Irrigation Technology}}|{{#ev:youtube|uWNlDKxRMmk|200|auto|Drip irrigation in Sugarcane - <br>A Successful Erode farmer}}* [http|{{#ev://www.practicafoundation.nl www.practicafoundation.nl]youtube|o7v_zC0LNw0|200|auto|Growing Corn with <br>Drip Irrigation by NDJ}}|}
===Acknowledgements===* CARE Nederland, Desk Study: [[Resilient WASH systems in drought-prone areas]]. October 2010.
* Sijali, Isaya V. [http://www.samsamwater.com/library.php?cat=irrigation Drip Irrigation; Options for smallholder farmers in eastern and southern Africa]. Sida’s Regional Land Management Unit, 2001.
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