Drip irrigation was used in ancient times by filling buried clay pots with water and allowing the water to gradually seep into the soil. Modern drip irrigation began its development in Germany in 1860 when researchers began experimenting with subirrigation using clay pipe to create combination irrigation and drainage systems. In 1913, E.B. House at Colorado State University succeeded in applying water to the root zone of plants without raising the water table. Perforated pipe was introduced in Germany in the 1920s and in 1934, O.E. Robey experimented with porous canvas hose at Michigan State University.
With the advent of modern plastics during and after World War II, major improvements in drip irrigation became possible. Plastic microtubing and various types of emitters began to be used in the greenhouses of Europe and the United States. A new technology of drip irrigation was then introduced in Israel by Simcha Blass and his son Yeshayahu. Instead of releasing water through tiny holes, blocked easily by tiny particles, water was released through larger and longer passageways by using friction to slow water inside a plastic emitter. The first experimental system of this type was established in 1959 in Israel by Blass, where he developed and patented the first practical surface drip irrigation emitter. This method was very successful and subsequently spread to Australia, North America, and South America by the late 1960s. In the United States, in the early 1960s, the first drip tape, called Dew Hose, was developed by Richard Chapin (first system established at 1964). [1]
Components and Operation
Drip irrigation systems may be manually operated or may be operated by a controller with electric or hydraulic valves.
Most large drip irrigation systems employ some type of filter to prevent clogging of the small emitter flowpath. New technologies are now being offered that minimize clogging. Some residential systems are installed without additional filters since potable water is already filtered at the water treatment plant. Virtually all drip irrigation equipment manufacturers recommend that filters be employed and generally will not honor warranties unless this is done.
Because of the way the water is applied in a drip system, traditional surface applications of timed-release fertilizer are sometimes ineffective, so drip systems often mix liquid fertilizer with the irrigation water. This is called fertigation; fertigation and chemigation (application of pesticides and other chemicals such as chlorine or sulfuric acid) use chemical injection equipment such as diaphragm pumps, piston pumps, or venturis. The chemicals may be added constantly whenever irrigating or at intervals. Fertilizer savings of up to 90% are being reported from recent university field tests using drip as compared to spraying.
If properly designed, installed, and managed, drip irrigation may help achieve water conservation by reducing evaporation and deep drainage since water can be more precisely applied to the plant roots, when compared to other types of irrigation such as flood or sprinkler irrigation. However, there have been a number of poorly designed and/or managed systems that have been expensive, colossal failures. In addition, in regions where water supplies are severely limited, there may be no actual water savings, but rather an increase in production while using the same amount of water as before. In very arid regions or on sandy soils, the trick is to apply the irrigation water as slowly as possible.
Drip irrigation is used by farms, commercial greenhouses, and residential gardeners.
Garden drip irrigation kits are increasingly popular and consist of a timer, hose and drippers.
Advantage of Drip Irrigation
It is defined as the precise, slow application of water in the form of discrete or continuous or tiny streams of miniature sprays through mechanical devices called emitters or applicators located at selected points along water delivery lines.
It is also called trickle irrigation. Drip irrigation is adopted extensively in areas of acute water scarcity and especially for crops such as Coconut, Grape, Banana, Ber, Citrus, Sugarcane, Cotton, Maize, Tomato, Brinjal and plantation crops. The advantages of drip irrigation are:
- No fertilizer nutrient loss due to localized application.
- High water distribution efficiency.
- Levelling of the field not necessary.
- Only root zone is saturated.
- Moisture always at field capacity in the root zone.
- Soil factor plays less important role in frequency of irrigation.
- No soil erosion.
- Highly uniform distribution of water i.e., controlled by each nozzle.
- Low labour cost.
- Variation in supply can be regulated by regulating the valves and drippers.
- Fertilisation can be included with drip irrigation.
The disadvantages of drip irrigation are:
- Expense. Initial cost can more than overhead systems.
- Waste. The plastic tubing and "tapes" generally last 1-3 seasons before being replaced.
- Clogging.
- Plant Performance. Studies indicate that most plants grow better when leaves are wetted as well.
See also
References
- Irrigation, 5th Edition, Claude H. Pair, editor, published by the Irrigation Association, 1983
- Trickle Irrigation for Crop Production, F.S. Nakayama and D.A. Bucks, editors, published by Elsevier, 1986, ISBN 0-444-42615-9
- S. Blass, Water in Strife and Action (Hebrew), published by Massada limited, Israel, 1973
External links