Indian family makes a breakthrough in hydroponics

by Mike Adams

Hydroponics, the practice of growing plants in water instead of soil, received a giant lift from a New Delhi family that created a purely organic nutrient mix that has sustained tomatoes and Arjun.

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An Indian hobbyist has created a purely organic nutrient mixture for growing plants in water. Although it is still an evolving science, hydroponic agriculture (growing plants in water solution rather than soil) is spreading fast the world over. The nutritional requirement of the plants in this system of soilless farming is met by the nutrient mixtures, called hydroponics fertiliser mixtures, added to the water in which the plant roots are kept submerged. These mixtures are made of chemical plant nutrients. A breakthrough has now been achieved by an Indian hydroponics hobbyist in creating a purely organic nutrient mixture for growing plants in water. This wholly chemical-free plant growth solution has been tested successfully for growing several plants, including common vegetables like tomato and arbi and some high value medicinal plants like Brahmi, Arjun and Cineraria. Indeed, a good deal of research is underway in this system of soilless farming in the US and Europe but not much headway has been made anywhere in organic hydroponics. Of course, some hydroponics enthusiasts abroad have been experimenting with various kinds of organic manures and mixtures of plants, but successful and commercially viable organic hydroponics models are still not available. His daughter, Shweta Singh, a Delhi University botany student, has been assisting him in discovering and further improving the biofertiliser mixture for growing plants in ordinary water. “I will work on it for a couple of years more before thinking of launching commercial production of this bio-fertiliser for hydroponics. However, if some government organisation, such as the Indian Council of Agricultural Research (ICAR), comes forward, I am willing to cooperate with it in promoting organic hydroponics in India,” he says. He believes that nearly 200 commercially important plants can be grown by hydroponics technique.

Source: Article taken from Natural News, only for information purpose

Hydroponics-A Wonder of Modern Science

Asad Manzoor

Department of Agriculture & Agribusiness Management, University of Karachi

Email: asad@gardener.com

Truly a greatest wonder of modern science – the hydroponic, hydroponic farming technique produce abundant harvests of fruit, vegetables, grains, herbs and flowers in places never before able to sustain growth, deserts of the earth turn into oasis of vegetables and herbs. Hydroponic farms produce the healthiest crops with the highest yields and vitamin content due to their absolutely balanced nutrient by mean of nutrients solutions. Modern hydroponic methods and techniques supply food for millions of hungry people worldwide and also supply you, me and the food service industry with high superior quality produce. In truth, hydroponic cultivation is so effective; hydroponic cultivation is now moving to be a necessary part of modern day life like NASA has devised an advanced method of hydroponics for use in outer space. The science and art of hydroponics or soilless farming start with experimentation into determining the basic elementary composition of plants. These experiments not only story of present day, experiments have been dated as early as 1600 A.D., on the other hand, historical records show that plants have been cultivated in soilless mixtures of sand and gravel even earlier. Historically the hanging farms of Babylon and the floating farms of the Mexican Aztecs are wonderful examples of premature hydroponic faming..

The word of "Hydroponics" was first time coined by Dr. W.F. Gericke in 1936 to explain the cultivation and farming method of both edible and ornamental plants in a solution of water and dissolved essential micro and macro nutrients. The word Hydroponics is derived from the Greek "Hydro"- meaning water, and "Ponos"- meaning labor. In hydroponic method of cultivation, plants are provided with the essential nutrients required for growth by a “nutrient” solution which is principally nutrient enriched mineral water. This nutrient solution can be distributed through circulation around the roots by either the passive force of gravity or the active force of an electromechanical pump. Some hydroponic systems remain bath the roots in nutrient solution and use an aquarium air pump to oxygenate the solution.

Plants grown hydroponically are healthier than their soil grown counterparts because they receive a perfectly balanced diet and do not come in contact with soil-borne pests and diseases. In soil plant compete with plants, weeds and other flora of the field, while in hydroponics farming plant feed without any competition and received maximum nutrients on perfect time of every growth stage. Super efficient hydroponic systems produce high yield by preventing evaporation and runoff. Arid regions and deserts where water is scarce can now grow crops with hydrofarming. Hydroponics systems deliver water and nutrients directly to the plant, crops can be grown closer together without spacing each other and healthier plants add to a higher yield. By growing crops in a hydroponics system saves the costs of soil preparation, insecticides, fungicides and losses due to drought and ground flooding.

Pakistan face serious crises of food and vegetables, the production of edible vegetable not increase significantly while demand increase day by day, due to low production, prices of vegetables increase significantly. The only sustainable solution of this crises is to adopt hydroponic farming, even initial cost is high to setup a hydroponics system, on the hand other hand system is durable and high productive for long time.

What is hydroponics?

Hydroponics is a technology for growing plants in nutrient solutions (water containing fertilizers) with or without the use of an artificial medium (sand, gravel, vermiculite, rockwool, perlite, peatmoss. coir, or sawdust) to provide mechanical support.

Liquidhydroponic systems have no other supporting medium for the plant roots: aggregate systems have a solid medium of support. Hydroponic systems are further categorized as open (i.e. once the nutrient solution is delivered to the plant roots, it is not reused) or closed (i.e. surplus solution is recovered, replenished, and recycled). Hydroponic growing (as opposed to soil growing) allows you to control the nutrient levels for your plants directly. Because of the higher control over nutrients, hydroponically grown plants generally have a much higher yield than similar plants grown in soil.

A plant gets its food source by turning Co2, light and water (or hydrogen) into carbohydrates through a process called photosynthesis. With hydroponics growing, plants are grown without soil so they must get their nutrients from the nutrient solutions added to water. The absence of soil in growing means that hydroponics systems must have some way of supporting the plants while still allowing the bare root system maximum exposure to the nutrient solution. Often a “growing medium” is used for support and to aid in moisture and nutrient retention in hydroponics growing. Because they lack media to store water and nutrients, water culture systems need a continuous flow of nutrients to prevent drying out the plant roots.

Hydroponics — Its history and use in barren land

As in due course of time, Pakistan may have to make use of its barren lands to meet the food requirement of its rapid growing population

By Dr. S.M. ALAM and Dr. R. ANSARI
NIA, TandojamApr 09 - 15, 2001

There are many excellent works, one can point out, which sufficiently presents the early work, that was done with the hydroponics (soilless) culture of plants. Woodward in 1699 made the earliest use of water culture method without any solid material. During the 1700s, several workers attempted to find out, what caused plants to grow. Later on in 1800s, Sachs and Knop in Germany conducted experiments, which helped to determine that certain essential elements were contributors to plant growth. Out of this early research proved the basic for preparing and managing the nutrient solution for growing plants. It was during the hundred years period from 1850 to the mid l900s, that all the currently recognized essential elements required by plants all over the world were discovered.

The word "Hydroponics" is a term commonly used in describing solution culture, water culture, liquid culture, chemical culture, aqua culture, vermiculiculture soilless culture or any of a variety of invented names. In the scientific field, it is used as a general term for growing plants without soil, whether water, sand, gravel, or any other inert material. These techniques may be divided into several categories, such as with and without root supporting media and static aerated or following nutrient solution with or without its reuse. Sand or gravel culture, the nutrients solution either periodically flooding the growing bed or vessel of dripped through it, is still widely used technique. However, the water culture method was developed in 1929 by Prof. W.F. Gericke of University of California Researcher, who demonstrated on a semi-commercial basis that plants could be grown to maturity without any soil. No other aspect of plant production has caught the fancy of the public than soilless growing normally thought of the public as hydroponics. Popularized in the 1930's by various books and writings on the object, hydroponics become a widely and frequently used technique for growing plants and vegetables in various countries of the world. However, this soil less culture procedure is not well suited, where precise control of the nutrient elements is desired. In 1930, there was a renewed interest in hydroponics. These most significant researches being done on soilless culture, primarily hydroponics, was being conducted at the Environmental Research Laboratory, Tucson, Arizona, USA and at the Glasshouse Crops Research Institute, Littlehampton, England. Later on, it was adapted in many other countries of the world. There are several factors, which control the growing of plants in soilless culture. These factors are control of pH, chemicals to be used in nutrient elements, electrical conductivity of the nutrients solution and temperature of the nutrient solution, and aeration of solution.

There are large barren areas (highly saline, sandy and gravelly areas) in Thar deserts, Thal and Cholistan, in the provinces of Sindh and Punjab, where normal agriculture is not feasible due to absence of good quality soil and enough sweet irrigation water. In such areas, hydroponic culture has proved an alternative for raising fresh vegetable crops. In this system, instead of soil, gravel or sand serves as the supporting medium and nutrient solution containing N, P, K, Ca, Mg, S, Fe, Mn, Zn, Cu, B, Mo, and Cl serve as plant food and due to the recycling of irrigation water, there is manifold saving on irrigation water. It may even be possible to use underground brackish water under hydroponics system.

Hydroponics use in Pakistan: As in due course of time, Pakistan may have to make use of its barren lands to meet the food requirement of its rapid growing population, it is considered worthwhile to explore the feasibility of growing fresh vegetables, using the local materials and with necessary modifications of the nutrient solution suited to our conditions.

Techniques and methods: At the first instance, for the experimental purpose, gravel and desert sands collected from Thar desert and Thana Bulla Khan were treated with 4% formaldehyde solution and washed thoroughly with tap water for several days prior to sowing vegetable seeds. Depending upon the seasons (Rabi and Kharif) various crops e.g. tomato (cvs. Fantastic, Roma VF, T-10, Summer Giant, Bountry, Marglobe, Marmande, Money maker etc), pepper (California wonder), bean, lettuce, watermelon, muskmelon, cucumber and kakri of different varieties, groundnut, garden pea, (American wonder), cotton, bajra, cauliflower (Chin Ka Moti), potato (atom Aloe-DRM), okra, sugarcane etc. were grown in desert sand and gravel media. Proper distance between rows and plants were maintained. All these crops were grown in 4 beds of glasshouse (38 sq.m each in area) and 8 beds of open pothouse (a 11.38 sq.m each in area), filled with gravel and desert sand. Regular spray of insecticides were made on different crops against white flies, aphids, powdery mildew etc. Hoagland nutrient solutions stocked in four different tanks of 1000 gallon capacity of concentrations (ppm) of N 182, P 120, K 160, Mg 50, Ca 300, S 64, B 0.5, Mn 0.5, Cu 0.5, Zn 0.09 Mo 0.3 and Fe 5 were irrigated to the each bed. The concentration of soluble salts and pH of the solution were checked regularly. The pH of the solution was maintained between 6.5 to 7.0 using H2 SO4. Optimum levels of nutrients in the tanks were maintained by analyzing the irrigated nutrient solutions.

Crop growth conditions: The growth of all the crops was generally better in the open pot house as compared to glass house with the exception of tomato and pepper plants, which were badly affected in pot house (i.e. tomato and pepper) due to viral infections, but grew well in glass house without any viral and white flies attack. It was generally observed that desert sand was proved to be a better medium for crop growth as compared to gravel. This may be due to likely more retention of water in the desert sand than gravel. Cucumber, kakri, watermelon and muskmelon varieties available in Pakistan are not suited to glass house condition, as these crops require cross fertilization by insects and lack of cross fertilization in glass house due to close system adversely affected the pollination or flower formation and fruit setting. Groundnut is not suited at hydroponics system.

Results: It was observed from the present results that all the tomato varieties tested hydroponically thrived best in gravel beds under glasshouse conditions, producing an average of 40 tons fruit yield per hectare. Due to severe viral infection, all fields grown tomatoes were destroyed in the vicinity of Tandojam. The open bed tomatoes suffered this a lot. Pepper growth was satisfactory in glasshouse. At the later stage of growth, the attack of spider mite and powdery mildew reduced its yields, yet it produced 15.6 tons per hectare. In the open beds, lettuce grew very well in desert sand and gave an average yield of 36.5 tons per hectare. In coarse gravel, the yield was 16 tons per hectare. Snake melon (kakri), grew well in desert sand of open pot house and produced an average yield of 24.66 tons fruit per hectare, while gravel medium produced only 11.16 tons per hectare. Potato produced yield of 10.38 tons per hectare in gravel bed under glasshouse condition. Cucumber produced an average yield of 34.11 tons fruit per hectare in desert sand and 12.35 tons in gravel bed in open pot house. Cauliflower produced an average fruit yield of 17.4 tons per hectare. Crops like bajra, bean, potato and garden peas grew well in gravel as well as in desert sand. With the increasing knowledge of better production techniques and growth control in soilless culture over that of soil; the yields and quality of crops have increased considerably. The growers, however, are generally required to have more technical knowledge in order to produce the high yields.

Hydroponics use in other countries: Hydroponics workers in Sadiyat greenhouse Dubai (1970-71) grew vegetable crops and obtained yield as tons/acre/crop: cabbage (31), cucumber (102), egg plant (107), lettuce (25), okra (23), tomato (71), and turnips (70). Similarly, workers in USA (Florida State) obtained yield of these vegetables by growing in the field as tons/acre/crop: cabbage (12), cucumber (12), eggplant (8.3), lettuce (10.5), okra (5), tomato (30), and turnips (10). Yields of 200 mt/ha of tomato have been obtained in greenhouse hydroponic culture in a 9 to 10 months period depending on the plant populations. This can be calculated as 10 to 15 kg of tomato fruit/plant. Production costs for hydroponic tomatoes of high quality can range from $0.80/kg. Yields of more than 100 mt/ha of field grown tomatoes have been produced in Florida (USA) in a 4 to 5 month period. There may be areas of the world where hydroponics may be the only systems that kind be used to grow successfully food crops, which are important in human diets. The desert reasons of the world may be such places, where hydroponics has important application. The successfully commercialization of hydroponics is still and open question and it has gained popularity due to successful production of vegetables.

Advantages: (i) Crops can be grown in localities where normal cultivation is difficult or impracticable e.g. in arid area of saline or shallow soil. This opens up new regions for settlement. (ii) Nutrient solution is homogeneous, thus relatively easy to sample, test and readjust. (iii) Both nutrient solution and supporting media are contained in beds filled with gravel or sand, which can be sterilized to prevent root diseases in crops. (iv) Seepage can be stopped and surface evaporation be minimized so that less water is required for optimum yields. (v) Watering can be automatically controlled, thus reducing labour costs. (vi) Average yields are higher and cultivation is easy.

Disadvantages: (i) Initially, the construction of glasshouse and their structures are expensive. (ii) The design of equipment and operation requires a great deal of technical knowledge. (iii) Even with automatic operation of the hydroponic system a constant supervision is necessary. (iv) Some diseases are problem one and even under the uniform conditions of hydroponic gardening may spread quite rapidly. (v) Production costs for establishing and maintaining a hydroponic system are higher than for other more conventional growing techniques. Therefore, hydroponic growing has to be limited to high cash crops. It takes greater skill on the part of the grower to manage a hydroponic system and the margin of error is quite narrow. Small misjudgments in procedures can result in significant crop losses. The current systems that have been most widely used with relatively good success are the various bag culture techniques, using an organic root supporting media, such as sphagnum peat moss or an inert substrate like perlite, with nutrient solution being dripped into the bag.

There may be areas of the world, i.e. countries in Middle East, Arizona state in USA, many African countries and arid areas. Where hydroponics may be the only system that can be used to grow successfully vegetable crops, which are important in human diets. The desert regions of the world may be such places, where hydroponics has important application.

Conclusion: The research works conducted for over ten years in gravel and desert sands at Nuclear Institute of Agriculture, Tandojam, Sindh have shown that the hydroponic system using local materials is feasible under our conditions. However, a number of drawbacks such as non-availability of seeds suited to glasshouse conditions, steady electricity supply to run the electric motors, and protection from insects and diseases, pose difficulties. It has been established under the present experimental conductions, that different crops can be grown in coarse gravel and desert sands of Thar and other barren areas of the country in open and glass house beds, provided all the necessary facilities are available. In the open hydroponic system successful cultivation is possible if effective viral infection control measures become available. Hydroponics system is very profitable and valuable for growing crops in desert sand and gravel media. However, there are certain advantages and disadvantages of the system.

Source

Hydroponics Technology

Hydroponics is a technology for growing plants in nutrient solutions (water containing fertilizers) with or without the use of an artificial medium (sand, gravel, vermiculite, rockwool, perlite, peatmoss. coir, or sawdust) to provide mechanical support.

Liquid hydroponic systems have no other supporting medium for the plant roots: aggregate systems have a solid medium of support. Hydroponic systems are further  categorized as open (i.e. once the nutrient solution is delivered to the plant roots, it is  not reused) or closed (i.e. surplus solution is recovered, replenished, and recycled). Hydroponic growing (as opposed to soil growing) allows you to control the nutrient levels for your plants directly. Because of the higher control over nutrients, hydroponically grown plants generally have a much higher yield than similar plants grown in soil.

A plant gets its food source by turning Co₂, light and water (or hydrogen) into carbohydrates through a process called photosynthesis. With hydroponics growing, plants are grown without soil so they must get their nutrients from the nutrient solutions added to water. The absence of soil in growing means that hydroponics systems must have some way of supporting the plants while still allowing the bare root system maximum exposure to the nutrient solution. Often a “growing medium” is used for support and to aid in moisture and nutrient retention in hydroponics growing. Because they lack media to store water and nutrients, water culture systems need a continuous flow of nutrients to prevent drying out the plant roots. Plants need an energy source in order to grow. With hydroponics growing this energy may come from natural light, which has the full spectrum of color or through the use of different types of artificial lighting (grow lights), which can be selected for specific plant varieties and optimum plant growth characteristics.
Source: Oasis Agro Industries Pakistan

Hydroponic farming to help achieve Agri targets

Pakistan can enhance vegetable and fruit crops yield with hydroponic farming technology to overcome the food shortages and price hike tendency. This technology would not only raise yield but also enhance nutrition abilities of plants. Hydroponics can be a futuristic technology for Pakistan to ensure proper supply of vegetable and fruits crops as it uses 70 percent to 90 percent less water than irrigated soil based agriculture. No water was lost in the ground or absorbed by weeds or lost in evaporation, officials in Ministry of Food, Agriculture and Livestock (MINFAL) said. A website relating to agri news reported that a hydroponic pilot project has already been launched in Rawat (Islamabad) under the name bio-blitz over just five acres of land. The state-of-the- art five-acre Green House facility is producing hydroponic tomatoes of all varieties including tangy, elegant, cherry and others. If hydroponics farming technology is introduced properly, then country can triple the revenues earned on agriculture exports and the country could be a huge power player in the market because nobody else in the region is using high-tech hydroponics. The officials said in the pilot project, a Dutch hydoponic expert was working with the team training Pakistani staff on how to run a hydroponic greenhouse. According to them, a high tech hydroponic facility was more expensive to set up than soil farming but once it is set up, operating and maintenance costs were low and the very high and definite yields means that invested money would be recovered in one year.

Countries, which were world leaders in hydroponics employ what was called a 'cluster approach where land is allocated just for hydroponic farming practiced by different farmers. To develop a viable hydroponics industry, Pakistan desperately needs to improve its infrastructure facilities, such as availability of electricity and land. Greenhouses need a constant supply of power but the situation in Pakistan is not encouraging, they added. Agriculture scientists said there are two main types of hydroponics culture, namely solution culture and medium culture. The solution culture excludes roots as source of nutrition, while the medium culture is based on roots as part of the process. The solution culture method is further divided into three types - static solution culture, continuous flow solution culture, and aeroponics. The medium culture, on the other hand, is based on medium through which the root is routed - sand culture, gravel culture or rock wool culture. These media of nutrition are again sub-divided into two categories - sub-irrigation and top irrigation. In all these techniques, mostly plastic is used for hydroponic reservoirs, though other materials have also been used, which include concrete, glass, metal, vegetable solids and wood. Experts advised that the containers should block light to prevent algae growth in the nutrient solution. Hydroponics is a method of growing plants, using mineral nutrient solutions without soil. Terrestrial plants may be grown with their roots in the mineral nutrient solution only or in an inert medium, such as perlite, gravel, or mineral wool. This technology was discovered in the 19th century. In this technology plants absorb essential mineral nutrients as inorganic ions in water. In natural conditions, soil acts as a mineral nutrient reservoir, but the soil itself is not essential to plant growth. Hydroponics is also a standard technique in biology research and teaching. Researchers have obtained groundbreaking results in various countries, however the process has proved it to be thoroughly practical, having an edge over conventional methods of horticulture. Talking about the benefits of the technology, the officials said it saves water, freedom from soil diseases and weeds and less labour needed and cost effective. Scientists agreed that hydroponics fruits and vegetables are sweeter and more luscious than those grown in ordinary soil are. The technology is being utilised around the globe, including the US, European Union (EU) and African countries. Repeated pricing studies have shown that only high-quality garden type vegetables like tomato, cucumber, potato, sweet peppers, melon, and specialty lettuce can cover costs or give a return in hydroponics systems. As the consumer becomes increasingly aware of quality differences, especially the high quality of tomatoes, cucumbers, and leafy vegetables coming from hydroponics, the demand will increase. This, along with the increased emphasis on eating more vegetables for dietary and health reasons, will surely help the hydroponics industry.

Source: http://www.nation.com.pk

High-tech agriculture: Hydroponic vegetable farming

By Imran Rana

Tahir Rana is a nuclear physicist who gave up a job in Canada to set up a vegetable farm in Faisalabad. He is part of a growing number of people worldwide who have been drawn in by the extraordinary profits in hydroponic vegetable farming, a new method that dramatically increases productivity and thus farmer incomes.

Hydroponic farms are unique in that they do not require any fertile soil. Indeed many of the world’s largest hydroponic farms are set up in the deserts of the Middle East or unfertile soils in other parts of the world. Seeds are placed in a growing medium – which can be either solid or liquid – in trays made from steel pipes. The advantage of this system is that nearly all of the nutrients poured into the growing medium are absorbed by the plant, making it exponentially more efficient and increasing productivity manifold.

Rana has set a up a small company just outside Faisalabad called Fareed Farmhouse, where he produces three varieties of tomato (cherry tomato, strawberry tomato, beef tomato), cucumber and capsicum. His production capacity is significantly above the norm.

“Through this technique, farmers can get between 450 and 550 tons of vegetables per acre, compared to the average yield of 15 tons per acre using traditional farming,” said Rana Zahid, the project director at Fareed Farmhouse.

Rana uses coconut waste imported from Sri Lanka as the solid medium in which he grows his plants. The vegetable plants are then irrigated through a water injection system. Fareed Farm uses reverse osmosis water purification systems to ensure the quality of the water.

Each plant requires up to two litres of water per day, which needs to be slightly acidic, with a pH of 5.8, according to Zahid.

Fareed Farmhouse produces relatively high-end vegetables that are consumed by higher income customers. His buyers include some of the large retail and wholesale chains in the country as well as hotels that have traditionally imported many of these vegetables from Europe.

Rana sells the tomatoes for about Rs225 per kilogram, compared to the cost of importing them from the Netherlands, which can run as high as Rs800 per kilogram. The seeds for the tomatoes at Fareed Farmhouse are imported from Canada and many of the other raw materials from China and Sri Lanka. Yet while the imported raw materials can be expensive, the method allows the company to save on other expenses.

“Our production method allows us to not use any kind of pesticides,” said Rana Arshad, a quality control officer at Fareed farmhouse.

The methods used by Fareed Farmhouse, however, do not come cheap. Hydroponic farming requires an investment of up to Rs1.5 million per acre, though it can yield net profits of up to Rs3 million per acre annually. Tahir Rana, however, is not content with just reaping the rewards of the existing techniques. He plans to spend up to Rs4 million in researching new methods and new variants of seeds. He is also planning on rapidly expanding his production base to up to 20 acres in the Faisalabad area.

Rana is a firm believer in the potential of hydroponic farming to transform Pakistani agriculture. “Every year, we import vegetables from India. If the government takes an interest in promoting these new technologies, we would not need to import from other countries. In fact, the country could earn a lot of foreign exchange by exporting to other countries.”

While Fareed Farmhouse is thus far focused on high-end vegetables, it appears that the company believes this method can be used to produce more mass market products as well.

Published in The Express Tribune, March 23^rd, 2012.

Why Hydroponics?

Hydroponics is often defined as “the cultivation of plants in water.” Hydroponics is however a technique for growing plants without using soil. Utilizing this  technology, the roots absorb a balanced nutrient solution dissolved in water that meets all the  plants developmental requirements.

Research has determined that many different aggregates or media can support plant growth,  therefore, the definition of hydroponics has been broadened to: “the cultivation of plants without soil.”

ADVANTAGES OF HYDROPONICS

As demonstrated by through research activities, including field trials, hydroponics is a far more economical and profitable technique than traditional agricultural cultivation.

Some of the advantages noted:

1.     The possibility of obtaining more products in less time than using traditional agriculture:

2.     The possibility of growing plants more densely

3.     Possibility of growing the same plant species repeatedly because there is no soil depletion

4.     Plants have a balanced supply of air water and nutrients

5.     More product/surface unit is obtained

6.     Cleaner and fresher products can be reaped

7.     Production can be timed more effectively to satisfy market demand

8.     Healthier products can be produced

9.     Products are more resistant to diseases

10.                        Natural or Biological control can be employed

11.                        Soil borne pests (fungi) and diseases can be eliminated

12.                        Troublesome weeds and stray seedlings which the result in the need for herbicides  use and increase labour cost, canalso be eliminated.

13.                        Reduction of health risks associated with pest management and soil care.

14.                        Reduced turnaround time between planting as no soil preparation is required

15.                        Stable and significantly increased yields and shorter crop maturation cycle

16.                        Can be utilized by families with small or no yard space

17.                        When water is used as the substrate:

a.     no soil is needed

b.     the water stays in the system and can be reused - thus, lower water costs

c.      It is possible to control the nutrition levels in their entirety - thus, lower nutrition costs

d.     No nutrition pollution is released into the environment because of the controlled system

18.                        Pests and disease are easier to get rid of because of container mobility

DISADVANTAGES OF HYDROPONICS

1.     Commercial Scale requires technical knowledge as well as a good grasp of the principles.

2.     On a commercial scale the initial investment is relatively high.

3.     Great care and attention to detail is required, particularly in the preparation of formulas and plant health control.

4.     A constant supply of water is required

Crop (No. of harvests a year using hydroponics)	Yield using soil (tons per hectare at harvest time)	Yield using hydroponics (tons per hectare at harvest time)
Lettuce (10)	52	300-330
Tomato (2)	80-100	350-400
Cucumber (3)	10-30	700-800
Carrot (1)	15-20	55-75
Potato(1)	20-40	120
Peppers(3)	20-30	85-105
Cabbage(3)	20-40	180-190

PRODUCTION SYSTEM

Hydroponics can be classified as:

-  Open system; or

-  Closed system

OPEN SYSTEM:

In the open system of hydroponics, the nutrient solution is mixed and applied to the plant as  required, instead of being re-cycled. Examples of some open system are:

-  growing beds

-  columns made out of tubular plastics or vertical and horizontal PVC pipes

-  individual containers e.g. pots, plastic sacks and old tires

CLOSED SYSTEM:

In this system the nutrient solution is circulated continuously, providing the nutrients that the  plant requires. Examples of closed systems include:

-  Floating roots

-  Nutrient Film Technique (NFT)

-  PVC or bamboo channels

-  Plastic or polystyrene pots set up in columns

MAJOR REQUIREMENTS THAT A HYDROPONICS SYSTEM MUST SATISFY

-  Provide roots with a fresh, balanced supply of water and nutrients

-  Maintain a high level of gas exchange between nutrient solution and roots

-  Protect against root dehydration and immediate crop failure in the event of a pump failure or power outage.

LOCATING A HYDROPONIC GARDEN

1.     Avoid heavily shaded, windy and extremely sunny places.

2.     Keep the garden protected from domestic animals and pets.

3.     The planting space must receive a minimum of six hours sunlight.

4.     Must be close to a source of water and the place where the nutrients are kept.

5.     It must be kept far from contaminated water.

6.     It must be kept far from trees and other plants that are affected by pests and diseases.

SIZE OF THE HYYDRONNICS GARDEN

1.     Space is not an important factor in hydroponic gardening.

2.     A   garden   can   be   set   up   in   spaces   as   small   as   1m².  Most   of   hydroponic   gardens   are   any   size between 10 to 20m², but some families are able to keep gardens as big as 200m².

3.     Within as small space, one may produce enough vegetables that will be nourishing and free of pollutants.