© Inter-American Institute for Cooperation on Agriculture (IICA). 2010
IICA encourages the fair use of this document. Proper citation is requested.
This publication is also available in electronic (PDF) format from IICA’s Web site at http://www.iica.int.
Editorial coordination: Jermaine Joseph
Mechanical editing: Aletha Isaacs, Maxine Parris-Aaron, Richard Blair
Layout: Michael Sears
Cover design: Michael Sears
Guyana
2010
Inter-American Institute for Cooperation on Agriculture 2009 annual report: IICA’s contribution to the development of agriculture and rural communities in Guyana / IICA – Guyana: IICA, 2010.
1. IICA – Hydroponics Manual
FFOORREEWWOORRDD
“If you think in terms of a year, plant a seed; if in terms of ten years, plant trees;
if in terms of 100 years, teach the people.” Confucius
A core thematic area of the Cooperation Agenda of the Inter-American Institute for Cooperation on Agriculture (IICA) is that of promoting the introduction of technology and innovation for the modernization of agriculture and rural life.
Following the flood of 2005, the late Dr. Hector Muñoz (then IICA Emeritus Professional) introduced hydroponics technology at St. Stanislaus College Farm. He firmly believed this farming system would be replicated particularly in coastal communities in Guyana, as a post-flood recovery measure, as a future flood risk minimization measure and in the context of food security.
This method of production has been taken across the country to community groups, particularly women’s groups and schools. The Ministry of Education, Ministry of Agriculture, NARI, St. Stanislaus Farm, the Partners of the Americas and Caribbean and African Self Reliance International (CASRI) have all partnered with IICA in this process.
As an aid to the teaching programme, we are pleased to present this revised version of our Hydroponics Training Manual.
We take the opportunity to recognize the special contributions of the Staff at the IICA Office in Guyana for the final product, particularly Jermaine Joseph, who has led the production and is fast gaining the reputation in the fields as the “Hyroponics Guru” for his persistence in promoting the technology.
This production is but a fitting tribute to the memory of Dr. Hector Muñoz for his pioneering contribution to promoting hydroponics in Guyana and also dedicated to the memory of Dr. Desrey Fox for her belief in the youth of Guyana and leading the promotion of hydroponics in the education system in Guyana.
We trust that users will find this manual a practical and user friendly guide to growing crops in non-soil media.
Ignatius Jean
IICA Representative in Guyana
CCOONNTTEENNTTSS
Title Page
Foreword i
Background 1
Introduction 2
Advantages of Hydroponics 3
Disadvantages of Hydroponics 4
Production System 5
Locating a Hydroponic Garden 6-7
Size of the Hydroponic Garden 8
Appropriate Containers for the Hydroponic Garden 9-10
Constructing a Container 11
The Substrate 12-13
Nutrients and Fertilizer 14-15
Pest Control 16
Conclusion 17
References 18
1
BBAACCKKGGRROOUUNNDD
Hydroponics is an ancient technique that dates back approximately 2600 yrs.
The first application of hydroponics in recorded history was the hanging gardens of Babylon that was built by KING NEBUCHADNEZZAR
Egypt and China also practice hydroponics on Chinampas
It was Dr. W. F Gericke in 1936 of the University of California who came up with the term Hydroponics from the Greek hydro (water) and ponos (work), meaning working with water. Dr. Gericke was the first person to carry out large-scale commercial experiments in which he grew tomatoes, lettuce and other vegetables.
Hydroponics was also applied during World War II between 1939 and 1945 so as to provide vegetables for the troops (in arid soils and in Greenland).
NASA currently uses the hydroponics technique to provide food for space travelers.
2
IINNTTRROODDUUCCTTIIOONN
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.”
3
AADDVVAANNTTAAGGEESS OOFF HHYYDDRROOPPOONNIICCSS
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, can also 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
4
DDIISSAADDVVAANNTTAAGGEESS OOFF HHYYDDRROOPPOONNIICCSS
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
COMPARISON BETWEEN TWO GROWING METHODS
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 15-20 55-75
Potato 20-40 120
Peppers(3) 20-30 85-105
Cabbage(3) 20-40 180-190
5
PPRROODDUUCCTTIIOONN SSYYSSTTEEMM
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
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INERS
11
CCOONNSSTTRRUUCCTTIINNGG AA CCOONNTTAAIINNEERR
If there is a need to build a container, you may consider building a bed or box with the following size:
- Length : 1.25m
- Width : 0.95m
- Depth : 0.10 m
The materials needed to build the box or bed are:
- Wood : 15 feet of 1 x 4 inch wood shingle or plank
- 166 feet of ½ x 3 inch wood shingle or plank
- Black plastic : 5.6 feet x 4.3 feet
- Nails : 1 pound – 2 inch
The tools and materials needed to build a bed are: hammer, saw, meter rule, stapler, staples, drill, drill bits, level, saran netting, water hose and water.
A substra
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- Clay b
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- Volca
- Water
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id or solid. T
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coal
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12
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13
The characteristics of a good substrate:
- It must be made of particles no larger than 7mm and no smaller than 2mm - It must be capable of maintaining moisture and draining excess liquid - It must not degrade or decompose easily - It must not hold microorganisms hazardous to human or plant health - It must not be contaminated with industrial residual waste - It must be readily available - It must be potable
Recommended Substrate Mixtures
Some recommended substrate mixtures are:
- 50% rice hull : 50% ground volcanic stones - 60% rice hull : 40% sand - 60% rice hull : 40% ground clay bricks - 80% rice hull : 20% saw dust
Another substrate which could be used is:
- Clean rain water
Rice hulls
These must be washed and kept very moist for ten (10) days in order that all seeds in the rice hulls will germinate. The germinated seedlings must be removed.
Saw dust
Saw dust may be used in small quantities, 15-20% of the substrate since large quantities are harmful to some plants.
14
NNUUTTRRIIEENNTTSS AANNDD FFEERRTTIILLIIZZEERRSS
The hydroponic solution contains a balanced amount of nutrients to produce healthy and productive plants. In addition to the elements (carbon, hydrogen, oxygen) that vegetables extract from the air and water, plants need some elements that may be classified by quantities and need.
ECAG HYDROPONIC FERTILIZER SOLUTION For four (4) liters of water:
A. CONCENTRATED SOLUTION OF MAJOR NUTRIENTS GRAMS
Mono-potassic Phosphate 190.0 Magnesium Sulfate 400.0 Potassium Nitrate 440.0
B. CONCENTRATED SOLUTION OF MINOR NUTRIENTS GRAMS
Fertilon combo 20.0 Boric acid 4.6
C. CONCENTRATED SOLUTION OF N C GRAMS
Calcium Nitrate 590 DOSAGE
Solution cc. per 1 liter of water A 5.0 B 2.5 C 5.0
Large Intermediate Small
Nitrogen Sulphur Iron
Phosphorus Calcium Manganese
Potassium Magnesium Zinc
Boron
Molybdenum
The selec
cted nutrient
- 6 daysplant
- On the
HOW
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15
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n diluted in wwater for eveery
16
PPEESSTT CCOONNTTRROOLL
For the control of pests, we may use natural products such as pepper, garlic and tomato.
These have the following advantages:
- They are non-pollutant - Pests do not develop a resistance to them - No special equipment is necessary to fumigate - They are easily made - They are economical
Note: These products are best used as a preventative method.
Preparation of material
Pepper
- Grind 3 ounces of pepper and add water - Let stand overnight, strain and mix with 5L of soapy water - Apply daily - Controls: ants, worms, fleas, flies, chewers
Garlic
- Mix 3 ounces garlic with oil and let stand for 24 hrs - Dissolve 10g of soap in 1L of water. Mix and strain and add 20L of water - It may be used as repellant, pesticide, bactericide, fungicide and nematicide.
Tomato
- Grind leaves and stems - Boil in 4 bottles of water for 10 mins - Let it cool and apply - Controls: Fleas, lice and hairy worms - Do not apply on plants of the same family, such as pepper and eggplant
17
CCOONNCCLLUUSSIIOONN
Today, hydroponics is an established branch of agronomy.
Progress has been rapid and results obtained in various countries have proved that this technology is thoroughly practical and has very definite advantages over conventional methods of crop production.
The two main advantages of the virtually soil-less cultivation of plants are, the much higher crop yields and hydroponics can be used in places where in-ground agriculture or gardening is not possible.
Thus not only is it a profitable undertaking, but one which has proved of great benefit to humanity. People living in crowded city streets, without gardens, can grow fresh vegetables and fruits in window-boxes or in small discarded containers. By means of hydroponics, a regular and abundant supply of fresh greens can be produced and barren and sterile areas can be made productive at relatively low cost.