What is Hydroponics?
In Latin, the word hydroponics means literally "water working." Hydroponics is the practice of growing plants in either a bath or flow of highly oxygenated, nutrient enriched water.
In soil, biological decomposition breaks down organic matter into the basic nutrient salts that plants feed on. Water dissolves these salts and allows uptake by the roots. For a plant to receive a well balanced diet, everything in the soil must be in perfect balance. Rarely, if ever, can you find such ideal conditions in soil due to contamination and biological imbalances.
With hydroponics, water is enriched with these very same nutrient salts, creating a hydroponic nutrient solution that is perfectly balanced. And since this hydroponic nutrient solution is contained, it does not harm our environment as does runoff from fertilized soil. Additionally, very little water is lost to evaporation in a hydroponic system, owing to its application in drought stricken areas.
To support the plants in a hydroponic system, an inert soil-free medium like fiber, sand or stone, may be used to anchor the roots. These hydroponic mediums are designed to be very porous for excellent retention of air and water that's necessary for a healthy plant - roots need to breathe too!
In addition to a perfectly balanced diet, hydroponic plants have their food and water delivered directly to their roots. This way, the energy normally used to develop long roots can be redirected to growing more plant, which is a great benefit indeed! With the proper exposure to natural sunlight or supplemental grow lights, your hydroponic plants will grow many times faster, bigger and healthier than those grown in soil.
What is Aeroponics?
Aeroponics is an application of hydroponics without a growing medium, although a small amount may be used to germinate the seed or root a cutting. Plant roots are suspended mid-air inside a chamber kept at a 100% humidity level and fed with a fine spray of nutrient solution. This mid-air feeding allows the roots to absorb much needed oxygen, thereby increasing metabolism and rate of growth reportedly up to 10 times of that in soil. And there is nearly no water loss due to evaporation.
Hydroponics was practiced many centuries ago in Amazon, Babylon, Egypt, china and India where ancient men used dissolved manure to grow cucumber, watermelons and other vegetables in sandy riverbeds. The “hanging harden of Babylon” and the Aztec’s floating farms were actually prototypes of hydroponic systems. Later, when plant physiologists started to grow plants with specific nutrients for experimental purposes, they gave the name “nutriculture.”
The word Hydroponics is derived from the Greek word Hudor for water, and Ponos meaning labor, thus meaning working with water. Hydroponics has been in use for nearly 300 years by a man named John Woodward. It wasn't until the 1930's that Dr. William R. Gericke, an American professor, set up outdoor growing units, producing tomato plants with a height of 25 feet tall. In 1944 the United States government actually began using hydroponics as a way to feed the U.S. troops in the pacific. 0.6 acres provided vegetables enough to feed 400 men a day.
Interest in practical application of “nutriculture” developed in 1925 when the green house industry expressed interest in its use. Green house soils had to be replaced frequently to overcome problems of soil structure, fertility and pests. As a result, researchers became interested in the potential use of nutriculture to replace conventional soil culture.
In 1929, Dr William F. Gericke of the University of California succeeded in growing tomato vines of 7.5 m height in nutrient solutions. He named this new production system “hydroponics” a word derived from Greek to reflect the importance of ‘Hydros’ (water) and ‘Ponos’ (working). Thus, hydroponics broke the laboratory bounds and entered the world of practical horticulture. The term hydroponics originally meant nutrient solution culture. However, crop growing in inert solid media using nutrient solution is also included in hydroponics in broad sense.
During 1960s and 70s, commercial hydroponics farms were developed in Abu Dhabi, Arizona, Belgium, California, Denmark, German, Holland, Iran, Italy, Japan, Russian Federation and other countries. During 1980s, many automated and computerized hydroponics farms were established around the world. Home hydroponics kits became popular during 1990s.
In Sri Lanka, the hydroponics system of cultivation is in its infancy. Many use inert solid medium such as coconut fibre or coir-dust with fertigation and some use balanced nutrient solution alone employing both circulating and non-circulating methods in small and medium scales.
Soils naturally maintain the temperature and aeration needed for root growth. When the soil is poor, plant growth and yield decline also due to unsuitable aeration and temperature. Plant cultivation is impossible under ill drained condition due to these conditions. Soil adjusts itself to provide suitable conditions for plant growth. It is called the buffer action of the soils. Plants also absorb nutrients released through natural mineralization.
In a solution or inert medium, maintenance of acidity or alkalinity (pH) and electrical conductivity (EC) in suitable ranges for plant root system is called buffer action. This requirement must be artificially maintained in hydroponics. In any hydroponics system the following basic requirements must be maintained at optimum levels.
• Buffer action of water or the inert medium used.
• The nutrient solution or the fertilizer mixture used must contain all micro and macro elements necessary for plant growth and development.
• Buffer action of the nutrient solution must be in the suitable range so that plant root system or the inert medium is not affected.
• The temperature and aeration of the inert medium or the nutrient solution is suitable for plant root system.
Classification of Hydroponics/ Soil-less Culture
The term hydroponics originally meant nutrient solution culture with no supporting medium. However, plant growing in solid media for anchorage using nutrient solution is also included in hydroponics. This technique is called aggregate system. Hydroponics 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). Current hydroponics systems of cultivation can be classified according to the techniques employed. A hydroponic technique refers to the method of applying nutrient solution to the plant roots.
Large numbers of hydroponic techniques are available. However, consider following factors in selecting a technique.
• Space and other resources available
• Expected productivity
• Availability of suitable growing medium
• Expected quality of the produce – colour, appearance, free from pesticides, etc.
1. Solution culture or Liquid hydroponics -Circulating methods (closed system)
Nutrient film technique (NFT)
Deep flow technique (DFT)
Non-circulating method (open systems) Root dipping technique Floating technique Capillary action technique
2. Solid media culture (Aggregate systems)
These can be open systems or closed systems.
Hanging bag technique
Grow bag technique
Trench or trough technique
Pot technique
3. Aeroponics -Root mist technique
Fog feed technique
http://www.co.kern.ca.us/farm/PUBS.HTM
Monday, February 19, 2007
Sunday, February 18, 2007
Hydroponics Part 1
Growing plants without dirt has always fascinated me for some reason, and about twenty years ago I bought a small self-contained hydroponics grower that was about a foot and a half square, had a reservoir and growing media, and some powdered nutrients. I grew some tomatoes as a proof of concept project, and, having satisfied my curiosity, moved on to other projects.
However, I never forgot the absolutely fantastic taste of those hydroponic tomatoes, and many years later revisited the concept. Searching the web I found a site that promoted a hydroponics system made from soda bottles and PVC piping. This gentleman's web site is the last word on this type of hydroponic growing system.
This system uses PVC piping and 1.5 liter soda bottles. I've used this system for about 3 years, and for a number of reasons I'm changing systems, but this certainly taught me a lot about growing veggies hydroponically.
Other than a post regarding how to hook up the bottles to the PVC pipe grid, the best source for information regarding this system is www.hydroponicsonline.com
This system uses a water pump to push the nutrient-laden water into the grid of PVC pipe and into the bottoms of the inverted 1.5 liter soda bottles. Starting to grow veggies hydroponically takes a bit of a shift in thinking about the concept, plus I decided to try to grow everything from seed. This post explains one way to accomplish that.
Quoting directly from www.hydroponics.net, rockwool is:
I'm not too sure about the reference to visiting volcanos but rockwool cubes are ideal for starting seeds hydroponically:
Rockwool is kinda like compressed organic steel wool; the idea is to place the seeds being germinated into the rockwool media and keep the media moist until the seeds sprouts.
Once the seeds germinate and show true leaves,
(I know this picture doesn't really show "true" leaves, but you get the idea)
it's time to prepare the seedlings for their hydroponics future.
This picture shows the plant container concept that works well with the PVC pipe/soda bottle hydroponics system. Using the rockwool cube with the seedling, two other items are used: a 12 oz. "Solo" drinking cup, and clay pebbles, which I can best describe as ceramic CoCoa Pebbles-
This is the type of bag these things come in, and the bad news is that they're kind of pricey, the good news is that they are reusable (clean, boil & dry off after each crop).
A soldering pen is used to burn the holes into the drinking cup, and the ceramic CoCoa Pebbles are placed in the bottom of the cup.
Once the seedling in its rockwool cube is placed into the drinking cup, more clay pebbles are added into the sides of the cup, surrounging the rockwool cube. Now the plant is ready to be placed into the cups provided by the inverted soda bottles.
Before the plants were placed into the hydroponics grid, I made an "ebb and flow" intermediary station for the plants, allowing them to grow a bit more before being placed on the grid. It's just two rubbermaid plastic containers with a small pump on a timer pushing the nutrient water into the upper box, which has a 1" PVC pipe as a water level control.
Here's a small animated GIF that shows the ebb and flow concept.
I built a germination/growing area from a plastic five shelf unit bought at Home Depot. It's handy to have everything in one spot. By the way, the flourescent lights are TOO FAR AWAY from the plants shown here. The lights should be about 1"-2" away from the tops of the plants depending how much heat your lights give off. Too close = too hot and your baby plants get cooked. Having the lights this far away from the plants doesn't give them enough light, and the plants tend to get "leggy", i.e., too long in the stem and not enough foliage.
My first system was small, but I was astounded at how well the plants grew, especially the lettuce. Rather than trying to describe how big the lettuce plants had grown, I pulled out one of the plants and placed it on a ladder to take a picture of it.
Even with this small hydroponics system I was able to harvest fresh lettuce leaves nightly for salads. I also had cherry tomatoes and peppers in this first system, and they all grew very well.
I had seen this picture on the web and decided that it was a good idea to make a similar covering for my new project.
However, I hadn't counted on the fierce Santa Ana winds that blow through Southern California, and within two weeks of finally installing the plastic sheeting, 60 MPH Santa Ana winds blew through, almost completely destroying my system.
The Santa Ana experience prompted the building of a shelter using 4X4 and 2X4 lumber:
However, I never forgot the absolutely fantastic taste of those hydroponic tomatoes, and many years later revisited the concept. Searching the web I found a site that promoted a hydroponics system made from soda bottles and PVC piping. This gentleman's web site is the last word on this type of hydroponic growing system.
This system uses PVC piping and 1.5 liter soda bottles. I've used this system for about 3 years, and for a number of reasons I'm changing systems, but this certainly taught me a lot about growing veggies hydroponically.
Other than a post regarding how to hook up the bottles to the PVC pipe grid, the best source for information regarding this system is www.hydroponicsonline.com
This system uses a water pump to push the nutrient-laden water into the grid of PVC pipe and into the bottoms of the inverted 1.5 liter soda bottles. Starting to grow veggies hydroponically takes a bit of a shift in thinking about the concept, plus I decided to try to grow everything from seed. This post explains one way to accomplish that.
Quoting directly from www.hydroponics.net, rockwool is:
Rockwool is a horticultural growing media made from the natural ingredients Basalt rock and Chalk. These are then melted at 1600° C into a lava which is blown into a large spinning chamber, which pulls the lava into fibers like "cotton candy." If you have ever visited a volcano you have probably seen these fibers flying around in the air surrounding the volcano. Once the fibers are spun they are then compressed into a mat which is then cut into slabs and cubes. The rockwool granulates are just bales of uncompressed fibers. The process is very efficient, producing 37 cubic foot of wool from 1 cubic foot of rocks. Since rockwool is born in fire it renders the product chemically and biologically inert and creates the ideal growing medium for hydroponics. Since its development in Denmark in the early 1970's, rockwool has become the major vegetable and flower production medium throughout Europe and North America.
I'm not too sure about the reference to visiting volcanos but rockwool cubes are ideal for starting seeds hydroponically:
Rockwool is kinda like compressed organic steel wool; the idea is to place the seeds being germinated into the rockwool media and keep the media moist until the seeds sprouts.
Once the seeds germinate and show true leaves,
(I know this picture doesn't really show "true" leaves, but you get the idea)
it's time to prepare the seedlings for their hydroponics future.
This picture shows the plant container concept that works well with the PVC pipe/soda bottle hydroponics system. Using the rockwool cube with the seedling, two other items are used: a 12 oz. "Solo" drinking cup, and clay pebbles, which I can best describe as ceramic CoCoa Pebbles-
This is the type of bag these things come in, and the bad news is that they're kind of pricey, the good news is that they are reusable (clean, boil & dry off after each crop).
A soldering pen is used to burn the holes into the drinking cup, and the ceramic CoCoa Pebbles are placed in the bottom of the cup.
Once the seedling in its rockwool cube is placed into the drinking cup, more clay pebbles are added into the sides of the cup, surrounging the rockwool cube. Now the plant is ready to be placed into the cups provided by the inverted soda bottles.
Before the plants were placed into the hydroponics grid, I made an "ebb and flow" intermediary station for the plants, allowing them to grow a bit more before being placed on the grid. It's just two rubbermaid plastic containers with a small pump on a timer pushing the nutrient water into the upper box, which has a 1" PVC pipe as a water level control.
Here's a small animated GIF that shows the ebb and flow concept.
I built a germination/growing area from a plastic five shelf unit bought at Home Depot. It's handy to have everything in one spot. By the way, the flourescent lights are TOO FAR AWAY from the plants shown here. The lights should be about 1"-2" away from the tops of the plants depending how much heat your lights give off. Too close = too hot and your baby plants get cooked. Having the lights this far away from the plants doesn't give them enough light, and the plants tend to get "leggy", i.e., too long in the stem and not enough foliage.
My first system was small, but I was astounded at how well the plants grew, especially the lettuce. Rather than trying to describe how big the lettuce plants had grown, I pulled out one of the plants and placed it on a ladder to take a picture of it.
Even with this small hydroponics system I was able to harvest fresh lettuce leaves nightly for salads. I also had cherry tomatoes and peppers in this first system, and they all grew very well.
I had seen this picture on the web and decided that it was a good idea to make a similar covering for my new project.
However, I hadn't counted on the fierce Santa Ana winds that blow through Southern California, and within two weeks of finally installing the plastic sheeting, 60 MPH Santa Ana winds blew through, almost completely destroying my system.
The Santa Ana experience prompted the building of a shelter using 4X4 and 2X4 lumber:
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