Aquaponics Grow Media

credit to : Farm Tech Mart
link : http://farmtech-mart.com/grow_media

Although there is no soil in a hydroponic garden, the plants must still be anchored. There is a wide range of inert materials which can be used to support plant roots and we call them "growing mediums". Clay Pellets, Perlite, Vermiculite, Coconut Fiber and Rockwool are the most popular media. The hydroponic media that work best are pH neutral, provide ample support for plants, retain moisture, and allow space for good air exchange. The type of media you choose will depend on the size and type of plants you wish to grow, and the type of hydroponic system being used. 

1. Clay Pebbles (LECA) 

Expended Clay Aggregate pebbles (LECA) main use is as a hydroponic growing media in flood and drain and dripper hydroponics systems like the Wilma. Clay pebbles can also be mixed with other hydroponic growing media like Cellmax, Coco or Soil to give better aeration. To create better drainage when growing in pots add a layer of Clay pebbles in the bottom.

Many growers use clay pebbles as a hydroponic growing media because they have excellent aeration and drainage properties. Clay pebbles are a clean, ph stable, and can be reused a couple of times before they need to be replaced.

Flood and drain or a dripper system will deliver the fast growth rates and yields using clay pebbles.

The centre of a clay pebble is honeycomb to make it light weight and the outside of a clay pebble is covered in a thin layer of solid clay making them suitable for use in hydroponics.

Tired of looking at dirty soil on the top of house plants in pots why not use some clay pebbles to make it look more attractive.

2. Perlite

Good old perlite! It's been around for years, mainly for use as a soil additive to increase aeration and draining of the soil. Perlite is a mined material, a form of volcanic glass that when rapidly heated to more than 1600 deg. f. it pops much like popcorn as the water vaporizes and makes countless tiny bubbles.

Perlite is one of the best hydroponic growing mediums around. Used by itself or as a mixture with other mediums. Perlite is commonly used with vermiculite ( a 50 - 50 mix is a very popular medium), and is also one of the major ingredients of soiless mix's. Perlite has good wicking action which makes it a good choice for wick-type hydroponic systems. Perlite is also relatively inexpensive.

The biggest drawback to perlite is that it doesn't retain water well which means that it will dry out quickly between waterings. The dust from perlite is bad for your health so you should wear a dust mask when handling it.

3. Vermiculite 

Vermiculite is another mined material. In it's natural state it resembles mica rock, but when quickly heated it expands due to the generation of interlaminar steam.

Vermiculite is most frequently used in conjunction with perlite as the two complement each other well. Vermiculite retains moisture (about 200% - 300% by weight), and perlite doesn't so you can balance your growing medium so that it retains water and nutrients well but still supplies the roots with plenty of oxygen. A 50/50 mix of vermiculite and perlite is a very popular medium for drip type hydroponic systems as well as ebb and flow systems. Vermiculite is inexpensive.

The major drawback of vermiculite is that it retains too much water to be used by itself. It can suffocate the roots of plants if used straight.

4. Coconut Fiber 

Coconut fiber is rapidly becoming one of the most popular growing mediums in the world. In fact it may soon be THE most popular. It is the first totally "organic" growing medium that offers top performance in hydroponic systems. Coconut fiber is essentially a waste product of the coconut industry, it is the powdered husks of the coconut itself.

There are many advantages - it maintains a larger oxygen capacity than rockwool, yet also has superior water holding ability than rockwool which is a real advantage for hydroponic systems that have intermittent watering cycles.

Coconut fiber is also high in root stimulating hormones and offers some protection against root diseases including fungus infestation. Dutch growers have found that a mixture of 50% coconut fiber and 50% expanded clay pellets is the perfect growing medium.

One word of caution about coconut fiber, you must be careful when you purchase coconut fiber. There is a commonly available, lower grade of coconut fiber that is high in sea-salt and is very fine grained. Lower grade coconut fiber will lead to disappointing results when used in a hydroponic system.

5. Rockwool

Rockwool is a very popular hydroponics growing medium. Rockwool is a porous substance that forms when a mixture of rocks, mostly basalt and dolomite, is melted at high temperature and specially processed. Given the material's neutral nature, it is used to build plant-growing medium granules or slabs, blocks, plugs, cubes, etc.

Rockwool provides roots with a good balance of water/oxygen As rockwool is composed of 97% air, it is easy to control the air/water ratio in it. Its porous quality also enhances root growth.

. Small cubes are used for starting seeds and cuttings, 3" or 4" cubes for small plants or intermediate growth, and slabs for larger plants. Rockwool can be used with continuous drip or flood and drain systems. Although it is possible to sterilize and re-use Rockwool, most often it is used only once.

More than 95% of all greenhouse vegetable production is carried out with the help of Rockwool -and for good reason. Like mentioned before, rockwool allows control over air and water supply, which are essential factors for plant growth. It also provides other feasible conditions to support a great crop, leading to consistency in plant production and yield, which is an important consideration in commercial harvesting.

Another pro is the easy availability of Rockwool products in a variety of shapes and sizes. This promotes the maximum utilization of Rockwool in various types of hydroponic set-ups.

Aquaponics & Mosquitoes - Lesson Learnt

credit to http://www.friendlyaquaponics.com/

from the post : Welcome to “The End of Malaria”

Are you irritated by mosquitoes in your neighborhood? Do you live in a location where malaria, elephantiasis, filariasis, dengue fever, or any of the other dangerous diseases carried by mosquitoes exist? Are you a health-care professional whose concern is these diseases and their control and eradication? If the answers to these questions interest you, please read on:

An additional benefit of farming aquaponically (that we noticed after our first system was operational for six months) was that the mosquitoes on our seven-acre farm had COMPLETELY disappeared! We live in Hawaii, where there are as many mosquitoes as any other tropical area in the world. Although we are fortunate not to have malaria, elephantiasis, filariasis, or any of the other dangerous diseases that are transmitted to humans by mosquitoes, we DO have dengue fever, which can be fatal in the young, elderly, or those with compromised immune systems.

Before we built our first aquaponics system, our farm was like any other place on the green windward coast of the Big Island: even during a drought, when the soil was dusty and dry and there was no standing water visible anywhere, there were still clouds of mosquitoes at dawn and dusk. If we left a door or window open in the house during the day, even for a few minutes, we knew that we would be tormented by the buzzing of hungry mosquitoes all night long as we tried to sleep. When we built our first aquaponics system, we knew we were creating additional habitat for mosquitoes to lay their eggs, so we introduced a few mosquito fish (gambusia affinis), and neon tetras into our system water.

They thrived and spread throughout the systems we built, and soon had become a self-sustaining population numbering in the tens of thousands. Six months later we noticed there were simply no mosquitoes around any longer. It’s easier to notice the presence of a pest than the absence of one, so we’re not certain when the number went to zero, but it was sometime during that six-month period. That was three years ago Since then, we’ve had the pleasure to live on a beautiful farm in the tropics that has NO mosquitoes! How does this work?

We live in the center of a deadly efficient mosquito trap: every female mosquito in the neighborhood can sense the roughly 50,000 gallons of water in our aquaponics systems, and comes to them to lay her eggs. Each egg hatches into a larva, which is then promptly consumed by one of the hundreds of thousands of mosquito fish in our water BEFORE it can ever develop sufficiently to hatch into an adult mosquito. That mosquito’s bequest of future generations is GONE, down the gullets of little fish who thrive on these meals and produce even MORE little fish hungry for mosquito larvae.

We don’t know what the effective radius of our mosquito eradicator is, but we’ve gone to the corners of our seven-acre property and haven’t found any mosquitoes there; we think there’s a good chance it is significantly reducing mosquito populations on the farms around us. We need help and funding to continue research into this phenomenon in order to understand it better, and to develop it to the point where it can easily be implemented in any location or culture.

This could make a huge difference in the lives of people worldwide who currently lose family members to malaria and other mosquito-borne diseases.

  

Home garden, Home aquaponics

credit to http://quantitativemetathesis.blogspot.com/

Aquaponics Is the Next Generation Name for House Garden

We have all observed of veggie plants, kitchen landscapes and bought clean vegetables from the grocer's shops and observed about The Lawn of Arden. At some point of life most of us might have used veggie agriculture, be it in the property garden or portable pots but I think most of us have not tried Aquaponics yet. Aquaponics is a recent innovation in the field of agriculture and shall become another name for home landscapes in the days to come.

                      

What is Aquaponics?

Aquaponics is the combination of hydroponics and aquaculture. Hydroponics is the method of growing vegetation in h2o or sand without the use of ground. Aquaculture is the agriculture of seafood. Aquaponics is the farming of both vegetation and seafood part by part. Fish is kept in an fish tank. The h2o made up of the toxic release by the seafood is sent to the hydroponic program through a pipe, where the vegetation utilize it to obtain their meals. The h2o becomes free from toxics and is sent returning to the aquaculture program.

                         

Vegetables can be expanded in multiplexes

All types of clean vegetables flourish in the Aquaponics program. Cucumber green beans, clothes or chili peppers any veggie can be expanded inside your house. Aquaponics can be used both, outdoors or in the house. No area is needed and this decreases the cost significantly especially, in cities and places where area for agriculture is hardly available. People living in multiplexes can also grow their clean vegetables.

Aquaponics gives you clean and natural vegetables

Since the vegetation obtain their nutritional value from the seafood fertilizer, no substances or bug sprays are needed. This means you get clean and natural veggie for your your meal. You do not need to pay high costs or even visit the Grocery stores store. These self produced clean vegetables involve no appearance, rating, marketing and marketing, which are the reasons for the rise in the costs of products in shops.

                                     

Saves h2o efforts and energy

All you need is a continuous supply of meals for the seafood. Difficult and time consuming washing of the fish tank is also reduced. The vegetation obtain the nutritional value from the h2o containing the natural waste of the seafood. Most of the washing is done by the vegetation. The h2o becomes clean and is supplied returning to the fish tank. It helps you to save a lot of h2o too.

                              

Easy accessibility to packages of different sizes

Aquaponics kit can be easily bought from plant centers, agriculture shops or via internet. Kits are available in different dimensions from huge tanks, to be used in verandas or mini ones for indoor preparations. The blooming bed too can be a huge tank or just a huge pail. Other necessary equipment is provided in the kit along with related information and training.

Relaxation of mind

Aquaponics gives an ultimate experience of staying close to nature in the grouped and disorderly places. The joy of eating self-cultivated meals is tremendous and no exotic supper at any cafe could ever meet it. It makes a relaxing green environment and gives pleasure to the brain. It can prove to be a treatment for many illnesses which owe their birth to stress and extremely stress.

What food can be grown in Aquaponics

PLANTS

credit to Endless Food Systems

Naturally, different plants grow under different conditions. Before you get started growing, it’s important to consider which type of growing bed to use. This is determined by the type of root structure that plant tends to have. Plants with no root structure need floating beds, while root vegetables grow better in wicking beds. Most everything else grows best in media beds. 

For plants like lettuce, herbs or leafy greens, floating “raft” style beds are ideal. For root vegetables, wicking beds are a better choice. If you plan to grow tomatoes, peppers, beans or most other types of multiple yield plants, media beds are probably your best option.

Choosing the right environment in which to place your aquaponics farm is another important consideration. The amount of sunlight, ambient temperature, rainfall and wind are all crucial factors in producing a healthy plant. If you decide to grow outdoors, choose varieties of vegetables that will grow best in your climate. In addition, most areas will require the use of a greenhouse, or you can always grow indoors.

It is best to avoid fighting Mother Nature. Even with a greenhouse, it is difficult to control the temperature, and plants thrive better when the temperature ranges match their normal processes. Therefore, in the colder months you should grow cold-weather crops and in the summer, you should grow your warm-weather plants.

It’s important to carefully schedule your planting times. If you’re looking to produce a sustained food supply, you should stagger your projected harvests so that all of your produce doesn’t become ripe at one time. This can lead to wasted food, as well as in-between periods where your aquaponics garden isn’t producing any vegetables. If you plan to grow multiples of the same vegetable, try to stagger growing periods by approximately the amount of time it will take you to consume a batch.

If you are aiming for more variety in your diet, try overlapping the growing times of three or more vegetable types. It can take a while to fine-tune this process to match your own consumption and the decomposition rates of your already picked vegetables. To err on the side of overproduction is never a bad idea, as you can easily donate excess vegetables, share them with friends or preserve them for later by freezing, dehydrating or canning. 

One of the quickest-yield vegetables you can get out of an aquaponics system is lettuce. Reaching peak maturity at around 28 days, lettuce grows ideally in floating beds. It is very forgiving in terms of the minimum and maximum water temperatures and can survive a range from 25-85 degrees Fahrenheit. 

If you’re looking to produce a more nutritious food in a short amount of time, pole, an Italian-style wax bean, can be harvested in around 54 days. Pole grows best in a media bed and is optimal at temperatures between 59 and 95 degrees Fahrenheit. Beans overall are an excellent investment, as they can be dried and stored for very long periods of time. 

Tomatoes are well worth the wait, taking around three months to reach peak maturity depending on the strain and variety. Like beans, they grow best in a media bed at a temperature of 59-95 degrees Fahrenheit. In order to ensure the highest yield from your tomato plants, be sure to trim off all shoots, leaving just the main vine. This will ensure that the bulk of the plant’s nutrients are delivered to the tomatoes once they begin to form. 

In about 65 days, you can have a full harvest of delicious carrots. They have a very well defined optimal growing temperature, at between 59 and 64 degrees Fahrenheit, although they are capable of growing in extreme temperatures in both directions. Wicking beds provide the perfect growing environment for carrots and other root vegetables.

With an aquaponics system, your ability to grow edible plants is limited only by your own desire to do so. The system does most of the labor that would be required of you in an ordinary in-ground growing operation, so you can spend your time on more pressing issues like scheduling harvests and finding new and interesting applications for your crops. When done correctly, you should be able to maintain a constantly rotating supply of organic, pesticide-free vegetables that can carry on indefinitely in a properly maintained system. 

FISH
credit to Backyard Aquaponics

There are many different species of fish that can be used in an aquaponic system, depending on your local climates and available supplies. Our local climate in Perth, Western Australia, allows us to keep Rainbow Trout through winter, then a warmer species like Barramundi during summer. There are also a few choices for year round fish that we could grow, but they often take a longer time to mature. If you live in a cooler climate you might be looking at growing Trout all year round, or perhaps another locally produced fish species. In warmer areas of Australia people generally grow Barramundi, or Jade Perch year round, in most warm areas throughout the world Tilapia is the fish of choice.

In deciding what is the best species for you to grow, you should take a few factors into account, most importantly is what you want from your system. If you don’t want to eat your fish then you probably won’t want to grow edible fish, or you may want to grow an edible fish that can live year-round in your area, so that you’re not having to harvest fish out seasonally. The second most important factor is ‘What’s available?’ You need to be able to buy fish to stock your system, even with species such as Tilapia that breed readily, you need to get your broodstock in the first place.

Here’s a list of useful aquaponic species with a few details about each

Barramundi: Barramundi are often grown in aquaponic systems through the warmer months of the year. Most growers will buy fairly mature stock so that they can harvest larger fish, at the end of the growing season. Barramundi that is grown in an aquaponic system has an exceptionally clean, crisp taste. Growing your own Barramundi excites guests and is the envy of neighbours. They provide a decent harvest at the end of the season and are one of the more majestic species of edible fish.

Catfish: There are many different species of catfish around the world that are well suited to aquaponics. Channel catfish are the most widely farmed aquaculture species in the United States, and they are available in many areas of Australia. Catfish don’t have scales so they need to be skinned, they are quick growing and have a good food conversion ratio.

Carp: There are many species of carp that could be very well suited to aquaponics, unfortunately because of their reproductive capabilities, their tough nature and ability to readily adapt in many areas of the world, carp have become noxious pests to native waterways and the environment, and as such they are not easily obtainable, and often there are high fines and fees for keeping them. In most western cultures carp also have a fairly poor reputation, as an eating fish, however, carp is still the most widely cultured fish in the world as it’s grown throughout most of Asia.

Goldfish: Although some people may group these with the carp, I’ve decided to cover these seperately as most people refer to them as goldfish, and this is what they will be sold as, at local pet shops or fish suppliers. Goldfish are generally pretty tough and make a great addition to an aquaponic system. In many areas they will breed in a tank, although they generally need plant cover within the tank to breed.

Jade Perch: This Australian fish is worth a special mention here, as it has the highest levels of omega three oils of any fish species in the world. In fact it’s so high in omega three oils that growers are trying to breed the oil out of them, they are trying to breed a less oily fish because they’ve found people don’t like the high oil content. They require warm water and consume an omnivorous diet. Very well suited to an aquaponic system, they grow quickly and fingerlings are readily available in warmer areas.

Koi: Once again, another species of carp, but better known as “Koi” rather than carp. Koi are very common within many Asian communities and they are often found in large ornamental ponds. For those who love Koi, an aquaponic system is a great proposition for stocking the fish.

Murray cod: Murray cod are a magnificent native Australian fish, known to grow to enormous sizes in their native habitats, their tank culture is still in reasonably early days. Murray cod are grown in recirculating aquaculture systems, and can also been grown in aquaponic systems, hopefully this fish will be utilised more over time because they are quick growing, and a great eating fish. One of the downfalls is that they must be kept at high stocking densities, and kept well fed otherwise they cannibalise each other.

Silver perch: Silver perch are a good allround native Australian fish that grow well under a variety of conditions. Perch are omnivorous and will happily eat green scraps as well as Duckweed and Azolla. They grow within a wide temperature range, though they’re not as fast growing as many other fish, taking 12-18 months for fingerlings to grow to plate size.

Tilapia: The second most cultured fish in the world, and extremely popular in Aquaponics systems. They are an ideal species for aquaponics for many reasons. They are easy to breed, fast growing, withstand very poor water conditions, consume an omnivorous diet and are good eating. The only downfall for some people will be that Tilapia require warm water. If you live in a cool area you are far better off growing a fish species that will grow well in your temperature range, rather than trying to heat the water. Tilapia are also a declared pest in many areas.

Trout: Trout are a great fish for aquaponic systems where water temperatures are a little cooler. Trout prefer water temperatures between 10°C and 20°C. They have extremely fast growth rates and excellent food conversion ratios.

Others: There are other fish species which are quite suitable for aquaponics, that might be available in your local area. In Europe many different species of carp are grown, within the United States such species as Bluegill are often available, while in Australia we also have a number of other native species like Sleepy cod which would be suitable.

Other aquatic animals that can be incorporated into an aquaponic system are fresh water mussles, fresh water prawns, and fresh water crayfish. Mussles are a filter-feeder, and do a great job of helping to clean the water, they will happily grow in flooded grow beds, or can be incorporated into fish tanks. Crustaceans make a nice addition to an aquaponic system and there are a few different species available depending on your location and water temperatures.

For those in tropical areas there’s Redclaw, a fast growing  Australian species, and for those in cooler areas there’s Yabbies or Marron.

Yabbies breed readily, given the right environment and the correct water temperature, as well as long daylight hours. They also grow fairly quickly, but they can be prone to fighting and cannibalism when stocked very densely.

  

Aquaponics' Applications [1]

Educational Applications of Aquaponics

credit to Nelson Pade website

Aquaponics and hydroponics are both excellent means of demonstrating many principles of science, agriculture, math and business in all grade levels and for home schooling. Applications of these technologies are only limited by ones imagination.

A unit in hydroponics or aquaponics enforces practical uses of chemistry, mathematics, physics, economics and engineering. The monitoring and care of a hydroponic or aquaponic system by students helps instill a sense of responsibility, inspires creativity and creates excitement in the learning environment.

A small aquaponic garden can sit on a counter top and be used to demonstrate botany, horticulture, hydroponics (soil less plant culture), plant science, nutrition, physiology and care, nutrient and pH testing, pH relationships, plant usage of nutrients, seed germination, photosynthesis and light and plant development.

An aquaponic system combines hydroponics with aquaculture in a recirculating system. In addition to the plant sciences, aquaponics incorporates and demonstrates many of natures natural cycles, nitrification, biology, fish anatomy and nutrition and high-tech agriculture.

A unit in hydroponics or aquaponics can be started at the beginning of a semester and run through the entire semester, allowing the educator to present the individual concepts and lessons as the plants and fish develop and grow. A small hydroponic or aquaponic system can sit on a spare counter top. Larger systems can be placed on the floor of a classroom, in a windowsill or a greenhouse.
  

How Aquaponics Makes Food Right

Credit to http://www.thecoolist.com

Aquaponics — The farms of the future are growing today. In a valley in the Virgin Islands, in a warehouse in Chicago, on a rooftop in Florida and a greenhouse in Milwaukee, history’s newest and most sustainable form of agriculture has broken out of its seed and has began to take root. In these farms of the future, you’ll find no waste water, no eroding soil and no harsh insecticides, but a mutually-balanced ecosystem that yields fast-growing organic produce– and the freshest, toxin-free fish money can buy. This is aquaponics, a high tech farming technology where vegetables and fish are grown in concert, a next generation symbiotic system that just might change the way we grow, harvest and eat the food of tomorrow.


1. The University of the Virgin Islands: Where the science began

After decades of scientific research, the team at the University of the Virgin Islands successfully grew fish and vegetables in a closed loop system that they ultimately called “Aquaponics”. Aquaponics is a hybrid technology including “aquaculture”, the raising of fish in a controlled system, and “hydroponics”, the farming of plants in a soil-free environment. Both techniques had survived for centuries before being merged, with hydroponics reaching back all the way to the hanging gardens of Babylon, where raised troughs of nutrient-rich water fed plants that hung and cascaded to the grounds below. Aquaculture is a newer technology, most commonly known as “fish farming”, where schools of fish are raised in controlled environments both in the seas and on land.

Both aquaculture and hydroponics produce toxic waste that ultimately harms the environment. In aquaculture, fish produce natural waste that is high in ammonia, resulting in water that must be discarded to maintain the health of the fish. In hydroponics, nutrient solutions degrade in quality and the waste water must be removed from the system or else it will harm the plants. When merged, aquaculture and hydroponics cancel out each other’s waste, providing a closed-loop system where the plants live off the fish waste and the fish live in water purified by the plants. In these aquaponic systems, humans can imitate the precise balance of nature to yield tons of fresh produce and healthy fish with very little effort.


2. Will Allen’s “Growing Power” Urban Farm, Milwaukee, WI

One of the champions of this new food movement is Will Allen, owner of the Growing Power urban farm in Milwaukee, Wisconsin. Allen has built a series of greenhouses that use aquaponic technology to raise 10,000+ lake perch and over a 1,000,000 pounds of produce every year. By using their own compost to heat the greenhouses, Growing Power runs year round, making them what might be the most productive year-round farm in the Midwest.

The secret to Growing Power, and many other aquaponic farms, is the vertical nature of their farming practice. Using multiple raised beds that stretch toward the roofs of each greenhouse, farmers can multiply the yield that traditional farmers could expect from a flat land investment. A single pump lifts the nutrient-rich water from the fish tanks to top level growing beds. This water feeds these plants and then cycles down to lower levels before falling back into the fish troughs below.

What makes Will Allen’s achievement so remarkable is that he has grown over 1,000,000 pounds of produce and 10,000 pounds of fish in just a few acres. It is an achievement that has inspired hobbyist and commercial growers alike, and has earned Allen a myriad of awards from some of the most prestigious grant organizations in the world. Allen has received a leadership grant from the Ford Foundation, a Genius Grant from the MacArthur Foundation and another from the Kellogg Foundation. In the world of aquaponics, this humble son of sharecroppers from South Carolina has risen to the most recognizable force in the world of future farming.


3. John Edels “The Plant” Warehouse, Chicago, IL

Not far from Growing Power in Milwaukee, another eco-entrepreneur has taken to the empty warehouses of Chicago’s meat-packing district to produce a new kind of edible product. Amidst a slew of slaughterhouses in every direction, John Edel and his company, “The Plant” yield pristine produce of the vegetative kind. Edel uses advanced LED grow lights to give life to his photosynthetic friends, lettuces and herbs grown in concert with fish. As in other aquaponic systems, fish waste in ammonia form is lifted throughout a series of plant beds, where naturally-occurring bacteria transform that ammonia into nitrites and then nitrates, a rich substance that feeds his produce.

Edel’s plan is to prove that empty warehouse space in cities around the world are ripe territory for future farming. Entrepreneurs like John can occupy this space and apply new age technology to farm vast amounts of food in limited space. Even with sunlight taken out of the equation, farmers can use aquaponic technology to raise produce and protein without breaking soil or wasting the water lost in traditional agriculture.


4.  Green Sky Growers: The Future of Farming

Not far from Orlando, Florida, an organic orange farmer and a biologist with Epcot Center experience have teamed up to build the true farm of the future. On a rooftop above their city center, Green Sky Growers use aquaponics and vertical farming to grow massive yields of produce and fresh, healthy tilapia using less than 10% of the water needed for traditional farming. As much a science lab as a farm, this facility uses a software-controlled greenhouse that ventilates based on local temperature, rotating plant towers that soak up solution from fish tanks, and happy tilapia that consume plant waste to produce nutrient-rich water.

A myriad of vegetables grow in this greenhouse year-round, where lettuces, herbs, peppers, tomatoes, cucumbers and more grow in a hydroponic setting while aquaculture tanks complete a biological closed-loop. Every Saturday, their produce is made available at a farmer’s market on the streets below in Winter Garden, Florida, inviting interested foodies up for a tour of the facility. Technology is everywhere in this farm, but the plants it yields are as organic as can be. No pesticides, genetic modifiers or toxic waste occur in this new-aged farm. It is the perfect marriage of technology and nature, where the people who run it understand the delicate balance between sensible agriculture and sustainable business. Visitors to the Orlando area might find more inspiration and fun in this rooftop farm than they would at the area’s entertainment district, where Mickey and Minnie Mouse dominate the environment.

     

Aquaponics' Origin

Aquaponics, with its fancy name, may sound like a trendy new concept developed by environmentalists. But it's actually as old as the hills.

The origins of aquaponics can be traced to ancient Egyptian and Aztec cultures.

The ancient Aztecs developed chinampas, man-made floating islands, which consisted of rectangular areas of fertile land on lake beds.

Aztecs cultivated maize, squas­h and other plants on the chinampas and fish in the canals surrounding them.

The fish waste settled on the bottom of the canals, and the Aztecs collected the waste to use as fertilizer.

Additionally, countries in the Far East like Thailand and China have long used aquaponic techniques in rice paddies.

Permaculture + Aquaponics = Self Sustaining

By bringing Permaculture Design principles and practices into Aquaponics, we are closing many loops, inefficiencies, and energy drains that exist in more conventional systems, as well as integrating the system appropriately into the larger landscapes and ecologies it is a part of, making it a much more holistic and sustainable enterprise. 

Closed-Loop Aquaponics focuses on designing aquaponics systems that that produce as much of the system’s needs (water, energy, fish, feed, heat, gas, etc.) on-site and within the system itself as possible. 

Products of the systems can include; solar electricity, solar heated air, solar heated water, fish, prawns, vegetables, fruit, aquatic plants, algae, minnows, snails, worms, dry and liquid fertilizers, methane gas, and more. By using the Permaculture Design process, we learn to design systems appropriate to diverse climates and unique ecological niches to meet various needs, dreams, and desires.

Aquaponics' Advantages - Commercially

credit to http://centerforaquaponics.com

Aquaponic systems possess many attractive commercial applications, as well as environmental and human health benefits, making them ideal for future use in developing regions of the world. Quantifiable results include:

• Additive water conservation benefits of recirculating aquaculture and hydroponics combined into an integrated waste free system. With uncertainty regarding water supplies and the population carrying capacity of arid regions of the world, water conservation practices may result in aquaponics replacing more traditional forms of food production. Additionally, the plant and microbial remediation of the fish effluent (waste) prevents environmental contamination (eutrophication) common with many forms of aquaculture.

• A controlled-environment greenhouse operation greatly increases the reliability of production while reducing the risk of environmental degradation such as non-native species introduction which is prevalent with other forms of agriculture. Through the prevention of greenhouse pest outbreaks the need for synthetic pesticides has been eliminated.

• Combining aquaculture and hydroponics technologies has demonstrated the potential to exceed the productivity and profitability of independently operated systems for a given resource constraint (land, water, capital).

• Unlike warm blooded food stocks, cultured aquatic species are not considered high probability vectors of zoonotic diseases to humans. They require fewer inputs (feed and time) than other livestock. The feed conversion ratio and carbon footprint for farmed fish is significantly less than other sources for animal protein.

• The technologies employed to run an aquaponics operation can be primitive and produced from a large range of readily available (post-consumer) materials. This lowers the overall environmental footprint of the design and broadens the availability of the technology to poorer regions of the world.

Aquaponics is Organic

Organic Grown Food

http://www.epa.gov/agriculture/torg.html

"Organically grown" food is food grown and processed using no synthetic fertilizers or pesticides. Pesticides derived from natural sources (such as biological pesticides) may be used in producing organically grown food.

Organic Farming

http://en.wikipedia.org/wiki/Organic_farming

Organic farming is a form of agriculture that relies on techniques such as crop rotation, green manure, compost and biological pest control. Organic farming uses fertilizers and pesticides but excludes or strictly limits the use of manufactured (synthetic) fertilizers, pesticides (which include herbicides, insecticides and fungicides), plant growth regulators such as hormones, livestock antibiotics, food additives, genetically modified organisms, human sewage sludge, and nanomaterials.

Organic agricultural methods are internationally regulated and legally enforced by many nations, based in large part on the standards set by the International Federation of Organic Agriculture Movements (IFOAM), an international umbrella organization for organic farming organizations established in 1972. IFOAM defines the overarching goal of organic farming as:

"Organic agriculture is a production system that sustains the health of soils, ecosystems and people. It relies on ecological processes, biodiversity and cycles adapted to local conditions, rather than the use of inputs with adverse effects. Organic agriculture combines tradition, innovation and science to benefit the shared environment and promote fair relationships and a good quality of life for all involved..."

—International Federation of Organic Agriculture Movements

Organic Products 

http://www.ams.usda.gov/AMSv1.0/getfile?dDocName=STELDEV3004446&acct=nopgeninfo

Organic products have strict production and labeling requirements. Unless noted below, organic products must meet the following requirements:

- Produced without excluded methods; genetic engineering, ionizing radiation, or sewage sludge.

- Produced per the National List of Allowed and Prohibited Substances (National List).

- Overseen by a USDA National Organic Program authorized certifying agent,

- Following all USDA organic regulations.

An overview of labeling the various categories of organic products is provided below.

PRINCIPAL DISPLAY PANEL: portion of the package most likely to be seen by customers at the time of purchase.

INFORMATION PANEL: includes ingredient statement (list of ingredients contained in a product, from highest to lowest percentage of final product) and other product information.

100% Organic

Raw or processed agricultural products in the “100 percent organic” category must meet these criteria:

- All ingredients must be certified organic.

- Any processing aids must be organic.

- Product labels must state the name of the certifying agent on the information panel.

An overview of labeling the various categories of 100% organic products is provided below.

PRINCIPAL DISPLAY PANEL: May include USDA organic seal and/or 100 percent organic claim.

INFORMATION PANEL: Must identify organic ingredients (e.g., organic dill) or via asterisk or other mark.

Normal Organic

Raw or processed agricultural products in the “organic” category must meet these criteria:

- All agricultural ingredients must be certified organic, except where specified on National List.

- Non-organic ingredients allowed per National List may be used, up to a combined total of five percent of non-organic content (excluding salt and water).

- Product labels must state the name of the certifying agent on the information panel.

An overview of labeling the various categories of normal organic products is provided below.

PRINCIPAL DISPLAY PANEL: May include USDA organic seal and/or organic claim.

INFORMATION PANEL: Must identify organic ingredients (e.g., organic dill) or via asterisk or other mark.

Organic Certification

http://en.wikipedia.org/wiki/Organic_certification

Organic certification is a certification process for producers of organic food and other organic agricultural products. In general, any business directly involved in food production can be certified, including seed suppliers, farmers, [food] processors, retailers and restaurants.

Requirements vary from country to country, and generally involve a set of production standards for growing, storage, processing, packaging and shipping that include:

• no human sewage sludge fertilizer used in cultivation of plants or feed of animals
• avoidance of synthetic chemical inputs not on the National List of Allowed and Prohibited Substances (e.g. fertilizer, pesticides, antibiotics, food additives, etc.), genetically modified organisms, irradiation, and the use of sewage sludge;
• use of farmland that has been free from prohibited synthetic chemicals for a number of years (often, three or more);
• keeping detailed written production and sales records (audit trail);
• maintaining strict physical separation of organic products from non-certified products;
• undergoing periodic on-site inspections.