Within intensive and extensive aquaculture methods, numerous specific types of fish farms are used; each has benefits and applications unique to its design.
Cage system is often raised in cages in central Thailand. Fish cages are placed in lakes, bayous, ponds, rivers, or oceans to contain and protect fish until they can be harvested. when the cages are placed in the sea. They can be constructed of a wide variety of components. Fish are stocked in cages, artificially fed, and harvested when they reach market size. A few advantages of fish farming with cages are that many types of waters can be used (rivers, lakes, filled quarries, etc.), many types of fish can be raised, and fish farming can co-exist with sport fishing and other water uses. Marine Scotland has kept records of caged fish escapes since 1999. They have recorded 357 fish escape incidents with 3,795,206 fish escaping into fresh and salt water. One company, Dawnfresh Farming Limited, has been responsible for 40 incidents and the escape of 152,790 rainbow trout into freshwater lochs. Though the cage-industry has made numerous technological advances in cage construction in recent years, the risk of damage and escape due to storms is always a concern.
Semi-submersible marine technology is beginning to impact fish farming. In 2018, 1.5 million
salmon are in the middle of a year-long trial at Ocean Farm 1 off the coast of
Norway. The semi-submersible project is the world's first deep-sea aquaculture project, and includes -high by -diameter pen made from a series of mesh-wire frames and nets. It is designed to disperse wastes better than more conventional farms in sheltered coastal waters, therefore supporting higher fish packing density. In
Maritime Southeast Asia, traditional fish cages built around an offshore wooden platform are generally called
kelong. They are usually used to temporarily keep caught fish until sold or cooked, but some are used for fish farming.
Copper-alloy nets Recently,
copper alloys have become important netting materials in
aquaculture. Copper alloys are
antimicrobial, that is, they destroy
bacteria,
viruses,
fungi,
algae, and other
microbes. In the
marine environment, the antimicrobial/algaecidal properties of copper alloys prevent
biofouling, which can briefly be described as the undesirable accumulation, adhesion, and growth of microorganisms, plants,
algae,
tube worms,
barnacles,
mollusks, and other organisms. The resistance of organism growth on copper alloy nets also provides a cleaner and healthier environment for farmed fish to grow and thrive. Traditional netting involves regular and labor-intensive cleaning. In addition to its antifouling benefits, copper netting has strong structural and corrosion-resistant properties in marine environments. Copper-zinc brass alloys are deployed in commercial-scale aquaculture operations in Asia, South America, and USA (Hawaii). Extensive research, including demonstrations and trials, are being implemented on two other copper alloys: copper-nickel and copper-silicon. Each of these alloy types has an inherent ability to reduce biofouling, cage waste, disease, and the need for antibiotics, while simultaneously maintaining water circulation and oxygen requirements. Other types of copper alloys are also being considered for research and development in aquaculture operations.
Fish pens in
Pangasinan,
Philippines ,
Philippines In the
Philippines, traditional enclosures used to farm fish directly on shallow bodies of water are called
fish pens. They differ from fish cages in that fish pens are not floating and do not have an artificial bottom. Instead, the seabed, riverbed, or the lakebed provides the floor of the enclosure. They are usually much larger than fish cages and come in various shapes like circles, squares, or rectangles. The fences that enclose the fish pen area are made from bamboo or wooden poles, netting, and ropes. The poles are sunk into the substrate at depths of . Fish pens often have a hut
raised on stilts nearby that function as a warehouse and accommodations for caretakers that may be necessary to guard against
poachers. Fish pens commonly cover large areas of bodies of water (both freshwater and marine) in the Philippines, similar to farm plots. Licenses are required to operate fish pens, and operators are usually granted a limited area for fish farming. Marine fish pens are commonly used to farm wild-caught juvenile
groupers. Due to their open-water nature and their typically large areas, supplemental feeding is typically not required for fish pens (unlike in fish cages and fish ponds), though some operators may provide additional feed for fingerlings like bread crumbs,
fish meal,
egg yolk, or plant leaves. The fish are living in natural water but are isolated with a net. Because the only barrier separating the fish from the surrounding environment is a net, this allows the water to flow from the 'natural' surrounding through the fish farms. The site of the fish farm is crucial for the farm to be a success or not. Before any fish farm is settled, it is highly recommended to be selective with the site location of the farm. The site must be examined on some essential elements. Important conditions on the location are: • A good interchange of water and also a high replacement of bottom water. • At all depths should be a good current condition. This is necessary because the organic particles should be able to be carried away using the current. • A gravel and sand bottom are qualified for fish farming, although bottoms with silt and mud are not qualified. These should be avoided. • A net should be at least or more above the bottom, so depth is important. Despite these important site conditions, the open net pen method was very popular in Norway and China. This is because of the cost friendliness and efficiency of this method.
Negative external effects Because of the ocean's water flow and other reasons, open net pen culture is seen as a high-risk method for the environment. The flow allows chemicals, parasites, waste and diseases to spread in the enclosed environment, and this is not beneficial for the natural environment. Another negative consequence is the high escape rate of the cultured fish from these open net pens. These escaped fish also pose a high risk to the surrounding ecosystems. The amount of organic waste produced by fish farms is also alarming. A salmon farm in
Scotland, for instance, is estimated to produce as much organic waste as equivalent to a town of people between 10,000 and 20,000 people each year. Today 50% of the world's seafood is farm-raised.
Irrigation ditch or pond systems project in a rural village in the
Congo. These use
irrigation ditches or farm ponds to raise fish. The basic requirement is to have a ditch or pond that retains water, possibly with an above-ground irrigation system (many irrigation systems use buried pipes with headers). Using this method, water allotments can be stored in ponds or ditches, usually lined with
bentonite clay. In small systems, the fish are often fed commercial fish food, and their waste products can help fertilize the fields. In larger ponds, the pond grows water plants and algae as fish food. Some of the most successful ponds grow introduced strains of plants, as well as introduced strains of fish. Control of water quality is crucial. Fertilizing, clarifying, and
pH control of the water can increase yields substantially, as long as
eutrophication is prevented and oxygen levels stay high. Yields can be low if the fish grow ill from electrolyte stress.
Composite fish culture The composite fish culture system is a technology developed in India by the
Indian Council of Agricultural Research in the 1970s. In this system, of both local and imported fish, a combination of five or six fish species is used in a single fish pond. These species are selected so that they do not compete for food among them by having different types of food habitats. As a result, the food available in all the parts of the pond is used. Fish used in this system include
catla and
silver carp (surface feeders),
rohu (a column feeder), and
mrigal and
common carp (bottom feeders). Other fish also feed on the excreta of the common carp, and this helps contribute to the efficiency of the system which in optimal conditions produces 3000–6000 kg of fish per hectare per year. One problem with such composite fish culture is that many of these fish breed only during monsoon. Even if fish are collected from the wild, they can be mixed with other species, as well. Thus, a major problem in fish farming is the lack of availability of good-quality stock. To overcome this problem, ways have now been worked out to breed these fish in ponds using hormonal stimulation. This has ensured the supply of pure fish stock in desired quantities.
Integrated recycling systems ,
Armenia) One of the largest problems with freshwater pisciculture is that it can use a million gallons of water per acre (about 1 m3 of water per m2) each year. Extended
water purification systems allow for the reuse (
recycling) of local water. The largest-scale pure fish farms use a system derived (admittedly much refined) from the
New Alchemy Institute in the 1970s. Basically, large plastic fish tanks are placed in a greenhouse. A
hydroponic bed is placed near, above or between them. When tilapia are raised in the tanks, they are able to eat algae, which naturally grow in the tanks when the tanks are properly fertilized. The tank water is slowly circulated to the hydroponic beds, where the tilapia waste feeds commercial plant crops. Carefully cultured microorganisms in the hydroponic bed convert
ammonia to
nitrates, and the plants are fertilized by the nitrates and
phosphates.Other wastes are strained out by the hydroponic media, which double as an aerated pebble-bed filter. This system, properly tuned, produces more edible protein per unit area than any other. A wide variety of plants can grow well in the hydroponic beds. Most growers concentrate on
herbs (e.g.
parsley and
basil), which command premium prices in small quantities all year long. The most common customers are
restaurant wholesalers. Since the system lives in a
greenhouse, it adapts to almost all temperate climates, and may also adapt to
tropical climates. The main environmental impact is discharge of water that must be salted to maintain the fishes'
electrolyte balance. Current growers use a variety of proprietary tricks to keep fish healthy, reducing their expenses for salt and wastewater discharge permits. Some veterinary authorities speculate that ultraviolet ozone disinfectant systems (widely used for ornamental fish) may play a prominent part in keeping the tilapia healthy with recirculated water. A number of large, well-capitalized ventures in this area have failed. Managing both the biology and markets is complicated. One future development is the combination of integrated recycling systems with urban farming as tried in Sweden by the
Greenfish Initiative.
Classic fry farming This is also called a "flow through system". Trout and other sport fish are often raised from eggs to
fry or fingerlings and then trucked to streams and released. Normally, the fry are raised in long, shallow, concrete tanks, fed with fresh stream water. The fry receive commercial fish food in pellets. While not as efficient as the New Alchemists' method, it is also far simpler and has been used for many years to stock streams with sport fish. European eel (
Anguilla anguilla) aquaculturalists procure a limited supply of glass eels, juvenile stages of the European eel which swim north from the
Sargasso Sea breeding grounds, for their farms. The European eel is threatened with extinction because of the excessive catch of glass eels by Spanish fishermen and overfishing of adult eels in, e.g., the Dutch
IJsselmeer. Although European eel larvae can survive for several weeks, the full life cycle has not yet been achieved in captivity. == Issues ==