RU86405U1 - BIOTECHNOLOGICAL COMPLEX FOR GROWING WATER OBJECTS IN NATURAL RESERVOIRS - Google Patents

Abstract

1. Biotechnological complex for growing water bodies in natural reservoirs, including a main cage attached to pontoons, as well as an additional smaller cage placed in it, which are designed for the isolated cultivation of fish of different species, characterized in that it additionally contains cultivators for growing aquatic plants and algae attached to the pontoons along the outer contour of the main charge, aerators and sludge dewatering station, while the bottom of the main charge is made in the form of systems interconnected conical elements, the tops of which are connected by means of flexible pipelines to a highway transporting bottom sediments to a dewatering station, and the upward-facing bases of the conical elements are equipped with covers with slots for collecting bottom sediment, and shelters for crayfish are made on each cover, made in the form rows of vertical stripes covered with horizontal plates. ! 2. The biotechnological complex according to claim 1, characterized in that between the main and additional cages are collectors for growing bivalve mollusks.

Description

The utility model relates to fish farming, namely to the field of aquaculture and ecology and can be used to obtain products such as fish and invertebrates, as well as feed and fertilizer for the soil. At the same time, in the process of growing hydrobionts, water will be cleaned from excess organics and nutrients.

A known method of cultivating a bivalve mussel mussel in biculture with rainbow trout, characterized in that as the carriers of the collectors use the design of the floating platform of the cage, fixing them stationary from the outside and the inside (Application for invention No. 2004138171/12 from 12.27 of 2004). This technology helps to reduce the cost of production of the main object (trout), as well as increase the productivity of the accompanying object (mussel) compared to its growth in natural conditions when grown separately. At the same time, mussels, as filtrators, purify water, consuming through the food chain an excess of organics and nutrients entering the reservoir as a result of the life of the fish.

The disadvantage of this method is that the use of intensively filtering water mussels leads to an increase in the volume and rate of sediment accumulation, which can cause a deterioration in the hydrochemical regime and eutrophication of closed marine areas.

A known installation for growing fish, including a fish tank with an aerator, a coarse filter, a cultivator with filamentous algae and mollusks, as well as a cultivator with higher aquatic plants, characterized in that the fish tank is connected to a coarse filter using a bottom sampling device precipitation (USSR Author's Certificate No. 789082, Cl. А01К 61/00, 1979). This installation provides a fine purification of water from fish vital products with the help of microorganisms, mollusk filters, as well as algae and higher aquatic plants.

The disadvantage of this device is its complexity and the ability to use only in artificial conditions.

A known method of purification of water of natural reservoirs from pollution, mainly by heavy metals, while obtaining products of fish and invertebrates (RF Patent (19) RU 2126624 (13) C1, (51) 6 A01K 63/04, C02F 3/32). This method involves the construction of a channel in communication with the reservoir, equipped with a lock and overflow dam. Mollusks and fish are introduced into the canal, as well as heating and aeration of the incoming water are carried out. In this case, the mollusks accumulate pollution and are periodically removed from the channel.

The disadvantages of this method are the large capital costs necessary for the construction of channels, locks and dams, as well as energy costs for heating the treated water.

Known installation "Atoll" (a group of companies "Water", Moscow) used to clean water from pollution using higher aquatic vegetation and zooplankton. This device is a floating ring-shaped platform, which is installed in a polluted reservoir. The ground was laid along the perimeter of the platform and marsh plants were planted. The middle of the platform is a chamber of fine-mesh material in which zooplankton develops. With the help of a wind or electric engine, a stream of water is created, which washes the structure. In this case, the thickets of bog plants absorb nutrients, and zooplankton - algae and bacteria.

The disadvantage of this method is that zooplankton is very sensitive to contamination and is characterized by extreme developmental instability. - In fairly clean, non-flowing reservoirs, it occasionally develops throughout the water area, and in polluted ones it develops weakly or does not develop at all. In particular, in eutrophic water bodies, the development of zooplankton is suppressed by the rapid development of blue-green algae (cyanobacteria)

The known technology of pneumatic extraction of bottom sediment (sapropel) and its processing without storage tanks using the electrophoresis http://saprex.ru/p121.htm). According to this technology, sapropel is fed into a storage hopper, in which after 30 minutes a marketable mass of 60% moisture is obtained. This mass, if final granular products are not required, is packaged in auger batcher in bags and delivered to the distribution network. The storage hopper can be installed on the shore, and with small production volumes - on a floating pontoon next to the mining device.

This technology can also be used to remove bottom sediment formed under cages. However, to carry out such work, it is necessary to first remove the cages from the water, which interrupts the fish breeding process and increases the labor costs for growing fish.

The known method of spatial isolation in cage fish growing in polyculture (Karachev R.A., Vlasov V.A., Labenets A.V., Lippo E.V. Use of spatial isolation in cage fish growing in polyculture. An interdepartmental collection of scientific and methodical works. M., Publishing house LLC "Rainbow plus", issue 2, 2007, S. 48-56.)

This method allows, along with the planned volume of the main production of sturgeon fish, to obtain about 45% of the additional production of herbivorous fish - white, colorful and hybrid silver carp, as well as grass carp. This effect is achieved due to the consumption by these fish of the remains of food specified by sturgeon, as well as their metabolic products (excrement and detritus), plankton and periphyton fouling on the walls of cages. At the same time, a good reclamation effect is noted - an improvement in the hydrological regime of cages and a reduction in labor costs for cleaning the delhi, as well as a decrease in the amount of sediment polluting the bottom of the reservoir.

However, this method has a common disadvantage of cage fish rearing — the accumulation (albeit somewhat slower) of a significant amount of sediment at the bottom of the reservoir. Over time, this leads to a significant deterioration in the hydrochemical regime of the water area and the eutrophication of the reservoir as a whole. From time to time, with the threat of fish killing and death, cages have to be removed from the water and work is carried out to remove bottom sediment.

The technical task of the claimed utility model is to increase the efficiency of growing water bodies, as well as the cleaning and fisheries management of contaminated water bodies by using and subsequently removing excess organics and nutrients.

This object is achieved by the fact that in the biotechnological complex for growing water bodies in natural waters, including the main cage attached to the pontoons, as well as an additional smaller cage placed in it, which are designed for the isolated cultivation of fish of various species, cultivators for growing aquatic plants are additionally installed and algae, which are attached to the pontoons along the outer contour of the main cages, as well as an aerator and dewatering station, while the bottom of the main Adka is made in the form of a system of conjugated conical elements, the tops of which are connected via flexible pipelines to a highway transporting bottom sediments to the dewatering station, and the upward-facing bases of the conical elements are equipped with covers with slots for sampling the bottom sediment, while shelters are mounted on each cover for crayfish made in the form of rows of vertical stripes covered with horizontal plates.

In addition, between the main and additional cages there are collectors for growing bivalve mollusks.

A diagram of a utility model is depicted in figure 1. General view.

A biotechnological complex for growing water bodies in natural waters, including a main cage 2 attached to the pontoons 1, as well as an additional cage 3 of smaller sizes, which are designed for the isolated cultivation of fish of different species, while it additionally contains cultivators 4 and 5 for growing aquatic animals plants and algae attached to the pontoons 1 along the outer contour of the main cage 2, the aerator 6 and the dewatering station 7, while the bottom of the main cage 2 is made in the form of a conjugated system interconnected conical elements 8, the tops 9 of which are connected by means of flexible pipelines 10 with a highway 11 transporting bottom sediments to the dewatering station 7, and the upward-facing bases of the conical elements 8 are equipped with covers 12 with slots 13 for sampling the bottom sediment, with each cover 12 reinforced shelters 14 for crayfish, made in the form of rows of vertical stripes 15, covered with horizontal plates. 16.

In addition, between the main and additional cages placed collectors 17 for the cultivation of bivalve mollusks.

Environmental prerequisites for the use of the proposed complex are that the problem of pollution of water bodies in densely populated regions of Russia over time becomes more acute. At the same time, most water bodies are subject to pollution not with toxic substances, but with an excess of nutrients. Increased concentrations of these elements lead to the rapid development of planktonic algae, whose production in large reservoirs is measured in millions of tons. These algae gradually die off and settle to the bottom, slowly decompose and degrade water quality according to hydrochemical and bacteriological indicators. At the same time, cleaning water bodies by draining water and removing bottom sediments is associated with significant material costs, is not always feasible for technical reasons and gives only a temporary effect.

Growing fish in cages along with advantages has its negative sides. - Dense fish landing and intensive feeding also lead to the accumulation of bottom sediments and the progressive eutrophication of water bodies. - When mixed feed is added to a reservoir, a large amount of excrement is formed which precipitates and impairs water quality. In this regard, the area of cages according to standards should not exceed 0.1% of the area of the reservoir, which limits the development of commercial fish farming.

Therefore, for the further development of cage fish farming, methods and devices are needed to develop contaminated water bodies, using and removing excess organics and nutrients in the process of growing water bodies. For this, at the first stage of development of a polluted reservoir, the proposed biotechnological complex can be used in a slightly truncated form, as a treatment plant, which may include collectors for growing bivalves, cultivators for growing higher aquatic plants or algae, devices for collecting sediment and aeration of water as well as sludge dewatering stations.

Objects that are promising for growing on collectors are some types of freshwater, brackish-water and marine bivalve mollusks, which are able to attach to underwater objects and form abundant clusters on them.

At the same time, artificial accumulations of mollusks created with the help of a floating structure daily provide a fine purification from organic and mineral suspensions, algae and bacteria of a volume of water comparable to the volume of water in the surrounding water area. Such a structure is a powerful tool that allows not only to clean the reservoir, but also to receive a large amount of raw biomass of mollusks.

To increase the intensity of water purification and the growth of mollusks in the upper layer of water, an aerator is created by using an aerator that carries oxygen to the mollusks and plentiful food — phyto-zoobacterioplankton and detritus. At the same time, plentiful nutrition of mollusks is accompanied by the formation of a large number of feces and pseudo-feces, which descend and are sent to a dehydration station using a device for collecting bottom sediments. Then they are packaged in bags and enter the distribution network as fertilizers for the soil. This organic sludge can also be used as raw material for biofuels.

Bivalve mollusks can also be used to purify water in hatcheries with a closed water supply.

The growing biomass of mollusks can be used as a component of combined feeds. If necessary, you can use "hard" processing techniques that can eliminate bacterial contamination from mollusk meat, as well as neutralize pesticides and other toxic substances to levels significantly lower than MPC.

The mollusk flaps contain a significant amount of trace elements and can serve as raw materials for the production of mineral flour, which can be useful as a component of fish feed. Excess shells can be used to prepare feed additives for poultry and other domestic animals, as well as building materials (artificial shell rock) or fertilizers for the soil.

In addition to bivalve mollusks, higher aquatic plants play an important role in the self-purification of freshwater bodies of water. Moreover, their high practical value lies not so much in the effect of concentration of pollutants as in the ability to decompose them into less toxic components, and, ultimately, to neutralize them.

To use plants to clean the reservoir of excess nutrients, they must be placed in cultivators (shallow floating perforated trays for growing higher aquatic plants or algae) located around the floating structure. Moreover, in freshwater reservoirs, various groups of higher plants and algae can be used - floating on the surface of the water, immersed in water or surface (marsh) plants.

At the first stage of the development of the reservoir, the excess biomass of plants and algae can be used to prepare fertilizers by composting, or as raw material for biofuels.

When the reservoir is cleaned to the level of sanitary and fishery standards, you can proceed to the second stage of development of the reservoir. For this, it is necessary to establish the proposed biotechnological complex in its entirety. After its installation, cages are stocked. - Sturgeon (or salmon) fish are launched into an additional cage, and herbivorous (white, motley and hybrid silver carp, grass carp), as well as river crayfish, in the main one.

The process of growing fish, plants and invertebrates using the proposed biotechnological complex is as follows. - Sturgeons located in the additional cage 3 (figure 1), receive food in accordance with fish breeding standards. In this case, the fish secrete a lot of excrement, which gradually passes through the walls and bottom of the additional cage 3. In addition, in the process of consumption of the feed, some of it (about 5%) is lost, and also passes through the walls and bottom of the cage. Suspended in the water and sinking to the bottom, feed excrement, fish excrement, and also brought from the reservoir by a surface stream of water into the main cage 2, phyto-zoobacterioplankton and detritus are filtered by mollusks located on the collectors 17. In this case, mollusks that are more perfect than in herbivorous fish by a filtering apparatus, they almost completely purify water from the smallest suspended particles. However, they consume only about 10% of the filtered material, and the remaining 90% is excreted in the form of feces and pseudo-feces, which sink down and form a precipitate on the lids. This sediment (detritus) consumes a white silver carp. Motley and hybrid silver carp besides detritus consume zooplankton. Amur white actively consumes periphyton fouling of plant origin (filamentous and other algae) that are formed on the walls of cages - both the main 2 and additional 3. In addition, to improve the growth of white amur, the excess biomass of higher plants and algae is periodically introduced into the cage 2, which is formed in cultivators 4 and 5.

Sturgeon fish in additional cage 3 also receive additional food - live mollusks. At the same time, large fish are able to remove mollusks directly from the collectors, and for smaller fish, they must first be crushed. - Natural live food contains biologically active components that are absent even in the highest quality compound feeds, so their consumption has a positive effect on the increase in fish biomass and the quality of the final product.

Crayfish, which occupy shelters 14 on covers 12, receive abundant food - excrement of herbivorous fish, as well as invertebrates (chironomids, oligochaetes, misid, etc.), which develop in abundance in mollusks of mollusks on collectors 17.

The organic sediment falling on the lids 12 is delayed for some time on them and is consumed by fish and crayfish. Over time, the excess of this sludge enters through the slots 13 in the covers 12 into conical elements 8, the peaks 9 of which communicate via flexible pipelines 10 with a line 11, with which the sludge is transported to the dewatering station 7. Then the dehydrated sludge is packaged in bags and delivered to the distribution network as a fertilizer for the soil.

The proposed biotechnological complex can be used in conditions of complex internal water bodies - in rivers with a slow flow, in lakes, ponds and reservoirs. Especially suitable for this are cooling ponds of thermal and nuclear power plants. Subject to the selection of appropriate hydrobionts, this technology can be implemented in closed marine areas. Its introduction into the practice of cage fish farming will allow to obtain the following positive effects:

1. To increase the efficiency of the use of expensive compound feed, as well as to increase the growth and quality of the main delicatessen products of sturgeon and salmon fish, due to the receipt and feeding to fish of natural live food - bivalves.

2. To receive, along with the planned volume of the main product, also a significant amount of additional fish products due to the use by the herbivorous fish of food residues and vital products of sturgeon fish, biomass of higher plants and algae, as well as a significant amount of phyto-zoobacterioplankton and detritus filtered into the cage bivalve mollusks and excreted in the form of feces and pseudofecals.

3. Additionally, to receive gourmet products - crayfish, using the excrement of herbivorous fish, as well as invertebrates (chironomids, oligochaetes, mysid, etc.), which develop in abundance in molluscs of drums.

4. To receive a significant amount of raw mass of mollusks, the meat of which can be processed and used as a component of animal feed, as well as for other purposes. Moreover, mollusk flaps containing a significant amount of microelements can be used for the production of mineral flour, which can be useful as feed additives for fish, poultry, and other domestic animals.

5. Use the huge production potential of eutrophic reservoirs, clean them of excess organics and nutrients, improve sanitary conditions, and also receive a large amount of fertilizer for the soil. At the same time, obtaining a significant amount of accompanying gourmet products of sturgeons and crayfish, as well as additional products of herbivorous fish and feed mollusks, will make the whole process as a whole, and the cleaning of reservoirs in particular, a cost-effective affair.

6. Receive additional products using shells of mollusks for the preparation of building materials (artificial shell rock), and organic sludge as fertilizers for soil or raw materials for biofuel production.

Claims (2)

1. Biotechnological complex for growing water bodies in natural reservoirs, including a main cage attached to pontoons, as well as an additional smaller cage placed in it, which are designed for the isolated cultivation of fish of different species, characterized in that it additionally contains cultivators for growing aquatic plants and algae attached to the pontoons along the outer contour of the main charge, aerators and sludge dewatering station, while the bottom of the main charge is made in the form of systems interconnected conical elements, the tops of which are connected by means of flexible pipelines to a highway transporting bottom sediments to a dewatering station, and the upward-facing bases of the conical elements are equipped with covers with slots for collecting bottom sediment, and shelters for crayfish are made on each cover, made in the form rows of vertical stripes covered with horizontal plates. 2. The biotechnological complex according to claim 1, characterized in that between the main and additional cages are collectors for growing bivalve mollusks.