RU2487536C1 - Compact fish-breeding assembly of closed water supply - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to the field of fish-culture. The assembly comprises pools, water-locking devices and an electric pump interconnected in a closed circulation loop. Also the assembly comprises a system of aeration and thermal control, a unit of level-sensitive automation and a water level sensor. The storage and water drive pools and also pools of biological purification are located in the central part of the assembly, are interconnected and mounted in three tiers. The pools of loading, cultivation of feed, water reserve are located in the left and right parts of the assembly and are mounted in two tiers.

EFFECT: invention improves efficiency, productivity and technological capabilities of the assembly.

4 cl, 1 dwg

Description

The present invention relates to the field of fish farming, namely to closed fish breeding devices, and can be used to obtain planting material for fish ponds, in particular farmers fish farms.

Year-round supply of urban population with live fish translates into the problem of creating aquaculture farms. The main production of salable fish can be carried out in flowing ponds with natural thermal water. The production cycle in these ponds can be significantly shortened if they are stocked with planting stock in mid-May. In this regard, it is advisable to carry out accelerated spawning and sequential incubation with the growth of larvae. In view of the fact that, at a suitable time for this, the natural temperature of water is much lower than necessary, both for the final maturation of producers and the development and growth of embryos and larvae, it is advisable to carry out these processes under conditions of complete control of environmental conditions, which provide closed-loop water circulation systems. The stocking of reservoirs with viable material reduces fish waste during the rearing process, ensures the production of marketable fish of large mass in a shorter time, reduces the cost of feed per unit of farmed fish, affects the effectiveness of the process - the percentage of return of salable and mature fish increases.

Known installations with a closed water exchange (UZV) for the cultivation of planting material for fish (Colman RV "Installations with a closed water exchange in sturgeon breeding" Aquaculture development strategy in the 21st century. Materials of the international scientific and practical conf. Aug. 23-27 2004 Minsk: ODO "Tonpik" p.53-58) (1) consist of autonomous production lines located in separate workshops: a workshop for keeping producers, a workshop for incubating eggs, a workshop for growing larvae and fry. The workshops occupy large areas, which significantly increases the cost of aquaculture. Especially if such a farm is located near a city where the land is very expensive. With a differentiated land price, an increase in farm productivity per unit of occupied space is desirable. In addition, during the operation of several workshops, there is a large consumption of water, high energy costs to maintain the optimum water temperature in several autonomous technological lines, and also require large costs for technical and hardware equipment.

Known installation for fish farming (French application No. 2520584, MKI A01K 61/00) (2), containing three pools: a reserve, for biothermal balance, and a worker, which communicate with each other in a closed loop through a block for water treatment. The known device does not provide a pool for the cultivation of live food and an incubator of eggs, which reduces the technological capabilities of the installation.

Closest to the proposed installation is, selected as a prototype, a plant for growing juvenile Atlantic salmon (Proskurenko I.V. “Enclosed fish hatcheries”: VNIRO Publishing House, 2003 p. 87-88) (3). The installation includes four load pools (fish-breeding), at the output of which a microfilter with a sieve is installed, where the mechanical impurities coming from the pools are separated on the microfilter. Purified from mechanical impurities, water from a microfilter is fed into a biological filter. After the biofilter, water accumulates in the storage tank and then is pumped through the bactericidal irradiator, sand filter, heat exchanger and aerator into the ballast (water) tank, from where it is supplied to the load pools. Make-up is carried out in a ballast (water) container, and the removal of excess water from the system is done through the overflow of the storage tank.

A disadvantage of the known installation is the large footprint, because all pools are located on one level. In addition, the device does not provide a pool for the cultivation of feed, and also does not provide an incubator for the incubation of eggs, which reduces installation capabilities and increases the cost of growing planting material.

The aim of the invention is to reduce the economic costs of growing planting stock for fish ponds.

The goal is achieved in that a compact fish breeding facility for closed water supply, including load pools, a biological treatment pool, a water pool, a storage pool, an electric pump, an aeration and thermoregulation system, interconnected into a closed circulation circuit by means of collectors, according to the invention is additionally equipped with a level automation unit , a water level sensor, fluorescent lamps, and pools for reserve are additionally included in the closed circulation circuit water, pools for the cultivation of feed, a flute for aeration of water, while the collectors are equipped with water shutoff devices for regulating the flow of water in the circuit, and the installation is divided into the left, right and central parts, where the storage pool, biological treatment pool and water pressure pool are located in the central parts of the installation, communicated with each other and mounted in three tiers, load pools, pools for the cultivation of feed, pools for water reserve are located on the left and right side of the installation and are mounted in two tiers, while the entrances of the load pools and the pools for the cultivation of feed are connected to the water basin through the collector for the supply of purified water and water shut-off devices, and the outputs are connected to the storage pool through the collector for the discharge of waste water, which is additionally connected through the water block to the discharge pipe water from the installation and to the exits of the pools for water reserve, the inlets of which are connected through a water-locking device to the water supplying the installation, the aeration system and the Regulation includes a flute located above the water basin and through a heat exchanger and pump connected to the outlet of the storage pool, as well as an air atomizer installed in the storage pool and electrically connected to the aeration compressor, which is connected to the control output of the aeration and thermoregulation unit, which has a different control output connected to the heat exchanger’s electric heater, and the input to the temperature sensor installed in the water pool, the level automation unit is connected to the sensor by the input ohm water level, located in the storage pool, and the control output is connected to an electric pump.

In addition, the installation of closed water supply further comprises an incubation apparatus, which during the incubation period of eggs by means of water-locking devices is connected to the closed circuit of the installation.

In addition, fluorescent lamps are installed above the biological treatment pool and feed cultivation pools.

An advantage of the invention is the tiered arrangement of the pools, which can significantly save the area of the insulated space occupied by the installation.

The use of one installation of closed water supply for all stages of growing planting material, starting from the production of reproductive products, will further save the area of the heat-insulated premises occupied by the hatchery, significantly reduce the cost of water and electricity for its heating, as well as fish-breeding equipment, technical equipment and automatic control devices to create optimal conditions in the installation during the production of planting material. In addition, improved working conditions for fish farmers.

The presence in the installation of pools for the cultivation of live food guarantee high survival and growth rates of larvae and fry.

The presence in the installation of structural elements that provide a continuous supply of oxygen to the water circulating in the installation, allows you to maintain normal oxygen levels in the load pools.

The invention is illustrated by the drawing, where figure 1 shows a block diagram of a compact fish breeding installation of a closed water supply.

The installation contains a water pool 1, above which there is a flute 2 for aeration of water, a biological treatment pool 3, a storage pool 4, load pools 5, pools 6 for a reserve of water, pools 7 for cultivating feed, an electric pump 8, an aeration and temperature control system, and collectors connecting said devices to form a closed system of water circulation. In addition, the installation is equipped with a level 9 automation unit and a level 10 sensor. The installation is divided into left, right and center parts. In the central part of the installation, there is a storage pool 4, a biological treatment pool 3 and a water pressure pool 1, which are interconnected and mounted in three tiers. A storage pool 4 is located on the first tier, a biological water treatment pool 3 on the second, and a water pool 1 on the third. Load pools 5, 7 feed cultivation pools, 6 water reserve pools 6 are located on the left and right of the unit, between themselves and are mounted in two tiers. On the first tier there are 5 load pools, and on the second tier - pools 6 for water reserve and pools 7 for fodder cultivation. The inputs of the pools 5, 7 are connected to the collector 11 for supplying purified water and are connected to the outlet of the water basin 1. The outputs of the pools 5, 7 are connected to the collector 12 to output the waste water and are connected to the input of the storage pool 4 and the outputs of the pools 6 for water reserve, and additionally through a water-locking device 13 with a pipe 14 for discharging water from the installation into the sewer. The inputs of the pools 6 for the reserve of water through the water-locking device 15 are connected to a water source feeding the installation. The aeration and thermoregulation system includes a flute 2 located above the water basin 1, which through the heat exchanger 16, the pump 8 is connected to the outlet of the storage pool 4, as well as an air atomizer 17, which is installed in the storage pool 4 and is electrically connected to the aeration compressor 18, which is connected to the control output of the aeration and thermoregulation unit 19. Another control output of the aeration and thermoregulation unit 19 is connected to an electric heater of the heat exchanger 16. And the input of block 19 is connected to a temperature sensor 20, which is installed in the water pool 1. Block 9 of the level automation is connected to the water level sensor 10 located in the storage pool 4, and the control output is connected to the electric pump 8. Blocks 9 and 19 by means of an electric plug 21 are connected to the electrical network. To control the circulating water flow in a closed circuit, the following water shutoff devices are mounted in the collectors: a water shutoff device 15 for switching water supply from the source to the pools 6 for water reserve on and off, a water shutoff device 22 that controls the flow of water from the water pool 1 to the load pools 5 and cultivation feed 7, water intake device 23, regulating the flow of water into the biological treatment pool, water intake device 13 for the complete discharge of water from the installation into the sewer, water discharge devices properties 24 filling the installation with fresh water from the pools for water reserve, water shutoff devices 25, regulating the flow into the load and cultivating feed pools, water shutoff device 26 for connecting the incubation apparatus to the circuit. In addition, the following nozzles are mounted in the pools: a water overflow pipe 27 with excess water in the water basin 1, a level pipe 28 of the biological water treatment pool 3, level pipes 29 installed at the outlet of waste water from load pools 5 and feed cultivation 7, level outputs 30 overfilling with water of the load and cultivating feed tanks, as well as a pipe 14 for discharging water from the installation into the sewer. A pack of cartridges 31 is installed in the biological treatment pool 3. The pools 7 for cultivating the feed (rotifers, daphnia, main) are equipped with fine mesh filters 32 from the mill sieve, which provide the exit of fine daphnia and its movement with circulating water to the larvae of aquatic organisms as live feed. In the load pools 5, fine mesh filters 33 from the mill sieve are installed, which prevent the exit of larvae from the pools. For better cultivation of phyto- and zooplankton above the biological treatment pool 3 and feed cultivation pools 7, 34 daylight lamps were installed. The number of pools 5 loadings are selected depending on the capacity of the fish farm.

Installation works as follows.

When the installation is put into operation, the water shutoff devices 13, 26 are closed and the water shutoff devices 15, 22, 23, 24, 25 are opened. Water from the source through the water shutoff device 15 starts to flow and fill the pools 6 for water reserve. Through the waste water collector, the left and right parts of the installation (pools 7, 5) are filled with water, which then flows into the storage pool 4. When filling the storage pool 4 with water, the plug 21 is connected to the electric network. A level automation unit 9 is turned on, which maintains a given level of water in the water basin 1 and an aeration and thermoregulation unit 19, which, if necessary, includes an electric heater for the heat exchanger 16 if the water in the installation does not correspond to the temperature set by the operator. Block 9 includes an electric pump 8. Pump 8 pumps water from the pool 4 through the heat exchanger 16 into the “flute” 2, from where aerated and heated water is supplied to the water pressure pool 1. Part of the water from the pool 1 through the collector 11 for supplying purified water through an open water outlet the device 22 and the water shutoff device 25 enters the pools 7 for cultivating feed and load pools 5. Another part of the water from the pool 1 through the water stopping device 23 enters the biological treatment pool 3. In the pool 3, the water passes through the package of cartridges 3 1, on which the development of colonies of bacteria that purify water from organics, suspensions, ammonium, etc. Next, the purified water through the pipe 28 is poured into the storage tank 4. The electric pump 8 continues to work and pumps the water through the heat exchanger 16, the “flute” 2 into the water pressure pool 1 and from it through the purified water collector 11 to the feed pools 7 and load pools 5 of which, further down the waste water collector, the storage pool 4 fills with water. Upon completion of filling the installation with water, its excess will begin to drain through the overflow pipe 27 installed in the water pressure pool 1, and level ode 30 overflow basin 5, 7 through the water pipe 14 to the sewer. At this time, the water supply to the installation should be stopped by shutting off the water-locking device 15, as well as the water-locking devices 24 of the water reserve pools.

At each achievement of a predetermined upper level of water in the water basin 1, block 9 issues the following command - shutting down the electric pump 8. At the same time, block 19 turns on the aeration compressor 18 and additionally aerates the water in the storage pool 4 with an air atomizer 17. Each time water is reached in the storage pool 1 of the lower level, block 9 includes an electric pump 8 and water begins to be pumped from pool 4 to pool 1, etc. Installation enters automatic operation mode and cycles are repeated.

At the end of filling the installation with water, the flow rate of the water should be adjusted with shut-off devices. The water shut-off devices of 25 pools 7 for cultivating live feed are set to a flow rate of 1-2 l / min. In the process of work, it may be necessary to further adjust the flow rate to cultivate the maximum possible amount of fodder juveniles Daphnia, rotifers, and main. Water-locking devices 25, regulating the flow rate in the load pools 5, are installed with a flow rate of 3-6 l / min, depending on the applicability of the pools and the expected number of hydrobionts. The water intake device 23, which regulates the flow of water into the biological treatment pool 3, is set to 4-6 l / min. Adjusting the flow rate and the number of cassettes 31 of the pool 3 depends on the volume of water in the installation. With a water flow of 4-6 l / min, the biological treatment pool 3 will additionally perform mechanical water treatment, as mechanical suspensions will be deposited at the bottom of the pool.

Due to the periodic operation of the “flute” 2, which additionally supplies water with oxygen, the water in the water basin 1 will be mobile and the suspension in it will not precipitate, but will flow through the water isolation device 23 into the biological treatment pool 3, where the phyto- sediment will settle and be disposed of. and zooplankton circulating with water in the installation.

Before starting work with hydrobionts, it is necessary to let the installation work for at least 7-10 days. This is necessary to start the biological treatment pool 3, on cassettes 31 of which biofilms are formed from bacterial colonies that purify water and create the ecological balance of the ecosystem. In addition, colonies of bacteria that contribute to the purification of water also settle on the inner walls of all pools. T.O. There is an ecological balance of the ecosystem.

As practice has shown, farm ponds contain a lot of phytoplankton in the form of chlorella, which is the food for zooplankton. Therefore, when using water from such reservoirs as a source in a closed circuit of the installation, water containing chlorella will circulate, which will serve as a food base for the zooplankton grown in the installation and, in addition, perform the purification function. In particular, in basin 3 of biological treatment, chlorella will consume organic sediments and suspensions falling out in basin 3 in the form of a mechanical suspension.

For incubation, eggs can be purchased at warm-water fish farms or produced in the proposed installation. To obtain sex products in the pools 5 loads are placed by producers, they create optimal conditions for them in the installation (temperature, oxygen content 0 ₂ ). To simultaneously obtain reproductive products, pituitary production of the producers is carried out. The resulting reproductive products are placed in an incubation apparatus, and producers are returned to the ponds. For incubation of fish eggs, the incubation apparatus is connected to the water-locking device 26. By adjusting the water-locking device, the water flow in the device is established. The outlet of the wastewater from the incubation apparatus is connected to a water shutoff device 13, through which the wastewater is discharged from the installation to the sewer. As an incubation apparatus, you can use a multifunctional device for incubating fish roe (RF patent No. 2243654, MKI A01K 61/00) (4), in which you can carry out all work related to the incubation of eggs of aquatic organisms: fertilization, washing, degumming, treatment of fungal diseases (saprolegneosis), incubation, growing of larvae with their natural conclusion to the load pools, without injuring them during transplantation. After receiving the larvae and placing them in pools 5, the loads of the larvae go to the dormant stage and, after a lapse of time, which depends on the type of larvae, switch to active nutrition using feed from pools 7 for cultivating feeds. Initially, the larvae feed on rotifers, and then small daphnia, mines exiting through a fine mesh filter 32. If there is a shortage of live food, the larvae can be fed with starter larval food. Upon reaching the optimum water temperature in the reservoir and the appearance of live food, the resulting planting material is released into the reservoir.

After completion of the work and conservation of the installation, phyto- and zooplankton remain in the installation mainly in pools 7 for food cultivation and pools 6 for water reserves, where, with decreasing temperature, they enter the state of phytoplankton spores and resting zooplankton eggs that are laid at the bottom of these pools. At the beginning of work, i.e. filling the installation with water and raising the temperature, spores and eggs begin to be cultivated in chlorella, rotifers, daphnia, maines. A particularly high outbreak of phyto- and zooplankton will occur when hatching larvae in the incubation apparatus, because at this time, the yield of organic matter will increase. By circulating in the plant’s water, phyto- and zooplankton will purify water from organic matter, which is their feed, which will ensure a high degree of water purification in the plant.

The proposed fish hatchery simulates a growing base that guarantees optimal conditions for the growth of individual stages of development of fish and aquatic organisms, which makes it possible to cycle fish in it and, accordingly, increases the efficiency, productivity, and technological capabilities of the installation.

The fish hatchery is inexpensive and has a simple design that uses commonly available, standard components. It can be placed in a small insulated room. Launching the installation and maintaining a continuous and normal process for the production of planting material require compliance with simple maintenance and control operations. The installation is economical in the consumption of water and electricity. If the unit is placed in a place where there is no industrial electric energy, it can be connected to an electric current generator. All this allows the installation to be used in small farms with limited staff.

Claims (3)

1. A compact fish breeding facility for closed water supply, including load pools, a biological treatment pool, a water pool, a storage pool, an electric pump, an aeration and temperature control system, interconnected into a closed circulation circuit by means of collectors, characterized in that it is additionally equipped with a level automation unit, water level sensor, fluorescent lamps, and in a closed circulation circuit additionally included pools for water reserve, pools for cultivated I feed, a flute for aeration of water, while water collectors are installed in the collectors to regulate the flow of water in the circuit, and the installation is divided into left, right and central parts, where the storage pool, biological treatment pool and water pressure pool are located in the central part of the installation, reported between each other and mounted in three tiers, load pools, pools for the cultivation of feed, pools for water reserve are located on the left and right side of the installation and are mounted in two tiers, while the inputs of the pool The load and pools for cultivating feed are connected to the water basin through the collector for the supply of purified water and water shut-off devices, and the outputs are connected to the storage pool through the collector for the discharge of waste water, which is additionally connected through the water block to the discharge pipe of the unit and to the pool exits for a reserve of water, the inlets of which are connected through a water-stopping device to a water source feeding the plant, the aeration and thermoregulation system includes a flute laid above the water basin and through the heat exchanger and pump connected to the outlet of the storage pool, as well as an air atomizer installed in the storage pool and electrically connected to the aeration compressor, which is connected to the control output of the aeration and thermoregulation unit, in which another control output is connected to the heat exchanger electric heater and the input to the temperature sensor installed in the water basin, the level automation unit is connected to the water level sensor located in storage tank, and the control output is connected to an electric pump. 2. Installation according to claim 1, characterized in that it further comprises an incubation apparatus, which during the incubation period of eggs by means of water-locking devices is connected to a closed circuit of the installation. 3. Installation according to claim 1, characterized in that daylight lamps are installed above the biological treatment pool and the feed cultivation pools.