SU710544A1 - Unit for rearing water-living organisms - Google Patents

Description

The invention relates to aquaculture, namely to installations for the maintenance of aquatic organisms, and may find application in the field of toxicology. A known installation for the maintenance of aquatic organisms, consisting of a reservoir for placing living organisms, equipped with a circulating water circuit. The circulating water circuit piping comunication includes sprays for saturating water with oxygen from the air, a water purification filter, a water supply pump, an electrolyzer with a gas separator, and a device for monitoring water quality with flow meter 1. However, in this installation it is impossible to determine the effect of metal ions under controlled conditions x temperature and oxygen regimes for aquatic organisms. Also known is an installation comprising a cylindrical tank with a conical base and a false bottom and a closed circulation circuit for supplying and draining water with a tracking system of automatic temperature and oxygen control, including a water purification filter, a water supply pump, an electric heater, an electrolyzer with a gas separator , refrigerator with heat exchangers, aerator and water quality control device 2. In this installation, the automatic temperature control system is connected to the refrigerator, the d conductive system of automatic control of oxygen to the aerator, both of which are associated with the reservoir and the reservoir and contain respectively blocks automatic temperature control and software blocks oxygen and temperature recording modes and oxygen. The installation does not provide the possibility of simultaneously determining the effect of metal ions on aquatic organisms adapted in a natural water body to different water flow rates and different between different biological and physiological and biochemical characteristics, since it does not provide for the flow rates of water that are identical to the flow rates of water in a natural reservoir throughout its length, and also reduced the accuracy of modeling. temperature and oxygen regimes. The aim of the invention is to improve the accuracy of determining the effect of metal ions on aquatic organisms adapted to different flow rates of water. To do this, in an installation containing a cylindrical tank with a main bottom and a false bottom and a closed circulation water supply and discharge circuit with a follow-up system for automatic temperature and oxygen control, the tank is made with a vertical partition mounted perforated water intake tube and grids. The free end of the partition is connected to the wall of the tank with the formation of a spiral channel, the perforated water intake pipe is placed in the center of the partition of the partition, the grids are located in the center plane of the tank to block the flow section of the spiral channel, and the false bottom is mounted under the spiral channel. It is advisable in the proposed installation of the lattice to perform in the form of cells, and the partition - along the profile of the logarithmic spiral. FIG. 1 shows schematically the proposed installation, side view and plan view; in fig. 2 and 3 - functional installation diagram; 4, a partition, a perforated water intake pipe and a cylindrical wall of the tank; in fig. 5 - the main conical bottom and false flat bottom of the tank with a perforated water intake pipe; in fig. b - the main conical bottom and false flat bottom with a perforated water intake pipe and a cylindrical wall of the tank; in fig. 7 - a tank with a partial cut-out of the lid of the intake compartment; in fig. 8 - water intake compartment cover; in fig. 9 is a part of the grid consisting of cells and one cell in two projections. The proposed installation for the maintenance of aquatic organisms contains a cylindrical reservoir in which a spiral-like partition 1 is installed in the varicontal plane, has a logarithmic spiral profile, and a perforated water intake pipe 2 is located in the center of this partition. the formation of the spiral channel 4. The cylindrical wall 3 of the tank together with the adjacent part of the spiral-like partition 1 form the intake compartment 5, the tank with The iraly-shaped channel 4 and the water intake compartment 5 have a main conical bottom 6 with a water supply nozzle 7. The base of the spiral channel 4 is separated from the main bottom 6 by a false flat bottom 8, made in the form of a solid flat plate partially overlapping the water intake compartment 5 from the bottom, resulting in an internal cavity The main bottom 6 is in communication with the water intake compartment 5. The spiral channel 4 is separated from the perforated water intake pipe 2 and the water intake compartment 5 with profiled gratings 9 located in the diametral plane p Tanks for blocking the flow section of the spiral channel 4. The smaller grid 9 prevents water organisms from entering the water intake pipe 2, and the large grid 9 prevents water organisms from leaving the spiral channel 4 and entering them into the water intake section 5. Both grids are dissecting water and contribute to its laminarization. The grids are made up of cells made in the cell type. Each cell of the grid 9 is a tetrahedral cell. The water intake compartment 5 is equipped with a hermetic cover 10, which facilitates the directional movement of water in the spiral duct e 4. The unit is equipped with main and additional circulation circuits and water circuits. The spiral channel 4 through the perforated water suction pipe 2, the water supply pipe 7, the valve 11, the three-way valves 12-15 and the valve 16 are in communication with both circulating water circuits. The main circulation water circuit includes a Veda purification filter 17, a water supply pump 18, an electric heater 19 consisting of two heat exchangers, an electrolyzer with a gas separator 20, a cooler 21 with two heat exchangers and an aerator 22. An additional water circulation loop is designed for storage of storage water and maintaining a predetermined temperature, pH and oxygen content in it and consists of a storage tank 23 of storage water, a water quality device 24 xxtrol with flow meter 25 and a water supply pump 26, hoc together with ocHOB-HBifvi circulating a water KOHTypof and reservoirs with living organisms by means of valves 27, 28 and 16 as well as three-way valves 29 and 30. Three-way valve 29 communicates with the water source, such as mains water. The valve 27 is made shut-off. The tank 23 is equipped with an aerator 31 with a valve 32. The aerator 31 with the valve 32 is connected by an air line to the heat exchanger of the cylinder 21,

For monitoring and timely adjusting the pH of the water, the installation is equipped with a pH meter 33 with pH sensors 34 and 35 located in the water quality control device 24 and in a spiral channel 4 and communicated by means of a switching device 36 with a pH meter 33. Alternate switching of sensors 34 and 35 per pH meter 33. provides monitoring of the value of p of water in the spiral channel 4 and in the additional circulation water circuit.

In order to provide a given oxygen regime of water, the installation is equipped with a blower 37 connected to the heat exchanger of the electric heater 19 and further to the heat exchanger of the refrigerator 21 and to the aerators 22 and 31.

The following automatic temperature control system consists of temperature meters 38 and 39, placed respectively in the spiral channel 4 and in a natural reservoir, converter 40, control unit 41 and program recording unit 42, as well as control valve 43 installed on the coolant supply pipe the refrigerator 21. At the same time, the temperature sensor 39 is connected via a telemetry system 44 to the regulating unit 41 and the program recording unit 42. The telemetric system 44 ensures the transmission of information on physico-chemical parameters of the water of a reservoir located at large distances from the installation.

The following system of automatic oxygen regulation consists of meters 45 and 46 of dissolved oxygen concentration installed in spiral channel 4 and in a natural reservoir, converter 47, regulating unit 48, unit 49 of program recording of oxygen concentration, telemetric system 44, two control valves 50 and 51, designed to change the flow of deaerated water in the aeration process. The oxygen sensor 46 is communicated via the telemetry system 44 with the regulating unit 48 and the program recording unit 49.

The proposed installation for the maintenance of aquatic organisms works as follows.

Temperature meter 39 and oxygen meter 46 is placed in a natural pond. Water from the water source is fed through a three-way valve 29 into the tank, and from it through a three-way valve 30 into the device 24 to determine the pH of the water. If necessary, adjust the pH of the water. Water is then supplied through valve 27 and flow meter 25. Next, it is supplied by pump 26 through three-way valves 15 and 12 into the water intake pipe 2 or

through valve 11 of the water supplying steam 7 to the reservoir with living organisms. Flow meter 25 determines the amount of water in the installation. Living organisms are placed in the spiral channel 4.

Valves 11, 12 and 13 are designed to reverse the flow of water in the spiral duct 4 (i.e., to change the direction of the flow of water). In this case, the circulating water can be directed through the three-way valve 12 into the perforated water intake pipe 2, from the latter water enters the spiral channel 4, passes through the smaller grid section 9, flows through this channel, leaves it through the larger grid section 9 and enters the water intake compartment 5. From the latter, water enters through the space formed by the butt of the false, bottom 8 and cylindrical wall 3, BO the internal cavity of the main bottom 6 and exits through the water inlet 7 and ve reflux, 11 and 13 in the water circulation loop. Circulating water can be directed through a three-way valve 12, valve 11, water supply pipe 7 into the internal cavity of the main bottom 6, from which water flows into the water intake compartment 5 under pressure, and from section 5 through a larger grating segment 9, into the spiral duct, circulates through it and passes a smaller segment of the grid 9.

Next, water through perforation enters the water intake pipe and is drained through a three-way valve 13 into the circulation water circuit at the pump 18 through the water purification filter 17 into the electric heater 19 In the latter, the water is heated to a predetermined temperature, enters the electrolyzer 20, undergoes a deaeration process and enters in the refrigerator 21. In the refrigerator 21, the water temperature drops to a level corresponding to the water temperature of the natural water body or the temperature corresponding to the specified program recorded in block 42. Then, through In the water supply system controlled by control valves 50 and 51, water enters the aerator 22. Air is blown into the heat exchanger of the electric heater 19 to aerate the water with the blower 37. Then it goes to the heat exchanger of the refrigerator 21, as a result of which its temperature drops to water, then to aerator 22, and also through valve 32 to aerator 31. Water and air in communications 19 and 21 are heated and then cooled to a predetermined temperature. In the tank 23, the water is additionally lost to air at a predetermined temperature.

This process ensures the preparation of water and air of a given temperature and a more rapid adjustment of the installation to a given mode of operation.

With the sweep of the following automatic temperature control system Ij, it is possible to maintain any desired temperature or to provide a temperature corresponding to the temperature change in the natural water body, i.e. monitor the temperature of the natural reservoir. In the latter case, the setting of the temperature controller 41 directly comes from the meter 39 through the telemetry system 44, wherein the change in water temperature in the natural pond is recorded on the software device. The recorded temperature of a natural water body in the form of a program can be submitted as tasks to the regulating unit 41, which at the same time provides for the regulation of the temperature of the water in the spiral channel 4 to a predetermined temperature together with the control systems 38, 40 and 43. The duration of the regulation of this program can vary time without distortion, as well as with acceleration or with deceleration using block 42,

The deaerated, enriched with metal ions and thermostatically controlled water from the refrigerator 21 enters two water pipes with control valves 50 and 51, one of which has an aerator 22 installed, both of which are connected to a common water pipe with a three-way valve 14. The last water can be directed an additional circulation water circuit or, shutting off the pipelines with the valves 15 and 16, the water is directed back to the tank,

In the spiral channel 4, the water flow rate gradually increases as it passes along the entire length of the spiral channel 4, In its narrowest part, the water velocity reaches its maximum value. In this case, for each species of aquatic organisms that are adapted to different rates of water flow in a natural water body, it is possible to operate under optimal conditions for the water flow rate that is identical to the water flow rate of the natural water body. The rate of flow of water in the spiral channel regulate the performance of pumps 18 and 26.

The following automatic oxygen control system operates as follows.

Information about the oxygen content in the spiral channel 4 is continuously supplied from the meter 45 to the controller 47, the output of which changes the ratio of the flow rates of the water to the aerator 20 and the water supplied to the spiral channel 4 using control valves 50 and 51. One of the last normally open, the other is normally closed.

The following automatic regulation system provides stabilization of the oxygen dissolved in water at a given constant value or provides the oxygen content in the water corresponding to the concentration of oxygen dissolved in the water, t, e, monitors the oxygen regime of the natural water body.

In the latter case, the regulating unit 48 continuously receives the driving signal from the meter 46, which in this case will carry out the program- regulation of the oxygen concentration in helicoid channel 4 according to a predetermined program. The duration of the program can be adjusted in time without distortion, either with acceleration or deceleration, using a program recording block 49 (similar to a tracking automatic control system).

In the process of keeping aquatic organisms in the spiral channel 4, the pH of the water is monitored using sensors 35 connected through a switching device 36 to a pH meter 33.

The water quality adjustment in the tank 23 is carried out as follows: i

Water from reservoir 23 is fed through communications 30, 24, 27, 25, 26, 15 16 and 29, carried out a closed circulation of water. The pH sensors of the water through the switching device 36 is connected to the pH meter 33 and adjust the pH of the water in a known manner.

After adjustment and stabilization of the pH of the water, the pipeline is closed by a valve 30 and the water from the device 24 Hacocovi 26 is supplied to the reservoir 23, then the water supply pump 26 is shut down. With the aid of the valve 32, regulate the quantitative supply of thermostatted air to adjust the temperature and saturation of the water with oxygen from the air.

To control the pH value of water in the spiral channel 4 by means of commutating device 36, sensors 35 are put into operation and pH value 33 controls the pH value of water. In the case when the pH value of the water needs to be corrected, the water circulating in the main water circuit , they are directed through communications 14, 16, 28, 24, 27, 25, 26, 15 and 12 into spiral channel 4 and back out of it through the system of valves 12, 11 and 13 (as described above), then through communications 17, 18, 19, 20, 21, 22, 14, 16 and 28, providing closed water circulation s. The pH 34 sensors are connected to a pH meter 33. Thus, in the device 24, the pH of the water is adjusted, and if necessary, in the electrolyzer with the gas separator 20, water is enriched with metal ions to a predetermined concentration.

After adjusting the pH of the water, the additional circulation circuit is shut off by shutting off the pipelines with valves 15 and 16. Through the three-way valve 14, water is fed into the spiral duct 4 and from there into the main circulation circuit,.

An installation for the maintenance of aquatic organisms provides for the adjustment of water purity, the enrichment of Vedas with metal ions, the removal of toxic gases from water, the adjustment and stabilization of the pH of water, automatic regulation of temperature and oxygen content of water, with automatic monitoring of the temperature and oxygen regimes of a natural water body. It provides for the creation of intervals of water flow rates that are identical to water flow rates in natural water bodies for simultaneous content of living organisms at optimal water flow rates that are adapted to livelihood in a natural water body at different water flow rates. In the installation, the radius of monitoring temperature and the oxygen regimes of the natural reservoir, the accuracy of reproduction of the modeled temperature and oxygen regimes is improved, and more efficient and smooth transfer is provided building installation from one mode to another.

Claims (1)

1. An installation for containing aquatic organisms, comprising a cylindrical reservoir with a conical day and a false bottom and a closed circulation loop for supplying and discharging water with a tracking system of automatic temperature and oxygen control, characterized by , | In order to improve the accuracy of determining the effect of metal ions on aquatic organisms, adapted to different flow rates of water, a partition in the tank in a vertical plane is installed in the form of a spiral, a perforated water intake pipe and grids, while the free end of the partition is connected to the wall the reservoir with the formation of a spiral channel, the perforated water intake pipe is placed in the center of the coil of the partition, the gratings are located in the center plane of the tank to block the spiral-stand section Channel 5, the false bottom is mounted under the spiral channel. 2, Installation according to claim 1, characterized in that the grids are made in the form of cells, and the partition 0 has a logarithmic spiral profile. Sources of information taken into account in the examination 1, USSR Copyright Certificate 535929, cl. A 01 K 61/00, 1975, 2, copyright certificate for application number 2405578, cl. A 01 K 61/00, 1976, h ipuif-. 5