SU818581A1 - Device for growing fish - Google Patents

Description

ultimately, it is determined by the amount of oxygen that is received by the fish, i.e., the difference between the amount of oxygen supplied to the pools and the amount of oxygen discharged from the used water. Considering that oxygen saturation in water at a water temperature: For example, + 21 ° C, already occurs at a concentration of 9.23 mg / l, it is clear that it is desirable to have water at such points in all points of the pool, whose oxygen concentration is close to saturation. It seems that it is enough to have a pumping station that provides for FULL-water exchange in ponds several times per hour. It turns out that such a decision is associated with a large expenditure of energy, and in some cases it is generally useless. On the other hand, in the Gulf of Finland, the oxygen content in water varies widely, depending on waves, providing natural aeration, on the direction and strength of the wind, on temperature, on time of year. With strong waves, the concentration is close to saturation, but already during a windless day, summer.m, with particularly adverse conditions, it can fall, for example, to 6 1/1 or less. Naturally, under such conditions, a further increase in the intensity of pump operation does not provide for the requirement of n-intensive fish farming. However, using the aerator when fresh water is close to saturation is a waste of energy. The actual situation is even more complex. It is known that the amount of oxygen consumed by fish depends on age, on illumination, but especially on temperature. It averages for trout on average at a temperature of + 200 ° C 200-250 mg of oxygen per 1 kg of fish for 1 hour. At a temperature of + 10 ° C, o-but is three times less: from 7-0 to 90. The oxygen consumption is rather exponential, it is precisely determined by the function where K is the amount of the consumed acidic type, (f) i is temperature, ° C; to - the reference temperature is + 5 ° C. The known setting allows you to automatically adjust the concentration of acid-water of the water, depending on the temperature of the water with the minimum amount of energy consumed 1 and thereby achieve the maximum weight of the fish and the efficiency of its increase per unit water volume with minimal energy consumption. The purpose of the present invention is to reduce power consumption. To achieve this goal, the plant is equipped with control units, a pump and a device for aerating water, while the sensors for monitoring and controlling the temperature of the oxygen concentration are placed in the water supply and drain channels, the outputs of the sensors, which are connected respectively to the P-program inputs The outlets of the latter are connected respectively to the inputs of the pump and control units for aeration of water. In addition, the installation is equipped with additional fish and fish basins, pumps and water aeration devices, made in the same way as the main one. A software device contains an analog converter, a node with a co-ordinated transmission, a source of reference voltages, comparison blocks, controllable keys, while the outputs of the analog-to-code converter are connected to the first input of the pump control unit and to the control inputs of the node with the coded-controlled transmission, the output of which is connected to the first input of the first comparison unit, and the output of the sensor controlling and regulating the oxygen concentration is connected to the left inputs of the second, third and fourth comparison units, and to volts At the input terminals of the comparison blocks, the corresponding outputs of the reference source source are connected: nyy, and the first output of the first comparison unit is connected to the control input of the first and second control key, the second output is connected to the control input of the third and fourth control key, the output of the second the comparison unit is connected to the signal inputs of the first and third control key, the output of the third comparison unit is connected to the signal inputs of the second and fourth control key, and the output of the fourth comparison unit is connected to the first The first input of the control unit p; -devices 1 for water aeration and the fourth input of the pump control unit, the outputs of the first and second control keys are connected respectively to the second and third inputs of the pump control unit: the outputs of which are connected to the terminals for controlling the intensity of pumps, the outputs of the third fourth key are connected respectively to the second and third inputs of the control unit of water aeration appliances, the outlets of which are connected to the terminals for controlling the aeration intensity, the analog input the code converter is connected to the output of the temperature monitoring and control sensor, and the signal output of the coding controlled node is connected to the output of the oxygen monitoring and control sensor.

FIG. 1 shows the proposed installation, the general view; in fig. 2 — nporpaMiM.Horo blockheme of the device for monitoring and regulating the oxygen concentration of the basins according to the invention; in fig. 3 - a, b, c, d, e - timing charts that explain the operation of the system within 48 hours.

The plant for growing fish is built on the shore of the Gulf of Finland and it includes water intake 1 through which it is clean (water from the surface of the bay to the pumping station 2 for pumping clean water to channel 3 for feeding water by gravity to the pond 4 for fishing, to the experienced the pools 5, the fry pools biv production pools 7, and the water discharge channel 8. In the channel 5 and in pools 6 and 7, water aeration facilities 9 are placed, which are controlled in the same way as pumps 2 by a program device 10, installed in work center L1 Istemi. In -channel 8 dewatering placed sensor (12 monitor and control the oxygen concentration in the channel 3 a sensor 13 is placed to monitor and control the oxygen concentration sensor 14 l of the control and regulation of the inflowing water temperature.

According to the invention, the software device 10 contains a terminal 15 connecting the output signal s-signal of the sensor 14, a terminal 16 connecting the output signal of the sensor 13, a terminal 17 connecting the output signal of the sensor 12. Terminal 15 is connected to an analog-to-code converter 18, the control outputs of which are connected to The signal inputs of node 19 with a CRD controlled transmission, and the signal input of node 19 are connected to terminal 16. The signal output of node 19 with a code-controlled transmission is connected to one input of the comparison unit 20, to the second input of which One output of the voltage source 21 is wired. Terminal 17 is connected to the same inputs of comparison units 22, 23 and 24, to the second inputs of which other outputs of the reference terminal 21 are connected. The first Bypass of the comparison unit 20 is connected to the control inputs of the keys 25 and -26, and the second output of the block is compared to the control inputs of the keys 27, 28. Sig /, C

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O;, - 15-17 23 --- 25 32-35 43-47 56 61 69-76 85 93 00--1П Efficiency of water enrichment of the ponds with oxygen by pumps (") is defined as 55 where the amount of oxygen that is supplied to the ponds at the expense of 1 kW-h of energy expended by the pumps, and is equal in this case

the key inputs of the keys 25 and 27 are connected to the output of the comparison unit 22, the signal inputs of the keys 26, 28 are connected to the output of the comparison unit 23. The outputs

keys 25, 26 are connected to different terminals of pump control unit 29, and outputs of keys 27, 28 are connected to different terminals of control unit 30 for aeration of water. To block 29

control of the pump and to the unit 30 of the control of the fixtures 9 are connected the output of the comparator unit 24. The output terminals of the blocks 29 and 30 are connected to the control terminals of the pumps of the station 2 and to the control terminals of the devices 9, respectively.

The system works as follows.

Clean water comes from the surface.

bay over the fence / pumping station

-2 where, for example, twelve pumps of type ОВ-06-55 are placed, each of which pumps 1 m of water for 1 channel 3 to a height of 3.5 m with a power consumption of 75 kW. Because of the natural

the slope begins the flow of water through channel 3 to ponds 4-7, into channel 8 of the outlet and back to the bay in a place where, due to natural conditions (current, normal wind direction, etc.), reused water is prevented from entering the water intake , /. The installation mode is chosen in such a way that at least three pumps always work, ensuring a full exchange of pond water (total surface 2.56 hectares) for two hours. In addition, when there is a shortage of oxygen, all twelve pumps can be turned on, ensuring full exchange of water for 30 minutes, and also devices 9 for aeration of water can be additionally included.

 (When determining the optimal mode of the system as a whole, firstly, the required amount of oxygen for a given amount of fish depends on temperature (Form 1) and other conditions, taking into account the loss of part of oxygen in other oxidation processes.

When maintaining the calculation, for example, for

300 g of trout in the ponds under consideration, the required amount of oxygen depending on the temperature is given in the table below.

20

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J5, 048 (L „x-Lvyh),, (2) Yavh - oxygen concentration of water in the supply channel 3; The left is the oxygen concentration of water in the outlet channel 8. Effect.Vn (Art |.: ... obo, arr. Prudov kksLorrdom; aerators, ($,). 0: is limited as the amount of k-hydrogen, krtorre is given in 1prud ( at the expense of 1, T /: c5, - h of energy expended, and the air of agoram n, H.paBjio in this case, in dependence on the oxygen deficit of oxygen in water; - -.; ..... .;.,; .. -: ....,., Q85 (, .h (3) to EL OD25 (/ (k - A ;,) kg:,; c.h (4) rb; e Kk - oxygen oxygen concentration: saturation;:, t, ° C - 7.57.5-10 10A, mg / l (1-10. 0-9.6 0H, mg; l 10-12.14 9, b- G1.5 9.2; ;; In Software Devices / (an electrical signal is received from sensor 14, and this analog signal is converted into an analog I / K converter, an I / K converter, into a code that has a coefficient of transmission of a node 19 with a code-controlled transmission. To the input of the node / P, post-pack. Analog terminal with datak / 5, Output signal of node / i9, dependence, concentration, III-oxygen, Omr, 1moturur1 1 liter, 1 day, and water is regulated in such a manner as: - output signal; iJfP node causes a certain Urs), it is advisable to regulate the regulation of the efficiency of the system,: P-the number of ectGs: p Eq.,. when, it is advisable, to regulate the intensity of aeration. -In the comparison block, 2 (cf., av1n1, va; output signal of the node, 75 with a given level of source 21 voltage levels, or depending on the sort of voltage cpaBHHBae ibix, or is transmitted on the left side; the signal 20, which controls the people 25, 26, if it is advisable to be controlled by € a.a.mi; or receive a signal on the second, block; 20 signal, ..g1 et., keys -and .27, 28, ls and tselesrobroznr, to regulate aeration. VlabkaI, comparing 22-w.-23 comes from; ignal: From the sensor, 12 kpdrny; signals from , source .a.: Comparative unit 22, produces a command D) Y); H) AI. Enrichment intensities -, oxygen, -, when the center of the kylrrda-dat-jakudeni water fell n-like the same green,. This level enters, depending on the state of the keys 25 and 27. either in the pump control unit 29, or in the control unit 30 for the fixtures 9, and switches on the additional enrichment power.

Comparison unit 23 generates a command to reduce the intensity of oxygen enrichment j when the concentration of oxygen: flowing: water exceeds a certain level. This command comes: depending on the state of the keys 26, 28 or to the control unit .9: 81558 5 10 -12.5 -9.2 -8.7

themselves, or in the device control unit 30 5. l. causes a decrease in the number of operating units. Comparison unit 24: also receives the sensor signal / 2. And the reference signal-l from the reference voltage source. The output signal of the block 24 is fed simultaneously to the blocks 25; and 30, in order to increase the intensity of the operation of the device; with a decrease or increase in the intensity of the work of the pumps. This unit is comparable to: 2: also serves as an emergency unit, in order to introduce any additional power;

Job-.installations are illustrated with - time diagrams, .fig. 3, - where: “- thus shows the composition of the flowing water; c is the oxygen concentration of prone: repentant water; c is the quantity of: consumed - oxygen; cf- Intensity of work-pumps; e - intensity. work. aerator. -. -As seen-: 1diafamm, the amount of oxygen consumed varies: depending on several conditions; times, and feasibility / on: aerator or pump.ov varies :: in: wide limits ..-, E-Copper.ments -n-have had, that - with -equal energy costs the introduction of software control and - control — oxygen content. —in water; basins - allowed to increase the density-planting of ponds by 2.4 times and, soo-TV-naturally; : lead off; performance-fish. at minimum up to ,-, investment: investment: - At the same time: it was possible to guarantee the good oxygen content of water at any climatic conditions of the external environment and thereby increase the efficiency of fodder digestion by fish and provide them more fast increment. Constant information about the temperature of the flowing water. allows optimalBNO to feed the trout; that, -For example, when the temperature changes from -p5 to + 15 ° C, the required amount of absorbed lithium increases-ich-2 -3 times and 1: Java: x. - the oxygen concentration center-- with ...:.:. flowing aody .:: - ::;;. Pr1I; .data: -conditions x: it is advisable to enrich water; K1 with oxygen: aerators in that case; if the deficit of α-oxygen is large, i.e., when the difference in the saturation concentration of this temperature is greater than the available concentration, and nacocaNtH, if the oxygen concentration of the flowing water is close to saturation.-The following table shows the oxygen concentrations of the flowing water at which they are regulated by intensity Thanks to the work of appliances 9, or pumps: 12.5-15 15-17.5 17.5-20. . . 0-8.8 0-8.40-8.0 8.8-1 (1.3 8.4 -.- 9.83 8.0-9.4, thereby optimizing the production performance of the fish industry rather. Formula and 3 about bout and 1. Installation for the cultivation of fish, containing a swimming pool for fish, water supply and drain channels, a pump, water aeration devices located in the water supply | Water channel, and a software device with control and regulation sensors temperature and oxygen concentration in water, characterized in that, in order to reduce energy consumption, it is equipped with pump control units and devices for aeration in The sensors for monitoring and regulating the temperature and oxygen concentration are located in the ducting and drainage channels, the sensor outputs: connected to the inputs of the software device, respectively, and the outputs of the latter are connected respectively to the inputs of the pump control units and water aeration devices. The installation of para. 1, characterized in that it is equipped with additional pools for fish, pumps and devices for aeration of water, made similar to the main one. 3. The installation according to p .1, from the point that the software device contains an analog-to-code converter, a node with a code-controlled transmission, a source of reference voltages, compared, the controlled keys, while the outputs of the analog the code converter is connected to the first input of the control unit of the pumps and to the control inputs of the node with the code-controlled transmission, output; which is connected to the first., input of the first comparison unit, and the output of the oxygen concentration monitoring and control sensor is connected to the first inputs of the second, third and fourth comparison blocks, and the corresponding outputs of the first voltage source are connected to the second inputs of the comparison blocks. the comparator unit is connected to the control input of the first and second control key, the second output is connected to the control input of the third and fourth control key, the output of the second comparator unit is connected to the signal The inputs of the first and third control keys, the output of the third comparator unit are connected to the signal inputs of the second and fourth control keys, the output of the fourth comparator unit is connected to the first input of the control unit with water aeration devices and the fourth input of the control unit of the people, the outputs of the first and. the second control key is connected respectively to the second and third inputs of the pump control unit, the outputs of which are connected to the terminals of the pump intensity control, the outputs of the third and fourth This key is connected respectively to the third and second inputs of the aeration device control unit, the outputs of which are connected to the aerial power intensity control terminals, the analog-to-code converter is connected to the output of the temperature control sensor, and the signal input of the node with code-controlled transmission is connected to the output of the sensor-for-control and regulation of the concentration of oxygen in the water. The source of information taken into account in the examination: 1. Copyright-USSR certificate № 588959, cl. And 01 K 61Sh, 1976.

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Claims (3)

Claim 1. Installation for growing fish containing a fish pool, channels for supplying and discharging water, a pump, water aeration devices located in the channel ^lci water supply, and a software device with sensors for monitoring and controlling the temperature and concentration of oxygen in water, characterized in that, in order to reduce energy costs, it is equipped with 15 pump control units and devices for water aeration, while the sensors for monitoring and controlling the temperature and oxygen concentration are located in the water supply and drain channels, outputs 20 yes tors are respectively connected to the inputs of the device software, and the latter outputs are respectively connected to the inputs of the pump control unit and means for aerating the water. 25 2. Installation according to π. 1, characterized in that it is equipped with additional pools for fish, pumps and devices for aeration of water, made similar to the main ones. thirty 3. The apparatus of claim. .1, l and m of h and u, and w I jar so that the software unit comprises analog-to-code converter assembly with kodoupravlyaemoy transmission source of reference voltages, comparison blocks ³⁵ Nia operated keys, while this yields an analog-code converter connected to the first input bloka- pumps and to control inputs of the transmission assembly kodoupravlyaemoy, yield ⁴⁰ koto- cerned .. connected to the first input of the first comparator unit ... and kontro- a sensor output and concentration adjustment oxygen is connected to the first inputs of volts The second, third and fourth comparison blocks, and the corresponding outputs of the reference voltage source are connected to the second inputs of the comparison blocks, and the first output of the first comparison block is connected to the control input of the first and second control key, the second output is to the control input of the third and fourth controlled key, output the second comparison unit is connected to the signal inputs of the first and third control key, the output of the third comparison unit is connected to the signal inputs of the second and fourth control key, output q of the fourth comparison unit is connected to the first input of the control unit for water aeration devices and the fourth input of the pump control unit, the outputs of the first and second controlled keys are connected respectively and the fourth key are connected respectively to the third and second inputs of the control unit for aeration devices, the outputs of which are connected to the control terminals Intensity aeration input analog-to-code converter connected to the output of the sensor kontrolyai temperature control, and a signal input node is connected to the transmission kodoupravlyaemoy vyhodudatchika- to-.kontrolya The concentration of oxygen in the water regulation. Source of information taken into account during the examination: 1. Copyright certificate of the USSR No. 588959, cl. A 01 K 61400, 1976. FIG. 2 X