RU2262570C1 - Fish protection structure - Google Patents

Abstract

FIELD: hydraulic structures, particularly to protect young fish against passing into water intake structures.

SUBSTANCE: fish protection structure includes filtering screen vertically installed in guiding means and formed of netted web secured to load-bearing frames. Filtering screen closes intake channel through the full depth thereof. Fish protection structure also has flushing unit made as perforated tube communicated with pump, fish pass arranged at downstream filtering screen end and additional device adapted to draw off garbage and young fish from the structure. The additional device is arranged in front of netted web from intake channel side and is formed as water-impermeable screen. Netted web is provided with additional vertical guiding means locating along its side surface facing water intake channel. Guiding means are formed as two channel bars with flanges secured to load-bearing frame and inner surfaces facing one another. Guiding means of load-bearing structures extend towards intake channel, secured to end parts of bridge piers and made as flange beams. Perforated tube is located under netted web from intake channel side, between netted web and flat water-impermeable screen facing intake channel and secured to side surface of perforated tube along its height. Water-impermeable screen plane is oriented along filtering surface of netted web. Perforated tube perforations are provided with nozzles extending at acute angles to longitudinal axis of perforated tube. Outlet nozzle orifices are directed towards water surface.

EFFECT: increased efficiency of netted web flushing.

19 cl, 29 dwg

Description

The invention relates to hydraulic engineering, and in particular to methods, structures and devices designed to protect juvenile fish from getting into water intake structures.

A fish protection device [1] is known, including a pump mounted on a trolley connected to a washing device, the working element of which is located in front of the net web, from the side of the supply channel.

The disadvantage of this device is the low cleaning efficiency of the net web from entrained debris and the low efficiency of removing young fish from the filter screen.

A device is known for washing the mesh web of a fish protection structure [2], including a pump mounted on a trolley connected to the pump and located behind the mesh web, a vertical perforated washing pipe facing the openings in the direction of the mesh web.

The disadvantage of this device is the low cleaning efficiency of the mesh web due to a significant (up to 50%) loss of kinetic energy of the hydraulic water-air jets that are spent on overcoming the mechanical structure of the mesh web.

A device is known for washing the mesh web of a fish protection structure [3], including a pump mounted on a trolley connected to the pump and located behind the mesh web, a vertical perforated washing pipe facing with openings in the direction of the mesh web.

The disadvantage of this device is the low cleaning efficiency of the mesh web due to a significant (up to 50%) loss of kinetic energy of the hydraulic water-air jets that are spent on overcoming the mechanical structure of the mesh web.

The closest in technical essence and the achieved result is a fish protection structure [4], which includes a filter screen vertically mounted in the guides, made of a net cloth mounted on bearing frames, overlapping the inlet channel along the entire depth, a fish outlet located at the downstream end filter screen, a washing device in the form of a perforated pipe in communication with the pump, and an additional device for the removal of debris and juvenile fish placed in front of a mesh web with Orons of the inlet channel.

The disadvantage of this fish protection device is the low cleaning efficiency of the net web due to the ineffective flow pattern of the hydraulic water-air jets.

The aim of the invention is to increase the washing efficiency of the mesh fabric.

The invention consists in the following.

According to claim 1 of the claims. The implementation of an additional device for the removal of debris and young fish in the form of a waterproof screen and its placement in front of the washing flute can significantly reduce the influence of the dynamic pressure of the feed channel and increase the washing efficiency of the filter screen made of mesh cloth. The screen, made to the entire depth of the stream, perceives the hydrodynamic pressure of the transit stream, and the washing flute at this point in time due to the action of plane-parallel hydraulic or water-air jets effectively cleans the surface of the filter screen.

The implementation of the mesh fabric with additional guides made in the form of channels, shelves fixed to the inner surface of the mesh fabric, allows you to form a filter screen without protrusions and roughness in the form of a mesh screen facing the supply channel. In this case, pairs of channels form the guides that come into contact with the guides of the supporting structures, beams of the I-section taken to the side of the supply channel and fixed to the end parts of the bulls (Fig. 1).

The fastening of the screen on the washing flute allows you to ensure the reliability of the structure, as well as their simultaneous movement along the filter screen and effective washing of the filter screen.

Placing the wash pipe in front of the net sheet and supplying its perforation holes with nozzles installed at an acute angle to the longitudinal axis of the washing pipe, and their outlet holes are oriented to the surface of the water, allows you to form a hydraulic wash jet along the filter screen. This method of supplying jets from the perforation holes of the washing pipe allows you to use all the kinetic energy of the feed stream and use it to clean and rinse the screen from debris and algae.

According to claim 2 of the claims. The execution of nozzles, in plan, at an acute angle to the plane of the net, allows you to enhance the effect of the washing jets on the surface of the filter screen.

According to claim 3 of the claims. An option for the location of the nozzles when their outlet openings are oriented towards the waterproof screen. In this case, the volume of the additional flow involved in the internal body of the jet increases, which entails an increase in the ejection ability of the hydraulic jets and, accordingly, an increase in the probability of separation of debris particles from the surface of the net web. In addition, this arrangement creates a more sparing regime for juvenile fish caught in the zone of influence of the wash flow.

According to claim 4 of the claims. The execution of nozzles parallel to the plane of the net cloth (filter screen) is also a variant of the nozzle arrangement, while the net cloth is effectively cleaned, and optimal conditions are created for the removal of juvenile fish from the filter screen.

According to claim 5, the claims. The implementation of a waterproof screen with a cowl-visor mounted on the opposite side from the nozzle outlet openings, at an acute angle to the plane of the net cloth, allows you to eliminate the influence of the external flow on the process of forming the washing jets, their distribution along the plane of the net screen when moving the washing device along the filter screen, and the process of cleaning the filter screen from debris.

The implementation of the visor-fairing at an acute angle to the plane of the net cloth allows you to reduce the amount of hydraulic resistance during the reciprocating movement of the washing device along the filter screen.

According to claims 6. 7 and 8 of the claims. The implementation of the visor-fairing curved, in plan, shape and layout of its concave or convex surface with respect to the perforated pipe allows to reduce the frontal hydraulic resistance to flow, as well as to improve the flow around the transit flow of the visor and the screen.

According to claim 9, the claims. The longitudinal axis of the upper nozzle of the water surface of the inlet channel allows the formation of a waste collection flow in the surface horizon of the watercourse and in the direction of the waste collection. All washed away debris lifted by the washing streams of the perforated pipe is transported by the directed flow of the upper nozzle along the plane of the net.

According to claim 10 of the claims. The execution of nozzles on the end parts of the nozzles, while the nozzles are placed in the direction of the plane of the mesh web, allows you to maximize bring the hydraulic jet to the surface being cleaned. This arrangement can significantly increase the efficiency of cleaning the web from debris due to the optimal use of the kinetic energy of high-speed hydraulic jets.

According to claim 11, the claims. The supply of nozzles with mixing chambers, with nozzles located inside them, allows the formation of water-air hydraulic jets at the outlet of the outlet openings of the mixing chambers. Air is supplied from the atmosphere through an air supply pipe and air supply pipes and, due to ejection, enters the mixing chambers. Formed water jets can improve the cleaning efficiency of the mesh web, as well as the efficiency of lifting the trash into the surface horizons of the watercourse. Placing the nozzle outlet plane under the outlet of the air inlet allows for maximum ejection ability of the mixing chamber.

According to paragraph 12 of the claims. The execution of the end part of the nozzles with flow stabilizers, made in the form of flat plates located radially relative to the longitudinal axis of the nozzles, allows you to stabilize the water flow before it enters the nozzle. The stabilization of the flow allows you to direct its kinetic energy to the formation of washing jets, and not to allow the flow to swirl inside the nozzles, since this leads to a loss of kinetic energy of the flow.

According to item 13 of the claims. The execution of the end part of the nozzles, the longitudinal axis of which coincides with the longitudinal axis of the nozzles, with an air supply pipe made coaxially with the nozzles and nozzles, allows you to form a nozzle layout, at the outlet of which a water-air stream is formed. The air supply pipe is connected to the air supply manifold, the inlet of which is in communication with the atmosphere, and due to the ejection ability of the water flow (which is facilitated by the arrangement of the nozzle and the air supply pipe), air enters the washing stream.

According to claim 14. The execution of the outlet of the air supply pipe inside the outlet channel of the nozzle allows for the ejection of air into the hydraulic flushing jet. Air ejection occurs due to the high-speed section of the water stream, which takes place within the nozzle outlet channel.

According to clause 15 of the claims. The execution of the outlet of the air supply pipe in the plane of the outlet nozzle also allows for the ejection of air into the hydraulic flushing jet, which is greatly facilitated by the presence of a compressed section of the water jet, and is a layout option.

According to clause 16 of the claims. The execution of the outlet of the air supply pipe extended beyond the plane of the outlet nozzle also allows for the ejection of air into the hydraulic flushing jet and is a layout option.

According to claim 17. The implementation of the plane of the waterproof screen parallel to the plane of the net web is a variant of the layout of the screen and allows you to create a channel for the formation of a hydraulic or water-air washing jet.

According to claim 18. The execution of the screen plane at an acute angle to the plane of the net cloth allows you to enhance the effect of the washing jet on the surface of the filter screen due to the formation of a compressed cross section in the site of placement of the free end edge of the waterproof screen.

According to claim 19 of the claims. The implementation of the washing device with an additional waterproof screen located behind the screen, from the intake channel, parallel to the filter screen and opposite the main waterproof screen, improves the washing efficiency of the screen. In this arrangement, the net web on both sides is limited by screens that create a channel for more efficient distribution of the washing jets formed by the nozzles. In this case, the mesh web is not affected by the flow of the supply channel (function of the main screen), and the additional screen to the maximum extent helps to stop filtering through the mesh web.

For reliable operation, an additional waterproof screen with its upper part is fixed to the carriage of the washing device, and is also connected to the pipe of the suction pipe of the pump by additional connections. Thus, the main screen, the perforated pipe with nozzles and the additional waterproof screen are a single system that has the ability to reciprocate along the mesh web.

The authors presented in sufficient detail the constructive part of the application, illustrated by extensive graphic material, and tried to describe in detail the principle of operation of the device, and also disclosed the essence of the invention and the physical effects used in it, which leaves the examination with a minimum of opportunity to request additional materials. For their part, the authors hope for a constructive dialogue with expertise, which will be fruitful for both interested parties.

In general, the structural features of the independent and dependent claims meet the criterion of "significant differences" and are so interconnected that they form a single creative concept and allow achieving a total positive effect.

The solution to this problem is achieved by creating a new design of fish protection facilities, which includes a new washing device. Graphic material that explains the essence of the invention is presented in the following figures:

figure 1 is a fragment of a filter screen;

figure 2 - fish protection structure, plan;

figure 3 is a fragment of a washing device, a longitudinal section;

figure 4 is a longitudinal section through the structure;

5 is a view of the washing device from the supply channel;

6 is an embodiment of a waterproof screen combined with a cowl-visor;

7 is the same, the visor-fairing is made curved, facing the concave side to the perforated pipe;

Fig. 8 is an embodiment of a waterproof screen combined with a cowl-visor convex side to a perforated pipe;

Fig.9 is a variant of the layout of the washing device, nozzles are located at an acute angle to the plane of the net web;

figure 10 is a variant of the layout of the washing device, nozzles are located at an obtuse angle to the plane of the net web;

11 is a variant of the layout of the washing device, the screen is placed at an acute angle to the plane of the net web;

Fig - view of the washing device from the intake channel;

Fig.13 is a view A in Fig.12;

Fig.14 is a view of B in Fig.13;

15 is a diagram of a washing nozzle on a nozzle;

Fig.16 is a view In Fig.15;

Fig.17 is a view of G in Fig.15;

Fig. 18 shows a construction of a nozzle with a nozzle equipped with flow stabilizers;

Fig.19 is a section I-I in Fig.18;

Fig - design of the mixing chamber and the nozzle;

Fig - design nozzle located on the pipe equipped with flow stabilizers;

Fig. 22 shows a design of a nozzle equipped with an air supply pipe made coaxially with it;

Fig.23 is the same, the outlet of the air supply pipe is made in the same plane with the outlet of the nozzle;

Fig.24 is the same, the outlet of the air supply pipe made outside the nozzle;

Fig - washing device, an option with an additional screen;

Fig is the same fragment;

Fig.27 is a cross section of a washing device and the structure of the washing stream;

Fig - the same, the main screen is made at an acute angle to the mesh web;

Fig. 29 is a fragment of a washing device, nozzles are provided with air supply pipelines connected to an air supply manifold;

The fish protection device of the water intake structure includes a filter screen 1 vertically mounted in the guides, made of a net web fixed on the supporting frames, overlapping the supply channel 2 along the entire depth, a fish branch 3 located at the bottom 4, with the flow of the end of the filter screen 1, a washing device 5 in the form of a perforated pipe in communication with the pump, and an additional device for the removal of debris and juvenile fish, placed in front of the mesh web from the side of the inlet channel 2. An additional device lining for removal of debris and juvenile fish is made in the form of a screen 6, the net web is provided with additional vertical guides 7 made along its side surface facing the intake channel 8, and additional guides 7 are made in the form of a pair of channels secured by a shelf to the supporting frame and facing the inner part to each other, and the guides 9 of the supporting structures are carried out towards the supply channel, fixed to the end parts of the bulls-abutments 10 and are made in the form of a beam of I-section In this case, the perforated pipe is located in front of the net sheet, from the side of the supply channel 2, between the net sheet and a flat waterproof screen 6, facing the side of the supply channel 2 and fixed on the side surface of the perforated pipe 11, along its entire height, and the plane of the screen 6 is oriented along the filter surface 1 of the mesh web, and the holes of the perforation of the washing flute 11 are provided with nozzles 12 mounted at an acute angle to the longitudinal axis of the perforated pipe 11, while their outlet openings are about oriented to the surface of the water.

In addition, nozzles 12, in plan, can be located at an acute angle to the net web.

In addition, nozzles 12, in plan, can be located at an obtuse angle to the net web, and their outlet openings are oriented toward the waterproof screen 6.

In addition, nozzles 12, in plan, can be arranged parallel to the web 1.

In addition, the waterproof screen 6 can be equipped with a cowl-visor 14, mounted behind the perforated pipe 11, on the opposite side from the outlet openings 13 of the nozzles 12, while the visor-cowl 14 is made at an acute angle to the plane of the net web 1.

In addition, the visor-fairing 14, in plan, can be made curved.

In addition, the visor-fairing 14 with the concave side may be facing the perforated pipe 11.

In addition, the visor-fairing 14 with the convex side may be facing the perforated pipe 11.

In addition, the longitudinal axis of the upper nozzle 15 can be made parallel to the plane of the net web 1.

In addition, the nozzle 12 can be located on the inlet pipes and taken out towards the plane of the net web 1.

In addition, the nozzles 12 can be equipped with mixing chambers 16 and located inside them, while the diameter of the mixing chambers 16 is larger than the outer diameter of the nozzles 12, and the plane of the outlet 13 of the nozzles 12 can be offset inside the mixing chambers 16 and is located under the outlet 17 air supply pipe 18 connected to the duct 19 in communication with the atmosphere.

In addition, the end part of the nozzles is made with flow stabilizers 20 in the form of flat plates located radially relative to the longitudinal axis of the nozzles and fixed by the end part to the inner walls of the nozzles.

In addition, the end part of the nozzles, the longitudinal axis of which coincides with the longitudinal axis of the nozzles 12, can be provided with an air supply pipe 21, made coaxially with the pipes and nozzles 12, inside them, while the air supply pipe 21 is connected to the air supply manifold 22, the inlet of which communicates with the atmosphere.

In addition, the outlet of the air supply pipe 21 can be placed inside the outlet channel of the nozzle 12.

In addition, the outlet of the air supply pipe 21 can be placed in the plane of the outlet of the nozzle 12.

In addition, the outlet of the air supply pipe 21 can be placed outside the interior of the nozzle 12.

In addition, the plane of the waterproof screen 6 can be made parallel to the plane of the net web 1.

In addition, the plane of the waterproof screen 6 can be made at an acute angle to the plane of the net web 1.

In addition, the washing device 5 can be equipped with an additional waterproof screen 23, located behind the net web, from the intake channel 2, parallel to the filter screen 1 and opposite the waterproof screen 6, combined with the perforated pipe 11, while the additional screen 23 is fixed with its upper part on the trolley 24 of the washing flute 5, and additional connections 25 connected to the pipe of the suction pipe 26 of the pump 27.

When cleaning the filter screen 1 of the nozzles 12, washing flows 28 are formed.

Fish protection construction works as follows.

As the fish protection structure is in operation, the filter screen 1 gradually becomes clogged with trash, filamentous algae and formations. To restore the design throughput of the mesh web, the operating service, acting in accordance with the requirements of the service instruction, includes a washing device 5, which can operate periodically or continuously, depending on the degree of clogging of the filter screen 1. By means of a drive (not shown), the cart 24 starts its return - progressive movement along the guides of the flyover (Fig.2, 4 and 5). At the same time, hydraulic jets in the form of a washing stream 28 come from the nozzles 12 of the perforated pipe 11, which are oriented along the plane of the filter screen 1 and effectively clean it of debris. With such a scheme for washing the net web, all the kinetic energy of the hydraulic jets is effectively used, which is expended on the separation of debris particles and fibrous inclusions from the cells of the net web and their removal to the upper horizons of the watercourse. Purified from debris and juveniles, the water flow coming from the supply channel 2, enters the intake channel 8 and then disassembled by consumers. The effective cleaning of the mesh web and the operation of the washing device 5 is facilitated by the presence of a waterproof screen 6, which perceives its external surface facing the supply channel 2, the dynamic pressure of the transit stream and creates favorable conditions for the spread of washing jets along the filter screen 1. Orientation of nozzles 12 and their outlet openings to the surface of the water creates the conditions for the formation of a powerful waste collection flow in the direction of fish drain 3.

To improve the washing efficiency of the filter screen 1, the screen 6 of the washing device 5 can be equipped with a cowl-visor 14 (Fig.6-11), the main function of which is to create favorable conditions for the operation of the washing flows 28. The shape and configuration of the cowl-cowl 14 may be different , but at the same time it prevents the influence of the surrounding water environment on the operation of the nozzles 12 and significantly reduces the hydraulic resistance when moving the washing device 5.

An embodiment of the device with nozzles 12 made on the end parts of the nozzles (Figs. 14, 15, 16 and 17) allows not only to make and bring nozzles 12 closer to the plane of the filter screen 1, but also to orient the outlet openings 13 of nozzles 12 at an acute angle to net cloth, which increases the efficiency of cleaning the screen 1 and the removal of washable debris.

The device inside the end parts of the nozzles of the flow stabilizers 20 in the form of radially mounted flat plates (Figs. 18, 19 and 21) does not allow the working flow to swirl relative to the longitudinal axis of the pipes, which ensures a more complete use of the kinetic energy of the washing flow.

To increase the washing efficiency of the mesh cloth of the filter screen 1, the nozzles 12 can be equipped with mixing chambers 16 (Fig. 20), while the nozzles 12 are located inside the chambers 16, and the outlet openings 13 of the nozzles 12 are aligned with the outlet openings of the mixing chambers 16. Placing the plane of the outlet 13 under the outlet 17 of the air supply pipe allows for efficient ejection of air entering the air supply manifold 22 from the atmosphere. This arrangement allows the formation of hydraulic water-air jets at the outlet of the mixing chambers 16, which, due to the presence of microbubbles of air, act more intensively on the surface of the net web and contribute to the separation of debris and destruction of the structure of fibrous inclusions stuck in the cells of the filter screen 1. In addition, the water-air jets 28 contribute to the active removal of washed garbage in the upper horizons of the stream.

Possible operation of the washing device 5 in the case of nozzles 12 with coaxially located inside them air inlet pipes 21 (Fig.22, 23 and 24). This arrangement is simpler compared to the arrangement containing the mixing chambers 16, and also allows, due to ejection, the formation at the outlet of the nozzles 12 of the water jets 28 (FIGS. 28 and 29).

The presence of an additional screen 23, located behind the mesh web, from the intake channel 8 (Figs. 26, 27 and 28), allows you to create the most favorable hydraulic conditions for washing the mesh cloth of the filter screen 1. By attaching the additional screen 23 with its upper part to the trolley 24, as well as connecting it with additional connections 25 with the suction pipe 26 of the pump allows not only to create a reliable design of the washing device 5, but also to ensure the constant movement of the screen 23 along the intake front (Fig.25).

The proposed fish-protection structure allows for efficient cleaning of the filter screen, since the design uses a plane-parallel scheme for supplying hydraulic or water-air washing jets. Using this washing method allows the maximum use of the kinetic energy of the washing jets. The device has a wide range of structural elements, allowing, taking into account both the characteristics of the watercourse and the biological characteristics of juvenile fish, to provide a high level of washing of the net web and, accordingly, a high level of fish protection.

Sources of information

1. A.S. USSR No. 631130 (USSR). IPC A 01 K 61/00, E 02 B 8/08. "Device for cleaning fish nets." Author: Ryabukhin L.G. Published. 11/05/78, B.I. No. 41, 1978.

2. A.S. USSR No. 1493730 (USSR). E 02 B 8/08, E 02 B 9/04. "A device for washing the mesh fabric of a fish protection structure." Authors: G.M. German, V.N. Shkura, P.A. Mikheev, A.A. Chistyakov and L.V. Efremkina. Published. 07/15/89, B.I. No. 26, 1989.

3. A.S. USSR No. 1629384 (USSR). E 02 B 8/08, E 02 B 9/04. "A device for washing the mesh fabric of a fish protection structure." Authors: G.M. German, A.A. Chistyakov, V.N. Shkura, M.P. Mikheev and V.M. Voloshkov. Published. 02/23/91, B.I. No. 7, 1991.

4. A.S. USSR No. 1372004 (USSR). E 02 B 8/08. "A device for washing the mesh web." Authors: V.A. Fomenko, A.A. Chistyakov, V.A. Cherkasov, P.V. Ivanov and G.N. Puras. Published. 02/07/88, B.I. No. 5, 1988.

Claims (19)

1. Fish protection structure, including a filter screen vertically installed in the rails, made of a net cloth mounted on bearing frames, overlapping the supply channel throughout the entire depth, a washing device in the form of a perforated pipe in communication with the pump, a fish outlet located at the downstream end of the filter screen, and an additional device for removal of debris and juvenile fish, placed in front of the net web from the inlet channel, characterized in that the additional device for I trash and juvenile fish is made in the form of a waterproof screen, the net cloth is equipped with additional vertical guides made along its side surface facing the intake channel, and additional guides are made in the form of a pair of channels, fixed by a shelf to the supporting frame and facing each other to a friend, and the guides of the supporting structures are brought out towards the supply channel, fixed to the end parts of the bulls and are made in the form of a beam of I-section wherein the perforated pipe is located in front of the mesh fabric from the supply channel side, between the mesh fabric and a flat waterproof screen facing the supply channel and fixed to the lateral surface of the perforated pipe along its entire height, the plane of the waterproof screen oriented along the filtering surface of the mesh fabric, and the holes of the perforation of the pipe are equipped with nozzles installed at an acute angle to the longitudinal axis of the perforated pipe, while their outlet openings are about ientirovany to the water surface. 2. Fish protection structure according to claim 1, characterized in that the nozzles in plan are located at an acute angle to the net web. 3. Fish protection structure according to claim 1, characterized in that the nozzles in plan are located at an obtuse angle to the net web, and their outlet openings are oriented towards the waterproof screen. 4. Fish protection structure according to claim 1, characterized in that the nozzles in plan are parallel to the net web. 5. Fish protection structure according to any one of paragraphs. 1 to 4, characterized in that the waterproof screen is equipped with a cowl-visor installed behind the perforated pipe on the opposite side from the nozzle outlet openings, while the cowl-visor is made at an acute angle to the plane of the net web. 6. Fish protection structure according to claim 5, characterized in that the cowl-visor is made in a curved shape in plan. 7. Fish protection structure according to claim 6, characterized in that the visor-fairing has a concave side facing the perforated pipe. 8. Fish protection structure according to claim 6, characterized in that the visor-fairing has a convex side facing the perforated pipe. 9. Fish protection structure according to any one of paragraphs. 1 - 4, 6 - 8, characterized in that the longitudinal axis of the upper nozzle is made parallel to the surface of the water. 10. Fish protection structure according to any one of paragraphs. 1 - 4, 6 - 8, characterized in that the nozzles are located on the inlet pipes and are taken out towards the plane of the net web. 11. Fish protection structure according to any one of paragraphs. 1 - 4, 6 - 8, characterized in that the nozzles are equipped with mixing chambers and are located inside them, while the diameter of the mixing chambers is larger than the outer diameter of the nozzles, and the plane of the nozzle outlet is offset inside the mixing chambers and is located under the outlet of the air supply pipe, connected to the duct communicating with the atmosphere. 12. Fish protection structure according to claim 11, characterized in that the end part of the inlet pipes is made with flow stabilizers in the form of flat plates located radially relative to the longitudinal axis of the pipes and fixed by the end part to the inner walls of the pipes. 13. Fish protection structure according to claim 10, characterized in that the end part of the supply nozzles, the longitudinal axis of which coincides with the longitudinal axis of the nozzles, is provided with an air supply pipe made coaxially with the pipes and nozzles inside them, while the air supply pipe is connected to the air supply manifold, the input whose opening is communicated with the atmosphere. 14. Fish protection structure according to claim 13, characterized in that the outlet of the air supply pipe is located inside the outlet of the nozzle. 15. Fish protection structure according to claim 13, characterized in that the outlet of the air supply pipe is located in the plane of the nozzle outlet. 16. Fish protection structure according to claim 13, characterized in that the outlet of the air supply pipe is located outside the internal space of the nozzle. 17. Fish protection structure according to any one of paragraphs. 1 - 4, 6 - 8, 12, 13, 15 and 16, characterized in that the plane of the waterproof screen is made parallel to the plane of the net web. 18. Fish protection structure according to any one of paragraphs. 1 - 4, 6 - 8, 12 - 16, characterized in that the plane of the waterproof screen is made at an acute angle to the plane of the net web. 19. Fish protection structure according to any one of paragraphs. 1 - 4, 6 - 8, 12 - 16, characterized in that it is equipped with an additional waterproof screen placed behind the net web from the intake channel parallel to the filter screen and opposite the waterproof screen combined with the perforated pipe, with an additional waterproof screen top part is fixed on the carriage of the washing device, and is connected to the pipe of the suction pipe of the pump by additional connections.

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