RU2277615C1 - Method for fish attraction into inlet head of fish-passing spawning channel and fish-passing spawning channel for above method realization - Google Patents

Abstract

FIELD: hydraulic building, particularly fish passes adapted for permitting fish passage through support structures to fish hatchery and growth areas.

SUBSTANCE: fish-passing spawning channel comprises waterway made as a channel having outlet head connected with upper hydrosystem pool and inlet head connected to lower pool thereof. Fish-passing spawning channel has roughness members made as parallelepipeds installed at channel bottom along channel length so that the roughness members extend at acute angle to longitudinal channel axis. The fish-passing spawning channel is also provided with additional feeding unit having inlet part connected with upper pool and outlet part connected with inlet head. Outlet additional feeding block part is parallel to longitudinal inlet head axis. Additional outlet head of additional feeding unit is located in waterway center and is coaxial to longitudinal axis of inlet head. Waterway of additional feeding unit is made as pressure conduit connected with bottom of additional outlet head included in additional feeding unit. Outlet waterway part is provided with outlet orifices. Additional flow is supplied simultaneously in current direction and against the current of main flow in waterway so that water flow directed in main flow direction increases attractive flow velocity along longitudinal axis of inlet head, water flow part directed against main flow direction dissipates kinetic water flow energy due to mutual dissipation of main flow energy and counter flow energy.

EFFECT: possibility of effective additional water flow usage, prevention of fish misorientation, elimination of additional member usage for kinetic flow energy dissipation, improved hydraulic conditions for fish passage in fish-passing spawning channel.

25 cl, 30 dwg

Description

The invention relates to hydraulic engineering, in particular to fish passage facilities designed to allow fish producers to pass through retaining structures to spawning and feeding grounds.

There is a method of attracting fish to the inlet head of a fish-spawning canal [1], which consists in creating a fish attracting stream in the inlet of the inlet head by supplying an attracting flow from the water supply path and additional water supply paths to the inlet head, while forming a stable hydraulic structure in the influence zone entry head and against the background of the search zone for fish.

The disadvantage of this method is the low efficiency of attracting fish to the inlet head and the irrational use of water resources.

The closest technological scheme is the method of attracting fish to the inlet head of the fish-spawning channel [2], which consists in creating a fish attracting stream in the inlet of the inlet head by supplying an attractive flow from the water supply path and an additional power supply to the inlet head, while forming a stable hydraulic structure in the zone of influence of the input head and against the background of the search zone for fish.

The disadvantage of this method is the low efficiency of attracting fish to the fish passage tract of the channel and the irrational use of additional water flow.

Known fish passage and spawning channel [1], including a water path made in the form of a channel, the head part of which is connected to the upper pool of the hydraulic system, and the mouth part is connected to the lower pool, elements of enhanced and natural roughness installed on the bottom of the channel along its length and additional flow paths, the head parts of which are connected to the water supply path, while additional flow paths are made with different longitudinal slopes.

The disadvantage of this structure is the low efficiency of the allocation of attracting fish flow generated in the inlet head.

The closest in technical essence and the achieved result is a fish-spawning channel [2], including a water supply path made in the form of a channel, the output head of which is connected to the upper pool of the waterworks, and the input head - to the lower pool, elements of enhanced roughness, made in the form parallelepipeds installed on the bottom of the channel along its length at an acute angle to the longitudinal axis of the channel and an additional power supply unit, the input part of which is connected to the upper pool, and the output part to the input head, the output part of the additional power supply is parallel to the longitudinal axis of the input head.

The disadvantage of this method is the low efficiency of attracting fish to the fish passage tract of the channel and the irrational use of additional water flow.

The aim of the invention is the creation of effective hydraulic conditions in a fish-spawning channel for the passage of fish into its internal space.

The invention consists in the following.

According to claim 1 of the claims. The technology by which the additional flow of water is simultaneously supplied in the direction and against the direction of the flow of the main stream in the water supply path, makes it possible to rationally use the additional flow of water. Indeed, the flow of water in the direction of flow of the main stream in the water path, allows you to increase the attractive speed along the longitudinal axis of the inlet head. At the same time, the simultaneous supply of a part of the water flow against the direction of the main flow in the water supply path can increase the efficiency of quenching the kinetic energy of the water flow due to the mutual quenching of the main and oncoming streams. In this case, there is no disorientation of the fish when they move along the water supply path and is not introduced into the stream of additional elements to damp the kinetic energy of the water stream.

According to claim 2 of the claims. The supply of additional water flow in the form of concentrated hydraulic jets is an option and allows more fully use the kinetic energy of the flooded concentrated stream. (Note. A concentrated jet is a compact jet that freely spreads in a given direction in the surrounding water space and does not experience mutual influence with other jets).

According to claim 3 of the claims. The supply of additional water flow in the form of dispersed hydraulic jets is also an option and allows more fully use their spatial layout and, accordingly, the kinetic energy of the flooded dispersed jets. (Note: A dispersed jet is a group of compact jets freely distributed in different directions in the surrounding water and experiencing mutual influence with other jets).

According to claim 4 of the claims. The supply of additional water flow to the bottom horizons allows more fully use the effect of quenching the kinetic energy of the water stream.

According to claim 5, claims. The supply of additional water flow to the surface horizons allows for unhindered passage of bottom fish species along the water supply path.

According to claim 6, claims. The implementation of the input head of the fish-spawning channel, equipped with an additional output head, an additional power supply located in the center of the water supply path, coaxial to the longitudinal axis of the input head, allows for the supply of additional flow along the channel axis. At the same time, the attracting "loop" of velocities in the central part of the channel is enhanced and, simultaneously, when the water flow is directed against the direction of the main stream in the channel, the efficiency of quenching the kinetic energy of the water stream is increased. In addition, a hydraulic jet or jets directed against the direction of flow of the main stream in the channel provide additional support of the water level in the alignment of the additional output head of the additional power unit, which makes it possible to control the free surface curve and, accordingly, the hydraulic mode in the estuarine part of the fish passage spawning channel.

The implementation of the water supply path of the additional power supply unit is made in the form of a pressure water conduit and its connection with the bottom of the additional output head of the additional power supply unit allows rationalizing the working water flow rate. In this case, the live section of the channel does not experience additional resistance.

The implementation of an additional outlet head with outlet holes located on its outer surface, allows you to evenly distribute the additional flow of water attracting fish.

According to claim 7 of the claims. The implementation of an additional output tip flooded is an option for its execution. With this arrangement, conditions are created for the effective attraction of bottom fish species, as well as for the effective quenching of the kinetic energy of the water stream in the bottom horizons of the stream.

According to claim 8 of the claims. The implementation of an additional output head unfrozen is also an option for its execution. With this arrangement, conditions are created for the effective attraction of fish living in the surface horizons of the stream, as well as for the effective quenching of the kinetic energy of the water stream in the surface horizons of the stream.

According to claim 9, the claims. Performing an additional outlet head of an additional power supply unit with outlet openings located on its end walls located perpendicular to the longitudinal axis of the inlet head of the water supply path, feed the additional flow along the channel axis both in the direction and against the direction of the main flow of the water supply path.

According to claim 10 of the claims. The execution of round outlets is a variant of their execution and allows the formation of flooded axisymmetric hydraulic jets.

According to claim 11, the claims. The execution of the outlet openings of a rectangular shape is also an option for their execution and allows you to form a flat hydraulic stream.

According to paragraph 12 of the claims. The execution of rectangular outlet openings located horizontally is an option for their spatial placement.

According to item 13 of the claims. The execution of the outlet openings of a rectangular shape, arranged vertically, is also an option for their spatial placement.

According to claim 14. The execution of the part of the outlet openings of the additional outlet head located on its side walls parallel to the longitudinal axis of the inlet head of the water supply path allows the formation of hydraulic jets distributed perpendicular to the main flow in the water supply path. This arrangement allows you to form the maximum quenching of the kinetic energy of the water stream.

According to clause 15 of the claims. The implementation of the part of the outlet openings of the additional outlet head, located on its upper horizontal cover, allows you to quench the kinetic energy of the water stream in the surface horizons of the water stream.

According to clause 16 of the claims. The implementation of the outlet openings of the additional outlet head, located in height of several tiers, allows you to enhance the degree of impact of the additional flow rate on the transit flow of water. In addition, this arrangement provides a more uniform distribution of additional flow.

According to claim 17. The execution of the outlet openings of even tiers offset relative to the outlet openings of the odd tiers increases not only the uniform distribution of the additional flow rate, but also the efficiency of quenching the kinetic energy of the transit stream.

According to claim 18. The execution of the outlet openings of the additional outlet head in the form of spill faces along its side walls parallel to the longitudinal axis of the inlet head of the water supply path, while the upper part of the additional outlet head is open, allows for a small flow to generate an additional flow rate from the unfilled outlet head.

According to claim 19 of the claims. The implementation of the upper part of the additional outlet head with a lid creates optimal conditions for the spreading of the supplied additional flow. This option is possible with high pressure in the water supply path.

According to claim 20 of the claims. The execution in the upper part of the output head, coaxial to it, of a V-shaped directing device, while its top is facing inside the frame of the output head, allows optimizing the conditions for the release of additional flow to the surface of the main stream. The V-shape forms the direction of exit of the additional flow rate, evenly distributing it into two autonomous flows.

According to claim 21. The implementation of the cover of the frame with perforation holes allows you to apply through them an additional flow of water to the surface of the main stream (additional output head of the additional power unit is made unfrozen).

According to claim 22. The execution of the cover of the frame of a V-shaped, with its top facing up, is an embodiment. This increases the total area of the perforation holes and improves the conditions for the release of additional water flow to the surface of the main stream.

According to claim 23 of the claims. The execution of the lid of the frame hemispherical shape, while its concave surface is turned inside the output head, is also an embodiment of the cover. This increases the total area of the perforation holes and improves the conditions for the release of additional water flow to the surface of the main stream.

According to paragraph 24 of the claims. The implementation of the frame of the additional output head, moving relative to the vertical guides, with the outlet openings located in the upper part of the frame, and the lower part of the frame equipped with sealed containers filled with air, allows for small differences in water levels of the upper and lower pools to supply additional water flow to the surface horizons of the main stream . When the depth in the inlet head of the fish-spawning canal changes due to buoyancy (pontoons in the form of sealed containers), the movable part of the additional outlet head tracks this change, while the additional flow of water is always supplied to the surface horizons of the main stream flowing through the water supply path.

According to claim 25 of the claims. The implementation of the input head of the water supply path with fish-guiding devices in the form of bottom thresholds, while the thresholds, in plan, are curved and their convex side facing the upstream, allows you to create a stationary fish-guiding system, due to which the bottom fish species (e.g. sturgeon) are stable tactile landmarks, moving along which they enter the fish-breeding and spawning canal.

The solution to this problem is achieved by implementing a new method of attracting fish to the input head of the fish-spawning channel and creating a new design of the fish-spawning channel that implements it. Graphic material that explains the essence of the invention is presented in the following figures:

figure 1 - input end of the fish-spawning channel, plan;

figure 2 is the same, the option of supplying an additional flow of water in and against the direction of flow in the water path;

figure 3 is a section aa in figure 1;

4 is the same, an embodiment of the exhaust openings in tiers;

5 is a section bB in figure 1;

6 is the same, the option of supplying an additional flow of water against the direction of flow in the water path;

Fig.7 is the same, the option of supplying an additional flow of water in and against the direction of flow in the water path;

Fig. 8 is a cross-sectional view of a water path, an embodiment of supplying an additional water flow perpendicular to the direction of flow in the water path;

Fig.9 is the same, the option of feeding in the horizontal plane;

figure 10 is a transverse section of the water path, the option of simultaneously supplying an additional flow of water perpendicular to the direction of flow in the water path in vertical and horizontal planes;

11 is a longitudinal section of the output tip of the additional power supply, an option for supplying additional flow through the end and side surfaces, the outlet openings are made in tiers;

Fig - the same, the exhaust holes are made in a rectangular shape;

Fig.13 is the same, the outlet openings are made in a rectangular shape and are offset from each other;

Fig - longitudinal section of the output tip of the additional power supply, an option for supplying additional flow through the exhaust holes made in the lid of the frame of the output head of the additional power supply;

Fig. 15 shows an output tip of an additional power supply unit, a plan, an option for supplying additional flow rate through outlet openings made in the side walls of the frame of the output tip of an additional power supply unit;

Fig. 16 is a cross-sectional view of the water supply path, a view of the end part of the outlet head, the outlet openings are round in shape and are arranged in tiers;

Fig is a cross section of a water path, a view of the end part of the outlet head, the outlet is made in a rectangular shape and forms a concentrated hydraulic stream;

Fig. 18 is a cross-sectional view of the water supply path, a view of the end part of the outlet head, the outlet openings are rectangular in shape and form dispersed hydraulic jets;

Fig.19 is a cross section of a water path, a view of the end part of the outlet head, the outlet is made in a rectangular shape, is horizontal and forms a concentrated hydraulic stream;

Fig. 20 is a cross-sectional view of a water supply path, an option for supplying an additional flow rate through lateral spill faces of an output head frame, the upper part of the output head is open;

Fig - the same, an option with a top cover;

Fig. 22 is a cross-sectional view of the water supply path, an option for supplying additional flow rate through the lateral spill faces of the output head frame, the upper part of the output head is open and provided with a V-shaped flow guide device, the apex of which faces inward of the output head frame;

23 is a cross-sectional view of a water supply path, an option for supplying additional flow rate through lateral spill faces of an output head frame and a perforated outlet head cover;

Fig - the same, an embodiment of the cover of a V-shaped, with its top facing up;

Fig - cross section of the water path, the option of supplying additional flow through the lateral spill faces of the frame of the output head and the perforated cover of the output head, made hemispherical in shape;

Fig is a longitudinal section of the output head, a variant of the output head made moving relative to the vertical guides, and the exhaust holes are located in the upper part of the frame, and the lower part of the frame is equipped with airtight containers filled with air, an intermediate position;

Fig.27 is the same, the lower position of the output tip;

Fig. 28 is a view of the output tip of the additional power supply unit from the side of its side wall, the tip is in the lowest position;

Fig.29 is the input tip of the water supply path, plan, variant with bottom curvilinear thresholds;

Fig. 30 is a layout diagram of a fish passage and spawning channel as part of a low-pressure hydroelectric facility, plan.

The fish spawning channel includes a water supply path 1 made in the form of a channel, the output tip 2 of which is connected to the upper pool of the hydraulic system, and the input tip 3 is connected to the lower pool, reinforced roughness elements 4 made in the form of parallelepipeds mounted on the bottom of the channel along its length at an acute angle to the longitudinal axis of the channel, and an additional power supply 5, the input part of which is connected to the upstream, and the output part 6 is connected to the input tip 3, while the output part 6 of the additional power supply 5 is parallel flax longitudinal axis of the input tip 3.

The fish-spawning channel is equipped with an additional output head 7 of the additional power supply unit 5 located in the center of the water supply path 1, coaxially to the longitudinal axis of the input head 3, while the water supply path 8 of the additional power supply unit 5 is made in the form of a pressure conduit that is connected to the bottom of the additional output head 7 of an additional power supply 5, while its output part 9 is made with outlet openings 10.

In addition, an additional output tip 7 may be flooded.

In addition, an additional output tip 7 can be made unfrozen.

In addition, the additional output tip 7 of the additional power supply unit 5 can be made with outlet openings 10 located on its end walls 11 located perpendicular to the longitudinal axis of the input end 3 of the water supply path 1.

In addition, the outlet openings 10 may be circular in shape.

In addition, the outlet openings 10 may be rectangular in shape.

In addition, the outlet openings 10 may be arranged horizontally.

In addition, the outlet openings 10 may be arranged vertically.

In addition, a part of the outlet openings 10 of the additional outlet head 7 may be located on its side walls 12 located parallel to the longitudinal axis of the inlet head 3 of the water supply path 1.

In addition, part of the outlet openings 10 of the additional outlet head 7 may be located on its upper horizontal cover 13.

In addition, the outlet openings 10 of the additional outlet head 7 may be located in height of several tiers.

In addition, the outlet openings 10 of even tiers may be offset relative to the outlet openings 10 of odd tiers.

In addition, the outlet openings 10 of the additional output head 7 can be made in the form of spill faces along its side walls 12 parallel to the longitudinal axis of the input head 3 of the water passage 1, and the upper part of the additional output head 7 is made open.

In addition, the upper part of the additional output head 7 may be provided with a cover 13.

In addition, in the upper part of the additional output head 7, coaxially to it, a V-shaped flow guide device 14 can be made, with its top facing the inside of the frame 15 of the additional output head 7.

In addition, the cover 13 can be made with perforation holes.

In addition, the cover 13 can be made V-shaped, with its top facing up.

In addition, the cover 13 can be made hemispherical in shape, while its concave surface faces the inside of the additional output tip 7.

In addition, the frame 15 of the additional output head 7 can be made moving relative to the vertical guides 16, and the outlet openings 10 are located in the upper part of the frame 15, and the lower part of the frame 15 is equipped with sealed containers 17 filled with air.

In addition, the input tip 3 of the water supply path 1 can be made with fish-guiding devices in the form of bottom sills 18, while the sills 18 are curved in plan and have their convex side facing the upstream.

For spawning of fish directly in the water supply path 1 of the fish passage and spawning canal, its bottom is made with gravel and pebble bedding 0.3 meters thick, which serves as a spawning substrate 19.

To control the supply of additional flow, the water supply path 8 is equipped with valves 20.

The guides 16 in their upper part have stops 21. The input tip 3 and the output part 6 of the additional power supply 5 are separated by a flow guide wall 22.

The method of attracting fish to the input head in the fish-spawning channel is as follows.

The technology by which the additional flow of water is simultaneously supplied in the direction and against the direction of the flow of the main stream in the water supply path 1, makes it possible to rationally use the additional flow of water. Indeed, the flow of water in the direction of flow of the main stream in the water supply path 1, allows you to increase the attractive speed along the longitudinal axis of the inlet head 3. At the same time, the simultaneous supply of part of the water flow against the direction of the flow of the main flow in the water flow path 1, allows to increase the efficiency of quenching the energy of the water stream due to the mutual cancellation of the main and oncoming flows. In this case, there is no disorientation of the fish when they move along the water supply path 1 and is not introduced into the stream of additional elements to damp the kinetic energy of the water stream.

The method can be implemented by the following technology. The supply of additional water flow in the form of concentrated hydraulic jets (Fig.1, 17 and 19) is an option and allows more fully use the kinetic energy of the flooded concentrated stream.

The method can be implemented by the following technology. The supply of additional water flow in the form of dispersed hydraulic jets (Figs. 3, 4, 5, 16 and 18) is also an option and allows more complete use of their spatial layout and, accordingly, the kinetic energy of the flooded dispersed jets.

The method can be implemented by the following technology. The supply of additional water flow to the bottom horizons (Fig.3-7, 9, 11, 12, 13, 15-19) allows you to more fully use the effect of quenching the kinetic energy of the water stream.

The method can be implemented by the following technology. The supply of an additional flow rate of water is fed to the surface horizons (Figs. 8, 14, 20-25) to ensure unhindered passage of bottom fish species along the water supply path 1.

Fishery-spawning channel works as follows.

The attraction of fish from the downstream end to the inlet head 3 of the water supply path 1 is carried out by supplying the working flow from the upstream flowing through the water supply path 1. In addition, due to the operation of the additional power supply unit 5 along the water supply path 8, a parallel to the flow guide wall 22 from the output part 6 is supplied concentrated hydraulic stream, which forms the outer boundary of the fish-attracting "train" of speeds (figures 1, 2 and 29). This diagram of the formation of the external border allows you to enhance the allocation of attracting fish flow due to the constant supply to the output part 6, made from the outer surface of the flow guide wall 22. The outlet of the output part 6 is located in the surface horizon of the stream and parallel to its plane. When a working flow of water is supplied from the outlet of the outlet part 6, a plane-parallel hydraulic stream flows out, which at the initial stage of its propagation moves along the outer surface of the flow-directing wall 22. This scheme of supplying an additional water flow allows due to the dynamic action of a plane-parallel hydraulic stream on the river flow, as well as due to the active ejection of the surrounding water masses, it is possible to increase not only the propagation range of the fenders, but also allows the formation of be stable conditions for forming the outer boundary of the flow which attracts fish.

Bottom species of fish (for example, sturgeon), moving mainly at the bottom of the watercourse, focusing on the attracting bottom stream, enter the inlet head 3, and then advance to the water supply path 1, where optimal conditions for their spawning on the spawning substrate 19 are created.

To increase the efficiency of attracting migrants from the zone of influence of the input tip 3 directly to the water supply path 1, the operation service includes an additional output tip 7 of the additional power supply 5 (Fig. 1). The layout of the additional output head 7 along the longitudinal axis of the fish-spawning channel allows to increase the high-speed flow along the axis of the input head 3, as well as depending on the location of the outlet openings 10 (on the end walls 11, side walls 12 or on the top cover of the output head 7) additional water flow to the bottom or surface horizons of the main flow of the water supply path 1. In addition, the creation of maximum speeds along the axis of the structure allows the formation of a re-gradient plan plot, directly in the mouth of the fish-spawning canal, which allows you to provoke a fish, concentrated in front of the input head 3 for active entry directly into the inner space of the water supply path 1.

It is possible to supply an additional water flow simultaneously in the direction (in the direction of the downstream) and against the direction of the main flow in the water supply path 1, which makes it possible to rationally use the additional water flow. At the same time, the simultaneous supply of part of the water flow against the direction of flow of the main stream in the water supply path 1 can improve the efficiency of quenching the kinetic energy of the water stream due to the mutual quenching of the main and oncoming streams. In this case, there is no disorientation of the fish when they move along the water supply path 1 and is not introduced into the stream of additional elements to damp the kinetic energy of the water stream (Fig.2, 7, 11 and 12).

Perhaps a constructive solution to the additional output tip 7, made flooded (Fig.3-19). In this embodiment, the outlet openings 10 can be placed:

- on the end walls 11 of the output tip 7 (Fig.3-7). In this case, three options for their placement are possible - on the end wall 11 facing the lower tail of the waterworks (Figs. 1 and 5); on the end wall 11 facing the main stream in the water path 1 (Fig.6); the simultaneous placement of the exhaust holes 10 on both end walls 11 (Fig.2 and 7);

- on the side walls 12 of the output head 7 (Fig.9,10, 11,12,13 and 15);

- on the top cover of the output tip 7 (Fig.8 and 14);

- on the side walls 12 and on the top cover of the output tip 7 (figure 10).

Each of the options for placing the outlet openings 10 has its own peculiarities and advantages, while these layouts correspond to the main function of the additional outlet head 7 — supplying an additional flow of water to the water supply path 1. The most effective layout of the outlet openings 10 is their combined arrangement on the outer surface of the additional outlet head 7 (Figs. 7, 10, 11, 12 and 13). In this case, the maximum effect is achieved by creating attractive velocities and quenching the excess kinetic energy of the water stream.

Embodiments of the outlets 10 are possible, which form concentrated or dispersed hydraulic jets. In the first embodiment (FIGS. 17 and 19), compact streams are formed, the energy of which allows both to attract fish and quench the kinetic energy of the water stream. In the second embodiment (Fig. 3, 4-7, 11-13), it is possible to more fully use its spatial layout and, accordingly, the kinetic energy of the flooded dispersed jets. The dispersed jets in the form of a group of compact jets freely propagate in different directions in the surrounding water space and experience mutual influence with other jets, while the power of their impact on the main stream of the water supply path 1 increases.

Perhaps a constructive solution to the additional output tip 7, made unfrozen (Fig.20-28). In this embodiment, the outlet openings 10 can be placed:

- on the side walls 12 of the additional output tip 7 (Fig.20-22 and 26-28);

- on the top cover 13 (Fig.23-25).

The main advantage of supplying an additional flow rate to the surface horizons of the flow of the water supply path 1 is the absence of concentrated flows in the bottom horizons, in which bottom fish species, for example, sturgeons, are mainly designed for fish passage and spawning channels.

A possible placement of the exhaust holes 10, arranged in tiers (Figures 4-7, 9-12 and 16). The implementation of the outlet openings 10 of the additional outlet head 7, located in height in several tiers, allows you to increase the degree of impact of the additional flow rate on the transit flow of water. In addition, this arrangement provides a more uniform distribution of additional flow.

A variant of the placement of the outlet openings 10 arranged in tiers is possible, while the outlet openings 10 of even tiers are offset relative to the outlet openings 10 of odd tiers by the size of the step of their placement (Figs. 4 and 13), which allows not only uniform distribution of the additional flow rate, but also damping efficiency kinetic energy transit flow.

A possible embodiment of the frame 15 of the additional output head 7, moving relative to the vertical guides 16, and the outlet holes 10 are located in the upper part of the frame 15, and the lower part of the frame 15 is equipped with sealed containers 17 filled with air, which allows for small differences in water levels of the upper and lower downstream feed the additional flow of water into the surface horizons of the main stream. When the depth in the inlet head 3 of the fish-spawning channel changes due to buoyancy (pontoons in the form of sealed containers 17), the movable part (frame 15) of the additional outlet head 7 monitors this change, while the additional water flow is always supplied to the surface horizons of the main stream, flowing through the water supply path 1.

An embodiment of the input head 3 of the water supply path 1 with fish guiding devices in the form of bottom sills 18 is possible, while the bottom sills 18 are, in plan, curved and their convex side facing the upstream, which allows the formation of a stationary fish guide system, due to which bottom species fishes (for example, sturgeons) have stable tactile landmarks, moving along which they enter the fish-passage and spawning canal.

The proposed layout of the inlet head is equipped with all the necessary tools that provide stable and efficient conditions for the formation of a fish attracting stream and providing effective quenching of the excess kinetic energy of the water stream.

Information sources

1. USSR author's certificate No. 1666633, "Fish passage and spawning canal", E 02 B 8/08, Shkura V.N., Chistyakov A.A., Novoydarsky A.V., Anokhin A.M. and Cherkasov V.A. (THE USSR). Publ. BI No. 28, 1991.

2. A.S. USSR No. 1544879, "Fish-pass", MKI E 02 B 8/08, Skura V.N., Sukalo G.M., Guyumdzhibashyan A.G., Anikin B.C. (THE USSR). Publ. BI No. 7, 1990.

Claims (25)

1. The method of attracting fish to the inlet head of the fish-spawning channel, which consists in creating a fish-attracting stream in the alignment of the inlet head by supplying an attracting flow rate from the water supply path and an additional power supply to the inlet head, and a stable hydraulic structure is formed in the zone of influence of the inlet head and against the background of the search zone for fish, characterized in that the additional flow of water is simultaneously supplied in the direction and against the direction of the main flow in the water supply I eat tract. 2. The method according to p. 1, characterized in that the additional flow of water is served in the form of concentrated hydraulic jets. 3. The method according to p. 1, characterized in that the additional flow of water is served in the form of dispersed hydraulic jets. 4. The method according to any one of paragraphs. 1 to 3, characterized in that the additional flow of water is fed into the bottom horizons. 5. The method according to any one of paragraphs. 1 to 3, characterized in that the additional flow of water is fed into the surface horizons. 6. Fishery-spawning channel, including a water supply channel made in the form of a channel, the output head of which is connected to the upper pool of the hydraulic system, and the input head - to the lower pool, reinforced roughness elements made in the form of parallelepipeds installed on the bottom of the channel along its length under an acute angle to the longitudinal axis of the channel, and an additional power supply, the input part of which is connected to the upstream, and the output part to the input head, while the output part of the additional power supply is parallel the longitudinal axis of the input head, characterized in that it is equipped with an additional output head of an additional power supply unit located in the center of the water supply path coaxially with the longitudinal axis of the input head, while the water supply path of the additional power supply unit is made in the form of a pressure conduit that is connected to the bottom of the additional output head additional power supply, while its output part is made with outlet openings. 7. Fishery and spawning channel according to claim 6, characterized in that the additional output tip is made flooded. 8. Fishery and spawning canal according to claim 6, characterized in that the additional output tip is made unfrozen. 9. Fishery-spawning channel according to claim 6 or 7, characterized in that the additional output head of the additional power supply unit is made with outlet openings located on its end walls located perpendicular to the longitudinal axis of the input end of the water supply path. 10. Fishery and spawning channel according to claim 6 or 7, characterized in that the outlet openings are round. 11. Fishery and spawning channel according to claim 6 or 7, characterized in that the outlet openings are made in a rectangular shape. 12. Fishery and spawning channel according to claim 11, characterized in that the outlet openings are arranged horizontally. 13. Fishery and spawning channel according to claim 11, characterized in that the outlet openings are arranged vertically. 14. Fishery and spawning channel according to any one of paragraphs. 6, 7, 12 and 13, characterized in that a part of the outlet openings of the additional outlet head is located on its side walls parallel to the longitudinal axis of the inlet head of the water supply path. 15. Fishery-spawning channel according to claim 6 or 7, characterized in that a part of the outlet openings of the additional outlet head are located on its upper horizontal cover. 16. Fishery and spawning canal according to claim 6 or 7, characterized in that the outlet openings of the additional outlet head are several tiers in height. 17. Fishery-spawning channel according to claim 16, characterized in that the outlet openings of even tiers are offset from the outlet openings of odd tiers. 18. Fishery and spawning channel according to claim 6 or 8, characterized in that the outlet openings of the additional outlet head are made in the form of spill faces along its side walls parallel to the longitudinal axis of the inlet head of the water supply path, and the upper part of the additional outlet head is open. 19. Fishery and spawning channel according to claim 18, characterized in that the upper part of the additional output tip is provided with a lid. 20. Fishery and spawning channel according to claim 18, characterized in that in the upper part of the output head, a V-shaped flow guide device is made coaxially with the top of the channel, while its apex is turned inside the frame of the output head. 21. Fishery and spawning channel according to claim 19, characterized in that the lid is made with perforation holes. 22. Fishery-spawning channel according to claim 21, characterized in that the lid is V-shaped, with its apex facing up. 23. Fishery-spawning channel according to claim 19, characterized in that the lid is hemispherical in shape, while its concave surface faces the outlet end. 24. Fishery and spawning channel according to claim 6 or 8, characterized in that the frame of the additional output head is made moving relative to the vertical guides, the outlet openings being located in the upper part of the frame and the lower part of the frame provided with sealed containers filled with air. 25. Fishery and spawning canal according to claim 6 or 8, characterized in that the input end of the water supply path is made with fish guiding devices in the form of bottom thresholds, while the thresholds in the plan are curved and their convex side facing the upstream.

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