RU2363807C1 - Inlet head of fish bypass (versions) - Google Patents

Abstract

FIELD: water supply engineering.

SUBSTANCE: invention concerns water supply engineering. Fish bypass head includes lower part of fish bypass route in tail pool, made in the form of graduated or leaning chute channel with lengthwise tilt towards head pool containing vertical splitter wall - inlet splitter wall - forming fish bypass inlet chamber with rectangular, square or round bypass holes along the whole width of bypass chambers. Jet generating nozzles are mounted along the hole perimetre at an angle or parallel to the hole axis inside discharge part of inlet hole formed by curtain deflectors on it; the nozzles are parallel to the plane of adjoining screening wall of curtain deflector. Discharge holes of nozzles can be positioned directly inside inlet holes between the planes of transverse splitter walls, or in separated channels. Inlet head of fish bypass - inlet splitter wall - is made in the form of two conjugated rectangular facets with bottom bypass inlet holes, and forms a triangle to the plane projection together with junction of drainage chute of the fish bypass route. Part of the ribs formed at junction of rectangular facets with each other and with vertical walls of drainage chute of the fish bypass route carry flow guiding walls.

EFFECT: improved efficiency of fish attraction to fish bypass facility.

33 cl, 28 dwg

Description

The invention relates to hydraulic engineering, in particular to structures designed to attract and transfer fish producers through retaining structures to spawning and feeding grounds.

Known fish passage for the passage of fish from the lower tail of the hydroelectric system to the upper one, proposed by O. Vvedensky and Polyanin A.Ya. (RF patent No. 2130990, class ЕВВ 8/08) and the design of a pump-ejector installation for transporting liquid from the first section to the second, higher located section, proposed by O. Vvedensky and Polyanin A.Ya. (RF patent No. 2178480, class ЕВВ 8/08), containing drainage trays open from above with transverse vertical dividing walls, separation walls made with rectangular fish-shaped openings located in the lower part thereof, equipped with protective canopies, along the perimeter of which inside the canopies jet forming nozzles are located.

In addition, the design of the fish passage proposed by A. Chistyakov is also close in terms of the technological scheme and the achieved result. (RF patent No. 2236501, cl. ЕВВ 8/08), including a fish passage connecting the lower and upper water bodies of the waterworks, made in the form of chambers interconnected by transverse partitions and placed in steps or in the form of a channel channel with a longitudinal slope towards the downstream the bottom swimming holes which are made in the transverse partitions, and the swimming holes on the upstream side are made with jet forming nozzles in communication with the source of the working medium and placed above and below the longitudinal axis of the swimming hole and the nozzles are oriented at an acute angle to the longitudinal axis of the inlet openings, and the nozzles are located between the shielding canopies located along the perimeter of the inlet opening above and below the installation plane of the jet forming nozzles in such a way that the nozzles are located inside the outlet part of the inlet opening formed by the visors and are parallel the plane of the adjacent shielding visor so that the jet forming nozzles are made around the perimeter of the inlet opening, with the exit The nozzle openings are located directly in the inlet openings between the planes of the lateral surfaces of the transverse partitions, and distributing manifolds are made inside the transverse partitions, the inlet openings may be square, rectangular or round, or the inlet openings in the transverse partition may be half-tucked, or the height of the inlet opening from the downstream side more than the same height from the upstream side, also the end sections of the pressure pipe adjacent to e to the nozzles, can be equipped with twisting devices that allow the hydraulic jets to be twisted clockwise, counterclockwise, towards each other or in various combinations; in addition, the transverse partition can be made with additional through holes communicating with the upper and lower level, while inside these holes coaxial with the formed autonomous channels placed jet forming nozzles.

The main common drawback of these designs of fish passageways is the coverage of a small part of the width of the watercourse to attract fish into the fish passage and the limited choice of the directions of movement of the formed attracting streams, and hence the low efficiency of passing the fish towards the upstream.

The aim of the invention is the creation of effective conditions for attracting fish with a greater width of the watercourse in the downstream of the waterworks, as well as the creation of conditions for choosing the directions and width of the attracting flows in the downstream of the waterworks before the fish passage.

The invention consists in the following.

According to claim 1 of the claims. The implementation of the input head of the fish passage (the entrance dividing wall of the fish passage) in the form of two mating rectangular faces with bottom fish passage (swimming) holes, which are a plan view along with the connection of the bottom of the input head of the fish passage with the bottom of the drainage channel of the fish passage tract, allows you to get a triangle in the bottom waterworks two directions of attracting flows, covering, compared with the prototype, a larger part of the watercourse before the fish passage. The installation of flow-guiding walls on the parts of the ribs formed by connecting rectangular faces between themselves and with the vertical walls of the drainage channel of the fish passage, will clearly distinguish the boundaries of the fish attracting stream.

According to claim 6 and 7 of the claims. Performing the same width of the rectangular faces of the inlet head of the fish passage with fish passage (swim) holes allows you to get the inlet head of the fish passage together with the connection of the bottom of the inlet head of the fish passage with the bottom of the spillway of the fish passage tract in plan view in the form of an equilateral or isosceles triangle in the lower one, which makes it possible there are two attracting flows (plume) of the same width at an acute angle to each other (the angle between the exit planes of the attracting flows en acute angle γ).

According to claim 8, 9 and 10 of the claims. Fulfillment of the rectangular faces of the input end of the fish passage with fish passage (vaping) openings of different widths makes it possible to obtain the input tip of the fish passage together with the connection of the bottom of the input passage of the fish passage with the bottom of the drainage channel of the fish passage tract in a plan view in the form of a rectangular, acute-angled or obtuse-angled triangle, which makes it possible to in the lower pool of the waterworks there are two attracting flows (plume) of different directions (with an acute angle γ between the exit planes of the attracting flows) different width of any one of two directions depending upon hydrology downstream hydroelectric and modes of operation.

According to claim 13 of the claims (2nd variant of the input tip of the fish passage). The implementation of the input head of the fish passage (input dividing wall of the fish passage) in the form of three mating rectangular faces with bottom fish passage (swimming) holes, which are a plan view together with the connection of the bottom of the entrance head of the fish passage with the bottom of the drainage channel of the fish passage tract, allows to obtain a convex quadrangle in the lower downstream of the waterworks, three directions of attracting streams, covering, in comparison with the prototype, an even larger part of the watercourse in front of the fish passage, including the frontal direction lniye and lateral approach ways. The installation of flow-guiding walls on the parts of the ribs formed by connecting rectangular faces between themselves and with the vertical walls of the drainage channel of the fish passage, will clearly distinguish the boundaries of the fish attracting stream.

According to p. 18 and 19 of the claims. Performing the same width of the rectangular faces of the inlet head of the fish passage with fish passage (swimming) holes allows to obtain the inlet head of the fish passage together with the connection of the bottom of the inlet head of the fish passage with the bottom of the drainage channel of the fish passage tract in plan view in the form of a square or rhombus, which makes it possible to form in the lower crib waterworks three attracting flows (plume) of the same width in all three directions with angles γ ₁ and γ ₂ between adjacent exit planes of the attracting flows.

According to claim 20, 21 and 22 of the claims. Fulfillment of the rectangular faces of the entrance end of the fish passage with fish passage (swimming) openings of different widths makes it possible to obtain the entrance tip of the fish passage together with the connection of the bottom of the entrance of the fish passage with the bottom of the drainage channel of the fish passage tract in a plan view in the form of a rectangle, parallelogram or trapezoid, which makes it possible to form the downstream side of the waterworks there are three attracting flows (plume) of different directions with angles γ ₁ and γ ₂ between adjacent exit planes of the attracting flows and different irins in any of three possible directions, depending on the hydrological features of the downstream of the waterworks and its operating modes.

According to claim 25 of the claims (3rd version of the input tip of the fish passage). The implementation of the input head of the fish passage (input dividing wall of the fish passage) in the form of five mating rectangular faces with bottom fish passage (swimming) holes, which are a plan view, together with the connection of the bottom of the input channel of the fish passage with the bottom of the drainage channel of the fish passage tract, allows to obtain a convex hexagon downstream of the waterworks there are five directions of attracting streams, embracing a watercourse in front of the entrance to the fish passage practically around the circumference with an attracting stream (plume). The installation of flow-guiding walls on the parts of the ribs formed by connecting rectangular faces between themselves and with the vertical walls of the drainage channel of the fish passage, will clearly distinguish the boundaries of the fish attracting stream.

According to claim 2, 14 and 26 of the claims. The implementation of the square fish-shaped (swimming) openings allows one to obtain several bottom openings on the rectangular face of the inlet head of the fish passage, increasing the number of fish movement paths moving towards the upstream.

According to claim 3, 15 and 27 of the claims. The implementation of round fish-shaped (inlet) holes allows you to get the same effect as in the case of paragraphs 2, 14 and 26, however, in this case, the velocity field over the area of the fish-through (inlet) hole will be more uniform.

According to claim 4, 16 and 28 of the claims. The implementation of the fish passage (vplivnyh) holes of a rectangular shape allows you to get fish passage holes over the entire width of the rectangular faces of the input head.

According to claim 5, 17 and 29 of the claims. The implementation of the fish passage (swimming) holes is tiered with the displacement of the holes of the upper tier with respect to the holes of the lower tier, which allows obtaining fish passage (swimming) holes for both bottom fish species and fish living at the surface of the watercourse.

According to claim 30. Performing the same width of the rectangular faces of the inlet head of the fish passage with fish passage (swimming) openings allows you to get the inlet head of the fish passage together with the connection of the bottom of the inlet head of the fish passage with the bottom of the drainage channel of the fish passage tract in plan view in the form of a regular hexagon, which makes it possible to form a hydrofoil in the lower bottom five attracting streams (loops) of the same width in all five directions with an angle γ between adjacent exit planes of the attracting streams.

According to clause 31 of the claims. The execution of the rectangular faces of the entrance of the fish passage with different widths with fish passage (swimming) openings allows you to get the input tip of the fish passage together with the connection of the bottom of the entrance of the fish passage with the bottom of the drainage channel of the fish passage tract in the plan view in the form of an irregular hexagon, which makes it possible to form a hydraulic reservoir in the lower tail attracting five streams (loops) of different directions and different widths according to any of the five possible directions with angles γ _1, γ _2, γ ₃ and γ ₄ between adjacent exit planes attracting flows depending on hydrology downstream hydroelectric and modes of operation.

According to claim 11, 23 and 32 of the claims. The execution of the flow-guiding walls with the possibility of rotation by means of self-contained drives relative to the vertical axes passing through the ribs formed by connecting rectangular faces to each other and with the vertical walls of the drainage channel of the fish passage tract allows changing the diagrams of velocities in the downstream side of the waterworks (when changing the discharge modes through the dam of the waterworks or when the water level in the lower pool changes), form attracting streams with optimal boundaries in front of the inlet head.

According to item 12, 24 and 33 of the claims. The implementation of the flow guide walls in two tiers with independent drives for each tier allows you to effectively manage the boundaries of the surface and bottom attracting flows.

The solution to this problem is achieved by creating a new design of the input head of the fish passage and its variants. Graphic material that explains the essence of the invention is presented in the following figures:

figure 1 is a General diagram of the fish passage with an input tip formed by two rectangular faces with bottom fish passage (vplyvny) holes of a rectangular shape, which is a plan view along with the connection of the bottom of the input tip of the fish passage with the bottom of the drainage channel of the fish passage tract, a triangle, and a method of obtaining attracting flows in two directions;

figure 2 is a General diagram of the fish passage with a variant of the input head (2nd option), formed by three rectangular faces with bottom fish passage (swimming) holes of a rectangular shape, which is a plan view along with the connection of the bottom of the input head of the fish passage with the bottom of the spillway of the fish passage the path is a convex quadrangle, and a method for producing attracting flows in three directions;

figure 3 is a General diagram of the fish passage with a variant of the input head (3rd option), formed by five rectangular faces with bottom fish passage (vplivny) holes of a rectangular shape, which is a plan view together with the connection of the bottom of the input head of the fish passage with the bottom of the spillway of the fish passage the path is a convex hexagon, and a method for producing attracting flows in five directions;

4 is a diagram of a fish passage with an inlet head according to the first embodiment in a plan view, the rectangular faces of the inlet head with the fish passage (inlet) openings have the same width and form, together with the connection of the bottom of the inlet head of the fish passage with the bottom of the spillway of the fish passage tract, an equilateral triangle when the width of the rectangular faces of the inlet head is equal to the width of the spillway of the fish passage tract;

figure 5 - the same form an isosceles triangle, the case when the width of the rectangular faces of the inlet head is not equal to the width of the spillway of the fish passage tract, an episode of increasing the width of the attracting streams in comparison with figure 4;

6 is a diagram of the fish passage with the inlet head according to the first embodiment in a plan view, the rectangular faces of the inlet head with the fish passage (inlet) openings have different widths and, together with the connection of the bottom of the inlet head of the fish passage with the bottom of the spillway of the fish passage tract, a rectangular triangle, version of the change directions of attracting flows in comparison with figure 5;

Fig.7 - the same, form an acute-angled triangle, a variation in the direction of attracting flows and their magnitude in comparison with figures 4 and 5;

Fig.8 - the same, form an obtuse triangle, a modification of the change in direction of attracting flows in comparison with Fig.4-7;

Fig.9 is a diagram of the fish passage with the inlet head according to the second embodiment in a plan view, the rectangular faces of the inlet head with the fish passage (inlet) openings form, together with the connection of the bottom of the inlet head of the fish passage with the bottom of the drainage channel of the fish passage tract;

figure 10 - diagram of the fish passage with the inlet head according to the second embodiment in a plan view, the rectangular faces of the inlet head with the fish passage (inlet) openings have the same width and together with the connection of the bottom of the inlet head of the fish passage with the bottom of the drainage channel of the fish passage tract, square;

11 - the same, form a rhombus, a version of the change in the directions of the attracting flows in comparison with figure 10;

12 is a diagram of a fish passage with an inlet head according to the second embodiment in a plan view, the rectangular faces of the inlet head with fish passage (inlet) openings have different widths and, together with the connection of the bottom of the inlet head of the fish passage with the bottom of the spillway of the fish passage tract, a rectangle, side reinforcement episode attracting streams in comparison with figure 10;

Fig.13 - the same, form a parallelogram, a modification of the change in direction of attracting flows in comparison with Fig.12;

Fig - the same, form a trapezoid, a variation in the direction of movement of the lateral attracting flows with a change in their magnitude, as well as the option of strengthening the front attracting flow without changing the direction of its movement compared to Fig;

Fig. 15 is a diagram of a fish passage with an inlet head according to the third embodiment in a plan view, the rectangular faces of the inlet head with the fish passage (inlet) openings have the same width and form a regular hexagon together with the bottom of the inlet head of the fish passage with the bottom of the spillway of the fish passage tract;

Fig. 16 is a diagram of a fish passage with an inlet head according to the third embodiment in a plan view, the rectangular faces of the inlet head with the fish passage (inlet) openings have different widths and together with the connection of the bottom of the inlet head of the fish passage with the bottom of the drainage channel of the fish passage tract, an irregular hexagon;

Fig. 17 is a general diagram of a fish passage with an inlet head formed by two rectangular faces with fish passage (inlet) openings of a square shape, which is a plan view along with the connection of the bottom of the inlet head of the fish passage with the bottom of the drainage channel of the fish passage tract;

Fig. 18 is the same, the fish passage (swimming) holes are made round;

Fig.19 is the same, fish passage (swimming) holes are made in tiers;

Fig. 20 is a general diagram of a fish passage with a variant of an inlet head (2nd variant) formed by three rectangular faces with square fish-shaped (inlet) openings, which is a plan view together with the connection of the bottom of the inlet head of the fish passage with the bottom of the drainage channel of the fish passage convex quadrangle;

Fig.21 is the same, fish passage (swimming) holes are made round;

Fig - the same, fish passage (swim) holes are made in tiers;

23 is a general diagram of a fish passage with an inlet head variant (3rd option) formed by five rectangular faces with square fish-shaped (inlet) openings, which is a plan view along with the connection of the bottom of the inlet head of the fish passage with the bottom of the drainage channel of the fish passage convex hexagon;

Fig - the same, fish passage (swim) holes are made round;

Fig - the same, fish passage (swimming) holes are made in tiers;

FIG. 26 is a view of a flow guide wall; FIG.

Fig.27 - the same, the walls of the upper and lower tiers are installed at different angles;

Fig. 28 is a diagram of a device of fish passage (vivid) openings in the input dividing wall of the fish passage (input head of the fish passage) and in the transverse (dividing) partitions in the section.

The fish passage (Figs. 1 - 25) is placed in the alignment of the dam 1 of the waterworks and is performed in the form of an open stepped, inclined or inclined-step overflow channel (fish passage path) 2 connecting the upper and lower downstream of the waterworks. Inside the spillway of the fish passage tract 2, vertical transverse (dividing) walls 3 are installed, dividing the total pressure of the hydraulic system into parts (1 ... 5 m) and forming the fish passage chambers. In the dividing walls 3, fish passage (swim) holes 4 are made. The inlet head of the fish passage (inlet separation wall of the fish passage) is made in the form of two (Fig. 1, 4-8, 17, 18) or three (Fig. 2, 9-14, 20 , 21), or five (Figs. 3, 15, 16, 23, 24) of mating rectangular faces 5 with bottom fish passage (swimming) holes 6, which are a plan view together with the connection of the bottom of the inlet head of the fish passage with the bottom of the spillway of the fish passage tract 7 triangle (Fig. 1, 4-8, 17-19) or a convex quadrangle (Fig. 2, 9-14, 20-22), or, respectively, you convex hexagon (figure 3, 15, 16, 23-25). On the part of the ribs (Fig.1-27), formed by connecting the rectangular faces 5 with each other and with the vertical walls of the spillway 2 of the fish passage tract, flow guide walls 8 are installed.

In addition, fish passage (swimming) holes 6 can be made square in shape (Fig.17, 20, 23).

In addition, fish passage (swimming) holes 6 can be made round (Fig. 18, 21, 24).

In addition, the fish passage (sinking) holes 6 can be made rectangular in shape (Fig.1-3).

In addition, the fish passage (swimming) holes 6 can be made in tiers (Figs. 19, 22, 25), while the holes of the upper tier are offset with respect to the holes of the lower tier.

In addition, the rectangular faces 5 of the inlet head of the fish passage with fish passage (inlet) openings 6 can be made of the same width with the formation in plan view along with the connection of the bottom of the inlet head of the fish passage with the bottom of the drainage channel of the fish passage 7, an equilateral triangle (Fig. 4) or, as options, an isosceles triangle (figure 5), a square (figure 10), a rhombus (figure 11), a regular hexagon (figure 15).

In addition, the rectangular faces 5 of the inlet head of the fish passage with fish passage (inlet) openings 6 can be made of different widths with the formation in plan view along with the connection of the bottom of the inlet head of the fish passage with the bottom of the drainage channel of the fish passage 7, a rectangular triangle (Fig.6) or, as options, an acute-angled triangle (Fig. 7), an obtuse-angled triangle (Fig. 8), a rectangle (Fig. 12), a parallelogram (Fig. 13), a trapezoid (Fig. 14), an irregular hexagon (Fig. 16).

In addition, the flow guide walls 8 can be mounted to rotate by means of autonomous drives (not shown) relative to the vertical axes 9 (Fig. 26) passing through the ribs formed by connecting the rectangular faces 5 with each other and with the vertical walls of the overflow channel 2 of the fish passage tract ( 1-25).

In addition, the flow guide wall 8 may consist of an upper 10 and a lower 11 tier, with each tier being provided with an autonomous drive (not shown) (Fig. 27).

The fish passage and the input head of the fish passage works as follows.

The working fluid (water) is supplied to the nozzles 12 from the pressure pipelines 13 (Fig. 28) from the pumps, which are located around the perimeters of the fish passage (inlet) holes 4 or 6. When water flows through these nozzles 12, rows of parallel hydraulic jets are formed, which, interacting among themselves, contribute to the formation of 4 or 6 zones of partially equal pressures (backpressure plots) in front of the fish passage (swimming) openings (4). Thanks to the creation of zones of partially equal pressure, they ensure an unhindered entry into the inlet head of the fish passage and the passage of fish producers through the fish passage from the lower pool of the hydraulic system to the upper pool. Stringing wall 8 (Fig.1-25) provides effective hydraulic conditions for attracting fish to the inlet head of the fish passage. Thanks to the installation of the flow guide walls 8 on the rotation axes 9 (Fig. 26), the fish-passage operation service has the ability to change the mode of attracting fish from the search zone of the downstream of the hydroelectric complex, taking into account the species composition of spawning fish and the regime of discharge of water flow through dam 1. External borders attracting fish flows are allocated by means of a drive of the guide walls 8 by installing them at a given angle in the direction of the attracting and transit flows. When changing the hydrological situation in the downstream, the angles of the installation of the guide walls 8 again change.

Due to the implementation of the fish passage (swimming) openings 6 in layers (Figs. 19, 22, 25), with the displacement of the openings of the upper tier relative to the openings of the lower tier, and the execution of the guide wall 8 also in the form of two tiers (Fig. 27) - the upper 10 and lower 11, expanding the ability to control the behavior of both bottom fish species and fish that live near the surface of the watercourse. To turn each tier 10 or 11, autonomous drives are used, setting them at predetermined angles and creating effective conditions for attracting bottom and surface fish species.

The fish passage in all three options allows you to create attractive flows in the downstream of the hydraulic system in several directions, covering a large area of the watercourse. Although the most preferred option for the input tip of the fish passage is the third variant of the tip (Figs. 3, 15, 16), which allows you to create five directions of attracting flows, covering the input part of the fish passage practically around the circumference.

The proposed entrance head of the fish passage for attracting and passing fish from the lower tail of the hydraulic system to the upper tail allows creating a controlled backpressure in front of the inlet (fish passage) openings of the fish passage and a uniform, adjustable, stable and powerful fish attracting stream, which maximally contributes to independent and free passage of fish from downstream of the waterworks to the upstream.

Claims (33)

1. The input tip of the fish passage, including the lower part of the fish passage, located in the lower pool, made in the form of a stepped or inclined tray - channel with a longitudinal slope towards the upper pool, containing a vertical separation wall - the input separation wall that forms the entrance chamber of the fish passage, with in it, fish passage openings along the entire width of the fish passage chambers of rectangular, square or round shape, along the perimeter of the holes there are jet-forming nozzles at an angle or parallel the axis of the holes, and equipped with a barrier visors in such a way that the nozzles are located inside the outlet portion of the inlet hole formed by the visors and are parallel to the plane of the adjacent shielding wall of the barrier peak, and the nozzle outlet openings can be located directly in the inlet holes between the planes of the lateral surfaces of the transverse separation walls or in autonomous channels, characterized in that the input tip of the fish passage is the input dividing wall The exit is made in the form of two mating rectangular faces with bottom fish passage - swimming holes and is a plan view along with the connection of the bottom of the input head of the fish passage with the bottom of the drainage channel of the fish passage tract, and on the part of the ribs formed by the connection of rectangular faces to each other and to vertical the walls of the spillway of the fish passage tract, establish flow guide walls. 2. The input tip of the fish passage according to claim 1, characterized in that the bottom fish passage - swimming holes are made square. 3. The input tip of the fish passage according to claim 1, characterized in that the bottom fish passage - swimming holes are made round. 4. The input tip of the fish passage according to claim 1, characterized in that the bottom fish passage - swimming holes are made in a rectangular shape. 5. The input tip of the fish passage according to claim 1, characterized in that the bottom fish passage - swimming holes are made in tiers, while the holes of the upper tier are offset with respect to the holes of the lower tier. 6. The inlet head of the fish passage according to claim 1, characterized in that the rectangular faces of the inlet head of the fish passage with bottom fish passage - inlet holes are made of the same width, forming an equilateral triangle in plan view together with the connection of the bottom of the inlet channel of the fish passage with the bottom of the drainage channel of the fish passage tract. 7. The inlet head of the fish passage according to claim 1, characterized in that the rectangular faces of the inlet head of the fish passage with bottom fish passage - inlet holes are made of equal width, forming an isosceles triangle in plan view together with the connection of the bottom of the inlet channel of the fish passage with the bottom of the spillway of the fish passage tract. 8. The inlet head of the fish passage according to claim 1, characterized in that the rectangular faces of the inlet head of the fish passage with bottom fish passage - inlet holes are made of different widths, forming in plan view, together with the connection of the bottom of the inlet head of the fish passage with the bottom of the drainage channel of the fish passage tract. 9. The inlet head of the fish passage according to claim 1, characterized in that the rectangular faces of the inlet head of the fish passage with bottom fish passage - inlet holes are made of different widths, forming in plan view, together with the connection of the bottom of the inlet head of the fish passage with the bottom of the drainage channel of the fish passage tract. 10. The inlet head of the fish passage according to claim 1, characterized in that the rectangular faces of the inlet head of the fish passage with bottom fish passage - inlet holes are made of different widths, forming an obtuse triangle in the plan view along with the connection of the bottom of the inlet channel of the fish passage with the bottom of the drainage channel of the fish passage tract. 11. The input tip of the fish passage according to claim 1, characterized in that the flow guide walls are mounted to rotate by means of self-contained drives relative to the vertical axes passing through the ribs formed by connecting rectangular faces to each other and with the vertical walls of the drainage channel of the fish passage tract. 12. The input tip of the fish passage according to claim 1, characterized in that the flow guide wall consists of upper and lower tiers, with each tier having an independent drive. 13. The input tip of the fish passage, including the lower part of the fish passage, located in the downstream, made in the form of a stepped or inclined tray - channel with a longitudinal slope towards the upper pool, containing a vertical separation wall - the input separation wall forming the entrance chamber of the fish passage, with in it, fish passage openings along the entire width of the fish passage chambers of rectangular, square or round shape, along the perimeter of the holes there are jet-forming nozzles at an angle or parallel to the axis of the hole, and equipped with a barrier visors in such a way that the nozzles are located inside the outlet portion of the inlet hole formed by the visors and are parallel to the plane of the adjacent shielding wall of the barrier peak, and the nozzle outlet openings can be located directly in the inlet holes between the planes of the lateral surfaces of the transverse separation walls or in autonomous channels, characterized in that the input tip of the fish passage is the input dividing wall the fish passage is made in the form of three mating rectangular faces with bottom fish passage - swimming holes and is a planar view along with the connection of the bottom of the entrance of the fish passage with the bottom of the spillway of the fish passage tract, and on the part of the ribs formed by the connection of rectangular faces to each other and to vertical walls of the spillway of the fish passage tract, establish flow guide walls. 14. The input tip of the fish passage according to item 13, characterized in that the bottom fish passage - swimming holes are made square. 15. The input tip of the fish passage according to item 13, wherein the bottom fish passage - swimming holes are made round. 16. The input tip of the fish passage according to item 13, characterized in that the bottom fish passage - swimming holes are made in a rectangular shape. 17. The input tip of the fish passage according to item 13, wherein the bottom fish passage - swimming holes are made in tiers, while the holes of the upper tier are offset with respect to the holes of the lower tier. 18. The inlet head of the fish passage according to claim 13, characterized in that the rectangular faces of the inlet head of the fish passage with bottom fish passage - inlet holes are made of equal width, forming a square in plan view together with the connection of the bottom of the inlet channel of the fish passage with the bottom of the drainage channel of the fish passage tract. 19. The inlet head of the fish passage according to claim 13, characterized in that the rectangular faces of the inlet head of the fish passage with bottom fish passage - inlet holes are made of the same width, forming a rhombus in the plan view together with the connection of the bottom of the inlet channel of the fish passage with the bottom of the spillway of the fish passage channel. 20. The inlet head of the fish passage according to claim 13, characterized in that the rectangular faces of the inlet head of the fish passage with bottom fish passage - inlet holes are made of different widths, forming a rectangle in plan view together with the connection of the bottom of the inlet channel of the fish passage with the bottom of the drainage channel of the fish passage tract. 21. The inlet head of the fish passage according to claim 13, characterized in that the rectangular faces of the inlet head of the fish passage with bottom fish passage - inlet holes are made of different widths, forming a parallelogram on the plan view together with the connection of the bottom of the inlet channel of the fish passage with the bottom of the drainage channel of the fish passage tract. 22. The inlet head of the fish passage according to claim 13, characterized in that the rectangular faces of the inlet head of the fish passage with bottom fish passage - inlet holes are made of different widths, forming a trapezoid on the plan view together with the connection of the bottom of the inlet channel of the fish passage with the bottom of the drainage channel of the fish passage tract. 23. The input tip of the fish passage according to claim 13, characterized in that the flow guide walls are mounted for rotation by means of autonomous drives relative to the vertical axes passing through the ribs formed by connecting rectangular faces between themselves and with the vertical walls of the drainage channel of the fish passage tract. 24. The input tip of the fish passage according to claim 13, characterized in that the flow guide wall consists of upper and lower tiers, with each tier having an independent drive. 25. The input tip of the fish passage, including the lower part of the fish passage, located in the lower pool, made in the form of a stepped or inclined tray - channel with a longitudinal slope towards the upper pool, containing a vertical separation wall - the input separation wall forming the entrance chamber of the fish passage, with in it, fish passage openings along the entire width of the fish passage chambers of rectangular, square or round shape, along the perimeter of the holes there are jet-forming nozzles at an angle or parallel to the axis of the holes, and equipped with a barrier visors in such a way that the nozzles are located inside the outlet portion of the inlet hole formed by the visors and are parallel to the plane of the adjacent shielding wall of the barrier peak, and the nozzle outlet openings can be located directly in the inlet holes between the planes of the lateral surfaces of the transverse dividing walls or in autonomous channels, characterized in that the input tip of the fish passage is the input dividing wall the fish passage is made in the form of five mating rectangular faces with bottom fish passage - swimming holes and is a plan view, together with the connection of the bottom of the entrance head of the fish passage with the bottom of the spillway of the fish passage tract, with a part of the ribs formed by connecting rectangular faces to each other and to vertical walls of the spillway of the fish passage tract, establish flow guide walls. 26. The input tip of the fish passage according to claim 25, characterized in that the bottom fish passage - the swimming holes are made in a square shape. 27. The input tip of the fish passage according to claim 25, characterized in that the bottom fish passage - the swimming holes are round. 28. The input head of the fish passage according to claim 25, characterized in that the bottom fish passage - swimming holes are made in a rectangular shape. 29. The input tip of the fish passage according to claim 25, characterized in that the bottom fish passage - swimming holes are made in belts, while the holes of the upper tier are offset with respect to the holes of the lower tier. 30. The input tip of the fish passage according to claim 25, characterized in that the rectangular faces of the input tip of the fish passage with bottom fish passage - inlet holes are made of the same width, forming a regular hexagon in the plan view together with the connection of the bottom of the input passage of the fish passage with the bottom of the drainage channel of the fish passage tract. 31. The inlet head of the fish passage according to claim 25, characterized in that the rectangular faces of the inlet head of the fish passage with bottom fish passage - inlet holes are made of different widths, forming an irregular hexagon in the plan view along with the connection of the bottom of the inlet channel of the fish passage with the bottom of the drainage channel of the fish passage path. 32. The input tip of the fish passage according to claim 25, wherein the flow guide walls are mounted to rotate by means of self-contained drives relative to the vertical axes passing through the ribs formed by connecting rectangular faces to each other and to the vertical walls of the drainage channel of the fish passage. 33. The input tip of the fish passage according to claim 25, characterized in that the flow guide wall consists of upper and lower tiers, with each tier having an independent drive.

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