RU2337209C1 - Fishway for attraction and passing fish from hydrosystem channel downstream to upstream - Google Patents

Abstract

FIELD: construction; mechanics.

SUBSTANCE: fishway is implemented as benched or slope conveyor or channel with longitudinal slope sideways downstream water, containing transverse vertical separation walls dividing fishway for chambers with located in them by full width of fishway chambers swimming in holes of rectangular, square or round. By holes perimeter are located stream-forming bleeds angularly or parallel to holes axes outfitted by obstructing screens so that bleeds are inside of formed by screens outlet part of swimming in hole and are located parallel to screening wall axes of adjoined obstructing screen. Outlet holes of bleeds are located directly inside of swimming in holes between surfaces of laterals and transverse separation walls or inside of autonomic channels. Inside of swimming in holes and obstructing screens there are mounted light sources directed into internal space of swimming in holes and obstructive screens. Light sources are located into niches on walls by full perimeter of swimming in holes and obstructive screens. There are presented versions of light sources location relative to each other.

EFFECT: increasing of efficiency for fish attraction into swimming in holes.

5 cl, 7 dwg

Description

The invention relates to hydraulic engineering, and in particular to methods and 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, CL ЕВВ 8/08, published. 1999.05.27, Bull. No. 15; Application No. 2006113903 dated April 24, 2006) and the design of a pump-ejector installation for transporting liquid from the first section to the second, higher section proposed by Vvedensky O.G. and Polyanin A.Ya. (RF patent No. 2178480, class ЕВВ 8/08, published. 2002.01.20, Bull. No. 2), containing drainage trays open from above with transverse vertical dividing walls, separation walls made with rectangular fish-shaped openings located in their lower part equipped with obstruction peaks, along the perimeter of which inside the obstruction peaks there are jet-forming nozzles.

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, published. 2004.09.20), including a fish passage connecting the lower and upper heads of the hydraulic system, made in the form of chambers connected by transverse partitions and placed in steps or in the form of a channel channel with longitudinal slope towards the downstream side, bottom inlet openings made in transverse partitions, and inlet openings from 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 inlet hole, while the nozzles are oriented at an acute angle to the longitudinal axis of the inlet openings, and the nozzles are located between the shielding visors placed along the perimeter of the inlet hole above and below the installation plane of the jet nozzles, so that the nozzles are inside the outlet formed by the visors of the inlet hole and are located parallel to the plane of the adjacent shielding visor, so that the jet forming nozzles are made along the entire perimeter of the float hole, with the outlet openings of the nozzles 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 in shape, or the inlet openings in the transverse partition may be half-way, or the inflow height the openings on the downstream side are larger than the same height on the upstream side, as well as the end sections of the pressure pipe, etc. adjacent 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 coaxially with the formed autonomous channels placed jet forming nozzles.

The main common drawback of these designs of fish passageways is a strong blackout from the barriers of the fish passage (swimming) holes and their outlet parts from the upstream side, which sharply reduces the efficiency of skipping the fish towards the upstream.

The aim of the invention is the creation of effective conditions for attracting fish to fish passage (swimming) holes.

The invention consists in the following.

According to claim 1 of the claims. The placement of light sources inside the fish passage (swimming) openings and the guard peaks directed into the internal space of the fish passage (swimming) holes and the guard peaks will allow the formation of light fields, both in the fish passage (swimming) hole and inside the guard peak. In this case, a known method of attracting fish to a light field is realized.

According to claim 2 of the claims. The installation of light sources on the walls around the entire perimeter of the fish passage (sinking) holes and obstacle visors makes it possible to obtain light fields of a given configuration. And the placement of light sources in special niches will eliminate unnecessary interference that interferes with the fish, the free passage of fish in the direction of the upper pool.

According to claim 3 of the claims. The arrangement of light sources symmetrical with respect to each other, installed inside the fish passage (swimming) openings and barriers, will simplify the management of light fields.

According to claim 4 and 5 of the claims. The placement of light sources installed inside the fish passage (swimming) holes, and light sources installed inside the barriers, in relation to each other is an option for the formation of light paths of various configurations.

The solution of this problem is achieved by creating a new design of the fish passage for attracting and passing fish from the lower pool of the hydraulic system to the upper pool. Graphic material explaining the essence of the invention is presented in the following drawings:

figure 1 - layout of the fish passage in the alignment of the waterworks;

figure 2 is a diagram of a cross section of the fish passage chamber with nozzles located parallel to the axis of the fish passage (inlet) hole;

figure 3 is a diagram of a cross-section of the fish passage chamber with nozzles located at an angle to the axis of the fish passage (inlet) hole;

figure 4 is a view from the side of the downstream on the inlet hole of a rectangular shape, the corresponding light sources installed inside the fish passage (inlet) holes, and the light sources installed inside the barrier visors lie in the same planes perpendicular to the dividing wall;

figure 5 is a view from the side of the downstream on the inlet openings of a square shape, the corresponding light sources installed inside the fish passage (inlet) openings, and the light sources installed inside the barriers, lie in different planes perpendicular to the dividing wall;

6 is a view from the side of the downstream on the round-shaped swimming openings, corresponding light sources installed inside the fish passage (swimming) openings, and the light sources installed inside the barriers, lie in the same planes perpendicular to the dividing wall;

7 is a view from the side of the downstream on the round-shaped swimming openings, the corresponding light sources installed inside the fish passage (swimming) openings, and the light sources installed inside the barriers, lie in different planes perpendicular to the dividing wall.

The fish passage (figure 1) is placed in the alignment of the dam 1 of the waterworks and is performed in the form of an open step, inclined or inclined-step overflow channel (fish passage path) 2, connecting the upper and lower downstream of the waterworks. Inside the spillway tray (fish passage path) 2, vertical separation walls 3 are installed (Figs. 1-3) forming the chambers of the fish passage 4. In the separation walls 3, fish pass (inlet) openings 5 of rectangular, square or round shape, equipped with protective canopies 6, formed shielding barrier walls installed around the entire perimeter of the passage (fish passage) holes 5 parallel to the axes of the distribution of jets. Also around the perimeters of the fish passage (inlet) holes 5 (FIGS. 2, 3), the jet-forming nozzles 7 are located inside the barrier visors in parallel (FIG. 2) or at an angle (FIG. 3) to the axis of the fish passage (inlet) hole 5. The jet-forming nozzles 7 are fed by supply pipelines 8 (figure 2, 3). Light sources 9 are installed inside the fish passage (swimming) openings 5 and the barriers 6 and directed to the internal space of the fish passage (swimming) holes 5 and the barriers 6, which illuminate the fish passage (swimming) holes 5 and their exit parts from the upstream side, thereby creating light paths through the fish passage (swimming) hole 5 and directing migrants directly through one fish passage (swimming) hole 5 to the other hole towards the upstream.

The placement of light sources 9 in special niches 10 (FIGS. 2, 3) makes it possible to eliminate mechanical and light (dazzle) interference that will interfere with the free passage of fish towards the upstream. In addition, the implementation of light sources 9 on the walls around the perimeter of the fish passage (swimming) holes 5 and the barriers 6 (Fig.4-7) allows you to obtain light fields of the necessary intensity and direction.

The location of the light sources (Figs. 4-7) installed inside the fish passage (inlet) openings 5 and the barriers 6, symmetrically relative to each other, will allow obtaining fields of various configurations, turning on or off the light sources 9 in various combinations.

The placement of the corresponding light sources 9 installed inside the fish passage (swimming) holes 5, and light sources 9 installed inside the barrier peaks 6, in the same planes perpendicular to the dividing wall 3 (Figs. 4, 6), will allow to obtain rectilinear light paths through the fish passage (swimming) hole 5 and the barrier peak 6. And the placement of the corresponding light sources 9 installed inside the fish passage (swimming) holes 5, and light sources 9 installed inside the barrier trump s, 6 in different planes perpendicular to the partition wall 3 makes it possible to receive the broken light path through the fish passage (vplyvnoe) opening 5 and the visor 6 barrage.

Fish passage works as follows.

The working fluid (water) is fed into the nozzle 7 from the supply nozzle of the piping 8 (figure 2, 3). When water flows through these nozzles 8, rows of parallel hydraulic jets are formed, which, interacting with each other, contribute to the formation of zones of partially equal pressures (backpressure plots) in front of the fish passage (swimming) holes 5 from the upstream side of the pool. Thanks to the creation of zones of partially equal pressures, the fish producers can freely pass through the fish passage from the lower tail of the hydraulic system to the upper tail, and the presence of light sources 9 eliminates the obscuration from the barriers 6 of the fish passage (inlet) holes 5 and their outlet parts from the upper pool and, finally, In the long run, it increases the efficiency of attracting fish to a fish passage.

Controlling the operation of light sources 9 (turning on / off) light sources 9 in various combinations: towards each other, with a shift (in a checkerboard pattern), only from above (above) the fish passage 5 and the protecting peak 6, only from the bottom (lower) the fish passage 5 and the barrier peak 6, only on the sides of the fish passage hole 5 and the barrier peak 6 or in various variants of the methods listed above), fields of varying intensity, directivity and a certain gradient are obtained. The type of light field is selected based on weather conditions, time of day, and the type of fish passed through the fish passage.

The advantages of the technical solution of the fish passage are the options for the placement of light sources 9 installed inside the fish passage (swimming) holes 5, and light sources 9 installed inside the barrier peaks 6 in relation to each other, as well as options for the operation of light sources 9 that allow you to control the configurations of light tracks. By changing the lighting combinations of the inside of the fish passage (swimming) openings 5 and the protective peaks 6 and using light sources located above the fish passage chambers and directed to the water surface (not shown in the figures), it is possible to form the routes of migrants along the fish passage according to the type of natural ones.

The proposed fish passage for attracting and passing fish from the lower pool of the hydraulic system to the upper pool allows you to create a controlled backpressure in front of the swim (fish passage) holes of the fish passage and form light fields in the fish passage (swim) holes, as well as inside the barriers, which maximally contributes to independent and free the passage of fish from the lower pool of the hydraulic system to the upper pool.

Claims (5)

1. A fish passage for attracting and passing fish from the lower pool of the hydraulic system to the upper pool, made in the form of a stepped or inclined tray or channel with a longitudinal slope towards the lower pool, containing transverse vertical dividing walls that divide the fish passage into chambers, with the entire width of the fish passage chambers with rectangular, square or round swimming inlets, while along the perimeter of the holes there are jet-forming nozzles at an angle or parallel to the axis of the holes equipped with barriers in such a way that the nozzles are located inside the outlet portion of the inlet opening formed by the visors and are parallel to the plane of the shielding wall of the adjacent barrier visor, and the nozzle outlet openings are 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 light sources directed into the interior are installed inside the swim-in openings and the protective canopies its space of swim-in openings and barrage visors. 2. The fish passage according to claim 1, characterized in that the light sources are located in niches on the walls around the perimeter of the float holes and the barriers. 3. The fish passage according to claim 1, characterized in that the light sources installed inside the inlet openings and the barriers are arranged symmetrically with respect to each other. 4. The fish passage according to claim 1, characterized in that the corresponding light sources installed inside the inlet openings and the light sources installed inside the barriers are in the same planes perpendicular to the dividing wall. 5. The fish passage according to claim 1, characterized in that the corresponding light sources installed inside the inlet openings and the light sources installed inside the barrier visors lie in different planes perpendicular to the dividing wall.

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