RU2326207C1 - Fish-way - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention refers to the sphere of hydraulic engineering immediately dealing with arrangement of fish-passing facilities intended to provide for passage of brood fishes over retaining structures to feeding and spawning grounds. The fish-way consists of a fish duct connecting the upstream and the downstream walls of the hydro-engineering structure, vertical enhanced roughness elements of flowing shape fixed to the fish duct bottom and arranged in transverse rows. The enhanced roughness elements are arranged chequerwise and form amenities for the fish located immediately behind them, with the bulging side of them oriented upstream. The sprawning understratum is a deposition of gravel and pebbles arranged along the fish duct bottom. The vertical slotted orifices are arranged regularly in the intervals between the enhanced roughness elements. The enhanced roughness elements of the even-numbered transverse rows are submerged, being lower as compared to similar elements of the uneven-numbered rows. The vertical enhanced roughness elements have niches in their concave surface sides.

EFFECT: making the fish duct conditions convenient for passage of fish.

4 cl, 11 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.

Known fish passage [1], including a fish passage, connecting the lower and upper pools of the hydraulic system, vertical elements of enhanced roughness, installed at the bottom of the fish passage and placed in transverse rows, made streamlined in plan.

The disadvantage of the structure is the low efficiency.

Known fish passage [2], including a fish passage, connecting the lower and upper pools of the hydraulic system, elements of enhanced roughness, installed at the bottom of the fish passage and placed in transverse rows with the formation of areas for fish relaxation.

The disadvantage of the structure is the low efficiency.

Known fish passage [3], including a fish passage, connecting the lower and upper pools of the hydraulic system, elements of enhanced roughness, installed on the bottom of the fish passage and placed in transverse rows with the formation of areas for fish relaxation.

The disadvantage of the structure is the low efficiency.

Known fish passage [4], including a fish passage, connecting the lower and upper ponds of the waterworks, reinforced roughness elements installed on the bottom of the fish passage and placed in transverse rows, staggered and made streamlined, with the convex surface of the reinforced roughness facing towards the flow .

The disadvantage of the structure is the low efficiency.

Known fish passage [5], including a fish passage, connecting the lower and upper pools of the hydraulic system, vertical elements of enhanced roughness, installed at the bottom of the fish passage and placed in transverse rows, made streamlined in plan.

The disadvantage of the structure is the low efficiency.

Known fish passage [6], including a fish passage, connecting the lower and upper heads of the hydraulic system, vertical elements of enhanced roughness, mounted on the bottom of the fish passage, placed in transverse rows and made streamlined in plan, while the height of the elements of enhanced roughness in the transverse rows is different.

The disadvantage of the structure is the low efficiency.

Known fish passage [7], including a fish passage, connecting the lower and upper pools of the waterworks, elements of enhanced roughness, installed at the bottom and depth of the fish passage and placed in transverse rows with the formation of areas for rest of fish, while the elements of enhanced roughness are made streamlined in plan .

The disadvantage of the structure is the low efficiency.

Known fish passage [8], including a fish passage, connecting the lower and upper pools of the waterworks, vertical elements of enhanced roughness, installed on the bottom of the fish passage and placed in transverse rows, made streamlined in plan, recreation areas for fish.

The disadvantage of the structure is the low efficiency.

Known fish passage [9], including a fish passage, connecting the lower and upper heads of the waterworks, vertical elements of enhanced roughness, mounted on the bottom of the fish passage and placed in transverse rows, made streamlined in plan, while the elements of enhanced roughness are placed in a checkerboard pattern and form zones recreation for fish formed directly behind them, with the elements of enhanced roughness with a convex surface facing the flow, spawning substrate in the form of gravel-pebble Tsypki laid on the bottom of the fish passage tract, drive for installing vertical elements.

The disadvantage of the structure is the complexity of the design and low efficiency.

The closest in technical essence and the achieved result is the exit tip of the fish passage [10], which includes the fish passage, connecting the lower and upper water bodies of the hydraulic system, vertical elements of enhanced roughness, stationary mounted on the bottom of the fish passage, and placed in transverse rows, streamlined in plan, with this reinforced roughness elements are placed in a checkerboard pattern and form rest areas for fish formed directly behind them, and the enhanced roughness elements a convex surface facing the flow, spawning substrate in the form of gravel and pebble gravel laid at the bottom of the fish passage, vertical swimming holes formed in the gaps between the elements of enhanced roughness.

The disadvantage of this structure is the low efficiency.

The aim of the invention is to create effective conditions for the passage of fish.

The invention consists in the following.

According to claim 1 of the claims. The implementation of the elements of enhanced roughness in even transverse rows flooded and with a height less than the height of similar elements located in odd rows, allows you to adjust the hydraulic flow resistance along the width and length of the fish passage tract. In this case, both the planned and the vertical velocity diagrams are reorganized.

The implementation of the vertical elements of enhanced roughness with a niche formed on the side of their concave surface, simplifies their design and improves the conditions for the formation of a recreation area for fish.

According to claim 2 of the claims. The option, when the cone angle of the elements of enhanced roughness decreases in the direction of flow in the fish passage, allows you to create a longitudinal velocity gradient along the length of the fish passage. With a decrease in the taper angle of the elements of enhanced roughness, the width of the inlet openings increases, the hydraulic resistance to the flow decreases, the local water level backwater decreases, etc. All this allows the formation of hydraulic conditions for fish entering the fish passage, characterized by a gradual increase in the average flow rate in the direction of the outlet head.

According to claim 3 of the claims. The option when the fish passage is made with sections within which, from their beginning to their end, the taper angle of the elements of enhanced roughness decreases in the direction of the flow stream, while the sections are successively alternating one after another, is a variant of the arrangement of the fish passage.

According to claim 4 of the claims. The option when the fish passage is made with sections within which, from their beginning to their end, the taper angle of the elements of enhanced roughness increases in the direction of the flow stream, while the sections are successively alternating one after another, is a variant of the layout of the fish passage.

The solution to this problem is achieved by creating a new design of the fish passage.

Graphic material explaining the essence of the invention is presented in the following drawings:

figure 1 - fish passage tract, plan;

figure 2 is the same, the structure of the planned plot of speeds;

figure 3 is a diagram of the flow around an element of reinforced roughness, plan;

figure 4 is a transverse section of the fish passage tract;

5 is the same, a variant with a rectangular shape of the tray;

6 is a longitudinal section of the fish passage tract;

Fig.7 is a fish passage tract, isometry;

Fig is a variant of the layout of the elements of enhanced roughness, isometry;

Fig.9 is a variant of the layout of the elements of enhanced roughness, isometry;

figure 10 - the fish passage is made with sections within which, from their beginning to their end, the taper angle of the elements of enhanced roughness decreases in the direction of flow, while the sections are sequentially alternated one after another;

11 - fish passage is made with sections within which, from their beginning to their end, the angle of conicity of the elements of enhanced roughness increases in the direction of flow, while the sections are sequentially alternated one after another.

The fish passage includes a fish passage path 1, connecting the lower and upper heads of the waterworks, vertical elements of reinforced roughness 2, stationary mounted on the bottom of the fish passage tract 1 and placed in transverse rows, made streamlined in plan, while the elements of enhanced roughness 2 are placed in a checkerboard pattern and form zones rest 3 for fish formed directly behind them, with the elements of enhanced roughness 2 with a convex surface facing the flow, spawning substrate 4 in the form of gravel-pebble new filling laid at the bottom of the fish passage tract 1, vertical inlet holes 5 formed in the gaps between the elements of enhanced roughness 2.

Elements of reinforced roughness 2 in even transverse rows are made flooded and with a height less than the height of similar elements 2 located in odd rows, while vertical elements of reinforced roughness 2 are made with a niche 6 formed from the side of their concave surface.

In addition, the taper angle of the elements of enhanced roughness 2 may decrease in the direction of flow in the fish passage 1.

In addition, the fish passage can be made with sections within which, from their beginning to their end, the taper angle of the elements of reinforced roughness 2 decreases in the direction of flow, while the sections are sequentially alternated one after another.

In addition, the fish passage can be performed with sections within which, from their beginning to their end, the angle of conicity of the elements of enhanced roughness 2 increases in the direction of flow, while the sections are sequentially alternated one after another.

Fish passage works as follows.

When the working flow is fed into the fish passage, migrants are allowed to pass through the spillway dam. The fish attracted from the lower pool enters the inlet head and gradually moves along the fish passage path 1 in the direction of the upper pool and the outlet head. During its advancement, the fish enters the zones characterized by different values of velocities and structure of the currents (Fig. 2), which are formed behind the vertical elements of enhanced roughness 2 and, overcoming the swimming openings 5, pass in the direction of the output head. Formed along the width of the fish passage tract 1, a multi-gradient planned velocity diagram allows the fish to select the optimal displacement paths within the fish passage. For the rest of the fish there are zones 3 formed directly behind the concave surface of the elements of reinforced roughness 2 (Fig. 3). At the same time, the fish has the opportunity to spawn on the substrate 4, made in the form of gravel and pebble bedding, laid on the bottom of the fish passage tract 1 (Fig.4-6).

It is possible that the taper angle of the elements of enhanced roughness 2 decreases in the direction of flow in the fish passage 1. This allows you to create a longitudinal velocity gradient along the length of the fish passage. With a decrease in the taper angle of the elements of enhanced roughness 2, the width of the inlet openings 5 increases, the hydraulic resistance to the flow decreases, the local water level backwater decreases, etc. All this allows the formation of hydraulic conditions for fish entering the fish passage, characterized by a gradual increase in the average flow rate (in the inlet openings 5) in the direction of the outlet head.

It is possible that the fish passage path 1 is made with sections within which, from their beginning to their end, the taper angle of the elements of enhanced roughness 2 decreases in the direction of flow (Fig. 10), while the sections are sequentially alternated one after another, which is layout option of the fish passage tract 1. This arrangement allows more rational use of the fish’s energy potential and optimizes the mode of its movement along the fish passage. Moving within each area, the fish is affected by a longitudinal gradient of the average flow velocity, which increases towards the upstream.

It is possible that the fish passage path 1 is made with sections within which, from their beginning to their end, the taper angle of the elements of reinforced roughness 2 increases in the direction of flow (Fig. 11), while the sections are sequentially alternated one after another, which is layout option of the fish passage tract 1. This arrangement also makes it possible to more rationally use the energy potential of the fish and optimize the mode of its movement along the fish passage. Moving within each section, the fish experiences the influence of a longitudinal gradient of the average flow velocity, which decreases towards the upstream, which makes it possible for the fish to rest and restore its physiological state.

The proposed fish passage allows to improve the conditions for the passage of fish in the upper pool.

Information sources

1. Japan Patent (JP) No. 09-132909, "Fish ladder", IPC E02B 8/08. Mizuyama Takahisa, Onoda Tadahiro. 1997, May 20.

2. Patent WO No. 2004/083530, "Fish-passing facility", IPC E02B 8/08. Gorodetskyi Emelyan, 2004, September 30.

3. Patent of Ukraine (UA) No. 62419, "Fish passage construction", IPC Е02В 8/08, ET Gorodetsky, Publ. B.I. No. 12, 12-15-2003.

4. Australian Patent (AU) No. 200400473, "Baffle for assisting the upstream passage of aquatic fauna", IPC E02B 8/08, A01K 29/00. Davies Peter E, 2004, August 26.

5. RF patent (RU) No. 22545424, "Fish passage", IPC E02B 8/08, Chistyakov A.A., Bull. No. 3, 2005-01-27.

6. RF patent (RU) No. 2263743, "Fish passage channel (options)", IPC E02B 8/08, Chistyakov A.A, Shkura V.N., Bull. No. 31, 2005-11-10.

7. RF patent (RU) No. 2260651, "Fish-pass", IPC E02В 8/08, Chistyakov A.A., Shkura V.N., Chemikosova E.A. Bull. No. 26, 2005-09-20.

8. Patent of the Russian Federation (RU) No. 20133492, "Fish-pass", IPC EV 02/08, Filippov G.G., 1994-05-30.

9. RF patent (RU) No. 2233940, "Fish-breeding and spawning canal", IPC EV 02/08, Chistyakov A.A., Shkura V.N., Anokhin AM, Chistyakov A.A., Chemikosova E.A., 2004-08-10.

10. Chistyakov A.A. Designs of fish passage and fish passage and spawning channels. / Tutorial. NGMA. - Novocherkassk, 2004 .-- 150 p., Pp. 100-101, Fig. 4.38.

Claims (4)

1. A fish passage, including a fish passage, connecting the lower and upper heads of the waterworks, vertical elements of enhanced roughness, stationary mounted on the bottom of the fish passage, placed in transverse rows and made streamlined in plan, while the elements of enhanced roughness are placed in a checkerboard pattern and form rest areas for fish, formed directly behind them, with the elements of enhanced roughness with a convex surface facing the flow, spawning substrate in the form of gravel-pebble the first filling laid at the bottom of the fish passage tract, vertical swimming holes formed in the gaps between the elements of reinforced roughness, characterized in that the elements of enhanced roughness in even transverse rows are made flooded and with a height less than the height of similar elements located in odd rows, while vertical elements of enhanced roughness are made with a niche formed on the side of their concave surface. 2. The fish passage according to claim 1, characterized in that the taper angle of the elements of enhanced roughness decreases in the direction of flow in the fish passage. 3. The fish passage according to claim 1, characterized in that it is made with sections within which, from their beginning to their end, the cone angle of the elements of enhanced roughness decreases in the direction of flow, while the sections are sequentially alternated one after another. 4. The fish passage according to claim 1, characterized in that it is made with sections within which, from their beginning to their end, the angle of conicity of the elements of enhanced roughness increases in the direction of flow, while the sections are sequentially alternated one after another.

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