RU2245425C1 - Fish pass - Google Patents

Abstract

FIELD: hydraulic engineering.

SUBSTANCE: invention relates to fish pass facilities designed for passing fish spawners through retaining facilities to places of spawning and fattening. Proposed fish pass contains fish conduit connecting lower and upper ponds of hydraulic works made in form of overfall fish through, chambers arranged over length to fish conduit and divided by cross partitions with swim-in holes. Partitions are submerged, and bottom of chambers is made with slope to side of upper pond cross partitions are formed by lower end face part of chamber bottom. Swim-in holes form longitudinal channels made in bottom of chambers and they communicate bottom of above chamber with below chamber of fish pass. Bottom of each chamber can be provided with water inlet hole form side of upper pond overlapped by fish grid and communicating with bottom undersluice whose outlet hole is found before inlet first chamber of fish pass and is overlapped by guide grate.

EFFECT: provision of effective passing of fish along fish conduit.

10 cl, 13 dwg

Description

The invention relates to hydraulic engineering, and in particular to methods and structures intended for passing fish producers through retaining structures to spawning and feeding grounds.

Known fish passage for the passage of fish from the lower tail of the hydraulic system to the upper [1], including the fish passage, made in the form of a tray with a stepped bottom, distributing a collector and water outlet slots located across the tray, at the end of each stage.

The disadvantage of this fish passage is the low efficiency of skipping fish towards the upstream.

Known fish passage [2], including a fish passage, made in the form of a tray with a stepped bottom, a power supply, holes in the bottom of each chamber of the fish passage and a means for transferring fish to the overlying chamber.

The disadvantage of this fish passage is the low efficiency of skipping fish in the direction of the upper pool, the complexity of its design, as well as the high probability of injury to fish by electric shock.

The closest in technical essence and the achieved result is a fish passage [3], which includes a fish passage, connecting the lower and upper water bodies of the waterworks, made in the form of a ladder tray, cameras located along the length of the fish passage and separated by transverse partitions with swimming holes.

The disadvantage of this device is the low efficiency of passing fish along the fish passage.

The aim of the invention is the creation of effective conditions for the passage of fish along the fish passage.

The invention consists in the following.

According to claim 1 of the claims. The implementation of the flooded partitions allows you to create uniform filtering across the width of the fish passage channel tray. Performing the bottom of the chamber with a slope towards the upstream gives the opportunity to form a fish passage chamber, and the speed mode along the length of the chamber is formed uneven - with a decrease in average speed, vertically, towards the upstream. This circumstance makes it possible for fish passing into the overlying chamber of the fish passage to adapt to the hydraulics of this chamber, restore their energy capabilities and subsequently select the most suitable speed conditions in one of the inlet openings formed in the end part of the chamber. The arrangement of the inlet openings in combination with the longitudinal channels makes it possible to form high-speed channels connecting the underlying chamber to the overlying fish passage chamber. At the same time, the fish, without changing its migration horizon, has the ability to freely overcome the design pressure and fall into the upper chamber of the fish passage.

According to claim 2 of the claims. The execution of longitudinal channels with a different slope towards the headstream allows the formation of high-speed autonomous channels characterized by different values of the average flow velocity, which makes it possible for fish with different indicators of swimming ability to effectively pass along the fish passage in the direction of the upper head.

According to claim 3 of the claims. The implementation of part of the longitudinal channels with a longitudinal slope towards the downstream allows the formation of high-speed sections with maximum flow rates for strong swimmers.

According to claim 4 of the claims. The implementation of the fish passage chamber with a water inlet and its connection with the bottom outlet gallery allows you to select the estimated part of the water flow from the chamber. This allows you to stabilize the hydraulic mode inside the fish passage tract (the average speed over the live section, water flow and water level indicators in the fish passage chambers). In this case, equivalent conditions are created in each chamber of the fish passage, allowing the fish to effectively move towards the upstream.

According to claim 5, the claims. The execution of the outlet of the outlet gallery in front of the entrance to the first chamber of the fish passage allows you to form an additional power supply and, accordingly, enhance the action that attracts fish "loop" speeds. Overlapping the outlet with a guiding grid does not allow the fish to penetrate into the outlet gallery, but directs it towards the entrance to the fish passage.

According to claim 6, claims. The installation of the guide lattice at an angle to the lower pool allows you to create a directional movement of fish in the first chamber of the fish passage.

According to claim 7 of the claims. The implementation of the elements of enhanced roughness along the length of the longitudinal channels allows you to effectively extinguish the excess kinetic energy of the stream.

According to claim 8 of the claims. The installation of reinforced roughness elements along the entire width of the longitudinal channels contributes to the effective quenching of the kinetic energy of the flow in its bottom region.

According to claim 9, the claims. The implementation of the elements of enhanced roughness at the bottom of the chambers of the fish passage, free from longitudinal channels, can increase the quenching of the excess kinetic energy of the stream flowing along the channel of the fish passage.

According to claim 10 of the claims. The implementation of the elements of enhanced roughness in a checkerboard pattern allows you to more evenly extinguish the excess kinetic energy of the flow in the bottom region of the fish passage path.

The solution to this problem is achieved by creating a new design of the fish passage for the passage of fish from one head of the hydraulic system to another. Graphic material that explains the essence of the invention is presented in the following figures:

figure 1 - fish passage, a longitudinal section;

figure 2 is a cross section aa in figure 1, a view of the float holes;

figure 3 is the same, embodiments of the inlet openings;

figure 4 is the same, embodiments of the inlet openings;

figure 5 - camera fish passage, isometry;

6 is a fish passage, a longitudinal section, a variant with a bypass gallery;

Fig.7 is a section bB in Fig.6;

Fig.8 is a section bb in Fig.6;

Fig.9 is a fragment of a longitudinal section along the fish passage, a variant with reinforced roughness elements installed at the bottom of the longitudinal channels;

figure 10 - the same elements of enhanced roughness installed on the bottom of the fish passage chamber;

11 is a fragment of the fish passage chamber, a variant of the combined installation of reinforced roughness elements installed at the bottom of the longitudinal channels and at the bottom of the fish passage chamber;

Fig - fish pass, plan, elements of enhanced roughness installed on the bottom of the camera fish pass and at the bottom of the longitudinal channels;

Fig - the same option with water inlets.

The fish passage includes a fish passage tract 1, connecting the lower 2 and upper 3 of the head of the hydraulic system, made in the form of a ladder tray, chambers 4, placed along the length of the fish passage tract 1 and separated by transverse partitions 5 having float holes 6. The partitions 5 are flooded, the bottom of the chambers 4 is made with a slope towards the upper pool 3, and the transverse partitions 5 are formed by the lower end part 7 of the bottom of the chamber 4, while the inlet holes 6 form longitudinal channels 8, made in the bottom of the chambers 4 and inform the bottom of the above chamber 4 with the downstream camera 4 of the fish passage.

In addition, the longitudinal channels 8 may have a different slope.

In addition, the longitudinal channels 8 can be made with a bias towards the lower 2 downstream.

In addition, the bottom of each chamber 4 can be equipped with a water intake hole 9, located on the side of the upper 3 downstream, while it is blocked by a fish grille 10 and communicates with the bottom outlet gallery 11.

In addition, the outlet 12 of the outlet gallery 11 can be made in front of the entrance to the first chamber 4 of the fish passage and is blocked by a guide grid.

In addition, the guide grill can be made with a bias towards the bottom 2 downstream.

In addition, along the length of the longitudinal channels 8, elements of reinforced roughness 13 can be installed at their bottom.

In addition, the elements of reinforced roughness 13 may have a width equal to the width of the longitudinal channels 8.

In addition, at the bottom of the chambers 4, free from the longitudinal channels 8, elements of enhanced roughness 13 can be made.

In addition, reinforced roughness elements 13 can be staggered.

Fish passage works as follows.

To attract fish into the fish passage, the operation service, through the shutter of the power unit (not shown), supplies the estimated water flow, thereby forming a hydraulic mode along the entire length of the fish passage tract 1. At the same time, normal hydraulic conditions for the passage of fish are created inside the path 1 (Fig. 1) by the formation of fish movement paths relative to the swimming holes 6, made in the lower end parts 7 of the transverse partitions 5. At the same time, from the bottom 2 of the downstream side, the calculated water flow rate forms a fish-attracting “loop” speed her, focusing on which, the fish enters the fish passage tract 1. To improve the hydraulic conditions inside the fish passage tract 1, a variant of the fish passage equipped with water inlets 9, made in the bottom of the fish passage chambers 4, from the upstream side 3 is possible (Fig. 6), which allows you to stabilize the flow of water passing through the fish passage path 1 and, accordingly, to form equivalent conditions along its length for the fish to move towards the upper 3 reach. At the same time, the organization of discharge of excess flow into the entrance of the fish passage in front of the first chamber 4 allows you to create effective conditions for attracting fish into the fish passage 1, increasing the speed-attracting fish loop.

To improve the passage of fish from one chamber of the fish passage to another chamber, as well as to quench the excess kinetic energy of the stream, reinforced roughness elements 13 can be installed at the bottom of the longitudinal channels 8 (Fig. 9). Elements of enhanced roughness 13 can also be installed on the bottom of the fish passage chambers 4, the surface of which is free from longitudinal channels 8 (Fig. 10). A variant of the combined use of reinforced roughness elements 13 (for example, Fig. 11) is possible, which improves the efficiency of quenching the kinetic energy of the flow in the bottom part of the chambers 4 of the fish passage tract 1. The layout of the reinforced roughness elements 13, in terms of, may be different, including placed in a checkerboard pattern (Fig.12 and 13).

The proposed fish passage allows you to create effective hydraulic conditions in the fish passage path for promoting fish in the upper pool by changing both the layout and configuration of the swimming holes working in conjunction with the longitudinal channels. In addition, its design allows you to effectively extinguish the excess kinetic energy of the stream passing through the fish passage.

Sources of information

1. A.S. USSR No. 293918 (USSR). IPC E 02 B 8/08 "Fish passage". Author: P.P. Bykov. Publ. 03.24.1971. BI No. 6.

2. A.S. USSR No. 1060750 (USSR). IPC E 02 B 8/08 "Fish passage". Authors: A.F. Avdonkin and I.M. Shatalov. Publ. 12/15/1983. BI No. 46.

3. Malevanchik B.S., Nikonorov I.V. Fish passage and fish protection facilities. - M.: Light and food industry, 1984. - p. 10, Fig. 1 c.

Claims (10)

1. A fish passage, including a fish passage, connecting the lower and upper water system head-ends, made in the form of a ladder tray, cameras located along the length of the fish passage and divided by transverse partitions having inlet openings, characterized in that the partitions are flooded, the bottom of the chambers is made with a slope towards the upstream, and the transverse partitions are formed by the lower end part of the bottom of the chamber, while the inlet holes form longitudinal channels made in the bottom of the chambers and inform the bottom of the upstream chambers with a downstream fish passage chamber. 2. The fish passage under item 1, characterized in that the longitudinal channels have different slopes. 3. Fish passage according to claim 2, characterized in that the longitudinal channels are made with a bias towards the downstream. 4. Fish passage according to any one of paragraphs. 1 - 3, characterized in that the bottom of each chamber is equipped with a water intake hole located on the upstream side, while it is covered by a fish grille and communicated with the bottom bypass gallery. 5. Fish passage according to claim 4, characterized in that the outlet of the outlet gallery is made in front of the entrance to the first chamber of the fish passage and is blocked by a guide grid. 6. Fish passage according to claim 5, characterized in that the guide grill is made with a bias towards the downstream. 7. The fish passage according to claim 1, characterized in that elements of enhanced roughness are installed along the length of the longitudinal channels at their bottom. 8. The fish passage according to claim 7, characterized in that the elements of enhanced roughness have a width equal to the width of the longitudinal channels. 9. Fish passage according to any one of paragraphs. 1 to 8, characterized in that at the bottom of the chambers, free from longitudinal channels, elements of enhanced roughness are made. 10. Fish passage according to claim 9, characterized in that the elements of enhanced roughness are staggered.

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