RU2310719C1 - Fish pass - Google Patents

Abstract

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

SUBSTANCE: fish pass comprises waterway made as gutter with head connected to upper pool of hydrosystem and mouth communicated with lower pool thereof. Fish pass also has roughness members distributed along waterway length and through zigzag channel extending along waterway length. Through zigzag channel bottom mark is below than that of waterway. Through zigzag channel extends along sinusoid curve having constant amplitude. Roughness members are connected to waterway bottom in areas adjoining through zigzag channel from both sides thereof. Roughness members are of different size and shape.

EFFECT: possibility to create hydraulic conditions, which facilitate fish movement along fish pass.

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.

A known channel [1], including a water supply path made in the form of a tray, elements of enhanced roughness located along the length of the water supply path, a flowing zigzag channel made along the length of the water supply path.

The disadvantage of this structure is the low efficiency of quenching the flow energy.

A known channel [2], including a water supply path made in the form of a tray, elements of enhanced roughness located along the length of the water supply path and adjacent to its sides, a flowing zigzag channel made along the length of the water supply path.

The disadvantage of this structure is the low efficiency of quenching the flow energy.

Known fish passage channel [2], including a water path made in the form of a tray, elements of enhanced roughness located along the length of the water path and adjacent to its sides, a flowing zigzag channel made along the length of the water path.

The disadvantage of this structure is the low efficiency of quenching the flow energy.

The closest in technical essence and the achieved result is a waterworks [3], including a water supply path made in the form of a tray, the head part of which is connected to the upper water head of the water system, and the wellhead part - to the lower water head, reinforced roughness elements located along the length of the water supply path, a flowing zigzag channel made along the length of the water supply path, while the bottom mark of the zigzag channel is lower than the bottom mark of the water supply path.

The disadvantage of this structure is the low efficiency of extinguishing the energy of the stream and the conditions for the promotion of fish.

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

The invention consists in the following.

According to claim 1 of the claims. Performing a flowing zigzag channel in plan along a sinusoidal curve with a constant amplitude allows you to bring its configuration closer to the structure of the natural river bed. At the same time, both the speed regime and the planned speed diagram contribute to the effective advancement of fish along the length of the water supply path.

The main flow of water flows above the flowing zigzag channel, where elements of enhanced roughness are installed, which effectively absorb the excess kinetic energy of the flow. Part of the kinetic energy of the transit flow is expended during the interaction of the surface flow with the flow of the zigzag flow channel.

The placement of the elements of enhanced roughness located at the bottom of the water supply path, in its sections adjacent to the flowing zigzag channel on both sides, allows to efficiently extinguish the kinetic energy of the flow.

The implementation of the elements of enhanced roughness of different sizes and having different geometric dimensions and shapes expands the possibilities for creating hydraulic resistance to the transit flow.

According to claim 2 of the claims. The variant, when the flowing zigzag channel is made with a longitudinal slope different from the longitudinal slope of the water supply path, allows you to expand the speed range that takes place in the fish passage channel.

According to claim 3 of the claims. The variant when the bottom of the sections of the water supply path adjacent to the flowing zigzag channel on both sides is made with a transverse slope, while the upper mark of the slopes adjoins the side walls of the tray of the water supply path, which makes it possible to increase the hydraulic resistance to the transit flow.

According to claim 4 of the claims. The variant, when the fish passage channel is equipped with an additional flowing zigzag channel made asymmetrically and specularly to the main flowing zigzag channel, while the mating sections of the additional and main flowing zigzag channels are located on the longitudinal axis of the water supply path, it allows efficient quenching of the flow kinetic energy in the bottom horizons of the flow. The bottom layers of the flow are inhibited in the transverse sections of the channel, in which there are sections of the interface between the additional and main flowing zigzag channels. Due to the collision of two streams connecting at the interface, the transit stream loses part of its excess energy.

According to claim 5, the claims. The option, when the elements of enhanced roughness are made of natural material in the form of boulders and large stones, brings the structure of the fish passage channel closer to the structure of natural river streams in which migrants spend most of their lives. In addition, the cost of building a fish passage channel is reduced.

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

figure 1 - fish passage channel plan;

figure 2 - section aa in figure 1;

figure 3 is a section bB in figure 1;

figure 4 - section bb in figure 1;

5 is a transverse section of the fish passage channel, an option when its bottom is made with a transverse slope;

6, 7, 8 - the same, on the slopes placed elements of enhanced roughness;

Fig.9 - fish passage channel, plan, option, when it is equipped with an additional flowing zigzag channel made asymmetrically and specularly to the main flowing zigzag channel, while the mating sections of the additional and main flowing zigzag channels are located on the longitudinal axis of the water supply path;

figure 10 - section GG in figure 9;

11 - the same option;

Fig - section DD in Fig.9;

Fig - the same option.

The fish passage channel includes a water supply path 1, made in the form of a tray, the head part of which is connected to the upper pool of the hydraulic system, and the wellhead part - to the lower pool, reinforced roughness elements 2 located along the length of the water supply channel 1, and a flowing zigzag channel 3 made along the length of the water supply tract 1, while the bottom mark of the zigzag channel 3 is lower than the bottom mark of the water supply path 1.

The flowing zigzag channel 3 is made in plan according to a sinusoidal curve with a constant amplitude, and the elements of reinforced roughness 2 are located at the bottom of the water supply path 1, in its sections adjacent on both sides to the flowing zigzag channel 3, and the elements of enhanced roughness 2 have different geometric sizes and form.

In addition, the flowing zigzag channel 3 can be made with a longitudinal slope different from the longitudinal slope of the water supply path 1.

In addition, the bottom of the sections of the water supply path 1 adjacent to the flowing zigzag channel 3 on both sides can be made with a transverse slope, while the upper mark of the slopes 4 is adjacent to the side walls of the tray of the water supply path 1.

In addition, the fish passage path can be equipped with an additional flowing zigzag channel 5 made asymmetrically and mirror-like to the main flowing zigzag channel 3, while the interface sections 6 of the additional 5 and the main 3 flowing zigzag channels are located on the longitudinal axis of the water supply path 1.

In addition, the elements of enhanced roughness 2 can be made of natural material in the form of boulders and large stones.

Fish passage channel works as follows.

When the working flow is fed into the fish passage channel, migrants are allowed to pass through the spillway dam. The fish attracted from the lower pool enters the water supply path 1 and gradually moves in the direction of the upper pool. Bottom species of fish can move freely along the flowing zigzag channel 3. Elements of increased roughness 2 are located at the bottom of the water supply path 1, in its sections adjacent on both sides to the flowing zigzag channel 3, which allows efficient quenching of the kinetic energy of the flow. The implementation of the elements of enhanced roughness 2 of different sizes and having different geometric dimensions and shape expands the possibilities for creating hydraulic resistance to the transit flow.

It is possible that the flowing zigzag channel 3 is made with a longitudinal slope different from the longitudinal slope of the water supply path 1, which allows you to expand the speed range that occurs in the fish passage channel. This arrangement allows you to create the most favorable hydraulic conditions for the passage of fish living in the bottom horizons of the watercourse (for example, sturgeons) into the upper pool.

An option when the bottom of the sections of the water supply path 1 adjacent on both sides to the flowing zigzag channel 3 is made with a transverse slope (Figs. 5-8), while the upper mark of the slopes 4 is adjacent to the side walls of the tray of the water supply path 1, allows you to increase the hydraulic resistance to transit flow.

The option, when the fish passage channel is equipped with an additional flowing zigzag channel 5, made asymmetrically and specularly to the main flowing zigzag channel 3, while the mating sections 6 of the additional 5 and the main 3 flowing zigzag channels are located on the longitudinal axis of the water supply path 1 (Fig. 9), which allows quench the kinetic energy of the flow in the bottom horizons of the flow. The bottom layers of the flow are inhibited in the transverse sections of the water supply path 1, in which the interface sections 6 of the additional 5 and the main 3 flowing zigzag channels are located. Due to the collision of two streams connecting at the interface 6, the transit stream loses part of its excess energy.

A variant when the elements of reinforced roughness 2 are made of natural material in the form of boulders and large stones, which brings the structure of the fish passage channel closer to the structure of natural river streams in which migrants spend most of their lives. In addition, the cost of building a fish passage channel is reduced. The proposed fish passage channel allows to improve the hydraulic conditions for the passage of fish into the upper pool.

Information sources

1. RF patent (RU) No. 2022091, “Channel”, IPC ЕВВ 5/02, Musin Zh.A., Aygaskaev K.S., Asanova D.A., Tleukulov A.T., Publ. 1994.10.30.

2. A.S. USSR (SU) No. 1331945, “Main canal”, MPK Е02В 5/00, Altunin BC, Selyametov M.M., Novikova N.M., Larionova L.V., Trunina E.V., Danelia Z.N. B.I. No. 31, 1987.08.23.

3. US patent (US) No. 206715, "Fishway", IPC E02B 8/08. D. Fisher, 1878, August 6.

4. US Patent (US) No. 126257, “Improvement in Chute and Fishway”, IPC E02B 8/08. J.D. Brewer, 1872, April 30.

Claims (5)

1. The fish passage channel, including the water supply path, made in the form of a tray, the head part of which is connected to the upper pool of the hydraulic system, and the wellhead part - to the lower pool, reinforced roughness elements located along the length of the water supply channel, flowing zigzag channel made along the length of the water supply channel wherein the bottom mark of the zigzag channel is lower than the bottom mark of the water path, characterized in that the flowing zigzag channel is made in plan according to a sinusoidal curve with a constant amplitude and, and the elements of enhanced roughness are located at the bottom of the water supply path in its sections adjacent to the flowing zigzag channel on both sides, and the elements of enhanced roughness have different geometric sizes and shapes. 2. The channel according to claim 1, characterized in that the flowing zigzag channel is made with a longitudinal slope different from the longitudinal slope of the water supply path. 3. The channel according to claim 1 or 2, characterized in that the bottom of the sections of the water supply path adjacent to the flowing zigzag channel on both sides is made with a transverse slope, while the upper mark of the slopes is adjacent to the side walls of the tray of the water supply path. 4. The channel according to claim 1 or 2, characterized in that it is equipped with an additional flowing zigzag channel made symmetrically and mirror-like to the main flowing zigzag channel, while the interface between the additional and main flowing zigzag channels is located on the longitudinal axis of the water supply path. 5. The channel according to claim 1 or 2, characterized in that the elements of enhanced roughness are made of natural material in the form of boulders and large stones.

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