RU2299289C2 - Fish pass - Google Patents

Abstract

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

SUBSTANCE: fish pass comprises fish-passing canal made as gutter and connecting upper and lower hydrosystem pools and roughed members made as blocks crossing water stream. The roughed members create longitudinal rows along fish-passing canal. Blocks in adjacent rows are shifted one from another to create swimming-in orifices in-between and fish' rest area defined by adjacent inclined edges of neighboring roughed members in longitudinal row. Fish-passing canal bottom is covered with gravel-and-pebble envelope. Longitudinal section of blocks is shaped as sinusoidal curve. Outer block surfaces form alternating depressions and projections, which simulate reaches and rifts of river bed. Front end of upstream block and rear end of downstream block are connected with each other and form continuous outer surface of roughed members. Gravel-and-pebble envelope is made in discrete points over full reaches and rifts area. Fish-passing canal bottom is inclined towards lower pool.

EFFECT: possibility to create conditions for efficient excessive kinetic energy damping and to form rest areas.

7 cl, 12 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 channel [1], including a water passage made in the form of a channel, spawning fields formed by spaced rows of spawning panels and elements of enhanced roughness installed on the bottom of the channel along its length in the spaces between spawning panels, made in the form of vertically installed elements having different height.

The disadvantage of this structure is the low efficiency of extinguishing the excess kinetic energy of the stream.

Known fish passage channel [2], including a fish passage path connecting the upper and lower heads of the hydraulic system, elements of enhanced roughness, installed by transverse rows at the bottom of the channel along its length and made in the form of cone-shaped pins with a rounded top, and the pins of each subsequent row are located in the middle of the gaps between the pins of the previous row, fish rest areas formed by an increased concentration of pins.

The disadvantage of this structure is the low efficiency of extinguishing the excess kinetic energy of the stream.

Known fish passage channel [3], including installed across the stream and displaced downstream one relative to the other blocks, which form their inclined faces side openings in the passage corridors for fish, recreation areas.

The disadvantage of this structure is the low efficiency of extinguishing excess kinetic energy.

The closest in technical essence and the achieved result is a fish passage channel [4], which includes a fish passage path made in the form of a tray connecting the lower and upper heads of the waterworks, reinforced roughness elements made in the form of blocks installed across the flow and forming longitudinal rows along the length of the fish passage, while the blocks in adjacent longitudinal rows are displaced relative to each other with the formation of swimming holes, rest areas for fish, formed between adjacent, in a longitudinal row, inclined faces E Enhanced roughness elements and pebble gravel-dumping formed on the bottom rybohodnogo tract.

The disadvantage of this structure is the low efficiency of extinguishing the excess kinetic energy of the stream.

The aim of the invention is to create effective hydraulic conditions in the fish passage channel to absorb the excess kinetic energy of the stream.

The invention consists in the following.

According to claim 1 of the claims. Performing a longitudinal section of the blocks along a sinusoidal curve allows you to form the outer surface of the enhanced roughness in the form of elevated and lowered sections that alternate one after another, simulating stretches and rifts of the river channel. At the same time, the elevated areas contribute to the suppression of excess kinetic energy of the water flow, and the lower areas form zones for the relaxation of fish, moving along the fish passage to the upper pool of the waterworks.

The execution of the end of the upstream block and the beginning of the downstream block, connected to each other in the middle of the reaches, allows you to form a continuous outer surface of the elements of enhanced roughness. This arrangement creates optimal conditions both for moving fish upstream and for efficient quenching of the energy of the water stream. The implementation of gravel-pebble graveling over the entire area of reaches and rifts allows the creation of hydraulic conditions in the bottom layer close to the natural conditions of the river bottom. Due to the inclusion of dusting in the body of increased roughness, the transit stream does not wash it off the bottom of the fish passage tract.

The implementation of the bottom of the fish passage tract with a longitudinal slope towards the downstream allows you to provide normal conditions for pairing the levels of the upper and lower pools.

According to claim 2 of the claims. The execution of the central longitudinal row of blocks with a height greater than the height of the blocks adjacent to the side walls of the fish passage channel tray (Fig. 7) allows the formation of a channel-floodplain-cross section in local transverse sections of the fish passage tract. This arrangement allows, using the well-known hydraulic phenomenon, called G.V.Zheleznyakov kinematic effect of the interaction of pressureless channel and floodplain flows to increase the efficiency of quenching excess kinetic energy of the flow. It is known that during the interaction of the channel and floodplain flows, there is a significant decrease in the average and surface velocities of the channel flow under the influence of the floodplain. At the same time, in the near-river compartment of the floodplain stream, as a rule, there is a slight increase in speeds. The zones of influence of the floodplain flow on the channel, as well as the channel flow on the floodplain depend on the geometric dimensions of the channel and floodplain, slopes of the bottom, roughness coefficients, etc.

According to claim 3 of the claims. The execution of the central longitudinal row of blocks with a height less than the height of the blocks adjacent to the side walls of the fish passage channel tray (Fig. 8) allows the formation of a cross-section of the “flood-bed-bed-flood” type in local transverse sections of the fish-passage tract. This arrangement also improves the efficiency of quenching the excess kinetic energy of the flow along the length of the fish passage.

According to claim 4 of the claims. The implementation of the outer surface of the elements of enhanced roughness in the longitudinal rows of blocks adjacent to the side walls of the fish passage channel tray, made with a transverse slope towards the longitudinal axis of the fish passage path (Fig. 9), is an embodiment of its cross section. The presence of a transverse slope allows you to create high-speed sections near the side walls of the tray, and in the immediate vicinity of the central row of blocks - zones with reduced flow rates, which expands the range of fish-attracting speeds.

According to claim 5, the claims. The execution of the outer surface of the elements of enhanced roughness in the longitudinal rows of blocks adjacent to the side walls of the fish passage channel tray, with a transverse slope towards the side walls of the fish passage channel tray (Fig. 10), also extends the range of fish attracting speeds. Moreover, zones with reduced flow rates are formed directly at the side walls of the fish passage channel tray.

According to claim 6, claims. The implementation of the outer surface of the elements of enhanced roughness in the longitudinal rows of blocks adjacent to the side walls of the fish passage channel tray, with a transverse slope towards the longitudinal axis of the fish passage path (Fig. 11), allows the formation of zones with reduced flow rates in the central part of the channel.

According to claim 7 of the claims. The implementation of the outer surface of the elements of enhanced roughness in the longitudinal rows of blocks adjacent to the side walls of the fish passage channel tray, with a transverse slope towards the side walls of the fish passage channel tray (Fig. 12), allows the formation of zones with reduced speeds in the central part of the channel and at the side walls of the channel flow.

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

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;

figure 5 - fish passage channel, isometry;

6 is the same, an embodiment of the fish passage tract;

Fig.7 is a cross section of a fish passage channel, an embodiment of a central longitudinal row of blocks with a height greater than the height of the blocks adjacent to the side walls of the fish passage channel tray;

Fig. 8 is a cross-sectional view of the fish passage channel, an embodiment of the central longitudinal row of blocks with a height less than the height of the blocks adjacent to the side walls of the fish passage channel tray;

Fig.9 - the outer surface of the elements of enhanced roughness in the longitudinal rows of blocks adjacent to the side walls of the fish passage channel tray, is made with a transverse slope towards the longitudinal axis of the fish passage path;

figure 10 - the outer surface of the elements of enhanced roughness in the longitudinal rows of blocks adjacent to the side walls of the fish passage channel tray, is made with a transverse slope towards the side walls of the fish passage channel tray;

11 - the outer surface of the elements of enhanced roughness in the longitudinal rows of blocks adjacent to the side walls of the fish passage channel tray, is made with a transverse slope towards the longitudinal axis of the fish passage;

Fig - the outer surface of the elements of enhanced roughness in the longitudinal rows of blocks adjacent to the side walls of the fish passage channel tray, is made with a transverse slope towards the side walls of the fish passage channel tray.

The fish passage channel includes a fish passage path 1, made in the form of a tray connecting the lower and upper heads of the waterworks, reinforced roughness elements 2, made in the form of blocks installed across the flow and forming longitudinal rows 3 along the length of the fish passage 1, while the blocks are in adjacent longitudinal rows 3 are shifted relative to each other with the formation of swimming holes, rest areas 4 for fish, formed between adjacent, in a longitudinal row, inclined faces of the elements of enhanced roughness 2, and gravel-pebble bedding 5, Making a bottom rybohodnogo tract 1.

The longitudinal section of the blocks is made along a sinusoidal curve, and their outer surface forms elevated 6 and lowered 7 sections that alternate one after another, simulating the reaches and rifts of the river channel, with the end of the upstream block and the beginning of the downstream block connected to each other in the middle of the reaches, forming a continuous the outer surface of the elements of enhanced roughness 2, while gravel-pebble dumping 5 in the form of inclusions is made over the entire area of reaches and rifts, and the bottom of the fish passage tract 1 is made but with a longitudinal slope towards the downstream.

In addition, the Central longitudinal row of 3 blocks can be made with a height greater than the height of the blocks adjacent to the side walls of the tray of the fish passage tract 1.

In addition, the Central longitudinal row of 3 blocks can be made with a height less than the height of the blocks adjacent to the side walls of the tray of the fish passage tract 1.

In addition, the outer surface of the elements of enhanced roughness 2 in the longitudinal rows of 3 blocks adjacent to the side walls of the tray of the fish passage 1 can be made with a transverse slope towards the longitudinal axis of the fish passage 1.

In addition, the outer surface of the elements of enhanced roughness 2 in the longitudinal rows of 3 blocks adjacent to the side walls of the fish passage channel tray 1 can be made with a transverse slope towards the side walls of the fish passage channel tray.

In addition, the outer surface of the elements of enhanced roughness 2 in the longitudinal rows of 3 blocks adjacent to the side walls of the tray of the fish passage 1 can be made with a transverse slope towards the longitudinal axis of the fish passage 1.

In addition, the outer surface of the elements of enhanced roughness 2 in the longitudinal rows of 3 blocks adjacent to the side walls of the fish channel 1 can be made with a transverse slope towards the side walls of the fish channel 1 channel.

Fish passage channel works as follows.

Fish attracted from the lower pool to the estuary of the fish passage tract 1 channel, enters it and gradually moves towards the upper pool of the hydraulic system. Due to the installation of reinforced roughness 2 elements at the bottom of the fish passage tract 1, a significant part of the excess kinetic energy of the water flow is quenched in the near-bottom horizon (Figs. 2 and 3). The implementation of gravel-pebble dumping 5 on the entire area of reaches and rifts allows you to create hydraulic conditions in the bottom layer, close to the natural conditions of the river bottom. Bottom species of fish (for example, sturgeon) move mainly at the bottom of the watercourse, where optimal conditions for their movement are created, and use the artificially created relief of the river channel, which is formed by elevated 6 and lowered 7 sections imitating reaches and rifts. When moving fish actively use recreation areas 4 (2 and 3) formed between adjacent, in a longitudinal row 3, inclined faces of the elements of enhanced roughness 2, where they restore their energy. Due to the displacement of the blocks, in adjacent longitudinal rows 3 relative to each other, the fish is able to use the formed swimming holes (6), thereby actively moving in the direction of the upper pool.

To increase the efficiency of quenching the excess kinetic energy of a water stream, elements of enhanced roughness 2 can be installed according to the following scheme (Fig. 7). The implementation of the Central longitudinal row of 3 blocks with a height greater than the height of the blocks adjacent to the side walls of the tray of the fish passage 1 allows the formation of a cross section of the channel-flood-bed-channel type in local cross sections of the fish passage 1. This arrangement allows, using the well-known hydraulic phenomenon, called G.V.Zheleznyakov kinematic effect of the interaction of pressureless channel and floodplain flows, to increase the efficiency of quenching the excess kinetic energy of the flow in the fish passage 1. During the interaction of the channel and floodplain flows, a significant decrease in the average and surface velocities of the channel flood under the influence of floodplain. At the same time, in the near-river compartment of the floodplain stream, as a rule, there is a slight increase in speeds. The zones of influence of the floodplain flow on the channel, as well as the channel flow on the floodplain, depend on the geometric dimensions of the channel and floodplain, the slopes of the bottom, roughness coefficients, etc.

It is possible to perform a central longitudinal row of 3 blocks with a height less than the height of the blocks adjacent to the side walls of the fish channel 1 channel (Fig. 8), which allows the formation of a cross-section of the “flood-bed-river-flood” type in local transverse sections of the fish passage tract 1. This arrangement also allows to increase the efficiency of quenching the excess kinetic energy of the stream along the length of the fish passage 1.

It is possible to perform the outer surface of the elements of reinforced roughness 2 in the longitudinal rows of 3 blocks adjacent to the side walls of the tray of the fish passage 1, made with a transverse slope towards the longitudinal axis of the fish passage 1 (Fig. 9), which is a variant of the layout of its cross section. The presence of a transverse slope allows you to create high-speed sections near the side walls of the tray, and in the immediate vicinity of the central row of 3 blocks - zones with reduced flow rates, which expands the range of fish-attracting speeds.

It is possible to perform the outer surface of the elements of enhanced roughness 2 in the longitudinal rows of 3 blocks adjacent to the side walls of the fish channel 1 channel, with a transverse slope towards the side walls of the fish channel 1 channel (Fig. 10), which also extends the range of fish attracting speeds. At the same time, zones with reduced flow rates are formed directly at the side walls of the fish passage channel tray 1.

It is possible to carry out the outer surface of the elements of enhanced roughness 2 in the longitudinal rows of 3 blocks adjacent to the side walls of the tray of the fish passage 1, with a transverse slope towards the longitudinal axis of the fish passage 1 (Fig. 11), which allows the formation of zones with reduced speeds in the central part of the channel flow.

It is possible to perform the outer surface of the elements of enhanced roughness 2 in the longitudinal rows of 3 blocks adjacent to the side walls of the fish channel 1 channel, with a transverse slope towards the side walls of the fish channel 1 channel (Fig. 12), which allows the central part of the channel and the side walls tray form zones with reduced flow rates.

The proposed fish passage channel allows to increase the efficiency of quenching the excess kinetic energy of the water stream and, at the same time, increase the efficiency of targeted, free and independent passage of fish into the upper pool of the hydroelectric complex.

Information sources

1. USSR author's certificate (SU) No. 1457870, "Device for spawning lithophilic fish", IPC А01К 61/00, Authors: Ivanov A.V., Lentyaev A.L. and Filippov G.G. (THE USSR). Publ. BI No. 6, 1989.

2. Patent of the Russian Federation (RU) No. 20133492, "Fish-ship", IPC EV 02/08, Author: G. Filippov (THE USSR). Publ. 05/30/1994.

3. Patent of Ukraine (UA) No. 62419, "Fish passage construction", IPC EV 02/08, Gorodetsky E.T. Publ. BI No. 12, 12/15/2003.

4. Patent WO No. 2004/083530, "Fish passage structure", IPC EV 02/08. Gorodetsky E., 2004, September 30.

Claims (7)

1. The fish passage channel, including the fish passage path, made in the form of a tray connecting the lower and upper heads of the hydraulic system, reinforced roughness elements made in the form of blocks installed across the flow and forming longitudinal rows along the length of the fish passage, while the blocks in adjacent longitudinal rows are displaced relative to each other with the formation of swimming holes, rest areas for fish, formed between adjacent in a longitudinal row inclined faces of the elements of enhanced roughness, and gravel-pebble bedding, execution at the bottom of the fish passage tract, characterized in that the longitudinal section of the blocks is made according to a sinusoidal curve, and their outer surface forms elevated and lowered sections that alternate one after another, simulating river reaches and rifts, with the end of the upstream block and the beginning of the downstream block connected with each other in the middle of the reaches, forming a continuous outer surface of the elements of enhanced roughness, while the gravel-pebble dumping is made in the form of inclusions on the entire area of the pl owls and rifts, and the bottom rybohodnogo tract formed with a longitudinal bias towards the downstream. 2. The channel according to claim 1, characterized in that the central longitudinal row of blocks is made with a height greater than the height of the blocks adjacent to the side walls of the fish passage channel tray. 3. The channel according to claim 1, characterized in that the central longitudinal row of blocks is made with a height less than the height of the blocks adjacent to the side walls of the fish passage channel tray. 4. The channel according to claim 2, characterized in that the outer surface of the elements of enhanced roughness in the longitudinal rows of blocks adjacent to the side walls of the fish passage channel tray is made with a transverse slope towards the longitudinal axis of the fish passage path. 5. The channel according to claim 2, characterized in that the outer surface of the elements of enhanced roughness in the longitudinal rows of blocks adjacent to the side walls of the fish passage channel tray is made with a transverse slope towards the side walls of the fish passage channel tray. 6. The channel according to claim 3, characterized in that the outer surface of the elements of enhanced roughness in the longitudinal rows of blocks adjacent to the side walls of the fish passage channel tray is made with a transverse slope towards the longitudinal axis of the fish passage path. 7. The channel according to claim 3, characterized in that the outer surface of the elements of enhanced roughness in the longitudinal rows of blocks adjacent to the side walls of the fish passage channel tray is made with a transverse slope towards the side walls of the fish passage channel tray.

Images