RU2269620C1 - Fish passing and spawning channel - Google Patents

Abstract

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

SUBSTANCE: fish passing and spawning channel comprises waterway made as a channel with head part connected to upper pool and mouth part communicating with lower pool of hydrosystem, rough members located on channel bottom and extending for the full length thereof and additional flow path with head part connected with supply unit, which in turn is communicated with upper pool. Mouth part of additional flow path is connected with waterway mouth part to create independent spawning channel. The fish passing and spawning channel has several additional spawning channels arranged in parallel to additional flow path. All additional spawning channels have different longitudinal inclinations, which in turn differ from that of additional flow path. Mouth parts of additional spawning channels are connected with head part of the waterway and are arranged inside it so that the mouth parts are parallel one to another and to waterway sides. Head parts of additional spawning channels are connected with supply unit.

EFFECT: creation of spawning-effective hydraulic conditions.

14 cl, 18 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 and spawning channel [1], including a water supply path made in the form of a channel, the head part of which is connected to the upper pool of the hydraulic system, and the mouth part to the lower pool, elements of enhanced and natural roughness installed on the bottom of the channel along its length, and additional flow paths, the head parts of which are connected to the water supply path, while additional flow paths are made with different longitudinal slopes.

The disadvantage of this structure is the low efficiency of fish spawning in its internal space.

The closest in technical essence and the achieved result is a fish-spawning channel [2], including a water supply path made in the form of a channel, 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 installed at the bottom the channel along its length, and an additional flow path, the head of which is connected to a power supply unit communicating with the upper pool, and its mouth part is connected to the mouth part of the water supply path, forming a circuit Onomic spawning channel.

The disadvantage of this structure is the low efficiency of fish spawning in its internal space.

The aim of the invention is the creation of effective hydraulic conditions in a fish-spawning channel for spawning fish in its internal space.

The invention consists in the following.

According to claim 1 of the claims. The implementation of the fish-spawning channel with several additional spawning channels, made parallel to the additional flow path, allows you to increase both the area of the spawning field and the total spawning capacity of the structure. Moreover, all spawning channels have different values of the longitudinal slope, different from the longitudinal slope in the additional flow path, which allows you to create different speed modes in each of them, choosing which, the fish will find the most favorable conditions for spawning.

The implementation of the estuarine parts of additional spawning channels connected to the estuarine part of the water supply path, and the location of their input heads inside it, parallel to each other and the coastal edges of the water supply tract, allows you to create optimal hydraulic conditions for the distribution of fish entering the estuarine part of the fish-spawning channel, and create an effective scheme for merging additional flows with the main flow of the water supply path.

The connection of the head parts of the additional spawning channels with the power supply unit makes it possible to rationally use the supplied water flow rate, as well as to quickly regulate the high-speed operation mode in the spawning channels (a single flow regulator, the same characteristics of the water flow: water temperature, degree of oxygen saturation, the same concentration of zooplankton and other).

According to claim 2 of the claims. The implementation of the power supply in the form of an outdoor pool (reservoir), connected by a supply channel to the upper pool allows you to take water with a higher temperature and thereby attract fish to the temperature gradient, forming a stratified attracting stream in the estuary of the water supply path. In addition, this arrangement of the power unit allows you to feed the working flow rate through the spillway dam, while the water will be pre-saturated with oxygen, in collision with the flow of spawning channels.

According to claim 3 of the claims. The implementation of the power supply in the form of a spillway dam connecting the head of the spawning channels with the upper pool, is an option for the layout of the power supply.

According to claim 4 of the claims. The implementation of the spawning channel located along the coastal edge of the lower pool, with a maximum value of the longitudinal slope, allows you to create a fish-attracting "train", characterized by maximum speeds at its outer boundary, facing the upper pool. It is this flow distribution scheme from the outlet heads of spawning channels that contributes to the maximum allocation of the attracting flow against the background of the hydraulic structure of the downstream.

According to claim 5, claims. The implementation of the input heads of spawning channels with fish guiding devices in the form of bottom thresholds allows you to create tactile landmarks for the promotion of bottom fish, as well as stream-forming channels for the flow of water flowing from spawning channels.

According to claim 6, claims. The implementation of bottom sills with the same height is a variant of the design of the fish and jetting device.

According to claim 7 of the claims. Fulfillment of bottom sills with different heights allows the creation of autonomous fish-guiding channels, while bottom fish have the ability to move from one channel to another.

According to claim 8 of the claims. The implementation of the height of the bottom thresholds decreasing in the direction from the water supply path to the spawning channel located along the coastal edge of the lower pool, is also an embodiment of the design of the fish guide device. This arrangement also allows bottom fish to move from one channel to another. In addition, a large part of the flow rate passed through spawning channels remains within the limits of the formed autonomous flow-guiding channels, while the planned velocity plot along the width of the wellhead of the water supply path is also stabilized.

According to claim 9, the claims. The fulfillment of the height of the bottom rapids increasing in the direction from the water supply path to the spawning canal located along the coastal edge of the lower pool is also an embodiment of the design of the fish-guiding device. However, in this embodiment, part of the total flow passing through spawning channels is smoothly redistributed towards the water supply path. This creates a gradient planned diagram of velocities and favorable hydraulic conditions for migrants to select acceptable travel routes.

According to claim 10 of the claims. The implementation of the free end edges of the bottom rapids within the inner space of the estuarine part of the water supply path allows fish entering the fish-spawning channel to choose a speed mode in one of the spawning channels.

According to claim 11, the claims. The implementation of the free end edges of the bottom sills located in the inlet alignment of the estuarine part of the water supply path allows the fish to select one or another autonomous fish-directing channel at the initial stage (inlet). In addition, this arrangement of bottom sills contributes to the stabilization of the flow of fish attracting fish in bottom horizons.

According to paragraph 12 of the claims. The implementation of the input heads of spawning canals with flow-guiding devices in the form of vertical walls with a height greater than the depth of the water in the water supply path allows the formation of independent fishing channels in the input head of the fish-spawning canal, in which different speed modes are created.

According to item 13 of the claims. The implementation of the free end edges of the vertical walls located within the inner space of the estuarine part of the water supply path allows the fish entering the fish-spawning channel to choose any speed mode in one of the spawning channels.

According to claim 14. The implementation of the free end edges of the vertical walls located in the inlet section of the wellhead of the water supply path allows the fish to choose one or another independent fishing attraction channel at the initial stage (inlet). In addition, this vertical wall pattern helps stabilize the fish attracting stream throughout the thickness of the stream.

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

figure 1 - fish-spawning channel plan;

figure 2 - section aa in figure 1;

figure 3 is the same, a variant of spawning channels with other values of the longitudinal slopes;

figure 4 - input end of the fish-spawning channel, wellhead section of the water path;

5 is the same, an option with fish-guiding devices;

6 is the same, a variant of the placement of the free end edges of the fish guiding devices within the wellhead of the water supply path;

Fig.7 - fish-spawning channel, plan, layout option of the power supply of spawning channels;

Fig.8 is a section bB in Fig.7;

Fig.9 is a section bb in Fig.8;

figure 10 is a fragment of the input head of the fish-spawning channel;

11 is a section GG in figure 10, a variant of fish-guiding devices in the form of vertical walls;

Fig - the same, a variant of the fish-guiding devices in the form of bottom sills with the same height;

Fig - the same, a variant of the fish guiding devices in the form of bottom sills with a height decreasing to the side of the water path;

Fig - the same, a variant of the fish-guiding devices in the form of bottom sills with a height increasing to the side of the water path;

Fig - cross section of the wellhead of the water supply path;

Fig - connection diagram of the input ends of spawning channels with the wellhead of the water supply path;

Fig is a cross section of a spawning channel;

Fig. 18 is the same, an embodiment with reinforced roughness elements.

Fishery-spawning channel includes a water supply path 1, made in the form of a channel, the head part 2 of which is connected to the upper pool 3 of the hydraulic system, and the wellhead part 4 is connected to the lower pool 5, reinforced roughness elements 6 installed on the bottom of the channel along its length, and an additional a flow path 7, the head of which is connected to a power supply unit 8, communicating with the upper pool 3, and its wellhead part is connected to the wellhead part 4 of the water supply path 1, forming an autonomous spawning channel. The fish spawning channel is provided with several additional spawning channels 9, parallel to the additional flow path 7, while all spawning channels 9 have different longitudinal slopes, different from the longitudinal slope in the additional flow path 7, and the mouth parts of the additional spawning channels 9 are connected to the wellhead part 4 of the water supply path 1, are located inside it parallel to each other and the coastal edges of the water supply path 1, and their head parts are connected to the block Ethan 8.

In addition, the power supply unit 8 can be made in the form of an outdoor pool 10 connected by a supply channel 11 to the upper pool 3.

In addition, the power supply unit 8 can be made in the form of a spillway dam 12 connecting the head parts of spawning channels 9 with the upper pool 3.

In addition, the spawning channel 9 with the maximum value of the longitudinal slope is located along the coastal edge of the lower pool 5.

In addition, the input heads of spawning channels 9 can be made with fish-guiding devices in the form of bottom sills 13.

In addition, the bottom sills 13 can be made with the same height.

In addition, the bottom sills 13 can be made with different heights.

In addition, the height of the bottom sills 13 may decrease in the direction from the water supply path 1 to the spawning channel 9 located along the coastal edge of the lower pool 5.

In addition, the height of the bottom sills 13 may increase in the direction from the water supply path 1 to the spawning channel 9 located along the coastal edge of the lower pool 5.

In addition, the free end edges of the bottom sills 13 can be located within the inner space of the wellhead 4 of the water supply path 1.

In addition, the free end edges of the bottom sills 13 can be located in the inlet section of the wellhead part 4 of the water supply path 1.

In addition, the input heads 14 of the spawning channels 9 can be made with flow-guiding devices in the form of vertical walls 15 with a height greater than the depth of the water in the water supply path 1.

In addition, the free end edges of the vertical walls 15 can be located within the inner space of the wellhead 4 of the water supply path 1.

In addition, the free end edges of the vertical walls 15 can be located in the input section of the wellhead part 4 of the water supply path 1.

For spawning of fish, the bottom of the water supply path 1, the additional water supply path 7, and spawning channels are made with gravel and pebble bedding 0.3 meters thick, which serves as a spawning substrate 16.

Fishery-spawning channel works as follows.

Attraction of fish from the downstream pool 5 to the wellhead 4 of the water supply path 1 is carried out by supplying a working flow from the upper pool 3 flowing along the water supply path 1. In addition, due to the operation of the power supply unit 8, the spawning channels 9 and the additional flow path 7 also receive a working water flow rate, which together with the flow rate of the water supply path 1 forms a “train” of speeds that attracts fish. Bottom species of fish (for example, sturgeon) moving mainly at the bottom of the watercourse, focusing on an attracting bottom stream, enter the inlet heads of 14 spawning channels, where optimal conditions are created for their spawning on the spawning substrate 16. If the conditions created in the spawning channels 9, do not satisfy migrants, then they slide into the mouth part 4 and, without leaving the mouth part 4, are able to move along the water supply path 1 to the head part 2 and go to the upper pool 3, where they continue spawning migrations th.

To increase the efficiency of quenching the excess kinetic energy of the water stream along the length of spawning channels 9, elements of enhanced roughness 6 can be installed (see Fig. 18). To create a different speed regime inside the spawning channels 9, they are made with different longitudinal slopes. Two layout schemes of spawning channels 9 in cross section are possible (FIGS. 2 and 3).

The variant when the spawning channel 9, located along the coastal edge of the lower pool 5, is made with the maximum value of the longitudinal slope, allows you to create a fish-attracting "train", characterized by maximum speeds at its outer boundary, facing the side of the tail 3 (Fig.4). It is such a flow distribution scheme from the outlet heads 14 of the spawning channels 9 that contributes to the maximum allocation of the attracting flow against the background of the hydraulic structure of the downstream 5.

The variant when the spawning channel 9, located tangentially along the water supply path 1, is made with the maximum value of the longitudinal slope, allows you to create a reorganized planned speed diagram along the width of the water supply path 1. This flow rate attracting flow extends the range of fish that can choose the most favorable hydraulic conditions for their advancement .

An embodiment of the power supply unit 8 in the form of an open pool 10 (reservoir) connected by a supply channel 11 to an upstream pool 3 (Fig. 1) allows water to be taken at a higher temperature and, thereby, attract fish to a temperature gradient, forming a stratified attracting stream in the mouth part 4 of the water supply path 1. In addition, this arrangement of the power unit 8 allows you to feed the working flow through the spillway dam 12, while the water will be pre-saturated with oxygen, when spawning with the flow spawning New channels 9.

It is possible to perform the power supply 8 in the form of a spillway dam 12 (Figs. 7, 8 and 9), connecting the head parts of spawning channels 9 with the upper pool 3, is an arrangement of the power supply 8.

The implementation of the input heads 14 spawning channels 9 with fish-guiding devices in the form of bottom thresholds 13, allows you to create tactile landmarks for the promotion of bottom fish, as well as stream-forming channels for the flow of water flowing from spawning channels 9 (Fig.5 and 6).

The high-altitude layout of the bottom fish guide sills 13 may be different: the same height of the sills 13 (Fig. 12) and the bottom sills 13 with a height decreasing (increasing) along the width of the wellhead 4 of the water supply path 1 (Figs. 13 and 14). The implementation of bottom rapids 13 with different heights, allows you to create autonomous fish-guiding channels, while bottom fish have the ability to move from one channel to another.

The implementation of the height of the bottom sills 13 decreasing in the direction from the water supply path 1 to the spawning channel 9, located along the coastal edge of the lower pool 5, is also an embodiment of the design of the fish guide device. This arrangement also allows bottom fish to move from one channel to another. In addition, a large part of the flow rate passed through spawning channels 9 remains within the limits of the formed autonomous stream-guiding channels, while the planned velocity plot along the width of the wellhead part 4 of the water supply path 1 is also stabilized.

The execution of the height of the bottom sills 13 increasing in the direction from the water supply path 1 to the spawning channel 9, located along the coastal edge of the lower pool 5, is also an embodiment of the design of the fish guide device. However, in this embodiment, part of the total flow rate passing through spawning channels 9 is smoothly redistributed towards the water supply path 1. This creates a gradient planned velocity plot and favorable hydraulic conditions for migrants to select suitable travel routes.

The implementation of the free end edges of the bottom sills 13 within the inner space of the estuarine part 4 of the water supply path 1 (Fig.6) allows the fish that entered the fish-spawning channel to choose a speed mode in one of the spawning channels 9.

The implementation of the free end edges of the bottom sills 13, located in the input section of the wellhead part 4 of the water supply path 1, allows the fish to choose one or another autonomous fish-directing channel at the initial stage (input target). In addition, this arrangement of bottom sills 13 helps to stabilize the flow of fish attracting fish in the bottom horizons (Fig. 5).

The implementation of the input heads 14 spawning channels 9 with flow-guiding devices in the form of vertical walls 15 (11) with a height greater than the depth of the water in the water supply path 1, allows you to create independent fishing channels in the input head of the fish-spawning channel, in which various high-speed channels are created modes.

Information sources

1. USSR author's certificate No. 1666633, "Fish-breeding and spawning canal", E 02 B 8/08, Authors: Shkura VN, Chistyakov AA, Novadarsky AV, Anokhin AM and Cherkasov V.A. (THE USSR). Publ. B.I. No. 28, 1991

2. US Patent No. 6652189 "Metod for a migratory fish bypass channel with natural features", G.C. Bums. IPC E 02 B 8/08, E 02 B 5/04. Publ. 2003, November 25.

Claims (14)

1. Fishery-spawning channel, including a water supply path made in the form of a channel, the head part of which is connected to the upper pool of the hydraulic system, and the wellhead part is connected to the lower pool, reinforced roughness elements installed along the channel bottom along its length, and an additional flow path, the head part of which is connected to a power supply unit communicating with the upper pool, and its wellhead part is connected to the mouth part of the water supply path, forming an autonomous spawning channel, characterized in that it is equipped with several additional spawning channels parallel to the additional flow path, while all additional spawning channels have different values of the longitudinal slope, different from the longitudinal slope in the additional flow path, and the estuarine parts of the additional spawning channels are connected to the wellhead part of the water supply tract, are located inside it parallel to each other and the coastal edges of the water supply path, and their head parts are connected to the power supply. 2. Fishery and spawning canal according to claim 1, characterized in that the power supply unit is made in the form of an outdoor pool connected by a supply channel to the upper pool. 3. Fishery and spawning canal according to claim 2, characterized in that the power unit is made in the form of a spillway dam connecting the head parts of the spawning canals with the upper pool. 4. Fishery-spawning channel according to claim 1, characterized in that the spawning channel with a maximum value of the longitudinal slope is located along the coastal edge of the downstream. 5. Fishery-spawning canal according to claim 1, characterized in that the input heads of the spawning canals are made with fish-guiding devices in the form of bottom thresholds. 6. Fishery and spawning canal according to claim 5, characterized in that the bottom rapids are made with the same height. 7. Fishery and spawning canal according to claim 5, characterized in that the bottom rapids are made with different heights. 8. Fishery-spawning canal according to claim 7, characterized in that the height of the bottom rapids decreases in the direction from the water supply path to the spawning canal located along the coastal edge of the lower pool. 9. Fishery-spawning canal according to claim 7, characterized in that the height of the bottom rapids increases in the direction from the water supply path to the spawning canal located along the coastal edge of the lower pool. 10. Fishery and spawning channel according to any one of paragraphs. 6 to 9, characterized in that the free end edges of the bottom sills are located within the inner space of the estuarine part of the water supply path. 11. Fishery and spawning channel according to any one of paragraphs. 6 to 9, characterized in that the free end edges of the bottom sills are located in the inlet section of the wellhead of the water supply path. 12. Fishery-spawning canal according to claim 1, characterized in that the input heads of the spawning canals are made with flow-guiding devices in the form of vertical walls with a height greater than the depth of the water in the water supply path. 13. Fishery and spawning canal according to claim 12, characterized in that the free end edges of the vertical walls are within the inner space of the estuary of the water supply path. 14. Fishery and spawning channel according to claim 12, characterized in that the free end edges of the vertical walls are located in the inlet section of the estuary part of the water supply path.

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