RU2286421C1 - Fish passing device - Google Patents

Abstract

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

SUBSTANCE: fish passing device comprises bottom fish-directing baffle inclined to longitudinal axis of fish pass and adjoining inlet part of fish accumulation bed. The device also has fish-guiding flow creation means, which creates flow at several levels above upper edge of bottom baffle. Fish-guiding flow creation means has working members connected to upper edge of bottom baffle by low ends thereof so that the working members may be displaced in space under the action of transit flow passing through spillway bays of hydraulic system. The working members are vertical and are discretely distributed over the full length of upper edge of bottom baffle. The working members define space for free transit flow passage located in-between.

EFFECT: simplified fish behavior control in surface flow levels.

21 cl, 24 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 guide device [1], including a bottom fish guide threshold, installed at an angle to the longitudinal axis of the fish passage structure and adjacent to the input part of the fish tray, means for regulating along the threshold flow, made in the form of a visor that can be changed by driving the elevation of its upper face .

The disadvantage of this fish directing threshold is the low efficiency of controlling along the threshold current, as well as the low efficiency of controlling the behavior of fish in the surface horizons of the stream.

Known fish guide device [2], including a bottom fish guide threshold, installed at an angle to the longitudinal axis of the fish passage structure and adjacent to the input part of the fish storage tray, means for creating a fish-guiding stream in the horizons located above the upper edge of the bottom threshold, and its working elements, attached with their lower end to the plane of the upper face of the bottom threshold, with the ability to change their spatial position.

The disadvantage of this fish guide threshold is the design complexity and low efficiency of controlling the behavior of fish in the surface horizons of the stream.

Known fish guide device [3], including a bottom fish guide threshold, installed at an angle to the longitudinal axis of the fish passage structure and adjacent to the input part of the fish storage tray, means for regulating along the threshold flow, having the ability to change by driving the elevation of its upper face.

The disadvantage of this fish guide threshold is the design complexity and low efficiency of controlling the behavior of fish in the surface horizons of the stream.

Known fish guide device [4], including a bottom fish guide threshold, installed at an angle to the longitudinal axis of the fish passage structure and adjacent to the input part of the fish storage tray, means for regulating along the threshold current, having the ability to change its location by means of a drive, while means for regulating along the threshold current made in the form of a system of louvre plates installed on the upper edge of the bottom of the fish guide threshold and connected to the drive.

The disadvantage of this fish guide threshold is the design complexity and low efficiency of controlling the behavior of fish in the surface horizons of the stream.

The closest in technical essence and the achieved result is a fish guide device [5], including a bottom fish guide threshold, installed at an angle to the longitudinal axis of the fish passage structure and adjacent to the input part of the fish storage tray, a means for creating a fish-guiding stream in horizons located above the upper face bottom threshold, and its working elements attached by the lower end to the plane of the upper edge of the bottom threshold, with the ability to change their spatial position Nia by exposing them to a transit flow discharged through the spillway spans waterworks.

The disadvantage of this device is the design complexity and low efficiency of controlling the behavior of fish in the surface horizons of the stream.

The aim of the invention is to simplify the process of controlling the behavior of fish in the surface horizons of the stream.

The invention consists in the following.

According to claim 1 of the claims. The implementation of the working elements vertically and discretely located along the length of the upper edge of the bottom threshold allows you to form a fish guide screen above the bottom threshold, which helps migrants to actively move in the surface horizons of the stream and move the fish towards the entrance of the fish storage tank of the fish passage structure. When flowing around the working elements in transit flow behind the working elements creates a zone with reduced pressure (Fig.4 and 5), characterized by whirlpool currents (Fig.3). In addition, the transit stream during the flow around the working elements generates a spectrum of turbulent pulsations in a wide range, which are perceived by the organs of the lateral line of the fish. The fish responds to the created hydrodynamic velocity field and, as it approaches the fish guide screen, experiences its maximum impact, which forces the fish to move at a certain distance from the working elements (along them) towards the entrance of the fish storage tray, where the fish can attract and accumulate and later transferred to the upper pool.

The working elements in the space between each other form the space for the free passage of the transit stream, which allows the formation of a along-threshold flow beyond the pressureless lateral face of the bottom threshold.

According to claim 2 of the claims. The implementation of the working elements in the form of rods with a round cross section is a private option. In addition, the cross-sectional shape of the rods is one of the optimal both in terms of reliability, and in terms of the flow around it in transit.

According to claim 3 of the claims. An embodiment of working elements in the form of plates with a rectangular cross section is possible. The plates have great flexibility and under the influence of the transit flow they vibrate more intensively, which enhances the deterrent-attracting effect on the fish.

According to claim 4 of the claims. A possible embodiment of the working elements in the form of plates, the width of the free ends of which is less than the width of the cantilevered ends. In this embodiment, the trapezoidal shape of the plane of the plates also allows you to expand the spectrum of turbulent pulsations generated by the transit stream over the entire height of the plates. The intensity of the vortex flows will be higher at the free end of the plates.

According to claim 5, claims. The implementation of the working elements from an elastic material (for example, from a rubberized reinforced material) allows, due to the increased degree of flexibility of the working elements, to expand the spectrum range of turbulent pulsations.

According to claim 6, claims. The implementation of work items with the same height along the length of the upper face of the bottom threshold allows the formation of equally probable conditions in the surface horizon to redirect the fish to the inlet of the fish storage tray.

According to claims 7 and 8 of the claims. Performing the height of the working elements decreasing in the direction from the end part of the bottom threshold to the input part of the fish storage tray or decreasing in the direction of the downstream allows you to adjust the intensity of the fish guide screen.

According to claim 9, the claims. The implementation of work items installed with an uneven pitch along the length of the bottom threshold allows you to adjust the density of the fish guide screen in the surface horizon.

According to claim 10 of the claims. The implementation of the working elements installed in increments decreasing in the direction of the input part of the fish storage tray allows increasing the density of the fish guide screen in the immediate vicinity of its input part.

According to claim 11, the claims. The implementation of the working elements installed in increments increasing in the direction of the input part of the fish storage tray allows for the gradual redirection of fish from the periphery (end part of the bottom threshold) to the input part of the fish storage tray. The increased density of the working elements at the end of the bottom threshold (a smaller step of their installation) provides an increase in the probability of redirecting fish along the working elements.

According to claims 12, 13 and 14 of the claims. The implementation of the diameter of the rods varying along the length of the bottom threshold allows you to simultaneously control both the intensity of the exposure of the fish guide screen and its density.

According to claims 15, 16 and 17 of the claims. The implementation of the thickness of the plates, varying along the length of the bottom threshold, allows you to form a fish guide screen, the plates of which have a different degree of flexibility (rigidity). This allows you to adjust the spectrum of turbulent pulsations along the length of the bottom threshold.

According to claim 18. The implementation of the pressure planes of the plates located in a plane perpendicular to the longitudinal axis of the fish passage structure (normal to the longitudinal vector) allows you to create maximum resistance to the transit flow and accordingly form a fish guide screen with maximum intensity.

According to claim 19 of the claims. The implementation of the bottom threshold along the length with uneven height allows you to adjust the intensity along the threshold current along the length of the threshold.

According to claim 20 of the claims. Fulfillment of the height of the bottom threshold decreasing in the direction of the downstream allows you to create favorable conditions for the passage of fish along the threshold, gradually decreasing the intensity along the threshold current and bringing the fish to the gradient of the attractive flow rate supplied from the fish storage tray.

According to claim 21. The fulfillment of the height of the bottom threshold increasing in the direction of the downstream allows the formation of boundary conditions for the distribution of flow, which, against the background of the hydraulics of the lower downstream, increase the efficiency of the fish-directing effect.

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

figure 1 - fish guide device, isometry, the working elements are made in the form of rods;

figure 2 - the same, under the influence of the transit stream;

figure 3 - flow pattern formed during the flow around the rod;

figure 4 is a fragment of a fish guide device, plan, shows a planned plot of speeds;

5 is the same, the working elements are made in the form of plates;

6 is a fish guide device, a view from the downstream side, the working elements are made with the same height;

Fig.7 is the same, the height of the working elements decreases towards the downstream;

Fig.8 is the same, the height of the working elements increases towards the downstream;

Fig.9 - fish guide device, isometry, the working elements are made in the form of plates;

figure 10 is a fragment of a fish guide device, isometry, an embodiment of plates with a free end width less than the width of the plate at the attachment point to the upper face of the bottom threshold;

11 - fish guide device, plan, option for uniform installation of rods along the length of the bottom threshold;

12 is a fish guide device, a plan, an option for installing rods with an uneven pitch decreasing in the direction of the inlet portion of the fish storage tray;

Fig - fish guide device, plan, an option for installing rods with an uneven pitch, increasing in the direction of the inlet of the tray-fish tank;

Fig. 14 is an embodiment of the installation of rods, the diameter of which increases in the direction of the input part of the fish storage tray, plan;

Fig - installation option rods, the diameter of which decreases in the direction of the inlet of the tray-fish tank, plan;

Fig is a variant of the installation of the plates, the thickness of which increases in the direction of the input part of the tray-fish storage, plan;

Fig - a variant of the installation of the plates, the thickness of which decreases in the direction of the inlet of the tray-fish tank, plan;

Fig is a variant of the installation of the plates, the pressure plane of which is located in a plane perpendicular to the longitudinal axis of the fish passage structure, plan;

Fig. 19 is an embodiment of the installation of rods, the diameter of which increases in the direction of the inlet part of the fish storage tray, isometry;

Fig. 20 is an embodiment of the installation of rods, the diameter of which decreases in the direction of the inlet part of the fish storage tray, isometry;

Fig.21 is an embodiment of the bottom threshold with uneven height increasing in the direction of the inlet of the fish storage tray, view from the downstream side;

Fig - the same, the free end of the working elements is located at the same elevation;

Fig. 23 is an embodiment of a bottom threshold with an uneven height decreasing towards the inlet of a fish storage tray, view from the downstream side;

Fig.24 is the same, the free end of the working elements is located at the same elevation.

The fish guide device includes a fish guide threshold 1, installed at an angle to the longitudinal axis of the fish passage structure and adjacent to the input part of the fish storage tray 2, means for creating a fish-guiding stream in the horizons located above the upper edge of the bottom threshold 1, and its working elements 3 attached the lower end to the plane of the upper face of the bottom threshold 1, having the ability to change their spatial position through exposure to a transit stream discharged through odoslivnye spans waterworks.

The working elements 3 are made vertical and discretely located along the length of the upper edge of the bottom threshold 1, while in the spaces between them they form a space 4 for free passage of the transit stream.

In addition, the working elements 3 can be made in the form of rods 5 with a circular cross section.

In addition, the working elements 3 can be made in the form of plates 6 with a rectangular cross-section.

In addition, the width of the free ends of the plates 6 may be less than the width of the cantilevered ends.

In addition, the working elements 3 can be made of elastic material.

In addition, the working elements 3 can be made with the same height along the length of the bottom threshold 1.

In addition, the height of the working elements 3 can be reduced in the direction from the end of the bottom threshold 1 to the input of the tray-fish tank 2.

In addition, the height of the working elements 3 can decrease in the direction from the inlet of the fish-storage tray 2 towards the downstream side 7 of the waterworks.

In addition, the working elements 3 can be installed with an uneven pitch along the length of the bottom threshold 1.

In addition, the working elements 3 can be installed in increments decreasing in the direction of the input part of the fish tank 2.

In addition, the working elements 3 can be installed in increments that increase in the direction of the inlet of the fish tray 2.

In addition, the diameter of the rods 5 may vary along the length of the bottom threshold 1.

In addition, the diameter of the rods 5 may increase in the direction of the input part of the tray-fish tank 2.

In addition, the diameter of the rods 5 may decrease in the direction of the inlet of the tray-fish tank 2.

In addition, the thickness of the plates 6 may vary along the length of the bottom threshold 1.

In addition, the thickness of the plates 6 may increase towards the entrance of the fish tray 2.

In addition, the thickness of the plates 6 may decrease towards the entrance of the fish tray 2.

In addition, the pressure plane of the plates 6 can be located in a plane perpendicular to the longitudinal axis of the fish passage structure.

In addition, the bottom threshold 1 in length can be made with uneven height.

In addition, the height of the bottom threshold 1 may decrease in the direction of the downstream 7.

In addition, the height of the bottom threshold 1 may increase in the direction of the downstream 7.

Fish guide device operates as follows.

Under stable hydraulic conditions in the downstream of the waterworks, the fish are attracted to the fish storage tray 2 by supplying a flow that attracts the fish from the main power supply, as well as through the fish guide bottom threshold 1 (Fig. 2). The transit stream acts on the working elements 3, forcing them to vibrate and change their spatial position. In this case, directly behind the working elements 3 (from the downstream side 7), a hydrodynamic field is formed that exerts a fish-directing effect on the fish.

The implementation of the working elements 3 vertically and discretely located along the length of the upper edge of the bottom threshold 1 allows you to form a fish guide screen above the bottom threshold 1, which helps migrants to actively move in the surface horizons of the stream and move the fish towards the entrance of the fish tank 2 of the fish passage structure. When flowing around the working elements 3 in transit flow behind the working elements 3 creates a zone with reduced pressure (Fig.4 and 5), characterized by whirlpool currents (Fig.3). In addition, the transit stream during the flow around the working elements 3 generates a spectrum of turbulent pulsations in a wide range, which are perceived by the organs of the lateral line of the fish. The fish responds to the hydrodynamic velocity field created and, as it approaches the fish guide screen, it experiences its maximum effect, which forces the fish to move at a certain distance from the working elements 3 (along them) towards the entrance of the fish storage tray 2, where the fish can attract and accumulation and subsequently transferred to the upper pool.

The working elements 3 in the space between each other form the space 4 for the free passage of the transit stream.

Bottom species of fish move along the pressureless lateral edge of the bottom threshold 1, which is largely facilitated by the formation of a longitudinal helical flow along it due to the work of the transit flow entering through the upper face of the bottom threshold 1 in the space 4 formed between the working elements 3.

A possible embodiment of the working elements 3 in the form of rods 5 with a circular cross-section (FIGS. 1 and 2). Moreover, this cross-sectional shape of the rods 5 is one of the optimal both in terms of reliability, and in terms of flow around it in transit.

A possible embodiment of the working elements 3 in the form of plates 6 with a rectangular cross section (FIGS. 5 and 9). The plates 6 have great flexibility and under the influence of the transit flow they vibrate more intensively, which enhances the repellent-attracting effect on the fish.

A possible embodiment of the working elements 3 in the form of plates 6, the width of the free ends of which is less than the width of the cantilevered ends (figure 10). In this embodiment, the trapezoidal shape of the plane of the plates 6 also allows you to expand the spectrum of turbulent pulsations generated by the transit flow over the entire height of the plates 6. In this case, the intensity of the vortex flows will be higher at the free end of the plates 6.

A variant of working elements 3 of elastic material (for example, of rubberized reinforced material) is possible, which allows, due to the increased degree of flexibility of working elements 3, to expand the range of the spectrum of turbulent pulsations and the intensity of the effect of the fish guide screen on the behavior of fish in the surface horizons of the stream.

A variant of the working elements 3 with the same height along the length of the upper face of the bottom threshold 1 is possible, it allows the formation of equally probable conditions in the surface horizon for redirecting the fish to the input of the fish-collecting tray 2.

Performing the height of the working elements 3 decreasing in the direction from the end part of the bottom threshold 1 to the input part of the fish storage tray 2 or decreasing in the direction of the lower pool 7 allows you to adjust the intensity of the exposure of the fish guide screen.

The implementation of the working elements 3, installed with an uneven pitch along the length of the bottom threshold 1, allows you to adjust the density of the fish guide screen in the surface horizon.

The implementation of the working elements 3, installed with a step decreasing towards the inlet of the fish tray 2, allows to increase the density of the fish guide screen in the immediate vicinity of its inlet.

The implementation of the working elements 3 installed in increments increasing in the direction of the input part of the fish tank 2, allows for the gradual redirection of fish from the periphery (end part of the bottom threshold 1) to the input part of the fish tank 2. The increased density of the working elements 3 at the end part bottom threshold 1 (a smaller step of their installation) provides an increased likelihood of redirecting fish along the working elements 3.

The implementation of the diameter of the rods 5, varying along the length of the bottom threshold 1, allows you to simultaneously control both the intensity of the exposure of the fish guide screen and its density.

The implementation of the thickness of the plates 6 varying along the length of the bottom threshold 1 allows you to form a fish guide screen, the plate 6 of which have a different degree of flexibility (stiffness). This allows you to adjust the spectrum of turbulent pulsations along the length of the bottom threshold 1.

The execution of the pressure planes of the plates 6 located in a plane perpendicular to the longitudinal axis of the fish passage structure (normal to the longitudinal vector of the transit stream) allows you to create maximum resistance to the transit stream and, accordingly, form a fish guide screen with maximum intensity.

The implementation of the bottom threshold 1 along the length with uneven height allows you to adjust the intensity along the threshold current along the length of the bottom threshold 1.

Fulfillment of the height of the bottom threshold 1 decreasing in the direction of the lower pool 7 allows you to create favorable conditions for the passage of fish along the bottom threshold 1, gradually reducing the intensity along the threshold current and bringing the fish to the gradient of the attractive flow rate from the tray-fish tank 2.

Performing the height of the bottom threshold 1 increasing in the direction of the downstream 7 allows you to create boundary conditions for the distribution of flow, which, against the background of the hydraulics of the downstream 7, increase the efficiency of the fish-directing effect.

The proposed fish guide device allows you to control the behavior of fish both in the bottom horizons and in the surface horizons, which contributes to a targeted, free and independent passage of fish to the entrance of the fish passage structure.

Information sources

1. A.S. USSR No. 1055814 (USSR). "Fishing passage". IPC E 02 B 8/08. Malevanchik B.C., publ. 11/23/83. BI No. 43.

2. A.S. USSR No. 1650865 (USSR). "Fish protection device." IPC E 02 B 8/08. Shkura V.N., Chistyakov A.A., Tsvetkov O.V., Sinyakin A.V., publ. 05/23/91. BI No. 19.

3. RF patent No. 22545426 (RU). "Fish guide device". IPC E 02 B 8/08. Shkura V.N., Chistyakov A.A., publ. 01/27/2005. BI No. 3.

4. RF patent No. 22545418 (RU). "A control method along the threshold current and a fish-guiding device implementing it." IPC E 02 B 8/08. Chistyakov A.A., Shkura V.N., publ. 01/27/2005. BI No. 3.

5. RF patent №2245417 (RU). "A control method along the threshold current and a fish-guiding device implementing it." IPC E 02 B 8/08. Chistyakov A.A., Shkura V.N., publ. 01/27/2005. BI No. 3.

Claims (21)

1. A fish guide device, including a bottom fish guide threshold, installed at an angle to the longitudinal axis of the fish passage structure and adjacent to the input part of the fish storage tray, means for creating a fish-guiding stream in horizons located above the upper edge of the bottom threshold, and its working elements attached to the bottom end to the plane of the upper face of the bottom threshold, having the ability to change their spatial position through exposure to a transit stream discharged through doslivnye spans waterworks, characterized in that the working elements are vertical and arranged discretely along the length of the upper face of the bottom threshold, wherein in between them they form a space for free passage of flow transit. 2. The device according to claim 1, characterized in that the working elements are made in the form of rods with a circular cross section. 3. The device according to claim 1, characterized in that the working elements are made in the form of plates with a rectangular cross section. 4. The device according to claim 3, characterized in that the width of the free ends of the plates is less than the width of the cantilevered ends. 5. The device according to any one of claims 1 to 4, characterized in that the working elements are made of elastic material. 6. The device according to any one of claims 1 to 4, characterized in that the working elements are made with the same height along the length of the bottom threshold. 7. The device according to any one of claims 1 to 4, characterized in that the height of the working elements decreases in the direction from the end part of the bottom threshold to the input part of the fish storage tray. 8. The device according to any one of claims 1 to 4, characterized in that the height of the working elements decreases in the direction from the inlet of the fish storage tray towards the downstream side of the waterworks. 9. The device according to any one of claims 1 to 4, characterized in that the working elements are installed with an uneven pitch along the length of the bottom threshold. 10. The device according to claim 9, characterized in that the working elements are installed in increments decreasing towards the inlet of the fish storage tray. 11. The device according to claim 9, characterized in that the working elements are installed in increments increasing in the direction of the input part of the fish storage tray. 12. The device according to claim 2, characterized in that the diameter of the rods varies along the length of the bottom threshold. 13. The device according to p. 12, characterized in that the diameter of the rods increases in the direction of the input part of the fish-storage tray. 14. The device according to p. 12, characterized in that the diameter of the rods is reduced in the direction of the input part of the fish storage tray. 15. The device according to claim 3 or 4, characterized in that the thickness of the plates varies along the length of the bottom threshold. 16. The device according to p. 15, characterized in that the thickness of the plates increases in the direction of the inlet of the tray-fish tank. 17. The device according to p. 15, characterized in that the thickness of the plates decreases in the direction towards the inlet of the fish-storage tray. 18. The device according to claim 3 or 4, characterized in that the pressure plane of the plates are located in a plane perpendicular to the longitudinal axis of the fish passage structure. 19. The device according to any one of claims 1 to 4, characterized in that the bottom threshold along the length is made with uneven height. 20. The device according to claim 19, characterized in that the height of the bottom threshold decreases in the direction of the downstream. 21. The device according to claim 19, characterized in that the height of the bottom threshold increases in the direction of the downstream.

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