RU2310715C2 - 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 fish-passing path created as canal having inlet head connected to upper pool of hydrosystem and outlet head connected to lower pool thereof, as well as roughness members made as flexible rods. The rods are grouped in transversal rows and are connected to canal bottom in cantilever manner. The rod rows extend for the full canal length. Canal areas free of vertical members are defined in transversal rows between vertical members, which have equal height equal to flow depth. Areas free of vertical members arranged along fish-passing path are grouped along sinusoidal line and define through canal simulating meandering river bed.

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

12 cl, 15 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 [1], including a water path 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 [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 mouth part is connected to the lower pool, elements of natural roughness made in the form of natural vegetation are installed at the bottom of the channel along its length.

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

Known fish passage [3], 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 is connected to the lower pool, reinforced roughness elements placed in the tray in transverse rows and made in the form of conical rods with a rounded apex moreover, the rods of each subsequent row are located in the middle of the gaps between the rods of the previous row and the areas free from the rods are located along the length of the channel.

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

Known fish passage [4], 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 placed in the tray in transverse rows and made in the form of rods, with the rods of each the next row are located in the middle of the gaps between the rods of the previous row, while the vertical elements placed along the length of the channel are made with different heights, forming elevated and lowered sections that alternate I am one after another, simulating the rapids and stretches of the river bed.

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

Known fish passage [4], 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 placed in the tray in transverse rows and made in the form of rods, with the rods of each the next row are located in the middle of the gaps between the rods of the previous row, while the vertical elements, along the width of the tray, are made with different heights, forming elevated and lowered sections that simulate floodplain and riverbed riverbeds.

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

The closest in technical essence and the achieved result is a fish pass [5], including a fish pass path, the output head of which is connected to the upper head of the hydraulic system, and the input head - to the lower head, vertically mounted elements of enhanced roughness, made in the form of flexible rods, placed in transverse rows at the bottom of the channel along its length and cantileverly attached to the bottom of the tray, sections free from the installation of vertical elements and located in transverse rows between the vertical elements.

The disadvantage of this structure is that the hydraulic conditions in the fish passage are not effective for promoting fish.

The aim of the invention is the creation of effective hydraulic conditions in the fish passage for the promotion of fish.

The invention consists in the following.

According to claim 1 of the claims. The implementation of vertical elements of the same height, to the entire depth of the stream, allows you to effectively extinguish the excess kinetic energy of the stream. The implementation of sections free from the installation of vertical elements along the length of the fish passage path, in the form of a through channel made in plan according to a sinusoidal curve, allows you to simulate a winding river channel and create optimal conditions for the movement of fish along the fish passage path.

This arrangement allows flow through the entire live section of the fish passage, as well as optimize the process of quenching the kinetic energy of the water stream. According to the theory of fluid motion, most of the flow will go to the minimum hydraulic resistance - through the through channel. However, along the entire path of the through channel, the stream flowing through it is affected by masses of water flowing in the installation areas of the vertical elements. Moreover, in addition to the active water exchange of the flow of the through channel with the flow flowing through the installation areas of the vertical elements, the flow in the fish passage is actively inhibited due to the presence of velocity vectors characterized by different planned angles.

According to claim 2 of the claims. The option, when the bottom of the through channel is made with a mark below the bottom mark of the fish passage, allows you to create optimal hydraulic conditions for the promotion of fish living in the bottom horizons of the watercourse. In addition, this arrangement allows due to the interaction of the bottom stream (flowing in the bottom of the through channel) and the stream flowing above the bottom mark of the fish passage, also provide additional quenching of the kinetic energy of the water stream.

According to claim 3 of the claims. The implementation of the bottom of the through channel with a longitudinal slope equal to the longitudinal slope of the bottom of the fish passage, is a special case of the execution of the fish passage.

According to claim 4 of the claims. The implementation of the bottom of the through channel with a longitudinal slope greater than the longitudinal slope of the bottom of the fish passage path, allows you to increase the flow velocity in the bottom of the through channel and expand the range of fish attracting speeds.

According to claim 5, the claims. The implementation of the bottom of the through channel with a longitudinal slope smaller than the longitudinal slope of the bottom of the fish passage, allows you to lower the flow velocity in the bottom of the through channel.

According to claim 6, claims. The option, when the bottom of the through channel is made with tapering and expanding sections that alternate one after the other, along the length of the through channel, allows you to create different gradient velocity sections of the stream to relax the fish or to actively move it upstream.

According to claim 7 of the claims. The implementation of bottom channels at the bottom of the through channel, along its length, allows actively inhibiting the bottom layers of the flow and, accordingly, reducing the average flow rate.

According to claim 8 of the claims. Fulfillment of bottom thresholds set to the entire width of the through channel allows the process of quenching the kinetic energy of the flow at the bottom to the maximum extent possible.

According to claim 9, the claims. The fulfillment of bottom sills established with the formation of swimming holes between the side walls of the through channel and the end parts of the bottom sills improves the conditions for the fish to move.

According to claim 10 of the claims. The variant when even bottom thresholds are set with the formation of swimming holes adjacent to the left, downstream side wall of the through channel, and odd bottom thresholds are established with the formation of swimming holes adjacent to the right, downstream side wall of the through channel, is a variant of the thresholds arrangement and float holes.

According to claim 11, the claims. The implementation of the through channel at the bottom, along its length, of elements of enhanced roughness in the form of boulders, allows you to quench the kinetic energy of the stream using natural material.

According to paragraph 12 of the claims. The option, when the vertical elements installed in even transverse rows are offset with respect to the vertical elements installed in odd transverse rows, by half the installation step of adjacent vertical elements, allows you to form a checkerboard installation of the rods. With this arrangement, the total hydraulic resistance to the flow flowing through the fish passage increases.

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

figure 1 - fish passage, a fragment of the plan;

figure 2 - section aa in figure 1;

figure 3 is a section bB in figure 2;

figure 4 - fish passage, a fragment of the plan, staggered placement of the rods;

figure 5 - section bb in figure 4;

6 is a section GG in figure 4;

Fig.7 - fish passage, isometry;

Fig. 8 is a fish passage, a longitudinal section through a through channel;

Fig.9 is the same, an option when the longitudinal slope of the bottom of the through channel is greater than the longitudinal slope of the bottom of the fish passage tract;

figure 10 - the same option when the longitudinal slope of the bottom of the through channel is less than the longitudinal slope of the bottom of the fish passage tract;

11 is a fish passage, a fragment of the plan, an option when the bottom of the through channel is made with tapering and expanding sections that alternate one after another, along the length of the through channel;

Fig - fish passage, a fragment of the plan, an option when the bottom thresholds are installed at the bottom of the through channel, along its length;

Fig - fish passage, a fragment of the plan, an option when even bottom thresholds are installed with the formation of swimming holes adjacent to the left, downstream, side wall of the through channel, odd bottom thresholds are installed with the formation of swimming holes adjacent to the right, downstream, lateral the wall of the through channel;

Fig. 14 shows a fish passage, a fragment of the plan, an embodiment when reinforced roughness elements in the form of boulders are installed at the bottom of the through channel along its length;

Fig. 15 is a fragment of the fish passage, an isometry, a variant when bottom thresholds are installed at the bottom of the through channel along its length.

The fish passage includes a fish passage tract 1, made in the form of a channel, the output head of which is connected to the upper pool of the hydraulic system, and the input head - to the lower pool, vertically mounted elements of enhanced roughness, made in the form of flexible rods 2, placed in transverse rows at the bottom of the channel along it the length and cantileverly attached to the bottom of the channel, areas free from the installation of vertical elements located in the transverse rows between the vertical elements.

The vertical elements are made of the same height, to the entire depth of the stream, and the areas free from the installation of vertical elements along the length of the fish passage 1 are made in plan according to a sinusoidal curve and form a through channel 3 imitating a meandering river channel.

In addition, the bottom of the through channel 3 can be performed with a mark below the bottom mark of the fish passage tract 1.

In addition, the bottom of the through channel 3 can be made with a longitudinal slope equal to the longitudinal slope of the bottom of the fish passage 1.

In addition, the bottom of the through channel 3 can be made with a longitudinal slope greater than the longitudinal slope of the bottom of the fish passage 1.

In addition, the bottom of the through channel 3 can be made with a longitudinal slope less than the longitudinal slope of the bottom of the fish passage 1.

In addition, the bottom of the through channel 3 can be made with tapering 4 and expanding 5 sections that alternate one after another, along the length of the through channel 3.

In addition, at the bottom of the through channel 3, along its length, bottom thresholds 6 can be set.

In addition, the bottom thresholds 6 can be set to the entire width of the through channel 3.

In addition, bottom sills 6 can be installed with the formation of swimming holes 7 between the side walls of the through channel 3 and the end parts of the bottom sills 6.

In addition, even bottom thresholds 6 can be set with the formation of swimming holes 7 adjacent to the left, downstream, side wall of the through channel 3, and odd bottom thresholds 6 can be set with the formation of swimming holes 7 adjacent to the right, with the flow, side wall of the through channel 3.

In addition, at the bottom of the through channel 3, along its length, reinforced roughness elements in the form of boulders 8 can be installed.

In addition, vertical elements installed in even transverse rows can be offset with respect to vertical elements installed in odd transverse rows by half the installation step of adjacent vertical elements.

Fish passage works as follows.

The fish attracted from the lower pool enters the inlet head of the fish passage tract 1, where it gradually moves along the through channel 3 towards the upper pool of the waterworks. Due to the installation of vertical reinforced roughness elements in the form of rods 2 at the bottom of the channel of the fish passage tract 1, a significant part of the excess kinetic energy of the water flow is quenched in depth. The implementation of vertical elements of the same height, to the entire depth of the stream, allows you to effectively extinguish the excess kinetic energy of the stream. The implementation of areas free from the installation of rods 2 along the length of the fish passage 1, in the form of a through channel 3, made in plan according to a sinusoidal curve, allows you to simulate a winding river channel and creates optimal conditions for the movement of fish along the fish passage 1.

This arrangement allows flow through the entire live section of the fish passage, as well as optimize the process of quenching the kinetic energy of the water stream. According to the theory of fluid motion, most of the flow will go to the minimum hydraulic resistance - through the through channel 3. However, along the entire path of the through channel 3, the stream flowing through it is affected by masses of water flowing in the installation areas of the rods 2. In addition to active water exchange the flow of the through channel 3 with the flow flowing through the zone of installation of the rods 2, the flow in the fish passage is actively inhibited due to the presence of velocity vectors characterized by different planned angles.

The flexibility of the rods 2 allows them to be cleaned of algae and floating debris, bending under the influence of the stream, in the direction of flow.

A variant of the fish passage operation is possible when the bottom of the through channel 3 is made with a mark below the bottom marker of the fish passage tract 1 (Figs. 4-6), which allows the formation of optimal hydraulic conditions for the promotion of fish living in the bottom horizons of the watercourse. Bottom species of fish (for example, sturgeon) move mainly at the bottom of the through channel 3, where optimal conditions for their movement are created.

In addition, this arrangement allows, due to the interaction of the bottom stream (flowing in the bottom of the through channel 3) and the stream flowing above the bottom mark of the fish passage path 1, also to provide additional quenching of the kinetic energy of the water stream.

A variant of the fish passage operation is possible when the bottom of the through channel 3 is made with a longitudinal slope equal to the longitudinal gradient of the bottom of the fish passage tract 1 (Fig. 8), which is a special case of the fish passage execution.

A variant of the fish passage operation is possible when the bottom of the through channel 3 is made with a longitudinal slope greater than the longitudinal slope of the bottom of the fish passage tract 1 (Fig. 9), which makes it possible to increase the flow rates in the bottom of the through channel 3 and expand the spectrum of the fish attracting speeds.

It is possible to work when the bottom of the through channel 3 is made with a longitudinal slope smaller than the longitudinal slope of the bottom of the fish passage tract 1 (Fig. 10), which reduces the flow rate in the bottom of the through channel 3.

A fish-pass operation option is possible when the bottom of the through channel 3 is made with tapering 4 and expanding 5 sections (Fig. 11), which alternate one after the other, along the length of the through channel 3, which allows you to create diverse gradient sections of the flow for resting fish or for its active advance upstream.

A fish-pass operation option is possible when bottom thresholds 6 are installed along the length of the through channel 3 (FIG. 12, 13), which allows to actively inhibit the bottom layers of the stream and, accordingly, reduce the average flow rate in the through channel 3.

An option is possible for the fish passage when the even bottom thresholds 6 are installed with the formation of swimming holes 7 adjacent to the left, downstream side wall of the through channel 3, and the odd bottom thresholds 6 are installed with the formation of the swimming holes 7 adjacent to the right, downstream the wall of the through channel 3, which is a variant of the layout of the thresholds 6 and the inlet openings 7.

An option is possible for the fish passage, when at the bottom of the through channel 3, along its length, reinforced roughness elements are installed in the form of boulders 8 (Fig. 14), which allows quenching the kinetic energy of the stream using natural material.

A fish-pass operation option is possible when the rods 2 installed in even transverse rows are offset with respect to the rods 2 installed in odd transverse rows by half the installation step of adjacent vertical elements, which makes it possible to form a checkerboard installation of rods 2 (Figs. 4, 7) . With this arrangement, the total hydraulic resistance to the flow flowing through the fish passage increases.

The proposed fish passage allows you to effectively extinguish the kinetic energy of the water stream, and also creates optimal conditions for the movement of migrants in the direction of the upstream.

Information sources

1. USSR author's certificate 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. B.I. No. 6, 1989.

2. Japan Patent No. 2003-171927, "Fishway", Hirakawa Tomoyuki. IPC Е02В 8/08. Publ. 06/20/2003.

3. RF patent № 2013492, "Fish-ship", IPC Е02В 8/08, Author: G. Filippov (THE USSR). Publ. 1994.05.30.

4. RF patent (RU) No. 2263743, “Fish passage channel (options)”, IPC EV 02/08, Chistyakov AA, Shkura V.N., Bull. No. 31, 2005-11-10.

5. Japan Patent No. 09-132909, "Fish ladder", Mizuyama Takahisa, Onoda Tadahiro. IPC Е02В 8/08. Publ. 05/20/1997.

Claims (12)

1. A fish passage, including a fish passage tract, made in the form of a channel, the output head of which is connected to the upper pool of the hydraulic system, and the input head - to the lower pool, vertically mounted elements of enhanced roughness, made in the form of flexible rods, placed in transverse rows at the bottom of the channel along it the length and cantileverly attached to the bottom of the channel, areas free from the installation of vertical elements located in the transverse rows between the vertical elements, characterized in that the vertical elements are made one tical height of the entire depth of the flow, the portions free of vertical installation of elements along the length rybohodnogo tract performed in terms of the sinusoidal curve and form a bore therethrough, simulating meandering river bed. 2. The fish passage according to claim 1, characterized in that the bottom of the through channel is made with a mark below the bottom mark of the fish passage path. 3. Fish passage according to claim 2, characterized in that the bottom of the through channel is made with a longitudinal slope equal to the longitudinal slope of the bottom of the fish passage. 4. The fish passage according to claim 2, characterized in that the bottom of the through channel is made with a longitudinal slope greater than the longitudinal slope of the bottom of the fish passage. 5. The fish passage according to claim 2, characterized in that the bottom of the through channel is made with a longitudinal slope less than the longitudinal slope of the bottom of the fish passage. 6. Fish passage according to any one of paragraphs.2-5, characterized in that the bottom of the through channel is made with tapering and expanding sections that alternate one after another along the length of the through channel. 7. Fish passage according to any one of paragraphs.2-5, characterized in that bottom thresholds are installed at the bottom of the through channel along its length. 8. The fish passage according to claim 7, characterized in that the bottom thresholds are set to the entire width of the through channel. 9. The fish passage according to claim 7, characterized in that the bottom sills are installed with the formation of swimming holes between the side walls of the through channel and the end parts of the bottom sills. 10. The fish passage according to claim 9, characterized in that the even bottom thresholds are set with the formation of swimming holes adjacent to the left downstream side wall of the through channel, and the odd bottom thresholds are established with the formation of the floating holes adjacent to the right downstream side wall of the through channel . 11. Fish passage according to any one of paragraphs.2-5, characterized in that at the bottom of the through channel along the length of the installed elements of enhanced roughness in the form of boulders. 12. Fish passage according to any one of claims 1 to 5, 8 to 10, characterized in that the vertical elements installed in even transverse rows are offset by half the installation step of adjacent vertical elements with respect to vertical elements installed in odd transverse rows.

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