RU2280733C1 - Fish pass (variants) - Google Patents

Abstract

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

SUBSTANCE: fish passage comprises waterway shaped as canal and having head part connected to upper pool of hydrosystem and mouth part communicated with lower pool thereof. Arranged on canal bottom are rough members, which are distributed along canal length. The fish pass also comprises additional through course connected with water supply course. Head part of additional course is independent and arranged upstream of head part of water supply course so that multi-head inlet head is created. The fish pass includes hatchery substrate formed as gravel-and-pebble filler. Additional through course has length equal to that of water supply course and is communicated with water supply course by means of connecting units formed by intersecting of additional through and water supply courses angularly related to each other to create closed sections. Head part of additional through course is parallel to head part of water supply course. Fish pass in accordance with the second embodiment comprises additional through course, which intersects water supply course in connection unit area. The connection unit area is defined by intersection of additional and water supply courses angularly related to each other and creating closed sections. Additional through course in connection unit area is formed as tray. Water supply course bottom in area of two courses intersection is of plunging type so that additional through course of waterway orifice is created under the tray.

EFFECT: provision of highly-efficient hydraulic conditions for fish passage due to damping of kinetic energy.

17 cl, 21 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 output head of which is connected to the upper pool of the hydraulic system, and the input head is connected to the lower pool, elements of enhanced roughness made in the form of parallelepipeds installed on the bottom of the channel along its length at an acute angle to the longitudinal axis of the channel, and additional flow paths, the input and output parts of which are connected to the water supply path.

The disadvantage of this structure is the low efficiency of quenching the kinetic energy of the water stream and the irrational use of additional water flow.

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 of which is connected to the upper pool of the waterworks, and the wellhead part - to the lower pool, reinforced roughness elements installed at the bottom the channel along its length, an additional flow path connected to the water supply path, and its mouth part is autonomous and located upstream of the mouth part of the water path, forming a lot the head entrance head and spawning substrate in the form of gravel and pebble bedding.

The disadvantage of this structure is the low efficiency of quenching the kinetic energy of the water stream.

The closest in technical essence and the achieved result for the option is a fish-spawning channel [2], including a water supply path made in the form of a channel, the head of which is connected to the upper pool of the waterworks, and the mouth part to the lower pool, elements of enhanced roughness, installed at the bottom of the channel along its length, an additional flow path, the estuarine part of which is autonomous and located upstream of the estuary part of the water supply path, forming a multi-headed inlet head, and spawning substrate in the form of gravel-pebble gravel.

The disadvantage of this structure is the low efficiency of quenching the kinetic energy of the water stream.

The aim of the invention is the creation of effective hydraulic conditions in the fish passage channel and its variant for damping the kinetic energy of the water stream.

The invention consists in the following.

According to claim 1 of the claims. The implementation of the additional flow path with a length equal to the length of the water path, while it communicates with the water path through the mating nodes formed by crossing at an angle to each other the additional flow path and the water path, allows you to create a new planned layout of the fish passage path. In this embodiment, when two flows (the additional flow path and the water supply path) merge (collide), directly in the area where the mating nodes are located, intense extinguishing of the excess kinetic energy of the flow occurs, while the energy of the colliding flows is used.

The implementation of the head of the additional flow path parallel to the head of the water supply path allows you to get the layout of a multi-headed output head.

According to claim 2 of the claims. The execution of the closed area is flooded (Fig. 10), while a spawning substrate is placed on its area, and it allows forming sections for fish spawning along the length of the fish passage channel. In addition, in this arrangement, a cross section of a channel of the channel-floodplain-channel type is formed, which helps to reduce the average flow rate. In addition, a hydraulic phenomenon, called the kinematic effect of the interaction of pressureless flows of the channel and floodplain parts of the channel cross section (the kinematic effect of G.V.Zheleznyakov), contributes to the suppression of excess flow energy. During the interaction of the streams of the channel and floodplain parts in the channel, a significant decrease in the average and surface flow velocities in the channel is observed under the influence of the floodplain flow, at the same time, as a rule, a slight increase in the velocities is observed in the riverbed compartment of the flow of the floodplain.

According to claim 3 of the claims. The execution of the closed area is flooded, while the spawning substrate is placed on its area in the form of gravel-pebble gravel bedding, while the side walls of the additional flowing and water supply paths adjacent to the closed area are made with swimming holes (Figs. 8 and 9), it allows the formation of spawning field with adjustable water flow rates. The presence of swimming holes, their size and placement govern the hydraulic regime in the spawning field, while the flow rates inside the closed section have lower values.

According to claim 4 of the claims. The execution of the closed section with additional fish passage channels and with additional mating nodes formed by crossing the additional fish passage channels at an angle to each other, while the head part of one fish passage channel is connected to the water supply path, and its wellhead part to the additional flow path, and the head part another fish passage channel is connected by an additional flow path, and its wellhead part - with a water supply path (Figs. 11 and 12), allows migrants to freely change move from the water path to the additional flow path. Thus, both tracts form a single system for the passage and spawning of fish.

According to claim 5, claims. The implementation of the head parts of the additional flow and water paths, combined with each other and separated by a longitudinal wall (Fig.13), allows you to get a multi-headed output head that provides fish exit in one transverse section of the upper pool.

According to claim 6, claims. The implementation of the estuarine parts of the additional flow and water paths, combined with each other and separated by a longitudinal wall (Fig. 19), allows you to get a multi-headed inlet head, characterized by a more powerful fish attracting stream.

According to claim 7 of the claims. The implementation of the head and estuarine parts of the additional flow and water paths, combined with each other and separated by longitudinal walls (Fig.20), allows you to get the layout of the multi-headed inlet and outlet heads of the fish passage channel.

According to claim 8 of the claims. The implementation of the additional flow and water paths along their length, made with tapering and expanding sections, which alternate one after another, and the tapering sections have a depth greater than the depth of the expanding sections, allows you to form a bottom along the length of the additional flow and water paths with stretches and rifts (Fig.17 and 18). This bottom layout is closest in shape to the shape of the river bed bottom.

In addition, this bottom shape of the two tracts contributes to an increase in the overall hydraulic resistance to the water flow and makes it possible to obtain a smaller fish passage channel layout. In addition, reaches and rapids allow bottom fish (for example, sturgeon) to more effectively overcome the fish passage tract.

According to claim 9, the claims. The implementation of the additional flow path along its length with tapering and expanding sections that alternate one after another, while the tapering sections have a depth greater than the depth of the expanding sections, while along the length of the additional flow path a bottom is formed with stretches and rifts, allows you to form flow path at a lower speed than the flow in the water path. This moment allows weak and weakened fish to effectively move in the direction of the upper pool. In addition, reaches and rapids allow bottom fish (for example, sturgeon) to more effectively overcome the fish passage tract.

According to claim 10 of the claims. The implementation of the water supply path along its length with tapering and expanding sections that alternate one after another, and the tapering sections have a depth greater than the depth of the expanding sections, while along the length of the water supply path a bottom is formed with stretches and rifts, allows you to form a flow in the water path lower speeds than the flow in the additional flow path. This moment allows weak and weakened fish to effectively move in the direction of the upper pool. In addition, reaches and rapids allow bottom fish (for example, sturgeon) to more effectively overcome the fish passage tract.

According to claim 11, the claims. Alternatively, the planned layout of the routes of the additional flow path and the water path, in the area of the mating nodes, can be performed differently. An additional flow path in the area of the mating nodes is made in the form of a tray, while the bottom of the water supply path, at the intersection of two paths, is made diving with the formation of an additional flow path of a bottom culvert under the tray. This allows you to avoid directly the collision of the two streams and create normal conditions for the passage of fish through an additional flow path. However, the presence of the design of the tray in the mating unit also contributes to the partial quenching of the kinetic energy of the water stream flowing through the water supply path, since this stream is extinguished in the surface horizons upon contact with the side wall of the tray. At the same time, to pass the main water flow rate, the bottom of the water supply path, under the tray of the additional flow path, is made diving with the formation of a bottom culvert.

According to paragraph 12 of the claims. The execution of the closed area is flooded (Fig. 10), while a spawning substrate is placed on its area, and it allows forming sections for fish spawning along the length of the fish passage channel. In addition, in this arrangement, a cross section of a channel of the channel-floodplain-channel type is formed, which helps to reduce the average flow rate. In addition, a hydraulic phenomenon, called the kinematic effect of the interaction of pressureless flows of the channel and floodplain parts of the channel cross section (the kinematic effect of G.V.Zheleznyakov), contributes to the suppression of excess flow energy. During the interaction of the streams of the channel and floodplain parts in the channel, a significant decrease in the average and surface flow velocities in the channel is observed under the influence of the floodplain flow, at the same time, as a rule, a slight increase in the velocities is observed in the riverbed compartment of the flow of the floodplain.

According to item 13 of the claims. The execution of the enclosed area is flooded, while a spawning substrate is placed on its area, and the side walls of the additional flowing and water supply paths adjacent to the enclosed area are made with inlet openings (Figs. 8 and 9), it allows the formation of a spawning field with adjustable water flow rates. The presence of swimming holes, their size and placement govern the hydraulic regime in the spawning field, while the flow rates inside the closed section have lower values.

According to claim 14. The execution of the closed section with additional fish passage channels and with additional mating nodes formed by crossing the additional fish passage channels at an angle to each other, while the head part of one fish passage channel is connected to the water supply path, and its wellhead part to the additional flow path, and the head part another fish passage channel is connected by an additional flow path, and its wellhead part - with a water supply path (Figs. 11 and 12), allows migrants to freely change move from the water path to the additional flow path. Thus, both tracts form a single system for the passage and spawning of fish.

According to clause 15 of the claims. The implementation of the additional flow and water paths along their length, made with tapering and expanding sections, which alternate one after another, and the tapering sections have a depth greater than the depth of the expanding sections, allows you to form a bottom along the length of the additional flow and water paths with stretches and rifts (Fig.17 and 18). This bottom layout is closest in shape to the shape of the river bed bottom. In addition, this bottom shape of the two tracts contributes to an increase in the overall hydraulic resistance to the water flow and makes it possible to obtain a smaller fish passage channel layout. In addition, reaches and rapids allow bottom fish (for example, sturgeon) to more effectively overcome the fish passage tract.

According to clause 16 of the claims. The implementation of the additional flow path along its length with tapering and expanding sections that alternate one after another, while the tapering sections have a depth greater than the depth of the expanding sections, while along the length of the additional flow path a bottom is formed with stretches and rifts, allows you to form flow path at a lower speed than the flow in the water path. This moment allows weak and weakened fish to effectively move in the direction of the upper pool. In addition, reaches and rapids allow bottom fish (for example, sturgeon) to more effectively overcome the fish passage tract.

According to claim 17. The implementation of the water supply path along its length with tapering and expanding sections, which alternate one after another, and the tapering sections have a depth greater than the depth of the expanding sections, while along the length of the water supply path a bottom with stretches and rifts is formed, allows you to form a flow in the water supply path with lower speeds than the flow in the additional flow path. This moment allows weak and weakened fish to effectively move in the direction of the upper pool. In addition, reaches and rapids allow bottom fish (for example, sturgeon) to more effectively overcome the fish passage tract.

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

figure 1 - fish passage channel plan;

figure 2 is a fragment of the fish passage channel, plan, sections of the interface;

figure 3 is a longitudinal section of the water path, the interface;

figure 4 is a longitudinal section of an additional flow path, the interface;

figure 5 - node a in figure 2, isometry;

6 is a node B in figure 2, plan;

Fig.7 is a section bb In Fig.6;

Fig. 8 is a flooded enclosed area bounded by the side walls of the water supply and additional flow path, a variant with inlet openings;

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

figure 10 is a cross section of a flooded enclosed area;

11 is a closed section of the option with additional fish passage channels;

Fig - section DD in Fig.11;

Fig. 13 is a variant of a fish passage channel with combined warheads of an additional flow and water paths, plan;

Fig. 14 is a longitudinal section through a water path, an interface, an embodiment with a bottom culvert;

Fig - section EE in Fig;

Fig.16 is a section FJ in Fig.14;

Fig - an embodiment of the bottom of the channel in the form of rifts and reaches, longitudinal section;

Fig. 18 is the same plan;

Fig. 19 is a variant of a fish passage channel with combined wellhead parts of an additional flow and water paths, plan;

Fig. 20 is a variant of a fish passage channel with combined head and wellhead parts of an additional flowing and water supply paths, plan;

Fig.21 is a section ZZ in Fig.20.

The fish passage channel includes a water supply path 1 made in the form of a channel, the head 2 of which is connected to the upper 3 downstream of the hydraulic system, and the wellhead 4 part to the lower 5 downstream, reinforced roughness elements 6 installed along the channel bottom along its length, an additional flow path 7 connected to the water supply path 1, and its wellhead 4 part is autonomous and located upstream of the wellhead 4 part of the water path 1, forming a multi-headed inlet head, and spawning substrate 8 in the form of gravel-pebble tsypki.

The additional flow path 7 is made with a length equal to the length of the water path 1, and it is in communication with the water path 1 through the mating nodes 9 formed by crossing at an angle to each other the additional flow path 7 and the water path 1 to form closed sections 10, and the head 2 part of the additional flow path 7 is made parallel to the head 2 of the water supply path 1.

In addition, the closed section 10 can be made flooded, while spawning substrate 8 is placed on its area.

In addition, the closed section 10 can be flooded, while a spawning substrate is placed on its area, and the side walls of the additional flowing 7 and water supply paths 1 adjacent to the closed section 10 are made with inlet holes 11.

In addition, the closed section 10 can be made with additional fish passage channels 12 and with additional mating nodes 13 formed by crossing additional fish passage channels 12 at an angle to each other, while the head of one fish passage channel 12 is connected to the water supply path 1, and wellhead part - with an additional flow path 7, and the head part of another fish passage channel 12 is connected to an additional flow path 7, and its well part - with a water path 1.

In addition, the head 2 parts of the additional flowing 7 and water-conducting 1 paths can be combined with each other and separated by a longitudinal wall 14.

In addition, the wellhead 4 parts of the additional flowing 7 and water-conducting 1 paths can be combined with each other and separated by a longitudinal wall 14.

In addition, the head 2 and wellhead 4 parts of the additional flow-through 7 and water-conducting 1 paths can be combined with each other and separated by longitudinal walls 14.

In addition, the additional flowing 7 and water-conducting 1 tracts along their length can be made with tapering 15 and expanding 16 sections that alternate one after another, and tapering 15 sections have a depth greater than the depth of the expanding 16 sections, while along the length of the additional flowing 7 and the water supplying 1 tracts the bottom is formed with reaches and rifts.

In addition, the additional flow path 7 along its length can be made with tapering 15 and expanding 16 sections that alternate one after another, and tapering 15 sections have a depth greater than the depth of the expanding 16 sections, while along the length of the additional flow path 7 is formed bottom with stretches and rifts.

In addition, the water supply path 1 along its length can be made with tapering 15 and expanding 16 sections that alternate one after another, and the tapering 15 sections have a depth greater than the depth of the expanding 16 sections, while along the length of the water supply path 1 a bottom is formed with stretches and rifts.

According to a variant, the fish passage channel includes a water supply path 1 made in the form of a channel, the head 2 of which is connected to the upper 3 downstream of the hydraulic system, and the wellhead 4 part is connected to the lower 5 downstream, reinforced roughness elements 6 installed on the bottom of the channel along its length, additional a flow path 7, the wellhead 4 of which is autonomous and located upstream of the wellhead 4 of the water supply path 1, forming a multi-headed inlet head, and spawning substrate 8 in the form of gravel-pebble gravel.

The additional flow path 7 is made with a length equal to the length of the water path 1, and it crosses the path of the water path 1 in the area of the mating nodes 9, formed by crossing at an angle to each other the additional flow 7 and water path 1 with the formation of closed sections 10, while the head 2 part of the additional flow path 7 is made parallel to the head 2 part of the water supply path 1, and the additional flow path 7 in the region of the mating nodes 9 is made in the form of a tray 17, with that the bottom of the water-path 1 at the intersection of the two paths 1 and 7 diving performed to form a chute 17 additional flow path 7 of the bottom opening 18 of pipe.

In addition, the closed section 10 can be made flooded, while spawning substrate 8 is placed on its area.

In addition, the closed section 10 can be flooded, while spawning substrate 8 is placed on its area, and the side walls of the additional flowing 7 and water supply paths 1 adjacent to the closed section 10 are made with inlet holes 11.

In addition, the closed section 10 can be made with additional fish passage channels 12 and with additional mating nodes 13 formed by crossing additional fish passage channels 12 at an angle to each other, while the head of one fish passage channel 12 is connected to the water supply path 1, and wellhead part - with an additional flow path 7, and the head part of another fish passage channel 12 is connected to an additional flow path 7, and its well part - with a water path 1.

In addition, the additional flowing 7 and water-conducting 1 tracts along their length can be made with tapering 15 and expanding 16 sections that alternate one after another, and tapering 15 sections have a depth greater than the depth of the expanding 16 sections, while along the length of the additional flowing 7 and the water supplying 1 tracts the bottom is formed with reaches and rifts.

In addition, the additional flow path 7 along its length can be made with tapering 15 and expanding 16 sections that alternate one after another, and the tapering 15 sections have a depth greater than the depth of the expanding 16 sections, while along the length of the additional flow path 7 is formed bottom with stretches and rifts.

In addition, the water supply path 1 along its length can be made with tapering 15 and expanding 16 sections, which alternate one after another, and the tapering 15 sections have a depth greater than the depth of the expanding 16 sections, while a bottom is formed along the length of the water supply path 1 stretches and rifts.

Fish passage channel works as follows.

The attraction of fish from the downstream 5 to the wellhead 4 of the water supply path 1 and the additional flow path 7 is carried out by supplying the working flow from the upper tail 3. Due to their layout (Fig. 1), paths 1 and 7 at their intersections form mating nodes 9 and simultaneously in the gaps between the mating nodes 9 are closed sections 10. In the mating nodes 9, the water flows of the paths 1 and 7 collide with each other, while the active process of extinguishing the excess kinetic energy of the flow and accordingly creating A locally backwater level. The merger of the two streams in the mating nodes 9 occurs at an angle of 90 degrees, which is the most effective scheme for quenching flows in the confluence zone.

Alternatively, the additional flow path 7 in the region of the mating nodes 9 can be made in the form of a tray 17, while the bottom of the water supply path 1 at the intersection of two paths 1 and 7 can be made diving with the formation of an additional flow path 7 of the bottom culvert under the tray 17 18. This allows you to avoid directly the collision of the two streams and create normal conditions for the passage of fish along the additional flow path 7. However, the presence of the design of the tray 17 in the mating node 9 also contributes to by quenching the kinetic energy of the water stream flowing through the water supply path 1, since this flow in the surface horizons is extinguished upon contact with the side wall of the tray 17. At the same time, to pass the main water flow, the bottom of the water supply path 1 under the tray 17 of the additional flow path 7 is diving with the formation of a bottom culvert holes 18 (Fig.14 and 15).

The lengths of the paths 1 and 7 are elements of enhanced roughness 6 (6), which contribute to the extinction of the kinetic energy of the flow in the bottom horizons.

It is possible that the closed section 10 is flooded (Fig. 10), while spawning substrate 8 is placed on its area, which allows forming sections for fish spawning along the length of the fish passage channel. In addition, in this arrangement, a channel-like-floodplain-channel-like channel cross section is formed, which contributes to a decrease in the average flow rate due to the manifestation of a hydraulic phenomenon called the kinematic effect of the interaction of pressureless flow of the channel and floodplain parts of the channel cross-section. During the interaction of the streams of the channel and floodplain parts in the channel, a significant decrease in the average and surface flow velocities in the channel is observed under the influence of the floodplain flow, at the same time, as a rule, a slight increase in the velocities is observed in the riverbed compartment of the flow of the floodplain.

A possible embodiment of the closed section 10 is flooded, while spawning substrate 8 is also placed on its area in the form of gravel and pebble bedding, while the side walls of the additional flowing 7 and water supplying 1 tracts adjacent to the closed section 10 are made with inlet holes 11 (Fig. .8 and 9), which allows the formation of a spawning field with adjustable water flow rates. The presence of the float holes 11, their sizes and planned placement govern the hydraulic regime in the spawning field, while the flow rates inside the closed section 10 will have lower values than in the case of a simply flooded section 10 (Fig. 10).

A possible embodiment of the closed section 10 with additional fish passage channels 12 and with additional mating nodes 13 formed by crossing additional fish passage channels 12 at an angle to each other, while the head part of one fish passage channel 12 is connected to the water supply path 1, and its wellhead part with an additional flow path 7, and the head part of another fish passage channel 12 is connected by an additional flow path 7, and its wellhead part is connected to the water supply path 1 (Figs. 11 and 12), which allows migrants to move freely from the water supply path 1 to the additional flow path 7 and vice versa. Thus, both tracts 1 and 7 form a single system for the passage of fish into the upper 3 pool of the waterworks.

A possible embodiment of the head 2 parts of the additional flowing 7 and water supplying 1 paths combined with each other and separated by a longitudinal wall 14 (Fig.13), which allows to obtain a multi-headed output head that provides fish exit in one transverse section of the upper 3 of the pool.

A possible embodiment of the wellhead 4 parts of the additional flowing 7 and water supplying 1 paths combined with each other and separated by a longitudinal wall 14 (Fig. 19), which makes it possible to obtain a multi-headed inlet head characterized by a more powerful fish attracting stream.

A possible embodiment of the head 2 and wellhead 4 parts of the additional flowing 7 and water-conducting 1 paths combined with each other and separated by longitudinal walls 14 (Fig. 20), which makes it possible to obtain a layout option for the multi-headed inlet and outlet ends of the fish passage channel.

A possible embodiment of an additional flow-through 7 and water-conducting 1 paths, along their length, made with tapering 15 and expanding 16, which alternate one after another, while tapering 15 sections have a depth greater than the depth of the expanding 16 sections, which allows you to form along the length additional flowing 7 and water-conducting 1 tracts with bottoms and rifts (Fig.17 and 18). This bottom layout is closest in shape to the shape of the river bed bottom. In addition, this bottom shape of the two paths 1 and 7 contributes to an increase in the total hydraulic resistance to the water flow and allows to obtain a smaller fish passage channel layout. In addition, reaches and rifts allow bottom fish (for example, sturgeon) to more effectively overcome the fish passage channel.

A possible embodiment of the additional flow path 7 along its length with tapering 15 and expanding 16, which alternate one after another, while the tapering 15 sections have a depth greater than the depth of the expanding 16 sections, and along the length of the additional flow 7 path a bottom is formed with reaches and rifts, which allows you to form a stream in the additional flow path 7 at lower speeds than the flow in the water supply path 1. This moment allows weak and weakened fish to effectively move in the direction 3 lenii upper pond. In addition, reaches and rifts allow bottom fish (for example, sturgeon) to more effectively overcome the fish passage channel.

A possible embodiment of the water supply path 1 along the entire length with tapering 15 and widening 16 in width sections that alternate one after another, while the tapering 15 sections have a depth greater than the depth of the expanding 16 sections, and a bottom is formed along the length of the water supply 1 path with stretches and rifts, which allows you to form a stream in the water supply path 1 at lower speeds than the flow in the additional flow path 7. This moment allows weak and weakened fish to effectively move in the direction of the upper 3 reach. In addition, reaches and rifts allow bottom fish (for example, sturgeon) to more effectively overcome the fish passage channel.

The proposed fish passage channel allows providing stable and effective conditions for the formation of a fish attracting stream, effective conditions for damping the excess kinetic energy of the water stream, as well as optimal conditions for the passage of fish into the upper pool of the waterworks. In addition, for the first time in the practice of designing fish passage and fish passage and spawning canals, the additional fish passage tract combines the functions of an additional power supply and a quencher of excess kinetic energy of the water stream.

Information sources

1. USSR author's certificate No. 1666633, "Fish passage and spawning canal", IPC E 02 B 8/08, Shkura V.N., Chistyakov A.A., Novoydarsky A.V., Anokhin A.M. and Cherkasov V.A. (THE USSR). Publ. BI No. 28, 1991.

2. RF patent No. 2233363, "Fishery and spawning channel", IPC E 02 B 8/08, Chistyakov A.An., Shkura V.N., Anokhin A.M., Chemikosova E.A., Chistyakov A.A. . Publ. 07/27/2004.

Claims (17)

1. Fish passage 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 - to the lower pool, reinforced roughness elements installed along the channel bottom along its length, an additional flow path connected to the water supply tract, and its estuarine part is autonomous and located upstream of the estuarine part of the water supply path, forming a multi-headed inlet head, and a spawning substrate in the form of gravel-pebble bedding, from characterized in that the additional flow path is made equal to the length of the water path, and it is connected to the water path through mating nodes formed by crossing at an angle to each other the additional flow and water paths with the formation of closed sections, and the head of the additional flow path parallel to the head of the water path. 2. The channel according to claim 1, characterized in that the closed area is made flooded, while a spawning substrate is placed on its area. 3. The channel according to claim 1, characterized in that the closed section is made flooded, while a spawning substrate is placed on its area, and the side walls of the additional flowing and water supply paths adjacent to the closed section are made with inlet openings. 4. The channel according to claim 1, characterized in that the closed section is made with additional fish passage channels and with additional mating nodes formed by crossing additional fish passage channels at an angle to each other, while the head of one fish passage channel is connected to the water supply path, and its wellhead part has an additional flow path, the head part of another fish passage channel being connected to the additional flow path, and its mouth part is connected to the water supply path. 5. The channel according to claim 1, characterized in that the head parts of the additional flow and water paths are combined with each other and separated by a longitudinal wall. 6. The channel according to claim 1, characterized in that the wellhead of the additional flow and water paths are combined with each other and separated by a longitudinal wall. 7. The channel according to claim 1, characterized in that the head and mouth parts of the additional flow and water paths are combined with each other and separated by longitudinal walls. 8. The channel according to any one of claims 1, 5-7, characterized in that the additional flow and water paths along their length are made with tapering and expanding sections that alternate one after another, and the tapering sections have a depth greater than the depth of the expanding sections along with the length of the additional flowing and water-conducting paths, a bottom is formed with reaches and rifts. 9. The channel according to any one of claims 1, 5-7, characterized in that the additional flow path along its length is made with tapering and expanding sections that alternate one after another, and the tapering sections have a depth greater than the depth of the expanding sections, this along the length of the additional flow path formed the bottom with reaches and rifts. 10. The channel according to any one of claims 1, 5-7, characterized in that the water supply path along its length is made with tapering and expanding sections that alternate one after another, and the tapering sections have a depth greater than the depth of the expanding sections, while along the length of the water supply path, a bottom is formed with reaches and rifts. 11. A fish passage channel, including a water supply channel 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 along the channel bottom along its length, an additional flow path, the mouth part of which made autonomous and located upstream of the estuarine part of the water supply path, forming a multi-headed inlet head, and a spawning substrate in the form of gravel-pebble bedding, characterized in that the additional prot the intramural tract is made in length equal to the length of the water supply path, and it crosses the water supply path in the area of the mating nodes formed by crossing at an angle to each other the additional flow and water paths with the formation of closed sections, while the head part of the additional flow path is made parallel to the head part water path, and an additional flow path in the area of the mating nodes is made in the form of a tray, while the bottom of the water path in places The intersection of the two paths is made diving with the formation under the tray of an additional flow path of the bottom culvert. 12. The channel according to claim 11, characterized in that the closed area is made flooded, while a spawning substrate is placed on its area. 13. The channel according to claim 11, characterized in that the closed section is made flooded, while a spawning substrate is placed on its area, and the side walls of the additional flowing and water supply paths adjacent to the closed section are made with inlet openings. 14. The channel according to claim 11, characterized in that the closed section is made with additional fish passage channels and with additional mating nodes formed by crossing additional fish passage channels at an angle to each other, while the head of one fish passage channel is connected to the water supply path, and its wellhead part has an additional flow path, the head part of another fish passage channel being connected to the additional flow path, and its mouth part is connected to the water supply path. 15. The channel according to claim 11, characterized in that the additional flow and water paths along their length are made with tapering and expanding sections that alternate one after another, and the tapering sections have a depth greater than the depth of the expanding sections, while along the length of the additional flowing and water-conducting paths formed the bottom with reaches and rifts. 16. The channel according to claim 11, characterized in that the additional flow path along its length is made with tapering and expanding sections that alternate one after another, and the tapering sections have a depth greater than the depth of the expanding sections, while along the length of the additional flow path formed bottom with stretches and rifts. 17. The channel according to claim 11, characterized in that the water supply path along its length is made with tapering and expanding sections that alternate one after another, and the tapering sections have a depth greater than the depth of the expanding sections, while a bottom is formed along the length of the water path with stretches and rifts.

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