RU2274703C1 - Fish pass - Google Patents

Abstract

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

SUBSTANCE: fish pass comprises tray-like channel, which connects upper and lower hydrosystem pools, flow kinetic energy dissipation device made as jet-forming nozzles arranged in side tray walls and connected with pressure pipeline. Jet-forming nozzle orifices are directed towards main flow running along fish pass channel tray. Fish pass also has swimming-in orifices defined by vertical transversal partitions and provided with additional jet-forming nozzles facing main flow. Outlet orifices of additional jet-forming nozzles and that of main ones are discretely distributed through water layer in tray. Depressions widened in upper pool direction are created in longitudinal plane of outlet orifice location coaxially to jet-forming nozzles. The depressions are shaped as truncated cones. Additional jet-forming nozzles are created on side walls of roughness member arranged in bottom part in longitudinal fish pass channel axis in transversal section defined by vertical transversal partitions and facing swimming-in orifice by obtuse end thereof. Side walls of roughness member extend at acute angle to longitudinal fish pass channel axis.

EFFECT: increased efficiency of fish pass flow regulation.

5 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 fish passage, connecting the lower and upper heads of the waterworks and a system of flow-forming nozzles located along the length of the fish passage, while the outlet openings of the nozzles are oriented towards the main stream flowing along the fish passage channel.

The disadvantage of this structure is the low efficiency of flow control in the fish passage.

Known fish passage [2], including a fish passage, connecting the lower and upper heads of the waterworks and a system of flow-forming nozzles located along the length of the fish passage, while the outlet openings of the nozzles are oriented towards the main stream flowing along the fish passage channel.

The disadvantage of this structure is the complexity of the equipment for controlling the flow in the fish passage.

Known fish passage [3], including a stepped fish passage path, connecting the lower and upper head of the waterworks and a system of flow-forming nozzles located along the length of the fish passage in the bottom of each stage, while the outlet openings of the nozzles are oriented towards the main stream and at an acute angle to it.

The disadvantage of this structure is the complexity of this structure.

Known fish passage [4], including a fish passage path connecting the lower and upper water head of the waterworks and a system of flow-forming nozzles located along the length of the fish passage, while the outlet openings of the nozzles are oriented towards the main stream.

The disadvantage of this structure is the low efficiency.

The closest in technical essence and the achieved result is a fish passage [5], which includes a fish passage path in the form of a tray connecting the lower and upper heads of the hydraulic system, a device for quenching the kinetic energy of the stream, made in the form of a system of flow-forming nozzles located in the side walls of the tray and connected to pressure pipeline, while the outlet openings of the flow-forming nozzles are oriented towards the main stream flowing along the channel of the fish passage tract, the float holes are formed by tical transverse partitions.

The disadvantage of this structure is the low efficiency of flow control in the fish passage.

The aim of the invention is to increase the efficiency of flow control in the fish passage.

The invention consists in the following.

The implementation of the fish passage tract with additional flow-forming nozzles, while additional flow-forming nozzles are made on the side walls of the reinforced roughness element located in the bottom part on the longitudinal axis of the fish passage in the transverse alignment located between the vertical transverse partitions and facing the blunt end towards the swimming hole, while the side walls of the element of enhanced roughness are made at an acute angle to the longitudinal axis of the fish passage tract, allows you to create l additional hydraulic resistance to transit flow. This, in turn, allows you to reduce the total length of the fish passage and increase the efficiency of controlling the flow flowing through the fish passage. The stream flowing from the inlet formed by vertical transverse partitions experiences hydraulic resistance when an element of enhanced roughness runs onto the blunt end, while it loses part of its kinetic energy. At the same time, flow-forming nozzles made on the side walls of the element of enhanced roughness and oriented towards the transit flow create a powerful counter-pressure to the oncoming flow in the near-bottom region. In addition, fish moving upstream have the ability to use the kinetic energy of hydraulic jets to overcome the transverse alignment, in which an element of enhanced roughness is located.

The optimal distribution of additional hydraulic jets in the water stream is facilitated by making their outlets and the outlets of the flow forming nozzles of the main group round and placing them discretely along the depth of the water in the fish passage channel.

In addition, the execution in the longitudinal plane of the placement of the outlet openings coaxially with the flow-forming nozzles expanding in the direction of the upper pool of the recesses, which are in the form of truncated semi-cones, allows you to stabilize the spatial location of the hydraulic jets in the stream, thereby preventing them from tearing away from the side walls of the element of enhanced roughness.

The execution of the lateral walls of the reinforced roughness element at an acute angle to the longitudinal axis of the fish passage allows not only to form the general direction of the hydraulic jets - parallel to the side walls of the reinforced roughness element and against the transit flow, but also to create a fish channel for the fish to move upstream efficiently.

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, plan;

figure 2 - section aa in figure 1;

figure 3 - element of enhanced roughness, isometry;

figure 4 - power system flow-forming nozzles, top view;

5 is a fragment of a cross section of the fish passage tract, a view from the side of the upper pool.

The fish passage includes a fish passage path 1 in the form of a tray connecting the lower and upper heads of the hydraulic system, a device for quenching the kinetic energy of the stream, made in the form of a system of flow-forming nozzles 2 located in the side walls 3 of the tray and connected to the pressure pipe 4, while the outlet openings 5 are flow-forming nozzles 2 are oriented towards the main stream flowing along the channel of the fish passage 1, and the inlet holes 6 are formed by vertical transverse partitions 7.

The fish passage is equipped with additional flow-forming nozzles 8, while their outlet openings 5 and outlet 5 of the flow-forming nozzles 2 of the main group are round and discrete placed in the depth of the water in the tray, while in the longitudinal plane of the placement of the outlet openings 5 coaxially with the flow-forming nozzles 2 are made expanding in the direction downstream of the recess 9, which are in the form of truncated semi-cones, and additional flow-forming nozzles 8 are made on the side walls of the reinforced wool element ocher 10, located in the bottom on the longitudinal axis of the fish passage 1 in a transverse alignment located between the vertical transverse partitions 7, and facing the blunt end towards the swimming hole 6, while the side walls of the element of enhanced roughness 10 are made at an acute angle to the longitudinal axis of the fish passage one.

Fish passage works as follows.

The fish attracted from the lower pool enters the inlet head of the fish passage and enters the fish passage 1, where it gradually overcomes the vertical transverse partitions 7 with inlet openings 6 and moves towards the upper pool of the waterworks, where it enters the outlet head and further into the reservoir.

The presence on the side walls of the element of enhanced roughness 10 additional stream-forming nozzles 8 allows you to create additional hydraulic resistance to the transit flow. This, in turn, allows to reduce the total length of the fish passage 1 and increase the efficiency of controlling the flow flowing through the fish passage. The flow flowing from the inlet 6 formed by the vertical transverse partitions 7 experiences additional hydraulic resistance when a reinforced roughness 10 is incident on the blunt end, while it loses part of its kinetic energy, and a difference in water levels is created in the alignment of the installation of the enhanced roughness 10. At the same time, additional flow-forming nozzles 8, made on the side walls of the reinforced roughness element 10 and oriented towards the transit flow, create a powerful counter-pressure to the oncoming flow in the bottom region. In addition, the fish, moving upstream, has the ability to use the kinetic energy of the hydraulic jets to overcome the transverse alignment, in which there is an element of enhanced roughness 10.

The optimal distribution of additional hydraulic jets in the water stream is facilitated by the execution of their outlet openings 6 and outlet 6 of the flow-forming nozzles 2 of the main group round and placing them discretely along the water depth in the fish passage channel.

In addition, the execution in the longitudinal plane of the placement of the outlet openings 6 coaxially with the flow-forming nozzles 2 and 8 of the recesses 9 expanding in the direction of the upper pool, which have the shape of truncated semi-cones, makes it possible to stabilize the spatial location of the hydraulic jets in the flow, thereby preventing them from tearing themselves away from the side walls 3 the fish pass channel tray 1 and the elements of enhanced roughness 10.

The execution of the lateral walls of the element of enhanced roughness 10 at an acute angle to the longitudinal axis of the fish passage 1 allows not only to form the general direction of the hydraulic jets - parallel to its side walls and against the transit flow, but also to create a fish guide channel for the fish to move upstream efficiently.

The arrangement, in which the elements of reinforced roughness 10 are placed in transverse sections between the vertical transverse partitions 7 and opposite the inlet hole 6, allows you to create maximum hydraulic resistance to the transit flow. In addition, hydraulic jets created by additional flow-forming nozzles 8 actively eject the fluid flow to be connected and transport it inside the inlet hole 6, directly behind the vertical transverse partition 7. This scheme increases the hydraulic resistance to the transit flow, since the bottom hydraulic jets and vertical transverse partitions 7 work to increase the overall hydraulic resistance.

Hydraulic jets created by the flow-forming nozzles 2 located on the side walls 3 of the fish passage tract 1 in the surface horizon of the flow (2 and 5) contribute to the formation of the general hydraulic resistance. Hydraulic jets flowing from the flow-forming nozzles 2 provide counter pressure to the transit flow in the surface horizon of the flow and, thereby, contribute to the formation of the total hydraulic resistance and to the flow control process in the fish passage.

Information sources

1. A.S. USSR No. 60371, "Fish-ship", IPC E 02 B 8/08, G. Lompo-Trofimov, 1941-01-01.

2. Swiss patent No. 77885, "Fischtreppe", IPC E 02 B 8/08, Gotlieb Luscher, 1918-06-01.

3. A.S. USSR No. 10600750, "Fish-pass", IPC E 02 B 8/08, Avdonkin A.F., Shatalov I.M., B.I. No. 46, 1983-12-15.

4. A.S. USSR No. 1808903, "Fish passage", IPC E 02 B 8/08, Ternovsky V.V., B.I. No. 14, 1993-04-15.

5. German patent No. 309506, "Fischtreppe", IPC E 02 B 8/08, Gotlieb Luscher, 1918-11-29.

Claims (1)

Fish passage, including a fish passage path in the form of a tray connecting the lower and upper heads of the hydraulic system, a device for quenching the kinetic energy of the flow, made in the form of a system of flow-forming nozzles located in the side walls of the tray and connected to the pressure pipe, while the outlet openings of the flow-forming nozzles are oriented towards the main the flow flowing along the channel of the fish passage tract, swimming holes formed by vertical transverse partitions, characterized in that it is provided with an additional body-forming flow-forming nozzles oriented toward the main stream, while their outlet openings and outlet openings of the flow-forming nozzles of the main group are round and discrete placed in the depth of the water in the tray, while in the longitudinal plane of the placement of the outlet openings, the depressions expanding in the direction of the upper pool coaxially with the flow-forming nozzles are made , which have the shape of truncated half-cones, and additional flow-forming nozzles are made on the side walls of the elements Enhanced roughness and placed at the bottom on the longitudinal axis of the tract rybohodnogo alignment transversely located between the vertical transverse partitions, and a blunt end facing towards vplyvnomu opening, wherein the side wall member of enhanced roughness formed at an acute angle to the longitudinal axis rybohodnogo tract.

Images