RU2318091C1 - Fish-protective device of water intake structure - Google Patents

Abstract

FIELD: hydraulic building, particularly fish-protective structures included in water intakes.

SUBSTANCE: fish-protective structure comprises suction pipe arranged in water stream and connected to sucking line of pump, filtering screen coaxial to suction pipe and water washing means installed at filtering screen top and coaxial thereto. Filtering screen is made as truncated cone having major base arranged from suction pipe side. Water washing means may rotate about horizontal axis and is connected to pressure line of pump through supply pipeline. Water washing means has main and additional nozzles. Main nozzles are formed on water washing means chamber and arranged from outer side of filtering screen so that outlet orifices thereof face truncated cone base. Additional nozzles are arranged in plane transversal to filtering screen axis and are connected to outer surface of water washing means chamber so that additional nozzles are inclined with respect thereto. Outlet orifices of additional nozzles are unidirectionally oriented. Flow directing members are arranged inside filtering screen so that they are coaxial thereto and distributed along filtering screen length. Outer edges of flow directing members adjoin inner filtering screen surface and create water intake sections defined between flow directing members. The flow directing members are made as truncated cones having major bases facing filtering screen top. Water conveyance path is made as pipe and is coaxial to suction pipe and filtering screen. The pipe connects water-intake sections with suction pipe. Minor bases of truncated cones defined by flow directing members adjoin water conveyance path. Water intake orifices of suction pipe are made inside filtering screens and are distributed along length thereof. Water conveyance path is made as independent coaxially arranged pipes, which form annular water intake orifices of suction pipe in-between. End parts of independent coaxial pipes are inserted inside suction pipe. Beginning parts thereof are rigidly connected to minor bases of truncated cones of flow directing members.

EFFECT: increased fish-protective efficiency due to improved filtering rate field distribution over filtering screen surface.

16 cl, 23 dwg

Description

The invention relates to hydraulic engineering, namely to fish protection devices and structures arranged as part of water intake structures.

Known fish protection device of the water intake structure [1], including a suction pipe located in the water stream and connected to the suction pipe of the pump, a filter screen in the form of a truncated cone, located coaxially with the suction pipe, while the larger base of the truncated cone is located on the side of the suction pipe, a hydraulic washer installed at the top of the filter screen, coaxially, moreover, the hydraulic washer is connected by a supply pipe to the pressure line of the pump, equipped with basic and additional bubbled nozzles which are provided at gidrosmyvatelya chamber and arranged on the outside of the filter screen, while their outlet openings are oriented at different angles towards the base of the truncated cone potokonapravlyayuschie elements arranged within the filter screen, coaxial to it.

The disadvantage of this device is the low efficiency of fish protection.

Known fish protection device of the water intake structure [2], including a suction pipe located in the water stream and connected to the suction pipe of the pump, a filter screen in the form of a truncated cone, located coaxially with the suction pipe, while the larger base of the truncated cone is located on the side of the suction pipe, a hydraulic washer installed at the top of the filter screen, coaxially, moreover, the hydraulic washer is connected by a supply pipe to the pressure line of the pump and is equipped with nozzles that are made They are located on the chamber of the hydraulic washer and are located on the outside of the filter screen, and their outlet openings are oriented towards the base of the truncated cone, a water supply path in the form of a pipe located coaxially with the suction pipe and the filter screen connecting the water intake sections with the suction pipe, water intake openings of the suction pipe, made inside the filter screen and distributed along its length.

The disadvantage of this device is the low efficiency of fish protection.

Known fish protection device of the water intake structure [3], including a suction pipe located in the water stream and connected to the suction pipe of the pump, a filter screen in the form of a truncated cone, located coaxially with the suction pipe, while the larger base of the truncated cone is located on the side of the suction pipe, a hydraulic washer installed at the top of the filter screen, aligned with it, and the hydraulic washer is connected by a supply pipe to the pressure line of the pump and equipped with nozzles that you are filled on the chamber of the hydraulic washer and are located on the outside of the filter screen, and their outlet openings are oriented towards the base of the truncated cone, flow guiding elements placed inside the filter screen, aligned with it and located along its length, while their outer edges are adjacent to the inner surface of the filter screen and form water intake sections located in the gaps between the flow guiding elements made in the form of truncated cones facing with smaller bases to the top of the fil an exhaust screen, a water supply path in the form of a pipe located coaxially with the suction pipe and a filter screen connecting the water intake sections to the suction pipe, the small bases of the truncated cones of the flow guiding elements adjacent to the water supply channel, the water intake openings of the suction pipe made inside the filter screen and distributed .

The disadvantage of this device is the low efficiency of fish protection.

Known fish protection device of the water intake structure [4], including a suction pipe located in the water stream and connected to the suction pipe of the pump, a filter screen in the form of a truncated cone, located coaxially with the suction pipe, while the larger base of the truncated cone is located on the side of the suction pipe, a hydraulic washer installed at the top of the filter screen, aligned with it, and the hydraulic washer is connected by a supply pipe to the pressure line of the pump and equipped with nozzles that you filled on the chamber of the hydraulic washer and located on the outside of the filter screen, and their outlet openings are oriented towards the base of the truncated cone, flow guiding elements located inside the filter screen and located along its length, while their outer edges are adjacent to the inner surface of the filter screen and form water intake sections placed in between the flow guiding elements, a water supply path in the form of a pipe located coaxially to the suction pipe and filtering the wound connecting the intake sections with the suction pipe, the intake holes of the suction pipe, made inside the filter screen and distributed along its length.

The disadvantage of this device is the low efficiency of fish protection.

Known fish protection device of the water intake structure [5], including a suction pipe located in the water stream and connected to the suction pipe of the pump, a filter screen in the form of a truncated cone, located coaxially with the suction pipe, while the larger base of the truncated cone is located on the side of the suction pipe, a hydraulic washer installed at the top of the filter screen, aligned with it, and the hydraulic washer is connected by a supply pipe to the pressure line of the pump and equipped with nozzles that you filled on the chamber of the hydraulic washer and located on the outside of the filter screen, and their outlet openings are oriented towards the base of the truncated cone, a water supply path in the form of a pipe located coaxially to the suction pipe and a filter screen connecting the intake sections with the suction pipe, the intake openings of the suction pipe, made inside the filter screen and distributed along its length.

The disadvantage of this device is the low efficiency of fish protection.

Known fish protection device of the water intake structure [6], including a suction pipe located in the water stream and connected to the suction pipe of the pump, a filter screen in the form of a truncated cone, located coaxially with the suction pipe, while the larger base of the truncated cone is located on the side of the suction pipe, a hydraulic washer installed in the top of the filter screen, coaxially with it, and the hydraulic washer is connected by a supply pipe to the pressure line of the pump and is equipped with nozzles that are filled on the chamber of the hydraulic washer and are located on the outside of the filter screen, and their outlet openings are oriented towards the base of the truncated cone, flow guiding elements placed inside the filter screen, aligned with it and located along its length, while their outer edges are adjacent to the inner surface of the filter screen and form water intake sections located in the gaps between the flow guiding elements made in the form of truncated cones facing large bases to the top of the fil a friction screen, a water supply path in the form of a pipe located coaxially with the suction pipe and a filter screen connecting the water intake sections to the suction pipe, the small bases of the truncated cones of the flow guiding elements adjacent to the water pipe, the water intake openings of the suction pipe made inside the filter screen and distributed along its length .

The disadvantage of this device is the low efficiency of fish protection.

Known fish protection device of the water intake structure [7], including a suction pipe located in the water stream and connected to the suction pipe of the pump, a filter screen in the form of a truncated cone, located coaxially with the suction pipe, while the larger base of the truncated cone is placed on the side of the suction pipe, a hydraulic washer installed at the top of the filter screen, aligned with it, and the hydraulic washer is connected by a supply pipe to the pressure line of the pump and equipped with nozzles that you are filled on the chamber of the hydraulic washer and are located on the outside of the filter screen, and their outlet openings are oriented towards the base of the truncated cone, flow guiding elements placed inside the filter screen, aligned with it and located along its length, while their outer edges are adjacent to the inner surface of the filter screen and form water intake sections located in the gaps between the flow guiding elements made in the form of truncated cones facing large bases to the top of the fil an exhaust screen, a water supply path in the form of a pipe located coaxially with the suction pipe and a filter screen connecting the water intake sections to the suction pipe, the small bases of the truncated cones of the flow guiding elements adjacent to the water supply channel, the water intake openings of the suction pipe made inside the filter screen and distributed .

The disadvantage of this device is the low efficiency of fish protection. Known fish protection device of the intake structure [8], including a suction pipe located in the water stream and connected to the suction pipe of the pump, a filter screen in the form of a truncated cone, located coaxially with the suction pipe, while the larger base of the truncated cone is located on the side of the suction pipe, a hydraulic washer installed at the top of the filter screen, aligned with it, and the hydraulic washer is connected by a supply pipe to the pressure line of the pump and equipped with nozzles that you are filled on the chamber of the hydraulic washer and are located on the outside of the filter screen, and their outlet openings are oriented towards the base of the truncated cone, flow guiding elements placed inside the filter screen, aligned with it and located along its length, while their outer edges are adjacent to the inner surface of the filter screen and form water intake sections located in the gaps between the flow guiding elements made in the form of truncated cones facing large bases to the top of the fil an exhaust screen, a water supply path in the form of a pipe located coaxially with the suction pipe and a filter screen connecting the water intake sections to the suction pipe, the small bases of the truncated cones of the flow guiding elements adjacent to the water supply channel, the water intake openings of the suction pipe made inside the filter screen and distributed .

The disadvantage of this device is the low efficiency of fish protection.

Known fish protection device of the water intake structure [9], including a suction pipe located in the water stream and connected to the suction pipe of the pump, a filter screen in the form of a truncated cone, located coaxially with the suction pipe, while the larger base of the truncated cone is located on the side of the suction pipe, a hydraulic washer installed at the top of the filter screen, aligned with it, and the hydraulic washer is connected by a supply pipe to the pressure line of the pump and equipped with nozzles that you are filled on the chamber of the hydraulic washer and are located on the outside of the filter screen, and their outlet openings are oriented towards the base of the truncated cone, flow guiding elements placed inside the filter screen, aligned with it and located along its length, while their outer edges are adjacent to the inner surface of the filter screen and form water intake sections located in the gaps between the flow guiding elements made in the form of truncated cones facing large bases to the top of the fil an exhaust screen, a water supply path in the form of a pipe located coaxially with the suction pipe and a filter screen connecting the water intake sections to the suction pipe, the small bases of the truncated cones of the flow guiding elements adjacent to the water supply channel, the water intake openings of the suction pipe made inside the filter screen and distributed .

The disadvantage of this device is the low efficiency of fish protection.

Known fish protection device of the water intake structure [10], including a suction pipe located in the water stream and connected to the suction pipe of the pump, a filter screen in the form of a truncated cone, located coaxially with the suction pipe, while the larger base of the truncated cone is placed on the side of the suction pipe, a hydraulic washer installed in the top of the filter screen, aligned with it, and the hydraulic washer is connected by a supply pipe to the pressure line of the pump and is equipped with nozzles that you are filled on the chamber of the hydraulic washer and are located on the outside of the filter screen, and their outlet openings are oriented towards the base of the truncated cone, flow guiding elements placed inside the filter screen, aligned with it and located along its length, while their outer edges are adjacent to the inner surface of the filter screen and form water intake sections located in the gaps between the flow guiding elements made in the form of truncated cones facing large bases to the top of the fil an exhaust screen, a water supply path in the form of a pipe located coaxially with the suction pipe and a filter screen connecting the water intake sections to the suction pipe, the small bases of the truncated cones of the flow guiding elements adjacent to the water supply channel, the water intake openings of the suction pipe made inside the filter screen and distributed .

The disadvantage of this device is the low efficiency of fish protection.

Known fish protection device of the water intake structure [11], including a suction pipe located in the water stream and connected to the suction pipe of the pump, a filter screen in the form of a truncated cone, located coaxially with the suction pipe, while the larger base of the truncated cone is located on the side of the suction pipe, a water washer installed at the top of the filter screen, aligned with it, and the hydraulic washer is connected by a supply pipe to the pressure line of the pump and equipped with nozzles that you filled on the chamber of the hydraulic washer and located on the outside of the filter screen, and their outlet openings are oriented towards the base of the truncated cone, flow guiding elements located inside the filter screen, aligned with it and located along its length, while their outer edges are adjacent to the inner surface of the filter screen and form the water intake sections located in the spaces between the flow guiding elements made in the form of truncated cones facing with large bases to the top of the phi an exhaust screen, a water supply path in the form of a pipe located coaxially with the suction pipe and a filter screen connecting the water intake sections to the suction pipe, the small bases of the truncated cones of the flow guiding elements adjacent to the water supply channel, the water intake openings of the suction pipe made inside the filter screen and distributed .

The disadvantage of this device is the low efficiency of fish protection.

A fish protection device of the water intake structure [12] is known, including a filter screen located in the watercourse, a water washer installed at the top of the filter screen, at an angle to it, and the water washer is connected by a supply pipe to the pressure pipe of the pump and is equipped with nozzles that are located on the outside of the filter screen, and their outlet openings are oriented towards the end part of the filter screen, flow-guiding elements located inside the filter screen and located along it the length, while their outer edges are adjacent to the inner surface of the filter screen and form water intake sections located in the spaces between the flow guiding elements made in the form of walls, a water supply path connecting the water intake sections to the suction pipe, water intake holes made inside the filter screen and distributed over its length.

The disadvantage of this device is the low efficiency of fish protection.

Known fish protection device of the water intake structure [13], including a suction pipe located in the water stream and connected to the suction pipe of the pump, a filter screen in the form of a truncated cone, located coaxially with the suction pipe, while the larger base of the truncated cone is located on the side of the suction pipe, a water washer installed at the top of the filter screen, coaxial to it, and the hydraulic washer is connected by a supply pipe to the pressure line of the pump and is equipped with basic and additional nozzles, which are made on the chamber of the hydraulic washer and are located on the outside of the filter screen, and their outlet openings are oriented towards the base of the truncated cone, flow guiding elements placed inside the filter screen, aligned with it and located along its length, while their outer edges are adjacent to the inner surface of the filter screen and form the water intake sections located in the spaces between the flow-guiding elements, made in the form of truncated cones, facing large by their bases to the top of the filter screen, a water supply path in the form of a pipe located coaxially to the suction pipe and the filter screen connecting the water intake sections to the suction pipe, the small bases of the truncated cones of the flow guiding elements adjacent to the water supply path, the water intake openings of the suction pipe and made inside the filter screen distributed along its length.

The disadvantage of this device is the low efficiency of fish protection.

Known fish protection device of the water intake structure [14], including a filter screen located in the watercourse, flow guides placed outside and inside the filter screen, located along its length, water intake holes made in the filter screen and distributed along its length.

The disadvantage of this device is the low efficiency of fish protection.

Known fish protection device of the water intake structure [15], including a suction pipe located in the water stream and connected to the suction pipe of the pump, a filter screen in the form of a cylinder located coaxially with the suction pipe, and its base is placed on the side of the suction pipe, and a hydraulic washer is installed at the top of the cylinder coaxial to it, moreover, the hydraulic washer is connected by a supply pipe to the pressure line of the pump, equipped with nozzles that are made on the chamber of the hydraulic washer and located s on the outside of the filter screen, and their outlet openings are oriented towards the base of the cylinder, the flow guide element located inside the filter screen, aligned with it and located along its length, while their outer edges are adjacent to the inner surface of the filter screen, and the flow guide element is made in the form of a truncated cone, facing a large base to the top of the filter screen.

The disadvantage of this device is the low efficiency of fish protection.

Known fish protection device of the water intake structure [16], including a suction pipe located in the water stream and connected to the suction pipe of the pump, a filter screen in the form of a cylinder located coaxially with the suction pipe, while the base of the cylinder is placed on the side of the suction pipe, flow guiding elements located inside the filter of the screen, coaxial to it and located along its length, while their outer edges form the water intake holes made inside the filter screen and limited along its length, while the water supply path is made in the form of autonomous coaxially installed pipes, forming between themselves the water inlets of the suction pipe in the form of an annular gap, and the end parts of the autonomous coaxially installed pipes are inserted inside the suction pipe.

The disadvantage of this device is the low efficiency of fish protection due to uneven filtering speeds.

The closest in technical essence and the achieved result is a fish protection structure [17], including a suction pipe located in a water stream and connected to a suction pipe of the pump, a filter screen in the form of a truncated cone, located coaxially with the suction pipe, with the larger base of the truncated cone placed on the side the suction pipe, a hydraulic washer installed at the top of the filter screen, coaxial to it and with the possibility of rotation relative to the horizontal axis, moreover, The driver is connected by a supply pipe to the pressure line of the pump, equipped with main and additional nozzles, while the main nozzles are made on the hydraulic washer chamber and are located on the outside of the filter screen, and their outlet openings are oriented towards the base of the truncated cone, additional nozzles are located in a plane perpendicular to the axis filter screen, located on the outer surface of the chamber of the hydraulic washer and at an angle to it, and their outlet openings are oriented in one direction, flow guide elements located inside the filter screen, aligned with it and located along its length, while their outer edges are adjacent to the inner surface of the filter screen and form water intake sections located in the intervals between the flow guiding elements, made in the form of truncated cones, facing large bases to the top a filter screen, a water supply path in the form of a pipe located coaxially to the suction pipe and a filter screen connecting the intake sections to the suction cartridge ubcom, and the small bases of the truncated cones of the flow guiding elements are adjacent to the water supply path, the intake openings of the suction pipe, made inside the filter screen and distributed along its length.

The disadvantage of this device is the low efficiency of fish protection due to uneven filtering speeds.

The aim of the invention is to increase the effectiveness of fish protection.

The invention consists in the following.

According to claim 1 of the claims. The implementation of the water supply path in the form of autonomous coaxially installed pipes, forming between themselves the water inlets of the suction pipe in the form of an annular gap, allows you to redistribute the suction torch along the length of the filter screen and form local suction sections on its surface.

The execution of the end parts of the autonomous coaxially installed pipes inserted into the suction pipe, allows to ensure a stable mode of selection of the suction flow of water, and from each intake section.

The implementation of the initial parts of the autonomous coaxially installed pipes rigidly connected to the small bases of the truncated cones of the flow-guiding elements allows the formation of independent water paths that ensure the transport of selected specific water flow rates. With this arrangement, independent water supply paths and their initial parts due to their geometry and inclination angles allow the formation of local hydraulic resistance along the length of the filter screen, which ensures uniform filtration rate on the surface of the fish head.

According to claim 2 of the claims. The option when autonomous coaxially installed pipes form between themselves the water inlets of the suction pipe in the form of a uniform annular gap with the same width is a particular constructive solution.

According to claim 3 of the claims. The option when the lateral surface of the truncated cones of the flow guiding elements is made curved and convex facing the axis of the filter screen, allows you to optimize the plot of the suction flow and align the plot of filtering speeds.

According to claim 4 of the claims. The variant when the end parts of autonomous coaxially installed pipes are located in different transverse sections, while the end part of the central pipe is located in the transverse section farthest from the top of the filter screen, ensures proportionality of the selected costs in each autonomous water supply path. The maximum suction flow rate falls on the longitudinal axis of the suction pipe, and the maximum suction length also coincides with it, therefore, the end part of the central pipe is located in the transverse section of the suction pipe, the most distant from the top of the filter screen.

According to claim 5, the claims. The option, when the inlet pipe of the hydraulic washer is located inside the filter screen along its side generatrix, reduces the amount of hydraulic resistance to the suction flow.

According to claim 6, claims. The option when the additional nozzles are equipped with nozzles forming a Segner wheel and are located in the same plane as the outlet openings of the additional nozzles is a variant of the jet-driven drive of the hydraulic washer chamber.

According to claims 7 and 8 of the claims. A variant when the outlet openings of the additional nozzles are oriented in a clockwise or counterclockwise direction are modifications of the drive of the hydraulic washer chamber.

According to claim 9, the claims. The option when the perforation holes of the filter screen are made in a rectangular shape is a private constructive solution.

According to claim 10 of the claims. The option, when the perforation holes of a large size are located in the transverse plane, that is, the large side of the rectangle is perpendicular to the longitudinal vector of the transit flow velocity, reduces the likelihood of juvenile fish entering the head.

According to claim 11, the claims. The option when the perforation holes are large in size in the longitudinal plane is a modification of the surface of the filter screen.

According to paragraph 12 of the claims. The option, when the perforation holes are staggered, reduces the unevenness of the filtering speeds over the area of the filter screen.

According to item 13 of the claims. An option when the perforation holes of the filter screen are round, is an embodiment of it.

According to claim 14. The option, when the perforation holes are staggered, reduces the unevenness of the filtering speeds over the area of the filter screen.

According to clause 15 of the claims. The option when the hydraulic washer is made in the form of a cone, the top of which is facing the flow, is its particular constructive solution.

According to clause 16 of the claims. The option when the hydraulic washer is made streamlined, while its convex surface is facing the flow, allows you to optimize the hydraulics in the area where the hydraulic washer is located.

The solution to this problem is achieved by creating a new design of a fish protection device for the water intake structure.

Graphic material illustrating the invention is presented in the following figures:

figure 1 - tip, isometric, perforation holes are made rectangular;

figure 2 is the same, the perforation holes are made round;

figure 3 - flow guiding elements, isometry;

figure 4 - head, isometry, a longitudinal section;

5 is a head, a longitudinal section;

6 is the same, an option when the lateral surface of the truncated cones of the flow guiding elements is made curved and convex surface facing the axis of the filter screen;

7 is a head, a longitudinal section, an option when the end parts of autonomous, coaxially installed pipes are located in different transverse sections, while the end part of the central pipe is located in a transverse section farthest from the top of the filter screen;

Fig.8 is a head, a longitudinal section, an option when the inlet pipe of the hydraulic washer is made coaxially to the head;

Fig.9 - inlet pipe of the hydraulic washer, a fragment, its initial part is made with a flange;

figure 10 - chamber washer, option with segner wheel;

11 is a view a in figure 10;

Fig - chamber of the hydraulic washer, an option when additional nozzles are located in a plane perpendicular to the axis of the filter screen, made on the outer surface of the chamber of the hydraulic washer and at an angle to it;

Fig.13 is a view of B in Fig.12;

Fig. 14 is a view of the main nozzles of the hydraulic washer from the side of the base of the head;

Fig - hydraulic washer fragment;

Fig.16 is a section bb in Fig.15;

Fig.17 is a filter cloth, an option when the perforation holes are made in a rectangular shape, while the perforation holes of a large size are located in the transverse plane;

Fig. 18 is the same, the perforation holes of a large size are located in the longitudinal plane;

Fig.19 is a filter cloth, an option when the perforation holes are rectangular in shape and large in size in the transverse plane, while the perforation holes are staggered;

Fig - filter cloth, an option when the perforation holes are made in a rectangular shape and are large in size in the longitudinal plane, while the perforation holes are staggered;

Fig - filter cloth, an option when the perforation holes are made round;

Fig - filter cloth, an option when the perforation holes are made circular in shape, while the perforation holes are staggered;

23 is a cross section of a suction pipe, a system for attaching autonomous coaxially mounted pipes to stiffeners.

The fish protection device of the water intake structure includes a suction pipe 1 located in the water stream and connected to the suction line of the pump, a filter screen 2 in the form of a truncated cone, located coaxially with the suction pipe 1, while the larger base of the truncated cone is placed on the side of the suction pipe 1, a hydraulic washer 3, installed at the top of the filter screen 2, coaxially with it and with the possibility of rotation relative to the horizontal axis, and the hydraulic washer 3 is connected by a supply pipe 4 to The main line of the pump is equipped with main 5 and additional 6 nozzles, while the main nozzles 5 are made on the chamber of the hydraulic washer 3 and are located on the outside of the filter screen 2, and their outlet openings are oriented towards the base of the truncated cone, additional nozzles 6 are located in a plane perpendicular the axis of the filter screen 2, are located on the outer surface of the chamber of the hydraulic washer 3 and at an angle to it, and their outlet openings are oriented in one direction, flow guiding elements placed inside At the filter screen 2, coaxial to it and located along its length, while their outer edges are adjacent to the inner surface of the filter screen 2 and form water intake sections 7 located in the spaces between the flow guiding elements, made in the form of truncated cones 8, facing large bases to the top a filter screen 2, a water supply path in the form of a pipe located coaxially to the suction pipe 1 and a filter screen 2 connecting the intake sections 7 to the suction pipe 1, and small bases truncated cones 8 of the flow guiding elements are adjacent to the water supply path, the water intake holes 9 of the suction pipe 1, made inside the filter screen 2 and distributed along its length.

The water supply path is made in the form of autonomous coaxially installed pipes 10, forming between them the water inlets 9 of the suction pipe 1 in the form of an annular gap, the end parts of the autonomous coaxially installed pipes 10 being inserted inside the suction pipe 1, and their initial parts are rigidly connected to the small bases of the truncated cones 8 flow guiding elements.

In addition, stand-alone coaxially installed pipes 10 can form water intake openings 9 of the suction pipe 1 in the form of a uniform annular gap with the same width.

In addition, the lateral surface of the truncated cones 8 of the flow guiding elements can be made curved and convex surface facing the axis of the filter screen 2.

In addition, the end parts of the autonomous coaxially installed pipes 10 can be located in different transverse sections, while the end part of the central pipe 10 is located in the transverse section farthest from the top of the filter screen 2.

In addition, the supply pipe 4 of the hydraulic washer 3 can be located inside the filter screen 2 along its side generatrix.

In addition, additional nozzles 6 can be equipped with nozzles 11 forming a Segner wheel, and are located in the same plane as the outlet openings of the additional nozzles 6.

In addition, the outlets of the additional nozzles 6 can be oriented in a clockwise direction.

In addition, the outlets of the additional nozzles 6 can be oriented counterclockwise.

In addition, the perforation holes 12 of the filter screen 2 can be made rectangular.

In addition, the perforation holes 12 of a large size can be located in the transverse plane.

In addition, the perforation holes 12 of a large size can be located in the longitudinal plane.

In addition, the perforation holes 12 can be staggered.

In addition, the perforation holes 12 of the filter screen 2 can be made round.

However, the perforation holes 12 can be staggered.

In addition, the hydraulic washer 3 can be made in the form of a cone, the apex of which is directed towards the flow.

In addition, the hydraulic washer 3 can be made streamlined, with its convex surface facing the flow.

Autonomous coaxially installed pipes 10 are fixed to each other and to the suction pipe 1 on the ribs 13.

Fish protection device of the intake works as follows.

In the mode of water intake for consumer needs, the flow of water from the stream flows through the perforations 12 of the filter screen 2 and then through the suction pipe 1 to the pump (not shown). Thanks to the additional nozzles 6 of the hydraulic washer 3, it constantly rotates and moves the main nozzles 5 along the generatrix of the filter screen 2. The hydraulic jets emerging from the additional nozzles 6, in addition to forming a jet-reactive moment, already at the preliminary stage contribute to the removal of most of the rolling young fish and entrained debris from the zone the influence of the filter screen 2. Hydraulic jets leaving the main nozzles 5 propagate along the surface of the filter screen 2 and wash it from debris. Due to the rotation of the chamber of the hydraulic washer 3, these jets uniformly wash the entire area of the filter screen 2, while there are no unwashed and "dead zones" not available for washing.

The implementation of the water supply path in the form of autonomous coaxially installed pipes 10, forming between themselves the water inlets 9 of the suction pipe 1 in the form of an annular gap, allows you to redistribute the suction torch along the length of the filter screen 2 and form local suction sections on its surface in the form of water intake sections 7.

The execution of the end parts of the autonomous coaxially installed pipes 10 introduced into the suction pipe 1, allows for a stable selection of the suction flow rate of water, and from each of the intake section 7.

The implementation of the initial parts of the autonomous coaxially installed pipes 10 rigidly connected to the small bases of the truncated cones 8 of the flow-guiding elements allows the formation of independent water paths that provide autonomous transport of selected specific water flow rates. With this arrangement, independent water supply paths and their initial parts due to their geometry and inclination angles allow the formation of local hydraulic resistance along the length of the filter screen 2, which ensures uniform filtration rate on the surface of the fish head.

A fish protection device operation option is possible when autonomous coaxially installed pipes 10 form water intake openings 9 of the suction pipe 1 in the form of a uniform annular gap with the same width, which is a particular constructive solution.

A fish protection device operation option is possible when the lateral surface of the truncated cones 8 of the flow guiding elements is made curved and convex facing the axis of the filter screen 2, which allows optimizing the plot of the suction stream and aligning the plot of filtering speeds.

A fish protection device operation option is possible when the end parts of autonomous coaxially installed pipes 10 are located in different transverse sections, while the end part of the central pipe 10 is located in the transverse section farthest from the top of the filter screen 2, which ensures proportionality of the selected flow rates in each autonomous water supply path. The maximum velocity of the suction flow falls on the longitudinal axis of the suction pipe 1 and the maximum suction length also coincides with it, therefore, the end part of the central pipe 10 is located in the transverse section of the suction pipe 1, the most remote from the top of the filter screen 2.

A fish protection device operation option is possible when the supply pipe 4 of the hydraulic washer 3 is located inside the filter screen 2 along its lateral generatrix, which reduces the hydraulic resistance to the suction flow.

A fish protection device operation option is possible when the additional nozzles 6 are equipped with nozzles 11 forming a Segner wheel and are located in the same plane as the outlet openings of the additional nozzles 6, which is a variant of the jet-driven drive of the hydraulic washer chamber 3.

A variant of the operation of the fish protection device is possible when the outlet openings of the additional nozzles 6 are oriented clockwise or counterclockwise, which are modifications of the drive of the chamber of the hydraulic washer 3.

A variant of the operation of the fish-protecting device is possible when the perforation holes 12 of the filter screen 2 are rectangular in shape, which is a particular constructive solution thereof.

A fish protection device operation option is possible when the perforation holes 12 of a large size are located in the transverse plane, that is, the large side of the rectangle is perpendicular to the longitudinal vector of the transit flow velocity, which reduces the likelihood of juvenile fish entering the head.

The option when the perforation holes 12 are large in size in the longitudinal plane is a modification of the surface of the filter screen 2.

A fish-working device operation option is possible when the perforation holes 12 are staggered, which reduces the unevenness of the filtering speeds over the area of the filter screen 2.

A variant of the operation of the fish protection device is possible when the perforation holes 12 of the filter screen 2 are round in shape, which is an embodiment thereof.

A fish protection device operation option is possible when the perforation holes 12 of a round shape are staggered, which reduces the unevenness of the filtering speeds over the area of the filter screen 2.

A variant of the operation of the fish protection device is possible when the hydraulic washer 3 is made in the form of a cone, the apex of which is directed towards the flow, which is its particular constructive solution.

A fish protection device operation option is possible when the hydraulic washer 3 is made in a streamlined shape, while its convex surface faces the flow, which allows optimizing hydraulics in the area where the hydraulic washer 3 is located.

The proposed design of the head combines the best qualities and the optimized structural elements that occur in analogues, and allows you to increase the efficiency of fish protection. In addition, the proposed device allows to provide a uniform field of filtration rates on the entire surface of the filter screen.

Information sources

1. A.S. USSR (SU) No. 1191517. "Fish protection device of the water intake structure". Publ. B.I. No. 42, 1985.11.15. Author: Kulyabko V.A., Sivkov A.A., Sinyavskaya V.M., Gavrilov E.N.

2. A.S. USSR (SU) No. 1493731. "Fish protection device of the water intake structure". Publ. B.I. No. 26, 1989.07.15. Authors: Cherkasov V.A., Chistyakov A.A., Vostrova L.I., Prokopov N.A.

3. A.S. USSR (SU) No. 1641936. "Fish protection device of the water intake structure". Publ. B.I. No. 14, 1991.04.15. Authors: Chistyakov A.A., Parulava II, Cherkasov V.A., Shkura V.N.

4. A.S. USSR (SU) No. 1671766. "Fish protection device of the water intake structure". Publ. B.I. No. 31, 1991.08.23. Authors: Parulava II, Chistyakov A.A., Cherkasov V.A., Shkura V.N.

5. A.S. USSR (SU) No. 1802039. "Fish protection device of the water intake structure". Publ. B.I. No. 10, 1993.03.15. Authors: Parulava II, Cherkasov V.A., Chistyakov A.A., Mikheev P.A.

6. A.S. USSR (SU) No. 949059. "Fish protection device of the water intake structure". Publ. B.I. No. 29, 1982.08.07. Authors: Kulyabko V.A., Sinyavskaya V.M., Sivkov A.A., Gavrilov E.N.

7. Australian Patent (AU) No. 7211781. "Screen device for a suction pipe". Publ. 1983.01.06. Kulyabko V.A., Sinyavskaya V.M., Sivkov A.A., Gavrilov E.N.

8. Canadian Patent (CA) No. 1140351. "Apparatus for fish protection". Publ. 1983.02.01. Kulyabko V.A., Sinyavskaya V.M., Sivkov A.A., Gavrilov E.N.

9. French Patent (FR) No. 2508512. "Dispositif de protection des poissons contre leur aspiration dans des prises d'eau." Publ. 1983.12.31. Kulyabko V.A., Sinyavskaya V.M., Sivkov A.A., Gavrilov E.N.

10. Italian Patent (IT) No. 1146304. "Fish protection appts. With water permeable screen". Publ. 1986.11.12. Kulyabko V.A., Sinyavskaya V.M., Sivkov A.A., Gavrilov E.N.

11. US patent (US) No. 4337008. "Apparatus for fish protection". Publ. 1982.06.29. Kulyabko V.A., Sinyavskaya V.M., Sivkov A.A., Gavrilov E.N.

12. A.C. USSR (SU) No. 1469011. "Water intake head". Publ. B.I. No. 12, 1989.03.30. Author: Sinyavskaya V.M., Khaladzhiev V.P., Gavrilov E.N., Vyuchnov B.C.

13. A.S. USSR (SU) No. 1641935. "Fish protection device of the water intake structure". Publ. B.I. No. 14, 1991.04.15. Authors: Chistyakov A.A., Cherkasov V.A., Parulava I.I., Shkura V.N.

N. Patent of the Russian Federation No. 2234568. "Fish protection construction." Publ. 2004.08.20. Authors: Barekyan A.Sh., Rybakov A.E.

15. RF patent No. 2250297. "Fish-washable head". Publ. 2005.04.20. Author: Barekyan A.Sh.

16. US Patent (US) No. 6051131. "Flow modifier for submerged intake screen". Publ. 04/04/18. Author: Maxson Richard S. (Figure # 5).

17. A.S. USSR (SU) No. 1585450. "Fish head". Publ. B.I. No. 30, 1990.08.15. Authors: Chistyakov A.A., Cherkasov V.A., Parulava I.I., Bauer V.Ya., Shkura V.N.

Claims (16)

1. Fish protection device of the intake structure, including a suction pipe located in the water stream and connected to the suction pipe of the pump, a filter screen in the form of a truncated cone, located coaxially with the suction pipe, while the larger base of the truncated cone is placed on the side of the suction pipe, a water washer installed at the top the filter screen coaxially with it and with the possibility of rotation relative to the horizontal axis, and the hydraulic washer is connected by a supply pipe to the pressure the pump line is equipped with main and additional nozzles, while the main nozzles are made on the hydraulic washer chamber and are located on the outside of the filter screen, and their outlet openings are oriented towards the base of the truncated cone, additional nozzles are located in a plane perpendicular to the axis of the filter screen, and are mounted on the outer surface of the chamber of the hydraulic washer at an angle to it, and their outlet openings are oriented in one direction, flow-guiding elements located inside the filter of the screen coaxial to it and located along its length, while their outer edges are adjacent to the inner surface of the filter screen and form water intake sections located in the spaces between the flow guiding elements, made in the form of truncated cones facing with large bases to the top of the filter screen, the water supply path to in the form of a pipe, located coaxially with the suction pipe and the filter screen, connecting the intake sections with the suction pipe, and the small base of the truncated flow cones of the guide elements adjacent to the water supply path, the intake openings of the suction pipe made inside the filter screen and distributed along its length, characterized in that the water supply path is made in the form of self-contained coaxially installed pipes forming the water intake holes of the suction pipe in the form of an annular gap, and the end parts of autonomous coaxially installed pipes are inserted inside the suction pipe, and their initial parts are rigidly connected to small bases section of the cone potokonapravlyayuschih elements. 2. The device according to claim 1, characterized in that the autonomous coaxially installed pipes form between themselves the water inlets of the suction pipe in the form of a uniform annular gap with the same width. 3. The device according to claim 1, characterized in that the lateral surface of the truncated cones of the flow guiding elements is made curved and convex surface facing the axis of the filter screen. 4. The device according to any one of claims 1 to 3, characterized in that the end parts of the autonomous coaxially installed pipes are located in different transverse sections, while the end part of the central pipe is located in a transverse section farthest from the top of the filter screen. 5. The device according to any one of claims 1 to 3, characterized in that the supply pipe of the hydraulic washer is located inside the filter screen along its side generatrix. 6. The device according to any one of claims 1 to 3, characterized in that the additional nozzles are equipped with nozzles forming a Segner wheel and located in the same plane as the outlet openings of the additional nozzles. 7. The device according to any one of claims 1 to 3, characterized in that the outlet openings of the additional nozzles are oriented in a clockwise direction. 8. The device according to any one of claims 1 to 3, characterized in that the outlet openings of the additional nozzles are oriented counterclockwise. 9. The device according to any one of claims 1 to 3, characterized in that the perforation holes of the filter screen are rectangular. 10. The device according to claim 9, characterized in that the perforation holes of a large size are located in the transverse plane. 11. The device according to claim 9, characterized in that the perforation holes of a large size are located in the longitudinal plane. 12. The device according to any one of paragraphs.10-11, characterized in that the perforation holes are staggered. 13. The device according to any one of claims 1 to 3, characterized in that the perforation holes of the filter screen are round. 14. The device according to item 13, wherein the perforation holes are staggered. 15. The device according to any one of claims 1 to 3, characterized in that the hydraulic washer is made in the form of a cone, the apex of which is directed towards the flow. 16. The device according to any one of claims 1 to 3, characterized in that the hydraulic washer is made streamlined, while its convex surface is facing towards the stream.

Images