RU2278207C1 - Water intake regime control method and fish protective structure for above method realization - Google Patents

Abstract

FIELD: hydraulic building, particularly structures adapted to prevent fish passage in water intake structures and included in water intake structures.

SUBSTANCE: method involves installing louvers at different angles to supply channel flow as vertical young fish descent dynamics changes to regulate water flow to be taken. Maximal hydraulic flow resistance of supply channel is formed in flow sections of maximal young fish concentration by installing louvers at maximal angle to supply channel flow. Minimal hydraulic resistance is formed in flow sections of minimal young fish concentration by installing louvers at minimal angle to supply flow.

EFFECT: increased fish protection, improved water intake regime control with taking into consideration of biological features of object to be protected.

8 cl, 32 dwg

Description

The invention relates to hydraulic engineering, and in particular to methods and structures designed to protect juvenile fish from getting into water intake structures.

A known method of controlling the water withdrawal mode [1], including changing the planned location of flexible elastic panels of the louvre system with respect to the flow of the supply channel and installing the panels at an angle of 0 <α <90 ° to the direction of the longitudinal flow rate in the supply channel.

The disadvantage of this method is the low efficiency of the management of water withdrawal.

Closest to the technological scheme is a method of controlling the water withdrawal mode [2], including changing, by means of a drive, the planned arrangement of the planes of the louvre system in relation to the flow of the supply channel and installing the blinds at an acute angle to the direction of the longitudinal velocity of the flow of the supply channel, sampling the estimated water flow in water intake between the planes of the blinds and the simultaneous formation, through the supply of hydraulic or water-air jets, of intensive garbage collection pipes in the inlet water inlets formed by the vertical planes of the louvre system with a speed exceeding the critical swimming speed of juvenile fish and the regulation of the magnitude of the taken specific consumption in the inlet gauge of the inlet channel.

The disadvantage of this method is the low degree of controllability in the appointment of water withdrawal conditions in the face of changing dynamics of the vertical slope of juvenile fish.

Known fish protection device [3], including installed in the channel at an angle to the flow, a fish-retaining screen with a waste collection tray attached to its upper part and connected with the fish drain, means for preliminary removal of juvenile fish in the form of a louvre system and vertically installed water-jet installations located in between between the blinds.

The disadvantage of this device is the low efficiency of removal of juvenile fish.

The closest in technical essence and the achieved result is a fish protection device [2], including a louvre system installed in the inlet of the water intake channel with the possibility of turning the louvres around the hinges by means of an individual drive, while the louvres face the flow with their outer surface and are located at an angle to the flow inlet channel, a means for preliminary removal of debris and juvenile fish, consisting of perforated pipes, distribution pipes, pressure pipes and a pump, with this blinds are made vertically to the entire depth of the flow and are connected with vertical perforated pipes with one vertical edge, and the axis of rotation of the blinds are pivotally mounted by means of a drive and connected to a distributing manifold connected to the pump, while the outlet openings of the perforated pipes are equipped with nozzles, mounted coaxially with the perforation holes, and flexible elastic elements attached to the side surface of the perforated pipes.

The disadvantage of this fish protection device is the low efficiency of the management of water withdrawal regimes when changing the dynamics of the vertical slope of juvenile fish.

The aim of the invention is the creation of effective conditions providing the ability to control the regime of water withdrawal when changing the dynamics of the vertical slope of juvenile fish.

The invention consists in the following.

According to claim 1 of the claims. When the dynamics of the vertical slope of juvenile fish changes, the operation service of the water intake facility, to regulate the flow rates, installs, through individual drives, blinds at different angles to the flow of the feed channel, while forming maximum hydraulic resistance in the flow horizons with the maximum concentration of juvenile fish, installing blinds at a maximum angle to the flow of the supply channel, and the minimum hydraulic resistance in horizons with a minimum concentration of m Lodi fish, establishing shutters at a minimum angle to the flow of the raceway. In this case, the maximum efficiency of fish protection is ensured.

According to claim 2 of the claims. Performing blinds from a rigid frame and installing them in tiers, with each tier connected to an individual drive, allows you to control the mode of water withdrawal of the estimated flow into the water intake. An individual drive allows independent rotation of the blinds of each tier and exposes them at different angles to the flow of the supply channel. The location of the louvre system, in plan, along the curvilinear generatrix, allows more efficient use of the resulting flow velocity vector created by hydraulic jets formed by nozzles made in the end part of the blinds facing the supply channel. The implementation of perforated pipes attached to the vertical edge of the blinds facing the inlet channel, allows you to more efficiently form at the preliminary stage of the garbage collection (garbage collection). In this arrangement, at the first stage, the louvre working planes perform the function of garbage collection, since the incoming flow forms, when interacting with the louvre plane, a velocity vector component directed along a curved generatrix along which the louvre system is installed. At the second and final stage, the function of the garbage collection is performed by hydraulic jets formed by nozzles of perforated pipes. In this case, the jets, possessing a high level of kinetic energy and high speeds, divert garbage and juveniles to a farther slope trajectory formed along a curved generatrix, according to which the blinds are installed. The presence of flexible elastic tapes mounted on the end parts of the blinds, from the side of the supply channel, allows you to create an additional fish screen, moreover, flexible elastic tapes, under the influence of hydraulic jets, constantly vibrate and form a dynamic fish shield, which is a logical continuation of the hard screen created by the planes of the blinds.

According to claim 3 of the claims. Attaching flexible elastic tapes on both sides of the nozzles of perforated pipes allows you to create a more dense fish shield formed by flexible tapes.

According to claim 4 of the claims. The implementation of the device with the garbage collection tray located in the upper part of the stream, and its connection with the garbage collection, allows you to effectively remove suspended garbage and juvenile fish, concentrated in the surface horizon of the stream.

According to claim 5 of the claims (option). The implementation of perforated pipes with perforated boxes with nozzles, and the perforated boxes are fixed along the perforated pipes with the formation of the air supply plane in communication with the atmosphere, while the nozzles are fixed on the inner surface of the perforated boxes, and the nozzle holes, perforation of pipes, boxes and the longitudinal plane of the blinds are aligned. allows the formation of water-air jets. The presence of water-air jets makes it possible to efficiently transport suspended fish and young fish to the upper horizons of the stream, where they fall into the garbage collection tray and then into the garbage collection. The principle of operation of this device is as follows. Coaxial execution of nozzles of boxes and exhaust openings of perforated pipes allows the formation of hydraulic jets to eject air from the atmosphere entering the air supply cavity. At the same time, water jets are intensely saturated with air and form water-air jets in front of the louvre system.

According to claim 6, claims. The implementation of flexible elastic tapes fixed to perforated boxes also allows you to create a dynamic fish protection screen, which is a logical continuation of the screen formed by the planes of the blinds.

According to claim 7 of the claims. The implementation of flexible elastic tapes, fixed on both sides of the relatively perforated boxes, allows you to form a more dense fish shield, formed by flexible tapes.

According to claim 8 of the claims. The implementation of the device with the garbage collection tray located in the upper part of the stream, and its connection with the garbage disposal allows you to effectively remove suspended garbage and juvenile fish, concentrated in the surface horizon of the stream.

The solution to this problem is achieved by implementing a new method of controlling the water withdrawal regime and creating a new design of a fish protection device and its variant. Graphic material that explains the essence of the invention is presented in the following figures:

figure 1 - fish protection device, plan;

figure 2 - section aa in figure 1;

figure 3 - the same, in the case of the operation of water-air jets;

figure 4 - the end part of the blinds, a fragment of the connection of the perforated pipe with the blinds;

figure 5 - the end part of the blinds, a fragment of the connection of the perforated duct with a perforated pipe;

6 is an end part of the blinds, a fragment of the connection of the perforated pipe with the blinds, an option with flexible tapes attached on both sides relative to the nozzles of the perforated pipes;

7 is the same, a variant of perforated boxes with flexible tapes attached on both sides relative to the perforated boxes;

Fig.8 is a longitudinal section through the device, the tiered arrangement of the blinds installed at the same angle to the flow;

Fig.9 is the same, an option with flexible tapes;

figure 10 is a longitudinal section through the device, the tiered arrangement of the blinds installed at different angles to the flow;

11 is a longitudinal section through the device, the option of working perforated boxes with the creation of water-air hydraulic jets;

Fig - the same, the blinds are installed at different angles to the flow of the supply channel;

Fig - a fragment of the plan, the blinds are installed at different angles to the flow of the supply channel;

Fig - the same, an option for the operation of water-air hydraulic jets;

Fig - layout of the axes of rotation of longline blinds and individual drives;

Fig.16 is a transverse section bB in Fig.15, the coaxial execution of the axes of rotation of the blinds;

Fig - cross-section bb in Fig, coaxial execution of the axes of rotation of the blinds;

Fig. 18 is a cross-sectional view of G-G in Fig. 15;

Fig - longitudinal section along the axis of rotation of the blinds;

Fig.20 is a longitudinal section DD in Fig.19, shows the water-distributing holes;

Fig.21 is a cross-section EE in Fig.19, a coaxial connection of the axes of rotation of the blinds with the display of water-distributing holes;

Fig.22 is a transverse section FJ in Fig.19;

Fig.23 is a longitudinal section of the blinds, an embodiment of the nozzles in the end part of the blinds facing the supply channel;

Fig - the same option with flexible tapes;

Fig - longitudinal section of the blinds, a variant with perforated boxes;

Fig.26 is the same, an option with flexible tapes;

Fig.27 - a system of individual drives for rotating the blinds, plan;

Fig.28 is a louvre system, a view from the side of the intake channel to the air supply system;

Fig.29 is the same fragment;

Fig.30 is a section 3-3 in Fig.29;

Fig. 31 is a sectional view of II in Fig. 29;

Fig. 32 is a view K of Fig. 29.

The method of controlling the water withdrawal is as follows. Depending on the dynamics of the vertical slope of the juvenile fish in the inlet channel, the operation service sets the tier of the blinds at different angles to the flow of the inlet channel according to the following principle: in the flow horizons containing the maximum concentration of juvenile fish, the blinds are set at the maximum angle to the flow, forming the maximum hydraulic resistance, and in horizons containing a minimum concentration of juvenile fish, the blinds are set at a minimum angle to the flow, forming a minimum hydraulic resistance in eye of the raceway.

The fish protection device includes a louvre system 1 installed in the inlet of the intake channel 2 with the possibility of turning the blinds 3 around the hinges 4 by means of an individual drive 5, while the blinds 3 are facing the flow with their outer surface and are located at an angle to the flow of the supply channel 6, means for preliminary garbage collection and juvenile fish consisting of perforated pipes 7, distributing manifold 8, pressure pipes 9 and a pump (not shown), while the blinds 3 are made vertically to the entire depth of the stream and with their bottom vertical edges connected to vertical perforated pipes 7, moreover, the rotation axes 10 of the blinds 3 are mounted in hinges 4 with the possibility of rotation by means of a drive 5 and are connected to a distribution manifold 8 connected to a pump (not shown), while the outlet openings 11 of the perforated pipes 7 equipped with nozzles 12 mounted coaxially with the perforation holes 11, and flexible elastic elements 13 attached to the side surface of the perforated pipes 7. The working surface of the blinds 3 is made in the form of a rigid plate speed, and the louvre system 1 is made in tiers 14, 15 and 16, each tier being connected to an individual drive 4 and installed in plan along a curved generatrix facing the convex side towards the inlet channel 6, while the perforated pipes 7 are fixed to the vertical edge of the blinds 3 facing the inlet channel 6, the nozzles 12 being made coaxially to the longitudinal axis of the plane of the blinds 3, and the perforated pipes 7 are connected to the axes 10 of rotation of the blinds 3 made hollow, while the axis of rotation 10 is made coaxially and pivotally connected to the distributing manifold 8, and flexible elastic elements 13 are made in the form of tapes.

In addition, flexible elastic bands 13 can be fixed on both sides with respect to the nozzles 12 of the perforated tubes 7.

In addition, the device can be equipped with a waste collection tray 17 and a waste collection 18. The tray 17 can be made in the form of a half-tray, the open part facing the inlet channel 6 and installed downstream of the louver system 1, and the end part of the waste collection tray 17 communicates with garbage collection 18.

In addition, the device can be equipped with perforated boxes 19 with nozzles 12, and the perforated boxes 19 are fixed along the perforated pipes 7 with the formation of the air supply cavity 20 in communication with the atmosphere, while nozzles 12 are fixed on the inner surface of the perforated boxes 19, and the holes of the nozzles 12, perforations of pipes 7, ducts 19 and the longitudinal plane of the blinds 3 are aligned.

In addition, the nozzle 12 can be made in the end part of the blinds 9, facing the supply channel 5.

In addition, flexible elastic bands 13 can be secured to perforated boxes 19.

In addition, flexible elastic bands 13 can be secured on both sides with respect to the perforated boxes 19.

Individual drives 5 are installed on the service bridge 21.

Axes 10 have distribution holes 22.

In the process of forming water-air hydraulic jets, a torch 23 of an air-bubble curtain is formed.

To ensure the supply of air from the atmosphere into the inner space of the air supply cavities 20 there is a supply air duct 24 connected by flexible reinforced hoses 25 with pipelines 26.

Fish protection device operates as follows.

The operation service of the water intake structure, depending on the dynamics of the vertical slope of the juvenile fish, sets the blinds 3, namely their tiers 14, 15 and 16, in the combination that corresponds to the real picture of the slope of the juvenile fish in the inlet channel 6. The technology for installing the tiers is as follows. The control of specific flow rates taken is carried out according to the depth of the flow of the supply channel 6 by setting tiers 14, 15 and 16 using individual drives 5, at different angles to the flow of the supply channel 6. Moreover, the maximum hydraulic resistance to the flow of the supply channel 6 is formed in those flow horizons in which the maximum concentration of juvenile fish is observed, while the blinds 3 are set at the maximum angle to the flow, and the minimum hydraulic resistance to the flow is formed in those horizons In which there is a minimum concentration of juvenile fish, setting 3 shutters at a minimum angle to the flow of the raceway 6.

Two options for the operation of the fish protection device are possible: the first - when the nozzles 12 form hydraulic jets (Figs. 4, 6, 8 and 9) and the second - when the perforated boxes 19, air supply cavities 20, nozzles 12 and outlet openings 11 form water-air hydraulic jets (Fig. .3, 5, 7, 11, and 12) and the torch 23 of the air bubble veil, which transports suspended garbage and juvenile fish to the upper horizons of the stream. Air is supplied from the atmosphere to the blinds 3 of the lower tiers 15 and 16 through a supply duct 24 connected by flexible reinforced hoses 25 to pipelines 26, which, in turn, are connected to the perforated boxes 19. The upper and lower parts of the perforated boxes 19 tiers 15 and 16 are muffled.

Both in the first and in the second variants of operation, the end parts of the blinds 3 facing the inlet channel 6 can be provided with flexible elastic elements 13 made in the form of tapes. In this case, the flexible elastic elements 13, under the dynamic influence of hydraulic or water jets, form a continuation of the screen formed by the blinds 3, which intensively scares away the young fish from the intake channel 2.

The presence of garbage collection tray 17 and garbage collection 18, allows you to effectively remove garbage and young fish from the influence zone of the intake channel 2.

The use of individual drives 5 (FIGS. 15 and 27) fully corresponds to the operational needs of the water intake structure.

A variant of the operation of the blinds 3 is possible, when the nozzles 12 are attached directly to the end part of the blinds 3 facing the inlet channel 6 (Figs. 23 and 24). In addition, it is possible to use the option when the perforated boxes 19 are attached directly to the end part of the blinds 3, facing the supply channel 6. In this case, the outlet holes 11 (perforation holes) are made on the end part of the blinds 3, and the nozzles 12 are fixed on the inner surface perforated boxes 19 (Fig.25).

The proposed method and the fish protection device that implements it allows one to control the water withdrawal regimes in conditions of changes in the dynamics of the vertical slope of juvenile fish, and, in full accordance with the biological characteristics of the protected object, provide a high level of fish protection.

Information sources

1. A.S. USSR No. 1551776 (USSR). E 02 B 8/08, 9/04. Water intake facility. Bondarenko V.L. and etc.

2. RF patent No. 2023795 (USSR). E 02 B 8/08, 9/04. The method of controlling the regime of water withdrawal and fish protection device. Chistyakov A.A., Shkura V.N., Shkura V.N., Pryadko A.A. Publ. 11/30/94. B.I. No. 22, 1994.

3. A.S. USSR No. 1441818 (USSR). E 02 B 8/08, 9/04. Fish protection device. Chistyakov A.A., Prokopov N.A., Borovskoy V.P., Fomenko V.A. Publ. 02/28/89. B.I. No. 8, 1989.

Claims (8)

1. A method of controlling the water withdrawal mode, including changing by means of a planned arrangement of the planes of the louvre system with respect to the flow of the supply channel and installing the blinds at an acute angle to the direction of the longitudinal velocity of the flow of the supply channel, taking a calculated water flow into the water intake between the planes of the blinds and simultaneously forming by supplying hydraulic or water jets of intensive garbage-discharge flows in inlet water inlets formed by the vertical planes of the louvre system, at a speed exceeding the critical swimming speed of juvenile fish, and regulating the magnitude of the taken unit costs in the section of the inlet of the intake channel, characterized in that the regulation of the magnitude of the taken unit costs is carried out along the depth of the feed channel through the use of individual drives and the blinds are installed at different angles, and the maximum hydraulic resistance to the flow of the supply channel is formed in the horizons of the flow ka with a maximum concentration of juvenile fish, setting the blinds at a maximum angle to the flow of the supply channel, and the minimum hydraulic resistance is formed in horizons with a minimum concentration of young fish, setting the blinds at a minimum angle to the flow of the supply channel. 2. Fish protection device of the water intake structure, including a louvre system installed in the inlet of the water intake channel with the possibility of turning the blinds around the hinges by means of an individual drive, while the blinds are facing the flow with their outer surface and are located at an angle to the flow of the supply channel, means for preliminary garbage collection and juvenile fish, consisting of perforated pipes, a distributing manifold, pressure pipes and a pump, while the blinds are made vertical to the full depth the flow and one vertical edge thereof are connected to vertical perforated pipes, the rotation axes of the louvres being pivotally mounted by means of a drive and connected to a distributing manifold connected to the pump, while the outlet openings of the perforated pipes are equipped with nozzles mounted coaxially with the perforation holes and flexible elastic elements attached to the side surface of perforated pipes, characterized in that the working surface of the blinds is made in the form of a rigid plane and the louvre system is made in tiers, each tier being connected to an individual drive, and installed in plan along a curvilinear generatrix, convex side facing the inlet channel, with perforated pipes fixed to the vertical edge of the louver facing the inlet channel, the nozzles being made coaxially with the longitudinal axis of the blinds, and the perforated pipes by means of pressure pipes made in the form of cavities inside the blinds are connected to the rotation axes of the blinds made hollow at m rotational axis coaxial and formed louvers pivotally coupled to share a collector, and the elastic flexible elements are in the form of ribbons. 3. The device according to claim 2, characterized in that the flexible elastic bands are fixed on both sides relative to the nozzles of the perforated pipes. 4. The device according to claim 2 or 3, characterized in that it is equipped with a garbage disposal and a waste collection tray made in the form of a half-tray, with the open part facing the inlet channel and installed downstream of the louver system, and the end part of the waste collection tray communicates with the waste collection. 5. Fish protection device of the water intake structure, including a louvre system installed in the inlet of the water intake channel with the possibility of turning the blinds around the hinges by means of an individual drive, while the blinds are facing the flow with their outer surface and are located at an angle to the flow of the supply channel, means for preliminary garbage collection and juvenile fish, consisting of perforated pipes, a distributing manifold, pressure pipes and a pump, while the blinds are made vertical to the full depth the flow and one vertical edge thereof are connected to vertical perforated pipes, the rotation axes of the louvres being pivotally mounted by means of a drive and connected to a distributing manifold connected to the pump, while the outlet openings of the perforated pipes are equipped with nozzles mounted coaxially with the perforation holes and flexible elastic elements, characterized in that the working surface of the blinds is made in the form of a rigid plane, and the louvre system is made in tiers, each tier connected to an individual drive, and installed in plan along a curved generatrix, convex side facing the inlet channel, while the perforated pipes are fixed to the vertical edge of the blinds facing the inlet channel, and the perforated pipes by means of pressure pipes made in the form of cavities inside blinds are connected to the axis of rotation of the blinds made hollow, while the axis of rotation of the blinds are made coaxial and pivotally connected to the distributing manifold, and flexible elastic the elements are made in the form of tapes, while the perforated pipes are equipped with perforated boxes with nozzles, and the perforated boxes are fixed along the perforated pipes with the formation of an air supply cavity in communication with the atmosphere, while the nozzles are fixed on the inner surface of the perforated boxes, and nozzle holes, perforated pipes, boxes and the longitudinal axis of the blinds are aligned. 6. The device according to claim 5, characterized in that the flexible elastic bands are fixed to the perforated boxes. 7. The device according to claim 5, characterized in that the flexible elastic bands are fixed on both sides relative to the perforated boxes. 8. The device according to any one of paragraphs.5, 6 and 7, characterized in that it is equipped with a garbage disposal and a waste collection tray made in the form of a half-tray, with the open part facing the inlet channel and installed downstream of the louver system, and the end part of the waste collection tray communicates with garbage collection.

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