RU2335600C1 - Way of attracting and passing of fish from tailrace canal of waterworks facility to headrace canal and fish way implementing it - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: way of attracting and passing of the fish from the tailrace canal of the waterworks facility to the headrace canal involves creating a controllable water flow along the entire fish-passing canal in each fish way chamber as a result of feeding water by means of pumps or bypass pressure pipes coupled with the headrace canal and integrated into the system of stream forming nozzles. This forms a flow resistance moving along the fish-passing canal through the fish way chambers from the headrace canal resulting in favourable conditions for passing of the fish through the swim-in holes of the fish way towards the headrace canal. A part of the fish way chambers, whose systems of stream forming nozzles of fish-passing holes take the water by means of bypass pressure pipes connected to the headrace canal, discharges the water by means of lateral pipelines or canals into the tailrace of the waterworks facility. This provides an attracting flow sufficient for attracting the fish into the fish way and passing them to the headrace canal. Water consumption supplied using bypass pressure pipes and discharges in the tailrace canal is set up for each swim-in hole separately, which controls a value of the additional force forming the attracting flow. The fish way chambers equipped with bypass pressure pipelines or canals interconnecting the systems of nozzles with the headrace canal are linked by means of discharge pipelines or canals with the tailrace canal of the fish way, which results in a steady operation of the fish way. The bypass pressure pipelines or canals and discharge pipelines or canals are equipped with valves or closure systems enabling to control the operation of the fish way.

EFFECT: enhancement of fish attraction to the fish way and passing of them to the headrace canal of the waterworks facility.

8 cl, 4 dwg

Description

The invention relates to hydraulic engineering, and in particular to methods and structures designed to attract and transfer fish producers through retaining structures to spawning and feeding grounds.

There is a method of attracting and transferring fish from the lower tail of the hydroelectric system to the upper one, proposed by O. Vvedensky (RF patent No. 2130991, CL ЕВВ 8/08, published. 1999.05.27, Bull. No. 15), and a method for transporting liquid from the first section to the second, higher located section, proposed by O. Vvedensky (RF patent No. 2179265, class F04F 5/02, published. 2002.02.10, Bull. No. 4), consisting in the formation of a controlled water flow along the entire length of the fish passage tract, depending on the difference in levels of the upper and lower pools, as well as the type passing fish created in each chamber of the fish passage as a result of water supply through the jet-forming nozzles located along the perimeter of the rectangular fish passage hole in the dividing walls, dividing the fish passage into the cameras and directed at an angle to each other, towards the upstream, subsequent formation two rows of flooded hydraulic jets and the creation, with the joint interaction of these hydraulic jets, hydraulic resistance to the flow entering the fish passage (fish passage chambers) from the upper pool, thereby creating favorable conditions for the fish to move towards the upper pool.

The disadvantage of this method is the low efficiency of using static pressure (the difference in elevation and downstream elevations) of the retaining structure.

The closest technological scheme and the achieved result is the method of passing fish through the fish passage tract of the fish passage, proposed by A. Chistyakov (RF patent No. 2236501, cl. ЕВВ 8/08, published. 2004.09.20), which consists in creating a controlled water flow along the entire length of the fish passage tract, while the controlled flow, depending on the difference in the levels of the upper and lower pools and the type of fish passed, create in each chamber of the fish passage as a result of supplying an additional flow of water to the system of jet-forming nozzles located above and below the longitudinal axis of the inlet hole located in the transverse baffle and directed at an angle to each other and towards the upstream, followed by the formation of two rows of flooded hydraulic jets and the creation of the combined hydraulic interaction of these hydraulic jets of hydraulic resistance to the flow coming through the fish passage and the fish passage chambers from the upstream, and thereby favorable conditions for the fish to pass through the inlet opening towards the upstream, and the hydraulic jets are formed directly in the inlet of the transverse septum or in autonomous channels made around the perimeter of the fish passage, and may be pre-twisted, the power jet forming nozzles can be arranged by means of pumps or pumps and integrated by-pass line of the upstream by using the kinetic energy of the level difference of the upper and lower water befov (claim 6).

The main disadvantage in the case of power supply of jet-forming nozzles with the help of a bypass pipe from the upper pool is the impossibility of stable operation of the fish passage.

Known fish passage for the passage of fish from the lower tail of the hydroelectric system to the upper one, proposed by O. Vvedensky and Polyanin A.Ya. (RF patent No. 2130990, CL ЕВВ 8/08, published. 1999.05.27, Bull. No. 15; Application No. 2006113903 dated April 24, 2006), and the design of a pump-ejector installation for transporting liquid from the first section to the second, higher located plot proposed by Vvedensky O.G. and Polyanin A.Ya. (RF patent No. 2178480, class ЕВВ 8/08, published. 2002.01.20, Bull. No. 2), containing drainage trays open from above with transverse vertical dividing walls, separation walls made with rectangular fish-shaped openings located in their lower part equipped with obstruction peaks, along the perimeter of which inside the obstruction peaks there are jet-forming nozzles.

The disadvantage of this fish passage is the low efficiency of skipping fish towards the upstream.

The closest in technological scheme and the achieved result is the design of the fish passage proposed by Chistyakov A.A. (RF patent No. 2236501, CL ЕВВ 8/08, published. 2004.09.20), including a fish passage connecting the lower and upper heads of the hydraulic system, made in the form of chambers connected by transverse partitions and placed in steps or in the form of a channel channel with longitudinal slope towards the downstream side, bottom inlet openings made in transverse partitions, and inlet openings from the upstream side are made with jet forming nozzles in communication with the source of the working medium and placed above and below the longitudinal axis of the inlet hole, while the nozzles are oriented at an acute angle to the longitudinal axis of the inlet openings, and the nozzles are located between the shielding visors placed along the perimeter of the inlet hole above and below the installation plane of the jet nozzles, so that the nozzles are inside the outlet formed by the visors of the inlet hole and are located parallel to the plane of the adjacent shielding visor, so that the jet forming nozzles are made along the entire perimeter of the float hole, with this outlet nozzles are located directly in the inlet openings between the planes of the lateral surfaces of the transverse partitions, and distributing manifolds are made inside the transverse partitions, and the inlet openings may be square, rectangular or round, or the inlet openings in the transverse partition may be half-way, or the height of the inflow openings from the downstream side are larger than the same height from the upper downstream side, as are the end sections of the pressure pipe, adjacent to the nozzles can be equipped with twisting devices that allow the hydraulic jets to be twisted clockwise, counterclockwise, towards each other or in various combinations; in addition, the transverse partition can be made with additional through holes communicating with the upper and lower level, while inside these holes stream-forming nozzles are arranged coaxially with the autonomous channels formed, moreover, part of the fish passage chambers from the lower side the downstream port is in communication with the upper downstream port via a pressure pipe connected to the jet nozzle systems (claim 13).

The main disadvantage of this design of the fish passage is the impossibility of creating a uniform attracting flow in the chambers of the fish passage feeding through the bypass pipe from the upper pool, and as a result, the low efficiency of attracting and passing fish to the upper pool.

The aim of the invention is to create a uniform and stable attracting flow, independent of the method of feeding the systems of jet-forming nozzles, along the entire length of the fish passage, increasing the efficiency of attracting fish to the fish passage and passing it into the upper pool of the hydraulic system.

The invention consists in the following.

According to claim 1 of the claims. The discharge of water through the outlet pipelines (channels) to the downstream end of the hydraulic system from the fish passage chambers, in which the jet-forming nozzle systems of the fish passage openings are fed by the bypass pressure pipelines connected to the upper discharge, will ensure the stable operation of the fish passage and obtaining an additional pressure that forms an attractive flow within necessary to attract fish to the fish passage and pass it into the upper pool. This feeding method is possible for fish passage chambers located at the beginning of the fish passage from the downstream side in the presence of a static pressure (the difference of the level marks of the upper and lower pools) of the retaining structure of more than 10 meters. The discharge of water into the lower pool of the hydraulic system from the fish passage chambers is also carried out due to the difference in the level marks above the horizon of the chamber under consideration and the lower pool. In this case, the full energy of the water located in the upper pool of the waterworks will be used quite effectively.

According to claims 2 and 3 of the claims. The independence of the flow of water (liquid) discharged via the outlet pipelines (channels) to the downstream side of the hydraulic system and supplied through the bypass pressure pipelines (channels) connected to the top head for a part of the fish passage chambers will allow flexible control of the fish passage operation.

According to claims 4 and 5 of the claims. The value of the additional pressure forming the attracting flow is adjusted on one or a group of dividing walls of the fish passage chambers by changing the flow rate of water supplied through the bypass pressure pipelines connected to the upper head of the hydraulic system to the jet-forming nozzles of the fish passage (inlet) openings made in these dividing walls, or by changing the discharge rate of water using outlet pipes (channels) from part of the fish passage chambers to the downstream of the hydraulic system. Such adjustment is carried out as the water levels in the head of the waterworks or the species composition of the moving fish changes.

According to claim 6, claims. The connection through the outlet pipelines (channels) to the downstream side of the hydraulic system of the fish pass chambers equipped with pressure bypass pipelines (channels) connecting the nozzle systems to the upstream head will ensure stable operation of the fish passage with the efficient use of the total energy of the difference in the levels of the head of the hydroelectric system while reducing the energy consumption earlier on pump operation.

According to claims 7 and 8 of the claims. The equipment of pressure bypass pipelines (channels) and discharge pipelines (channels) with valves (locking devices) will allow you to control the operation of the fish passage.

The solution to this problem is achieved by implementing a new method of attracting and passing fish from the lower pool of the hydraulic system to the upper pool and creating a new design of the fish passage. Graphic material that explains the essence of the invention is presented in the following figures:

figure 1 is a General diagram of the fish passage and the method of its placement in the alignment of the dam hydroelectric station;

figure 2 is a longitudinal section of a fish passage with jet-forming nozzles located around the perimeters of the fish passage openings, a variant of supplying the systems of jet-forming nozzles of the fish passage chambers located at the beginning of the fish passage, from the downstream side by means of bypass pressure pipelines connected to the upper downstream;

figure 3 is a longitudinal section of a fish passage with jet-forming nozzles located directly in the fish passage holes, a variant of supplying systems of jet-forming nozzles of fish passage chambers located at the beginning of the fish passage, from the downstream side by means of bypass pressure pipelines connected to the upper downstream;

4 is a longitudinal section of a fish passage with jet-forming nozzles located in autonomous channels, a variant of supplying systems of jet-forming nozzles of fish passage chambers located at the beginning of the fish passage, from the downstream side by means of bypass pressure pipelines connected to the upper downstream.

The fish passage (figure 1) is placed in the alignment of the dam 1 of the waterworks and is performed in the form of an open step, inclined or inclined-step overflow channel (fish passage path) 2, connecting the upper and lower downstream of the waterworks. Inside the spillway of the fish passage tract 2, vertical (dividing) walls 3 are installed (FIGS. 1-4), forming the fish passage chambers 4. In the dividing walls 3, there are rectangular, square or round fish pass (inlet) openings 5 equipped with barriers 6 formed by shielding barriers installed along the entire perimeter of the passage (fish pass) openings 5 parallel to the jets. Inside the barrier visors around the perimeters of the fish passage (swimming) holes 5 (figure 2) or directly in the fish passage (swimming) holes (figure 3), or in autonomous channels 7 (figure 4) there are jet-forming nozzles 8 parallel to the axis of the fish passage holes (figure 2) or at an acute angle (figure 3, 4). The system of jet-forming nozzles 8 fish passage holes 5 chambers 4 of the fish passage, located at the beginning of the fish passage, from the downstream side, through supply pipelines 9 (Fig. 2) or distributing manifolds 10 (Figs. 3, 4) are connected via bypass pressure pipelines 12 to the upper pool waterworks. In turn, the chambers 4 of the fish passage, equipped with pressure bypass pipelines (channels) 12 connecting the nozzle systems with the upper pool, are connected through the discharge pipelines (channels) 13 to the lower pool of the hydraulic system (Figs. 2-4).

In addition, all bypass pressure pipelines (channels) 12 (Fig.2-4) equipped with valves 14.

In addition, all the outlet pipelines (channels) 13 (Fig.2-4) are equipped with valves 15.

The method of attracting and passing fish from the lower pool of the hydraulic system to the upper pool through the fish passage is as follows.

The working fluid (water) is supplied to the nozzles 8 from the supply pipelines 9 (FIG. 2), which are placed around the perimeters of the fish passage holes 5, or from the distributing manifolds 10 located inside the partition walls 3 (FIGS. 3-4). When water flows through these nozzles 8, rows of parallel hydraulic jets are formed, which, interacting with each other, contribute to the formation of partially equal pressure zones (backpressure plots) in front of the swimming (fish passage) holes 5. Thanks to the creation of zones of partially equal pressures, fish producers can freely pass through the fish passage from the lower tail of the hydraulic system to the upper tail. Jet-forming nozzle systems 8 fish passage openings 5 chambers 4 fish passageways supply the complex. Moreover, the fish passage chambers located at the beginning of the fish passage, from the downstream side, in the presence of a static pressure (the difference of the level marks of the upper and lower heads) to the retaining structure of more than 10 meters, are fed with the help of bypass pressure pipelines (channels) 12 connected to the upper head. At the same time, the upper chambers 4 of the fish passage, where the static pressure does not allow to create a given pressure in the power system of the jet nozzles 8, are fed with the help of pumps 11 (Figs. 2-4). To ensure stable operation of the fish passage and obtaining an additional pressure ΔH, which forms an attracting flow to the extent necessary to attract fish into the fish passage and passing it into the upper pool, water is discharged using the outlet pipelines (channels) 13 to the lower pool of the hydraulic system (Fig. 2- four). The outlet pipelines (channels) 13 are equipped with those fish passage chambers 4, for which the systems of the jet-forming nozzles 8 are powered by the bypass pressure pipelines (channels) 12 connected to the upper pool. This is a prerequisite for the successful operation of the fish passage, otherwise, with the integrated power supply system for the jet-forming nozzles 8, the fish passage will not work to let the fish pass into the upper pool (the fish passage will pump water from the lower pool to the upper pool of the hydraulic system).

The implementation of the method in the case of independence of the flow rate of water supplied using the bypass pressure pipelines (channels) 12 connected to the upper head and discharged using the outlet pipelines (channels) 13 to the downstream side of the water system, for a part of the fish passage chambers 4 it will be possible to separately establish the actual pressure water falling on the separation walls of this part of the fish passage chambers. In this case, flexibility is achieved in controlling the operation of the fish passage.

Setting the magnitude of the additional pressure ΔH (Figs. 2-4), which forms an attracting flow, on one or a group of dividing walls 3 of the fish passage by changing the flow rates of water supplied by the bypass pressure pipelines 12 connected to the upper head of the hydraulic system to the jet-forming nozzles 8 of the fish passage (swimming ) holes 5, made in these dividing walls 3, will create a uniform, attracting fish flow along the entire length of the fish passage. The value of the additional pressure ΔH is set depending on the type of fish passed through the fish passage by changing the initial velocities V _{0 of the} outflow of hydraulic jets from nozzles 8 installed around the perimeter of the fish passage holes 5 made in these separation walls 3 of the fish passage, i.e. change the pressure value H _CP.N , which can be held on the partition wall 3 by means of hydraulic jets. The values of the initial velocities V _{0 of the} outflow of hydraulic jets from the nozzles are set using valves (shut-off devices) 14 installed on the pressure bypass pipelines (channels) 12. In this case, all actual pressures attributable to all the separation walls 3 of the fish passage will be redistributed.

It is possible to implement the method in the case of regulating the value of the additional pressure ΔH on one or a group of dividing walls 3 of the fish passage chambers 4 by changing the discharge rates of water using outlet pipelines (channels) 13 from the fish passage chambers 4 to the downstream of the hydraulic system (Figs. 2-4). In this case, the value of the additional pressure ΔH is set depending on the type of fish passed through the fish passage by changing the values of the actual pressure falling on the separation walls 3 of the fish passage. The value of ΔH is determined by the difference between the actual pressure attributable to the separation wall 3 of the fish passage, and the pressure value H _CP.N , which can be held on the separation wall 3 using hydraulic jets. The change in the flow of discharged water from the chambers of the fish passage 4 to the downstream of the hydraulic system is carried out using valves (shut-off devices) 15 installed on the discharge pipelines (channels) 13. Correction of the additional pressure ΔH, which forms an attracting flow, in any of the chambers of the fish passage will cause a redistribution of all pressure attributable to all dividing walls 3 of the fish passage. As a result of such a chain of transformations, an attracting flow is established that is uniform along the entire length of the fish passage tract 2 (Figs. 1-4).

The fish passage for attracting and passing fish from the lower pool of the hydraulic system to the upper pool works as follows.

With the beginning of the filling of the fish passage tract 1 with water (Fig. 1), pumps 11 (Figs. 2-4) are turned on, which provide power to the systems of the jet-forming nozzles 8 of the upper chambers 4 of the fish passage. At the same time, for supplying the systems of the jet-forming nozzles 8 of the lower chambers 4 of the fish passage (Figs. 2-4), water is supplied from the upstream bypass pressure pipelines (channels) 12. To ensure the functioning of the fish passage, water is discharged from the lower chambers 4 of the fish passage using outlet pipelines (channels) 13 to the downstream of the hydraulic system. The system of jet-forming nozzles 8 form hydraulic jets along the perimeters of the fish passage (swimming) openings 5 in the separation walls 3, which create hydraulic resistance (zones of partially equal pressures), which facilitate independent and unhindered passage of fish through all the swimming (fish passage) holes of the fish passage from the downstream of the hydraulic system into upper pool. To attract fish into the fish passage, the orientation of the fish in the chambers 4 of the fish passage and the fish finding the swimming holes 5, the presence of an attracting stream is necessary (Figs. 2-4). It is created with the help of an additional pressure ΔH, the value of which is regulated with the help of valves (shut-off devices) 14 or 15 installed, respectively, on the pressure bypass pipelines (channels) 12 or discharge pipelines (channels) 13. The value of the attracting flow is set in accordance with the type fish moving along the fish passage on one or a group of dividing walls 3 of the 4 fish passage chambers.

The most preferred placement of the jet nozzles 8 is the option shown in figure 2. The undoubted advantage of the technical solution of the fish passage is the equipment of the fish passage chambers 4 with discharge pipes (channels) in case of supply of the jet-forming nozzle systems 8 of the chambers 4 by means of pressure bypass pipelines 12, as well as equipping the pressure and discharge piping bypass valves (shut-off devices) 14, 15 (Fig. 2-4), allowing to control the operation of the fish passage.

The proposed fish passage for attracting and passing fish from the lower pool of the hydroelectric station to the upper pool allows you to create a controlled backpressure in front of the swim (fish passage) openings of the fish passage and a uniform, adjustable, attracting fish flow throughout the fish passage, which maximally contributes to independent and free passage of fish from the lower downstream of the waterworks in the upstream.

Claims (8)

1. The method of attracting and passing fish from the lower pool of the hydroelectric system to the upper pool, which consists in the formation of a controlled water flow along the entire length of the fish passage tract, depending on the difference in the levels of the upper and lower pools and the type of fish passed in each fish passage chamber as a result of the flow of water by means of pumps or bypass pressure pipelines connected to the upstream, into jet-forming nozzles located along the perimeter of the fish passage, i.e. swimming, holes, or directly in the fish holes, or in autonomous channels made in the dividing walls, and directed towards the upper pool, the subsequent formation of parallel or at an angle to the axis of the swimming hole rows of flooded parallel hydraulic jets, and the jets may be pre-twisted, and the creation of the joint flow of these series of jets of hydraulic resistance to the main stream, i.e. zones of partially equal pressures entering the fish passage through the fish passage chambers from the upper pool, and thereby favorable conditions for the fish to pass through the inlet opening towards the upper pool, characterized in that from the part of the fish passage chambers in which the jet-forming nozzle systems of the fish passage holes are fed by bypass pressure pipelines connected to the upper pool, discharge water using the discharge pipes or channels into the lower pool of the hydraulic system, and additional Op forming attracting stream to the extent necessary to raise fish in the fish ladder, and passes it to the upstream. 2. The method according to claim 1, characterized in that the water flow discharged using the discharge pipelines or channels into the downstream of the hydraulic system is set separately for the fish passage chambers. 3. The method according to any one of claims 1 and 2, characterized in that the flow rate of water supplied through the bypass pressure pipelines connected to the upstream for supplying systems of jet-forming nozzles of the fish passage holes of the fish passage chambers is set separately for each such fish passage chamber . 4. The method according to claim 1, characterized in that the magnitude of the additional pressure that forms the attracting stream is regulated on one or a group of dividing walls of the fish passage by changing the flow rates of water supplied through the bypass pressure pipelines connected to the upper head of the hydraulic system to the jet-forming nozzles of the fish passage, those. floating, holes made in these dividing walls. 5. The method according to claim 1, characterized in that the magnitude of the additional pressure forming the attracting flow is controlled on one or a group of dividing walls of the fish passage chambers by changing the flow rates of water discharged using the outlet pipelines or channels from these fish passage chambers to the downstream of the hydraulic system. 6. Fish passage for attracting and passing fish from the lower pool of the hydraulic system to the upper pool, made in the form of a stepped or inclined tray or channel with a longitudinal slope towards the lower pool, containing transverse vertical dividing walls dividing the fish channel into chambers, with fish passage located in them , i.e. swimming, rectangular, square or round holes, along the perimeter of which there are jet-forming nozzles and which are equipped with obstruction shields so that the nozzles are inside the outlet portion of the float hole formed by the visors and are parallel to the plane of the shielding wall of the adjacent guard visor, and the nozzle outlet openings are located directly in the swimming holes between the planes of the lateral surfaces of the transverse dividing walls and whether in the autonomous channels, in addition, the jet-forming nozzles are in communication with supply pipelines or distributing collectors made inside the transverse dividing walls, moreover, a part of the fish passage chambers from the downstream side are connected to the upper pool by means of a pressure bypass pipe connected to systems of jet-forming nozzles, characterized in that the fish passage chambers equipped with pressure bypass pipelines or channels connecting the nozzle systems to the upper pool are connected to the lower pool of the hydraulic system by means of discharge pipelines or channels. 7. The fish passage according to claim 6, characterized in that the pressure bypass pipelines or channels connecting the jet-forming nozzle systems of the fish passage, i.e. floating, openings with the upper pool of the hydraulic system, equipped with gate valves or locking devices. 8. The fish passage according to any one of claims 6 and 7, characterized in that the outlet pipelines or channels connecting the fish passage chambers to the downstream of the hydraulic system are equipped with valves or shut-off devices.

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