RU2245414C1 - Method to control modes of fish passing through fish conduit - Google Patents

Abstract

FIELD: hydraulic engineering.

SUBSTANCE: invention relates to hydraulic works designed for passing fish spawners through retaining facilities to places of spawning and fattening. Control of fish passing through fish conduit comes to creating fish attraction water fed from upper pond of hydraulic works into fish conduit and further into lower pond, forming favorable hydraulic conditions directly in fish conduit by changing water level drop between cross partitions by displacing partitions proper relative to bottom of fish conduit and creating overcomable velocity in swim-in holes of partitions. Partitions are displaced along length of fish conduit by driven in direction of upper pond and, simultaneously with displacement of partitions, water level drop formed between partition formed between partitions is displaced, and value of local water level drop is changed over length of fish conduit owing to nonuniform perforation of sections of partitions having different porosity.

EFFECT: provision of controllable hydraulic conditions in fish conduit contributing to effective movement of fish along its length.

19 cl, 18 dwg

Description

The invention relates to hydraulic engineering, and in particular to methods and structures intended for passing fish producers through retaining structures to spawning and feeding grounds.

Closest to the technological scheme is the method of controlling the passage of fish through the fish passage tract [1], which consists in creating a fish attracting stream supplied from the upper pool of the hydraulic system to the fish channel and then to the lower pool, the formation of favorable hydraulic conditions directly in the fish passage, by changing the level difference water between the transverse partitions by moving the partitions themselves relative to the bottom of the fish passage and creating surmountable speeds in the swimming holes across nny partitions.

The disadvantage of this method is the low degree of controllability in the appointment of modes of passage of fish through the fish passage tract.

Known fish passage [2], including a fish passage, made stepwise, and in the lower part of each stage made distributing collectors connected by a supply conduit to the upper pool.

The disadvantages of this fish passage are low reliability and low efficiency of skipping fish in the upper pool.

Known fish passage [3], including a fish passage path connecting the lower and upper heads of the hydraulic system and made stepwise, with the bottom of each stage made perforated, while the perforation holes communicate with the working chambers in communication with the source of the working medium.

The disadvantage of this fish passage is the real danger of harm to fish entering the fish passage, since in the working chambers there are bellows for changing the pressure of the working medium in the chambers, the main working element of which is the electrodes.

Known fish passage [4], including a fish passage tract connecting the lower and upper heads of the waterworks and made stepwise, and the bottom of each stage ends with a threshold on which a spillway in the form of an elastic shell with the possibility of vertical movement is installed.

The disadvantage of this fish passage is the lack of favorable conditions for overcoming the local water level difference when moving fish along the fish passage.

Known fish passage [5], including a fish passage tract connecting the lower and upper water system head-ups, made in the form of an escalator device having transverse partitions that form autonomous chambers when moving the fish passage working element.

The disadvantage of this device is the design complexity and the possibility of injury to the fish when it is transferred to the upper pool.

A device is known for transferring fish to the upper pool of a hydraulic system [6], including a tray connecting the lower and upper pool of a hydraulic system made with an inclined bottom, a flexible elastic tape made endless and passed through transverse guides moving in the guide grooves made in the side walls of the tray . At the same time, the endless ribbon during its movement forms transverse partitions moving towards the upstream and forming cameras during its movement, the endless tape being able to freely move in the bottom gallery, made directly under the bottom of the tray, and the guides are connected by an endless chain to the endless tape moving drive .

The disadvantage of this device is the low efficiency of transferring fish to the upper pool, since the presence of a moving, formed during the movement, septum scares off a suitable fish. In addition, the device is complex in design and unreliable in operation.

The closest in technical essence and the achieved result is a fish passage [1], including a fish passage, connecting the lower and upper water heads of the water system, transverse partitions with swimming holes located in a checkerboard pattern, while the partitions can move along the length of the fish passage through the drive and are installed in pairs, at an acute angle to each other, while their vertices are located on the transverse guides having the same degree of freedom.

The disadvantage of this fish passage is the low efficiency of controlling the regimes of skipping fish in the upper pool and, accordingly, the low efficiency of skipping fish in the upper pool.

The aim of the invention is the creation of effective hydraulic conditions in the fish passage, providing the ability to control the modes of operation of the fish passage, as well as the creation of effective conditions for the advancement of fish along the length of the fish passage.

The invention consists in the following.

According to claim 1 of the claims. Due to the implementation of the partitions in the form of a flexible elastic tape, made endless and passed through the transverse guides, it is possible to regulate the local water level difference in the fish passage, formed by sections of the endless tape. The optimization of the control of the water level difference in the inter-partition space is facilitated by the implementation of an endless belt of sections having different throughness of the working flexible canvas. In this case, the alternation of areas with different throughness (for example, with a decrease in throughness, and accordingly, the size of the inlet openings in the direction of the upper pool, Fig. 5) allows you to simulate the movement of the local water level difference formed in the "inter-partition" space formed by an endless ribbon in the alignment transverse guides. Thus, the difference in water level in sections of the endless belt varies according to a given program, and at the same time along the entire length of the fish passage tract (Fig. 18). If we carefully analyze the pattern of changes in the local difference in water levels between the sections of the endless belt formed by the main 7 and additional 9 guides, we can note the following:

- sections of the endless belt formed by the working canvas with maximum throughness, allow you to form a water level difference with a minimum value (Fig. 18, pos. 26). In this case, the fish located in front of this section of the endless belt has the ability to move higher, that is, in the direction of the upstream, since the minimum difference in water level dictates the minimum flow velocity in the inlet openings 5;

- sections of the endless belt 10 formed by the working canvas with an average throughness (Fig. 18, item 27) partially allow a certain group of fish to move up to the overlying section of the fish passage tract, if its swimming ability and energy capabilities, as well as the size of the swimming holes 5, are allow. The rest of the fish, who did not want to move upstream, remains within this local section of the fish passage tract and has the likelihood of further movement during the formation of the corresponding favorable hydraulic conditions, as the endless belt 10 moves;

- sections of the endless belt formed by the working canvas with the minimum throughness (Fig. 18, pos. 28) create the maximum drop in the water level in the sections of the endless belt 10, which, in turn, complicates the movement of fish towards the upper pool and delays for a certain time fish in these sections of the fish passage tract. However, this negative point cannot and does not beg the merits of the proposed technological scheme of the process of passing fish through the fish passage. In any case, with further movement of the endless belt 10, the fish has all the possibilities to go up the fish passage path 1 (see the previous two paragraphs). The most important advantage of the proposed method for controlling the modes of fish passage through the fish passage path is the creation of favorable hydraulic conditions for the fish to move along the fish passage path 1 by changing the local water level difference, which has not yet been applied in any known fish passage examination. This method involves the optimal passage of fish of different species and with different levels of swimming ability, regardless of the dynamics of external environmental factors. On the other hand, the proposed method creates conditions that provoke the fish to further its advancement and at the same time create conditions for its temporary rest, making it possible to restore its energy capabilities, while the design of the fish passage does not allow previously entered fish to slide back into the lower pool.

According to claim 2 of the claims. It is possible to create more favorable conditions for the fish to move along the fish passage, for example, by changing the speed of the endless belt, it is possible to achieve stable hydraulic conditions under which the dynamics of the local differential will be close in physics to the effect of the "traveling wave", and the direction of movement of this wave will be directed towards the upstream, which in turn will contribute to the active movement of fish also towards the upstream. What else actually gives a change in the speed of movement of an endless tape? Firstly, a fairly rapid change in the local water level difference (it goes without saying that the speed of the endless belt cannot be "infinite", but due to the technical capabilities of the technological equipment that is part of the mechanical equipment of the fish passage) will stimulate the fish to actively move towards the upstream . Secondly, a fairly rapid change in hydraulic conditions (the average flow velocity across the width of the fish passage, the speed in the inlet openings and the magnitude of the water level difference) creates favorable conditions both for the fish to be in the fish passage and for its movement towards the upper pool.

According to claim 3 of the claims. All constructive essential features of the distinctive part of this independent claim allow and contribute to the new design of the fish passage, which, without a doubt, fully allows the proposed method to control the passage of fish through the fish passage. Let us consider the above statement in more detail.

The presence of the bottom gallery makes it possible to move the endless belt along the entire length of the fish passage, taking into account the structural features of the proposed design of the fish passage.

The presence of additional guides and their location in the bottom of the fish passage tract allows you to form a given shape of the transverse partitions that take place in the prototype. In addition, both the main and additional guides make it possible, when passing through them a flexible elastic web (tape), made endless, to form the working elements of the fish passage path.

The presence of a minimum clearance between the generators of the additional guides and the bottom of the fish passage allows free movement of the endless belt.

The implementation of the partitions from a flexible elastic tape allows you to implement the main author’s plan - only moving floating holes made on sections of an endless tape with different throughness, allow to realize the invention. At present, the author knows 450 constructive solutions for fish passageways created in the world practice of designing this type of fish passage structure, and the examination can be sure (of course, after checking this technical solution for novelty) that no known fish passage is capable of implementing such a technology for passing fish into upper pool.

The implementation of the guides with the possibility of rotation around the horizontal axis corresponds to the health of the fish passage, namely, the free movement of an endless belt along the fish passage path. The cylindrical cross-sectional shape of the guides is the optimal contour that provides effective contact of the surface of the endless tape with the guides.

The implementation of the bottom guides located in the bottom niches, made in the input and output parts of the bottom gallery, allows you to optimize the layout of the input and output head of the fish passage, namely, to ensure a minimum of hydraulic resistance to flow and a maximum of conditions for free passage of fish.

The connection of the drive with the driving drum, located at the level of the guides of the main group and installed from the upstream side, is the most rational version of the layout of the endless belt drive mechanism, naturally, taking into account the design features of the proposed design.

In addition, the basic arrangement of the fish passage according to claim 3 has another indisputable advantage compared to analogues: the transverse partitions are perforated (as in the case of the prototype), which allows the maximum allowable water flow through the fish passage, and this, in in turn, it can significantly enhance the "train" of speeds that attracts fish to attract it to the entrance to the fish passage. When choosing a prototype, the author had a certain kind of doubt associated with a set of common structural elements that take place in analogues and in the present invention. However, their own experience in writing the claims and intuition made it possible to choose A.S. as a prototype. USSR No. 1574721. The main argument in favor of this choice is the presence of perforated transverse partitions made with floating holes and having the ability to move along the length of the fish passage. What is not present in any of the analogues presented to the examination. The author does not admit that the examination will select a stronger basic version of the prototype.

According to claim 4 of the claims. The implementation of the fish passage path with side bypass galleries allows you to create a more efficient layout of the fish passage, allowing to ensure the effective attraction of fish from the search zone of the lower pool (figure 2).

The supply of bypass galleries with the shutters of the power unit allows you to adjust the modes of attracting fish depending on changes in the hydraulic conditions of the lower reach (dynamics of the water level of the lower reach, operation mode of the spillway dam, etc.).

The presence of fish gratings from the downstream side prevents fish from entering the interior of the galleries.

According to claim 5, the claims. The implementation of an endless belt with sections having different throughness allows you to create different hydraulic conditions along the length of the fish passage tract, ensuring optimal passage of fish towards the upstream.

According to claim 6, claims. The implementation of an endless tape with sections of different throughness, alternating with increasing (decreasing, everything is relative, because of what to repel, the more the tape turns over and the direction of the location of the perforation holes changes, which makes it impossible to introduce clear certainty when describing this symptom. In this case there is a contradiction that does not meet the rules for constructing a formula and an unambiguous interpretation of an essential attribute !!! In the existing instruction for patent experts and in the new patent There are no direct instructions to the law for resolving this contradiction, except for changing the interpretation of this essential feature. I think that the examination will understand and clarify the position of the author) the size of the float holes, allows you to create local sections along the length of the fish passage tract, characterized by local differences. This circumstance allows you to provide an effective passage of fish in the direction of the upper pool and creates the basic prerequisites for the implementation of the proposed method.

According to claim 7 of the claims. The implementation of the guides of the main group at different elevations, decreasing towards the downstream, allows you to get a more compact layout of the endless belt (reducing the consumption of material from which the tape is made, taking into account the drop on the hydraulic system, reducing the height of the walls of the fish passage and, accordingly, the volume of concrete work, and t .d.), and on the other hand, this arrangement allows you to change the angle of the endless belt relative to the bottom of the fish passage tract and, accordingly, increase the rate of change of the perforated on the canvas of the tape from the side of the downstream (the path that the tape passes decreases and the speed of replacing sections of the tape with different throughness changes from here) The above circumstance makes it possible to control the initial drop in water level, which in many respects dictates the dynamics of changes in drops on the overlying "partitions". In addition, if the distance between the additional guides located at the bottom of the fish passage path is small, then according to the laws of hydraulics of the flow flowing along several resistances located sequentially one after another and located relatively close relative to each other, there will be a mutual influence of local resistances on friend. That is, the downstream resistance will affect the hydraulic resistance of the upstream resistance. Based on the foregoing, this paragraph of the formula has an essential feature that allows you to contribute to the achievement of not a total positive effect.

According to claim 8 of the claims. The implementation of the fish passage tract with a longitudinal slope towards the downstream of the hydraulic system allows you to optimize the layout of the fish passage and, accordingly, reduce the total length of the fish passage. In this case, the average flow velocities along the width of the fish passage path will slightly increase. This variant of the fish passage is recommended for strong swimmers - whitefish, salmon, etc.

According to claim 9, the claims. The implementation between the guides of an additional group of bottom transverse partitions allows you to provide stable hydraulic conditions in the fish passage, in case of a change in the water level in the downstream. In this case, we have the minimum estimated water level in the fish passage, necessary and sufficient for the normal movement of fish through the fish passage.

According to claim 10 of the claims. The implementation of the bottom transverse partitions with swimming holes allows the fish to move freely in the bottom of the fish passage tract.

According to claims 11 and 12 of the claims. The placement of swimming holes in the central part of the bottom transverse partitions or in the parietal region adjacent to the side walls of the fish passage, allows you to create optimal paths for moving fish in the bottom of the stream.

According to item 13 of the claims. The implementation of the guides of the additional group with the possibility of vertical movement in the vertical guide grooves with the possibility of fixing them at a predetermined level allows to reduce the total number of partitions in the case of a decrease in the difference between the pools and thereby optimize the passage of fish into the upper pool.

According to claim 14, 15 and 16 of the claims. The implementation of the swimming holes of a rectangular, rhomboid or round shape allows, using the patterns of change of the inversion of the hydraulic stream passing through the hole of a certain shape, to optimize the passage of fish through the swimming hole. At the same time, the different shape of the swimming holes, contrasting with the shape of the mid-section of the fish, contributes to the optimal passage of fish through the swimming holes upstream.

According to claim 17. The implementation of the endless tape connected to endless chains attached to its end parts, while the guides of the main and additional groups are equipped with gears coaxially located on them from the side walls of the fish passage tract, improves the reliability of moving the endless ribbon along the fish passage path (no broaches, no gap tape, lack of tape stretching, elimination of slipping, etc.).

According to claim 18. The implementation of an endless ribbon of transparent material greatly reduces the reaction of fish fright due to the presence of a moving object in a stream of water.

According to claim 19 of the claims. The implementation of the guide rollers located in the bottom gallery, allows you to optimally move the endless tape, while there is no sagging surface of the tape, and its surface does not have direct contact with the bottom of the bottom gallery.

The author presented in sufficient detail the constructive part of the application, illustrated by extensive graphic material, and tried to describe in detail the principle of the device, and also revealed the essence of the invention, which leaves the examination with a minimum of opportunity to request additional materials. For his part, the author hopes for a constructive dialogue with expertise, which will be fruitful for both interested parties.

In general, both technological and design features of the independent and dependent claims of the invention meet the criterion of "significant differences" and are so interconnected that they form a single creative concept.

The solution to this problem is achieved by implementing a new method for controlling the modes of fish passage through the fish passage and creating a new fish passage construction. Graphic material that explains the essence of the invention is presented in the following figures:

figure 1 - fish passage, a longitudinal section;

figure 2 is the same plan;

figure 3 - fish passage tract, a fragment of the plan, a view of an endless tape attached to endless chains;

figure 4 - the entrance of the fish passage, plan, structure of the fish attracting currents;

5 is an endless tape, fragment, sections with different throughness;

6 is a fish passage, a longitudinal section, an installation option of the main guides at different altitudes;

Fig.7 - fish passage, a longitudinal section, a variant with a longitudinal slope of the bottom;

Fig - the same, an option with bottom transverse partitions;

Fig.9 is a transverse section of the fish passage tract, view of the bottom transverse septum with a central inlet opening;

figure 10 is the same, a view of the bottom transverse septum with a lateral location of the float holes;

11 is a fragment of a longitudinal section of the fish passage tract, showing vertical guide grooves;

Fig - the same, in the case of the release of the fish passageway for washing from sediment;

Fig is a fragment of an endless tape, rectangular swimming holes;

Fig is a fragment of an endless ribbon, diamond-shaped swimming holes;

Fig. 15 is a fragment of an endless tape, round float holes;

Fig - guide with gears;

17 is a section of an endless tape with square swimming holes;

Fig. 18 is a fragment of the fish passage tract, a diagram of the formed local water level differences and an arrangement of guide rollers.

The fish passage includes a fish passage tract 1, connecting the lower 2 and upper 3 of the head of the hydraulic system, the transverse partitions 4 with the inlet holes 5 located in a checkerboard pattern, while the partitions 4 have the ability to move along the length of the fish passage path 1 through the drive 6 and are installed in pairs, at an acute angle to each other, while their vertices are located on the transverse guides 7 located above the water level in the fish passage 1. The fish passage 1 is equipped with a bottom gallery 8 and additional guides 9 located in the bottom part of the fish passage 1 with the formation of a minimum clearance between the generatrix of the guides 9 and its bottom, and the partitions 4 are formed by an endless tape 10 made of flexible elastic material passed between the guides 7 and 9, and the guides of the main 7 and additional 9 groups are made in the form of cylinders, installed with the possibility of rotation relative to the horizontal axis, while the bottom guides 9 located in the input 11 and output 12 parts of the fish passage 1 are made in the bottom niches 13 located at the entrance and the outlet of the bottom gallery 8, and the drive 6 for moving the tape 10 is connected to the driving drum 14 located at the level of the guides 7 of the main group.

In addition, the fish passage tract 1 can be made with lateral bypass galleries 15, having gates 16 of the power supply unit on the upper 3 foot side, and fish grills 17 on the lower 2 foot side.

In addition, the endless tape 10 can be made with sections 18 having different throughness.

In addition, sections 18 with different throughness can alternate with increasing sizes of the inlet holes 5.

In addition, the guides 7 of the main group can be installed at different altitudes, and the marks are reduced to the entrance 11 to the fish passage 1.

In addition, the fish passage tract 1 can be performed with a longitudinal slope towards the bottom 2 of the pool.

In addition, between the guides 9 of the additional group can be made bottom transverse partitions 19.

In addition, the bottom transverse partitions 19 can be made with inlet holes 5.

In addition, the inlet holes 20 can be made in the Central part of the bottom partitions 19.

In addition, the swimming holes 20 can be made at the side walls of the fish passage 1.

In addition, the guides 9 of the additional group may be able to move vertically in the guide grooves 21 made in the side walls of the fish passage 1 with the possibility of fixing at a given level.

In addition, the swimming holes 5 on the endless belt 10 can be made in a rectangular shape.

In addition, the swimming holes 5 on the endless belt 10 can be made diamond-shaped.

In addition, the swimming holes 5 on the endless belt 10 can be made round.

In addition, the endless belt 10 can be made with endless chains 22 attached to its end parts, while the guides of the main 7 and additional 9 groups can be equipped with gears 23 coaxially made on them, from the side walls of the fish passage 1.

In addition, the endless tape 10 may be made of a transparent material.

To attract fish to the input 11 of the fish passage tract 1, an attracting stream 24 is formed, supplied from an additional power supply. Moreover, the hydraulic structure is characterized by a planned plot of 25 speeds.

The endless tape 10 can be made of sections 26 with a maximum throughness, connected to sections 27 with an average throughness, connected to sections 28 with a minimum throughness.

To eliminate the sagging of the endless tape 10 and to exclude direct contact of its surface with the bottom of the bottom gallery 8, guide rollers 29 are installed in the bottom gallery 8.

The method of controlling the modes of passage of fish through the fish passage tract is as follows.

Due to the design of the partitions 4 in the form of a flexible elastic tape 10, made endless and passed through the transverse guides 7 and 9, it is possible to regulate the local water level difference in the fish passage path 1 formed by sections 26, 27 and 28 of the endless belt 10. Optimization of the control of the water level difference in inter-septum space contributes to the implementation of the endless tape 10 of the sections having different throughness of the working flexible canvas. In this case, the alternation of sections 18 with different throughness (for example, with a decrease in throughness and, accordingly, the size of the inlet openings 5 in the direction of the upper 3 downstream, Fig. 5) allows you to simulate the movement of the local water level difference formed in the "inter-partition" space formed by an endless ribbon 10 in the cross sections of the transverse guides 7 and 9. Thus, the water level difference in sections 18 of the endless belt 10 changes according to a given program, and at the same time along the entire length of the fish passage tract 1 (Fig. 18). If we carefully analyze the pattern of changes in the local difference in water levels between the sections 18 of the endless belt 10 formed by the main 7 and additional 9 guides, we can note the following:

- sections 18 of the endless belt 10 formed by the working canvas with a maximum throughness (section 26), allow you to create a water level difference with a minimum value (Fig, pos.26). In this case, the fish located in front of this section 18 of the endless belt 10 has the ability to move higher, that is, in the direction of the top 3 of the pool, since the minimum difference in water level dictates the minimum flow rates in the inlet openings 5;

- sections 18 of the endless belt 10 formed by the working canvas with an average throughness (Fig. 18, item 27) partially allow a certain group of fish to move up to the overlying section of the fish passage tract 1, if its swimming ability and energy capabilities, as well as the size of the swimming holes 5 allow it. The rest of the fish, who did not want to move upstream, remains within this local section 18 of the fish passage tract 1 and has the likelihood of further movement during the formation of the corresponding favorable hydraulic conditions formed as the endless belt 10 moves;

- sections 18 of the endless belt 10 formed by the working canvas with a minimum throughness (Fig. 18, pos. 28) create the maximum drop in the water level in the sections of the endless belt 10, which, in turn, makes it difficult to move the fish towards the upstream side 3 and a certain time delays the fish in these sections 18 of the fish passage tract 1. However, this negative point cannot and does not beg the merits of the proposed technological scheme of the process of passing fish through the fish passage. In any case, with further movement of the endless belt 10, the fish has all the possibilities to go up the fish passage path 1 (see the previous two paragraphs). The most important advantage of the proposed method for controlling the modes of fish passage through the fish passage 1 is the creation of favorable hydraulic conditions for the fish to move along the fish passage 1 by changing the local water level difference, which has not yet been used in any known fish passage. This method involves the optimal passage of fish of different species and with different levels of swimming ability, regardless of the dynamics of external environmental factors. On the other hand, the proposed method creates conditions that provoke the fish to further its advancement and at the same time create conditions for its temporary rest, giving it the opportunity to restore its energy capabilities, while the design of the fish passage does not allow previously entered fish to slide back into the downstream 2.

It is possible to create more favorable conditions for the fish to move along the fish passage tract 1, for example, by changing the speed of movement of the endless belt 10, stable hydraulic conditions can be achieved under which the dynamics of the local differential will be close in physics to the effect of the "traveling wave", and this direction of movement of this waves will be directed towards the upper 3 reach, which in turn will contribute to the active movement of fish also towards the upper 3 reach. The change in the speed of movement of the endless belt 10, firstly, gives a fairly rapid change in the local difference in water level, which will stimulate the fish to actively move towards the upstream. Secondly, a fairly rapid change in hydraulic conditions (the average flow rate across the width of the fish passage, the speed in the inlet openings and the magnitude of the water level difference) creates favorable conditions both for the fish to be in the fish passage 1, and for its movement towards the upper 3 .

Fish passage works as follows.

The operation service opens the shutters 16 of the power supply and the downstream 2 is supplied with an additional flow rate 24 of water, forming a fish-attracting "loop" of speeds, characterized by a planned diagram of 25 speeds (figure 4). At the same time, the drive 6 is turned on and the endless belt 10 starts to rotate at a given speed relative to the main 7 and additional 9 guides, while moving the float holes 5 along the entire length of the fish passage tract 1. The presence of the bottom gallery 8 makes it possible to move the endless belt 10 along the entire length of the fish passage 1.

The presence of an additional 9 guides and their location in the bottom of the fish passage tract 1 allows you to form a given shape of the transverse partitions 4 formed when moving the endless belt 10. The presence of a minimum clearance between the generators of the additional 9 guides and the bottom of the fish passage path 1 allows the endless belt 10 to move freely.

The execution of the guides 7 and 9 with the possibility of rotation around the horizontal axis meets the condition of the fish passage working condition, namely, the free movement of the endless belt 10 along the fish passage path 1. The cylindrical cross-sectional shape of the guides 7 and 9 is the optimal contour that ensures the effective contact of the surface of the endless belt 10 s guides 7 and 9.

The implementation of the bottom guides 9 located in the bottom niches 13, made in the input and output parts of the bottom gallery 8, allows you to optimize the layout of the input 11 and output 12 of the head of the fish passage, namely, to ensure a minimum of hydraulic resistance to flow and a maximum of conditions for free passage of fish.

The connection of the drive 6 with the driving drum 14, located at the level of the guides 7 of the main group and installed from the upstream side 3, is the most rational option for the arrangement of the drive mechanism 6 of the endless belt 10.

In addition, the design of the fish passage has another indisputable advantage, since the transverse partitions 4 are perforated, which allows the maximum allowable water flow to pass through the fish passage 1, and this, in turn, can significantly increase the speed loop attracting the fish to attract it to the entrance 11 of the fish passage.

The fish entering the fish passage 1 begins its progress towards the upper pool 3, gradually overcoming the swimming holes 5 made on the surface of the flexible elastic tape 10. The belt 10 with sections 18 having different throughness and different sizes of swimming holes 5, which can be made of various shapes - square (figure 5), rectangular (figure 13), diamond-shaped (figure 14) or round (figure 15). Due to this, sections 18 are created along the length of the fish passage tract 1, in which the difference in the endless belt 10 is different, and the dynamics of this difference is constantly changing due to the alternation of sections 26, 27 and 28 having different throughness. Fish have several opportunities both for moving upstream and for temporary relaxation and restoration of their energy capabilities.

A possible embodiment of the fish passage, when the guides 7 of the main group are made at different elevations, and the marks decrease towards the input part 11 of the fish passage 1. This arrangement allows you to change the angle of the endless belt 10 relative to the bottom of the fish passage 1 and, accordingly, increase the rate of change of the perforated web of the tape 10 from the side of the downstream side (the path that the tape goes through decreases, and from here the speed of replacing sections of the tape with different through awn). The above circumstance makes it possible to control the initial drop in water level, which in many respects dictates the dynamics of changes in drops on the overlying "partitions". In addition, if the distance between the additional 9 guides located at the bottom of the fish passage path is small, then according to the laws of hydraulics of the flow flowing along several resistances located sequentially one after another and located relatively close relative to each other, there will be a mutual influence of local resistances to each other to a friend. That is, the downstream resistance (partition 4) will affect the hydraulic resistance of the upstream partition 4.

A variant of the design of the fish passage is possible when its bottom is made with a longitudinal slope towards the downstream side of the 2 hydroelectric complex. This arrangement of the fish passage allows to reduce the total length of the fish passage 1. At the same time, the average flow velocities along the width of the fish passage 1 will slightly increase. This fish passage variant is recommended for strong swimmers - whitefish, salmon, etc.

The implementation between the guides 9 of an additional group of bottom transverse partitions 19 allows us to provide stable hydraulic conditions in the fish passage 1, in case of a change in the water level in the downstream 2. In this case, we have the minimum calculated water level in the fish passage 1, necessary and sufficient for normal movement fish through the fish passage.

The implementation of the bottom transverse partitions 19 with the inlet openings 20 allows the fish to move freely in the bottom of the fish passage path 1.

Different placement of the swimming holes 20 in the central part of the bottom transverse partitions 19 or in the near-wall region adjacent to the side walls of the fish passage tract 1 allows creating optimal paths for the movement of fish in the bottom of the stream.

There is a variant of the design of the guides 9 of the additional group with the possibility of their vertical movement in the vertical guide grooves 21 with the possibility of fixing them at a given height level, which allows, in case of a decrease in the difference between the downpipes, to reduce the total number of partitions 4 and thereby optimize the passage of fish into the upper pond 3 waterworks. At the same time, this arrangement allows, by raising the additional guides 9 up, to free the fish passage for revising its internal space, for example, for flushing from sediments previously deposited there.

An arrangement of the endless belt 10 together with the endless chains 22 mounted on gears 23 (Fig. 16 and Fig. 3) is possible. The presence of chains 22 ensures reliable operation of the fish passage, namely, the stable movement of the endless belt 10 along the entire length of the fish passage 1.

The implementation of the endless tape 10 from a transparent material greatly reduces the reaction of fish fright due to the presence of a moving object (endless tape 10) in the water stream.

The proposed method and the fish passage, implementing it, is one of the few designs that have a minimum number of elements that create resistance to flow and maximize the free and independent passage of fish into the upper pool.

Sources of information

1. A.S. USSR No. 1574721 (USSR). E 02 B 8/08. "Device for passing fish through a retaining structure." Author: V. Lagutov Publ. B.I. No. 24, 1989.

2. A.S. USSR No. 293918 (USSR). E 02 B 8/08. "Fish passage". Author: Bykov P.P. Publ. 01/26/71. B.I. No. 6, 1971.

3. A.S. USSR No. 1060750 (USSR). E 02 B 8/08. "Fish passage". Authors: Avdonkin AF and Shatalov I.M. Publ. 12/15/83. B.I. No. 46, 1983.

4. A.S. USSR No. 1002452 (USSR). E 02 B 8/08. "Fish-ship A.I. Prostova". Author: Prostov A.I. Publ. 03/07/83. B.I. No. 9, 1983.

5. US Patent No. 2922282 (USA). E 02 B 8/08. "Fish passage".

6. A.S. USSR No. 706036 (USSR). E 02 B 8/08. "Device for transferring fish to the upper pool". Author: Malevanchik B.S. Publ. 06/02/79. B.I. No. 48, 1979.

Claims (19)

1. A method of controlling the modes of passage of fish through the fish passage tract, which consists in creating a fish attracting stream supplied from the upper branch of the hydraulic system to the fish passage and further to the lower pool, creating favorable hydraulic conditions directly in the fish passage by changing the water level difference between the transverse partitions by moving the partitions themselves relative to the bottom of the fish passage tract and creating surmountable speeds in the swimming holes of the transverse partitions, characterized in that the towns through the drive move along the entire length of the fish passage in the direction of the upper pool, while simultaneously with the movement of the partitions, the difference in water levels formed in the gaps between the partitions is moved, and due to the uneven perforation of the partitions formed by sections of the partitions having different permeability, the value of the local level difference water change along the length of the fish passage tract. 2. The method according to p. 1, characterized in that the speed of the movement of the partitions along the length of the fish passage path is prescribed so as to achieve a change in the local water level difference, similar to the presence of the "traveling wave" effect. 3. A fish passage, including a fish passage, connecting the lower and upper water system head-ends, transverse partitions with inlet openings arranged in a checkerboard pattern, while the partitions have the ability to move along the length of the fish passage path by means of a drive and are installed in pairs at an acute angle to each other, while the vertices of the pairs are located on transverse guides located above the water level in the fish passage, and the guides have the ability to move, characterized in that the fish passage is provided with a bottom with an alley and an additional group of guides located in the bottom of the fish passage with the formation of a minimum clearance between the generatrix of the guides and its bottom, and the partitions are formed by an endless ribbon made of flexible flexible material skipped between the guides, and the guides of the main and additional groups are made in the form of cylinders, installed with the possibility of rotation relative to the horizontal axis, while the bottom guides located in the input and output parts of the fish passage They are made in bottom niches located at the entrance and exit of the bottom gallery, and the displacement drive is connected to a driving drum located at the level of the guides of the main group. 4. The fish passage according to claim 3, characterized in that the fish passage is made with side bypass galleries having gates of the power unit on the side of the upper pool, and fish grills on the side of the lower pool. 5. The fish passage according to claim 3 or 4, characterized in that the endless belt is made with sections having different throughness. 6. The fish passage according to claim 5, characterized in that the areas with different throughness alternate with increasing sizes of the inlet openings. 7. Fish passage according to any one of paragraphs. 3 - 6, characterized in that the guides of the main group are installed at different elevations, and the marks are reduced to the entrance to the fish passage tract. 8. Fish passage according to any one of paragraphs. 3 to 7, characterized in that the fish passage path is made with a longitudinal slope towards the downstream. 9. Fish passage according to any one of paragraphs. 3 to 8, characterized in that between the guides of the additional group made bottom transverse partitions. 10. Fish passage according to claim 9, characterized in that the bottom transverse partitions are made with inlet openings. 11. The fish passage according to claim 10, characterized in that the swimming holes are made in the central part of the bottom partitions. 12. Fish passage according to claim 10, characterized in that the inlet openings are made at the side walls of the fish passage tract. 13. Fish passage according to any one of paragraphs. 3 to 12, characterized in that the guides of the additional group have the ability to move vertically in the guide grooves made in the side walls of the fish passage, with the possibility of fixing at a given level. 14. Fish passage according to any one of paragraphs. 3 to 13, characterized in that the float holes on the endless tape are made in a rectangular shape. 15. Fish passage according to any one of paragraphs. 3 to 13, characterized in that the float holes on the endless ribbon are made in a diamond shape. 16. Fish passage according to any one of paragraphs. 3 to 13, characterized in that the float holes on the endless belt are made round. 17. Fish passage according to any one of paragraphs. 3 - 16, characterized in that the endless tape is made with endless chains attached to its end parts, while the guides of the main and additional groups are equipped with gears coaxially made on them from the side walls of the fish passage tract. 18. Fish passage according to any one of paragraphs. 3 to 17, characterized in that the endless tape is made of a transparent material. 19. Fish passage according to any one of paragraphs. 3 to 18, characterized in that the bottom gallery is equipped with guide rollers.

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