RU2274706C1 - Method for fish passage via fish pass channel and fish pass - Google Patents

Abstract

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

SUBSTANCE: method involves supplying working water flow from upper pool in fish pass channel simultaneously with passing thereof from upstream fish pass chamber to downstream fish pass chamber through surface swimming-in orifice and additional orifices created in transversal partition; passing working water flow through perforated transversal partitions arranged in two independent fish pass channels defined by longitudinal partition arranged along fish pass axis; reducing water level difference over the first independent fish pass channel length in direction towards inlet fish pass head by passing working flow through additional orifices formed in transversal partitions and having perforation orifice areas increasing in the same direction; increasing water level difference over the second independent fish pass channel length in direction towards inlet fish pass head by passing working water flow through additional orifices made in transversal partitions and having perforation orifice areas decreasing in the same direction.

EFFECT: possibility to create effective hydraulic conditions to permit fish passage in upper pool of hydraulic system.

14 cl, 16 dwg

Description

The invention relates to hydraulic engineering, in particular to fish passage facilities designed to allow fish producers to pass through retaining structures to spawning and feeding grounds.

A known method of passing fish through the fish passage tract of the fish passage [1], which consists in feeding the fish passage path of the working flow of water from the upper pool, at the same time passing it from the upstream chamber into the downstream chamber of the fish passage, through the swimming hole formed by the end faces of the transverse partition, followed by a change in the planned position septa and the formation of attracting fish flow in the alignment of the inlet head of the fish passage.

The disadvantage of this method is the low efficiency of movement of fish along the fish passage tract and the complexity of the design of the fish passage.

A known method of passing fish through the fish passage tract of the fish passage [2], which consists in feeding the fish passage tract of the working flow of water from the upstream, while passing it from the upstream chamber into the downstream chamber of the fish passage through the surface inlet hole formed by the spillway face of the transverse partition, made in the form of a shutter , a subsequent change in the vertical position of the septum and the formation of a flow attracting fish in the alignment of the inlet head of the fish passage.

The disadvantage of this method is the low efficiency of movement of fish along the fish passage tract and the complexity of the design of the fish passage.

The closest technological scheme is the method of passing fish through the fish passage tract of the fish passage [3], which consists in supplying the fish to the fish passage tract of the working flow of water from the upper pool, at the same time passing it from the upstream chamber into the downstream chamber of the fish passage through the surface swimming inlet and additional openings located in transverse septum, and the formation of attracting fish flow in the alignment of the input head of the fish passage.

The disadvantage of this method is the low efficiency of moving fish along the fish passage tract.

Known fish passage [1], including a fish passage, made in the form of a tray, the output head of which is connected to the upper pool of the hydraulic system, and the input head is connected to the lower pool, perforated partitions located along the length of the fish passage and forming swimming holes.

The disadvantage of this structure is the low efficiency.

Known fish passage [4], including a fish passage tract, made in the form of a tray, the output head of which is connected to the upper pool of the hydraulic system, and the input head is connected to the lower pool, perforated partitions with inlet openings.

The disadvantage of this structure is the low efficiency.

Known fish passage [5], including a fish passage, made in the form of a tray, the output head of which is connected to the upper pool of the hydraulic system, and the input head is connected to the lower pool, perforated partitions with float holes, equipped with movable perforated curtains.

The disadvantage of this structure is the low efficiency.

The closest in technical essence and the achieved result is a fish passage [3], including a fish passage, connecting the upper pool of the hydraulic system with the lower one through the outlet and inlet heads, transverse partitions located along the length of the fish passage and forming working chambers, surface swimming holes and additional holes, located in the transverse partitions.

The disadvantage of this method is the low efficiency of moving fish along the fish passage tract.

The aim of the invention is the creation of effective hydraulic conditions in the fish passage for the passage of fish into the upper pool of the hydraulic system.

The invention consists in the following.

According to claim 1 of the claims. The technology, according to which the working water flow rate is simultaneously supplied to two parallel located autonomous fish passageways, makes it possible to organize independent hydraulic conditions for the passage of fish into the upper pool of the hydroelectric complex. The main and main advantage of this method is that in one fish passage, along its length, two different patterns of changing the water level difference on the transverse partitions are formed:

- the water level difference along the length of the first autonomous fish passageway is lowered in the direction of the inlet head of the fish passage by passing the working flow through additional holes in the transverse partitions, the perforation area of which increases in the same direction;

- the water level difference along the length of the second autonomous fish passage path is increased in the direction of the inlet head of the fish passage by passing the working flow through additional holes in the transverse partitions, the perforation area of which decreases in the same direction.

The fish that entered the entrance head of the fish passage has the opportunity to choose the most optimal conditions for its advance into the upper pool.

Strong swimmers choose an autonomous fish passage, in which the maximum speed in the inlet hole (maximum difference in water levels on the first transverse partition), and begin their advance in the direction of the upper pool. Moving up, the fish spends less and less of its muscular energy, since the magnitude of the water level difference on each upstream transverse septum decreases towards the upper pool. This scheme optimizes the passage of fish along the fish passage.

Weak fish swimmers or weakened individuals choose an autonomous fish passage, the speed in the inlet of which is minimal (the minimum difference in water levels on the first transverse septum), and begin their advance in the direction of the upper pool. Moving up, the fish restores its energy reserves and restores the swimming ability. This is facilitated by an increase in the water level difference on the upstream transverse partitions, that is, an increase in the flow rate in the inlet hole stimulates the passage of migrants in the direction of the upper pool. In this case, the fish has to spend more and more of its muscular energy, since the magnitude of the water level difference on each upstream transverse partition increases. This scheme helps to restore the energy potential of fish and stimulates them to pass through the fish passage, while the fish experiences a kind of training.

According to claim 2 of the claims. The execution of the surface of the transverse perforated partitions allows you to pass a greater flow rate of water through the fish passage. In addition, by changing the throughness of the perforated transverse partitions, it is possible to control the magnitude of the difference in water levels on the partitions installed along the length of the fish passage. At the same time, the perforated transverse partitions are located in two autonomous fish passageways formed by a longitudinal partition made on the longitudinal axis of the fish passage, the perforated transverse partitions being installed between the longitudinal partition and the inner side walls of the fish passage. The formation of two autonomous fish passage paths makes it possible to provide an independent hydraulic flow regime for the water flow in each of the autonomous fish passage paths. This is achieved by changing the area of perforation (and, accordingly, throughness) of the transverse partitions in the first autonomous fish passage path, which increases in the direction of the inlet head, while the perforation area of the transverse (and, accordingly, throughness) partitions in the second autonomous fish passage path decreases in the direction of the inlet head.

Thus, in the first autonomous fish passage path, the difference in water levels on the transverse partitions decreases, and in the second autonomous fish passage path, the difference in water levels on the transverse partitions increases.

Strong swimmers choose an autonomous fish passage, in which the maximum speed in the inlet hole (maximum difference in water levels on the first transverse partition), and begin their advance in the direction of the upper pool. Moving up, the fish spends less and less of its muscular energy, since the magnitude of the water level difference on each upstream transverse septum decreases towards the upper pool. This scheme optimizes the passage of fish along the fish passage.

Weak fish swimmers or weakened individuals choose an autonomous fish passage, the speed in the inlet of which is minimal (the minimum difference in water levels on the first transverse septum), and begin their advance in the direction of the upper pool. Moving up, the fish restores its energy reserves and restores the swimming ability. This is facilitated by an increase in the water level difference on the upstream transverse partitions, that is, an increase in the flow rate in the inlet hole stimulates the passage of migrants in the direction of the upper pool. In this case, the fish has to spend more and more of its muscular energy, since the magnitude of the water level difference on each upstream transverse partition increases. This scheme helps to restore the energy potential of fish and stimulates them to pass through the fish passage.

According to claims 3, 4 and 5 of the claims. The implementation of perforation holes of various shapes: round, square or rectangular, are options for their design.

According to claim 6, claims. The implementation of rectangular perforation holes, the larger size of which is located in the horizontal plane, is an option for their spatial placement.

According to claim 7 of the claims. The execution of rectangular perforation holes of a larger size which is located in a vertical plane is also an option for their spatial placement.

According to claim 8 of the claims. The execution of the longitudinal septum from the upstream side, extended beyond the perforated transverse baffle placement target, allows stabilizing the hydraulic conditions of the approach flow. On the other hand, this arrangement improves the fish exit towards the upper pool, forming a tactile fish guide.

According to claim 9, the claims. The implementation of transverse perforated partitions in autonomous fish passageways located in the same transverse sections is an option for their planned placement.

According to claim 10 of the claims. The implementation of perforated transverse partitions in autonomous fish passageways located in different transverse sections is also an option for their planned placement.

According to claim 11, the claims. The implementation of the surface inlet holes of even perforated transverse partitions in autonomous fish passageways adjacent to the longitudinal partition allows not only forming zigzag fish movement paths, but also improving hydraulics inside the fish passage chambers.

According to paragraph 12 of the claims. The implementation of perforated transverse partitions in autonomous fish passageways made of flexible flexible material can significantly reduce the cost of building a fish passage (reducing the volume of concrete work) and its operation. In addition, the use of soft material dramatically reduces the likelihood of injury to the fish when it comes in contact with perforated transverse partitions.

According to item 13 of the claims. The implementation of perforated transverse partitions in autonomous fish passageways made with bottom swimming inlets expands the possibilities of the fish passage for passing bottom fish species.

According to claim 14. The implementation of the area of the bottom swimming inlets of the perforated transverse partitions installed in the autonomous fish passageways, varying along the length of the fish passage, while in the first autonomous fish passage path it increases in the direction of the inlet head, and in the second autonomous fish passage path decreases in the same direction, it allows more correct regulation the dynamics of changes in the difference in water levels on partitions.

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

figure 1 - fish passage, plan;

figure 2 - section aa in figure 1;

figure 3 is a section bB in figure 1;

figure 4 - perforated transverse septum, isometry;

figure 5 - fish passage, plan, option with the placement of perforated transverse in different transverse sections;

6 is a section bb in figure 1;

Fig.7 is the same, a variant of the surface of the swimming inlets adjacent to the longitudinal partition;

Fig.8 is the same, the perforation holes are made square;

Fig.9 is a cross section of the fish passage tract, fragment, perforation holes are made in a rectangular shape, and their larger size lies in the horizontal plane;

figure 10 is the same, the perforation holes are made in a rectangular shape, and their larger size lies in a vertical plane;

11 is a fish passage, plan, a variant of the placement of even surface swimming inlets adjacent to the longitudinal partition;

12 is a graph of the dependence of the difference in water levels on the partition from the throughness of the perforated transverse partition;

13 is a longitudinal section through an autonomous fish passage, the perforated transverse partitions of which are made of flexible flexible material, the difference in water levels on the partitions increases toward the inlet head of the fish passage;

Fig. 14 is a longitudinal section through an autonomous fish passage, the perforated transverse partitions of which are made of flexible flexible material, the difference in water levels on the partitions decreases towards the inlet head of the fish passage;

Fig - perforated transverse partitions, a variant with bottom swimming partitions;

Fig.16 is the same, the surface of the swimming inlet adjacent to the longitudinal partition.

The fish passage includes a fish passage tract 1, connecting the upper pool of the hydraulic system with the lower one through the outlet 2 and input 3 heads, transverse partitions 4 located along the length of the fish passage path 1 and forming working chambers 5, surface 6 swimming holes and additional holes located in the transverse partitions 4.

The surface of the transverse partitions 4 is perforated with perforation holes 7, while they are located in two autonomous 8 fish passageways formed by the longitudinal partition 9 made on the longitudinal axis of the fish passage, and the perforated transverse partitions 4 are installed between the longitudinal partition 9 and the inner side walls of the fish passage, this perforation area of the transverse partitions 4 in the first autonomous 8 fish passage path increases in the direction of the inlet head 3, and the perforation area is transverse s partition 4 in the second autonomous 8 rybohodnom path decreases in the direction of the input tip 3.

In addition, the perforation holes 7 can be made round.

In addition, the perforation holes 7 can be made square.

In addition, the perforation holes 7 can be made rectangular.

In addition, the larger size of the perforation holes 7 can be located in a horizontal plane.

In addition, the larger size of the perforation holes 7 may be located in a vertical plane.

In addition, the longitudinal partition 9 from the upstream side can be moved beyond the target of perforated transverse partitions 4.

In addition, the perforated transverse partitions 4 in the autonomous 8 fish passage paths can be located in the same transverse sections.

In addition, the perforated transverse partitions 4 in the autonomous 8 fish passage paths can be located in different transverse sections.

In addition, the surface 6 inlet holes of even perforated transverse partitions 4 in autonomous 8 fish passage paths can adjoin the longitudinal partition 9.

In addition, the perforated transverse partitions 4 in the autonomous 8 fish passage paths can be made of flexible flexible material.

In addition, the perforated transverse partitions 4 in the autonomous 8 fish passage paths are made with bottom 10 inlet openings.

In addition, the area of the bottom 10 of the inlet openings of the perforated transverse partitions 4 installed in the autonomous 8 fish passageways varies along the length of the fish passage, while in the first autonomous 8 fish passage it increases in the direction of the inlet head 3, and in the second autonomous 8 fish passage decreases in the same direction.

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

The technology, according to which the working water flow rate is simultaneously supplied to two parallel 8 autonomous fish passage paths 1, allows you to organize independent hydraulic conditions for the passage of fish into the upper pool of the hydraulic system. The main and main advantage of this method is that in one fish passage, along its length, two different patterns of changing the water level difference on the transverse partitions 4 are formed:

- the water level difference along the length of the first autonomous 8 fish passage path 1 is lowered in the direction of the inlet head 3 of the fish passage by passing the working flow through the perforation holes 7 in the perforated transverse partitions 4, the perforation area of which increases in the same direction;

- the water level difference along the length of the second autonomous 8 fish passage path 1 is increased in the direction of the inlet head 3 of the fish passage by passing the working flow through the perforation holes 7 in the perforated transverse partitions 4, the perforation area of which decreases in the same direction.

The fish that entered the inlet head 3 of the fish passage has the ability to select the most optimal conditions for its advance into the upper pool. Strong swimmers choose autonomous 8 fish passageway 1, in which the speed in the surface 6 inlet hole is maximum (maximum difference in water levels on the first transverse partition 4), and begin their advance in the direction of the upper pool. Moving up, the fish spends less and less of its muscular energy, since the magnitude of the water level difference on each upstream transverse partition 4 decreases towards the upper pool. This scheme optimizes the passage of fish along the fish passage.

Weak fish swimmers or weakened individuals choose an autonomous 8 fish passageway 1, the minimum speed in the surface 6 of the inlet opening (the minimum difference in water levels on the first transverse baffle 4), and begin their advance in the direction of the upper pool. Moving up, the fish restores its energy reserves and restores the swimming ability. This is facilitated by an increase in the water level difference on the upstream perforated transverse partitions 4, that is, an increase in the flow rate in the surface 6 inlet opening stimulates the passage of migrants in the direction of the upstream. In this case, the fish has to spend more and more of its muscular energy, since the magnitude of the difference in water level on each upper transverse partition 4 increases. This scheme helps to restore the energy potential of fish and stimulates them to pass through the fish passage, while the fish experiences a kind of training.

Fish passage works as follows.

The attraction of fish from the downstream to the inlet head 3 of the fish passage path 1 is carried out by supplying the working flow from the upstream. The execution of the surface of the transverse partitions 4 perforated allows you to pass through the fish passage 1 more water flow. In addition, changing the throughness of the perforated transverse partitions 4, it is possible to control the magnitude of the difference in water levels on the partitions 4 installed along the length of the fish passage. In this case, the perforated transverse partitions 4 are located in two autonomous 8 fish passageways 1 formed by a longitudinal partition 9 made on the longitudinal axis of the fish passage, and the perforated transverse partitions 4 are installed between the longitudinal partition 9 and the inner side walls of the fish passage. The formation of two autonomous 8 fish passage paths 1 allows you to provide an independent hydraulic mode of the flow of water in each of the autonomous 8 fish passage paths 1. This is achieved by changing the area of perforation (and, accordingly, throughness) of the perforated transverse partitions 4 in the first autonomous 8 fish passage path 1, which increases in the direction of the input tip 3, while the perforation area of the transverse (and, accordingly, throughness) partitions 4 in the second autonomous 8 fish passage path 1 decreases in the direction Leaning input tip 3.

Thus, in the first autonomous 8 fish passage path 1, the difference in water levels on the perforated transverse partitions 4 decreases, and in the second autonomous 8 fish passage path 1, the difference in water levels in the transverse partitions 4 increases. The created hydraulic mode of the flow of water in the autonomous 8 fish passageways 1 allows you to:

- for strong swimmers to choose an autonomous 8 fish passageway 1, in which the speed in the surface 6 inlet hole is maximum (the maximum difference in water levels on the first transverse baffle 4), and begin their advance in the direction of the upper pool. Moving up, the fish spends less and less of their muscular energy, since the magnitude of the water level difference on each upstream transverse partition 4 decreases towards the upstream. This scheme optimizes the passage of fish along the fish passage 1;

- weak fish swimmers or weakened individuals can choose an autonomous 8 fish passageway 1, the speed in the surface 6 of the inlet opening of which is minimal (the minimum difference in water levels on the first perforated transverse partition 4), and begin its advancement in the direction of the upper pool. Moving up, the fish restores its energy reserves and restores the swimming ability. This is facilitated by an increase in the water level difference on the upstream perforated transverse partitions 4, that is, an increase in the flow rate in the surface 6 inlet opening stimulates the passage of migrants in the direction of the upstream. In this case, the fish has to spend more and more of its muscular energy, since the magnitude of the water level difference on each upstream perforated transverse partition 4 increases. This scheme helps to restore the energy potential of fish and stimulates them to pass through the fish passage.

The implementation of perforated transverse partitions 4 is possible with different shapes of perforation holes 7: round (Fig. 4, 6 and 7), square (Fig. 8) or rectangular (Fig. 9 and 10).

It is possible to perform a longitudinal septum 9 from the upstream side, extended beyond the perforated transverse partitions placement target 4 (Fig. 1), which makes it possible to stabilize the hydraulic conditions of the approach flow. On the other hand, this arrangement improves the fish exit towards the upper pool, forming a tactile fish guide.

There are two options for the planned placement of perforated transverse partitions 4 in autonomous 8 fish passageways 1 located in the same transverse sections (Figs. 1 and 11), or located in different transverse sections (Fig. 5).

A possible embodiment of the surface 6 inlet openings of even perforated transverse partitions 4 in autonomous 8 fish passageways 1 adjacent to the longitudinal partition 9 (Fig. 11), which allows not only to form zigzag-like paths for moving fish, increase the overall hydraulic resistance to the transit flow, but also improve hydraulics inside the working chambers 5 of the fish passage.

A possible embodiment of perforated transverse partitions 4 in autonomous 8 fish passageways 1 made of flexible flexible material (Figs. 13 and 14), which can significantly reduce the cost of building a fish passage (reducing the volume of concrete work) and its operation. In addition, the use of soft material dramatically reduces the likelihood of injury to the fish when it comes in contact with perforated transverse partitions 4.

A possible embodiment of the area of the bottom 10 inlet openings of the perforated transverse partitions 4 installed in the autonomous 8 fish passageways 1, varying along the length of the fish passage, while in the first autonomous 8 fish passage path 1 it increases in the direction of the inlet head 3, and in the second autonomous 8 fish passage path 1 decreases in the same direction, which makes it possible to more correctly control the dynamics of changes in the difference in water levels on the partitions 4.

The proposed method for passing fish through the fish passage and its fish passage expand the potential of the fish passage for passing different types of fish, as well as swimmers with different indicators of swimming ability.

Information sources

1. RF patent №2022097, "Fish passage", E 02 B 8/08, A. Chistyakov and Skin V.N. Publ. BI No. 20, 1994.

2. Japan patent No. 02-279815, "Automatic gate for fishway", IPC E 02 B 8/08, E 02 B 7/20. Aragata Kunikazu, Shimomi Kouji. Publ. 11/15/1990.

3. Japan patent No. 2000-120052, "Going-up system of fish to fresh water reservoir", IPC E 02 B 8/08. Hata Kenji. Publ. 04/25/2000.

4. USSR author's certificate No. 1535932, "Fish-pass", E 02 B 8/08, Skura V.N., Cherkasov V.A., Chistyakov A.A., Parulava I.I. and Anokhin A.M. Publ. BI No. 2, 1990.

5. Copyright certificate of the USSR No. 1592435, "Fish-ship", E 02 B 8/08, Skura V.N., Chistyakov A.A., Cherkasov V.A., Parulava I.I. Publ. BI No. 34, 1990.

Claims (14)

1. The method of passing fish through the fish passage tract of the fish passage, which consists in supplying to the fish passage tract a working flow of water from the upper pool, simultaneously passing it from the upstream chamber into the downstream fish passage chamber through the surface inlet and additional openings located in the transverse baffle, and forming attracting fish flow in the alignment of the inlet head of the fish passage, characterized in that the working flow of water is passed through a fully perforated transverse partition installed in two autonomous fish passage paths formed by a longitudinal partition located along the longitudinal axis of the fish passage, while the water level difference along the length of the first autonomous fish passage path is reduced in the direction of the inlet head of the fish passage by passing the working flow through additional holes in the transverse partitions, the perforation area of which increases in in the same direction, and at the same time, the water level difference along the length of the second autonomous fish passage path is increased in the direction of the input Single pass through the fish ladder operating flow through additional holes in the transverse septa, perforation area which decreases in the same direction. 2. A fish passage, including a fish passage, connecting the upper pool of the hydraulic system with the lower one through the outlet and inlet heads, transverse partitions located along the length of the fish passage and forming working chambers, surface inlet openings and additional openings located in the transverse partitions, characterized in that the surface transverse partitions made perforated, while they are located in two autonomous fish passageways formed by a longitudinal partition made on the longitudinal the axis of the fish passage, and the perforated transverse partitions are installed between the longitudinal partition and the inner side walls of the fish passage, while the perforation area of the transverse partitions in the first autonomous fish passage tract increases in the direction of the inlet head, and the perforation area of the transverse partitions in the second autonomous fish passage tract decreases in the direction of the inlet head. 3. Fish passage according to claim 2, characterized in that the perforation holes are made round. 4. Fish passage according to claim 2, characterized in that the perforation holes are square in shape. 5. Fish passage according to claim 2, characterized in that the perforation holes are made in a rectangular shape. 6. Fish passage according to claim 5, characterized in that the larger size of the perforation holes is located in a horizontal plane. 7. Fish passage according to claim 5, characterized in that the larger size of the perforation holes is located in a vertical plane. 8. Fish passage according to any one of paragraphs. 2 to 7, characterized in that the longitudinal septum from the upstream side is taken out of the perforated transverse septum placement target. 9. Fish passage according to any one of paragraphs. 2 to 7, characterized in that the perforated transverse partitions in the autonomous fish passageways are located in the same transverse sections. 10. Fish passage according to any one of paragraphs. 2 to 7, characterized in that the perforated transverse partitions in the autonomous fish passageways are located in different transverse sections. 11. Fish passage according to any one of paragraphs. 2 to 7, characterized in that the surface swimming holes of even transverse partitions in autonomous fish passage paths are adjacent to the longitudinal partition. 12. Fish passage according to any one of paragraphs. 2 to 7, characterized in that the perforated transverse partitions in the autonomous fish passageways are made of flexible flexible material. 13. Fish passage according to any one of paragraphs. 2 to 7, characterized in that the perforated transverse partitions in the autonomous fish passageways are made with bottom swimming inlets. 14. The fish passage according to claim 13, characterized in that the area of the bottom swimming inlets of the perforated transverse partitions installed in the autonomous fish passageways varies along the length of the fish passage, while in the first autonomous fish passage it increases in the direction of the inlet head, and in the second autonomous fish passage tract - decreases in the same direction.

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