RU2272865C1 - Spawning system for reophilic fish reproduction - Google Patents

Abstract

FIELD: hydraulic building, particularly structures to provide natural brood fishes spawning.

SUBSTANCE: spawning system comprises supply unit communicating with upper hydrosystem pool and with head part of spawning channel inclined in longitudinal direction. Spawning substrate, namely gravel-sand filling, is laid on channel bottom. Channel bottom also has roughness members installed so that the roughness members are project over the spawning substrate and extend at and angle to longitudinal axis of spawning channel. The system also has fish-pass gutter communicated with spawning channel and having inlet part communicated with lower hydrosystem pool, as well as brood fish keeping chamber. The chamber is connected with fish-pass gutter and spawning channel. The fish-pass gutter is provided with locks and stimulating device formed as cart sliding along guiding members and having stimulating web to provide fish movement along the full fish-pass gutter length. The spawning channels define spiral in plane. Fish-pass gutter is communicated with spawning channel through brood fish keeping chamber, which is connected with spawning channel inlet. Fish-pass gutter end is provided with means for fish inspection and selection. The means is made as ichthyologic plate and regulation lock, which separate the fish-pass gutter from the brood fish keeping chamber. The brood fish keeping chamber has water accumulation tray arranged in parallel to it and with trapping net, which isolates the chamber and water accumulation tray. Water accumulation tray interior is communicated with fish-pass gutter end via bottom gallery. Horizontal part of bottom gallery outlet has louver gate arranged under fish arresting grid. The water accumulation tray is provided with gate to separate thereof from discharge channel. Spawning channel gutter is supported by vertical posts, which form load-bearing pier structure.

EFFECT: improved hydraulic conditions for fish spawning.

14 cl, 29 dwg

Description

The invention relates to hydraulic engineering, in particular to structures intended for natural spawning of fish producers.

A known system for breeding and spawning fish [1], including a closed annular channel, a pumping station, outlet and inlet channels, fish trap, dams and jet forming devices.

The disadvantage of this structure is the low efficiency of fish spawning in its internal space.

Known spawning complex for the reproduction of rheophilic species of fish [2], including a closed annular channel, a pumping station, outlet and inlet channels, fish catcher, dams and stream forming devices.

The disadvantage of this structure is the low efficiency of fish spawning in its internal space.

The closest in technical essence and the achieved result is a spawning complex for the reproduction of rheophilic fish species [3], including a power supply unit connected with the upper pool of the waterworks and with the head part of the spawning channel, the bottom of which is made with a longitudinal slope, spawning substrate laid on the bottom of the tray channel in the form of gravel and pebble dusting, elements of enhanced roughness installed on the bottom of the channel with elevation above the spawning substrate and located at an angle to the longitudinal axis of the spawning channel la, a fish passage tray in communication with a spawning channel, the inlet of which is connected to the downstream of the hydraulic system, while the fish passage is equipped with gates and a motive device made in the form of a trolley mounted on guides and having a motive belt for transferring fish along the fish passage, and a camera for preliminary keeping of fish producers, communicating with the fish passage and spawning channel.

The disadvantage of this structure is the low efficiency of fish spawning in its internal space.

The aim of the invention is to create effective hydraulic conditions for spawning fish.

The invention consists in the following.

According to claim 1 of the claims. The implementation of the spawning channel in a spiral shape in plan allows not only rational use of land resources, but also the formation of a spawning channel of a given length and providing the estimated spawning area for fish producers.

The implementation of the fish passage tray, communicating with the spawning channel through the camera for pre-keeping fish producers, which is connected to the input part of the spawning channel, and the end part of the fish passage is equipped with a device for inspection and selection of fish producers in the form of an ichthyological site and a shutter-regulator that separates the fish passage tray chambers for preliminary maintenance, allows a full cycle to attract, accumulate, inspect and select fish producers. In addition, after the operation of selecting fish producers ready for spawning, they are transferred to a pre-keeping chamber, where the fish adapt to new conditions, high-speed and oxygen conditions, after which the fish have free access to move to the spawning channel, where they will cycle spawning migrations.

The implementation of the camera with a catchment tray located parallel to it, and a catcher mesh separating the camera and the catchment tray, allows you to dump the flow coming through the spawning channel into the catchment channel and then into the discharge channel and the downstream of the waterworks. Water from the catchment can be discharged in two ways:

- the first discharge scheme involves the discharge of flow through the bottom gallery, communicating the spillway and fish passage tray, into the interior of the fish passage. At the same time, the shutter-regulator located in the catchment tray completely covers its live section. The flow rate entering the fish passage tray is used to attract an additional number of producers suitable from the downstream side of the hydraulic system;

- the second discharge scheme involves the discharge of flow through the trap grid and then through the discharge channel to the downstream of the hydraulic system. The mesh catcher has the ability to move vertically and is designed to prevent migrants from entering the pre-detention chamber in the catchment and downstream. At the same time, the shutter separating the catchment tray from the discharge channel is raised, and the louvre shutter of the bottom gallery and the shutter of the manufacturers' preliminary containment chamber are closed. At this moment, an operation is carried out to select producers on the ichthyological site and the subsequent transfer of producers ready to spawn in the preliminary detention chamber.

The installation of the spawning channel on the vertical supports forming the flyover allows you to create a given configuration of the spawning ground.

The implementation of the horizontal part of the outlet of the bottom gallery, located in the fish passage with a louvre shutter placed under the fish-retaining grill, allows you to quickly transfer the working flow of water from the spawning channel to the discharge channel.

According to claim 2 of the claims. The implementation of the head of the spawning channel with a minimum radius of twist of the spiral, and its input part with the maximum radius of twist of the spiral, allows you to get the layout of the spawning channel, made in a downward spiral, in which the radius of the turns increases in the direction of its input part (figure 1). In this case, it is possible to form a spawning channel of a given length and spawning power (spawning area).

According to claim 3 of the claims. The implementation of the head of the spawning channel with a maximum radius of twist of the spiral, and its input part with a minimum radius of twist of the spiral allows you to get the layout of the spawning channel, made in a downward spiral, in which the radius of the turns decreases in the direction of its input part (11 and 12). At the same time, it is also possible to form a spawning channel of a given length and spawning power (spawning area).

However, this arrangement has its undeniable advantages: firstly, in terms of space and in space, the spawning channel has the shape of a “stadium bowl”, which creates favorable conditions inside it - minimum exposure to wind loads, maximum lighting under the influence of sunlight, and the presence of stable temperature conditions; secondly, migrants, at the beginning of their advancement along channel 4, quickly overcome its initial part and, subsequently, getting to the sections of channel 4, with a large spiral radius choose acceptable sites for spawning.

According to claim 4 of the claims. The implementation of the water path of the spawning channel in the form of two turns of a spiral, forming a figure eight, while part of the upstream water path is located above its lower sections, is an option and also allows you to create a spawning channel of a given length and spawning power.

According to claim 5, claims. The implementation of the spawning channel, equipped with an additional water supply path located symmetrically with respect to the axis of the structure, with both threads of the spawning channel forming two turns of a spiral forming a figure eight, while part of the upstream water supply path is located above its lower sections, the main and additional water supply paths having common head and inlet parts, allows you to get a spawning channel that simulates the cyclic movement of migrants (in a closed circuit ur). Indeed, migrants who have reached its head part can roll along the second thread of the spawning channel and again spawn migration, while they can choose a new migration path, since the input part of the spawning channel is common for both channels of the channel.

According to claim 6, claims. The implementation of the elements of enhanced roughness in the form of parallelepipeds adjacent one end part to the sides of the channel tray, while the even elements are located along the starboard side, and the odd elements along the left side of the channel (Fig. 13), allows not only to form swimming holes, but also to form a system artificial roughness, which allows to effectively extinguish excess kinetic energy in the bottom horizon of the water stream. With this arrangement, the elements of enhanced roughness cause the water stream to spend an additional part of its energy on the longitudinal swinging of the dynamic axis of the stream.

According to claim 7 of the claims. The implementation of the elements of enhanced roughness in the form of parallelepipeds, forming a V-shape in plan, while the elements of enhanced roughness are located along the longitudinal axis of the spawning channel with the formation of floating holes between their free end parts and the sides of the spawning channel tray, allow not only to form swimming holes, but and form bottom thresholds allowing evenly redistributing the flow of water across the width of the spawning channel tray (Fig. 14).

According to claim 8 of the claims. The implementation of the elements of enhanced roughness are made in terms of a curvilinear shape, with their convex side facing downstream, and the elements of enhanced roughness are located along the longitudinal axis of the spawning channel with the formation of floating holes between their end parts and the sides of the spawning channel tray, also contributes to the effective uniform redistribution of flow rate water across the width of the tray spawning channel (Fig).

According to claim 9, the claims. The supply of the spawning channel with additional elements of enhanced roughness, which are installed on the longitudinal axis of the spawning channel, perpendicular to it in transverse sections located between the rows of the main elements of the increased roughness, allows you to enhance the effect of quenching the kinetic energy of the water flow (Fig. 16).

According to claim 10 of the claims. The implementation of the elements of the enhanced roughness of the main group, located in even rows, set mirror-like relative to the elements of the enhanced roughness of the main group, located in odd rows, also allows you to enhance the effect of quenching the kinetic energy of the water flow (Fig. 17) by creating additional resistance to the bottom jets formed in gaps between parallelepipeds.

According to claim 11, the claims. The supply of the spawning complex with means for the artificial reproduction of juvenile fish - circulation pools, a hatchery, uterine and larval ponds, as well as a pumping station equipped with a fish protection device, expands its ability to reproduce fish stocks and increases not only the percentage of survival of juvenile fish, but also the overall work efficiency complex as a whole.

According to paragraph 12 of the claims. The implementation along the length of the spawning channel of an additional spawning substrate imitating natural aquatic vegetation expands its capabilities for spawning phytophilic fish species (phytophilic fish species are fish that spawn on the surface of aquatic vegetation).

According to item 13 of the claims. The implementation of spawning substrate on removable spawning panels allows you to optimize the process of cleaning spawning substrate by facilitating the removal of panels and their removal of sediment and debris.

According to claim 14. The implementation of the bottom gallery is connected by a collector to a larval pond, while the collector is equipped with a shutter-regulator, it is guaranteed to collect from the spawning channel the larvae of juvenile fish and eggs into the larval pond. During this operation, the louvre shutter closes completely.

The solution to this problem is achieved by creating a new spawning complex for the reproduction of rheophilic fish species. Graphic material that explains the essence of the invention is presented in the following figures:

figure 1 - spawning channel, plan, an embodiment of the head of the spawning channel with a minimum radius of twist of the spiral, and its input part with the maximum radius of twist of the spiral;

figure 2 is the same side view;

figure 3 is a section aa in figure 1;

figure 4 is a section bB in figure 1;

figure 5 - spawning complex plan;

6 is a section bb in figure 5;

Fig.7 is a section GG in Fig.6;

Fig. 8 is an embodiment of a water path of a spawning canal in the form of two turns of a spiral forming a figure eight, with a part of an upstream water path being located above its lower sections;

Fig. 9 is an embodiment of a spawning channel equipped with an additional water supply path located symmetrically to the main axis relative to the axis of the structure, while both spawning channel paths form two turns of a spiral forming an eight in plan, while part of the upstream water supply path is located above its lower sections, the main and additional water supply paths have a common head and input parts;

figure 10 - spawning channel in figure 9, side view;

11 is an embodiment of the head of the spawning channel with a maximum radius of twist of the spiral, and its input part with a minimum radius of twist of the spiral;

Fig - the same plan;

13 is a fragment of the spawning channel tray, an embodiment of reinforced roughness elements in the form of parallelepipeds adjacent one side to the sides of the channel tray, with even elements located along the starboard side and odd elements along the left side of the channel;

Fig. 14 is an embodiment of reinforced roughness elements having a V-shape in plan, wherein reinforced roughness elements are located along the longitudinal axis of the spawning channel with the formation of floating holes between their free end parts and the sides of the spawning channel tray;

Fig - the same, the elements of enhanced roughness are made curved in plan, while their convex surface is facing downstream;

Fig is a variant of the spawning channel with additional elements of enhanced roughness, which are installed on the longitudinal axis of the spawning channel, perpendicular to it in transverse sections located between the rows of the main elements of enhanced roughness;

Fig - the same, an embodiment of the elements of the enhanced roughness of the main group, located in even rows, set mirror-like relative to the elements of the enhanced roughness of the main group, located in odd rows;

Fig. 18 is a cross-sectional view of a spawning channel tray;

Fig. 19 is the same, an embodiment with two inlet openings;

Fig. 20 is a cross-sectional view of a spawning channel tray; an embodiment of a spawning substrate on spawning panels;

Fig - cross section of the tray spawning channel, a variant with spawning substrate that simulates natural aquatic vegetation;

Fig is a longitudinal section along the drainage tray;

Fig.23 is a section DD in Fig.22;

Fig - the same, in the case of discharge flow;

Fig - spawning complex, plan, version of the bottom gallery, connected by a collector with a larval pond;

FIG. 26 is a longitudinal section through a preliminary fish holding chamber and a fish passage tray, an operation for attracting migrants from a downstream;

Fig.27 - the same, the louvre shutter of the bottom gallery is closed;

Fig - operation of selecting fish producers on the ichthyological site;

Fig. 29 is a translation operation of fish producers ready to spawn in a preliminary holding chamber.

The spawning complex for the reproduction of rheophilic fish species includes a power supply unit 1, connected with the upper pool 2 of the waterworks and with the head part 3 of the spawning channel 4, the bottom of which is made with a longitudinal slope, spawning substrate 5, laid on the bottom of the channel tray in the form of gravel-pebble gravel , reinforced roughness elements 6 installed on the bottom of channel 4 with an elevation above the spawning substrate 5 and located at an angle to the longitudinal axis of the spawning channel 4, fish pass tray 7 in communication with the spawning channel 4, inlet 8 which is in communication with the downstream pool 9 of the waterworks system, while the fish passage tray 7 is equipped with gates and a motive device 10 made in the form of a trolley mounted on guides and having a motive belt for transferring fish along the fish passage tray 7, and a camera 11 for preliminary keeping of fish producers, communicating with fish pass tray 7 and spawning channel 4.

The spawning channel 4 is made in a spiral shape in plan, while the fish passage 7 communicates with the spawning channel 4 through the camera 11 for pre-keeping fish producers, which is connected to the input part 12 of the spawning channel 4, and the end part of the fish passage 7 is equipped with a device for inspection and selection fish producers in the form of an ichthyological site 13 and a shutter-regulator 14 separating the fish passage 7 from the chamber 11 for preliminary keeping of fish producers, while the said chamber 11 is made a catchment tray 15 parallel to it and a catch catcher 16 separating the chamber 11 and the catchment tray 15, and the inside of the catchment tray 15 is connected via the bottom gallery 17 to the end part of the fish passage tray 7, while the horizontal part of the outlet opening of the bottom gallery 17, located in the fish passage tray 7, is made with a louvre shutter 18 located under the fish-retaining grill 19, the catchment tray 15 is equipped with a shutter 20 separating it from the discharge channel 21, and the spawning channel tray 4 is installed flax on vertical supports 22 forming the carrier rack.

In addition, the head part 3 of the spawning channel 4 can be made with a minimum radius of twist of the spiral, and its input part 12 with the maximum radius of twist of the spiral.

In addition, the head part 3 of the spawning channel 4 can be made with a maximum radius of twist of the spiral, and its input part 12 with a minimum radius of twist of the spiral.

In addition, the water path of the spawning channel 4 can be made in the form of two turns of a spiral forming a figure eight, while part of the upstream water path is placed above its lower sections.

In addition, the spawning channel 4 can be equipped with an additional water path 23, located symmetrically to the main axis of the structure, and both paths of the spawning channel 4 form two turns of a spiral forming a figure eight, while part of the upstream water path is placed over its lower sections, moreover the main 4 and additional 23 water paths have a common head 3 and input 12 parts.

In addition, the elements of enhanced roughness 6 can be made in the form of parallelepipeds and adjoin one end part to the sides of the channel 4 channel, while even elements 6 are located along the starboard side, and odd elements along the left side of channel 4.

In addition, the elements of reinforced roughness 6 can be made in the form of parallelepipeds having a V-shape in plan, while the elements of reinforced roughness 6 are located along the longitudinal axis of the spawning channel 4 with the formation of swimming holes 24 between their free end parts and the sides of the spawning channel tray four.

In addition, the elements of reinforced roughness 6 can be made in terms of a curved shape, with their convex side facing downstream, and the elements of reinforced roughness 6 are located along the longitudinal axis of the spawning channel 4 with the formation of void holes 24 between their end parts and the sides of the spawning tray channel 4.

In addition, the spawning complex can be equipped with additional elements 25 reinforced roughness, which are installed on the longitudinal axis of the spawning channel 4, perpendicular to it in transverse sections located between the rows of the main elements of enhanced roughness 6.

In addition, the elements of reinforced roughness 6 of the main group located in even rows can be set mirror-like with respect to the elements of reinforced roughness 6 of the main group located in odd rows.

In addition, the spawning complex can be equipped with means for artificial reproduction of juvenile fish - circulation pools 26, hatchery 27, uterine 28 and larval 29 ponds, as well as a pump station 30 equipped with a fish protection device.

In addition, an additional spawning substrate 31 simulating natural aquatic vegetation can be made along the length of the spawning channel 4.

In addition, spawning substrate 5 can be performed on removable spawning panels 32.

In addition, the bottom gallery 17 can be connected by a collector 33 with a larval pond 27, while the collector 33 is equipped with a shutter-regulator 34.

The fish passage tray 7 is equipped with a vertical fish-holding grating 35. The head part 3 of the spawning channel 4 is equipped with a fish-holding grating 36 and a spillway 37. The input part 12 of the spawning cocoa 4 is made with a bottom threshold 38, which is able to adjust its vertical position. The end part of the discharge tray 21 is blocked by a fish-retaining grill 39 to prevent migrants from entering the downstream side 9.

Spawning complex for the reproduction of rheophilic fish species works as follows.

To fill the internal space of the spawning channel 4 by producers, fish are brought from the lower pool 9 by supplying the working flow with a power supply 1 from the upper pool 2, which flows through the tray of the spawning channel 4. A formed “trail” of speeds attracting fish allows fish to enter the fish passage tray 7. By after a certain time, necessary and sufficient for the accumulation of migrants, the operation of attraction is completed. In this case, the shutter 20 opens and the shutter 14 closes, and the louvre shutter 18 is also in the closed position and the water flow from the pre-maintenance chamber 11 enters through the catcher 16 first into the catchment tray 15, and then into the discharge channel 21 and then into the downstream 9, forming a fish attracting current. At the same time, the mesh web of the incentive device 10 is lowered and overlaps the living section of the fish-pass tray 7, so that the fish accumulated in it is cut off from the water of the lower pool 9.

The cart of the induction device 10 begins its movement along the guides in the direction of the ichthyological site 13, upon reaching which it stops. To examine the physiological state of migrants, as well as to discard individuals not ready for spawning, raise the ichthyological site 13 to the water level in the fish passage 7 (Fig. 28). At the end of this operation, the ichthyological site 13 lowers to its lowest position, the shutter 14 opens and the migrants, focusing on the generated water flow, independently move into the inner space of the chamber 11 (Fig. 29), at this moment the bottom threshold 38 is laid on the bottom of the chamber 11, providing a free passage of fish into the spawning channel 4. After all fish producers have entered the fish holding grid 35, the mesh web of the motivation device 10 is raised, the cart of the motivation device 10 is lowered tsya to the inlet portion 8 rybohodnogo tray 7 where it stops. The shutter 20 is lowered, and the shutter 14 rises, while the working flow of water in transit bypasses the chamber 11 and fish passage tray 7, forming an attractive flow for fish against the background of the hydraulic conditions of the downstream 9.

Once in spawning channel 4, migrants are able to spawn along the entire channel of channel 4, where favorable conditions are created for the movement of fish and their spawning on spawning substrate 5 (gravel-pebble bedding or spawning panels 32). Hydraulic resistance to flow in the channel 4 create elements of enhanced roughness 6 or elements 6 and additional elements of enhanced roughness 25 (see Fig.13-20). Elements 6 and 25 are installed in such a way that between them and the sides of the spawning channel tray 4, swimming holes 24 are formed, intended for free passage of fish upstream or for their safe slope downstream. Migrants have the possibility of free movement along channel 4, up to the alignment of the installation of fish-retaining lattice 36 (figure 1), which prevents the passage of fish to the power supply 1.

According to spawning technology and taking into account the physiology of spawning fish, migrants are sampled from spawning channel 4 at the end of the spawning process (6-8 days from the start of migrants' landing in channel 4), which can be determined by taking control ichthyological samples from the surface of the spawning substrate 5. Spawning migrants are either caught within the chamber 11, or give them the opportunity to slide into the lower pool 9 on their own, which allows the technological equipment of the spawning complex.

Larvae of juvenile fish that hatched from eggs are gradually concentrated within chamber 11, where, using special equipment, the juvenile fish are transplanted into larval pond 29 or into circulation pools 26, where further work with the offspring is carried out to increase its viability and gain the required weight (weight one fry in grams).

With a massive slope of the larvae, the following variant of their concentration in the chamber 11 is possible. The power supply unit 1 is gradually covered, thereby the water flow along with the larvae moves to the inlet part 12 of the channel 4 and the chamber 11.

An improved variant of the concentration of the larvae of juvenile fish by dumping them directly into the larval pond 29 is possible (Fig. 25). In this case, the following manipulations are made with the technological equipment of the spawning complex. The gates 14 and 20 are closed, the louvre shutter 18 is also closed, the shutter-regulator 34 is opened. Thus, the water flow together with the fish larvae is discharged along the drainage channel 15, the bottom gallery 17 and the collector 33 into the larval pond 29.

The layout of the spawning channel path 4 is possible when it is made in the form of two turns of a spiral forming, in plan, a figure eight (Fig. 8), while part of the upstream water supply path is located above its lower sections, which allows the spawning channel to be formed with a given length and spawning power , with minimal cost of land.

The layout of the spawning channel path 4 is possible when it is equipped with an additional water supply path 23 located symmetrically to the axis of the structure, while both spawning channel paths 4 form two turns of a spiral forming a figure eight, while part of the upstream water path is located above its lower sections, the main 4 and additional water supply paths 23 have a common head 3 and input 12 parts (Fig. 9), which makes it possible to obtain a spawning channel 4 simulating a cyclic movement of m gamers (in a closed loop). Indeed, migrants who have reached its head 3 part have the opportunity to roll along the second path of the spawning channel 4 and again to spawn migration, while they can choose a new migration path, since the input part 12 of the spawning channel 4 is common for both channel paths.

The layout of the spawning channel 4 channel is possible when its head part of the spawning channel 4 is made with a maximum radius of twist of the spiral, and its input part 12 is with a minimum radius of twist of the spiral, which allows you to get the layout of the spawning channel 4, made in a downward spiral, which has a radius of turns decreases in the direction of its inlet (Fig.11 and 12). At the same time, it is also possible to form a spawning channel 4 of a given length and spawning power (spawning area). However, this arrangement has its undeniable advantages: firstly, in terms of space and in space, the spawning channel has the shape of a “stadium bowl”, which creates favorable conditions inside it - minimum exposure to wind loads, maximum lighting under the influence of sunlight, and the presence of stable temperature conditions; secondly, migrants, at the beginning of their advancement along channel 4, quickly overcome its initial part and, subsequently, getting to the sections of channel 4, with a large spiral radius choose acceptable sites for spawning.

To ensure spawning of phytophilic fish species (spawning eggs on the surface of aquatic vegetation), channel 4, along its length, can be made with an additional spawning substrate 31 imitating natural aquatic vegetation, which expands its potential for spawning of phytophilic fish species.

The supply of the spawning complex with means for artificial reproduction of juvenile fish - circulation pools 26, hatchery 27, broodstock 28 and larval 29 ponds, as well as a pumping station 30 equipped with a fish protection device, expand its capabilities for reproducing fish stocks and increase not only the percentage of survival of juvenile fish, but also the overall performance of the whole complex. These funds can increase the survival rate of juvenile fish and, ultimately, the overall fish-producing function of the reservoir.

An important circumstance is the fact that the working flow rate of water supplied to the spawning channel 4 creates a flow stream enriched with oxygen, and most importantly, that water is taken from the upper pool 2 of the hydraulic system, with a temperature higher than the temperature of the water in the lower pool 9.

The proposed spawning complex is equipped with all the necessary tools and equipment necessary and sufficient for a full cycle of reproduction of fish stocks of river reservoirs, the channel of which is blocked by retaining structures.

Information sources

1. USSR author's certificate No. 1637726, "System for spawning and fish farming", A 01 K 61/00, Authors: Duplyak VD, Filchagov LP et al. (USSR). Publ. BI. No. 12, 1991.

2. USSR author's certificate No. 17575752, "Spawning complex for the reproduction of rheophilic fish species", A 01 K 61/00, Authors: Berezovskaya VI, Savelyeva EA et al. (USSR). Publ. BI. No. 31, 1992.

3. USSR author's certificate No. 1644855, "Device for spawning fish", A 01 K 61/00, Author: Malevanchik BS (THE USSR). Publ. BI. No. 16, 1991.

Claims (14)

1. Spawning complex for the reproduction of rheophilic fish species, including a power supply unit connected with the upper pool of the waterworks and with the head part of the spawning channel, the bottom of which is made with a longitudinal slope, spawning substrate laid on the bottom of the channel tray in the form of gravel-pebble gravel, reinforced elements roughnesses installed on the bottom of the channel with an elevation above the spawning substrate and located at an angle to the longitudinal axis of the spawning channel, a fish passage connected with the spawning channel, the inlet of which communicated with the downstream of the waterworks, while the fish passage tray is equipped with gates and a motive device made in the form of a trolley mounted on guides and having a motive belt for transferring fish along the fish passage, and a chamber for preliminary keeping of fish producers, communicating with the fish passage and spawning channel characterized in that the spawning channel is made in a spiral shape in plan, while the fish passage channel is in communication with the spawning channel through the camera for pre-soda fish producer, which is connected to the input part of the spawning channel, and the end part of the fish passage is equipped with a device for inspection and selection of fish producers in the form of an ichthyological site and a shutter-regulator that separates the fish passage from the camera for preliminary keeping of fish producers, while the said camera is made with a catchment tray parallel to it and a catcher net separating the chamber and the catchment tray, and the interior of the catchment tray is connected by by means of the bottom gallery with the end part of the fish passage tray, while the horizontal part of the outlet of the bottom gallery located in the fish passage tray is made with a louver shutter placed under the fish-retaining grate, the catchment tray is equipped with a shutter separating it from the discharge channel, and the spawning channel tray is installed on vertical supports forming the supporting flyover. 2. Spawning complex according to claim 1, characterized in that the head part of the spawning channel is made with a minimum radius of twist of the spiral, and its input part with a maximum radius of twist of the spiral. 3. Spawning complex according to claim 1, characterized in that the head of the spawning channel is made with a maximum radius of twist of the spiral, and its inlet with a minimum radius of twist of the spiral. 4. The spawning complex according to claim 1, characterized in that the water supply path of the spawning canal is made in the form of two turns of a spiral forming a figure eight, while part of the upstream water supply path is located above its lower sections. 5. The spawning complex according to claim 1, characterized in that the spawning canal is equipped with an additional water supply path located symmetrically to the main axis of the structure, and both spawning channel paths form two turns of a spiral forming a figure eight, while a part of the upstream water supply path is located above its downstream sections, with the main and additional waterways having a common head and inlet parts. 6. Spawning complex according to any one of paragraphs. 1 - 5, characterized in that the elements of enhanced roughness are made in the form of parallelepipeds and adjoin one end part to the sides of the channel tray, while even elements are located along the starboard side, and odd elements along the left side of the channel. 7. Spawning complex according to any one of paragraphs. 1 - 5, characterized in that the elements of reinforced roughness are made in the form of parallelepipeds, forming a V-shape in plan, while the elements of reinforced roughness are located along the longitudinal axis of the spawning channel with the formation of floating holes between their free end parts and the sides of the spawning channel tray. 8. Spawning complex according to any one of paragraphs. 1 - 5, characterized in that the elements of enhanced roughness are made in the plan of a curved shape, with their convex side facing downstream, and the elements of enhanced roughness are located along the longitudinal axis of the spawning channel with the formation of swimming holes between their end parts and the sides of the spawning channel tray . 9. Spawning complex according to any one of paragraphs. 1 to 5, characterized in that it is equipped with additional elements of reinforced roughness, which are installed on the longitudinal axis of the spawning channel perpendicular to it in transverse sections located between the rows of the main elements of reinforced roughness. 10. The spawning complex according to claim 9, characterized in that the main elements of reinforced roughness, located in even rows, are set mirror-image relative to the main elements of reinforced roughness, located in odd rows. 11. Spawning complex according to any one of paragraphs. 1 to 5, characterized in that it is equipped with means for the artificial reproduction of juvenile fish: circulation pools, a hatchery, uterine and larval ponds, as well as a pumping station equipped with a fish protection device. 12. Spawning complex according to any one of paragraphs. 1 to 5, characterized in that the spawning channel along the length is made with an additional spawning substrate imitating natural aquatic vegetation. 13. Spawning complex according to any one of paragraphs. 1 to 5, characterized in that the spawning substrate is made on removable spawning panels. 14. The spawning complex according to claim 11, characterized in that the bottom gallery is connected by a collector to a larval pond, while the collector is equipped with a shutter-regulator.

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