RU2480985C1 - Method for fishing in process of vertical fish migration - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to fishery. The method includes placement of a passive fishing tool at a largest depth during that time of the day, when the main mass of fish is available there. Upon daily migration of the main mass of fish the passive fishing tool is lifted. A hydroacoustic signal is emitted from a fishing vessel towards the passive fishing tool, and this signal synchronously actuates mechanical locks of underwater modules, releasing reserves of vertical working halliards, therefore depth of passive fishing tool location is reduced. Further changes of passive fishing tool location depth are carried out in a similar manner.

EFFECT: invention makes it possible to remotely many times lift a passive fishing tool in accordance with change of a horisation of main fish mass location.

1 tbl, 5 dwg

Description

The invention relates to the field of fishing - fishing with passive fishing gear (FL): nets, longlines, etc., in the process of their vertical migration (for example, daily migration, etc.), as well as to the field of acoustics, and, in particular, to transmission underwater sonar encoded control signals.

The problem that is solved by the invention is to increase the productivity and efficiency of fishing, reducing labor costs on an unlimited range of fishing with expanding the scope while ensuring environmental safety of fishing by remote control of the process of multiple - at least two times, and uniform - simultaneously from both sides, lifting FLOOR to a new depth, determined by the hydroacoustic method - according to the fish-searching means: sonar, echo sounder, etc. or in another way - according to long-term data accurate observations in this area gear et al., i.e., to a depth corresponding to the current horizon of fish during their vertical (for example, diurnal, etc.) migration: the bottom layer - in the daytime (from 10:00 to 16:00), the deep layer - evening twilight (from 16: 00 to 22:00), the surface layer - at night (from 22:00 to 04:00), etc.

There is a known method of fishing, which consists in the horizontal installation of the FLOOR (for example, the net) in a given fishing area and at a given depth determined by a hydroacoustic method - according to the fish-searching means (echo sounder, etc.), or in another way - according to long-term observations in this area fishing, getting the fish into the zone of the retaining action of the FLOOR and keeping the fish in it - getting stuck in the mesh, entangling in a net denser, etc., raising the FLOOR to the sea surface and removing fish from it [1, 2].

The disadvantages of this method include:

1. Low fishing efficiency due to the impossibility of fishing in the process of their vertical (for example, daily) migration.

2. The inability to remotely raise the floor to the surface after the fishing process.

3. The impossibility of fishing in the conditions of intense competition of fishermen with developed sea waves and floating ice, intensive shipping, etc.

A known method of fishing marine biological objects (e.g., squid), which consists in the vertical installation of FLOOR (e.g., vertical pelagic layer) in a given area of fishing, determined by the hydroacoustic method - according to the fish-searching means (echo sounder, etc.), or in another way - according to long-term observations in the fishing area, getting the fishing object into the catchment area and holding the fishing object in it - swallowing hooks with profit, raising the fishing gear to the sea surface and removing the fishing object from it [1, 2, 3].

The disadvantages of this method include:

1. Low efficiency due to fishing of marine biological objects in a small volume of water.

2. The inability to remotely raise the floor to the surface after the fishing process.

3. The impossibility of fishing in the conditions of intense competition of fishermen with developed sea waves and floating ice, intensive shipping, etc.

Closest to the technical nature of the claimed method includes fishing in the process of vertical migration, selected as a prototype method, which consists in forming a horizontal order from one or more networks and installing it, in forming a vertical order from one or more networks and installing it , horizontal and vertical strapping with flexible coupling and their combination into a passive fishing gear (FL) installed in a given body of water, determined in advance by a sonar method - yes fishing means, or in another way - according to long-term observations in this fishing area, etc., when fish get into the zone of retention action of FLOOR and keep fish in it - they get stuck in meshes and entangle in a denser net, raise FLOOR to the surface of the sea and remove from it fish [4].

The disadvantages of the prototype method include:

1. Lack of productivity (fishing efficiency) of fishing - due to the impossibility of correctly taking into account the vertical migration of fish in this area.

2. Lack of efficiency of fishing - due to the use of a large number of horizontal and vertical networks, the inability to remotely raise the FLOOR to the sea surface after the end of the fishing process, etc.

3. High labor costs - due to the use of a large number of horizontal and vertical networks, etc.

4. Limited fishing range - due to the impossibility of fishing in the conditions of floating ice, etc.

5. Limited scope - due to the impossibility of fishing with developed sea waves, the active confrontation of competitors and poachers, intensive shipping, etc.

6. Impossibility of emergency lifting of the LPO - after separation (by wind, waves, passing ships, unscrupulous competitors, etc.) of marker buoys located on the surface, etc.

The problem that is solved by the invention is to develop a method that is free from the above disadvantages.

The technical result of the proposed method consists in a productive and efficient fishing with minimal labor costs on an unlimited range of fishing with the expansion of the scope while ensuring environmental safety of fishing.

This goal is achieved by the fact that in the known method of fishing in the process of their vertical migration, which consists in the formation of a horizontal order from one or more networks - FLOOR, its installation in a given body of water, determined by the hydroacoustic method - according to the fish search means, or in another way - according to long-term observations in this fishing area, etc., when fish enter the FLA holding zone and keep the fish in it (they get stuck in the mesh and entangle in the net), the FLO lifts to the surface armature and extracting therefrom fish LPO initial setting is carried out in the lowermost portion of a predetermined body of water - the horizon find the bulk of fish in a given time of the day with little - 1.5 ... 1 Network height proactively; in addition, before each subsequent change in the horizon (decrease in depth) of the FLOOR location, hydro-acoustic encoded synchronization signals F _C are sequentially formed, amplified and directed towards the FLOOR to provide subsequent synchronous activation of mechanical locks of the NPM or VPM, as well as hydro-acoustic encoded control signals F _i operation NRM or VPM - for the simultaneous operation of their mechanical locks and the release of the corresponding reserves of the vertical working file; additionally carry out the first LPO rise by the first hydroacoustic encoded control signal F ₁ transmitted from the RPM, after raising the bulk of the fish to a depth exceeding 1-1.5 the height of the LPO network, changing the depth of the LPO location by 2-3 height of its network (anticipating equal to 1-1.5 network heights) - due to the synchronous operation of the lower mechanical locks at two NPMs and the simultaneous release of the first stocks of a vertical working file, which were previously in the lower containers; the second LPO rise is carried out by the second hydroacoustic encoded control signal F ₂ transmitted from the RPM, after raising the bulk of the fish to a depth exceeding 1-1.5 the height of the LPO network, changing the depth of the LPO to 1.5-2 the height of its network - for the synchronous operation of the upper mechanical locks of the NPM and the synchronous release of the second stocks of the vertical working file, which were previously in medium containers; the third LPO rise is carried out by the third hydroacoustic encoded control signal F ₃ transmitted from the RPM, after raising the bulk of the fish to a depth exceeding 1.5-2 the height of the LPO network, changing the depth of the LPO by 1-1.5 of the height of its network - for the synchronous operation of the VPM mechanical locks and the synchronous release of the necessary (and not all) third stocks of the vertical working file previously located in the upper containers; at the same time, the third reserves of the vertical working halyard are no less than 10% (for taking into account the current in the area of the LPO installation) exceed the depth of the area of the LPO installation and are placed in the corresponding upper containers in a certain way (laid in the bay with rings from the “English noose” - sea knots, easily blooming when unwinding the bay during the ascent of the FLOOR), thereby providing the possibility of emergency (due to the breakage of signal buoys that were previously on the surface and indicating the boundaries of the FLOOR, etc.) of the rise of the FLOOR from any depth (including bottom) to the surface of the sea; additionally apply backup - temporary control of the operation of all NPMs and VPMs due to the use of timers identical to each other in each of them, ensuring the operation of their respective mechanical locks at a predetermined time; additionally, on the sea surface, the boundaries of the previously set FLOOR are marked with two identical marker buoys and milestones with flashing beacons installed on both sides of the FLOOR and connected to the upper parts of the corresponding VPM by means of thin vertical lines, eliminating, due to a small breaking force, the possibility lifting with their help to the surface of the sea by unscrupulous competitors FLOOR with caught fish.

Figure 1 and figure 2 presents a structural diagram of a device that implements the developed method of fishing in the process of vertical migration. Moreover, figure 1 illustrates the structural diagram of the device mainly to the general principle of implementation of the developed method; figure 2 illustrates the structural diagram of the device mainly to the upper and lower remotely controlled (by sonar channel) underwater modules.

Figure 3 illustrates the appearance of a two-section (with two mechanical locks) lower underwater module (NPM), which has negative buoyancy. Figure 4 illustrates the appearance of a single-section upper underwater module (VPM) with positive buoyancy, as well as a command module (KM).

In Fig. 5, in the form of corresponding histograms, the average catches of fish are illustrated when LPO was found on one (histogram I), two (histogram II) and three (histogram III) horizons during the implementation of the developed method of fishing in the process of their vertical migration.

The device contains (figure 1 and figure 2): fishing (1) vessel (RPS), FLOOR (2) and the object of fishing (OL) - fish (3). At the same time on the RPS (1) there are: a device (4) for setting-sample FLOOR (2), KM (5), a navigation radar (6) station (NRLS) with an antenna (7). In this case, the CM (5) contains serially electrically connected blocks: the formation (8), amplification (9) and radiation (10) of the hydro-acoustic encoded control signals F _i (F ₁ , F ₂ and F ₃ ) and the hydro-acoustic encoded synchronization signals F _C.

In turn, the FLOOR (2) contains: a horizontal working halyard (11) with negative buoyancy (ridge), to which a horizontal network (12) is attached, a vertical working halyard (13) having positive buoyancy (buyre), located on both sides horizontal network (12) and the lower end attached to the corresponding (one of two) anchor (14), as well as having the necessary reserves of the vertical working file, placed in the form of two lower containers (near the bottom) identical to each other (15), ident GOVERNMENTAL one another medium (a network under the horizontal) of containers (16) identical to each other and the upper (above the horizontal chain) of containers (17). In this case, between the corresponding lower containers (15) located on opposite sides of the horizontal network (12) at the same distance from the bottom) and the middle containers (16), two NPMs are identical to each other (18), and two VPMs are identical to each other (19) located above the horizontal network (12) and above the upper containers (17). The fishing gear (2) also contains: a thin vertical line (20), which has positive buoyancy and is attached with its lower end to the corresponding (one of two) VPMs (19), and the upper end to the corresponding (one of two) marker buoys (21) . In turn, each of the two marker buoys (21) is connected with a thin horizontal line (22) to a corresponding milestone (23), at the upper end of which there is a flashing beacon (24).

Moreover, each of the two NPMs (18) and each of the two VPMs (19) contains identical blocks: receiving (25) and amplifying (26) hydro-acoustic encoded synchronization signals at a frequency F _C and hydro-acoustic encoded control signals at frequencies F ₁ , F ₂ and F ₃ , electromagnets identical to each other (30) and mechanical locks (31), each of which in the initial position inserted identical to each other connecting rings (32), identical to each other high-capacity batteries (33) and timers (34) .

Moreover, each of the two NPMs (18) contains identical decoders (27) and (28) of hydroacoustic encoded synchronization signals at a frequency of F _C and hydroacoustic encoded control signals at frequencies of F ₁ and F _2, respectively, and each of two VPMs (19 ) contains identical decoders (29) of hydro-acoustic encoded synchronization signals at a frequency of F _C and hydro-acoustic encoded control signals at a frequency of F ₃ .

The output of each of the high-capacity batteries (33) PNM (18) and VPM (19) is connected to the corresponding amplification units (26), decoders: (27), (28) and (29), electromagnets (30) and timers (34 ) In this case, the body of each of the two VPMs (19) has: bright color and reflective coating - for effective visual search, as well as a special radar coating - for effective technical search (effective reflection of signals) using radar (6) RPS (1).

The method is implemented as follows (figure 1, figure 2).

According to the standard scheme: RPS (2) leaves the base in the morning and goes to the fishing area - in relation to coastal fishing, or leaves in the morning in the specified square of the fishing area - in relation to ocean fishing.

In a given fishing area - OL (3) using the sonar method - according to the fishfinding sonar or echo sounder RPS (1) with radar (6) and antenna (7), or in another way - according to long-term observations, etc. determine the characteristic depths of finding OL (3) at a particular time of day (in the process of vertical migration of fish).

As is known, RPS (1) can serve not one, but several - not less than two, PIC (2), therefore, depending on the fishing situation, they foresee the possibility of changing, in accordance with the vertical migration of fish, the horizon of this LPO (2) ), both by the hydroacoustic encoded control signal F _i transmitted using KM (5) with RPS (1), and at a predetermined time (for example, at 16:00, 22:00 and 04:00 at the initial setting of the FLOOR in 10:00) - using the appropriate timers (34). In this case, the temporary control channel is a backup sonar control channel.

Then, with RPS (1) in the daytime, when OL (3) is in the bottom layers of water, the initial setting of POL (2) in the lowest part of the given water space is carried out - to the horizon of the bulk of fish at this time of day with a small: 1-1.5 heights of the horizontal network (12) FLOOR (2) by anticipation. At the same time, the boundaries of the exposed FLOOR (2) are indicated on the sea surface using two identical marker buoys (21) and connected in them, using thin horizontal lines (22), milestones (23) with flashing beacons (24) installed with both sides of the FLOOR (2) and connected to the upper parts of the corresponding VPM (19) by thin vertical lines (20), which exclude, due to a small breaking force, the possibility of lifting them with the help of unscrupulous competitors of the FLOOR (2), including including already caught fish.

In the presence of developed (more than 3-4 points) sea waves, marker buoys (21), due to insignificant linear dimensions and windage, are more reliably held on the sea surface than typical working buoys, which have much larger linear dimensions and windage. For the same reason, anchors (14) work more efficiently, which ultimately more reliably hold the horizontal network (12) and the FLOOR (2) in the water column as a whole. If unscrupulous competitors and poachers try to raise the previously installed FLOOR (2) to the sea surface, the corresponding thin vertical line (20) with a small tensile force will break off and the FLOOR with fish will remain in place. The same thing will happen when there are floating ice on the sea surface, passing ships, etc.

In the process of moving in a horizontal plane with a gradual rise to the surface - search for food, etc., fish accumulation - OL (2) gets into the zone of catching - holding action of LPO (2), and there is fishing in it: fish get caught in the cells and entangling them in a net web.

However, after some time, during the natural daily migration, the bulk of the fish accumulation leaves the catch zone - it rises above the horizontal network (12) of the FLOOR (2) and continues to move in the horizontal plane with a gradual rise to the surface - search for food.

At the estimated time of lifting LPO (2) to a new horizon, or based on the fishing situation, RPM (1) approaches the area with LPO (2), avoiding repelling OL (3) with its low-frequency (LF) underwater acoustic (noise of operating mechanisms and etc.) and hydrodynamic (noise flowing around the water of the RPS hull and others) noise and using a fish-finding sonar or echo sounder determines the horizon of the current location of OL (3) in the water column, including relative to the FLOOR (2).

With RPS (1), having determined that the main accumulation of fish - OL (3) rose 1-1.5 heights above the horizontal network (12), using KM (5) they give a hydro-acoustic coded control command to trigger the lower mechanical locks (31) ) NPM (18) and the release of stocks of a vertical working file from identical lower containers (15) located on both sides of the horizontal network (12) and below it.

To do this, the RPS (1) falls into the drift, and the KM block (10) is lowered from its side to the depth of at least (to avoid screening by the RPS hull) 5-10 m below the keel of the RPS (1). Then, in series-connected electrically connected blocks (8) and (9), they are set and amplified to the required level (determined by the distance to the NPM LPO) of the hydroacoustic encoded (to exclude accidental operation from signals of natural and technogenic origin, as well as to exclude the selection of signals by dishonest competitors) the synchronization signal F _C , as well as its subsequent radiation directed toward the NPM (18), using the CM unit (10) (5).

In the receiving (25) and gain (26) blocks that are identical to each other, as well as in the identical blocks: decoders (27) - for the lower locks of each of the two NPMs (18), in decoders (28) - for the upper locks of each of the two NPM (18), in the decoders (29) - for the locks of each of the two VPMs (19), receive, amplify and decrypt (compare the synchronization code set in advance with the received synchronization code) of the received hydroacoustic encoded synchronization signals F _C. In case of coincidence of the set and accepted codes, the electronic blocks of all NPMs (18) and VPM (19) are synchronized and put into standby mode for receiving the corresponding hydroacoustic encoded control signal. Synchronization of all underwater modules is done so that in case of force majeure circumstances it would be possible to immediately stop fishing and raise the FLOOR (2) to the surface of the sea, or, based on fishing conditions: the fish went abruptly to the surface, etc., to ensure synchronous rise of LPO (2) not by 2-3 heights of the horizontal network (12), but by 4-6 heights of the horizontal network (12), etc.

Then, in series-connected electrically connected blocks (8) and (9), the coded control signal F ₁ is set and amplified to the required level, as well as its subsequent radiation directed towards the NPM (18), using the KM block (10) (5) .

In the blocks of reception (25), amplification (26) and decoders (27) that are identical to each other, the received, amplified and decrypted received hydroacoustic encoded control signals F _{1 are} received. In case of coincidence of the set and accepted codes, the control signals are synchronously applied to the electromagnets (30), which in turn synchronously open the lower mechanical locks (31) of the NPM (18). Under the action of positive buoyancy provided by the VPM (19), the connecting rings (32) previously inserted into them are synchronously released from the mechanical locks (31). Then, from the lower containers identical to each other (15), the corresponding reserves of the vertical working file (13) synchronously exit and the horizontal network (12) synchronously rises to 2-3 of its height and occupies a new horizon.

In the process of moving in a horizontal plane with a gradual rise (due to natural daily migration) to the surface - search for food, etc., fish accumulation - OL (2) gets into a new area of LPO fishing (2) and a new (repeated) fishing occurs in it: fish stuck in the cells and their entanglement in the net. However, after some time in the course of natural daily migration, the bulk of the fish accumulation leaves the new fishing zone - rises above the horizontal network (12) of FLOOR (2) and continues to move in the horizontal plane with a gradual rise to the surface - search for food.

By analogy with the above, with RPS (1), having determined that the main accumulation of fish - OL (3) has risen 1-1.5 times the height of the horizontal network (12), using KM (5) they give a hydroacoustic encoded control command to operate upper mechanical locks (31) NPM (18) and the release of stocks of a vertical working file from identical middle containers (16), placed on both sides of the horizontal network (12) and below it. For this, the RPM (1) again drifts to the drift and from its side the block (10) KM (5) is lowered to a depth of at least 5-10 m below the keel of the RPM (1). Then, in series-connected electrically connected blocks (8) and (9), the hydroacoustic encoded synchronization signal F _C is set and amplified to the required level, as well as its subsequent radiation directed towards the NPM (18), using the CM unit (10) ( 5).

In the receiving (25) and gain (26) blocks that are identical to each other, as well as in the identical blocks: decoders (28) - for the upper locks of each of the two NPMs (18) and decoders (29) - for the locks of each of the two VPMs ( 19), receive, amplify and decrypt received hydroacoustic encoded synchronization signals F _C. If the set and accepted codes match, the corresponding electronic units of all NPMs (18) and all VPM electronic units (19) are synchronized and put into standby mode for receiving the corresponding hydroacoustic encoded control signal. Then, in series-connected electrically connected blocks (8) and (9), the coded control signal F ₂ is set and amplified to the required level, as well as its subsequent radiation directed towards the NPM (18) using the KM block (10) (5 )

In the blocks of reception (25), amplification (26) and decoders (28) that are identical to each other, reception, amplification and decryption of the received hydroacoustic encoded control signals F _{2 are} carried out. In case of coincidence of the set and accepted codes, the control signals are synchronously fed to the electromagnets (30), which in turn synchronously open the upper mechanical locks (31) of the NPM (18). Under the action of positive buoyancy provided by the VPM (19), the connecting rings (32) previously inserted into them are synchronously released from the mechanical locks (31). Then, from the middle containers identical to each other (16), the corresponding reserves of the vertical working file (13) synchronously exit, and the horizontal network (12) synchronously rises to 2-3 of its heights and occupies a new horizon.

In the process of moving in the horizontal plane with a gradual rise (due to natural daily migration) to the surface - search for food, etc., fish accumulation - OL (2) falls into the second new zone of LPO fishing (2) and a new (third) fishing occurs fish in it: fish stuck in the cells and their entanglement in the net. However, after some time in the process of natural daily migration, the bulk of the fish accumulation leaves the second new catch zone - rises above the horizontal network (12) of FLOOR (2) and continues to move in the horizontal plane with a gradual rise to the surface - search for food.

By analogy with the above, with RPS (1), having determined that the main accumulation of fish - OL (3) has risen 1-1.5 times the height of the horizontal network (12), using KM (5) they give a hydroacoustic encoded control command to operate mechanical locks (31) VPM (19) and the release of stocks of a vertical working file from identical top containers (17), placed on both sides of the horizontal network (12) and above it. For this, the RPM (1) again drifts to the drift and from its side the block (10) KM (5) is lowered to a depth of at least 5-10 m below the keel of the RPM (1). Then, in series-connected electrically connected blocks (8) and (9), the hydroacoustic encoded synchronization signal F _C is set and amplified to the required level, as well as its subsequent radiation directed towards the VPM (19), using the KM block (10) (5).

In identical reception blocks (25) and amplification (26), as well as in identical decoders (29) of each of the two VPMs (19), the received, amplified, and decrypted received hydroacoustic encoded synchronization signals F _{C are} carried out. In case of coincidence of the set and accepted codes, the electronic blocks of all VPM (19) are synchronized and put into standby mode for receiving the corresponding hydroacoustic encoded control signal. Then, in series-connected electrically connected blocks (8) and (9), the coded control signal F ₃ is set and amplified to the required level, as well as its subsequent radiation directed towards the VPM (19), using the KM block (10) (5 )

In identical blocks of reception (25), amplification (26) and decoders (29), receive, amplify and decrypt received hydro-acoustic encoded control signals F ₃ . In case of coincidence of the set and received codes, the control signals are synchronously fed to the electromagnets (30), which, in turn, simultaneously open the mechanical locks (31) of the VPM (19). Under the action of positive buoyancy provided by the VPM (19), the connecting rings (32) previously inserted into them are synchronously released from the mechanical locks (31). Then, from the upper containers identical to each other (17), the corresponding reserves of the vertical working file (13) synchronously exit, and the horizontal network (12) synchronously rises to 2-3 of its heights and occupies the third new horizon.

In the process of moving in the horizontal plane with a gradual rise (due to natural daily migration) to the surface - search for food, etc., fish accumulation - OL (2) falls into the third new zone of LPO fishing (2), and a new (fourth) occurs fishing in it: stuck fish in the cells and entangling them in the net.

As noted earlier, in the case of using information about typical fish horizons according to long-term daily observations or the inability, for some reason, of the RPS (1) approach to LPO (2), the signal for the operation of the corresponding electromagnets (30) and locks ( 31) NPM (18) and VPM (19) comes from the corresponding timers (34). In this case, using the corresponding high-capacity batteries (33), power is supplied to the amplification units (26), decoders: (27), (28) and (29), as well as electromagnets (30) and timers (34).

After the end of the fishing process, the FLO data (2) to one of its ends (for example, to the west - with the east wind): marker buoy (21), connected using a thin horizontal line (22) with the corresponding pole (23), at the upper end which contains a flashing beacon (24) - if they are on the sea surface, or at the calculated point - in the event of a marker buoy (21) breakage with a milestone (23), the emergence of the corresponding VPM (19), whose body has a bright color and a reflective coating ( for a better visual search), as well as a special radio munication coating (for better technical research), suitable RPM (1) with NRS (6).

After the detection (visually or technically) of the VPM that has surfaced on the sea surface (19), it is lifted aboard the RPS (1), and then, using the vertical working halyard (13) and the FLOOR sampling and selection device (4), (2), boarding the RPS (1) of the FLOOR itself (2) with fish - OL (3). Then, the FLOOR (2) is prepared for a new formulation, for which: each of the IMF (18) and each of the VPM (19) are put into standby mode (standby mode for receiving hydroacoustic encoded synchronization and control signals) by turning the inserted in the corresponding mechanical locks (31) of the connecting rings (32), and the reserves of the vertical working file in a certain way (excluding tangling during automatic unwinding) are placed in the corresponding lower (15), middle (16) and upper (17) containers.

Wherein:

1. High fishing productivity is achieved due to the fact that:

- the initial setting of the FLOOR is carried out using the data of a fish-finding sonar (echo sounder), or long-term observations, in the lowest part of a given water space - to the horizon of the bulk of fish at a given time of the day with a little lead;

- make a multiple change in the depth of the FLOOR, preliminarily using the data of a fish-finding sonar (echo sounder), or long-term observations, to the horizon of finding the bulk of fish at a given time of the day with a little lead, etc .;

- apply backup (temporary) management of all NPMs and VPMs through the use of identical timers in each of them;

- ensure that LPO is protected from theft by unscrupulous competitors by connecting VPM and marker buoys with a thin vertical line, which eliminates, due to a small breaking force, the possibility of lifting LPO to the sea surface, etc.

2. High efficiency of fishing is achieved due to the fact that:

- with RPS, only one horizontal network is set up, and then repeatedly, remotely or after a predetermined time, they are raised to a new depth in accordance with a change in the horizon of the bulk of fish - OL in the process of their vertical migration;

- one RPS can simultaneously serve several FLOOR. For example, one LPO can be controlled remotely via a sonar channel, and the other (other) LPO can be controlled via a temporary channel, etc.

3. Low labor costs provide due to the fact that:

- the deck team is involved in the work 2 times - for one setting and sampling of the FLOOR, and then repeatedly, remotely or after a specified time, the FLOOR is raised to a new depth in accordance with the change in the horizon of the bulk of the fish, without the participation of the deck team.

In other words, instead of 4 sets of LPO samples at different depths, only one LPO sample statement is performed:

- one RPM, at the same labor costs of the deck crew, can simultaneously serve four LPOs. For example, one LPO can be controlled remotely via a sonar channel, and three by a temporary channel, etc.

4. The expansion of the range of fishing is achieved due to the fact that:

- provide, due to the presence of a channel for automatic emergency search and ascent of FLOOR to the sea surface, the possibility of fishing in areas with difficult soil, when as a result of anchor hooks and subsequent breakage of vertical working files, LPF is usually lost and they refuse fishing in productive areas;

- provide, thanks to hydroacoustic coded control signals, the possibility of fishing in the conditions of floating ice, when the FLOOR is immediately raised to the sea surface during the formation (due to wind, current, etc.) of the corresponding wormwood above it, etc .;

5. The expansion of the scope is achieved due to the fact that:

- provide, thanks to hydroacoustic coded control signals, the possibility of fishing with developed sea waves;

- provide, thanks to hydro-acoustic coded control signals, the possibility of fishing in heavy shipping;

- provide, thanks to hydroacoustic coded control signals, the possibility of fishing and putting products (without raising part of the LPO) with the active confrontation of competitors and poachers (usually in a very productive fishing area), etc.

6. Ensuring environmental safety of fishing (fishing) is achieved due to the fact that:

- provide, thanks to hydroacoustic coded control signals, the possibility of emergency - after separation (by wind, waves, passing ships, etc.) of marker buoys, ascent of LPO to the surface;

- provide, thanks to the temporary control channel, the possibility of automatic ascent at a given time FLOOR to the surface, etc.

Distinctive features of the prototype of the features of the proposed method are:

1. Initial setting of FLOOR is carried out in the lowest part of a given body of water - to the horizon of the bulk of fish at a given time of the day with a small - 1 ... 1.5 network height, lead.

2. Before each subsequent change in the horizon, LPO emit hydro-acoustic encoded synchronization signals F _C.

3. The first synchronous LPO rise is carried out according to the first hydroacoustic encoded control signal F ₁ transmitted from the RPM, after raising the bulk of the fish to a depth exceeding 1-1.5 the height of the LPO network, changing the depth of the LPO location by 2-3 height of its network from a lead equal to 1-1.5 network heights.

4. The second synchronous lifting of the LPO is carried out by the second hydroacoustic encoded control signal F ₂ transmitted from the RPS, after lifting the bulk of the fish to a depth exceeding 1-1.5 the height of the LPO network, changing the depth of the LPO to 1.5-2 its height network.

5. The third synchronous rise of the FLOOR is carried out by the third hydroacoustic encoded control signal F ₃ transmitted from the RPM, after raising the bulk of the fish to a depth exceeding 1.5-2 the height of the FLOOR network, changing the depth of the FLOOR by 1-1.5 of its height network.

6. Emergency lifting of the FLOOR from any depth (including from the bottom) to the sea surface is carried out at any time or at any stage of lifting, according to the third hydroacoustic encoded control signal F ₃ transmitted from the RPM, as well as due to the third reserve of the vertical working file less than 10% (to account for the flow in the area of the LPO installation) exceeding the depth of the area of the LPO installation and placed in the corresponding upper containers.

7. The stocks of the vertical working file in the lower, middle and upper containers are stacked with rings from the "English noose", which are easily opened when unwinding during the ascent of the FLOOR.

8. To change the depth of the FLOOR during vertical migration of fish, backup (temporary) control of the operation of all NPMs and VPMs is used due to the use of identical timers in each of them.

9. On the surface of the sea, the boundaries of the previously announced FLOOR are marked with two identical marker buoys and milestones with flashing beacons installed on both sides of the FLOOR and connected to the upper parts of the corresponding VPM.

10. Ensure that LPO is protected from theft by unscrupulous competitors by connecting VPM and marker buoys with a thin vertical line, which eliminates, due to a small tensile force, the possibility of lifting LPO on the sea surface.

The presence of distinctive features from the prototype features allows us to conclude that the proposed method meets the criterion of "novelty."

An analysis of the known technical solutions in order to detect the indicated distinctive features in them showed the following.

Signs 3, 4, 5, 6 and 10 are new and their use for fishing in the process of their vertical migration is unknown.

Signs 2, 7 and 8 are new and their use for fishing in the process of their vertical migration is unknown. At the same time, the use is known: sign 2 - in telemetry, sign 7 - in navigation and fishing, sign 8 - in oceanology.

Signs 1 and 9 are well known when fishing.

Thus, the presence of new significant features, in combination with the known ones, provides the appearance of the proposed solution with a new property that does not coincide with the properties of the known technical solutions - to fish (productively (efficiently) and quickly (quickly) in the process of their vertical migration with minimal labor costs unlimited fishing range (rocky soil, floating ice, etc.) with the expansion of the scope (with developed sea waves, intensive shipping, etc.) while ensuring environmental safety and (providing automatic search and recovery at the sea surface from any depth, including from the bottom) fishing.

In this case, we have a new set of features and their new relationship, moreover, it’s not a simple combination of new features and already known ones, but the execution of operations in the proposed sequence leads to a qualitatively new effect.

This circumstance allows us to conclude that the developed method meets the criterion of "significant differences".

An example implementation of the method.

Field tests of the developed method were carried out at the fishery training ground in Severnaya Bay (Peter the Great Bay, Sea of Japan) in 2001, as well as in the Republic of Korea in 2005-2007. A total of 16 LPO settings were carried out, as well as 48 remote changes in the depth of horizontal networks, and not a single case of failure of the NPM and VPM was recorded. There were also 8 sets of LPOs, as well as 24 automatic ones — through a temporary control channel, remote changes in the depths of horizontal networks, and not a single case of failure of the NPM and VPM timers was recorded.

Figure 3 and figure 4 illustrates the appearance of a two-section NPM with negative buoyancy, and a single-section VPM with positive buoyancy, as well as KM used in the testing process of the developed method of fishing.

In table 1 - in the corresponding lines and in figure 5 - in the form of the corresponding histograms, the average fish catches (kg) are presented when the experimental (length - 50 m, height - 2.5 m) LPO on one (histogram I) is presented, two (histogram II) and three (histogram III) horizons during the implementation of the developed method of fishing in the process of their vertical migration. Tests of the developed method were carried out in the coastal regions of the Republic of Korea on one of the fishing vessels of the company "BluWave" (Seoul).

Average catches of fish in the process of implementing the developed method FLOOR horizons and time spent, hours The average catch of LPO on this horizon, kg Note One, 6 500 Lower Two, 12 850 Lower and middle Three, 18 1250 Lower, middle and upper

As can be seen from table 1 and figure 5, when the experimental LPO is located on two horizons for 12 hours, its catchability increases by ~ 350 kg (~ 70%), and when located at three horizons for 18 hours ~ 750 kg (~ 150%). It should be noted that in the design of experimental FLOOR as in the prototype method (one horizontal network 50 m long and 2.5 m wide, as well as two vertical networks 50 m long and 2.5 m wide, located at the edges of the horizontal network ) the catch for 18 hours was 750 kg (gain ~ 500 kg or ~ 66.7%), and with the typical design of experimental FLOOR as the analogue method (one horizontal network 50 m long and 2.5 m wide) catch for 18 h was 600 kg (gain ~ 650 kg or ~ 108.3%). However, when implementing the prototype method, the duration of the staging-sampling process was 4-5 times the duration of the developed method and was 5-6 hours with the involvement of the second RPS. It should also be noted that when the sea wave was more than 2-3 points, even experimental (shortened) LPO was not possible. Thus, the advantages of the developed method of fishing in the process of their vertical migration over the prototype method are obvious. Wherein:

1. High fishing productivity was achieved due to the fact that:

- the initial setting of the FLOOR was carried out, using the data of a fish-finding sonar (echo sounder) or long-term observations, in the lowest part of a given water space - to the horizon of the bulk of fish at a given time of the day with little lead;

- made a multiple change in the depth of the FLOOR, preliminarily using the data of a fish-finding sonar (echo sounder), or long-term observations, to the horizon of finding the bulk of fish at a given time of the day with a little lead, etc .;

- applied backup (temporary) control of all NPMs and VPMs through the use of identical timers in each of them;

- ensure that LPO is protected from theft by unscrupulous competitors by connecting VPM and marker buoys with a thin vertical line, which eliminates, due to a small breaking force, the possibility of lifting LPO to the sea surface, etc.

2. High efficiency of fishing was achieved due to the fact that:

- with RPS, only one horizontal network was set up, and then it was repeatedly, remotely, or after a specified time raised it to a new depth in accordance with the change in the horizon of the bulk of fish - OL in the process of their vertical migration;

- one RPS simultaneously served several PAFs. For example, one LPO was controlled remotely via a sonar channel, and the other (other) LPO was controlled via a temporary channel, etc.

3. Low labor costs provided due to the fact that:

- the deck team was involved in the work 2 times - for one setting and sampling of the FLOOR, and then repeatedly, remotely or after a specified time, the FLOOR was raised to a new depth in accordance with the change in the horizon of the bulk of fish, without the participation of the deck team;

- one RPM, with the same labor costs of the deck crew, could simultaneously serve four LPOs;

4. The expansion of the range of fishing was achieved due to the fact that they provided the possibility of fishing in areas with difficult soil, etc.

5. The expansion of the scope was achieved due to the fact that:

- provided the possibility of fishing with developed (more than 3 points) sea waves;

- provided the opportunity for fishing with intensive coastal shipping;

- provided the possibility of delivery of products when the floor was under water, etc.

6. Ensuring the ecological safety of fishing is achieved thanks to:

- provided the possibility of emergency ascent of FLOOR to the surface;

- provided the possibility of automatic ascent at a given time FLOOR to the surface, etc.

Literature:

1. Telyatnik OV Technology for fishing. - Vladivostok: Dalrybvtuz, 2000, p.13-17.

2. Melnikov V.N. The device of fishing gears and technology for fishing. - M.: Agropromizdat, 1991, 384 p.

3. Daily vertical migration of planktonivorous fish. - Proceedings of VNIRO. - M .: 1961. - T.14. - S.177-186.

4. Mammoth A.M. - RF patent No. 2279217, by application No. 2004130223 of October 11, 2004.

5. Bakharev SA, Bondar LF, Norinov E.I. et al. Progressive fishing methods for marine biological objects. Report on scientific research "Water area". - Vladivostok. - Dalrybvtuz, 2000, 198 p.

Claims (1)

The method of fishing in the process of their vertical migration, which consists in the formation of a horizontal order from one or more nets - a passive fishing gear, its installation in a given body of water, determined by a hydroacoustic method - according to a fish finding tool, or in another way - according to long-term observations in this fishing area, etc., when fish enter the retention zone of a passive fishing gear and retain fish in it, raise a passive fishing gear to the surface of the sea and remove fish from it, characterized in that then the initial setting of the passive fishing gear is carried out in the lowest part of the specified body of water - to the horizon of finding the bulk of fish at a given time of the day with a small - 1 ... 1.5 height of the net, leading, in addition, before each subsequent change in the horizon of finding the passive fishing gear, sequentially form, amplify and toward the passive fishing gear emit hydroacoustic encoded synchronization signals F _C - to ensure subsequent synchronized operation of mechanical locks, and also hydro-acoustic coded control signals F _{i for} operation of the lower underwater modules or upper underwater modules - for the simultaneous operation of their mechanical locks and the release of the corresponding reserves of the vertical working halyard, additionally the first passive fishing gear is lifted by the first hydro-acoustic coded control signal F ₁ transmitted from the fishing vessel , after raising the bulk of the fish to a depth exceeding 1-1.5 network heights, changing the depth of the passive instrument fishing at 2-3 heights of his net - due to the synchronous operation of the lower mechanical locks at the two lower underwater modules and the synchronous release of the first stocks of the vertical working file, which were previously in the lower containers; the second rise of the passive fishing gear is carried out in a similar manner by the second hydroacoustic encoded control signal F ₂ after lifting the bulk of the fish to a depth exceeding 1-1.5 network heights, changing the depth of the passive fishing gear by 1.5-2 height of its net - the synchronous operation of the upper mechanical locks of the lower underwater modules and the synchronous release of the second stocks of the vertical working file, previously located in medium containers; the third passive fishing gear lift is carried out in a similar manner by the third hydroacoustic encoded control signal F ₃ after the bulk of the fish has been raised to a depth exceeding 1.5-2 network heights, changing the depth of the passive fishing gear by 1-1.5 of its net height - for due to the synchronous operation of the mechanical locks of the upper underwater modules and the synchronous release of the necessary third reserves of the vertical working file, previously located in the upper containers; while the third stocks are not less than 10% greater than the depth of the region and placed in the corresponding upper containers in a certain way, providing the possibility of emergency lifting of the passive fishing gear from any depth to the sea surface, additionally apply temporary control of the operation of all lower underwater modules and upper underwater modules for the use of timers in each of them, which ensures that their respective mechanical locks are activated at a predetermined time, additionally on the sea surface mean the boundaries of the previously set passive fishing gear using two identical marker buoys and milestones with flashing beacons installed on both sides of the passive fishing gear and connected to the upper parts of the corresponding upper underwater modules by thin vertical lines, which exclude the possibility of lifting the passive gear to the sea surface fishing with fish.

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