RU2760192C2 - Method for growing fish in cage complexes - Google Patents

Abstract

FIELD: fish farming.SUBSTANCE: method is characterized by the formation, amplification and emission of acoustic signals under water towards a fish cluster. During feeding of farmed fish, previously recorded signals are emitted that are generated by farmed fish during their feeding. After feeding, previously recorded signals are emitted that are formed by farmed fish during their smooth movement after feeding. Broadband signals of a “white noise” type and high-gradient signals in the ultrasonic frequency range are emitted towards the fish cluster continuously, and additionally, in the opposite direction from farmed fish.EFFECT: invention provides a rapid increase in the biomass of fish framed in cage complexes.1 cl, 7 dwg

Description

The invention relates to the field of bioacoustics. In particular: in the process of raising fish in cage complexes (SC) - to calm it down and eliminate its irritation (fright, etc.): man-made noise and signals (operation of a diesel generator, ship systems, crew life, etc.) ) a feed barge (BKR), located at a distance of tens of meters from the cage complex (SC), noises of long-distance navigation (passing vessels at a distance of tens of kilometers from the SC) and noise of short-range navigation (passing motor boats at a distance of tens of meters from the SC), increased (as a result of a storm, etc.) by sea noises, signals of marine (MM) mammals (seals, seals, etc.) -natural predators of fish raised in the UK, etc., to motivate (call) fish to start taking food with BKR and active food intake in the process of feeding all fish (regardless of the physiological state and depth of being in the SC), for relaxation (relaxation) of the fish after the end of the food intake; to neutralize the negative impact (fish biting) of fish parasites (lice, etc.) and calm the fish in the aquatic environment of the UK; for luring fish to passive fishing gear (fixed seines, nets, longlines, etc.) in industrial fishing; for luring fish to pleasure yachts and boats in sea tourism; for luring fish to recreational fishing grounds in restaurants on the water, etc.

A known method of scaring fish, based on the formation, amplification and radiation under water towards the accumulation of fish energy (negatively affecting the internal organs of fish: the swim bladder, the inner ear, etc.) signals (ES) frightening fish and displacing them from an underwater object: from a water intake, etc. / Protasov V.R., Poddubny A.G., Pyatnitsky and others. Method of scaring away fish // AS USSR No. 454878, 1974 /.

The disadvantages of this method include.

1. Low efficiency of frightening off fish - due to the impossibility of forming and emitting energy signals (which have no information value for fish) in a narrow frequency range.

2. Fast adaptation of fish to the same type of energy (artificial and concentrated in a narrow frequency range) signals.

3. Limited area of application of the method: the impossibility of increasing the appetite of fish during their feeding (to receive the maximum amount of food), the impossibility of calming the fish after eating (to accelerate weight gain), the impossibility of physical destruction of fish parasites, etc.

A known method of scaring fish, based on the formation, amplification and radiation under water in the direction of the accumulation of fish information signals (IS) - signals of natural fish predators [Bogatyrev PB, Pyatnitsky II, Protasov V.R. A method of scaring away fish // AS USSR No. 1118382, 1984].

The disadvantages of this method include.

1. Low efficiency of frightening off fish - due to the use of the same type (only information - not having a painful effect on fish) signals in a narrow frequency range.

2. Fast adaptation of fish to information signals of the same type in a narrow frequency range.

3. Limited area of application of the method: the impossibility of increasing the appetite of fish during their feeding (to receive the maximum amount of food), the impossibility of calming the fish after eating (to accelerate weight gain), the impossibility of physical destruction of fish parasites, etc.

There is a known method of fishing in inland waters, based on the formation, amplification and radiation under the water towards the accumulation of fish information and energy signals in a wide frequency range [Truskanov MD, Ionkin NN, Kondratyev V.I. The use of sound fields in inland fisheries // Fish industry. - M., 1977, no. 11, p. 65-66].

The disadvantages of this method include.

1. Insufficient efficiency of the method - due to the use of only energy signals and information signals.

2. Impossibility of acoustic concealment of noise and harmonic, continuous and impulse man-made signals (short and long distance navigation, noises and signals of a feeding barge, etc.) and fish calming.

3. Impossibility of acoustic concealment of the surrounding fish, harmonic, quasi-continuous (lasting up to 5 sec) and impulse signals of a biological nature (signals of marine mammals - natural predators of fish, etc.) and calming the fish.

4. Impossibility of acoustic lure of fish (for example, in the feeding area, etc.).

5. Impossibility of acoustic stimulation (to receive the maximum amount of food) of the fish feeding process.

6. Impossibility of relaxation (relaxation and calming) of fish after feeding.

7. The impossibility of neutralizing the possible negative effects of fish parasites on fish, and calming the fish, etc.

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

The technical result of the proposed method for growing fish in cage complexes is to rapidly increase the biomass of fish grown in cage complexes (after each feeding and during the entire period of fish growing in cage complexes) by: luring into the feeding area (which may be located above or below the traditional horizon) finding fish reared in cage complexes); increasing appetite during each feeding (which increases with active food intake by relatives), calming the fish after feeding; against the background of negative impact: man-made noise (noise and signal of the feeding barge: operation of the ventilation system, operation of the feed supply system to cage complexes, etc.), noises of long-distance navigation (passing vessels of transport and fishing classes) and short-range navigation (boats and motor boats of the population of coastal villages and tourist centers), signals of the biological nature of marine mammals (seals, seals, dolphins, sea lions, etc.) - natural predators of fish reared in cage complexes, etc .; under different conditions (for example, in different seasons of the year, with different amounts of precipitation, with different waves of the sea, etc.); against the background of negative (irritating, painful, etc.) effects of parasites (fish lice); ensuring medical safety for humans (servicing cage complexes); ensuring environmental safety: for fish grown in cage complexes, for marine mammals (traditional inhabitants of seas and rivers and natural predators of fish raised in cage complexes) and for the natural environment (OPS) in general.

This goal is achieved by the fact that in the method of growing fish in cage complexes, characterized by the formation, amplification, and radiation under water towards the accumulation of fish acoustic signals: while feeding the farmed fish, they emit previously recorded signals formed by the farmed fish in the process of their feeding; after feeding, they emit previously recorded signals formed by the farmed fish in the process of their smooth movement after eating; broadband signals of the "white noise" type and high-gradient signals in the ultrasonic frequency range are emitted towards the congregation of fish continuously, and additionally, in the direction opposite to the farmed fish.

FIG. 1-fig. 3 shows a block diagram of a device that implements the developed method of raising fish in cage complexes.

FIG. 1 illustrates the block diagram of the device in relation to the general principle of the implementation of the developed method of raising fish in cage complexes.

FIG. 2 illustrates the block diagram of the device in relation to a single SC cage.

FIG. 3 illustrates the block diagram of the device in relation to the acoustic unit (AB).

A device for growing fish in cage complexes, in the simplest case, contains: water space (1) - a source of broadband water noise at a frequency F _ШВ (as a result of waves, tidal currents, etc.) of the sea, BKR (2) with a sealed housing (3), a diesel generator (4), a mechanical workshop (5), with a feed complex (6) and with an acoustic unit (7) - a source of wide-band ship noise (diesel generator operation, etc.) at a frequency F _SS and a control unit (21), with the help of which a uniform supply of HA (16) to all cages (13) of the SC (12) is provided.

In turn, each cage (13) SC (12), in the simplest case, contains functionally connected in series: a buoyancy block (22), a set-cloth (23) and an anchor block (24). Each cage (13) SK (12) also contains: an underwater lamp (25) - to simulate daylight hours under water, etc., an underwater video camera (26) - to monitor the BP feeding process (14), etc.

In this case, the AB (7) contains: a channel (27) for the formation, amplification and continuous emission of broadband signals of the "white noise" type at a frequency f _BS , which, in terms of the frequency range and signal level, completely overlap similar parameters of sources: sea noise at a frequency F _ШВ ; ship noise at frequency F _SN ; ship signals at frequencies F _SS ; noise at frequency F _PR , biological signals MM at frequency F _MM , noise at frequency F _SHDS and noise at frequency F _SHBS ; channel (28) for the formation, amplification and continuous emission of high-gradient SPL signals at frequencies f _SPL ; channel (29) of formation, amplification and emission of low-frequency (LF) - in the frequency range from 20 Hz to 2 kHz (in the range of maximum acoustic sensitivity BP), pulse - with a signal duration of several - at least two, milliseconds, signals received on hearing as a "crunch" at frequency f ₁ ; channel (30) of formation, amplification and emission of LF - in the frequency range from 20 Hz to 2 kHz (in the range of maximum acoustic sensitivity BP), modulated in frequency and in amplitude, quasi-pulse signals - with a signal duration from fractions of milliseconds to units of seconds, perceived by ear as a "gurgle" at a frequency, an electronic computing (computer) machine (31), which controls the operation of all AB channels (7) with control signals at a frequency ω _Y.

In turn: channel (27) AB (7) contains functionally connected in series: the first generator (32), the first power amplifier (33), the first signal cable-cable (34) and the first hydroacoustic emitter (35); channel (28) AB (7) contains functionally connected in series: the first multichannel generator (36), the first multichannel power amplifier (37), several - according to the number of cages (13), second signal cables (38), several - according to the number cages (13), second hydroacoustic emitters (39); channel (29) AB (7) contains functionally connected in series: the second multichannel generator (40), the second multichannel power amplifier (41), several - according to the number of cages (13), third signal cables (42), several - according to the number cages (13), third hydroacoustic emitters (43); channel (30) AB (7) contains functionally connected in series: the third multichannel generator (44), the third multichannel power amplifier (45), several - according to the number of cages (13), fourth signal cables (46), several - according to the number cages (13), fourth hydroacoustic emitters (47).

The device operates as follows (Fig. 1-Fig. 3).

In the water space (1), cages (13) SC (12) with BP (14) are installed. In this case, the process of raising fish (for example, salmon fish: trout, etc.) usually takes 2-3 years.

The body of water is a source of sea noises (as a result of wind waves, etc.) at frequency F _SW , the level of which (noise) is significant - 2 times or more, periodically increases even in natural conditions - during the sea waves, to which BP (14) got used to it. That is, even high sea noises at frequency F _SW do not have a negative effect on BP behavior (14): BPs actively feed, move smoothly and slowly in the cage (in a circle) after feeding, and, ultimately, gain weight well.

However, the BKR (2) - with a diesel generator (4), a mechanical workshop (5) and with a feed complex (6), etc., is a source of constant and periodic (including unequal in shape and amplitude) ship noises at the Fern frequency and ship signals at the Fee frequencies. These noises and signals, in contrast to the noise of the sea at the frequency Rtsch, have no analogues in Nature. Therefore, BP (14) reacts negatively to them: they begin to eat less actively, begin to move unevenly and in more than one direction, gain weight worse, etc.

Also negatively BP (14) influence driving noise at the frequency F of navigation _FAS, and especially low noise dispatch at frequency F _SDC. In particular, when a high-speed motor boat passes near the SC (12), a negative BP reaction is always noted (14): BPs begin to eat worse, begin to move unevenly and not in one direction, and, ultimately, gain weight worse, etc.

Also, BP (14) is negatively influenced by biological signals of MM (9) - natural predators PR (9) and BP (14) at the frequency F _MM .

To minimize, or even to completely eliminate, the negative impact of the above factors on BP (14) using a series of functionally connected: the first generator (32), the first power amplifier (33), the first signal cable-cable (34) and the first hydroacoustic emitter (35) channel (27) AB (7) carry out the formation, amplification and continuous radiation - from the moment of planting juvenile BP (14) in the corresponding cage (13) SC (12) to the removal of marketable fish from the cage (13) SC (12) , broadband signals of the "white noise" type at frequency f _BS , which (signals) in the frequency range and in the level of radiation (intensity) completely cover similar parameters of the sources: sea (water) noise at frequency F _WB ; ship noise at frequency F _SN ; ship signals at frequency F _SS ; noise at frequency F _PR , biological signals MM at frequency F _MM , long-distance shipping noise at frequency F _SHDS and short-range shipping noise at frequency F _SHBS .

As a result, from the moment of being in the cage (13) BP (14) almost completely - by 95%, stop reacting negatively to these "acoustic stimuli", eat well, move smoothly and slowly in the cage (in a circle), and gain weight well.

However, due to insufficiently high competition for BP (it is much lower than in Nature), due to excess (almost always part of the feed remains in the water) feed for BP (14), due to incorrect BP feeding process (14) by the feed operator complex (6) BKR (2), due to the presence of BP (14) in the cramped conditions of the cage (13), etc., BP (14), at some stage of its growth, or at some period of the year (for example, in winter - at low water temperatures, on a polar night - with poor lighting, etc.), or at some period of the day (for example, new), they begin to eat poorly and, ultimately, gain weight worse.

To minimize, or even to completely eliminate, the negative impact of the above factors on BP (14) using a series of functionally connected: a second multichannel generator (40), a second multichannel power amplifier (41), several - according to the number of cages (13), third signal cables (42), several - according to the number of cages (13), third hydroacoustic emitters (43) of the AB channel (29) (7) carry out the formation, amplification and radiation - immediately after the supply of the GK (16) to the corresponding cage ( 13) LF. in the frequency range from 20 Hz to 2 kHz, pulsed - with a signal duration of several milliseconds, signals at a frequency f ₁ , perceived by ear as a "crunch". At the same time, these signals were previously recorded at BP (14) and recorded on a measuring tape recorder.

BP (14) perceive acoustic impulse signals at frequency f ₁ as an active food intake by a competitor, rush to the center and to the upper part of the cage (13) - to the area of the signal source, to the area of supply (spreading) of the GC (16) and start, from for the increased competition, eat actively. In this case, BP rushes to the signal source (14), which were previously at different cage depths (13). Ultimately BP (14) gains mass faster (more actively).

However, a situation may arise that after active feeding, BP (14) begin to move unevenly (by throws, etc.) along the cage (13), their digestive tract begins to function poorly (they can spit out food, as well as get rid of the food that has not yet been digested ahead of time). feed, etc.).

To minimize, or even to completely eliminate, the negative impact of the above factors on BP (14) using a series of functionally connected: the third multichannel generator (44), the third multichannel power amplifier (45), several - according to the number of cages (13), fourth signal cables (46), several - according to the number of cages (13), fourth hydroacoustic emitters (47) of the AB channel (30) (7) carry out the formation, amplification and radiation - immediately after the cessation of the supply of HA (16) to the corresponding cage (13), LF - in the frequency range from 20 Hz to 2 kHz, modulated in frequency and amplitude, quasi-pulse signals - with a signal duration from fractions of milliseconds to a few seconds, at a frequency f ₂ , perceived by ear as "gurgling". At the same time, these signals were previously recorded at BP (14) and recorded on a measuring tape recorder.

BP (14) perceive acoustic quasi-impulse signals at frequency f ₂ as calm movement with rhythmic digestion of food by a relative, calm down and reach the maximum radius of movement along the cage (13). As a result, BP (14) gains mass faster.

Unfortunately, there is always a situation (especially in warmer seas and water bodies) when PR (8), periodically entering (due to smaller geometrical dimensions than that of VP) into the cage (13), bring RP (15) with them. In its active state, RPs (15) easily attach to the body of BP (14), irritate BP (BP starts to eat poorly), and ultimately gain less weight.

To minimize, or even to completely eliminate, the negative influence of the above factor on BP (14) using a series of functionally connected: the first multichannel generator (36), the first multichannel power amplifier (37), several - according to the number of cages (13), the second signal cables (38), several - according to the number of cages (13), the second hydroacoustic emitters (39) of the AB channel (28) (7) carry out the formation, amplification and continuous radiation - immediately after planting BP fry (14) in the corresponding cage (13) SC (12), high-gradient SPL signals at frequency f _SPL .

Due to high gradient signals SPL at the frequency f _SPL performed: physical destruction part RP (15) - located in the near field corresponding sonar transducer (39) - in the mode of the controlled acoustic cavitation, immobilization and shaking off with BP bodies (14) of the second part RP ( 15) - located in the far field of the corresponding hydroacoustic emitter (39) - in the mode of alternating acoustic pressure. As a result, BP (14) does not get irritated, eats well, and actively gains mass.

Wherein:

1. Effective (high-quality and long-term) acoustic control of the behavior of fish during their rearing in the UK is provided due to the fact that:

- from the moment of landing of juvenile BP in the SC, they continuously emit broadband signals of the "white noise" type at frequency F _BSh , which, in terms of the frequency range and signal level, completely overlap (mask) similar parameters of annoying, frightening, etc., BP sources (signals): noise of the sea (water) at frequency _FWB ; ship noise at frequency F _SN ; ship signals at frequency F _SS ; the noise at the frequency F _OL, biological signals at frequency F _MM noise distal navigation on frequency F _FAS and low noise dispatch at frequency F _SDC. As a result, BPs are less irritated and gain weight more actively;

- from the moment of landing of juvenile BP in the SC, they continuously emit high-gradient SPL signals at frequency f _SPL , which immobilize (in the far field of the corresponding hydroacoustic emitter) or physically destroy (in the near field of the corresponding hydroacoustic emitter) fish parasites (which irritate BP, etc.) etc.). As a result, BPs are less irritated and gain weight more actively;

- during feeding period BPs emit LF (in the range of maximum acoustic sensitivity BP), impulse (with a duration of several - at least two, milliseconds) signals at frequency f ₁ , which are perceived by ear as a “crunch”. As a result, BPs eat better and gain mass more actively;

- after feeding, BPs emit LF (in the range of maximum acoustic sensitivity of BP), quasi-impulse (lasting from several milliseconds to several seconds) signals at frequency f ₁ , which are perceived by ear as “gurgling”. As a result, BPs move smoothly, process food well, and gain mass more actively;

- the process of formation, amplification and emission of all hydroacoustic signals is controlled by the BKR operator, etc.

2. Diversified (luring, activation during feeding, calming down after feeding, etc.) acoustic control of the behavior of fish during their rearing in the UK is provided due to the fact that:

- from the moment of landing of juvenile BP in the SC, they continuously emit broadband signals of the “white noise” type at frequency f _BS , which, in terms of the frequency range and signal level, completely overlap (mask) similar parameters of annoying, frightening, etc., BP sources (signals): noise of the sea (water) at frequency _FWB ; ship noise at frequency F _SN ; ship signals at frequency F _SS ; the noise at the frequency F _OL, biological signals at frequency F _MM noise distal navigation on frequency F _FAS and low noise dispatch at frequency F _SDC. As a result, BPs are less irritated and gain weight more actively;

- from the moment of landing of juvenile BP in the SC, they continuously emit high-gradient SPL signals at frequency f _SPL , which immobilize (in the far field of the corresponding hydroacoustic emitter) or physically destroy (in the near field of the corresponding hydroacoustic emitter) fish parasites (which irritate BP, etc.) etc.). As a result, BPs are less irritated and gain weight more actively;

- during feeding period BPs emit LF (in the range of maximum acoustic sensitivity BP), impulse (with a duration of several - at least two, milliseconds) signals at frequency f ₁ , which are perceived by ear as a “crunch”. As a result, BPs eat better and gain mass more actively;

- after feeding, BPs emit LF (in the range of maximum acoustic sensitivity of BP), quasi-impulse (lasting from several milliseconds to several seconds) signals at frequency f ₁ , which are perceived by ear as “gurgling”. As a result, BPs move smoothly, process food well, and gain mass more actively;

- the process of formation, amplification and emission of all hydroacoustic signals is controlled by the BKR operator, etc.

3. Acoustic control of the behavior of fish during their rearing in cage complexes under different conditions (for example, in different seasons of the year, with different sea waves, at different water temperatures, etc.) is provided due to the fact that:

- from the moment of landing of juvenile BP in the SC, they continuously emit broadband signals of the “white noise” type at frequency f _BS , which, in terms of the frequency range and signal level, completely overlap (mask) similar parameters of annoying, frightening, etc., BP sources (signals): noise of the sea (water) at frequency _FWB ; ship noise at frequency F _SN ; ship signals at frequency F _SS ; the noise at the frequency F _OL, biological signals at frequency F _MM noise distal navigation on frequency F _FAS and low noise dispatch at frequency F _SDC. As a result, BPs are less irritated and gain weight more actively;

- from the moment of landing of juvenile BP in the SC, they continuously emit high-gradient SPL signals at frequency f _SPL , which immobilize (in the far field of the corresponding hydroacoustic emitter) or physically destroy (in the near field of the corresponding hydroacoustic emitter) fish parasites (which irritate BP, etc.) etc.). As a result, BPs are less irritated and gain weight more actively;

- during the feeding period, BPs emit FT4 (in the range of maximum acoustic sensitivity BP), impulse (with a duration of several - at least two, milliseconds) signals at frequency f ₁ , which are perceived by ear as a “crunch”. As a result, BPs eat better and gain mass more actively;

- after feeding, BPs emit LF (in the range of maximum acoustic sensitivity of BP), quasi-impulse (lasting from several milliseconds to several seconds) signals at frequency f ₁ , which are perceived by ear as “gurgling”. As a result, BPs move smoothly, process food well, and gain mass more actively;

- the process of formation, amplification and emission of all hydroacoustic signals is controlled by the BKR operator, etc.

4. Medical safety for a person (serving the UK) is ensured due to the fact that:

- for the formation, amplification and emission of ICs, ES, VGS and BRS use commercially available, certified, musical equipment;

- for the radiation of hydroacoustic ICs and ESs, underwater hydroacoustic emitters are used;

- the process of formation, amplification and emission of all hydroacoustic signals is controlled by the BKR operator, etc.

5. Environmental safety for fish (grown in the UK and natural fish outside the UK) is ensured due to the fact that:

- natural fish always have the opportunity to leave the area in which IP and ES are distributed;

- for the formation, amplification and emission of ICs and ESs, mass-produced, certified, musical equipment is used;

- the process of formation, amplification and emission of all hydroacoustic signals is controlled by the BKR operator, etc.

6. Environmental safety for MM (traditional inhabitants of seas and rivers and natural predators of fish) is ensured due to the fact that:

- MM always has the opportunity to leave the area in which IP and ES are distributed;

- for the formation, amplification and emission of ICs and ESs, mass-produced, certified, musical equipment is used;

- the process of formation, amplification and emission of all hydroacoustic signals is controlled by the BKR operator, etc.

7. Ecological safety for the environment, in general, is ensured due to the fact that:

- for the formation, amplification and emission of ICs and ESs, mass-produced, certified, musical equipment is used;

- the process of formation, amplification and emission of all hydroacoustic signals is controlled by the BKR operator, etc.

Distinctive features of the proposed method are:

1. BP is used as fish.

2. The following types of signals are used as ES: white noise (broadband signal in the sound and ultrasonic frequency ranges).

3. As an IC, broadband signals of the following conventional types are used: pulse signals with a duration of several miles of seconds, formed by BP in the course of its feeding and perceived by ear as a “crunch”, quasi-pulse amplitude-frequency-modulated signals with a duration from a few milliseconds to a few seconds, formed by BP in the course of its smooth movement after a meal and perceived as a “gurgle” by the ear.

4. ES radiation is carried out continuously: from the moment of placement of BP fry in the UK and until the withdrawal of marketable (farmed) fish from the UK.

5. IS radiation is carried out according to the program set by the BKR operator: pulse signals are emitted during BP feeding, quasi-pulse signals are emitted after BP feeding.

6. ES radiation is additionally carried out in the opposite direction from BP.

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

Analysis of the known technical solutions with the aim of detecting these distinctive features in them, showed the following.

Features: 3, 4, and 5 are new, and their use for acoustic control of the behavior of fish during their rearing in the UK is unknown.

Features: 2 and 6 are new and their use for acoustic control of fish behavior during their rearing in the UK is unknown. At the same time, it is known: for feature 2 - the use of noises and signals from civilian ships to mask the noise of naval submarines; for feature 6, the use of noises and signals to scare off MMs from fixed seines with fish.

Feature 1 is well known.

Thus, the presence of new essential features, in combination with the known ones, ensures that the proposed solution has a new property that does not coincide with the properties of known technical solutions - efficiently (qualitatively and for a long time), versatile (luring, activation during feeding, calming down after feeding etc.) acoustically control the BP behavior against the background of negative influences: man-made noises (noises and the signal of a feeding barge), noises of long-distance and short-range navigation, biological signals of MM (natural predators of BP located in the UK), etc., under different conditions (for example, in different seasons of the year, with different sea waves, at different water temperatures, etc.), against the background of negative (irritating, etc.) effects of fish parasites (fish lice), with ensuring medical safety for a person (serving the UK), ensuring environmental safety: for BP and natural fish, for MM (traditional inhabitants of seas and rivers and nature predators of fish) and for the OPS, in general.

In this case, we have a new set of features and their new relationship, and not a simple combination of new features and already known ones, namely, performing operations in the proposed sequence and leading to a qualitatively new effect. This circumstance allows us to conclude that the developed method meets the criterion of "significant differences".

An example of the implementation of the method.

Industrial tests of the developed method were carried out: at a special geophysical test site in b. Vityaz of Peter the Great Bay, Sea of Japan - from 1994 to 1998, Primorsky Territory; at a special fishing ground in b. Northern Gulf of Peter the Great, Sea of Japan - from 1999 to 2001, Primorsky Territory; on fixed seines r / k them. Bekerev - in the period from 2002 to 2008, Kamchatka; at the IC of Sam Won - in the period from 2004 to 2008, Republic of Korea; at the SK of the company - in the Socialist Republic of Vietnam (2008-2010).

For example, in FIG. 4 illustrates: typical audiograms (distribution of the signal level by frequency) of the acoustic sensitivity of some salmon species of the Far East of the Russian Federation: chum salmon (curve 1) and pink salmon (curve), recorded in fixed seines of the R. Bekerev - in the period from 2002 to 2008; typical audiograms: long-distance navigation noises (curve 3), short-range navigation noises (curve 4), noises and signals from the BKR (curve 5), biological signals of MM (curve 6), sea noises during sea waves 1 point (curve 7) and sea noises with roughness of the sea 4 points (dashed curve 8).

As seen in FIG. 1: maximum acoustic sensitivity of chum salmon - at a frequency of 450 Hz, and pink salmon (with smaller geometric dimensions than chum salmon) - 750 Hz; the main energy of the noises of long-distance and short-range navigation, as well as noise and signals from the BKR, is concentrated in the low-frequency (from 20 Hz to 2 kHz) frequency range, i.e. in the range of acoustic sensitivity BP; The greatest energy of the signals emitted by the MM during their movement in space and in the process of their search for food (the navigation channel and the search channel of the conventional MM biological sonar, respectively) is concentrated in the ultrasonic frequency range, i.e. out of range of acoustic sensitivity BP; at sea noise level 1, BP perceives acoustic signals from all of the above sources; at sea noise level of 4 points, BP practically does not perceive acoustic signals from all of the above sources, because they are "masked" by the noise of the sea at its 4-point roughness.

For example, in FIG. 5 illustrates typical audiograms of signals in the SC (with BP) in the process of implementing the developed method of acoustic control of the behavior of fish during their rearing in the SC. In this case, the numbers: 1, 2, 3 and 4, denote (to understand the idea of implementing the developed method), respectively, signals at frequencies f _BSh , f _SPL , f ₁ and f ₂ . FIG. 5 also illustrates audiograms of sea noise during waves: 1 point (solid line, indicated by the number 5) and 4 points (dashed line, indicated by the number 6).

As seen in FIG. 5, the implementation of the developed method is provided when the sea state is 4 points or more. In this case, the maximum signal level is provided at a frequency f _SPL - to implement the mode of controlled acoustic cavitation.

One of the postulates of the developed method is reduced to fish farming (from the “fry” stage to the “marketable fish” stage) with constant sea noise of 4 points. In this case, all man-made noises will be masked by the noise of the sea, and will never annoy or frighten BP. We can say that the UK is supposedly in the open sea, in which the sea waves are constantly 4 points. We can also say that in the process of implementing the developed method, BP will be more "hard of hearing" than PR.

FIG. 6 illustrates the average weight (kg) of BP in SC cages. In this case: the index I denotes histograms illustrating the BP mass in the cages closest to the BKR (solid line - when implementing the developed method, dashed line - when implementing the prototype method); the subscript II denotes histograms illustrating the BP mass in the cages far from the BKR (solid line - when the developed method is implemented, the dotted line - when the prototype method is implemented).

As seen in FIG. 6: the average BP mass for 2 years in the cages closest to the BKR with partial (only when the signals are emitted from the BKR at a frequency f _BSh ) implementation of the developed method, in comparison with the prototype method, was increased by 0.94 kg (from 4.03 kg to 4.97 kg), or by 23.3%; the average weight of BP for 2 years in cages far from BKR during the implementation of the developed method, in comparison with the prototype method, was increased by 0.32 kg (from 4.88 kg to 5.20 kg), or by 6.5%. In other words, the negative influence of noise and RBR signals on the BP, as well as the positive influence of the signals emitted from the RBR at the frequency f _{BS is} obvious.

It should also be noted that in the process of implementing the developed method, the average mass (4.97 kg) of BP in the cages closest to the BKR was greater than the average mass (4.88 kg) of BP in the cages far from the BKR during the implementation of the prototype method.

FIG. 7 illustrates the average weight (kg) of BP in SC cages. In this case: the index I denotes histograms illustrating the BP mass in the cages closest to the BKR (solid line - when implementing the developed method, dashed line - when implementing the prototype method); the subscript II denotes histograms illustrating the BP mass in the cages far from the BKR (solid line - when the developed method is implemented, the dotted line - when the prototype method is implemented).

As seen in FIG. 7: the average BP mass for 2 years in cages closest to the BKR with the full implementation of the developed method, in comparison with the prototype method, was increased by 1.45 kg (from 4.03 kg to 5.78 kg), or by 35, 5%; the average weight of BP for 2 years in cages far from the BKR during the implementation of the developed method, in comparison with the prototype method, was increased by 1.1 kg (from 4.88 kg to 5.98 kg), or by 22.5%.

Thus:

1. Effective (high-quality and long-term) acoustic control of the behavior of fish during their rearing in the UK was provided due to the fact that:

- from the moment of landing of juvenile BP in the SC, they continuously emitted broadband signals of the "white noise" type at frequency f _BS, which, in terms of the frequency range and signal level, completely overlapped (masked) similar parameters of annoying, frightening, etc., BP sources (signals) : noise of the sea (water) at a frequency _FWB ; ship noise at frequency F _SN ; ship signals at frequency F _SS ; the noise at the frequency F _OL, biological signals at frequency F _MM noise distal navigation on frequency F _FAS and low noise dispatch at frequency F _SDC. As a result, BPs were less annoyed and more actively gaining mass;

- from the moment of landing of juvenile BP in the SC, they continuously emitted high-gradient SPL signals at frequency f _SPL , which immobilized (in the far field of the corresponding hydroacoustic emitter) or physically destroyed (in the near field of the corresponding hydroacoustic emitter) fish parasites (which irritate BP, etc.) etc.). As a result, BPs were less annoyed and more actively gaining mass;

- during the feeding period, BP emitted LF (in the range of maximum acoustic sensitivity BP), impulse (with a duration of several - at least two, milliseconds) signals at frequency f ₁ , which were perceived by ear as a “crunch”. As a result, the BPs were eating better and gaining mass more actively;

- after feeding, BP emitted LF (in the range of maximum acoustic sensitivity of BP), quasi-impulse (lasting from several milliseconds to several seconds) signals at frequency f ₁ , which were perceived by ear as “gurgling”. As a result, BP moved smoothly, processed food well, and gained their mass more actively;

- the process of formation, amplification and emission of all hydroacoustic signals was controlled by the BKR operator, etc.

2. Diversified (luring, activation during feeding, calming down after feeding, etc.) acoustic control of fish behavior during their rearing in the UK was provided due to the fact that:

- from the moment of landing of juvenile BP in the SC, they continuously emitted broadband signals of the “white noise” type at frequency f _BS , which, in terms of the frequency range and signal level, completely overlapped (masked) similar parameters of annoying, frightening, etc., BP sources (signals ): noise of the sea (water) at the frequency F _SHB ; ship noise at frequency F _SN ; ship signals at frequency F _SS ; the noise at the frequency F _OL, biological signals at frequency F _MM noise distal navigation on frequency F _FAS and low noise dispatch at frequency F _SDC. As a result, BPs were less annoyed and more actively gaining mass;

- from the moment of landing of juvenile BP in the SC, they continuously emitted high-gradient SPL signals at frequency f _SPL , which immobilized (in the far field of the corresponding hydroacoustic emitter) or physically destroyed (in the near field of the corresponding hydroacoustic emitter) fish parasites (which irritate BP, etc.) etc.). As a result, BPs were less annoyed and more actively gaining mass;

- during the feeding period, BP emitted LF (in the range of maximum acoustic sensitivity BP), impulse (with a duration of several - at least two, milliseconds) signals at frequency f ₁ , which were perceived by ear as a “crunch”. As a result, the BPs were eating better and gaining mass more actively;

- after feeding, BP emitted LF (in the range of maximum acoustic sensitivity of BP), quasi-impulse (lasting from several milliseconds to several seconds) signals at frequency f ₁ , which were perceived by ear as “gurgling”. As a result, BP moved smoothly, processed food well, and gained their mass more actively;

- the process of formation, amplification and emission of all hydroacoustic signals was controlled by the BKR operator, etc.

3. Acoustic control of the behavior of fish during their rearing in cage complexes in different conditions (for example, in different seasons of the year, with different sea waves, at different water temperatures, etc.) was provided due to the fact that:

- from the moment of landing of juvenile BP in the SC, they continuously emitted broadband signals of the “white noise” type at frequency f _BS , which, in terms of the frequency range and signal level, completely overlapped (masked) similar parameters of annoying, frightening, etc., BP sources (signals ): noise of the sea (water) at the frequency _FWB ; ship noise at frequency F _SN ; ship signals at frequency F _SS ; the noise at the frequency F _OL, biological signals at frequency F _MM noise distal navigation on frequency F _FAS and low noise dispatch at frequency F _SDC. As a result, BPs were less annoyed and more actively gaining mass;

- from the moment of landing of juvenile BP in the SC, they continuously emitted high-gradient SPL signals at frequency f _SPL , which immobilized (in the far field of the corresponding hydroacoustic emitter) or physically destroyed (in the near field of the corresponding hydroacoustic emitter) fish parasites (which irritate BP, etc.) etc.). As a result, BPs were less annoyed and more actively gaining mass;

- during the feeding period BP emitted LF (in the range of maximum acoustic sensitivity BP), impulse (with a duration of several - at least two, milliseconds) signals at frequency f ₁ , which were perceived by ear as a “crunch”. As a result, the BPs were eating better and gaining mass more actively;

- after feeding, BP emitted LF (in the range of maximum acoustic sensitivity BP), quasi-impulse (lasting from several milliseconds to several seconds) signals at frequency f ₁ , which were perceived by ear as “gurgling”. As a result, BP moved smoothly, processed food well, and gained their mass more actively;

- the process of formation, amplification and emission of all hydroacoustic signals was controlled by the BKR operator, etc.

4. Medical safety for a person (serving the UK) was ensured due to the fact that:

- for the formation, amplification and emission of ICs, ES, VGS and BRS used commercially available, certified, musical equipment;

- for the radiation of hydroacoustic ICs and ESs, underwater hydroacoustic emitters were used;

- the process of formation, amplification and emission of all hydroacoustic signals was controlled by the BKR operator, etc.

5. Environmental safety for fish (grown in the UK and natural fish outside the UK) was ensured due to the fact that:

- natural fish have always had the opportunity to leave the area in which IP and ES were spread;

- for the formation, amplification and emission of ICs and ESs, we used mass-produced, certified, musical equipment;

- the process of formation, amplification and emission of all hydroacoustic signals was controlled by the BKR operator, etc.

6. Environmental safety for MM (traditional inhabitants of seas and rivers and natural predators of fish) was ensured due to the fact that:

- MM always had the opportunity to leave the area in which IP and ES are distributed;

- for the formation, amplification and emission of ICs and ESs, we used mass-produced, certified, musical equipment;

- the process of formation, amplification and emission of all hydroacoustic signals was controlled by the BKR operator, etc.

7. Ecological safety for the environment, in general, was ensured due to the fact that:

- for the formation, amplification and emission of ICs and ESs, we used mass-produced, certified, musical equipment;

- the process of formation, amplification and emission of all hydroacoustic signals was controlled by the BKR operator, etc.

Claims (1)

A method of growing fish in cage complexes, characterized by the formation, amplification and emission of acoustic signals under the water towards the accumulation of fish: during feeding, the fish that are being raised emit previously recorded signals generated by the raised fish during their feeding; after feeding, they emit previously recorded signals formed by the farmed fish in the process of their smooth movement after eating; broadband signals of the "white noise" type and high-gradient signals in the ultrasonic frequency range are emitted towards the congregation of fish continuously, and additionally, in the direction opposite to the farmed fish.

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