DE1084378B - Electric fishing equipment for deep sea fishing - Google Patents

Description

GERMAN

The invention relates to an electric fishing device for deep sea fishing. There are such Facilities known that consist of a trawl narrowing towards the rear with a bag-shaped actual power supply and a grid-like widening front part with a A multitude of electrode wires fed with pulses via a cable from the towing vehicle.

The strength of the field formed at the electrodes is known to decrease with increasing distance from the Electrode surfaces quickly. A large distance between the electrodes therefore requires maintenance a field strength that has an effective effect on the fish requires a considerable amount of energy. Consequently the operating costs increase very sharply with the size of the networks. Among other things, this is a reason that such interception devices have so far not found any noteworthy distribution. Also require the previous interception devices of the type mentioned to maintain the effective field strength proportionately large-area electrode pairs, which naturally increases the drag resistance and thus the Energy consumption of the towing vehicle can be increased.

A fish trap similar to a fish trap has been proposed as a stationary system for freshwater fishing, the consists of two fence-like walls converging towards the bottom of the trap, which are made of vertical, Rod-shaped electrodes fed with alternating current pulses are formed. The impulses are like this supplied that a traveling field is created, which has an intensity above the stimulus threshold of the fish and extends periodically in the longitudinal direction of the trap from the wide opening to the narrow trap end moves where a field is maintained with such strength that the moving field goes there shooed fish is stunned.

Such stationary systems cannot be used for deep-sea fishing. Also with them is the energy consumption uneconomically high.

The present invention solves the problem relating to electric deep-sea fishing with an electric one Network that is characterized by low energy consumption and by means of electrical impulses, which are just sufficient to cause a shock effect on the fish, engage in the fishing leaves.

The invention relates to an electric fishing device for deep sea fishing, which consists of a trawling net narrowing towards the rear with a bag-shaped actual power supply unit and a front part widening like a grid in the towing direction with a plurality of electrode wires fed with pulses via a cable from the towing vehicle. In such a Netzanord-Electric fishing device
for deep sea fishing

Applicant:

Halldor Gudjohnsen,

Thybor0n (Denmark),

and Jakob Gudjohnsen,

Reykjavik (Iceland)

Representative: Di. R. Hempel, patent attorney,
Sctiussenried (Württ), Berengerstr. 12th

Claimed priority:
Denmark July 2, 1955

Halldor Gudjohnsen, Thyboren (Denmark),

and Jakob Gudjohnsen, Reykjavik (Iceland),

have been named as inventors

According to the invention, the individual electrode wires are arranged insulated from one another and two each spatially opposite electrode wires, forming an individual electrode system, in such a way to one Distribute electricity connected so that the generated impulses the individual electrode systems one after the other are fed.

In the interception device according to the invention, the respective field strength concentration around the electrodes around fully exploited. It is only operated with little energy on the extended front part of the power supply In places an electric field is created, which, however, runs around the front part of the network and is so practical forms a closed electric fence for the fish in the network entrance.

To achieve a favorable pulse distribution in the arrangement of electrode systems, according to In a particular embodiment of the invention, an alternating current generator is provided as a pulse generator its output terminals through slip rings with a power distributor similar to a commutator rotating brush set are connected, the lamellae through the multi-conductor cable each with a Electrode wire are connected.

The circulating one belonging to such a pulse generator The brush set can be driven by the generator via a gear drive.

009 548/341

The electrodes located on the trawl can be connected to the pulse generator in such a way that the Ends of the multi-conductor cables, which also serve as towing ropes, through the hollow shaft of a capstan drum to which the fins of the power distributor are connected.

The structure and the mode of operation of the system according to the invention are shown below with reference to the Drawing explained in more detail.

Fig. 1 shows a catching device in an oblique view,

Fig. 2 shows the relationship between the voltage applied to a fish and a conductor potential diagram showing the distance between the fish and the ladder,

Fig. 3 is a similar diagram, * 5

4 shows a circuit diagram for a pulse generator belonging to the interception device,

5 shows the structure of the pulse generator in a schematic representation and in side view,

6 shows an unfolding of the current distributor belonging to the pulse generator.

According to FIG. 1, the swimming trawl has net-forming electrode wires 2 in its front part on. An electric potential is applied to these so that an electric field is generated around them. whose strength is sufficient to scare away the fish approaching the electrode wires, so that the fish get into the rear power supply unit 4 when the trawl is pulled forward. The electrode wires 2 are attached with their front end parts to a rope 5 forming the opening of the trawl net and with their rear ends on another rope 6, on which the actual bag-shaped close-meshed network 4 connects. Ropes 3 hold the middle parts of the electrode wires 2 in place mutual distance.

The trawl is with the help of two ropes 11, which are attached to tow ropes 9 and to the upper part of the Schineppnetzes lead, and of two pull ropes 7, which over shovels 10 on the lower part attached to the trawl. The pull ropes 7 and 11 lead to the four the edges of the close-knit Network 4 forming ropes 12. The pull ropes 9 are designed as multi-conductor cables, their Branch off conductors one after the other from cables 14 lying parallel to one another to the electrode wires 2.

The pull ropes 9 are provided with two sets of reinforcement wires that serve to the ropes to protect against wear and tear and the train from the trawl through a clamping device 15 on the Transfer ropes 7 and 11. The ropes 13 for the rear part of the trawl are used to pull the filled net on board the fishing vessel.

The electricity for the pulse generator is supplied by the electrical system of the fishing vessel. as The pulse generator is a motor generator, i. H. a DC shunt motor, used with a single-phase synchronous generator is directly coupled.

As can be seen from the circuit diagram of FIG. 4, the current is supplied by a motor generator 20 via two slip ring brushes 22, slip rings 23 and "power distribution brushes 24" to a stationary one Power distributor 21 out, the slip rings 23 and the brushes 24 from one with the motor generator 20 directly coupled gear drives 25 are driven 6g.

According to FIG. 5, the power distributor 21 is arranged on the hollow shaft of a capstan drum 26. the Ends of the pull cables are led through the hollow shaft to the power distributor, where the cable ladders each are connected to a lamella, so that diametrically opposed power distribution brushes Connect diametrically opposite electrode wires in the trawl. The measuring and signal conductors of the Towing net are connected to instruments mounted on a power board 28 by means of a plug contact 27.

Fig. 6 shows the distribution of the electrical impulses in the electrode wires of the trawl. The current distribution brushes 24 are somewhat narrower or as wide as a lamella, so that only one pair of electrodes and, if necessary, an adjacent pair are supplied with current at the same time. To avoid loading difficulties, the position of the brushes 24 in relation to the pole wheel of the synchronous generator 20 is coordinated in such a way that the current passes through its zero value at the moment when the brush only touches one lamella, and the gear drive 25 is dimensioned so that a half-wave is that Includes the amount of time it takes for the brush to slide over a power distribution blade. Each conductor thus receives voltage for the duration of t seconds with a positive and a negative half-wave. The remaining conductors receive the same voltage pulses one after the other.

The time interval t _t between the voltage pulses in a specific electrode wire depends on the time it takes a brush to slide over half of the power distribution blades. The diagram of FIG. 2 shows the relationship between the voltage difference .E ₁₂ , which a fish is exposed to, and an electrode potential E ₀ , which is dependent on the distance X ₁ between the electrode and the tip of the fish, provided that the fish is approaches the electrode in a plane perpendicular to the electrode (Fig. 3). The diagram shows that a short fish is exposed to a lower value (E ₁₂ [E ₀ ) than a long fish at a certain distance X _1.

The diagram also shows that a short fish is _{exposed to a lower potential difference than a long fish at a certain value of the potential £ 0} and that a short fish is influenced by a given value of the potential difference E ₁₂ at a much shorter distance from the electrode than a long fish.

In order to effectively contain a fish by the electrode wires, it is necessary that the electrified Area has a certain minimum extent, so that the fish of a certain number of electrical impulses, the strength of which increases as the fish attaches itself to the electrode wires approaching. The electrical fencing formed by the electrode wires thus has one of the length of the Fish dependent selective effect on the fish. Since the related electric field consists of positive and If there is negative field impulses, the fish is not attracted by the electrode wires, but tries to to adjust to an equipotential surface parallel to this.

In a direct current field, the fish is parallel to the lines of force and moves through as it increases Field intensity gradual the three stages:

Muscle contractions,

Electrohypnosis, in which the fish swims in the direction of the increasing field strength, and Electronic anesthesia, which causes the fish to lie on its side and no longer be able to close swim.

In an alternating current field, on the other hand, the fish will search for an equipotential surface, i.e. H. one at right angles to the direction of the lines of force.

Tests have shown that this is necessary to achieve the effects of the third stage Potential difference for each fish species is constant and independent of the length of the fish and from 1 to 4 volts for the different fish species. The experiments have also shown that the induction the effects of the first or the second stage required potential difference only 6 or about 60% of the potential difference required to bring about the third stage. If, therefore, alternating current is used to generate a potential difference, which leads to it the action of the first stage is required, the fish will flee from the electrode and with to move away from it under one's own power.

As a result, the field strength is adjusted so that the fish is at the outer limit of the field to bring about the effect of the first stage is exposed to the potential difference necessary, so that the fish can swim away from the electrodes under its own power. In an electrode gap, which is greater than the distance of the outer field boundary from the electrode, the fish will be affected by the Field not affected and thus not caused to swim away and pass through the front opening of the Through the trawl.

If, where mentioned above, the low field strength is used, one has the advantage that the electrical Current in the electrodes has low strength, so that this is supplied from the fishing vessel without the need for sturdy conductors.

Because the electrode wires from the front opening of the electric trawl to the rear end of the trawl converge, the distance between the electrode wires becomes in the direction of accordingly enlarged on the front opening of the net. The potential at the front ends of the Electrode wires is larger than due to the inevitable voltage drop in the electrode wires the potential at their back end. With an expedient choice of the cross section of the electrode wires it is possible to measure the voltage drop so that along the entire length of the electrode wires the same potential difference is achieved at a certain distance from these. It is therefore possible A fish is determined by a circumferential electric field that sweeps across a truncated pyramid Length so that the fish can move in while the trawl is pulled out the close-meshed rear part of the same reaches, provided that it is not possible, from the front To escape opening of the trawl.

The trawl can be pulled by two fishing vessels instead of one. Farther two generators can supply the trawl network with electricity. It can also be in the front part of the Trawling a combination of electrical electrode wires and net mesh can be used. Finally, of course, floats and counterweights can be used where this is required.

Claims (3)

PATENT CLAIMS: 1. Electric fishing device for the deep-sea fishing, comprising a rearwardly narrowing trawl with a bag-like actual power supply and a grid-like widening in the towing direction the front part with a plurality of via a cable from the towing vehicle from fed with pulses of electrode wires, characterized in that the individual electrode wires are arranged insulated from each other and, two spatially opposite electrode wires, forming an individual electrode system, are connected to a power distributor in such a way that the generated pulses are fed to the individual electrode systems one after the other. 2. Device according to claim 1, characterized in that that the output terminals of an alternator serving as a pulse generator are connected via slip rings (22, 23) to a rotating brush set (24), which on a static, commutator-like power distributor (21) slides, with its lamellas Multi-conductor cables are each connected to an electrode wire of the network. 3. Plant according to claim 1 and 2, characterized in that the brush set (24) has a Gear transmission (25) is driven by the generator (20). Considered publications:
"Orion" magazine, Volume 8, No. 3/4, pp. 91 to 99; "ETZ" magazine, 1954, pp. 176 to 179. 1 sheet of drawings © 009 548/341 6.60