DE1295691B - Device for electric fishing - Google Patents

Description

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The invention relates to a device for electrical dimensions that each through the capacitor centric Fishing with a circuit arrangement charge resulting oscillation the time from Entzum Generation of direct current pulses that go through the start of charging until the first voltage zero crossing Electrodes are fed to the water and due to damping is much greater than the time Fishing induce electrotaxis and electronic anesthesia. 5 from voltage zero to first current devices of a similar type are already known. zero crossing. With this known device is Through this direct current impulses are connected with peak the disadvantage that no pure direct currents of about 20 kA with a pulse length of voltage pulses, but alternating voltage pulses generated about 1 msec. The arithmetic mean of the generated, which greatly reduces the catch DC current is then still some 100 A. The io is reduced. Then there are the others The use of such direct current pulses has the disadvantages of such known inputs as outlined above Cons: directions.

The high mean value of the direct current has the effect that, in contrast to this, however, the one out the anodes dissolve quickly and the cable example of the device according to the invention, methods with a badly conductive salt crust, which this circuit uses, parallel to load pulling. You can therefore only work with it for a short time. and then have to replace the anodes with new ones and use a power source and an ohmic resistor Clean cathodes. standing series connection, whereby all switching

The transmission of the direct current pulses to large processing elements are dimensioned so that in the load resistance distance causes difficulties, because the creation of the direction opposite to the catch pulse current distance from the ship to the trawl is often more constant direct current is generated, than 1 kilometer. DC pulse transformers It is advantageous to use the ohmic resistance

in order to reduce the line losses are to be measured in such a way that the arithmetic mean value of the beat. As a result of the considerable Vormagne- current is zero. This results in the best tization, but these transformers must have very _a5 electrolytic behavior.

be large. This prevents the entrainment. If you change the number of pulses in this circuit

Ships because of their size as well as because of or the pulse height, the zero compensation must be used of weight. of the direct current through a corresponding other

The invention overcomes these disadvantages by restoring the ohmic resistance a device for electric fishing can be guided.

will create, in the invention, the circuit It is also within the scope of the invention, as

arrangement is designed so that the water path is a direction opposite to the capture pulse stream between the electrodes also to use a pulse current from one of the currents. Fish not influencing electric current in to Also in this case can basically already be the capture pulses in the opposite direction can be used by known device, but with will flow, the strength of which is such that the difference, that now the load resistance is so arithmetic mean value of the catch pulse current and between the capacitor and the controlled interrupter that of the flowing in the opposite direction is arranged that the EntStroms forming the capture pulse are approximately the same size. charging current surge of the capacitor the load resistance

The electrolytic decomposition of the electrodes is ₄₀ in one direction and the subsequent charging is then very low. Electrodes made of bil- current impulse resistance in the other direction can also be used. The electrode flows through.

metal, which dissolved during the positive impulse. This has the advantage that

is, no further switching elements compared to the known are precipitated again during the negative current. 45 th arrangement are required, but only their

Prevents the other arrangement in the circuit that has gone into solution. The other VorMetall by the movement of the electrodes through the part is that now when changing the pulse water is flushed away, for example, by the fact that the number or the pulse height of the capture pulse current that you touch the electrodes with a substance such. B. from an arithmetic mean value of the current across the load plastic, so the electrolysis is automatically always zero on a 50, so that a negligibly small value is reduced. It is advisable to set the zero compensation when changing, to arrange the circuit elements in such a way that the number of pulses and the pulse height is not required. Nevertheless, the entire current has the same catch current opposite current by about 30% fishing advantages, as the known pure one is lower than that of the impulse current. ₅₅ Flying pulse direct current.

It is also possible according to the invention, a further embodiment of the invention to use constant direct current, which is the catch- is further below with reference to the F i g. 7 explains impulse current is directed in the opposite direction. The transmission lines are advantageous

In this case, a circuit arrangement known per se, concentric lines, which in the tow ropes used in which a direct current generator is embedded over 60 of the network. The concentric line a choke and a half-wave rectifier has the advantage that the pulse shape of the transmitted Charges storage capacitor, which is changed very little or not at all by a controlled current. Man erte interrupter over the transmission lines, can also be towed with a single conductor Electrodes and water path formed load counteract when the steel casing of the stand is discharged in a pulsed manner. 65 tow rope or the surrounding sea water as

In a known arrangement of this type (German concentric return line is used see patent specification 835 084) are the inductance of the but make sure that the on the winch on the circuit and the capacitance of the capacitor so wound part of the cable a concentric back

3 4

has line. This can be formed by a constant flow between the capture pulses

the fact that on the drum of the winch a layer of direct current.

non-ferromagnetic conductive metal. The circuit arrangement according to FIG. 5 shows that

is brought, which is connected to the sea water in the load resistor 5 with the capacitor 6 in series commitment. 5 is connected, while both switching elements are in parallel

In the following, the invention will be arranged with reference to the controlled interrupter 4. here

Management examples with the help of schematic are thus in contrast to the circuit arrangement

Current diagrams and circuit arrangements according to FIG. 3 compared to the known circuit

purifies. It shows the arrangement no further circuit elements are

F i g. 1 requires a known circuit arrangement for io, but only a different arrangement

Generation of a direct current pulse current, voltage of the load resistor 5 taken.

F i g. 2 the pulse shape of the with the arrangement In this case, that occurs through the choke coil 2

according to FIG. 1 generated current, forced slow charging of the capacitor 6

F i g. 3 a circuit arrangement according to the Er- over the load resistor 5. When the current passes

finding, with a constant direct current in ent- i ₅ through the interrupter 4 then results in a current that

opposite direction to the catch pulse generated via the load resistor 5 in the opposite direction

becomes, tung flows. In this arrangement, the arithmetic

F i g. 4 the time course of the mean value of the total current across the load through the switching table

arrangement according to FIG. 3 generated electricity, automatically always equal to zero, so that when there is a change

F i g. 5 a further circuit _{arrangement according to the a} o the number and strength of the capture pulses according to the invention, the direct current pulses in the opposite position of a zero compensation, as in the case of the direction generated, circuit arrangement according to FIG. 3, not applicable.

F i g. 6 shows the time course of the circuit with the circuit arrangement according to FIG. 5 will

arrangement according to FIG. 5 generated current, a current generated as shown in FIG. 6 is shown.

F i g. 7 shows another embodiment of a circuit arrangement according to FIG. 7 consists of

processing arrangement for generating one from the same next again from the direct current generator 1, the

Current pulses of opposite direction together- choke coil 2 and the half-wave rectifier 3, the

set current, together with the primary winding of the transformer

F i g. 8 shows the temporal course of the through the formulator 10, the storage capacitor 11 and the

arrangement according to FIG. 7 generated electricity. 30 primary winding of another transformer 12

The structure and mode of operation of the device form a current loop.

according to the invention and the importance of this circuit has two parallel branches,

Reference symbols in FIGS. 1, 3 and 5 are as follows. one of which consists of two

In Fig. 1 is with 1 a DC generator with controlled switching tubes 13 and 14 and the draws, 2 is a choke coil and 3 is a one-way 35 others made up of two pulse rectifiers connected in series, while with 4 there is a controlled switching capacitors 15 and 16. The is on display tube, for example an ignition pin-controlled switching branch formed by the controlled switching tubes tube, is designated. 5 is the load resistance that is on the one hand between the half-wave rectifier 3 and essentially from the between the immersed in the water transformer 10 and on the other hand between the there is a water gap between the electrodes. 40 DC generator 1 and the transformer 12. With a storage capacitor 6 is designated. The branch of the line, which consists of the impulse

This known arrangement has the following effectors 15 and 16 is formed on the one hand between

way. the transformer 10 and the storage capacitor

The direct current source 1 charges via the throttle H, and on the other hand between the storage capacitors

coil 2 and the half-wave rectifier 3 of the condensate 45 ^sator U ^{and the} transformer 12th

sator6 slowly on. The latter is controlled by the two branches of the line are between their two

controlled switching tube 4 in predetermined time intervals similar circuit elements through the line

the discharged through the load resistor 5. The Ent- 17 connected.

charging takes place in a very short time and charging with the transformers 10 and 12 are Oberin a comparatively long time. By the load resistance 50 transmission lines 18 and 19 in connection, which Stand 5, a current flows according to FIG. 2. The lead there to further transformers 20 and 21, Provided impulses, as in Fig. 4, secondary windings each with the electrodes 6 and 8, the positive capture pulses. Pair 22 and 23 are connected. Between

In the circuit arrangement according to FIG. 3, these electrodes, the water (not shown) is arranged parallel to the load resistor 5 in series connection 55.

a further choke coil 7, a direct current source 8 The mode of operation of this switching arrangement is as follows

and an ohmic resistor 9 is arranged. area. The DC generator 1 charges over the

So it is through the load resistance a con-choke coil 2 and the half-wave rectifier 3 the constant direct current in the opposite direction to storage capacitor 11 slowly. The Speicherden Catch impulses sent. Here, with the help of the 60 capacitor 11 is large compared with the impulse ohms Resistance 9 of the floating capacitors 15 and 16 through the load 5 ßende current can be appropriately adjusted so that the controlled switching tube 13 and with the tube blocked the resulting direct current component through the 14 discharges the pulse capacitor 15 through the Load 5 is approximately zero. The primary winding of the transformer 11 has the same time coil 7 has the task of preventing the DC 65 is the pulse capacitor 16 from the storage current pulses also through the direct current source 8, capacitor 11 to the full voltage of the generator can. tor 1 charged. This burst of charging also takes place via

The electricity generated in this way is shown in FIG. 4 shown. It is the primary winding of the transformer 10. The

total impulse over the transformer 10 continues that is, from the discharge current of the pulse capacitor and the charge current of the pulse capacitor 16 together. This total pulse is transmitted to the transformer 20 through the transmission line 18 and thus also on the pair of electrodes 22. As a result of the charging of the pulse capacitor 16 Although a small part of the charge of the storage capacitor 11 was consumed. This part will but then slowly replenished from generator 1. By the circuit arrangement according to F i g. 7, a flat surge is generated in the transformers 10 and 12.

If the interrupter 14 is ignited, the same process is repeated quite analogously with the pulse capacitor 16 (discharge) and the capacitor 15 (charge).

The pulse shape at the electrode pairs 22 'and is shown in FIG. 8 shown.

Claims (9)

Patent claims: 1. Device for electric fishing with a circuit arrangement for generating DC impulses that are fed to the water via electrodes and to the fish Induce electrotaxis and electronic anesthesia, characterized by such a configuration the circuit arrangement that the water path between the electrodes in addition from an electrical current which does not influence the fish in the opposite direction to the catch impulses Direction is traversed, the strength of which is such that the arithmetic Average value of the catch pulse current and that of the current flowing in the opposite direction are approximately the same size. 2. Apparatus according to claim 1, characterized in that the circuit elements are arranged and are dimensioned that the peak value of the current opposite to the capture pulse current is about 30% lower than that of the catch pulse current. 3. Device according to claims 1 and 2, characterized in that the capture pulse opposing current is a constant direct current. 4. Apparatus according to claim 3, wherein a DC generator via a choke coil and a downstream half-wave rectifier charges a storage capacitor to which the series connection from a controlled interrupter and the essentially forming the load resistance Water path is connected in parallel between the electrodes, characterized in that parallel to the load resistor (5) one of a choke coil (7), a direct current source (8) and an ohmic resistor (9) existing series circuit is placed, which the catch pulse current constant direct current in the opposite direction is generated in the load resistor (Figs. 3 and 4). 5. Apparatus according to claim 4, characterized in that the ohmic resistor (9) is dimensioned such that the arithmetic mean of the total current through the load resistance (5) is zero. 6. The device according to claim 1, characterized by such a design of the circuit arrangement, that the current opposite to the catch pulse current is also a pulse current. 7. Apparatus according to claim 6, consisting of a direct current generator, the via a choke coil and a half-wave rectifier charges a storage capacitor and a controlled one Interrupter, which this capacitor across from transformers, transmission lines, electrodes and discharges the load resistance formed in the waterway in a pulsed manner, characterized in that that the load resistance (5) between the capacitor (6) and the interrupter (4) in such a way is arranged that the discharge current of the capacitor (6) forming the catch pulse Resistance (5) in one direction and the charging current for the capacitor the resistor flows through in the other direction. 8. Apparatus according to claim 7, characterized in that the load resistor (5) with the capacitor (6) is in series and parallel to this series circuit is the controlled switching tube is arranged (Fig. 5 and 6). 9. The device according to claim 6, consisting of a direct current generator, the via a choke coil and a half-wave rectifier charges a storage capacitor, characterized in that that in each of the two lines leading to the storage capacitor (11) the primary winding of a pulse transformer (10 or 12), the secondary winding of which is connected to cables (18 or 19) connected to the primary winding of another pulse transformer (20 or 21) whose secondary winding is connected to a pair of electrodes immersed in the water (22 resp. 23) is connected, that the series circuit is also parallel to the large-capacity storage capacitor two capacitors (15,16) of smaller capacitance is connected in parallel and between the ends of the primary windings of the transformers (10, 12) facing the generator (1) the series connection of two alternately igniting controlled interrupters is, and that the Connection point of the two switching tubes (13, 14) with the connection point of the series-connected Capacitors (15,16) is connected in an electrically conductive manner. 1 sheet of drawings