DE1114589B - Electric fence energizer for mains connection and pulse generation by means of capacitor discharge - Google Patents

Description

Electric fence energizer for mains connection and pulse generation by means of Capacitor discharge For fence energizers that are fed from the lighting network, a capacitor is usually charged via a rectifier, which periodically is discharged every second via a high-voltage transformer. the Capacitor discharge through the primary coil of the high voltage transformer transformed to a high voltage pulse. Around the capacitor discharge periodically to be carried out in a cycle of one second, is used as a switching means in known devices a relay with normally closed contact or a mercury interrupter connected by a the motor connected to the lighting network is switched every second.

The discharge current of the capacitor through the primary winding of the transformer takes place in the form of a strongly damped sinusoidal oscillation in the secondary winding generates a high voltage pulse of the same shape. The secondary winding is with one pole connected to the electric fence, the other pole connected to the earth. If a person touches the electric fence, an electric shock flows through his body, which also has the form of a strongly damped sinusoidal oscillation. The accident prevention regulations for Electric fencers assume that in the worst case the ohmic resistance of the When touched by people is 500 ohms. There is a danger to life if the electric fence is touched to exclude by a person or by an animal, write the accident prevention regulations do the following: 1. The peak value of the current intensity of the pulse must not be 300 mA exceed.

2. The amount of electricity per pulse may be 2.5 mA per second (coulomb) do not exceed.

3. The duration of the impulse must not exceed 0.1 seconds.

4. In addition, the time between two consecutive pulses is allowed Do not fall below 0.75 seconds.

An energizer must comply with these conditions when connected to the secondary winding a resistor of 500 ohms is connected to the transformer.

To be safe, it is desirable to keep the high voltage pulses so to generate that they reach all maximum values 1 to 3 as possible, of course without that they are exceeded. As the operating costs from the lighting network for the generation these high-voltage impulses are so small, there are also no economic ones Disadvantages in generating pulses with the maximum values mentioned. A capacitor discharge with the devices of the known type that generate a maximum peak current of 300 mA, now has the property that the amount of electricity of these pulses and the pulse duration are far below the permissible maximum values.

So is z. B. the pulse duration of the known pulses in the order of magnitude of a few milliseconds and is thus far below the permissible pulse duration of 0.1 second, as well as the amount of electricity well below 2.5 coulombs.

A greater pulse duration and a greater amount of electricity per pulse to achieve is with the known devices, the impulses with the discharge only one Generate a capacitor, only possible with pulses, the peak current of which is 300 mA and is not permitted according to the accident prevention regulations. This lies the fact that the one working with the discharge of only one capacitor and thereby a stronger one Call charge during discharge necessarily causes a larger peak current strength.

In contrast, these disadvantages are based on the invention from a power supply fence energizer, in which the to be transferred to a fence High voltage impulses by discharging a capacitor by means of a relay the primary winding of a high-voltage transformer are generated - thereby remedied, that according to the invention the discharge circuits of two to be discharged one after the other Pulse capacitors via one discharge relay each to the primary winding of the same High-voltage transformer are connected and that the actuating coils the both relays are in the charging circuit of a pulse capacitor, the relay this capacitor is designed with normally closed contacts, that of the other with normally open contacts is. In this way, two high-voltage pulses with z. B. a maximum Peak current of 300 mA and a pulse duration of a few milliseconds, the at a time interval of z. B. 50 milliseconds in succession.

The pulse duration is due to the rapid succession of the pulses every two or more pulses together are less than 0.1 second, so they together as just an impulse, e.g. B. double pulse, can be perceived only after a new multiple pulse follows about one second. The amount of electricity per multiple pulse then still remains below the allowable amount of z. B. 2.5 coulombs, but comes as aimed, closer to this crowd. The multiple impulses are therefore according to the accident prevention regulations permissible. These multiple impulses double the electrical effect of the impulses, and the herding effect should be not only corresponding, but also physiological amplify more, because immediately on the stimulus effect of the first impulse a second impulse with the same stimulus effect follows.

The fact that, according to the invention, the actuators of the relay for the discharge of the capacitor or capacitors following the first are switched into the charging circuit of the previously discharged capacitor, it is achieved that inevitably the pulses briefly follow one another and the Pulse duration of the pulses together never the permissible size of z. B. 0.1 second falls below.

Arrangements are known in which from a lighting network via a Rectifier two or more capacitors are charged via a breaker contact are discharged via two or more high-voltage transformers, their secondary windings are connected to two or more electric fences.

This known power supply is in at least two separate Electric fences, at the same time, generating high voltage surges with the advantage of that if one fence is earthed, the other fence will still perform well.

The invention differs from this, inter alia, in that in one and the same electric fence not at the same time, but at least at a short distance two high-voltage impulses are generated, which have the protective effect in one electric fence without violating the accident prevention regulations.

In a practice of the invention, the capacitors are via their associated relay switches, each with a primary winding of the high-voltage transformer connected, while the magnet windings of the relays in the charging circuit of each previously discharged capacitor are connected, what for the fast pulse train is advantageous.

The switching relay is useful for discharging the first capacitor designed as a rest switch, whose magnet winding in the charging circuit of the first Capacitor is switched on while the entire ohmic resistance in the charging circuit of the first capacitor with the capacitance of this capacitor is the cycle time of the high-voltage pulses, preferably about 1 second. The relay switches for the discharge of the following Capacitor or the following capacitors can expediently with normally open contacts be provided.

In a preferred embodiment of the invention with two to be unloaded Capacitors produce the ohmic resistances of the two primary windings of the transformer with the capacitance values of the two capacitors a total discharge time for both Capacitors less than 0.1 second.

For faster and safer operation of the relay contacts without Contact migration and without wear and tear should be the anchors of the work and rest relays be suspended directly from the associated contact spring.

Both relay coils and the transformer coils can be on a common Iron core be mounted, while this iron core is the spring set with normally closed contact and carries the spring with normally open contact.

The primary winding of the high voltage transformer to which the first Capacitor is connected via the normally closed relay, appropriately has a smaller number of turns than the primary winding of the high-voltage transformer, to which the second capacitor is connected via the normally open contact relay.

The drawing shows the circuit diagram and the arrangement schematically of the two relays and the transformer in two different embodiments the invention shown by way of example.

Fig. 1 shows an embodiment of the invention in which the transformer and the two relays are united on an iron core; Fig. 2 shows an embodiment of the invention in which the relay and transformer each have their own iron cores own.

In both embodiments of the invention, the capacitor 5 is charged via the rectifier 1, the relay windings 2 and 3 and via a resistor 4. In parallel with this, the capacitor 7 is charged via a resistor 6. A capacitor B is used to smooth the direct current.

According to FIG. 1, the relay windings 2 and 3 sit on the transformer sheet 14, which carries the primary windings 15 and 16 and the secondary winding 17. The relay winding 2 is placed on the leg 25 of the transformer 24, while the relay armature 20 sits on the contact spring 21 which carries the contact 22 and is attached to the core of the transformer 24. The mating contact 23 is also attached to the transformer 24 or the relay leg 25. The relay winding 3 is placed on the leg 26 of the transformer 24 in a similar manner. The contact springs 11 and 13, of which the contact spring 11 carries the relay armature, are designed with their contacts 10 and 12 as normally closed relays. The contact springs 11 and 13 are also attached to the transformer 24.

In the example of Fig. 2 of the transformer 24a and the two relays have separate cores, namely the transformer core 24 a and the two relay cores 25 a and 26 a. Furthermore, all device parts are installed in a common housing 27.

The mode of operation of the arrangement is as follows: The charging current of the capacitor 5 flows via the relay windings 2 and 3 and attracts the armature 9. When the capacitor 5 is practically charged to the rectified mains voltage, ie the Rufladestrom has become small, the armature 9 drops and brings the contacts 10 and 12 to contact, whereby the capacitor 5 is discharged via the primary winding 15, whereby a high-voltage pulse in the Secondary winding 17 arises. When the capacitor 5 is discharged, a charging current arises which flows through the windings 2 and 3 and which attracts the armature 9 again, as well as the armature 20; thus the contacts 22 and 23 come into contact, whereby the capacitor 7 is discharged via the primary winding 16. A second high-voltage pulse occurs in the secondary winding 17, to be precise briefly after the first high-voltage pulse. With decreasing Rufladestrom the capacitor 6 , the relay armature 20 has dropped again, and the call charging of the capacitor 7 takes place again. The resistor 4 and the resistors of the relay windings 2 and 3 are chosen so that the armature 9 in a cycle of one second Normally closed contact 10 and 12 actuated, whereby the normally open contact 22, 23 always comes into action.

The mechanical arrangement of the relays with those suspended on contact springs Anchoring has the advantage that no mechanical friction occurs, but above all also the advantage that no bruises occur. For reasons of manufacturing simplicity sit both relay windings together with the transformer coils on a common Core.

The contact time of the contacts 10 and 12 is essentially determined by the period of oscillation of the contact springs 11 and 13. The primary winding 15 is dimensioned so that the discharge of the capacitor 5 has practically decayed to zero when the contacts 10 and 12 open. So that the capacitor 5 discharges quickly enough, it is necessary to give the winding 15 relatively few turns, with the result that long fences can only be charged to a relatively low voltage with the transformed high-voltage pulses. This is due to the fact that the peak amperage of the discharge current is relatively high due to the small number of turns, but this is limited for reasons of accident protection, so that with such a short discharge time, voltages of unlimited magnitude cannot be generated on the fence.

For this reason, the primary winding 16 has a larger number of turns, so that the discharge of the capacitor 7 takes place more slowly. For this reason, the contact contact time of the normally open contact 22, 23 must be longer, to be precise by a multiple greater than that of the normally closed contact 10, 12. It is therefore easy to generate voltages which also charge long fences to a relatively high voltage.

There is also the option of completely separate high-voltage transformers with one primary and one secondary winding each assigned to one of the relays to use. The relays can be used individually with one of the two transformer cores be connected or sit on the transformer core. However, you can entirely be provided separately. In both cases the secondary windings are either to be connected in parallel or one behind the other to the output terminals of the fence energiser.

The invention thus offers the advantage that without bruises, d. H. is switched without contact wear, the further advantage that in the fence two capacitor discharges are transformed, which are transferred shortly after one another in each case generate the highest permissible peak current due to the accident prevention regulations is permissible. This practically doubles the herding effect, without creating a greater risk of accidents.

Claims (4)

PATENT CLAIMS: 1. Electric fence energiser for mains connection, in which the high-voltage pulses to be transmitted to a pasture fence are generated by discharging a capacitor by means of a relay over the primary winding of a high-voltage transformer , characterized in that the discharge circuits of two pulse capacitors to be discharged one after the other over each a discharge relay are connected to the primary winding of one and the same high-voltage transformer and that the actuating coils of the two relays are in the charging circuit of a pulse capacitor, the relay of this capacitor is equipped with normally closed contacts, the other with normally open contacts. 2. Electric fence device according to claim 1, characterized in that the ohmic resistances of the two primary windings (15, 16) of the transformer (24) with the capacitance values of the two capacitors (5, 7) are matched so that the total discharge time for both capacitors is less than 0.1 second. 3. Electric fence device according to claim 1 or 2, characterized in that the two relay coils (2, 3) and the transformer coils (15 to 17) are mounted on a common iron core and that this iron core is the spring set (11, 13) with normally closed contact for the carries a relay (10, 12) and the spring (21) with normally open contact (22, 23) for the other relay. 4. Electric fence device according to one of claims 1 to 3, characterized in that the primary winding (15) of the high-voltage transformer (24), to which the first capacitor (5) is connected via the normally closed relay (3, 9 to 13) , has a smaller number of turns as that primary winding (16) of the high-voltage transformer (24) to which the second capacitor (7) is connected via the normally open relay (2, 20 to 23). Considered publications German patent specification No. 920 622.