DE1514726C - Circuit for generating shock voltage pulses for training animals - Google Patents

Description

are considered the circuit according to the invention because at a separate complete winding is required for each discharge circuit, could through Transfer of its basic structure to circuits for dressage equipment that is the basis of the invention underlying problem cannot be resolved. This also applies to the circuits for pulse generation where two separate discharge circuits are provided, but they can only be switched on individually to to enable a change in the pulse strength by switching the device. It should also be taken into account that with shock pulse generating devices for pasture fences not, as with the circuit after of the invention, worked with discharge circuits with substantially different windings due to the strong dependency of the adjustment on the pulse transformer translation ratio.

An example embodiment of a circuit according to the invention is shown in FIG. 1 shown.

F i g. 2 shows the shape of the pulse generated with the circuit of FIG.

The electrodes la and Ib to be applied to the animal body are connected to one another via the secondary winding of a pulse transformer.

On the primary side, the winding of the pulse transformer 2 is divided by a tap into two windings Wl and Wl , one of which, WL, has a lower number of turns than the other, W 2. The number of turns of the primary windings W1 and W 2 of the pulse transformer 2 are selected in this way that there is a transmission ratio of 1: 1000 for the winding pair PFl, W 3 and a transmission ratio of 1: 125 for the winding pair Wl and Wl, W 3.

The primary winding Wl, Wl of the pulse transformer 2 is connected to the poles of a battery 5 via silicon rectifiers 3 a, 3 b, one of which is each connected to one end of the primary winding, and via lines 4 a, 4 b. The silicon rectifier 3 α is controllable.

To form a discharge circuit of the partial winding of the ignition transformer Wl is 2 and the silicon controlled rectifier 3 a, a capacitor 6 (1000 microfarads) α via lines 7 and 7 b connected in parallel. A larger capacitor 8 (2500 microfarads) is connected in parallel to the entire primary winding Wl, Wl of the pulse transformer 2 and the two silicon rectifiers 3 a and 3 b via lines 9 a and 9 b , so that a further discharge circuit is formed.

To form an additional discharge circuit, a third capacitor 13 can be connected to the primary winding of the pulse transformer via lines 15 a, 15 b with switch 14, namely to the overall winding Wl, Wl. By closing the switch 14, the capacitor 13 can be switched on as an additional capacitance in order to amplify the impulse caused by the discharge of the capacitor 8.

In a further parallel branch 10 a, 10 6 to the overall primary winding Wl, Wl of the pulse transformer 2 and the two silicon rectifiers 3 a and 3 b, which forms the control line for the controllable silicon rectifier 3 α , a switch 11 is provided through which it is closed the rectifier 3 α is switched on and the discharge of the two capacitors 6 and 8 via the partial or total primary winding of the ignition transformer 2 is triggered. A correspondingly dimensioned ignition resistor 12 is switched on in branch 10 b.

A charging resistor 16 is switched into the charging circuit of all charging capacitors.
The device to which the dressage device equipped with the circuit according to the invention belongs operates as follows:

The switch 11 is normally open. He is through an outside signal that the control unit is operating Person triggers to close. This external signal can, for. B. by an acoustic signal coming from a pipe used by the person training the animal, or by an electromagnetic signal that is triggered by actuating an electric wave transmitter, the the person who trains the animal is carrying the animal.

When the switch 11 is open, the capacitors 6 and 8 are charged from the battery 5 via the lines 4 a, 4 b and 7 a, 7 b and 9 a, 9 b, respectively. When the switch 14 is closed, the capacitor 13 is also charged. A discharge of the capacitors 6, 8, 13 via the primary winding Wl, Wl of the ignition transformer 2 is not possible because of the controllable silicon rectifier 3 α connected upstream of this winding when the switch 11 is open, since this controllable silicon rectifier is not switched on. By closing the switch 11, the discharge of the capacitors 6, 8 enables and optionally 13, as the controllable SiIiziumgleichrichter 3 is turned on α.

The discharge current from the capacitor 6, which only through the winding W; flows with the lower number of turns, brings the high gear ratio of this winding to the secondary winding W 3 (1: 1000) a high voltage on the secondary winding W 3 which causes the flashover between the electrodes 1 α and 1 b. However, this high voltage pulse is short-lived. He is in the fig. 2 shown in dashed lines and denoted by 17.

The voltage surge on the entire primary winding Wl, Wl of the pulse transformer 2 caused by the discharge of the capacitor 8 and possibly also the capacitor 13 causes a pulse of lower voltage but longer duration on the secondary winding Wi of the pulse transformer due to the low transformation ratio (1: 125) 2. This momentum is in FIG. 2 reproduced in dotted lines and denoted by 18. The superimposition of the two pulses results in the in FIG. 1 during the entire discharge time. 2 pulse reproduced in a solid line, which has a voltage peak at the beginning and then in the further course then shows an initially only slowly falling low voltage.

By superimposing two discharge processes when using the circuit according to the invention a high voltage pulse is generated at the beginning of the entire discharge time, the ensures the flashover, and immediately afterwards a pulse with low voltage, however longer duration that produces the desired irritant effect.

Since the charging process of the capacitors 6, 8 and possibly 13 extends over a certain time, you can use a small battery for a relatively high internal resistance and thus that Keep weight low.

In practice, a transistor is used as the switch 11. Since the charged capacitors on the silicon controlled rectifier 3 α switched to the primary winding of the Impulstransfromators, not leading to a contact spark resistance and thus no energy loss occurs during switching. The power consumption when charging is low due to the charging resistor. When the capacitors are charged, no power is consumed from the battery at all.

1 sheet of drawings

Claims (2)

1 2 pulse transformer whose optimal values are not patent claims: ter 1:? 0 are at a capacitor voltage of at least 300 volts. 1. Circuit to generate Schreckspan- As a result of the completely different conditions in a voltage impulses for training animals for a 5 impulse transmission directly to the animal carcass of the animal to be carried remotely wirelessly for the purpose of adapting circuits controlling dressage device, in which one of a completely andeeiner battery charged capacitor for dressage equipment to the animal body are trodden on the rer way than in circuits for the primary winding of a pulse transformer via electric fence energizers, which z. B. to overset a remote-controlled switch is discharged, 'io switching ratios for the pulse transformer in the characterized in that two areas of at least 1: 100, e.g. 1: 1000, leads discharge circuits with one of the same battery with a significantly lower capacitor voltage, terie ( 5) charged to the same voltage. The impulse transmitted to the carcass must be provided with a capacitor (6, 8), of which a certain strength has to be provided, which allows an ionization of the one discharge circuit with a larger current path through the carcass between the two capacitors ( 8) is guaranteed to the electrodes over the entire primary winding. Because of the hair (W 1, W 2) of the impulse transformer (2) and the dressing of the animal, the electrodes hardly come into direct contact with a smaller capacitor (6) only with the skin. Part (Wl) of the primary winding is aimed at the current flashover between the electrode, and that both discharge circuits require a relatively high voltage via an external signal and require a relatively high voltage. As a result of the low resistance of the current path, rectifiers (3 a) are switched at the same time. the high tension breaks through the animal 2. Circuit according to claim 1, characterized ge but after the occurrence of ionization together, so that indicates that in the one discharge circuit with the current flow through the animal body in the the larger capacitor (8) of this optional 25 known dressage devices is not the desired one Another capacitor (13) connected in parallel gives a strong electrifying effect. At work can be. with low voltage pulses and accordingly a longer period of time is a sufficient irritant effect achievable, but the rollover is between 30 see electrode and carcass in particular Collar devices not guaranteed. The invention is based on the object of remedying this by means of a circuit in which both sufficient electrification of the 35 tier as well as the rollover is guaranteed, The invention relates to a circuit for generating without damaging or endangering the animal generation of shock voltage impulses for training res would be feared that the use of from animals for one to be carried by the animal, from the capacitors with increased capacitance in their Remote, wirelessly controllable dressage equipment, with charging on a rollover guarantee rather a capacitor charged by a battery would be the case. tor across the primary winding of a pulse transformer. The circuit according to the invention is characterized tors via a remote-controlled switch marked that two discharge circuits with one each will. from the same battery to the same voltage A wirelessly controlled training device of this charged capacitor is provided, of which ii Art is in the German patent 841 241, the 45 one discharge circuit with a larger capacitor wrote. It is equipped with an electric drover gate over the entire primary winding of the pulse! Stocke well-known circuit equipped, in the case of a transformer, the other with a smaller one which for generating a high voltage pulse capacitor only over part of the primary winding is passed between to be attached to the carcass electrodes, and that both discharge circuits through one the primary current of an ignition transformer less than 5 ° common, controlled by an external signal j is broken, the secondary winding of which the electrical rectifiers are switched at the same time. \ troden connects. By means of this circuit, two Also for the purpose of generating shock impulses, impulses are generated which superimpose one another, namely '| circuits are used for electric pasture fences a high voltage pulse that uses the flashover, with soft one charged by a battery, and a pulse of lower voltage, each ner capacitor across the primary winding of an im- yet longer period of time that generates the desired stimulus- j pulse transformer is discharged. The capacitor effect causes. discharge takes place periodically by means of the To amplify the pulse, the discharge Transformer of upstream automatic working circuits with the larger capacitor, optionally the switching devices. The secondary winding of the 60 additional capacitor can be connected in parallel.
The transformer is grounded on the one hand, and on the other hand. connected to the pasture fence, already known, to form two discharge circles For the design of such circuits for elec- trical two capacitors to be provided, which have separate Fence fencers are discharged with regard to their matching windings, and not to any Solution to the pasture fence is the theory of the impulse case at the same time, but for the intended purpose transmission over long lines with considerable generation of two consecutive pulses Capacity to earth decisive. This small time interval. Besides that fit depends heavily on the gear ratio of these known circuits technically more complex