DE695160C - Relay breaker - Google Patents

Description

Relay interrupter The invention relates to a circuit arrangement for a relay breaker that allows for precise adaptation to the respective operating conditions.

There are already relay breakers with two mutually controlling Known relays whose mode of operation is connected in parallel to one of these relays Capacitor can be adapted to the switching tasks to be fulfilled. But there that Relay that can be temporally influenced by the capacitor directly - the mode of operation of the other relay, changes inevitably with these relay breakers with every change in the mode of operation of the relay parallel to the capacitor the mode of operation of the other relay, so that in each case the frequency is at the same time and change surge division. One must therefore, if one z. B. only the frequency of the. Relay interrupter must adapt while maintaining the current surge division, according to Change of the capacitor assigned to a relay directly affects the electrical Change the sizes of the other relay or the alignment of its contacts. That requires but a time-consuming and difficult one, especially in the case of interrupters that have to be precisely coordinated Job. Since otherwise such a vote of a relay only within certain If limits are possible, these breakers allow adjustment only within narrower limits Limits too. The same disadvantages arise when the breaker is connected to a certain Current surge division should be adapted without changing the frequency. But also with simultaneous adjustment of frequency and surge division to specific operating conditions such difficulties arise as a result of being inaccurate and difficult to perform Possibility of tuning the relay breaker.

According to the invention, these disadvantages are avoided in that the Relays of the relay breaker influence each other in such a way that each Relay the state of charge of a capacitor used to influence the other relay controls.

In the accompanying drawing are several - exemplary embodiments shown, but to which the inventive concept is not limited. It is about here to current surge generator.

In detail, the FIGS. R and a represent relay interrupter, at which relay A and B under the influence of capacitor discharge currents respond, while Figs. 3 to 5 further embodiments of relay, relay breakers show, in which the "E, = lais A and B each under the influence of #M: capacitor charging currents speak to.

In Fig. I, two Re = "lais A and B are connected together with two capacitors C1 and C2 via contacts a1 and b1. Another circuit is under the influence of relay A through contact a3 2, or at the same time under the influence of relays A and B. Both capacitors are discharged when the switch is closed S, in addition to charging the capacitor Cl, the relay A is excited. The relay A closes its contact a2 and thus connects the capacitor C2 to the power source After the switch S is opened, the relay A loses its excitation, the contact a1 closes again and the capacitor C2 discharges via the relay B, which then responds and closes its contact b2. When relay A is de-energized, the working circuit at contact äs has also been interrupted again. By closing the contact b2, the capacitor Cl, which would have discharged its first charge brought about by closing the switch S via the relay A, is again connected to the power source and charges up again. As soon as the capacitor C2 has discharged, the relay B is de-energized and the contact b1 closes again, whereby the charged capacitor C can discharge again via the relay A : The relay A causes a charge again by closing its contact a2 of the capacitor C2 and the play of the relay is repeated until, as is not shown in more detail in FIG. B. by interrupting a power supply is prevented. Since every excitation of relay A among other things also actuates contact a3, a current impulse is given in the indicated circuit in which the contact is located in the rhythm of the excitation of relay A.

A circuit arrangement which corresponds to FIG. in which, in a manner similar to that in FIG. The difference between the two circuits is the different rest position of the contact b2. Hereby it is achieved that the capacitor Cl @ `is charged loosely. When the switch S is closed, the relay A is immediately fully energized and not, as in the arrangement according to FIG. 1, with a delay by the charging time of the capacitor.

In the further exemplary embodiments of FIGS. 3 to 5, how already indicated, the capacitor charge currents to the relay to respond bring: In Fig. 3, the capacitors C1 are in the idle state of the arrangement and C2 via contacts b1 and a1 to relays A and B, which are in the initial state can be constantly under tension. When the switch S is pressed, the is discharged Capacitor Cl through resistor R1. But as soon as the switch S is opened again is, flows through the relay A of the charging current of the capacitor Cl, which this relay to respond. As a result, the capacitor C2 is connected to the Resistance R2 placed, through which it discharges. Once the capacitor C1 is charged the excitation current of relay A disappears. This closes the contact a1 again, and the relay B speaks as a result of the charging current of the capacitor C2 at. The capacitor C1 is now discharged via the resistor via the contact b2 R1 as long as the excitation of relay B as a result of the charging current of the capacitor C2 lasts. When the relay B is de-energized, the contact bi is closed again and by the charging current of the capacitor C, the relay A is brought into action again. The process continues; now until a capacitor discharges is prevented by z. B. a normally closed contact x1 is opened.

From Fig. 3 it can also be seen that with each response of the relay A in a further, otherwise not shown circuit, a Kontaktas is actuated, which in the present embodiment is designed as a normally closed contact and acts as a rush contact in the indicated circuit. The control this circuit can, however, as shown in FIG. 4; by a normally closed contact of relay B.

The embodiment of FIG. 4 differs, corresponding to that of FIG. 2, from that of FIG. 3 only in the different rest position of the contact b2. The capacitor C1 - is discharged in the idle state. By pressing the S button, the full excitation current immediately flows through the relay A: The relay A responds and causes the capacitor C2 to discharge via the contact a2. When the key is pressed, contact a1 is closed as a result of the de-energization of relay A. The relay B responds as a result of the charging current of the capacitor C2 and thereby closes the contact b1. The relay A responds again and the interplay of the relay is repeated until z. B. by opening the contact x2 a discharge of the capacitor C2 is prevented. Likewise, the process can be carried out by interrupting the power supply, e.g. B. for the relay A ', are terminated.

In the further illustrated embodiment of FIG by closing the switch S, the capacitor Cl is discharged through the resistor R1. Due to the battery current, relay A continues to respond, which inter alia. the Contact a2 closes, whereby the capacitor C2 discharges through the resistor R2 will. As soon as the switch S is opened again, loses. the relay A its excitation. Contact a1 is closed again and relay B speaks as a result of the charging current of the capacitor C2. Contact b2 is closed, causing the capacitor to discharge Cl entails. As soon as the relay B loses its excitation again, what then occurs when the capacitor C2 has charged, the contact becomes b1 again closed. So long. the switch S is actuated, the closing of the contact remains b1 without any particular effect. But if the switch S is in the idle state; so the relay A responds again as a result of the charging current of the capacitor Cl. the Relays A and B then switch each other by one after the other Discharge and charge the capacitors C1 and C2 one after the other in a constant sequence and from; until z. B. by interrupting the power supply a further repetition switching operations is prevented.

With all the arrangements described, you have it through appropriate Choice of the rating of the capacitors in hand, the breaker frequency and the To specify surge sharing. By replacing one or both capacitors with such a different size one is now in a position to breaker frequency and current surge division set either simultaneously or separately. By using mutable Capacitors can even make these changes during operation of the arrangement make.

The arrangement can now also be made so that only the capacity one capacitor is variable and adjustable, while the capacitance of the other is retained or vice versa. In this case it is a simultaneous one Change of breaker frequency and surge sharing. Will the capacitors but if both are made changeable, then we are dealing with a correspondingly co-rotating one (e.g. enlarging one capacitor and enlarging the other) Change of both capacitors by a change in the interrupter frequency, in the case of an opposite (e.g. increasing one, decreasing the other) by changing the current surge division. The change in one capacitor does not need to be the same in any case Law to proceed like the change of the other capacitor, but can be the desired changes of current impulse length and current impulse division adapted accordingly will.

Finally, it is also noteworthy that the interruption frequency is also nor through the change in the properties of the interrupter relay, which is known per se can be influenced by z. B. the resistances or the self-induction the breaker relay coils increased or decreased. You can do this e.g. B. thereby achieve that the relay has additional copper damping (e.g. special damping windings) according to the short-circuit windings shown in dashed lines in FIGS. 3 and q. which influence the time constants of the relays through optional activation. So z. B. both relays are provided with such damping windings; But it is also possible to have just one relay with a special damping winding to be provided: It is still easier to adjust the interrupter frequency by changing the To influence ohmic resistances of the charging and discharging circuits of the capacitors. The simplest circuit results when you have a z. B. gradually or continuously variable resistance arranged in the center conductor, as shown in Fig.-a would if a variable resistor R were switched on between points i and z would. Furthermore, those designated in FIGS. 3 to 5 with R1 and R2 can also be used Resistances can be made adjustable. All of these mentioned setting options the interrupter frequency can either be used by itself or z. B. for the purpose Coarse and fine adjustment of the interrupter frequency can be combined together. '

Claims (6)

PATENT CLAIMS: i. Circuit arrangement for relay interruption with two each other controlling relay, characterized in that that the relays influence each other in such a way that each relay (A resp. B) the state of charge of one used to influence the other relay (B or: A) Capacitor (C2 or Cl) controls. 2. Circuit arrangement according to claim z, characterized in that each relay (A or B) of the relay interrupter through the contact (b1 or a1) of the other relay (B or A) of the relay interrupter in the discharge circuit of the capacitor assigned to it (Cl or C2) is switched. 3. Circuit arrangement according to claim z, characterized in that each relay (A or B) of the relay interrupter through the contact (bi or a1) of the other relay (B or A) of the relay interrupter in the charging circuit of the capacitor assigned to it ( Cl or C2) is switched. 4. Circuit arrangement according to spoke 2 or 3, characterized in that the capacitors (Cl; C2) are exchangeable or adjustable with regard to their capacitance value. Circuit arrangement according to Claim 2 or 3, characterized in that the Self-induction of the charging or discharging circuits of the capacitors (Cl, C2) variable are. 6. Circuit arrangement according to claim 2 or 3, characterized in that the ohmic resistance of the charging or discharging circuit (s) of the capacitors (C1, C2) are variable.