DET0010927MA - - Google Patents

Description

FEDERAL REPUBLY OF GERMANY

Registration date: May 14, 1955 Posted on 21; June 1956

GERMAN PATENT OFFICE

For the solution of certain tasks of the relay management technology devices are necessary, which allow it to influence ek relay so that it responds or drops out, - without that in ^{: the} circuit of this relay contacts are actuated. It is known to achieve a 'such an effect by the use of- induction current surges which werden- produced with aid of a transformer ¹ and act on the actuating winding of a relay. ·

In order to use this effect of the induction ^{current surges for the mutual influence of normal 1} relays in circuit technology, the windings of at least ¹ two relays are switched according to the invention in such a way that an iriductor rush is generated in the winding of one of the relays the second relay betätigt.- with simple techrtische'n ¹ Mittel'n 'e' is fnöglich, in this way the AbfällbetätigUTig of 'bring relays. · Special advantages ergeb'en thereby for so-called zd Ha-ftrelai'S. Öi'ese Behal-teh ¹ afe selbsthaltehde relay irffolge magnetiscWef Reniänen'z the anchor to ^one of excitement in the .Arbeitsstellung ·. · In the ^one this 'way'a'uf in the working position held relay, the 'drop operation already 25' due to ¹ low, that counter-excitation is achieved without causing inductive current impulses. But also normal reliais of the telephone and '

T 10927 VIIIc / 21g

Remote control technology that is kept excited in a holding circuit can be influenced by devices according to the invention. Fig. Ι shows an embodiment of the subject of the invention explained in more detail by the following description. '■■■■' ■ ...- ■■

A key T ₂ is used to switch on relay B via winding B (1/2), and after it has responded, a holding circuit is formed via contact b and winding B (3/4). A third winding B (5/6) of relay B is connected to winding A (5/6) of a second relay A. A key T ₁ , the winding ^ (1/2) of the relay A is excited, so that when you open the key. the interruption of the excitation current in winding A (ζ / 6) . creates an induction voltage. ¹ This causes a counter-excitation of relay B via winding B (6/5) so that it drops out.

Correspondingly, the relay influenced by the inductive current impulse transmission can be a latching relay, the armature of which is held in the working position by remanent magnetism after it has been excited. FIG. 2, in which the relay B is represented by a drawn triangle ials a latching relay, shows such an exemplary embodiment. In this case, the holding circuit of relay B is replaced by the holding force of the remanent magnetism.

Another example of the inductive influence for the release actuation of a relay is shown in

- Fig. 3. With this arrangement, only one winding is required for the influencing relay A and only two windings are required for the influenced relay B. A rectifier Gr is connected in parallel with the winding B (5/6) of the response winding A (1/6) of a relay A to be influenced. When the excitation current is interrupted by key T ₁ , a voltage is induced in winding A (1/6), which in winding B (6/5) and through the rectifier Gr in the forward direction. results in a power surge. The relay B, which was switched on by the button T ₂ and kept energized by its own contact b , receives a counter-excitation from the induction current surge and drops out. The same mode of operation is achieved if such an arrangement contains a latching relay, as shown in FIG. In this embodiment, the .Holding circuit formed by the contact b for the relay B. ■ A similar example 'of the inductive influence of a relay is shown in FIG. 5, in which instead of the rectifier Gr, a capacitor C between the windings of the relay A and © is switched on. When the button T ₁ is closed, the capacitor C is charged via winding B (5/6). When opening the. Button T ₁ is the capacitor over the. Windings 5. (5/6) and Α (τ / 6) discharged. By interrupting the excitation current for. the relay A, is in the winding A (1/6). ■. at the same time, a voltage is induced which, together with the current caused by the capacitor discharge, briefly excites winding B (5/6) of relay B. The relay B, designed as a latching relay, which was switched on by the button T ₂ , receives a counter-excitation and drops out.

There is also the possibility that the relay influenced by the induction current surges only after a certain number of power surges. This can be done, for example, by. appropriate Sizing the coupling between the relay windings can be achieved in which on the one hand the impulse induction current is generated and otherwise received.

The previous exemplary embodiments show how the induction current surge is brought about by interrupting the excitation current of the influencing relay. The same effect can be achieved by switching on the excitation current. In the described exemplary embodiments according to FIGS. 1 and 2, this is achieved by reversing the polarity of the winding B (6/5) of the relay B which absorbs the induction current.

Claims (1)

PATENT CLAIMS: i. Circuit arrangement for the actuation of relays by inductive influence, thereby characterized in that the windings of at least two relays are switched so that An induction current surge is generated in the winding of one of the relays, which the second relay actuated. * 2. ■■ circuit arrangement according to claim i, characterized in that on the core of the. .the induction current generating relays several windings are arranged, one of the windings energizing the relay "is while a second winding with one winding of the induced current surge to be operated relay is connected. 3. Circuit arrangement according to the claims ι and 2, characterized in that the actuated by the induction surge Relay over one or more windings energized and kept energized in a self-holding circuit, with one more winding is connected to the relay generating the induction current surge. 4. Circuit arrangement according to claims ι to 3, characterized in that, in the excitation circuit of the relay generating the induction current surge, a contact is switched on, when ^: its open in the . second winding of this relay creates an induction voltage pulse, so that this in the Winding of the relay influenced by the induction current surge for its release actuation causes a counter excitation current pulse. 5. Circuit arrangement according to claims ι to 4, characterized in that on: the core of the induction surge generating relay is arranged only one winding and with the winding of the Induction current surge actuated relay over 546 / 366- T 10927 VIIIc / 21g a rectifier or capacitor is connected so that the circuit for the Excitation of the relay generating the induction current surge and the circuit for influencing it of the relay to be actuated by the induction current surge are galvanically isolated. 6. Circuit arrangement according to claims ι to 5, characterized in that the relay to be actuated by the induction current surge is designed as a latching relay is that keeps its anchor after the excitation due to magnetic remanence in the working position. 7. Circuit arrangement according to claims ι to 6, characterized in that the interconnected windings of the relay generating the impulse induction current and the relay affected thereby are polarized so that the actuation of the affected relay by switching on the excitation current of the relay generating the induction current surge he follows. 8. Circuit arrangement according to claims ι to 7, characterized in that the generated induction current surge causes the affected relay to be actuated. 9. Circuit arrangement according to claims ι to 7, characterized in that the generated induction current surge is dimensioned so that the relay influenced by it only is brought to waste after several power surges that can be determined in terms of their number. For this purpose ι sheet of drawings