DE437332C - Circuit arrangement for relay selectors - Google Patents

Description

GERMAN EMPIRE

ISSUED ON November 20, 1926

REICH PATENT OFFICE

PATENT LETTERING

CLASS 21a ³ GROUP

(A 39484 VUIj ₂ Ia ³ j

Allmänna Telefonaktiebolaget L M. Ericsson in Stockholm.

Circuit arrangement for relay selector. Patented in the German Empire on February 27, 1923.

According to the Union Treaty of June 2, 1911, priority is due to this application of the application in Sweden of January 29, 1923.

The invention relates to selector switches, in particular for automatic telephone systems, namely those that consist of relays. Among already known switching devices of this kind, one can distinguish between those that follow a certain code system by means of various combinations are operated by power surges and those in which the relays in a certain Sequence are operated by means of a series of power surges. The present Invention relates ■ to switching

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Devices of the latter type. Relay selector of this type are known in which the relays are arranged in pairs and the circuits of the relays in the first relay pair controlled by a rush relay in such a way that the first-mentioned relays respond half as often as the rush relay, while the circuits of the relays in the second and further relay pairs are similar Controlled by one of the relays of the immediately preceding relay pair will.

The present invention relates to a special design of the relay circuits of such selectors in order to ensure safe operation of the selector under all circumstances, and consists mainly in the fact that the circuits of the relays of each relay pair are controlled in this way by the surge relay or the corresponding relay of the immediately preceding relay pair be that each relay is alternately energized by switching on a working winding and de-energized by short-circuiting a holding winding that is switched on when responding. The invention will be described in more detail with reference to the accompanying drawings, where Fig. 1 shows an embodiment of an apparatus for selecting ten lines or circuits by means of four combination relays. Fig. 2 is a diagram showing the various combinations that are gradually created by the action of electrical surges ^; the can. Fig. 3 shows another embodiment, composed of a smaller number of relays, while Fig. 4 shows a diagram to illustrate the switching process in Fig. 3. Fig. 5 shows an apparatus for selecting 100 different lines.

The apparatus shown in Fig. 1 consists of two rows of relays A ₁ C, E ₁ G and B ₁ D ₁ P ₁ H, of which the first row comprises the selecting relays or combination relays, while the second row is made up of auxiliary relays . The above-mentioned relays are combined in pairs in such a way that the relays within each pair AB, CD etc. are actuated alternately, with the same number of times, while the relays of each following relay pair work only half as often as the relays of the immediately preceding relay pair, as will be explained in more detail below. Each relay is provided with three windings AL, BL and CL , of which the first is a working winding, the second is a holding winding and the third is an auxiliary winding. The two relays in each individual relay pair mutually monitor their working circuits, while the holding circuits are independent of one another. The selector current impulses by which the switchgear is operated are sent through a current impulse relay / which controls the circuits of the first relay pair. In a similar way, the auxiliary relays B ₁ D and F control the circuits of the subsequent relay pairs CD ₁ EF and G H. Two delay relays K and L are also used to control the circuit. All circuits are fed by a common battery, not shown in the drawing, the positive and negative terminals of which are connected to the various lines at the points marked with plus and minus. The relay H together with the connections marked with dashed lines can be omitted under certain circumstances, namely in the event that the apparatus is provided for the selection of only ten lines; then the winding AL of the relay G is connected directly to the battery.

When the power is first closed by the impulse relay /, only the delay relay K is switched on via contact 11. The selector surges are produced by repeatedly breaking and closing the circuit of the surge relay. The delay relay L is switched on at the first power interruption, which follows the first current surge. The two delay relays then keep their armature attracted as long as the impulse current continues. The delay relay L prepares the working circuit for the relay A by closing the contact 12. As soon as the impulse relay picks up its armature again, the mentioned circuit is closed by the winding ./4L ₁ , and the relay A picks up its armature. The second current impulse only actuated relay A, the first of the various combination relays. However, by closing contact 13, relay A prepares a holding circuit for winding BL ₁ , but at this moment it is short-circuited via the contact. In addition, relay A prepares the working circuit for relay B by closing contact no.

When the rush relay I drops its armature for the second time, the latter circuit is completed and the relay B picks up its armature. At the same time, the working circuit for relay A is interrupted, which now receives holding current through the windings BL ₁ and CL ₁ after the winding ^ L _{1 has been switched off} at the contact on relay B. The relay B partly prepares its own holding

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Circuit by closing the contact id and partly the working circuit for the relay C by closing the contact ι J before. When the impulse relay picks up its Ankei again, the winding SL _{1 of} the relay A is short-circuited, while the winding CL ₁ remains live. However, this winding has such a small number of turns that it is unable to operate the relay. 1 get energized. In addition, it is wound so that it counteracts the winding BL _1. If the winding BL _{1 is} short-circuited, the winding CA ₁ therefore accelerates the de-energization of the relay A, so that the relay A quickly drops its armature. The armature of the relay B is now held in place by current through the windings BL ₂ and CL ₂ . When the relay A drops its armature, the working circuit is closed ^: so for the relay C by its winding AL _1. Relay C attracts its armature and prepares, in a similar way to relay A, partly its own holding circuit and partly the working circuit for relay D. Relays B and C are therefore energized during the third surge. > Relay A, however, is now deenergized.

If the relay / after the third current- ^! if the thrust drops its anchor, the; Holding winding BL ₂ of relay B short-circuited, which is de-excited and can drop its armature, whereby the working circuit of relay D via contact 18 on relay B and contact 19 on relay C is closed. The relay D \ consequently attracts its armature and, in a similar way to the relay B, prepares partly its own holding circuit by closing the contact 20 and partly the working circuit for the relay E by closing the contact 21. When the impulse relay / its armature picks up again, the relay A is activated for the second time j. When the fourth current surge occurs, relays A, C and D are in their working position.

After the fourth current surge, ahn- | Licher W ^T else first excitation of the re 'relay B and then at the fifth surge: causing deenergization of the relay A. So-; soon the relay A drops its armature, the holding winding BL _{1 of} the relay C is short-circuited via the contacts 17 and 22, which is why the relay C can drop its armature. The working circuit for I relay E is closed at contact 23, and relay E consequently attracts its armature. j With the fifth current impulse, the relays B ₁ D and E are in the working position. At the end of the fifth current impulse, relay B is de-energized and thus the excitation of relay A is prepared. Because the relay B drops its armature, the relay D is de-energized and the working circuit of the relay F is thereby closed via the contact 24. With the sixth current impulse, the relays A ₁ E and F are in the working position.

At the end of the sixth current surge, relay B is energized, while relay A is de-energized at the beginning of the seventh current surge, relay C is actuated again; the relays E and F remain in their working position. During the seventh current impulse, relays B, C ₁ E and F are in their working position.

At the end of the seventh .Stromimpulse the relay B is de-energized and the relay D is operated again. The eighth current impulse energizes relay A , while relays E and F remain in the working position. As a result, relays A, C, D, E and F are now in their working position.

After the eighth current surge, relay B is energized. The relay A is de-energized by the following ninth current impulse, so that the relay C drops its armature and consequently short-circuits the holding winding of the relay E via the contact 23, so that the relay E also drops its armature. The working circuit of relay G is closed via contacts 25 and 26. During the ninth current impulse, relays B, D, F and G are in their working position.

At the end of the ninth current impulse, relay B is de-energized. As a result, the relay D is also de-energized, which, by dropping its armature, short-circuits the holding winding of the relay F , so that this also drops its armature and the relay H switches on. Relay A is energized by the tenth current surge. Relays A, G and H are now in their working position.

At the end of the tenth pulse, relay B is energized. Finally, the relay A is de-excited by the eleventh current impulse, so that the relay C responds again. The relays / ?, C, G and H are now in their working position.

The circuit process described is illustrated by FIG. The horizontal lines represent the different time segments during which the relays / and A to H are in the working position, while the vertical, dash-dotted lines separate the time intervals of the successive power closures and power interruptions in the electrical circuit of the impulse relay /. It follows directly from the diagram which relays during the

first, second, third, etc. current impulse are in the working position.

From Fig. 2 it can be seen that the relays A and B are energized and de-energized half as often as the impulse relay I. It also shows that the various relays of the second, third and fourth relay pairs are alternately energized and de-energized half as often as the relays of the immediately preceding relay pair. It can also be seen from Fig. 2 that relays B, D, F and H operate with a shift of half a period in relation to relays A, C, E and G. As a result, the various relays in each of the two rows of relays respond gradually in different combinations. In the embodiment shown in Fig. 1, the first ten combinations in the relay series A, C, E, G are used to select ten different circuits 1, 2, 3, 4, 5, 6, 7, 8, 9, 10 which is brought about in a manner known per se by means of contacts AK, CK, EiT and GK .

After the impulse relay / has been de-energized a few times, namely corresponding to the relevant number of selector current surges, it remains in the working position while the relay L is de-energized. The selected circuit is closed via a contact 27. After transmission of example only six electric shocks, after which the relay A ₁ E and F loading into working position find \, so the circuit is 5 via the j contact 28 at relay A and the contact 29 at relay E closed. Immediately thereafter, all those relays are de-excited which receive current via the contact 12, which is opened by the relay L +0 dropping its armature. After the conversation has ended, the circuit of the impulse relay I and thus also the circuit of the delay relay K are interrupted.

The auxiliary winding CL, which essentially has the task of causing rapid de-excitation of the associated relay, may be omitted or replaced by an inactive resistor.

By using the auxiliary relays as combination relays, the total number of Relays are reduced. Fig. 3 shows an example of a switchgear, which from only three relay pairs is put together; those four relays which the two Last relay pairs are used as combination relays for selecting lines used, while the first pair of relays is only used to control the switching process.

The switching process is essentially as follows: The five first selector current surges act in a similar way to the embodiment according to Fig. 1. During the fifth current surge, the relays B, D and E are in the working position. The current interruption following the fifth current surge causes the relay B to deenergize, so that the holding winding of the relay D is short-circuited via the contact 18. Thus the relay D is deenergized. The sixth current surge causes relay A to be energized. With the sixth current surge, only relays A and E are active.

At the end of the sixth surge, relay B is energized. The seventh current surge causes relay A to deenergize, and relay C responds again. This creates the combination B, C and E.

The current interruption following the seventh current surge causes relay B to be de-energized. As a result, the relay D responds again. At the same time, however, the working winding of the relay F receives power via the contact 19 on the relay C and the contact 31 on the relay E, whereby the relay F also responds. The eighth current surge energizes relay A. This results in the combination A ₁ C ₁ D ₁ E ₁ F.

At the end of the eighth surge, relay B is energized. The ninth current surge causes relay A and relay C to de-energize and thus results in the combination of B, D, E and F.

The subsequent interruption of the current causes the de-energization of the relay B and the relay D. The tenth current impulse energizes the relay A. This creates the combination A, E and F.

The eleventh impulse finally produces the combination B ₁ C ₁ E and F.

As can be seen from Fig. 4, the relays A, B, C and D work regularly in the same way as in the arrangement according to Fig. 1, while E and F remain in the working position after being switched on once the switching on of the relay F a full period instead of half a period after the relay D as shown in Fig. 1. The relays E and F do not require any special auxiliary windings in this case. Since the first and second current surges have no effect on the combination relay, the first of the circuits to be selected must be routed to all combination relays via normally closed contacts, as can be seen in Fig. 5.

The switchgear shown in Fig. 5 is composed of two devices according to Fig. 3, but the first relay

couple AB the actual combination relay [together. Among the combination relays, relays C ₁ , D ₁ , E ₁ , F _{1 are used} to select the tens and relays C ₂ , D ₂ , E ₂ , F ₂ to select the ones. The corresponding tens and circuits TS and ES are guided via contacts on special relay CR, DR, ER, FR, which eingeschal- by the 'corresponding relay C, D, E, F ₍

ίο be tet. The tens circuits TS contain tens relays TR, through which the ones circuits ES are switched to different groups of circuits GS . Switching from one relay group, C ₁ , D ₁ , E ₁ , F ₁ to the other group C ₂ , D ₂ , E ₂ , F ₂ is carried out by a relay P through the intermediary of a relay O and two relays M and N, from which the last two are switched in a similar manner to relays A and B and are arranged under the control of relay L.

The switching takes place in this case by means of two series of current surges, which Operate one of the two groups of combination relays in exactly the same way

• As with the arrangement according to Fig. 3. The first series of impulses actuates the relay J group C ₁ , D ₁ , E ₁ , F ₁ . If the delay relay drops its armature after receiving the first series of current surges, the relay A ^{r is} switched on, the circuit of which has been prepared by the relay M, which was actuated when the relay L first picked up its armature .- The I

M relay switches on the relay O, which 'thereby attracts its anchor and containing in a P relay circuit turns on, so that the relay P responsive and switches the two relays groups. The subsequent series of current surges must consequently actuate _{the relay groups C 2} , D ₂ , E ₂ , F _2. If the delay relay L then drops its armature for the second time, the relay N is deenergized. This closes the circuit of the relay R, which in turn switches on a relay 5 and at the same time closes the circuits of the relays CR, DR, ER, FR , which correspond to the actuated combination relays. The relay S closes the corresponding tens circuit and thereby causes a tens relay TR to respond, which, by attracting its armature, closes the relevant ones circuit. When the impulse relay / finally drops its armature, the switchgear is restored to its original state.

Claims (4)

Patent claims: 1. Circuit arrangement for relay selectors with relays arranged in pairs, which are influenced in a certain order by means of a series of current surges and are made to respond in various combinations, and in which the circuits of the relays in the first relay pair are controlled by a surge relay in such a way that the the first-mentioned relay respond half as often as the pulse relay, while the circuits of the relays in the second and further relay pairs are controlled in a similar manner by one of the relays of the relay pair immediately preceding, characterized in that the circuits of the relays of each relay pair are controlled by the pulse relay (/ ) or the corresponding relay of the immediately preceding relay pair can be controlled in such a way that each relay is alternately energized by switching on a working winding (AL) and de-energized by short-circuiting a holding winding (BL) that is switched on when responding. 2. Switching arrangement for relay selector according to claim 1, characterized in that the holding circuit each. Relay contains an auxiliary winding (CL) counteracting the holding winding (BL) , which remains live when the holding winding is short-circuited and has such a small number of turns that it cannot keep the relay in the working position. 3. Switching arrangement for relay selector according to claim 1, characterized in that the selector has three relay pairs, of which the relays of the last two relay pairs (C D and EF) are arranged as combination relays for the selection of lines, while the relays of the first relay pair (AB ) only work as a control relay. 4. Switching arrangement for relay selector according to claim 3, characterized in that the control relays (A, B) for two groups (C ₁ , D ₁ , E ₁ , F ₁ and C ₂ , D ₂ , E ₂ , F ₂ ) of combination relays are arranged in common and work together with a changeover relay (P) , through which they are brought to interact with one or the other relay group. For this purpose ι sheet of drawings. BERLIN OEDBfCKT IN THE