DE688072C - Circuit arrangement for relay selectors in telephone systems - Google Patents

Description

Circuit arrangement for relay selectors in telephone systems of the invention is based on the task of creating an arrangement in which a certain, in several connection devices at the same time possible switching process, such. B. Checking, switching on, disconnecting, calling, switching through, one after the other on the connection devices is distributed in order to prevent a desired line from being used by several at the same time Connection devices is used.

Arrangements with rotary selectors are already available to solve this problem known. But these have the disadvantage that only a relatively small Number of connection devices can be controlled in the desired manner. Furthermore, these voters are due to the heavy wear and tear of the mechanically moving parts the high demands placed on such a facility in the long run not grown.

According to the invention is now to eliminate these disadvantages Relay selector used. The well-known relay selector, which comes from a management group Selecting a particular single line by scanning are used to solve the above The task, however, is not immediately suitable, because the switching process is distributed not just a one-time choice, but a continuously repeating scan of lines required. The invention consists in that the relay selector several groups of relays are assigned, which during the occupancy period of the The selector automatically selects the distribution of a switching process (e.g. checking) lines serving various connection devices in this way continuously scan one after the other that alternately through the one part of the relay the successive Activation of the various line groups and by the other part of the relay the successive scanning of the individual lines within a line group is initiated.

The embodiment according to FIG. Z shows an embodiment of the invention. When the relay selector is put into operation, the starting relay An is energized by a contact x, which remains closed for the duration of the occupancy. The relay An connects by means of a contact q.4an the following circuit for the relays H and R: earth, contacts 44 an, 42 bn, winding of relay R, contact 36n, winding of relay H, battery, earth. The relays H and R respond. The following circuit is formed for relay Bn: earth, contacts 28 on, 3o h, winding of relay Bn, battery, earth. The relay Bn responds and interrupts the excitation circuit of the relays R and H through its contact q.2 bn. However, these relays hold themselves via the contact 55 h. The relay bit is held in a holding circuit that is independent of the relay H through its contact 29 bia. After relays Aia and H respond, the following circuit is formed for relay V1: earth, contacts 28 on, 27 h; 18 bia, winding of relay V1, battery, earth. The relay IV responds and remains independent of the relay Bn via its contact 1 7 vl. The relay V1 also closes its contacts 1 v1, 2 v1, 3 vi, 4 v1. The first line of line group I is switched on via contact r v1, the first line of line group II through contact 2 v1, the first line of line group III through contact 3 v1 and the first line of line group IV through contact 4v1. The four individual lines of line groups I to IV, which are switched on at the same time, themselves form a line group. It should be inserted here that the lines 1 to 16, which are subdivided into four groups I to IV, to certain connecting devices; for example, to local trunk line selectors, over which z. B. by applying earth the incentive for the Aufschaltüng on a called but busy line should be given: After the relay bit has responded , the relay chain A, B, C, D (timing relay chain) is started. It. the following circuit is formed for relay A : earth, contacts 48 bia, 47 d, winding of relay A, battery, earth. Relay A responds and applies ground to line i through its contact 31 a via contact i v1. The relay A switches on the relay B through its contacts 49 a and 50 a. Relay B responds and applies ground to line 2 through its contact 32 b via contact z v1; Relay B switches on relay C via its contacts 5 rb and 52b. Relay C applies earth to line 3 through its contact 33 C via contact 3v. The relay C switches on the relay D through its contact 54c. Relay D puts through his. Contact 34d via contacts 35C and 4v1 earth to line 4. Relay A drops out after relay D has responded, in that contact 47 d opens. If relay A drops out, the circuit for relay B is interrupted. Relay B interrupts the circuit of relay C when it drops out, relay C that of relay D. Relays A, B, C, D are provided with short-circuit windings and therefore drop out with a delay.

During the release time of relay D, the following excitation circuit for relay N is closed: earth, contacts 41d; 40c, 38r, winding of relay N, battery, earth. In order to ensure reliable response of the relay N, contacts 38.r of the contact 3911 are also closed in parallel, which keeps the response circuit for the relay N closed after the relay 12 has dropped out. The relay N interrupts the holding circuit for the relays I2 and H by opening its contact 361a: the two relays drop out. At first, they can no longer be aroused; because on the one hand the hold circuit by opening the contact 55, the excitation circuit on the other hand by the during the whole. Duration of the occupancy of the energized relay bit is interrupted.

After relay H drops out, the following circuit for relay IV2 is closed: earth, contacts 28 on, 261a, 2o v, {relay TV, drops out with a delay), winding of relay V2, battery, earth. The relay. TV2 holds itself after the drop of the relay V1 via its contact 21 v2. Furthermore, the relay b'2 switches on the lines 5 to 8 by closing its contacts 5v2, 6v 7v2, 8v2. After the delayed release of relay D, relay chain A, is again activated. B, C, D left on . As already described, the relays respond one after the other and drop out again one after the other. Earth potential is applied to lines 5 to 8 one after the other via contacts 31 a, 32 b, 33 C, 34 d.

In this sequence of the relay chain A, B, C, D is addressed via relay D and relay C has dropped out, the following circuit for relay H is closed again: earth, contacts 41 d, 40 c, 37 r, 36 ia, winding of relay H, battery , Earth. The relay H responds and is placed in the already described hold circuit via its contact 55h. The relay R cannot respond in this hold circuit as long as the relay D is energized because it is still short-circuited via contact 41 d. After the relay D has dropped out, the relay R can also respond in this hold circuit. After relay H has responded, the following circuit for relay TV3 is closed: earth, contacts 28 aiz, 27h, 25v2 (relay V2 drops out with a delay), winding of relay T'3, battery, earth. The relay TV3 remains after the dropout of the relay 1V2 via its contact 24v3. TV3 schältet relay by closing its contacts 9v3, zov3, 11 v3 lines 9 to 12 a preliminarily. After the relay D! the sequence of the relay chain A, B, C begins again; Di. The lines are one after the other. 9 to 12 scanned. In this sequence of the relay chain, relay D is addressed, relay C de-energizes, relay N is again energized: Relay N causes relays H and R to drop out, as already described, and drops out again even after relay D drops out. When relay H drops out, relay V4 is switched on via contacts 261a and 22v3, which relay is maintained via contact 23v4. Relay L'4 switches on lines 13 to 1.6 by closing its contacts 13 v4, 14v4, 13v4, 16v4. When the relay chain A, B, C, D runs , these lines are scanned one after the other.

The game described above is repeated according to the number of lines connected. A further relay V must be provided for every four lines. After the drop of the last TI relay, which is not shown and should be designated with V ,, the lines are scanned anew, starting from the beginning; because the relay Vl is vx via the contact 9 1 turned on again. The already described game of the relay chains A to Di, H, R, N, V1 to V, 1 is repeated.

If the relay selector is to be put out of operation, opening the contact x causes the starting relay An to drop, whereby the relay Bn and all other relays are also returned to the rest position.

The embodiment according to FIG. 1 can be modified. This can be done, for example, as shown in FIG. The line groups are not summarized as in Fig. 1 in such a way that in each line group a group relay (V1 to V,) switches on an individual line and the line groups are scanned one after the other for the purpose of individual selection by a second relay group (A to D), but the group relays (V, to Vx) mark the line groups one after the other by connecting earth, whereby after marking a group in this the individual selection begins. The latter arrangement results in a greater number of relays to be scanned for a smaller number of lines to be scanned, since the relay chain A to D must be enlarged (in FIG. 2 by the relays E, F, G, H), but the relays are more expensive As a simple consideration shows, less for a larger number of lines to be scanned than in FIG. 1.

3 shows a further embodiment of the invention.

The operation of this arrangement is essentially the same as in Fig. 1, however, it differs from this in that it repeats expired relay chain the timing relay does not start again when the last relay of this relay chain has dropped out, but the expiry of the relay chain already starts when only some of the relays have dropped out. This will make the time which is required for scanning a large number of lines, is significant decreased.

The arrangement according to FIG. 3 comprises, as already mentioned, a relay chain of time relays, labeled A, B, C, D, E, F, G, H, and also two groups of relays h, to T128 and K1 to K28, finally a group of auxiliary relays, of which the relays U, W, 1bl are assigned to the relay group Uli to V., and the relays N, R, S are assigned to the relay group KI to K28. The auxiliary relay group W, M, U is in turn assigned to a part of the timing relay chain, namely the relays A, B, C, D and the relay group N, R, S is assigned to the rest of the timing relay group, namely the relays E, F, G, H.

224 lines can be scanned through the relays provided: The mode of operation of the arrangement is as follows: When the relay selector is put into operation, the relay An is excited by a contact x, which remains closed for the entire duration of the occupancy. The relay An closes a circuit for the relays TY and U on the one hand and for the relays R and S on the other hand: earth, contacts 84an, 86 bn, 87 bzz, winding of relay W, contact 94m, winding of relay U, battery, earth. In parallel with this circuit, the relays R and S are energized: earth, contacts 84 on, 86 bzz, 87 bu, winding of relay R, contact 92 tt, winding of. Relay: S, battery, earth. Next excitation of relay U responds to relay 1l1 in the following circuit: earth, contacts 66aia, 67 1c, 5o bn, winding of relay Vi, battery, earth. After energizing relay S, relay KI is energized in the following circuit: earth, contacts 66 on, 70 s, 71 bn, winding of relay KI, battery, earth. After energizing the relays U and S, the following circuit for the relay bit is closed: earth, contacts 66 on, 64s, 632z, winding of relay Bn, battery, earth.

After the relay bit has responded, relay Vi remains independent from the relay bit via its contact 52v1, the relay K1 is independent of the Relay bit via its contact 73 h, the relay V1 switches through its contacts i v1, 2vi, 3 v1, 4v1 in preparation for lines 1 to 4. Furthermore, this prepares Relay V1 by closing its contact 55 v1 a circuit for the relay V2 before. The relay ha switches by closing its contacts 5 h1, 6 hi, 7lei, 8 hl lines 5 to 8. Furthermore, the relay K prepares by closing its Contact 7q.lz, a circuit for the relay 1i2.

After relay Bai has responded, the following circuit for relay A, the first relay in the timing relay chain, is closed: earth, contacts 47 to 48 e or parallel contact 491t, winding of relay A, battery, earth. Relay A responds and switches on the second relay in the timing relay chain, relay B, through contact 40a. Relay B switches the third relay in the chain, relay G, through contact 41b; a. Relay C switches relay E through contact 42 c relay D, contact 43 d; Contact 44.e the relay F, contact 45 f the relay G and contact 46g the relay H. The relays A to H of the timing relay chain respond one after the other. The preparatory switched-on lines i to 8 are scanned one after the other: line i via contact 33 a, line 2 via contact 34; b, line 3 via contact 3 5 c, line 4 via contact 3 6 g1, line 5 via contact 37 e, line 6 via contact 38f; Line 7 scanned via contact ioi g, line 8 via contact 39h.

It should be switched on here that the relays W and U hold themselves initially after the response of the relay Bn via contact 992t and the relays R and S via contact 85 s.

After the response of the relay H of the timing relay chain, the relay A begins to drop out, because both contact 48e of the still energized relay E and contact 491a are open. When relay A drops out, contact 33 a opens and the scanning of line i is ended. When relay A drops out, the circuit for relay B is also opened. The opening of the contact 34 b ends the scanning of the line 3. The relays D, E, F, G, H drop out one after the other.

After the relay E drops out, the relay starts again a, since contact 48e is closed. So the relay chain starts here to expire again.

After relay B has dropped out, the following circuit for relay M is closed: earth, contacts ioo d, 98b, 96w, winding of relay 1y7, battery, earth. The relay 31 responds and interrupts the holding circuit of the relays U and W by opening its contact 94.m. The two relays drop out. Relay 11.T initially remains independent of relay W via its contact 972f2. Relay Bu remains independent of contact 63u via its contact 65 bn. After relay U has dropped out, the following circuit for relay h2 is closed: earth, contacts 66 on, 68u, 55v, winding of relay V2, battery, earth. The relay V2 binds itself independently of the relay Tal, which drops out shortly after the opening of the contact 67 ü , via its contact 56v2. Relay V2 also prepares a circuit for relay V3 via its contact 53v1 and finally relay h2 switches on lines g to 12 by closing its contacts 9v2, 10V2, ii v2 and i2 v2, so that the timing relay chain is already there already after the relay E has recently started to expire, these lines can be scanned.

After the relay F of the timing relay chain has dropped out, the following circuit for relay N is closed: earth, contact, te 881a, 89f, gor, winding of relay N, battery, earth. The relay N responds and initially holds on to his. Contact 932t in a hold circuit independent of relay R. Relay R drops just like relay S shortly thereafter, since the hold circuit of the two last-mentioned relays is interrupted by contact 922t. After the relay S drops out, at which contact los opens and contact 69s is closed, relay K1 drops out with a delay. During this time the relay K2 is energized in the following circuit: earth, contacts 66 on, 69 s, 74 3l, winding of relay K2, battery, earth, relay K2 binds via its contact 75 k .. By closing its contact 76h2 prepares there is a circuit for the relay 1 (3 in front, and finally, by closing the contacts 13k2, 14k2, 15k2, 1 6 k2, the lines 1 3 to 16 are switched on in preparation. The scanning of these lines takes place during the second run of the timing relay chain A to H, which takes place in the manner already described: As soon as the relay H responds as the last relay of the timing relay chain on the second run, the relay A again begins to drop out. As already described, the relays drop out one after the other and thus end the scanning of the lines 9 until 16.

It should also be added that the hold circuit of the relay M, which how described, after the first run, when relay B drops out, it would be closed, is already opened again when relay D drops. So is the holding circle of relay N, which is closed after the first cycle when relay F drops was opened again as soon as the relay H drops out for the first time.

If after the second run the relays of the timing relay chain fall again, after the fall of relay B, relay U is again energized in the following circuit: earth, contacts ioo d, 98 b, 95w, 94m, winding of relay U, battery ; Earth. Relay U responds and remains in series with relay W via its contact 992z. If relay D has dropped out and the short circuit for relay W is open, this relay in series with relay U also responds. The relay U interrupts the circuit of the relay V2 by opening its contact 682t and, through its contact 67u, closes the following circuit for the relay, V3: earth, contacts 66 , 67 it, 53v2, \ Vicklung of the relay TV ", battery, earth. Relay ZTg responds and remains independent of relay V2, which drops out shortly thereafter, via its contact 54v3. Furthermore, relay V3 prepares a circuit for relay V4 by closing its contact 57V3. Finally relay V3 switches by closing its contacts 17V3 , 18v "19v3,: 20V3 in preparation for the lines 17 to 2o. These lines are scanned one after the other by the relays A to D, which, as already described, begin to run again after the relay D has dropped out. After relay F has dropped after the second cycle of the timing relay chain, the following circuit for relay S is closed again: earth, contacts 88h, 89f, 91r, 92% 2, winding of relay S, battery, earth. The relay S responds and holds on to his. Contact 85 s in series with relay R, which is also energized after relay H has dropped out in this circuit. After the relay has responded. S contact is opened for 69 s and the circuit for relay K2 is interrupted. During the release time of relay I12, relay Kg is energized via contact los: earth, contacts 66an, los, 76h2, winding of relay Kg, battery, earth. The relay Ks holds itself via its contact 771z3, furthermore it prepares a circuit for relay K4 by closing its contact 7 8 h3, and finally relay Kg switches the lines 21 by closing its contacts 2, i 1z3, 22k3, 23 hs, 24h3 to 2 ¢ preparatory .ein, which are scanned during the third pass of the relays E to H.

The interaction between relay groups A to H described above; l19, W; U, V1 to V28; N, R, S; l ('1 to I @ 2g is repeated until all 224 lines have been scanned. Once this has been done, scanning starts from the beginning in that relays I28 and I128 switch on relays V1 and K1 again. Relay V1 becomes switched on via contact 5 i v..s, relay K1 via contact 721z28.

The relay selector is triggered when contact x opens, causing relay A12 to drop out. The fall of the relay An also causes the fall of the relay Bat and thus the interruption of the starting circuit for the relay A. When relay An drops out, the excitation and hold circuits of relay groups Z 'and K and relay groups W, U or R, S are interrupted.

Claims (3)

PATENT CLAIMS: i. Circuit arrangement for relay wiililer in telephone systems in which individual lines are scanned one after the other within a line group, characterized in that several groups of relays (V1 to TV ", K1 to K" A to H) are assigned to the relay selector, which during the Occupancy duration of the selector automatically scan the lines used to distribute a switching process (e.g. checking) to different connection devices one after the other in such a way that alternately through one part (V1 to V., K1 to K ") of the relay the successive activation of the various line groups and the other part (A to H) of the relay initiates the successive scanning of the individual lines within a line group. 2. Circuit arrangement according to claim i, characterized in that the successive switching on of the line groups by a relay chain (V1 to h,) (group relay) and the scanning of the individual lines by a further relay chain (Ab, $, C, D) ( Timing relay) takes place, of which the first relay chain only comes into operation once while all lines are being scanned, while the second relay chain is repeated repeatedly. 3. Circuit arrangement according to claim 2, characterized in that the relay chain (A, B, C, D) running repeatedly by means of a group of auxiliary relays (H, R, N) controls the operation of the first relay chain (V1 to V ") in such a way that that after each expiry of the timing relay chain, one relay in the group relay chain is switched off and the next relay in this chain is switched on 2 ¢ etc.) by two groups of relay chains (V1 to V2s, K1 to K2s) and the scanning of the individual lines within a line group by another relay chain that runs repeatedly (timing relays A to H), which is carried out with the help of two groups of auxiliary relays ( 31, U, W or N, R, S) controls the first two relay groups (group relays) (Fig.3). 5. Circuit arrangement according to claim ¢ ,, characterized in that the relays of the repeatedly running R elaiskette (A to H) control themselves in such a way that after a part of the chain (e.g. B. Relays A to E) a new sequence of the relay chain begins. 6. Circuit arrangement according to claim ¢ and 5, characterized in that the one group of auxiliary relays (M, W, U) through the one. Part of the repetitive relay chain (A to E) is controlled; after which the relay chain begins to run again, and the other group of auxiliary relays (N; R, S) is controlled by the remaining relays in the timing relay chain (F to H). 7. Circuit arrangement according to claim 6, characterized in that each group of auxiliary relays controls a specific, assigned group of group relays (hl to T28 or KI to K28) in such a way that after each corresponding part of the timing relay chain, a group relay of the corresponding one alternates The relay chain is switched on one after the other.