DES0037972MA - - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY

Registration date: March 4, 1954. Advertised on July 26, 1956

GERMAN PATENT OFFICE

The invention is based on the task of reducing the cost of expensive storage means for Storage facilities in telecommunications, in particular Telephone systems to reduce. In which the switching orders in. Form of multi-digit. Dual-, numbers are stored in groups of storage elements, their number of digits corresponds to the binary number. The invention solves this. Task by having the same storage device as storage means for ReJais switching orders to be repeatedly stored, as storage means on the other hand, capacitors are assigned for switching jobs that are only to be saved once.

The circuit arrangement according to the invention allows the formation of memory devices, which the same requirements as the known, consistently equipped with relays as storage means Storage devices, meet, but in contrast to these known. Facilities the cost of storage relays is reduced to the absolutely necessary level and this Relays as far as possible are replaced by capacitors as much cheaper storage means. According to a further development of the invention is for a group of storage relays or storage capacitors is provided for each switching order.

609 576/168

S 37972 VIHa / 21a ³

· 'Tere saving on switching means is achieved in that the same selection device is used for both the groups of storage relays or storage capacitors for both storage and withdrawal turns on gradually one after the other and that the memory states of the memory relays and the Storage capacitors from the same switching means be evaluated.

Fig. Ι shows an embodiment of the invention, Circuit arrangement and consists of the sub-figures ιa, ιb and ic;

Fig. 2 indicates how the parts of Fig. Ι in context are to be read;

Fig. 3 shows a conversion scheme that simultaneously is to be read as a working diagram for certain switching means in Fig. ι.

The memory device shown in FIG. 1 is intended to accommodate up to eight switching orders, of which the first two are repeated, whereas the following are only to be saved once. The switching orders are expressed by numbers, which in the present exemplary embodiment are not stored in and out in their decadic form, but in dual form.

It is provided that the binary numbers to be stored in and out, to. can have up to four digits. 3 shows a conversion scheme in which the binary numbers that are thus possible and the decadic numbers corresponding to them are plotted. The ones by the numbers. 1 to 10 or the corresponding, binary numbers, expressed switching orders can refer, for example, to the setting of voters in 'decadic dialing switching systems, while the numbers 11 to 15 which are not considered for a voter setting, special ¹ , switching orders that influence the establishment of a connection can express.

The memory device is occupied via the, input 5 (Fig. Ι a.) By energizing the relay C- with the contacts 1 c and 2 c . The storage takes place via the inputs ι to 4 leading to the storage relays I to IV. The operating states of these relays can be seen in FIG the activation of the relevant relay can be understood.

It is assumed that the binary number 1100 corresponding to the number 12 is stored in the first place. Relay III with contacts 9-3 to 11-3 and relay IV with contacts 12-4 to 14-4 then respond. The relay I with the contacts. 3-1 to 5-1 and II with the contacts. 6-2 to 8-2 are not switched on., Contacts 9-3 and 12-4 switch on relay Zi with contacts 15x1 and 16 ι. Contact 15x1 switches on relay X2 with contacts 17 χ 2 to 20x2. Contact 17x2 closes one. Holding circuit for relay X 2, which is currently via contacts 4-1 and 7-2. From Fig. 3 it can be seen that this holding circuit, insofar as it is dependent on the contacts of the storage relay, is maintained as long as the binary number corresponding to the number 15 is not stored in. In this case the holding circuit is interrupted because the contacts 4-1, 7-2, 10-3 and 13-4 of the storage relays are open at the same time. Contact 18x2 closes the circuit for storage.

The group of storage relays Si to S 4 is provided for receiving the first switching order. In the present case, relays 5 "3 with contact 23 j 3 and S 4 with contact 24 j4 are switched on from these:

S3, 29m 1 ... J2mj, 83 ze / 3, 11-3

^lg '*' ^ 4,3OWI ... 73W7 ,!
18x2, 11, i4Sr (Fig. Ia), +.

(.ze / 3, ΙΊ-4 '

Relay ^ 3 binds itself via its, contact 23 ί 3, relay S4 via its contact 24s4. The working states of the Rielais Si to ^ 4 agree with those of the corresponding storage relays I to IV and can therefore also be taken from ^ of FIG.

At the end of the storage, the storage relays and subsequently relay X1 drop out again. The relay H 1 with the contacts 25 h 1 and 26 h ι is switched on via the contacts 19x2, 16x1 and 40 h 2. Contact 25 h 1 prepares the activation of relay H2 . Contact 26 hi switches the relay selector consisting of the relays M τ to M 7 for the storage and withdrawal by the. The circuit prepared by contact 20x2 for the winding T of the relay Mx with the, contacts, 27 m 1 to 31 ml and 147 ml closes.

Contacts 27 m 1 to 30 «1 provide the group of memory relays E 1 to .E 4 for storing the following switching order. Let this be expressed by the binary number 0011 corresponding to the number 3. According to Fig. 3, the relays I and II are energized. Relay X 1 is switched on again via contacts 3-1 and 6-2. His contact 16 χ ι removes the short circuit of the winding I of the relay H 2 with the contacts 40 h 2 to 42 h 2 (Fig. Ι c). Relay H 2 responds in addition to relay H 1. The storage relays E 1 and E 2 with contacts 32 ^ 1 and 33 e 1 or 34 e 2 and 35 ^ 2 are switched on:

.-p. ,. - egg, 27ml. . . 70W7, 81 ze / 3, 5-1

Ez, 28ml ... yimy, 82203, 8-2 ' τ% χ2, ii, 145 ^r ( Fig.ia), +.

They bind via their contacts 32 e 1 and 34 c 2. The contacts 33 ^ 1 and 35 ^ 2 switch on the relay G with the contacts 48 g and 49 g (Fig. 1 a).

The storage relays and subsequently relay Xi drop out again. Contact 16 χ ι drops the relay H 1, whose switch-on circuit is separated by contact 40 h 2 . Relay H 2 continues to be held via its winding II. Contact 26 hl closes the circuit prepared by contact 31ml for winding II of relay M1 and I of relay M 2 with contacts 43 m2 to 47m2 and 148m2 (Fig. Ic).

576/168

S 37972 VIIIal21 a ^s

The contacts 43 m2 to φνη, 2 represent the group of storage capacitors. Co 11 to Co 14 for storing the following. Switching order ready. Let this be expressed by the binary number corresponding to the number 8, iooo. According to FIG. 3, only relay IV is energized. Contact 12-4 switches the relay Xi on again, contact 16x1 interrupts the holding circuit for the winding II of the relay H 2, whose contact 40 h 2 prepares the re-switching of the relay H 1 when the relay X1 drops out. The storage capacitor Co 14 is charged via:

- (Fig. Ib), Co 14, resistance, φηΐ2 ... 73 w 7.84w 3.14-4, i8 χ 2, 11.145 r (Fig. 1 a), +.

The charge states of the storage capacitors match the working states of the corresponding ones; Storage relay match and can therefore also be seen in FIG. 3 when the Dual digit »o« as a symbol for not charging and the dual digit »1« as a symbol for charging the corresponding storage capacitor can be viewed,

After relay IV, relay X 1 drops out again. ■ His contact 16 χ ι switches the relay H1 on again. Its contact 26 hl closes the circuit prepared by contact 47 m 2 for winding II of relay M 2 and winding I of relay M 3 with contacts Sow3 to 54m3. Contacts 50m3 to 53 w3 represent the next group of storage capacitors. Co 21 to Co 24 ready for the storage of the following S cha ita ft rags.

After further switching orders have been saved, the contacts 70 m 7 to

. 73 m 7 of the relay M 7, the last group of Einspeicherkondensatoiren Co 61 to Co 64 have been provided. On. last digit becomes a. the end of the storage and retrieval characteristic switching task is issued, which is expressed by the binary number corresponding to the number 15 in. The relays I to IV are now switched on at the same time and the storage capacitors Co 61 to Co 64 are charged, relay X 2 drops out because its holding circuit, as already mentioned, is disconnected, its contact 20x2 switches the last energized windings II of the relay M 6 and I of relay M 7 off. The relay he chooses is now in the rest position again. The opening contact \% x2 prevents any further influence on the memory elements.

The stored in the relay 5 "1 to £" 4 and E 1 to 4 £ first two switching orders can be the premise of destaged repeated, the üsf in the capacitors Co Co 11 to 14th saved only once. The withdrawal is initiated by energizing the relays W and Ws via the input 6 of the storage device. The windings of these relays are dimensioned so that the relay Ws can be excited either alone or together with the relay W by current grading. In the first case, the withdrawal of the in the relay, in the second case that in the. Capacitors stored switching orders.

The first case will be considered first. By a small current, which does not allow the relay W to respond, only the relay Ws with the contacts y ^ ws and 75 Ws is temporarily excited. Contact 74 «/.? switches on relay Wx with contacts 76 w 1 to 80 «) 1, contact 76 wi closes a holding circuit for relay Wi. When the relay Ws drops out again, the relay W 3 with the contacts 81 ze / 3 to 85 «; 3 switched on. The contacts 81 ze / 3 to 84ze / 3 switch the. Windings I of evaluation relays K1 to K 4, the first group of storage relays 5 "1 to 5" 4. In. This group has been saved by a switching order expressed by the binary number 1100, so the relay i? 3 and K 4 with contacts 94 k 3 to 97 ^ 3 and 98 ^ 4 to 107 £ 4 to:

- (Fig ib) ^ 31.83 ^ 3.72 ^ 7 ... 29W 1.23 ^ 3

^h K 4L84W3,73 my ... 30mi, 24 ^ 4 '146 r, 2c, +. '

The evaluation relays bind themselves via their windings II and their contacts 94 k 3 or 98 k 4 in a holding circuit prepared by contact 79 w 1. The working state of the evaluation relay corresponds to that of the storage relay or, as will be shown later, with the charge state of the storage capacitors and can therefore also be seen in FIG.

Via the contacts 75 ws, 78 wi, 97 £ 3/101 £ 4, 125 & / 130/2 and 102 «, the self-interrupting pulse relay / with the contacts 102 i to 108 i is switched on. Contact 103 »switches on relay V with contacts 109 ν and now. Contact 109 ν closes a holding circuit for relay V. Contacts 104 i and 105 ″ serve to advance a counting chain consisting of relays A, B, D, Fi, F2 and I ^{7 3.} Contact 106 i sends impulses through output 7 of the memory device, which is switched through by contact 49 g.

After the first impulse, the relay A with the contacts 111 α to 115 a · responds via the contacts oz /, 104 «and ΐΐό / ΐ. Contact 1140 · prepares the closing of winding I of relay Fi. before. Relay · Fι with the contacts 116 to 118/1 fi responds as soon as the second pulse contact 104, "the short end of his winding I revokes it. After the second pulse, relay A drops out again, there. its switch-on circuit at contact 116/1 is interrupted. The third pulse causes the relay F ι to drop out again, since contact 104 i the. iao holding circuit for its winding II interrupted. After the third impulse, relay A responds again and the processes are repeated.

After the second pulse, relay B with contacts 119 & to 125 & is switched on. Contact 119 & prepares winding I to be switched on

609 576/168

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of relay F 2. Relay F 2 with contacts 126/2 to 131/2 responds as soon as they are actuated at the same time with the fourth impulse. Contacts 1054 ″ and 115 h cancel the short circuit of its winding I.

Contact 106 i sends out four impulses corresponding to the four digits of the binary number expressing the switching order for each switching order saved. Contact 137M of relay U marked across the output of the memory device for each of these four. Impulse the stored, value. Since the contacts 96 k 3 and 100/24 are open, the relay U does not respond when the first and second pulses are transmitted. At the third impulse relay U speaks over

- (Fig. Ia), U, 122b, ii2a, 92 ^ 2, 85 ^ 3, 12, ygwi (Fig. Rb), 131/2/108? ', +

and at the fourth impulse over

-, U, 122b, 112a, 88 & I, 85W3, 12, 79OTI, io8i, +.

Relay U therefore responds to the place value "0" and not to the place value: "1" of the binary number concerned. Its: working states can therefore also be taken from FIG. 3.

After the fourth pulse, winding II of relay F 1 via contacts 116/1, 104t and nov and winding II of relay F2 via contacts 126/2, 1052/1150 ·, iijfx, now are switched on. Relay B has tied itself via its winding II and via contacts 123 b, ic, 97 ^ 3/101 ^ 4, 78 wi and 75Wi. Contact 130/2 interrupts the switch-on circuit for the pulse relay / with the fourth pulse, after contact 125 b has already opened after the second pulse. After the fourth pulse, contact 108 i interrupts the holding circuit for windings II of evaluation relays if 3 and. K 4. These relays would, however, remain excited via the contacts 83 w 3 and 84 W3 and the marking and holding circuits of the storage relays S 3 and S 4 . To avoid this, contact 129/2 switches off relay W- $ with the fourth pulse. The contacts 83 ^ 3 and 84 w 3 then interrupt the marking circuits for the relays K 3 and K 4, which now drop out. The Kontakte97 k 3 and, 104k4 interrupt, holding circuit for the winding of the relay B. II relay B is released. The relay D with the contacts 132 d and 133 d is switched on via the contacts 134/3, 120b, 127/2 and ττον. Contact 132 d prepares the switch-on

the winding I of the relay F 2> . Contact 133 a switches on the relay selector (FIG. 1 c) by closing the circuit for relay M1 prepared at contact 80wi. The relay W 3 is now switched on again: via contacts 136/3, 147 m i, yywi and 75 ws.

Relay M has switched on the group of S ρ ei rather relays E τ to E 4 , in which a switching order expressed by the binary number 0011 has been stored. After the relay
accordingly, the evaluation relays K 1 and K 2 respond to contacts 86 k 1 to 89 £ 1 and 90 k 2 to 93 £ 2, respectively:

_. Ki I, Siw2,7omy .. .27ml, 32 * 71

146 /, 2c,

K 21,

W7 ... 28ml, 34 ^ 2 '

They bind themselves in the holding circuit closed again by contact 124b. The pulse relay / is switched on again via the contacts 89 k 1 and 93 k 2 and the contact 125 & which is closed again. Four more impulses are given. With the first and second impulse the relay U responds, and closes its. Contact 137 u. With the third and fourth impulse, relay U remains in the rest position, since contacts 88 k 1 and 92 ^ 2 are open. The relays A, B, F1 and F 2 work during the transmission of this series of pulses, as already described.

After the second pulse, relay F ^ with contacts 134/3 to 136/3 responds, since contact 120 & removes the short circuit of its winding I. Relay W '3 remains turned on 129/2 from that moment on the contact. The relay F 2 was switched off again at the first impulse through contact 117/1, since the holding winding II of relay Fi was switched off through contact 104 ». Relay F 2 responds again with the fourth impulse. Contact 130/2 switches off the pulse relay 7, since contact 125 b was opened again after the second pulse. Contact 129/2 switches the relay Wt off again. After the fourth. Impulse drops the Rblais Wi , since the contacts 107 «, 11 ία, I28f2 and 135/3 are open at the same time, and. therefore, holding circuit is disconnected. Contact 77 toi prevents the relay W3 from being switched on again. Contact 78 »1 disconnects the holding circuit of relay V. Contact 79 w 1 switches off the holding windings II of the relays K 1 and K2 . The windings I of these relays have already been switched off by the contacts 81W3 and 82TO3. Contact i8owi switches off the relay selector (Fig. Ic), which returns to the rest position. Contact " ¹ no ν switches off the relays B, D, Fi F 2 and F 3, which are still excited after the fourth pulse. The saving of the switching orders stored in the two groups of relays Si to F 4 and Ei to £ 4 is now complete. As is readily apparent, it can be repeated as often as desired by switching on the relay Ws again.

It is now assumed that the retrieval of the switching orders stored in the capacitors is requested. For this purpose, the low-resistance relay W with contact 138 to is temporarily excited via input 6 by applying a correspondingly strong current. Relay Ws also responds in this case, but now only its contact 75 ws is effective. Contact 138 to switches the relay W2, with the. Contacts 139W2 to 143TO2. Contact 139W2 closes a holding circuit for relay W2. Contact

5T6 / 168

S 37972 VIIIal21a ³

141 w 2 switches on the windings, I of relay M 2 and II of relay M1 . About the contacts 43 W 2 to 46 m 2, the first group of the storage condensate, Co 11 to Co 14 for the. 5 storage provided. After the relay Ws has dropped out, the relay W3 is switched on via contacts 148 ^ 2, 140W2 and 75Wi.

A switching order corresponding to the binary number 1000 has been stored in the first capacitor group. Only the capacitor Co 14 was charged in the process. After the response of the relay W 3, this capacitor discharges through the winding I of the relay K 4. Relay K 4 responds and binds itself through its winding II and the contacts 98 ^ 4, 143 w 2, 1246/131/2. In order to ensure reliable response of the relays K1 to K 4 under the influence of the capacitor discharges, the holding windings of these relays are pre-excited via resistors Wi .

. Contact ioife4 switches the pulse relay / on, Four pulses are sent out in the manner already described. According to the job

. value »i« does not respond to relay U with the first impulse, but does respond to the second to fourth impulse according to its value »o«. After the fourth pulse, relay if 4 drops out, since contacts 108 i, 124 & and 131/2 in its holding circuit are open at the same time. As already described, the relay B , which was held via its winding II, then drops out. Contact 120 & switches on relay D. Contact 133 rf advances the relay selector by preparing the through contacts 47'w 2 and 142102. Circuit for windings I of relay M 3 and II of relay M 2 closes. The next group of storage capacitors Co 21 to Co 24 is made available for withdrawal via the contacts 50 m 3 to 53 ^ 3. After the withdrawal, which proceeds in the manner already described, relay D drops out again and switches the relay selector on by closing the circuit prepared by contact 54m 3 for windings I of relay M 4 and II of relay M 3 with contact 133 d .

Finally, the group of storage capacitors Co 61 to Co 64 should be connected via the contacts yomy to 73 m 7. In, this is the switching order that marks the end of the storage and retrieval and is expressed by the binary number 1111. Relays Ki to K 4 therefore respond. While this switching order is being saved, relay H 2 responds after the second pulse:

- (Fig. Ic), # 211.15 / 99 * 4 (Fig. Ib), 95 ^ 3, 91 £ 2, 87fei, 13, 121 & (Fig.ia), 118/1, +.

Relay H 2 binds via its contact 41/12 and the. Contact 110 ν (Fig. 1 a). After the fourth pulse, relays K1 to K 4 and subsequently relay B drop out. Contact 12,1b interrupts the holding circuit for relay H 2 and switches on relay R with contacts 144 r to 146 r and 149 r during the release time of this relay:.

- (Fig. La), R, 42h2, I2ib, ii8fi, +.

Relay R binds via his, contact 144 r. Contact 145 r switches off relay JF 2. Contact 146 r switches off the storage relay. After relay W 2 , relay V drops out. Contact τ 10 ν switches the relay F 1 off. As a result, relay R drops out. The memory device is thus in the rest position again and can be occupied again after the input 5 has been switched through again by contact 149 r.

Claims (9)

Patent claims: 1. Circuit arrangement for storage devices in telecommunications, in particular telephone systems, in which the switching orders in the form of multi-digit binary numbers in groups of storage elements - and are stored, the number of which corresponds to the number of digits of the binary number, characterized in that the same storage device as Storage means for switching orders to be repeatedly stored relays (Si to S 4, Ei to E 4), whereas capacitors (Con to Co 14, etc.) are assigned as storage means for switching orders to be stored only once. 2. Circuit arrangement according to claim 1, characterized in that a group of memory relays for each switching order or storage capacitors is provided. 3. Circuit arrangement according to claim 2, characterized in that the same selection device (relay selector in, Fig. 1 c) both the groups of storage relays and storage relays, respectively, for injection and withdrawal Turns on storage capacitors one after the other. 4. Circuit arrangement according to claim 1, characterized in that the storage states of the storage relays and the storage capacitors are evaluated by the same switching means (Ki to K4). 5. Circuit arrangement according to claim 4, characterized in that the contacts the storage relay on, the evaluation relay on, -placed Marking potentials and the stored charging potentials of the storage capacitors are equal to each other. 6. Circuit arrangement according to claim 5, characterized in that the evaluation relays (Ki to K 4) are each pre-excited via a winding (if ι II to i? "4ll) in a fault current circuit and via a second winding (if 11 to if 41 ) rather capacitors (capacitor group Coil to Co 14 ..., Co 61 to Co 64) are started by the storage in a discharge circuit free of shunts. 7. Circuit arrangement according to claim 5, characterized in that the holding circuits of the closed during storage Storage relay also part of the 609 576/168 S 37972 VIII a / 21 a ^s these relays are controlled marking circuits. 8. Circuit arrangement mach claim 5, characterized by, Schaltmiftel (W 3), which of the. Storage relay. dominated Miarkien circuits for the evaluation relays; after each accumulation, and by switching means (B), which allow the connection of a group of storage relays only after all the evaluation relays switched on when the previous group of storage relays was withdrawn. 9. The circuit arrangement according to claim 6, characterized in that the evaluation relays are kept energized after their caused by the capacitor shock response over the faulty circuit. Wherein a separate relay contact (86 ki, 90 k 2, 94 3, 98 ^ 4) has a Fault current circuit Hegenden series resistor (Wi) switches off, preferably short-circuits. Considered publications:
German patent specification No. 881 369. 1 sheet of drawings, © 605576/165 7.56