DE1512890C - Circuit arrangement for telecommunications, in particular telephone switching systems, with a number of relay devices - Google Patents

Description

The invention relates to a circuit arrangement for telecommunications, in particular telephone switching systems, with a number of relay devices that contain a plurality of electromagnetic relays and to which includes a marker having a marker conductor for each relay device, with a choice

correspond to a specific relay device

Marking conductor is provided with a marking by the marker, and the circuit arrangement a control device common to all relay devices contains which for each relay in an arbitrary Relay device provided with two control conductors, each control conductor for several to be different.

Relay devices belonging to relays is used. Such a system of relay devices w Among other things, it is used in self-connecting telephones with central control. As an example, let ι Control of the transmitter mentioned, which Koppe the connection lines with the subscriber lines these transmitters each containing a number of relays for different purposes.

The aim of the invention is to create a new Schaltungsano voltage in which a significant association chung is achieved.

The circuit arrangement according to the invention is c characterized in that each marker conductor in c associated relay device several times each ü! Decoupling rectifier belongs to each relay: first and second nodes are connected and that the excitation winding of each relay is connected between the first node and the z \\ th node connected to the control conductor via a decoupling rectifier, while the shark winding of each relay is connected in a circuit manner 7 . See the second node and a third node, which is verb via a make contact ι relay with a point of constant potential, and that a resistor is connected to the first node of each I lais, the other end of which to receive a switch-on potential 1 a second control conductor is connected.

The invention and its advantages will now become apparent from an Ausl'i shown in the drawing rungsbeispie's explained in more detail.

The figure shows two of the relay devices Wi and W2 available in any number in the practical version. These relay devices are e.g. the transmitter of a self-connecting telephony device. Each relay device contains several relays, which are B. So-called Magneiziingenre: (Reed relay). In the figure are in each Relaisvorri. The windings of three relays and one working contact of jcd relays are shown. In the Voith device Wi, the windings of the relays Kw, / Ci 2 1; / Ci i with the associated contacts k \ 1, kt2 and k \ i 1: the windings of the relays / / C> 2 and K21 with the associated contacts ks \, and k2i are shown in the device Wi. Each of these windings is included in a circuit, hereinafter referred to as the control circuit and denoted by T. The first control circuits differ in their numbering by their two-digit indices, of which the decade corresponds to the index of the relay device, and the second index denotes the current number of the control circuit in the device - hereinafter referred to as the rank number. The control circuits are identical to one another, so that only one control circuit will be described. Control circuit Tn is chosen as an example. The figure shows we:

Another marker M and a common control device SS. The marker M reveals as many M kierleiter as there are relay devices, in this case those belonging to the device Wi:

15 12 89U

Marking conductor Mi and the marking conductor Mi belonging to the device VV2 . The marking conductors are normally connected to earth via associated marking contacts m \ and / m. The common control circuit SS contains a number of pairs of control conductors which coincide in number with the number of relays present in the relay devices, and in this case it contains the control conductors U \ and Vi belonging to the control circuits with the rank number 1, which are associated with the control circuits the control conductors Ui and Vi belonging to rank number 2 and the control conductors Ui and V3 belonging to the control circuits with rank number 3. The control conductors Vi, Vi and Vx, hereinafter referred to as the "first control conductor", are normally connected to earth via their associated control contacts vi, \ n and V3, and the control conductors U \, Ui and Ui, hereinafter referred to as the "second control conductor", can be connected to a negative potential via their associated control contacts ui, ui and m.

The control circuit Ti 1 will now be described in more detail. The marking conductor Mi belonging to the device Wi lies above the marking conductor IMi and a rectifier 4Di 1 at a node 1 of a resistor \ Rw and a rectifier 3Dn. The other end of the resistor \ R \\ leads to the control conductor U \. The forward direction of the rectifier 4Di 1 is determined in such a way that the marker line Mi has ground potential and the control conductor U \ has a negative potential, the rectifier carries current and thus node 1 is connected to ground potential. The other connection side of the rectifier 3Di 1 is connected to a node 2 to which the winding / Cn and one pole of the normally open contact k \ 1 are also connected. The second pole of the contact kw is connected to a negative potential via a resistor 2Rw. The other end of the winding / Cn is at a node 3 of the rectifier IDn and the rectifier 2Dn. The other connection side of the rectifier IDn is connected to the control conductor Vi and the other connection side of the rectifier 2Dn is connected to the marking conductor Mi via the marking conductor 2Mi. The transmission directions of the rectifiers IDn, 2Dn and 3Dn are identical to one another and are set in such a way that, when the control conductor Vi or the marking conductor Mi has ground potential, the rectifier IDn or 2Dn supplies current to the node 1 via the winding Kn and the rectifier 3Dn, when the latter has a negative potential, or through the winding Kw, the normally open contact ku u, nd the resistor 2R \\ supplies a current to a point of negative potential when the contact / cn is closed. The control circuits Ti 2 and Tn are connected to the marking conductors IMi and 2Mi in the same way as the control circuit Tn, and the connection to the control conductors Ui and Vi or Ui and Vj is made in a completely analogous manner. In the device Wi , the control circuits T21, Tn and Tu are connected in an analogous manner to the marking conductors IM2 and 2M2 and the connection to the control conductors is established in a corresponding manner. The rectifiers in the control circuits cause a complete decoupling of all control circuits that are connected to the same marking or control conductors.

To switch on a relay in a relay device, the marking conductor in question is disconnected from earth in the marker M and the second control conductor in question is connected to a negative potential in the common control circuit SS. As an example, consider the relay Ku in the device Wi. The marker contact / 771 is opened in the marker M and the control contact ui is closed in the common control circuit SS. This closes the following excitation circuit: negative potential, contact ui, conductor U \, resistance XRw, rectifier 3Dri, winding Kw, rectifier IDn, conductor Vi, contact vi, earth. This excitation current closes the contact k \\. The contact kw connects the node 2 directly via the resistor 2Rw to a point of negative potential, whereby the relay continues to meet the holding conditions after the control contact ui has opened. The holding circuit is as follows: earth, contact vi, conductor Vi, rectifier IDn, winding Kw, contact kw. Resistance 2Rw, negative potential. After closing the marker contact mi, the alternative is the holding circuit: earth, contact / 771, conductor Mt, conductor 2Mi, rectifier 2Dn and further via the aforementioned holding circuit to the point of negative potential. If, after the relay Kw has been picked up, the contact mi is first closed and then the contact u \ is opened, the relay Kw is first held via the alternative holding circuit and then via the two holding circuits. The excitation circuit mentioned is formed because the marking conductor Mi is disconnected from earth. In the opposite case, in which the marking conductor Mi is connected to earth, when the control contact ui is closed, a current flows through the rectifier 4Dn, which keeps the node 1 at earth potential. When the relay Kw is not picked up, both ends of the winding Kw are at ground potential and the relay cannot change state. However, if the relay Kw is picked up and it is held via the normally open contact kw , the rectifier 3Dn is blocked by the ground potential of the node 1 for the negative potential of the node 2 and the holding conditions for the relay / Cn are still met. If other relays are also attracted in the device W \ when the relay Kn is energized, the latter remain held via the associated first control conductors, which are connected to earth in the common control device SS.

After switching off a relay in a relay device, which will again be described, for example, for the relay Kw in the device Wi, the marker contact / JJt is opened in the marker M, and the control contact vi is also opened in the common control device SS. As a result, both the holding circuit via the control conductor Vi and the alternative holding circuit via the marking conductor Mi are interrupted, as a result of which the relay / Cn drops out. If other relays besides the relay / Cn are picked up in the device Wi, the latter remain, just as when the relay Kw is switched on, held via the associated first control conductors which are connected to earth in the common control device SS. If, in addition to the relay / Cn, other relays of the relays whose control circuits are connected to the control conductor Vi are attracted, the latter remain held by the associated marking conductors, which are earthed in the marker Man.

In the apparatus described above, it is important that there be only one marker contact for each relay device is required, which is effective both when switching on and when switching off a relay in the associated relay device. This will make the effort for the one needed to mark the relay devices Marker almost halved. This saving

is achieved through the double action of the contacts. Each marker contact has a double function, namely it acts as a blocking contact, whereby the switching on of a relay in the associated relay device is prevented, and as a holding contact for the relays that are already picked up, whereby the switching off of an activated relay is avoided. By opening the marker contact, both the prohibition to switch on and the prohibition to switch off a relay are removed, and as a result the common control device SS can bring about a desired change of state (switch on or switch off) in the marked relay device. The double effect of the marker contact is illustrated by the following process: If, after switching on a relay, the marker contact concerned is closed before the negative potential of the second control conductor in question has been eliminated, the excitation circuit is interrupted by the earth potential at node 1 and, at the same time, a holding circuit via the same marker contact , which causes the change in potential of the node 1, formed.

1 sheet of drawings

Claims (4)

Patent claims: 1. Circuit arrangement for telecommunications, in particular telephone exchanges, with a number of relay devices which contain a plurality of electromagnetic relays and to which a marker belongs, which has a marker conductor for each relay device, the corresponding marker conductor from the marker with a marker for selecting a specific relay device is provided, and where 'the circuit arrangement contains a control device common to all relay devices, which is provided with two control conductors for each relay in any relay device, each control conductor being used for several relays belonging to different relay devices, characterized in that each marking conductor (M \) in the associated relay device (W \) is connected several times via decoupling rectifiers (4 £> ii or 2Dw) to each relay (/ Cn, K12. Ku) associated first and second nodes (1 or 3) and that the excitation winding j Each relay (Kw) is connected between its first node (1) and the second node (3) connected to the control conductor (V \) via a decoupling rectifier (IDn), while the holding winding of each relay is connected between the second node (3) and a third node (2) is connected via a normally open contact (k \\) of the relay to a point of constant potential, and that a resistor (IÄ11) is connected to the first node (1) of each relay, the other end of which is connected is connected to a second control conductor (U \) to receive a switch-on potential. 2. Circuit arrangement according to claim 1, characterized in that the first node (1) Each relay is connected to the third node (2) via a decoupling rectifier (3Dn) and each relay with its winding is included in the circuit, the winding is connected between the associated second node (3) and the third node (2). 3. Circuit arrangement according to claim 1 or 2, characterized in that for actuating the Marking and control conductors normally closed contacts are provided, which in the closed state a solid Apply potential to the relevant conductors. > 4. Circuit arrangement according to claim 1, 2 or 3, characterized in that the first nodes the relay via the nodes separately assigned resistors to the second control conductor are connected, and that marking contacts are provided for actuating the second control conductor which, when closed, apply a switch-on potential to the relevant conductor.