DE1800950B2 - Coupling network for telecommunication exchanges, in particular for telephone exchanges, with line holding wires - Google Patents

Description

As is well known, in the switching network of telecommunications switching, in particular telephone exchanges, connection paths that lead to contact addresses inserted setting means have been switched through, then with the help of setting means that inserted in row holding wires are held on hold until they are over those row holding wires be triggered again. As setting means can, for. B. arranged to relay couplers in matrix form Coupling relays be used, which carry pick-up windings and holding windings, respectively are inserted into the cores marked accordingly (see e.g. German patent specification 1048 956, F i g. 5 and 10). In addition to the setting means already mentioned, there are also in such a row holding headers Crosspoint contacts that are to be actuated by these setting means, as well as link relays Usable relays inserted. Such relays have contacts that indicate the operating status of the associated Intermediate lines z. B. in a route search network, so that there the search and Selection of connection paths according to the operating status of those belonging to the switching matrix Intermediate lines can be carried out.

Row holding wires from connecting routes via multi-level switching fields now also lead each via several coupling levels. The greater the number of these coupling stages, the fewer Resistance must the adjustment means inserted there, z. B. the holding windings of coupling relays, to have. It can now be because of unfavorable manufacturing possibilities or because of a standardization of Windings of such holding relays to a relatively large winding resistance show that a single series connection with the given number of coupling stages is not sufficient if one demands that the normal operating voltage of 60 V is not exceeded. In this In this case, line holding wires divided into sections are to be provided as a remedy. An unacceptable restriction the number of coupling stages can be avoided. It then arises, however, if no special measures are foreseen, another technical difficulty; namely it occurs an extension of that tax time, which expires until all of the individual sections of the divided Row holding headers inserted setting means their full holding ability for the associated connection path have attained. When this control time is to be awaited by the control device of the exchange until other operations are performed in front of it, a division of row holding wires the use of the mentioned control device is extended in time, which means less Connection requests than usual. can be handled.

The invention now shows a way of how, inter alia, this disadvantageous consequence of the division of Row holding wires can be avoided. The invention accordingly relates to a switching network for telecommunications switching, in particular telephone switching systems, in which the connection paths by means of line holding wires divided into sections in the hold-through state are held, if necessary triggered via these row holding wires and at which these row holding wires except via crosspoint contacts and setting means for their actuation Run via relays that can be used as link relays. This switching matrix is characterized by that of a normally open contact at least one relay lying at a division point holding circuit to be closed for the adjacent section of the holding wire already when switching through of the crosspoint contacts there temporarily until the mentioned working contact of the relay closes via an additional centralized one Power source is closed. The presence of this centralized power source has the consequence that when switching through the crosspoint contacts in all sections of the relevant row holding headers the associated setting means are simultaneously energized. They therefore all attain at the same time their full holding capacity within the shortest possible time. An extension of one for this anticipated tax time is avoided.

The centralized power source can either via decoupling rectifiers or via provided for them

ao contacts of the mentioned relays must be switched on. It can also be provided that the held The connection path can be released from one of its ends or from both ends by separating them there is. The invention can therefore be used for connection paths from one side of the switching matrix to lead his other side, and also be provided for so-called reverse connection routes. Such reverse connection paths lead again to the same side of the switching matrix from which they originate back (see German publication 1235 379). You do not need to have all the coupling levels provided of the switching matrix, but it can

. This also involves so-called short routes (see German interpretation document 1262 358). With the help of splitting parts of holding wires into Parallel wires in coupling multiples connected together from coupling relays, so-called relay couplers, a restriction of connection options can be avoided.

The invention will now be explained in detail using several figures:

F i g. 1 initially shows a row holding header divided into sections, in which no additional centralized power source is provided;

F i g. Figures 2 and 3 show split row retaining wires in which the additional centralized power source is turned on in different ways;

F i g. Figure 4 shows a segmented row holding header with the associated connection path can be triggered from one or the other end;

F i g. Fig. 5 shows a row holding header, the sections of which form two branches leading to a reverse connection path belong. .

On the basis of FIG. 6 to 9 the splitting of parts of the holding wires into two parallel wires is shown, who used the management of reverse connection routes as short routes in various coupling stages of the Coupling allows.

F i g. 10 shows how the different in connection with · the splitting into parallel cores provided measures are used at the same time in the switching stages of a switching network can;

11 shows a switching matrix via which the connection education paths are to lead without reversing paths, and the F i g. Figure 12 shows a switch fabric over which reverse links are to be guided, which can also be short routes.

In the example shown on the basis of FIG. 1 for the division of a row holding header into several sections, the section assigned to the switching stage A and the section assigned to the switching stage B of a multi-stage switching network are shown in detail. The switching matrix can, for. B. have a structure known per se (see German Auslegeschrift 1275149, Figs. 1 and 3 including the associated description), as shown in FIG. It consists of several sub-coupling elements KTeI ... KTe r, each of which has three coupling stages. The connection path designated as an example with the reference symbol 2 leads from the subscriber circuit Tn 2 via the switching stages A, B, C, D, E and F to the device RS2. Correspondingly, the section of the row holding head assigned to the coupling stage A leads via a relay T allocated to the subscriber circuit Tn 2, a coupling point contact, the holding winding II of a coupling relay and via the normally open contact zab, which belongs to the relay ZAB , which is in the section of the allocated to the coupling stage B Row holding leader is inserted. In addition to this relay ZAB , this section also has, inter alia, a coupling point contact and a holding winding II of a coupling relay. Further sections of the row holding headers have the corresponding devices and are shown in FIG. 1 indicated by dots. The last section leads via the relay M assigned to the device RS 2. The tripping contact on is also inserted in this section. When it is opened, the circuit for the relay ZAB is finally interrupted, whose working contact zab opens and thus interrupts the holding circuit of the holding winding II of the associated section, [whereby the part of the [connection path assigned to this section is triggered. The parts of the connection path assigned to the other sections have been triggered beforehand in a corresponding manner. Relays T and M are also de-energized in the course of tripping. The relay ZAB and corresponding relays inserted in other sections of the row holding Iader can be used in a manner known per se as occupancy relays to identify the operating status of the associated parts of the connection route with the help of contacts in a route search network.

How the extension of the control time is avoided according to the invention will now be explained with reference to FIGS. In both cases, the additional centralized power source E is provided, which temporarily closes the associated holding circuit until the associated J working contact closes when the coupling junction contact belonging to a section of the row holding lead is switched through. With the arrangement according to | Fig. 2, the centralized power source E is connected to the relevant holding wire via a decoupling rectifier G in parallel with the working contact. The multiple circuit symbol inserted between the decoupling rectifier XiG and the centralized current source E indicates that the current source E is connected to several holding wires. It supplies such a voltage that [iä claims the decoupling rectifier G in Durchlaßrichag when the normally open contact is closed, while the decoupling rectifier G is required to be set up when this working contact is closed. Since the working contact zab

Ground is placed, while the holding winding II controlled by it is connected to negative voltage, the centralized power source E must supply a voltage that is negative to ground, but the amount of which is smaller than the amount of the negative voltage on the holding winding. If the working contact zab is open, the holding circuit is closed via the power source E when the associated coupling point contact is switched through, so that the holding winding II is immediately energized. When the normally open contact is closed, the decoupling rectifier G is used in the reverse direction, and the current source E is no longer used for holding. It therefore only needs to be dimensioned in such a way that it can take over the holding current for those connecting paths whose timing is randomly summarized. If it is a very large switching network, it can be

ao recommend using several separate centralized power sources.

On the basis of FIG. 3 shows that the function of decoupling rectifiers by additional Contacts of the ones inserted in the row holding headers

»5 relays can be taken over. For this purpose, the relay ZAB has, in addition to the normally open contact, a normally closed contact which is structurally combined with the normally open contact to form a subsequent changeover contact. The additional centralized power source E in the arrangement according to FIG. 3 connected to the holding wire in parallel with the normally open contact. The relevant section of the holding wire is connected to ground via the centralized power source. Therefore, the holding circuit is closed when the associated coupling point contact is switched through. After actuation of the subsequent changeover contact zab , the current path leads directly to the ground connection of this contact instead of via the current source E. The current source E then no longer has to supply any current. With this approach, too, instead of a single current source E, several such current sources can be provided, if it is expedient. This also applies to the other exemplary embodiments described below.

It was previously provided that the connection path is triggered from one of its two ends by being separated there via a contact, namely the trigger contact on. Sometimes it is also required that the connecting path can be released from both ends. An arrangement with a row holding header divided into several sections, in which this is possible, is shown in FIG. 4 shown. The two release contacts on and at are provided there for tripping. Here, too, only the structure of the sections of the row holding headers assigned to the coupling stages A and B is shown in detail. The section that is assigned to the switching stage A.

has, in addition to the relay T, the release contact at, the holding winding II of a coupling relay and an associated coupling point contact , the relay ZABa. Of the correspondingly constructed section that is assigned to the coupling stage B , only the relay ZABb inserted there is shown here. Of the. Trip contact on the last section is also shown. The relays ZABa and ZABb each have a follow-up changeover contact via des-.

sen working contact the respective other section of the row holding wire is connected to ground and this section is connected to the centralized 'power source E via the break contact. The holding circuit of the section of the series holding conductor assigned to the coupling stage A is interrupted or switched through by the subsequent changeover contact zabb of the relay ZABb in the same way as in the arrangement according to FIG. 3. An extension of the control time is also avoided here and, on the other hand, a release by means of the release contact on is enabled. Since the arrangement according to FIG. 4 is symmetrically constructed at the transition point from this section of the row-holding wire to the section of the row-holding wire assigned to the coupling stage B , a release of the connection path with the help of the release contact at, which is located at the coupling stage A, is made possible in a corresponding manner. The holding circuit of the section of the series holding lead assigned to the coupling stage B is also immediately energized when the associated coupling point contact is closed, so that here too an extension of the control time is avoided. If the arrangement covers more than two coupling stages, further splitting points can be provided which are switched as shown in FIG. 2 or 3 is shown.

Switching matrices are also used in exchanges in which all devices to be connected via connection paths are connected to the inputs of a first switching stage and at the outputs of the first to penultimate switching stage are connected to the inputs of the respective downstream switching stage and can be interconnected behind this (see German Auslegeschrift 1 235 379, claim 1). An example known per se for such a switching network (see German Auslegeschrift 1 275 149, FIG. 2 including the associated description) is shown in FIG. 12 shown. This switching matrix also consists of three-stage switching matrix parts, which are designated with KTl ... KTs. A connection path in question leads z. B. from the subscriber circuit TnX to the facility RSl. Its individual sections are marked with the reference symbol 1. An example of the structure of the assigned row holding headers, in which the division according to the invention is provided, is shown in FIG. 5 shown. A splitting point is provided here at the switching stage C serving downstream. Here the subscriber circuit TnI mentioned is connected to the device RS1 via the connection path under consideration to form a pair. This interconnection leads there via an intermediate line. There, the two intermediate line relays ZCCa and ZCCb are inserted into the holding wire, via whose working contacts zcca and zccb, which are in series, the holding circuit of the sections or branches of the row holding wire leading to the two devices is to be closed. One branch of this holding circuit leading via the intermediate line relay ZCCa via the coupling stages C, B and A associated devices, at about the trip contact and via which the subscriber circuit Tn 1 assigned relay T. The other branch of the row holding wire via the intermediate line relay ZCCb, via the switching stage C, B and A associated means, on the trip contact at and "the setting RS 1 assigned relay M. Di centralized power source e is the make contacts zcca and zccb connected in parallel to the at · on the rows keep vein. It is the same as in the arrangement according to FIG. 2 still the decoupling rectifier G inserted. The power source £ here has the same voltage as in the arrangement according to FIG. 2. Accordingly, the holding circuit in both sections or branches is dci

ίο Row holding lead already closed when switching through the associated coupling contacts via the power source £, the decoupling rectifier G being stressed in the forward direction. If when you close this! Cross- point contacts energized intermediate line relays ZCCa and ZCCb have closed their working contacts zcca and zccb, the holding current only flows through these two working contacts, the decoupling rectifier G is loaded in the reverse direction, and d'n

ao power source £ no longer has any power to supply. Obviously, because of the symmetrical structure of the arrangement, the connection path can be triggered either with the help of the cancel contact on or with the help of the release contact at. An off

A solution from both ends of the connection path to ¹ is often required for connection paths that connect devices connected as reverse connection paths to the same switching stage of a switching network. It should also be noted that the intermediate line relays ZCCa and ZCCb are inserted into a Tci of the row holding headers which is assigned to an intermediate line which connects the outputs of the coupling stage C. As their name already suggests, these intermediate line relays can be used to identify the operating state of this intermediate line in a route search network with the aid of at least one contact.

The reverse connection path considered above led over the largest possible number of voe Switching stages of the switching matrix used. You can now also provide connecting paths that go via dit the smallest possible number of coupling stages. Such a connection is aimed at you according to where the devices to be connected are connected to the switching network and wk the operating status of the connection path it

. Question is coming intermediate lines (see the see interpretation 1262 358, claim 1) The resulting reverse connection paths that do not lead via the greatest possible number of switching stages are referred to below as shortwcp designated. Such a short path is z. B. the reverse connection path, which in the switching matrix gem'a! Fig. 12 is denoted by the reference symbol 3

and which leads from the subscriber circuit Tn 7 via the coupling stages A and B to the coupling stage C and voe there directly back via the coupling stages I and A to the subscriber circuit Tn 8. The bond path is Ve connects here via an intermediate line, it outputs two of the coupling stage C, ¹ nid performed. This short path is possible here because both connected subscriber circuits are connected to the same sub-switching network. Z «> interconnects that connect the outputs of the switching stage with one another in the same sub-switching network are saved here because such short paths να are seen. However, when producing a «short path one at an exit of the Koppe! ·

stage C anj luch of the k iting to now row holder f i g. loppel much lamen zu ier fig. <let this sengescha lie for di <sing the le shows, di mn khs uöd its leading idem h ' ? u: air gapi Mgeschlps η statistis cleavage; e «a. So sir Feil der I! Cmcinsan ^: elais / ai enen Päi) he mentors in the P "aptly 110 an s are: elais an ifferten 'hlossen. drelais running 'arallelad! en Ansc

9,> or the 210 gel musts (lie vert ^: rage kc istisch zi! Ate lens eini ■ wei önnen, £ em at irrelevant, ■ tungen inations; he vers: n were ilteader borrowed v <«ils ü al. about the

2 de iderem irchgesi id b ", ■ rbunde rzweg ie es ir

stage C connected between line busy ,, although the shortcut itself does not have this ^{intermediate:} is guided line.

In order to split the row holding headers in the same way as shown in FIG. 5 is shown to enable, special measures must be taken for the switching matrices of the switching stage C. These measures are shown in FIG. 6, assuming; that these coupling matrices are interconnected from coupling relays. In the upper part of FIG. 6 shows ■ the interconnection of the coupling relays provided for this purpose to form a coupling matrix [which is designated KVCl. There the parts of the holding wires leading to the outputs of the coupling multiplier and thus the outputs of the coupling stage C [are split into two parallel chargers Λ 'and h " . The connections connected to the otherwise not { split parts of holding wires of coupling relays I are connected in a statistical distribution to the two parallel wires resulting from the splitting! So the connections of the coupling relays KIl, K12 that are otherwise connected to the vertical part of the holding wires when they are not split are there! ..K110 not jointly connected to the now existing parallel wires. | The relevant connection of the coupling relay K 11 is connected to the parallel wire ti , while the! Relevant connections of the coupling relays K 12 and 1X10 are connected to the parallel wire h " . ! The coupling relays with odd numbers are connected to the parallel wire ti and the even-numbered coupling relays to the parallel wire h " . The distribution of the connections of the coupling relays to the parallel wires of the vertical part of the holding wire 2 is different. To the F parallel wire ti , for example, the relevant connections of the coupling relays labeled with the last digits 1, 2, 5, ii, 9, 10 are connected, I uO to the shown coupling relays K 21, K22 and j $.? 210 belong h "are the beginnings of the remaining coupling relays connected. The? The distribution of the connections in the other parts of the holding wire in question has to change statistically, whereby the aim should be, however, that there is at least one possibility for the switching matrices to have a short path over, if differently designated entrances lead to channels , to which horizontally running parts of i \ dern are connected. This can already be done here if the coupling multiple has only four column joints (vertical). All communication pairs of row lines (horizontal) \ kr differently designated parallel cores can then be connected. Correspondingly, the serial cores of the associated short routes also lead via stubs with differently designated parallel cores, which are connected via two relays in series. The row holding leader of a short path, which leads ixr the horizontally running row lines 1 | ai 2 of the coupling multiple KVC 1, is fiiched under J & rem with the help of the coupling relays K 11 and K 12 and leads via the parallel wires ti ύ h ", which are via the relays Ca and Cb are "tied together. it will be apparent to those 'j aaweg two branches, which are structured the same, * it i g in F i. 5 is shown. the Relais Ca and Cb can be also exploited to with in a To make path search network recognizable that the intermediate line connected to the column line 1 of the switching matrix KVCl and leading from there to another switching matrix of the switching stage C is occupied.

The part of the holding wire assigned to this intermediate line is also split into two parallel wires and leads to the split parts of the

ίο holding wires of such a coupling multiple. This is also shown in FIG. 6, it is the switching matrix, designated KVC 2 , of the sub-switching network KTs, which is also shown in FIG. 12 is shown with. A reverse connection path, which leads via the row line labeled 1 of the switching matrix KVC 2 and, in addition to the mentioned intermediate line, also leads via the row cable labeled 1 of the switching matrix KVCl of the sub- switching network KT2, can be used without additional:

ao borrowed measure cannot be kept using the relays Ca and Cb , since the coupling relays K 11 to be used for this connection path in the coupling manifold KVC 1 and UK in the coupling manifold K VC 2 on parallel cores of the same name, namely

»5 loaned to parallel veins ti. connected to their respective port. The associated series holding circuit therefore only leads via the relay Ca, but not via the relay Cb. Corresponding relationships result for other analogue reverse connection paths. In order to be able to hold such reverse connection paths with the aid of the relays already provided, to which the relays Ca and Cb belong, without extending the control time, a measure is taken which is illustrated in FIG. 7 is shown. Here, too, split parts of holding cores of switching matrices are directly interconnected via cores of intermediate lines that have been split in a corresponding manner. However, these interconnections are each formed by switching contacts which, in the working position, replace the direct interconnections with a short circuit of the two parallel wires formed by splitting the same parts of the holding wires by an interconnection via the relay provided. Thus, the parallel cores ti and ti ' assigned to the vertically extending column lines 1 of the switching matrices are connected to one another directly via the switchover contacts cc when these switchover contacts are in the rest position. In this case, the parallel wires are still connected to one another via the series connection of the relays Ca and Cb. For short routes, row holding wires are therefore in the manner already shown in FIG. 6 is provided. If a reverse connection path is to be established, which leads via the sub- switching fields KT2 and KTs and thus also via the intermediate line connecting these two sub-switching fields, the relay Cc, which carries the switchover contacts cc, is energized. Its contacts come into the working position, whereby the parallel wires belonging to the same coupling matrix are short-circuited and these short-circuited parallel wires are also interconnected via the relays Ca and Cb . The row holding header of a reverse connection path that leads via the sub-switching networks KT 2 and KTs therefore has the same structure as that in FIG. 5 row holder shown, namely it has two sections or

009583/235

Branches, one of which leads via the relay Ca, via the short-circuited parallel wires h ' and h " and via a row line of the switching matrix KVCl as well as via the switching stages B and A to an" input of the switching matrix and the other via the relay Cb as well as via short-circuited parallel wires of the switching matrix KVC2, via a row line of this switching matrix and via the switching stages B and A to another input of the switching matrix. Of course, windings of coupling relays, coupling point contacts, etc. are also inserted into these two branches. In an arrangement according to FIG. 7, in addition to the short routes, reverse connection routes can also be established using the measures according to the invention.

The splitting of the parts of the holding wires leading to the outputs into two parallel wires is expediently provided not only in the last downstream switching stage of the switching network used, but also in the first to penultimate switching stage of this switching network. In this case, reversing short paths can also be established with these upstream coupling stages, the row holding circles of which are divided into sections or branches. Such short paths are also shown in FIG. The subscriber circuit Tn 5 is connected to the subscriber circuit Tn 6 via a short path, which is denoted by 5 and in which the coupling stage B reverses. In FIG. 8 shows the necessary splitting of the relevant parts of the holding wires into two parallel wires W and h ″ . These parallel wires are also each connected via two relays in series, to which those labeled Ba and Bb belong to close the holding circuit of the branches of the series holding leads leading to the two connected devices via series working contacts, e.g. ba and bb of the relays Ba and Bb This results in row holding wires which are constructed exactly as shown in FIG. 5, but which comprise one coupling stage less than usual; namely, the devices assigned to coupling stage C are missing in these row holding wires.

On the basis of FIG. 9 shows how row holding wires are constructed which are assigned to short paths through which devices connected to the same switching matrix are connected to one another. Such a row holding header leads z. B. via the relay T, the holding windings of the coupling relay K including the associated crosspoint contacts, the parallel wires ft 'and h ", the relays Aa and Ab, the extinguishing contact on and the relay M. The holding current is either via the decoupling rectifier G or via the aa series-connected make contacts and from fed. the two sections or branches of this series holding vein are here particularly short, since only one switching stage is to be recorded. Otherwise it fully meets the g in F i. series holding artery shown. 5 Accordingly, they will also like The distribution of the connections of the coupling relays belonging to a coupling manifold of the coupling stage A to the parallel wires provided there is particularly simple, if the devices connected to such a coupling manifold consist of two groups and if

'Only connections between a device dtt one and a device of the other group are to be established. In this case, the coupling · relay can, the connections to the establishment of the gleichet group by turn, with their connections ά an equally called parallel vein are angeschlosscs. This is also the case in FIG. 9 arrangement is provided. The one in the upper half diesct

Coupling relay provided switching relay switches through connections to the upper group TS of devices, while the coupling relay provided in the lower half of this switching matrix switch through connections to the lower group VS of closed devices. Accordingly, the connections of the above are "half belonging coupling relays connected to Paralleladert, which are denoted by h 'During" ¹ the other relevant connections of coupling

»Ο relays are connected to parallel wires, which are marked rr.ii h" . The row holding wires of all connections provided then lead in each Fat over two relays connected in series, which connect two parallel wires.;

as in fig. 10 it is shown how all on hand dt * F i g. 6 to 9 measures already explained can be provided in the same switching matrix. This is a switching matrix in which. Reverse connection paths and shortcuts hergestcii be ^first In any case, this results in hall wheels which consist of sections which each contain drives assigned to only one coupling stage, i.e. very short sections. If the row holding wires of connecting paths, ds each lead over several coupling stages, contain matching parallel wires in the coupling stages involved, the parallel wires of split parts of holding wires are still the Koppelvic! times the upstream coupling stages B and A auv

4P changeover contacts bc and ac provided on the output side. The holding wires of the jt Weil downstream coupling stage are individually connected to the center springs of these changeover contacts via intermediate wires. In order to hold a connection path, one or the other parallel of a split part of a holding wire can therefore be activated in a clocked manner by actuating a changeover switch. This ensures that a row holding header can be created in the intended white * in every case.

In the in Fig. Overview shown 10 by dt in the various stages of a three-stage L ·} pelfeldes measures to be taken according to the h · invention is the splitting of portions of shark * ädern in the coupling stage A shown further dl closure of the holding circuits into Row pJ switched contacts aa and off or by means of a centralized current source Ea. Also shown is ": lead on switch-over to ac Zwischenleitungsadr switching stage B, in which likewise parts \ t holding wires are split and Haltestromkreii can be connected in series contacts ba and bb bu on the centralized power source Eb geschlo". From there lead on Us switch contacts bc intermediate line wires to nä'ci most switching stage, namely the coupling stage C, dl also split parts of holding wires vote are seen. Associated holding circuits körnu

also cb or closed bars' cc

circuit multiples, etc. it indicates that the 'Aufs' leads to whoever contacts the with A <

In particular the V divided stand <ranks this Γ contact a usable: sign (zab) η lying Abschrstromk by passing work one to lock «2. K identification (E) each parallel to ar Spannu (O) in work equation, closes

3. Kc mark (E) jew parallel wire an;

4. Kc mark of the Zugi Umshai sine

5. Ko claims neighboring each < whose K barte ar dem jev parallel

800

can also be closed via series-connected contacts ca and Λ or via the centralized power source Ec . Switching contacts cc are also provided there, which replace direct interconnections of parallel cores of different coupling multiples by short circuits of these parallel cores sw. In the case of coupling stage C it is also indicated that splitting can be dispensed with there even in the case of switching matrices, namely if no short paths are routed via the relevant outputs. The switching clocks already mentioned and provided in the coupling stages in Den- yer-i Ki are actuated, among other things, via relays which are designated Ac, Bc and Cc.

15th

Claims (9)

Patent claims: 1. Coupling network for telecommunication switching systems, in particular telephone switching systems, in which the connection paths are kept in the switched-on state by means of line-holding wires divided into sections, if necessary triggered via these line-holding wires and in which these line-holding wires, in addition to cross-point contacts and setting means for their actuation, also act as link relays ^; Usable relay lead, characterized in that a holding circuit (-, T, KVA, ground) to be closed by a working contact (zab) at least one relay [ZAB) located at a splitting point for the adjacent section of the holding wire temporarily already when the local crosspoint contacts are switched through until the mentioned work contact (zab) of the relay (ZAB) is closed via an additional centralized power source (E) (Fig. 2, 3). 2. Coupling matrix according to claim 1, characterized in that the centralized power source (E) is connected to a holding wire via a decoupling rectifier (G) in parallel with the normally open contact (zab) and that it has a voltage such that it connects the decoupling rectifier (G ) is claimed in the forward direction when the normally open contact (zab) is open, whereas the decoupling rectifier (G) is claimed in the reverse direction when the normally open contact (zab) is closed (Fig. 2). 3. Coupling matrix according to claim 1, characterized in that the centralized power source (E) is connected to a holding wire in each case via a normally closed contact of the relay in parallel with its normally open contact. 4. Coupling matrix according to claim 3, characterized in that in each case a normally closed contact and the associated normally open contact to form a subsequent changeover contact (zab) are structurally combined (Fig. 3). ' 5. Coupling matrix according to one of the preceding claims, characterized in that both adjacent sections of a row holding conductor each have a relay (ZABa, ZABb) , to whose contacts (zaba, zabb) the respective adjacent other section is connected, at . each of which the centralized power source (E) is connected in parallel, so that the connection path can be triggered from its two ends by separation there (via contacts on the, at} of the holding wire (Fig. 4). 6. Switching matrix according to claim 2, in which all devices to be connected via connection paths are connected to the inputs of a first switching stage and in which the outputs are connected. The first to the penultimate coupling stage are connected to the inputs of the respective downstream coupling stage and can be interconnected behind this, characterized in that the division point of the row holding headers is at the relevant downstream coupling stage (C), in which the devices are connected in pairs via connecting paths, that there in the holding wires two intermediate line relays (ZCCa, ZCCb) are inserted, via whose in-series working contacts (zcca, zccb) the holding circuit of the branches of the series holding wire leading to the two devices (T, M) is to be closed, and that the centralized power source (E) is switched on in parallel with these two working contacts (zcca, zccb) (FIG . 5). 7. Switching network according to claim 2, in which all devices to be connected via connection paths are connected to the inputs of a first switching stage, in which the outputs of the first to penultimate switching stage are connected to the inputs of the respective downstream switching stage and can be interconnected in this, in which connection paths are also connected are provided, which lead over the smallest possible number of coupling stages, characterized in that in the interconnected coupling relays of the coupling stages the parts of the holding wires leading to the outputs are split into two parallel wires (A ', A "), that the to the otherwise not split parts of holding wires jointly connected connections of coupling relays in statistical distribution to the two parallel wires resulting from the split are connected that these two parallel wires (A ', A ") via two relays (Ca, Cb; Ba, Bb; Aa, Ab) are connected, that at their junction with working contacts in series (ca, cb; ba, bb; aa, ab) of these relays jointly the holding circuit of the branches of the series holding wire leading to the two connected devices is to be closed and that the centralized power source (E) is connected in parallel to these two working contacts (Fig. 6, 7, 8, 9). 8. Switching network according to claim 7, characterized in that in the last downstream switching stage (C) the split parts of switching matrices are connected together directly via cores split up in a corresponding manner from i intermediate lines, but that these interconnections are each formed via switching contacts (cc, cc) are, 'which in the working position replace the direct interconnections with a short circuit of the two parallel wires formed by splitting (A', h ") of the same parts of the holding wires by an interconnection via the provided relays (Ca, Cb) , so that connecting paths via contacts from Coupling relays (Kx, Ky) can be performed, the parallel wires that are otherwise interconnected with one another are connected to different switching matrices (KVCl, KVC 2) (Fig. 7). 9. Coupling matrix according to claims or 7, characterized in that the parallel wires (A ', A ") of split parts of holding wires of the switching matrices of the upstream coupling stages (B, A) are provided on the output side in each case switching contacts (6c, ac) , on their Center springs are individually connected via intermediate line wires dit holding wires of the downstream coupling stages (ß, C), so that one or the other parallel wire (A ', ft ") of a split part of a holding wire can be used to hold a connection path by actuating a changeover contact (F i g. 8,9) For this purpose 3 sheets of drawings