DE1259990B - Arrangement for performing electrical serial measurements on multi-core telecommunication cables - Google Patents

Description

Arrangement for performing electrical serial measurements on multi-core Telecommunication cables The invention relates to an arrangement for the implementation of electrical cables Series measurements on multi-pair telecommunication cables that check for wire resistance, insulation, Operating capacity, couplings, etc. are to be checked, using connection devices, to which the cable cores to be measured are connected, and of switching devices containing switching devices, via which the cable cores to be tested to the measuring devices are switched on; by a program storage device for Program control containing series measurements become the switching devices for application the cores to be measured to the required measuring lines (intermediate lines) and the switching elements for connecting the required measuring devices to the measuring lines controlled. To control and determine whether the manufactured lengths of multi-pair telecommunication cables that also have other cores, e.g. B. signal cores may contain, achieved crosstalk attenuation values and others specific to the cables Properties that meet the required conditions are extremely numerous measurements required, which are carried out in series measurements. In particular, required the application of the cable cores to be measured prior to each individual measurement a large expenditure of time and manpower on the respective measuring devices. If you have but via a switching facility, at whose inputs all wires of a cable be clamped in preparation, while at their outputs all necessary measuring devices are switched on, measurements can be carried out at a high walking pace that depend solely on the time required for switching through the switching device and is determined for measuring and processing the measurement result. In connection with the implementation of electrical serial measurements in multi-pair communication cables it is already known based on telephone switching equipment to use interconnection networks built from the point of view of telephony technology; such networks can, however, meet the conditions required for cable measuring systems not meet.

The object of the invention is now to provide a To train through-switching device so that it meets the requirements for cable tests Conditions, in particular the requirement for equality of all resistance values of the Through-connection paths in the through-connection device after high insulation values and after Freedom of coupling corresponds. In addition, at the various connections the wires to be tested to the measuring devices by the structure of the switching device and the capacitance values caused by the interconnection of the lines are as small as possible and the same, as well as those for the various connections of the wires to the measuring lines (intermediate lines leading to the measuring devices) resulting differences in capacitance be as small as possible so that the coupling or operating capacitance values of the various Paths of the switching device are the same as one another.

In the arrangement according to the invention, the conditions are set fulfilled in that the switching elements for electrically controllable switching through of the each cores to be measured of a telecommunication cable to the respectively required measuring devices are summarized in a coupling network that as switching elements protective gas contact relays are used that the symmetrical wire pairs used for telephone purposes des cable to be tested grouped according to the cable structure to the switching device are connected that the switching elements of the switching elements and the switchable Paths are constructed symmetrically so that the cables that may still be present in the cable Cores not used for voice transmission, e.g. B. signal cores, to switching devices are connected with wiring cables intended for this type of wire only, and that the relay inputs and outputs, d. H. those connected to the cable cores Contact springs of the relay on the one hand and that to the multiple wiring and thus contact springs leading to the measuring lines on the other hand, on the two Coupling fronts are divided. There are therefore on one switching matrix front only connections for the cable cores or for the lines to them and on the other Coupling front only those grouped according to certain measuring tasks and via measuring lines Multiple wirings that can be connected to measuring devices (intermediate lines). at the arrangement according to the invention thus takes place both a selection of the wires the stranding elements of cables according to the ones to be placed on the cores concerned Requirements, in particular a selection for symmetrical wire pairs for voice transmission and according to signal wires, as well as a connection of these different wires to different, Multiple wirings that meet the different requirements via different Measuring lines leading to the measuring devices (intermediate lines). As all wires for voice transmission be connected in pairs at the switching matrix input and these in the entire switching matrix paired arrangement is retained, the arrangement according to the invention can be independent from the cable structure practically for all occurring cable types with symmetrical lines and, if necessary, can be used with other cables. ..

In the arrangement according to the invention, depending on the measurement specification for a cable, individual wire pairs, but also whole wire groups with the intended ones Measuring lines, which in turn are connected to the corresponding Measuring devices can be switched on, are coupled. The Dürchschalteinriehtung and the measuring device connection with its switching elements form the multiple wiring and the measuring lines (intermediate lines) a measuring path network. By a program control device the measuring process can be carried out automatically according to the type of cable to be measured being controlled.

Two measuring lines are generally required for coupling measurements, one of which is intended for the disturbing wire pair and the other for the disturbed pair of wires is. For this purpose, there are between the switching device and the measuring device connection among other things, two high-quality double-core measuring lines (intermediate lines) for Connection of the wires to be measured with the appropriate measuring devices provided. In particular, because of the coupling measurements to be carried out, each one is symmetrical Pair of wires as a disturbing or disturbed line at the same time to the inputs of two Switching elements connected via which each of these pairs of wires to one of the two electrically high quality test leads (including multiple wiring) can be created. These measuring lines are designed differently, see above that the wire pairs to be measured for types of measurement with opposing requirements the suitable measuring line can be assigned in each case. The arrangement is made in such a way that that the wire pairs to the one measuring line (intermediate line) with double contacts and therefore with low contact resistance spread, especially for measuring wire resistance and can be switched through to receive extremely small voltages; the other The measuring line can be connected to the wire pairs via single contacts, has higher insulation values and can mainly because of their low capacity and lower reloading can be used for capacitance and insulation measurements. The ones not for voice transmission usable cable cores, e.g. B. signal wires are connected to the inputs of special switching devices switched, via which these wires, also via intermediate lines, only to certain Measuring devices can be connected. With signal cores are common only the wire resistance and the insulation checked, not during crosstalk measurements required are. The switching elements and intended for this type of cable cores their wiring thus form a completely separate one from the other measuring paths, however constructively assembled with the measuring path network for symmetrical wire pairs Measurement path network, to which no high symmetry and no high decoupling requirements be asked. This separation of the coupling devices for normal measuring paths . Facilitated by the coupling devices for the measuring paths with high-quality properties the fulfillment of the requirements to be placed on the measuring path network is significant and saves a large additional expense on switching means and control devices. The unnecessary requirement that the signal cores z. B. to the crosstalk meters should be able to be switched on, would result in a considerable amount of additional work. In a smaller switching network, namely in the measuring device connection, are those of the measuring lines (intermediate lines) coming from the mooring coupling to the corresponding Measuring devices switched through. - The multiple wiring, the wiring of the coupling relays and the measuring paths up to the measuring device connection are constructed symmetrically; this Construction is also retained for circuits in which only one at a time Wire is measured. In this case, the single core concerned is only immediately activated in front of the measuring device, specifically in the measuring device connection. The special one The type of wiring and the operation of the switching device entails: that all paired measuring paths retain their high electrical symmetry and no undesired ones Cause disturbances in the measuring process. Because of the grouping of the wires to be tested Cables, e.g. B. after symmetrical wire pairs and signal wires, and thus the to this Wires connected switching elements is the control of the switching device relatively easy. The use of protective gas contact relays makes the arrangement according to the invention independent of external influences, in particular of impurities the air of a manufacturing facility. The connections to the inert gas contact relays are separated by entrance and exit. This results in a clear connection circuit both for the wire feeds and for those on the other front side Multiple wiring to which the measuring lines are connected. A high one The insulation value and a low-coupling structure can be achieved with the multiple contacts cantilevered rigid wiring can be achieved between the relay connections. The multiple wiring is advantageously carried out by crossing the two wires from relay to relay, so that the wires swap places on the docking contacts and continue to rotate in the longitudinal direction by 180 ° in the same direction. From the special Line routing results despite the extensive multiple wiring not only high symmetry, but also a reduction in electrical and magnetic couplings. The structure of the switching device can, for. B. so chosen that a larger number of coupling relays are arranged one above the other. There each wire to be tested is switched through via two different relay functions can be, two adjacent rows of relays form a unit for the connection of the corresponding pairs of wires that lead to this double row are.

To the switching device (application coupling field) and the decoupling To be able to make it even more advantageous in the same, the veins of the to be tested can Cable are connected in such a way that the veins of the trunks 1 of the vein groups the one, e.g. B. on the left, the veins of the trunks 11 on the other, e.g. B. on the right-hand side of the mooring coupling field to the switching elements arranged there are connected. The wires of the cable to be tested can also in particular so divide the switching matrix parts that all in the counting sequence in the cable cross-section odd-numbered stranding elements on the -one part - and all even-numbered stranding elements are connected to the other part of the switching matrix. These measures cause that the measuring paths for coupling measurements on neighboring stranding elements do not exceed neighboring coupling relays are running. The mooring switching network is advantageously divided in halves, e.g. B. in an upper and a lower half, and places the terminal strips for attaching the connecting cables coming from the docking frame between the halves of the mooring switch. The coupling relays can also be arranged in blocks in columns or Arrange lines; the signal wires can be connected to such rows or columns via coupling relays are switched on between the lines provided for symmetrical wire pairs or columns of coupling relays are arranged. This grouping is also beneficial contributes to the best possible decoupling of the switching paths in the measuring path network.

In an advantageous embodiment of the arrangement according to the invention the switching field consisting of the switching relay is divided into several field sections subdivided, of which only the section in which the wire pair to be measured is present, is connected to the measuring line (intermediate line). Through this outline becomes an additional decoupling of the extensive multiple wiring and circuitry it acts. The additional effort for an optional connection of switching matrix sections is small compared to the advantage, which then branched out less widely because of it Multiple wiring network results.

The telecommunication cables to be tested are advantageously not immediate to the switching device (docking switch), but to one or more Connection frame or the like connected, from which connection cables (supply cables) lead to the mooring switch. In an advantageous embodiment of the lead frame the cores of a certain cable type, e.g. B. a shift cable, in the natural Sequence, regardless of the structure of the cable to be tested. the Connector plugs for the connecting cables are designed in two rows and are assigned in such a way that that adjacent pairs of wires are arranged symmetrically to one another, as in the case of a star quad are. Signal wires, on the other hand, should then be based on the wiring of the connecting cables be switched to the special connection plug-in connections in the mooring switching network. For this purpose, special connecting cables are used for two, three, etc. grouped Cable created, over which the wires are combined according to stranding elements and the speech cores from the signal cores or the like. separately and accordingly to the special The coupling relays provided for this purpose in the coupling field must be connected. With another advantageous embodiment of the lead frame, the terminals are like the wires in the cable to be tested are assigned to one another in pairs; for those in special Cables that are still carried along are provided with special terminals. Corresponding to the order of the wires in the cable are the connection terminals after the cable stranding elements grouped, and depending on the construction of the cable, terminals are left free, if the corresponding wires, e.g. B. signal wires, not provided in the cable to be tested are. If you do this pre-sorting when connecting the cable cores to the Connection frame through, so the through-connection and line routing in the switching matrix advantageously take place with pairs of lines that are permanently assigned to one another. This results in an electrically symmetrical structure with constant transmission properties to create with any through-path. The advantage of being applied in both cases Pre-grouping of the cable cores results from the following considerations. You would Connect a cable wire for wire to the grouped input terminals of the connection frame and there would not be special connecting cables or connection frames for each stranding element type create, one would have to be practical, taking into account the various cable structures be able to connect any input terminal to any measuring device terminal. But that would the cost of switching means increase considerably; the symmetry requirements the lines to be switched through and the decoupling could, however, with such a Construction can no longer be fulfilled with bearable effort, because then also a pair Arrangement of cores belonging together would practically no longer be possible.

To reduce the inequalities of the resistance of the measuring paths and to equalize the measurement path length in the coupling network can advantageously to be measured cores of the cables or their feed cables from one of the location of the measuring line feed opposite side, e.g. B. from the lower or from the upper side of a Switching matrix from, fed and on the other front surface of the switching matrix to be supplied measuring lines accordingly z. B. on the upper or lower side this coupling matrix can be connected to the relevant multiple wirings. It has been found that in special cases the remaining measurement uncertainty on different wire lengths depending on the position of the coupling relays in the docking coupling field is based. With the measures specified, all lines are now in the switching network the same length, regardless of whether z. B. the lowest or the highest coupling relay is involved in the interconnection of the wires. To the resistance values possibly the same size as possible even without using the measure described above To be able to do this, a large wire gauge will be required for the wiring of all connections be beneficial. Furthermore, wires of larger diameter can be used in the larger distances and in the shorter distances, wires with correspondingly smaller diameters for wiring build in. It can also be advantageous to reduce the resistance values in the switching matrix to make it the same size that you have all the individual lines of the individual inputs on Bringing them a uniform length by placing them in appropriate loops.

With the new arrangement for carrying out electrical serial measurements A particularly low-coupling construction results from multi-pair telecommunication cables the contact manifold and its wiring. This has an advantageous effect the connection of the cables according to stranding elements, the grouping of which is also extends to the switching means and a pair in the entire measuring path network symmetrical conductor arrangement allows. This results in good transfer parameters for all required measured values. The grouping of the switching paths in the measuring path network enables a relatively simply structured programmer that adheres to the principle which is based on the through-connection arranged according to stranding elements and which is easy to use can be adapted to different measuring programs.

The invention is described below on the basis of an exemplary embodiment explained in more detail.

The F i g. 1 represents a block diagram for a program controlled Measuring system for testing telecommunication cables. The overall system consists of one Feeder and a measuring station. The application device contains the switching device 1 (coupling field), which requires special construction measures from an electrical point of view. It consists of a relay circuit that connects each wire of the cable under test To switch on measuring devices permitted. The wires to be measured are not immediate connected to the mooring switch, but lie on the lead frame 2. The Connection between the mooring switch 1 and the connection frame 2 is made by pluggable Connection cable 3 (supply cable) established. Lead from mooring switch 1 Measuring lines 4 to a measuring device connection 5, which, like the mooring coupling 1, contains a protective gas contact relay, via which the various measuring devices 6, e.g. B. to measure the wire resistance, the capacitance values of the wires, the coupling values etc., can be turned on. The measuring device connection 5 and .the measuring devices 6 can already be facilities of a measuring station. The measuring station essentially consists nor from a control panel 7, which the means for setting, control and Contains control of the entire measuring device. The measuring device connection 5, the measuring devices 6 and the relays in the program control 8 can be in a special measuring frame be accommodated. The measurement results are registered in the device 9 and evaluated.

In FIG. 2 is the front of the mooring switch 1 (F i G. 1) shown in principle. The individual stranding elements are in the mooring coupling field the telecommunication cable is switched through to the test leads. It consists of two symmetrical to a center line lying relay frames 10 and 11, between which the terminal strips 12 are arranged. Those coming from the connection frame 2 are attached to these connection strips Connection cable 3 (F i g.1) connected via a connector. The connections the connection strips 12 are via shielded symmetrical lines 13 with coupling relay pairs connected, namely each line 13, as can be seen from the figure, both to the two working double contacts of a coupling relay of the column that is only assigned to it 15 as well as in parallel to the working contacts of only two single contacts having coupling relay of column 14. A double contact in the relay of the Columns 15 can e.g. B. by parallel connection of one pair of contacts one and the same Relay. Two relays that belong together are always next to each other and arranged in the same block (14, 15) as the associated strips 12. The breakdown the wire groups can be used for better decoupling of the measuring paths of adjacent wire groups of the cable are taken so that, for. B. in the relay frame 10 the odd ones Core groups, e.g. four, and in the relay frame 11 the even-numbered core groups of the telecommunication cable are in place. Are now the inputs of the coupling relay pairs on the connection side of the frame, the outputs of the coupling relays are on the led out to the rear of the frame and for each of the various relays 14 and 15 separately multiplied, as can be seen from the illustration of FIG. 3 can be seen is. In this way, each wire pair, depending on whether the relay type is 14 or 15 is controlled, optionally with the corresponding multiple wiring network 16 or 17 are connected. This multiple wiring is as cantilever wiring Made of bare wire, run over the relay contact soldering lugs and end at the connection strips 18. The individual multiples 16 and 17 are correspondingly on these connection strips 18 connected to the circuit of the docking switch and through the lines 19 and 20 connected in parallel. The connection in the docking coupling is done in pairs. is a wire selection is necessary, this is only done within the measuring device connection 5 (Fig. 1). As shown in FIG. 3, they all connect with double contacts equipped coupling relay 15 with the wire pairs placed on the connection strips 12 of the measuring line 21, due to the pre-grouping of all lines that are classified as Trunks in telecommunication cables can be addressed. It can be both the trunks of the KoppeIfeldteils 10 as well as those of the part 11 coupled to this measuring line will. On the other hand, the same wire pairs are connected to the measuring line via the relay 14 22 switched, again all the trunks of the upper and lower contact field 10 and 11. In an advantageous manner, a grouping of the tribes is carried out in this way by attaching the trunks I to the two left relay double rows (14 and 15 in Fig. 2) and the trunks II to the two right relay double rows (14 and 15 in FIG. 2). The relays of the middle double row 25/26 are on signal wires of the telecommunication cable, if there are any in the cable to be tested are. The signal cores of two adjacent stranding elements are also advantageously combined in pairs. The signal wire pairs are only on measuring devices for signal wires connectable, and although via the relay of column 26 to the symmetrical Signal wire measuring line 23 or via the relay in column 25 to the single-wire measuring line 24. The four measuring lines 21, 22, 23 and 24 lead to the measuring device connection 5 (Fig. 1). From FIG. 2 it can be seen that the cable cores to be tested over the connection strips 12 and the lines 13 either to the upper, 10, or to the lower, 11, switching matrix part are continued. The upper and lower part of the switching matrix associated terminal strips 18 can through the lines 27, 28, 29 and 30 in parallel be switched.

An advantageous modification of the FIGS. 2 and 3 arrangement shown is that the connecting cable 3 between the lead frame 2 and the Mooring switching network 1 (F i g.1) not corresponding to the illustration in F i g. 2 between the two halves of the mooring matrix, but above and below the switching matrix halves 10 and 11 are fed. The terminal strips 12 are then correspondingly above of the field 10 and arranged below the field 11. The in F i g. 3 wiring shown of the switching matrix multiple and the location of the strips 18 can be retained in this case will. The advantage here is that the path length for all coupling paths in the coupling matrix and thus the volume resistances of all through-going paths are the same are independent of the location of the relay switching through.

Since the contact capacitance values in the switching path of the relays 14 equipped with single contacts are only half as large as the values of those measuring paths in which the cable cores are switched through to the measuring line with single contacts connected in parallel, i.e. with double contacts, the measuring line 22 can preferably be used for the operating capacitance measurement of the wire pairs are used. By connecting two contacts in parallel, on the other hand, through-contact devices are obtained with greater security against fluctuations in contact resistance. A low contact resistance with high constancy is z. B. particularly required for wire resistance measurement and measurement of small voltages. It is therefore advantageous to provide those coupling relays with double contacts which are activated for the connection of the disturbed line during the resistance measurement or during crosstalk measurements. Even those coupling relays that are only intended for switching through the signal wires to be tested for resistance value can be equipped with double contacts. This different configuration of the coupling paths is based on the requirement for special properties of the measurement paths.

Claims (15)

Claims: 1. Arrangement for carrying out electrical series measurements on multi-pair telecommunication cables that may contain other wires can and are checked for insulation value, operating capacity, crosstalk couplings, etc. are to be, using connection devices to which the to be measured Cable cores are connected, and by switching devices containing switching devices, via which the cable cores to be tested are connected to the measuring equipment, with program control containing program storage means for the series measurements Switching elements for applying the wires to be measured to the required ones Measuring lines (intermediate lines) and switching devices for connecting the necessary Measuring devices to which the measuring lines are controlled, .d u r c h e k e n n z e i c h n e t that the switching elements for the electrically controllable switching through of each to be measured cores of a telecommunication cable to the respectively required measuring devices are summarized in a coupling network that as switching elements protective gas contact relays are used that the symmetrical wire pairs of the cable to be tested after the cable structure grouped connected to the switching device. are that the switching elements the switching elements and the switchable paths are constructed symmetrically that the possibly still present in the cable, not used for voice transmission Cores, e.g. B. signal wires, to special switching devices with only intended for this type of wire Wiring lines are connected, and that the relay inputs and outputs, d. H. the contact springs of the relay connected to the cable cores on the one hand and the contact springs leading to the multiple wiring and thus to the measuring lines on the other hand, are divided between the two switching matrix fronts. 2. Arrangement according to Claim 1, characterized in that for each pair of wires two coupling relays to optional application of the wires to one of two measuring lines are provided. 3. Arrangement according to claim 2, characterized in that the one coupling relay for switching through with a single contact and the other coupling relay with double contacts, e.g. B. by connecting two contact elements in parallel to one and the same coupling relay, is equipped. 4. Arrangement according to one of the preceding claims, characterized in that that the switching matrix consisting of the switching relay is divided into several field sections is divided and that only that section is connected to the measuring line, in which the associated energized coupling relay is located. 5. Arrangement according to one of the preceding claims, characterized by such a design that when taking measurements on individual wires the wire selection is only made in the measuring device connection. 6. Arrangement according to one of the preceding claims, characterized in that the contact springs the relays on the multiple wiring side are wired in a self-supporting manner. 7. Arrangement according to claim 6, characterized in that the connecting lines for the wiring Swap their places on the contact contacts from relay to relay and thereby When viewed in the longitudinal direction, continue turning 180 ° in the same direction. B. arrangement according to one of the preceding claims, characterized in that the to be tested Cable cores are connected to special lead frames and that the or the Connection frame via connection cable (supply cable ) with the Mooring switching network are connected. 9: Arrangement according to claim 8, characterized in that that special considerations for the structure of the stranding elements for the cables to be measured Connection frames and / or connection cables are used. 10. Arrangement after a of claims 8 and 9, characterized in that for measurements on cables with under other special veins, e.g. B. with signal wires and symmetrical wire pairs, ankle frame with additional special connection terminals for connecting these special wires are provided. 11. Arrangement according to one of claims 1 to 10, characterized in that that the switching network is divided into two halves and that the veins of the trunks I connected on one half and the veins of the stems II on the other half are. 12. Arrangement according to one of claims 1 to 11, characterized in that the switching matrix is divided into further halves if necessary and that all in the counting sequence of odd-numbered stranding elements of the telecommunication cables to one half of the coupling matrix and all even-numbered stranding elements are routed to the other half of the coupling matrix. 13. Arrangement according to one of the preceding claims, characterized in that that the coupling relays are arranged in blocks in columns or rows and that the Signal wires are switched on via coupling relays such rows or columns that between the rows or columns of coupling relays provided for symmetrical wire pairs are arranged. 14. Arrangement according to one of the preceding claims, characterized characterized in that the connection strips for connecting the wire pairs or the wires in the case of switching matrices grouped into several parts, e.g. B. switching matrices divided into halves, are arranged between these parts. 15. Arrangement according to one of claims 1 to 14, characterized in that to reduce the inequality of the resistance the measuring paths and the feeder cables to equalize the length of the measuring paths in the coupling network of the cables to be measured from the side opposite to the measuring line feed off, e.g. B. from the lower or from the upper side of a switching matrix supplied and that the measuring lines to be fed in on the other front surface of the switching network then on the upper or lower side of this coupling matrix to the relevant multiple wirings are connected.