DE840714C - Multi-core cable line - Google Patents

Description

Multi-core cable for the transmission of messages in carrier current mode multi-core cables are generally used, which usually have several cores are grouped together to form core groups. As a rule, there are four cores each z. B. be assigned to so-called star fours. Also the fours are in general stranded together again or, if they are arranged in layers, in the form of Helical lines wound around each inner layer.

To keep the crosstalk between the individual wire groups as small as possible to hold, one usually gives each core group a different twist, i.e. the lay length stranding is different for each core group. The stranding creates But now runtime changes in the individual line loops, since both the absolute The length of the line as well as the capacitance and inductance of the individual wire the other compared to the values to be expected with straight parallel laying is enlarged, namely the more it is enlarged, the shorter the twisting twist. It is clear that when using wire groups with different twist, the running times on the individual groups of veins are of different sizes, leading to the known phenomena this leads to the so-called exchange effect. As a result of the different running tents per unit of length the line you get different values for the crosstalk coupling (long-distance crosstalk coupling) " depending on whether the transition from the eagle group smaller to the vein group larger Swirl or vice versa takes place. One has to combat the difficulties that arise thereby so far the veins of the individual wire groups at the connection points the cable manufacturing lengths connected to the wires of other wire groups, so that the same conductor loop in one fabrication length on another Place was as in the neighboring.

However, this requires a relatively large amount of attention when connecting the cable lengths to each other and leads above all to difficulties in repair work, because the same conductor loop in each cable length in a different core group of the cable structure. -With the increase in operating frequencies has also increased shown that these hitherto customary measures do not have the desired effect on the exchange Reduce measure.

The arrangement genläß the invention eliminates the particular in high carrier frequencies occurring difficulties due to the fact that the mean twist of all wire groups is made approximately the same over a certain distance, where in each vein group stretches with larger and smaller than the middle one Alternate twist with each other. In this way it is achieved that when interconnected of the cable lengths, the corresponding wire groups of each length are interconnected can be, so that a certain conductor loop in the entire cable connection each lies in a specific core group that is the same for all cable lengths. Even in the embodiment according to the invention, of course, the twists are different Groups of wires in a given piece of cable are all different from one another.

The higher the operating frequencies of the cable, the shorter it becomes expediently chosen the distance over which the mean twist is all the same. Up to frequencies of a few hundred kHz, however, it is sufficient with today's standard Fabrication lengths of the cables, the mean twist of all wire groups in such a cable To make manufacturing length the same.

In a further embodiment of the invention, at least one group of cores can be provided which has the central twist itself unchanged over the entire route. This can be done with the so-called counting quad, especially in the case of layers with a finite odd number of wire groups, while the other wire groups are then always designed alternately according to a twist scheme I and a twist scheme 11 , with the veins that were previously in accordance with scheme 1 at certain intervals were stranded, are further stranded according to scheme 11 and vice versa.

In the drawing some cross-sections of cables are shown, in which the invention is applied. For the sake of clarity, is in each case only one layer of the cable is drawn while the conductor is in the core or further out lying layers are omitted. In the embodiment shown in FIG a layer with an even number of wire groups is shown. Balancing the twist the individual 2 @ dergruppen is now achieved in that in the first half of the Fabrication length the finite tin-even numbers denoted core groups one each longer, the groups of cores marked with even numbers have a shorter pitch of the stranding, the twists of the fours i, 3, 5, 7, 9 somewhat from one another are different, as are the twist lengths of the fours 2,: 1, 6, 8, io. The other way around in the second half of the fabrication @, the odd-numbered groups would be shorter and the even-numbered a longer stroke. Fig. 1a accordingly shows a cross section in the second half of a production length of this cable.

In Fig. 2 a position with an odd number of wire groups is shown, where the count quad is denoted by i. -Except for this four-count, the the same over the entire length of manufacture, namely the middle one Possesses twist, the arrangement is here again made in such a way that in the first one Half of a production length, the odd-numbered wire groups are longer, the even-numbered ones have shorter stroke (shown in Fig. 2a), while in the second half the the even-numbered longer and the odd-numbered shorter beats (Fig. 2 b). In order to get as close as possible to the middle twist, one combines in a four short and long twist preferably so that the shortest twist is the longest Twist follows, while a half-short one is followed by a half-long twist. To this In this way one achieves that the number of twisting turns is approximately the same in all fours will.

Finally, in Fig. 3 there is an arrangement with nine wire groups, their twist lengths are all different from one another, three of which are shown with one each middle pitch, unchanged over the entire cable length, are stranded, while of the six remaining groups 2, 5 and 8 are short in the first half of the length, have a long stroke in the second half, it would be for core groups 3, 6 and 9 is reversed. Accordingly, F-ig. 3 a again a cross section in the first Half, Fig. 3 b a cross section in the second half of the cable length.

If you do not value twist compensation within a single cable length, so each the Fig. 1a, 2a and 3a represent cross-sections at any point Cable length, the Fig. I b, 21), 3 b cross-sections at any point of the before and behind this arranged cable length. The individual cable lengths of the cable are then made according to two different twist schemes, e.g. B. lengths with straight lines Numbers according to scheme I, those with odd numbers according to scheme I1.

Claims (1)

PATENT CLAIMS: i. Multi-core cable for the transmission, in particular, of carrier currents of high frequencies with groups of wires, e.g. B. Star fours, each with a different twist length of twist combined, characterized in that the mean twist of all groups of veins is approximately the same over a certain distance without interchanging the lengths of four; where iii <lcii single vein groups stretch with "i-oil: iereni and smaller than (lern middle alternate bulging with each other. 2. Cable line according to claim i, characterized in that indicates that the route over which the lere twist of the groups of veins made the same size is, höclisteiis is as big as a fabrication. l: iiige of the cable. 3. Cable line according to claim i, characterized in that indicates that the mean twist of the vein groups on a route of two factories tion lengths can be achieved without exchanging four by using two groups of fabrication lengths with different twist schemes. , 4. Cable line according to Claims 1 to 3, characterized in that at least one group of cores is provided which has a mean twist unchanged over the entire route. 5. Cable line according to claim 4, characterized in that one of the core groups of unchangeable mean twist is characterized and used as a count quad.