DE2557179C2 - Line arrangement - Google Patents

Description

Cable runs (1,2) with lateral branches (A, B, C ₁ D) are formed.

7. Line arrangement according to one of the preceding claims, characterized in that the line pairs consist of etched lines (I ₁ 2).

8, line arrangement according to one of the preceding claims, characterized in that in The same number of cable runs are arranged at each management level.

The invention relates to a line arrangement with at least one provided with plated-through holes Circuit board laminated on both sides, with a level with at least two one on both sides Line pairs forming line runs is formed

For the transmission of signals in communications technology, twisted pairs of cables are preferred used where there is a risk of electromagnetic interference (DE-OS 23 28 974). By twisting a pair of wires, the cross-section of a conductor loop becomes as close as possible kept small; this leaves the interference voltage induced in the conductor loop by a magnetic field also small. In addition, the twisting causes a reorientation of the induced interference voltages on each two adjacent line sections, whereby these interference voltage contributions are mutually exclusive compensate. Overall, twisting reduces the influence of induced disturbances compared to non-twisted disturbances Line pairs beträc '' borrowed, with additional the advantage of high packing density results.

The invention is based on the object of creating a line arrangement with twisted line routing for printed circuit boards laminated on both sides.
This object is achieved according to the invention in that two line runs, which form a line pair and are provided in different line levels, are arranged in two parallel side-by-side strip conductors and at several points at regular intervals via a through-hole connection in each case from one line level to the other line level, and that each line between two successive lead-through points in the line from one conductor track to the other conductor track is alternately routed.

With this line arrangement, the twisting of two lines forming a line pair is ensured by an advantageous arrangement of the lines in the line levels and an alternating routing of each line from one line level to the other, as well as an appropriate distribution of through-contacts in the course of the conductor tracks and a meandering course of the two Lines of a line pair reached between the vias. The main advantage is therefore that twisted pairs of lines can be built up in a very simple manner in line arrangements, for example on printed circuit boards laminated on both sides. In this case _(can be the signal-to-noise ratio improve. There are not required changes to existing Herslellungsverfahren for printed circuit boards. In addition, line guides were made possible with side branches. Another advantage is in the use of twisted wire pairs as multiple

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lines, also lateral branch lines are possible (data bus). In this way, particularly space-saving arrangements of line pairs can be achieved will. By combining individual pairs of lines into sub-bundles, additional space is saved possible, but dispensing with unrestricted lateral branching options.

If, due to the circuitry, signal cables are on top of printed circuit boards laminated on both sides are to be routed, these lines are routed, in particular from a line length of about 0.5 m, expediently as etched cable runs.

Multi-layer line arrangements can also be used, in which line runs in more than two line levels are arranged to be crossed in this way.

Advantageous refinements of the subject matter of claim 1 are related to the subclaims remove.

In the following an embodiment of the invention with reference to schematic drawings explained in more detail The figures each show Dra. View on line pairs of a not shown, one Circuit board forming a line arrangement, laminated on both sides. At the top of the circuit board in the Lines of lines running along a line level are indicated by solid lines on the underside of the Printed circuit board in the second line level ■ guided Cable runs, on the other hand, are shown by dashed lines. Execution points of the cable runs through the Circuit boards are marked with small circles. Here, the pairs of lines are made of etched Cable runs.

The F i g. 1 shows a possible embodiment of a twisted line with branch options on both sides. This is of particular importance in the case of multiple lines (data bus). With attention the minimum permissible distances between two adjacent vias are at least two side by side ..- lying conductor tracks are required for the construction of a twisted pair of cables. This is at the embodiment according to FIG. 1 the case. There are two line runs 1 and 2 forming a line pair provided, the cable run 1 at the beginning of the line on the left edge of Fig. 1 on the Top of the circuit board, the Leitm.gszug 2 against it is guided on the underside of the circuit board. The lines 1 and 2 are in two parallel side by side Conductor tracks, i.e. two lanes, are arranged. These are used to twist the cable tracks 1 and 2 guided in such a way that they are from one management level on the one side of the platform to the other management level on the switch from the other side of the board and from one track to the other. For this purpose, the lines 1 and 2 are in several places at regular intervals short distances via a through-hole 3, 4 or 5, 6 etc. for each bushing one Cable run alternately from one side of the plate to the other side of the plate. In the standard version According to FIG. 1, the line 1 lying in the one conductor track runs up to the plated through hole 3 on the top of the plate and then changes to the underside of the plate, on which he goes to the next Through contact 4 runs, while the line 2 lying in the second conductor track up to Through-contacting 5 is guided on the lower side of the plate and then changes to the upper side of the plate and there runs up to the following through-hole 6 in this cable run. Successive individual sections, z. B. the sections 7 and 8,9 and 10 etc. of the cable run 1 or the sections 11 and 12,13 and 14 etc. of the cable run 2 are thus located on different plate sides, so in a total of two Management levels. In addition, each line is between two consecutive lines in the line Implementation points, so the line 1 between the vias 3, 4 on the

ίο the bottom of the plate and the line 2 between the vias 5,6 on the top of the plate, alternating from one conductor track to the other conductor track. In the embodiment according to FIG. 1, the plated-through holes 3, 6 of a conductor track are offset in the longitudinal direction of the conductor tracks with respect to the plated-through holes 5, 4 of the other conductor track belonging to a line pair. So is z. B. the first via 3 of the lead block 1 in the longitudinal direction of the conductive path viewed before the first Durchko ⁿ * iktierung 5 of the I eitungsziiges 2 and the second Durenkontaktierung 6 of the line the train 2 before the second via hole 4 of the line train 1. Accordingly, the line section 1 of the line pair z. B. between the two vias 3 and 4 following one another in the line run after the passage from the top of the plate via the via 3 to the underside of the plate in a first section 15 and a second section 16, initially continued in the conductor path in which it ran before the implementation, while the second line 2, which was changed before the implementation on the underside of the plate and via the plated-through hole 5 to the top of the plate, is routed at right angles to the conductor path of the first line 1 immediately after the implementation, so that the two lines 1 and 2 of the line pair are in the second section 16 on the same track are Leite ^r, the second line section 2 to the next via hole 6 and beyond the section 18 '.ediglich for reasons of greater clarity, in Fig. 1 as well as in the subsequent figures, on one and the same conductor track running sections of cable runs drawn close to one another. The first line pull is against it! after the second section 16 at right angles away from the common conductor track, alternately guided to the other conductor track on which the second conductor run 2 ran over the plated-through hole 5 before it was passed through. On this conductor track, the line 1 is guided in a third section 17 to the through-hole 4 following this line. This change of the line runs from one side of the plate to the other side of the plate and from one conductor to the other take place several times in the same way as shown and described. The cable runs thus run in a meandering manner in the plate vertical and in the line levels parallel to the plate level. The etched branch lines to both sides of the line pair, for example possible in this embodiment, are indicated by A, B and C, D.
It is also possible that in contrast to Fi g. 1 the vias are juxtaposed, e.g. B. the vias 3,5 and the vias 6, 4, so are not offset from one another. In this case each cable run is a cable pair

between two iffi Leiiufigszug AUFifiäfideffölgeiTden Implementation points after implementation on the other side of the panel in a first section continued in the conductor path in which it ran before the implementation. Then one of the two line runs after the first section away from one conductor track to the other conductor track led alternately so that both lines of a line pair in a second section on and and finally the other one is on the other side of the plate Line run after the second section away from the common conductor track to the other conductor track alternately out on which the first cable run in the first section.

2 shows a possible embodiment of the space-saving structure of two twisted pairs of lines with branching options B, E and F. G to both sides dsr. For the Resl d

The following simplification results: every twisted pair of a cable bundle should only allow branches to one side. The twisted pairs of lines that allow branches on the same side are combined into two sub-bundles, which are arranged next to or one above the other according to F ί g. 6. This results in branching options N ₁ M ₁ Dog I, F, G to one side each, whereby ten conductor tracks are required for twelve cable runs.

The number of required conductor tracks N results here generally from the number η of the twisted line pairs used

W = 2 (/ 1-1) ^ = 4,5,6,7 ...).

A further space saving results if lateral branches are dispensed with. Under this

Vnraiiccpt7iina lacepn ciph ipwpil.Q 7Wfii! .EituncrKnaarf?

at least three adjacent or, in the case of multilayer line arrangements, one above the other Conductor tracks are required in which the four lines are routed. The change of the cable runs from one The plate side to the other side of the plate and from one conductor track to the other is carried out by hand the F i g. 1 in an analogous manner.

In the F i g. 3 and 4 is an embodiment of three twisted wire pairs with branch options H, E and /. F, G shown on both sides. By using the in F i g. The modification of the drilling scheme at K shown in FIG. 4 ensures that all three pairs of lines can cross one another on both sides. For the practical structure according to FIGS. 3 and 4, at least five adjacent or superimposed conductor tracks are required for six cable runs

F i g. 5 illustrates the expansion of a line system to four twisted line pairs with branch options H, and C. F, I, L on both sides. The in F i g. The modification shown in FIG. 4 can also be used with four or more twisted wire pairs. Two twisted wire pairs can then be crossed on one side and as many as desired on the other side. For a structure according to FIG. 5, at least seven adjacent or superimposed conductor tracks are required for eight cable runs.

In general, the number of conductor tracks N required in the previously described construction system (FIGS. 1 to 5) can be calculated from the number π of the line pairs used

N = 2n - \ (n = 2.3A ...).

In the following, line systems with limited branching options are shown. If the requirement is dispensed with that each twisted line pair of a line bundle accommodates all neighboring twisted line pairs of the same structure on three adjacent or superimposed conductor tracks. 7 shows an example with six twisted wire pairs, for which nine conductor tracks are required. The number of required conductor tracks / is assigned for this system with the number η of the twisted wire pairs used for

a) even; i = 2. 4, 6, ...

b) odd »= i. 3, 5. 7. ...
N ₁ . = lJL ± A.

F i g. 7 also shows that this system also allows branches to be etched to one side for the two outer pairs of lines of a bundle, or if the modification according to FIG. 4 K for each of the three outer pairs. If branches are required from one of the pairs of lines further inside the bundle, two options can be used:

a) while maintaining the space-saving drill system, the branches are soldered through Wire bridges made

b) The drill system is expanded at the point of junction and into one of the above described drill systems transferred

8 shows one of several such transfer options, e.g. B. for six twisted wire pairs of nine conductor tracks with limited etched branching options on eleven conductor tracks with any etched branching options.

For this purpose 3 sheets of drawings

Claims (6)

25 claims: 1. Line arrangement with at least one provided with vias and laminated on both sides Printed circuit board with a level with at least two pairs of wires on both sides forming cable runs is formed thereby characterized in that two lines forming a line pair are provided in different line levels Cable runs (1,2) arranged in two parallel side-by-side conductor tracks and on several places at regular intervals, each via a through-hole (3, 4, 5, 6) from the one management level in the other management level are alternately led and that each line of cables (!, 2) between two consecutive feed-through points (3, 4 or 5, 6) from one conductor track to the other conductor track v. t.chselnd is managed. 2. Line arrangement according to claim i, characterized in that each cable run (1, 2) one first pair of cables /. between two in the cable run successive implementation bodies (3, 4 b / w 5, 6) after implementation in the other First level of exercise in a first section that conductor track is guided in which it ran before the implementation that one of the two line / üge (1, 2) after the first section away from its conductor track to the other Conductor is routed w.rhselnd in such a way that both lines of a line pair are in one second section are on one and the same conductor track and that the other, in the other Line level running line after the second section of the common track is alternately returned away to the first conductor track. 3. Line arrangement according to claim 1 or 2, characterized in that the vias (3, 6) of a conductor path opposite the vias (5, 4) of the other conductor path belonging to a line pair in the longitudinal direction of the conductor tracks are offset. 4. Line arrangement according to claim 3, characterized in that a cable run (1) one Cable pair between two consecutive feed-through points (3, 4) in the cable run after the implementation in the other management level in a section (15, 16) initially in that Conductor is continued. in which it ran before the implementation and that the second, in the other line level running line (2) of the line pair immediately after the Implementation on the conductor track of the first cable run (1) is alternately performed in such a way that both cable runs (1,2) of a line pair in a second section (16) on and the same conductor track are located and that the first line (1) after the second section (16) of the common conductor path is alternately returned to the second conductor path. 5. Line arrangement according to one of Claims 1 to 4, characterized in that the line sections (I ₁ 2) are alternately guided at right angles from one conductor track to the other conductor track. 6. Line arrangement according to one of the preceding claims, characterized in that the 7Q ι jr