EP1091362A2 - Data transmission cable and method of manufacture - Google Patents

Abstract

The data transmission cable comprises at least one line pair (1) consisting of two parallel electrical conductors (2) and insulating covers (3) which are joined to one another to form a single component extruded onto the conductors. Also claimed is a method for producing such line pairs. It involves extrusion of the insulating covers as a single component.

Description

The invention relates to a data transmission cable with at least one pair of conductors and a method for producing such a data transmission cable.

Such a data transmission cable is for example from US 4,873,393 known. Several wire pairs are arranged within an outer cable jacket, which are formed from two single wires stranded together. At a However, data transmission cables are capacity asymmetries distributed over the cable length of the wire pairs is problematic because these impedance fluctuations and Signal energy losses and crosstalk effects and thus cause Transmission properties of the data transmission cable, especially in the required by the relevant standards ISO / IEC 1181 (2nd edition) and pr EN 50288 high frequencies of up to 600 MHz, deteriorate.

The causes of the capacity asymmetries are fluctuating distances between the conductors of a pair of wires and in particular changing diameters of the wire sheaths. Therefore, in the manufacture of data transmission cables elaborate production monitoring and quality control required. At Conventional data transmission cables are first made through single wires Extrusion manufactured. To do this, an electrical conductor is passed through a circular extrusion nozzle an extruder and with an insulation material encased in a thermoplastic. Despite monitoring the Extrusion parameters, in particular the temperature, the extrusion pressure and the extrusion speed, fluctuations in the wire diameter can be observed and the material consistency of the wrapping material is practically incomplete avoid.

For example, pressure changes during extrusion cause different Extrusion quantities and therefore different wire diameters. It is therefore additional an elaborate quality control is required in order to be intolerable To sort out veins. The suitable wires are then stranded into pairs. This is due to diameters or material fluctuations Impurities in the individual wires are randomly arranged next to each other, which results in the asymmetry of the capacitance of a pair of wires still promotes. Previous data transmission cables of this type are therefore only suitable for frequencies up to approximately 600 MHz.

The invention has for its object to provide a data transmission cable without the ISO / IEC 1181 (2nd edition) and pr EN 50288 standards leave the specified tolerance ranges in a particularly simple manner can be produced.

This object is achieved according to the invention with regard to the data transmission cable by the features of claim 1 and in terms of its manufacture by solved the process features of claim 8.

A data transmission cable according to the invention contains at least one pair of wires, the one-piece interconnected by a common extrusion has claddings applied to a pair of conductors. This approach has first the advantage that the distance between the conductors of a pair is exact can be met. It is also advantageous that fluctuations in the Always affect extrusion parameters simultaneously on both wires of a wire pair. Inhomogeneities in material consistency as well as diameter fluctuations are therefore symmetrical.

The result is that extrusion-related capacity fluctuations over the length seen the line pair, run almost synchronously. Opposing Areas of the single cores therefore always have comparable capacities, so that asymmetries are avoided. Accordingly, the proposed one Data transmission cables are lower than conventional cables Impedance fluctuations and less crosstalk effects. Besides, is the data transmission cable according to the invention for transmission frequencies up suitable at least 2000 MHz. In addition, the data transmission cable according to the invention easier, namely with comparatively little effort producible for quality monitoring.

The shape of the extrusion die is chosen so that the cylindrical envelopes touch in a line. The two envelopes are thus in one piece with one another connected and the mutual distance between the electrical conductors is exact fixed and practically unchangeable.

In an expedient embodiment, the sheaths are a pair of wires connected to each other via a bridge. Such a pair of wires can be opened simply disconnect, for example to fix the single wires to connectors. Have proven to be particularly advantageous for the insulating material of the envelopes the plastics polypropylene, polyethylene and copolymers from hexafluoropropylene and proven tetrafluoroethylene.

In a particularly advantageous embodiment, there is a connector at one end of the cable with contact elements for fixing the electrical conductors of a pair of wires arranged. The grid dimension of the contact elements corresponds to that Distance of the electrical conductors in the wire pair, so that a separation of the wire pairs can be omitted. The geometry of the wire pair remains up to the Receive transfer points so that transmission losses due to reflection are minimized are.

Further advantageous refinements can be found in the subclaims.

Fig. 1 bis 7

verschiedene Bauarten eines erfindungsgemäßen Datenübertragungskabels,

Fig. 8

ein Diagramm, das die Impedanz eines erfindungsgemäßen Datenübertragungskabels in Abhängigkeit von der Signalfrequenz wiedergibt,

Fig. 9

ein Diagramm, das das Dämpfungs- und Nebensprechverhalten in Abhängigkeit von der Signalfrequenz zeigt, und

Fig. 10

einen Steckverbinder des Datenübertragungskabels.

Exemplary embodiments of the invention are explained in more detail below with reference to a drawing. In it show:

1 to 7

different types of a data transmission cable according to the invention,

Fig. 8

2 shows a diagram which shows the impedance of a data transmission cable according to the invention as a function of the signal frequency,

Fig. 9

a diagram showing the attenuation and crosstalk behavior as a function of the signal frequency, and

Fig. 10

a connector of the data transmission cable.

Figures 1 to 7 show data transmission cables in cross-sectional representation. All Data transmission cables contain at least one consisting of two wires Pair of wires 1. A wire comprises an electrical conductor 2, preferably made of Copper, optionally coated with tin or silver, and a coating 3 from an insulation material, e.g. B. made of polyethylene. The casing 3 can also be built up in multiple layers (e.g. skin-foam-skin).

The conductor 2 can be a wire or a strand. The two envelopes 3 are in one piece by a common extrusion process formed and connected to each other via a web 4. The web 4 extends extends over the entire length of the veins and runs in the transverse direction of the Wire pair 1, based on the imaginary connecting line between the center points the leader 2.

In the exemplary embodiments shown, the individual wires are stranded together, therefore have a twist. With the data transmission cables according to the Figures 1 to 3 and 6 are the wire pairs 1 of a shield 5, z. B. from one aluminum-clad film. The wire pairs can also be used without twist be formed, in which case two pairs of wires 1 lie parallel to each other.

1 contains two wire pairs 1, while the the remaining data transmission cables each contain four wire pairs. One with the Exemplary embodiments according to FIGS. 1 to 5 provided overall shielding can, for example, from a metal foil 6a or through a screen braid 6b. Such a screen braid 6b improves the one mechanical cohesion of the wire pairs comprised by this and improved also the electromagnetic compatibility (EMC) of the shield. It is also conceivable that the shielding from a metal foil 6a and from one Shield braid 6b is formed (Fig. 4).

The shielded or unshielded package of several pairs of wires 1 is finally by a cable sheath 7, for example made of PVC. If necessary an FRNC material (flame retardant, Non-Corrosive) or LSZH material (Low Smoke, Zero Halogen) can be used. In the embodiment of FIG. 3, two cables are on one of them Cable sheath 7a connecting web 8 held together. Within a drain wire 9 is arranged on the overall shield 6b.

The measured values shown graphically in FIGS. 8 and 9 were also measured on wire pairs 1 a width of 4.2 mm and a height of 2.0 mm and a web width of Get 0.2 mm. The diameter of the conductor 2 was 0.64 mm. As material for the envelopes 3 were made of solid PE. As a shield 5 for the Wire pairs 1 became an aluminum-laminated film strip with the dimensions 20mm x 0.065mm inserted.

8 shows the impedance behavior as a function of Signal frequency again. Lines A limit that of the standards ISO / IEC 1181 (2nd edition) and pr EN 50288 specified tolerance range for the Impedance. The measurement curve B entered between the lines A gives the measured ones Values again. It can be seen that in a range from 1 to 300 MHz standard tolerance is far below. The impedance fluctuations here are values below ± 2 Ω. In the frequency range from 300 to 600 MHz, the impedance fluctuations are less than ± 6 Ω. The standard tolerance range however, provides for a fluctuation range of ± 25 Ω. The diagram it can also be seen that in a data transmission cable according to the invention still permissible up to a frequency value of 2000 MHz Impedance fluctuation range is available.

9 shows the crosstalk behavior and the attenuation of the above cable is shown depending on the frequency. The for the values determined for the crosstalk behavior, the measurement curve shows C. All values are above those specified by the prEN 50288-4-1, Category 7 standard Limit values (reference curve D). In the lower part of the diagram are those of the limit specified for the attenuation by the reference curve E reproduced.

The values for the attenuation measured on the cable described above are represented by the measurement curve F. These values are up to that of the standard prescribed maximum frequency of 600 MHz in the permissible range. The The diagram is still the signal-to-noise ratio, i.e. the difference between the dB value of the useful signal (curve E or F) and the dB value of the interference signal (curve D or C). At the maximum value of 600 MHz, a signal-to-noise ratio of 10 dB is permissible, while in the examined Data transmission cable there is a signal-to-noise ratio of about 50 dB. At a Frequency of 1600 MHz (dashed vertical line in Fig. 9) is still a signal-to-noise ratio of about 20 dB.

Fig. 10 shows a preferred connector 10 of the pair of wires 1 with opposite Fixing elements 11, 12 for fixing and contacting the conductor 2 of the wire pair 1. The fixing elements 11, 12 are each in a half-shell 10a or 10b of the connector 10 is provided and there at the apex of at least approximately receiving recesses adapted to the outer contour of the pair of wires 1 13 arranged.

This connector 10 causes interference in the transmission properties of the pair of wires and thus the data transmission cable avoided by the geometry specified by the wire pair 1 in the connector 10 remains the same is continued. For this purpose, the contact and fixing elements 11, 12 designed as insulation displacement contacts are narrower at their contact tips than the diameter of the copper conductor 2 within the respective wire of the wire pair 1 and thus do not protrude over the conductor 2 into the dielectric, that is to say into the casing 3. This ensures a constant distance between the two conductors 2 within the connector 10. It is essential that the contact elements 11 in the upper half-shell 10a and the contact elements 12 in the lower Half-shell 10b of the connector 10 at the same distance from each other are like the two conductors 2 of the wire pair 1.

The execution of such a coextruded core pair 1 on the one hand and the Execution of the connector 10 on the other hand ensures in contrast to two individually extruded wires that when pressing the two half-shells together 10a and 10b, the conductors 2 are positioned exactly when cutting in the contact elements 11 and 12 can be contacted. This ensures reliable contacting the conductor 2 avoiding a change in their distance from each other in the Connection with the connector ensured. In addition, the ensures special structure of the cutting contacts or contact elements 11, 12, that the cable geometry within the connector 10 with exactly the same Impedance is continued, so that losses at these contact points are reliable are avoided.

Reference list

1

Wire pair

2nd

ladder

3rd

Wrapping

4th

web

5

shielding

6

Overall shielding

6a

Partial film

6b

Screen braid

7

Cable sheath

8th

web

9

Drain wire

10th

Connectors

10a, b

Half shell

11.12

Fixing elements

13

Receiving troughs

A

line

B

Measurement curve

C.

Measurement curve

D

Reference curve

E

Reference curve

F

Measurement curve

Claims (8)

Data transmission cable, which for a transmission frequency of more than 600 MHz is formed, with at least one wire pair (1) of two in parallel arranged side by side and each have an electrical conductor (2) and one Enclosure (3) made of wires with insulating material, the envelopes (3) integrally connected and by a common extrusion are applied to a pair of conductors. Data transmission cable according to claim 1,
characterized,
that the pair of wires (1) is surrounded by a shield (5). Data transmission cable according to claim 1 or 2,
marked by
a plug connector (10) arranged on a cable end with contact elements (11, 12) for fixing the electrical conductors (2) of a pair of wires (1), the pitch of the contact elements corresponding to the spacing of the conductors (2) in the pair of wires (1). Data transmission cable according to claim 3,
characterized,
that the contact elements (11, 12) are designed as fixing elements in the form of insulation displacement contacts. Data transmission cable according to one of claims 1 to 4,
characterized,
that the envelopes (3) are connected to one another via a web (4). Data transmission cable according to one of claims 1 to 5,
characterized,
that the insulating material is polypropylene, polyethylene or a copolymer of hexafluoropropylene and tetrafluoroethylene. Data transmission cable according to one of claims 1 to 6,
characterized,
that it is designed for an impedance range of 80 to 150 Ω. Method for producing a data transmission cable with at least one Pair of wires (1) each consisting of two wires arranged in parallel next to each other an electrical conductor (2) and a cylindrical sheath, wherein the two envelopes (3) by a common extrusion the conductors (2) are applied by connecting them in one piece are.

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