EP1163684A1

EP1163684A1 - Cable shield made of fibre reinforced material

Info

Publication number: EP1163684A1
Application number: EP00914037A
Authority: EP
Inventors: Wolfgang Kreitmar-Steck; Wolfgang Tauber
Original assignee: Eurocopter Deutschland GmbH
Current assignee: Airbus Helicopters Deutschland GmbH
Priority date: 1999-02-23
Filing date: 2000-02-23
Publication date: 2001-12-19
Also published as: WO2000051143A1; BR0008412A; JP2002538581A; DE19907675A1

Abstract

The invention relates to a device for electromagnetically shielding any kind of electrical conductors (e.g. component conductors, conductor bundles and coaxial cables). The main advantage in comparison with the shields used so far is a significant reduction in weight and an improved damping in the high MHz range. This is achieved by using materials (e.g. carbon fibres) as shields, whereby said materials are provided with an essentially lower conductivity than metal shields. Even metal shields are not damped in the lower frequency range, the existing conductivity in the higher frequency range (⊃ 1 MHz), however, is high enough to attain the transfer impedance values of metal shields due to the fact that inductive and capacitive losses are less important, whereby said effect is utilised. Another advantage of the invention is that the shield is not affected by corrosion and can be produced in a substantially easier manner in relation to metallic conductive shields. The invention can be especially be used as cabling in aircrafts and motor vehicles requiring weight-reducing solutions.

Description

Title of the invention:

Cable shield made of fiber composite materials

Brief description and field to which the invention relates:

Cable shields are often used to shield electromagnetic fields and to prevent electromagnetic coupling within systems / platforms due to their great protective effect. The shields currently used for this are based on highly conductive metallic materials. Except when using special shielding materials (e.g. mu-metal), the damping behavior of these shields only begins in the upper kHz range and strives towards a finite damping value with increasing frequency. In addition, the umbrellas used are generally very heavy and therefore rather unsuitable especially for flying platforms.

The invention relates to a device according to the preamble of claim 1. The electromagnetic shielding of system cabling proposed in this publication has the task

■ undertaking a weight optimization (up to 70% less than with normal metallic cable shields) in the frequency range from a few MHz to the GHz range to achieve a shielding effect which is similar or better than that of metallic shields and which is thereby easier to manufacture;

■ in the HF / VHF / UHF frequency range to significantly improve the shielding behavior of metallic shields, whereby a weight reduction is also possible here.

Basic principle on which the idea is based:

The basic principle of the invention is that fiber composite materials with a high proportion of electrically conductive fibers (e.g. carbon fiber or metallized carbon fibers) are used as the shielding material. The so-called transfer impedance, which allows the comparison of electrical properties of cable shields, is generally used as a measure of the shielding effect of a cable shield. The transfer impedance can be calculated from the following measured variables in a test setup in accordance with VG 95373 Part 15 (measurement method for coupling and shielding, KS01):

U OL

'Disturbance

U _0L = open circuit voltage under the screen I _fault ⁼ _injected interference current on the screen In the case of metallic cable shields, it is known that, except for some special cables with mu-metal, the damping behavior only begins in the upper kHz range or at even higher frequencies (see Figures 9 and 10 from publication l \ l), provided that the cable shield is connected at both ends to the connector housing. This result is confirmed by the following attenuation equation for cable shields in publication 121:

20 log [µ ₀ f / (2 Z _τ )] / dB

μ ₀ = permeability constant (= 4π l0 ⁷ As / V / m) f = frequency a _s = damping value

Z _{τ =} transfer impedance

This equation can be used when the wavelength is much larger than the cable shield length.

The beginning of the attenuation in the higher kHz range is generally sufficient, since up to these frequencies the field coupling is relatively low or the crosstalk of neighboring lines is attenuated with 80 dB and more even with closely adjacent line routing. It is only when cable lengths in a system come in the range of 1/10 of the wavelengths and longer that the use of cable shields is of the greatest interest. So it can easily be that e.g. with system cabling lengths of maximum 3m, a cable shield only has to have its optimal shielding effect at 10 MHz. In addition, other factors with regard to this limit frequency to be used are also decisive, such as the signal characteristics of neighboring lines or the frequency of the incident electromagnetic field.

If the analysis of a system and its cabling reveals that shielding attenuation is only necessary in the MHz range, a device according to claim 1 can be used to switch to cable shields made of fiber composite materials with a high proportion of electrically conductive fibers. In addition to the clear advantage of an almost negligible additional weight compared to the unshielded cable, this also gives the advantage of corrosion resistance.

If the system analysis reveals that electromagnetic damping is also necessary for lower frequencies, the screen made of fiber composite materials can be combined either with a metallic screen or with a screen with high relative permeability. As an alternative to this, the synthetic fibers could also be vapor-coated with appropriate ferromagnetic materials. State of the art on which the invention is based:

It is known that cable shields made of electrically highly conductive materials attenuate electromagnetic fields from a lower cut-off frequency if they are connected at their ends to the device housing or the connector housing. If only inadequate plug connections are used or shields are not connected to the connector housing at all, the damping disappears. Fiber composite materials are only mentioned as mechanical protection, as some of the following patents show.

U.S. Patent 5556697: Semiconductive power cable shield

This invention assumes that a semiconducting screen is applied directly to electrical conductors (especially to power cables), which is then surrounded by an insulation layer and an outer screen. The special chemical composition of the semiconducting screen offers the advantages of lower shrinkage behavior, lower water permeability, better processability compared to other semiconducting screens, and more favorable electrical properties. In contrast to the present invention, in which an electrical insulation layer is provided between the electrical conductor and the cable shield made of fiber composite material, in US Pat. No. 5,556,697 the semiconducting cable shield is applied directly to the conductor. The task of electromagnetic shielding cannot be achieved with this.

U.S. Patent 5554678: Electromagnetic shielding composite

The object of the invention in US Pat. No. 5,554,678 is to define composite materials which ensure electromagnetic shielding of housings for electronic devices. The goal here is to achieve good shielding effectiveness in low and high frequency ranges. This task is solved by a composite material, which consists of defined proportions of thermoplastics, conductive metal fibers and carbon fibers. Here, basic physical properties of the carbon fibers or the carbon fiber-containing fiber composite materials are used, which are also important for the cable shields - the subject of the present invention. Neither the tasks nor the implementation according to US patent 5554678 in the form of plates or other shaped housings overlap with the present invention.

U.S. Patent 4,538,151: Electro-magnetic wave absorbing material

The object of this invention is the coating of metal surfaces for the absorption of electromagnetic waves (eg for radar camouflage) over a large frequency range. This is achieved on the basis of the invention by mixing a molecular, synthetic synthetic resin with highly conductive metal fibers and a ferromagnetic material. In contrast to the present invention, this is a highly rigid coating of surfaces for the absorption of electromagnetic waves, which cannot be used for a cable shield with the desired properties.

Patent DE 195 45 559 AI:

The object of this invention is the interference suppression of electrical assemblies or circuits by sheathing with embedded absorber material made of ferrites or dielectrics with polarized particles.

In contrast to this, the present invention requires electrical conductivity of a non-metallic material and differs in that no absorber material in the form of a dielectric or in the form of ferrites is used.

Patent DE / EP 0528 611 AI:

The object of this invention is the production of a conductor and cable article which offer protection against conducted signals on the line and emitted EMI (electromagnetic interference). This is achieved by using only a single layer of material consisting of spherical ferrite particles or shaped ferrite particles which are distributed within a polymeric binder / polymeric matrix (e.g. fluorocarbon, polymer).

This invention differs from the present invention in that neither spherical ferrite particles, shaped ferrite particles nor a polymeric matrix such as "fluorocarbon" or "acrylates" is used, but rather an electrically conductive non-magnetic material. In addition, the frequency range affected in the present invention differs significantly from that specified in invention DE / EP 0528 611 AI.

All other claims of DE / EP 0528 611 AI do not affect the electromagnetic shielding and the subclaims and are therefore meaningless with respect to the present invention.

Patent DE 298 02 010:

The object of this invention is the elimination of cable vibrations / vibrations caused by periodic vibrations of the wires by their wire spacing and the associated inductive and capacitive undesirable changes in the line characteristic. This is achieved by introducing additional single lines made of non-metallic fiber (including carbon fiber) as a further strand element.

This invention differs from the present invention in that the task of the non-metallic fibers is not electromagnetic damping, but rather they are used only as non-inductive spacers. In the present invention there is an all-round sheathing of electrical lines Prerequisite for achieving electromagnetic damping. In addition, in DE 298 02 010, the metallic strands are followed by an insulation layer, over which the cable shield is finally applied.

All claims do not affect the electromagnetic shielding and the subclaims and are therefore not relevant to the present invention.

Patent DE 39 40 293:

The object of this invention is to create a ribbon cable, the outer conductive layer of which, compared to the prior art, has improved flexibility and conductivity. This is achieved by surrounding the ribbon cable made of several signal conductors with a screen made of non-conductive material, in which carbon fibers obtained from high-melting particles are distributed and coated with a metallic coating.

This invention differs fundamentally from the present one in that no high-melting particles and no metallization are used in the present invention. In addition, the present invention is not limited to a strip conductor, but is applicable to any type of electrical conductor.

All other claims of DE 39 40 293 do not affect the electromagnetic shielding and the subclaims and are therefore meaningless with respect to the present invention.

Patent DE 38 780 22:

The object of this invention is the assembly of a cable shield jacket for protection against electromagnetic radiation from power cables in the low-frequency range (<100 kHz). This is achieved through the use of conventional metallic screens and assembly using a special screw connection and the use of multi-layer insulation.

The present invention differs in that conductive, non-metallic materials are used as electromagnetic screens which can only be used for the high frequency range (> 1 MHz), both for power supplies and for any signal line or multiple line.

Patent DE 34 38660:

The object of this invention is to improve a cable so that it can be manufactured and handled more easily. This will be achieved by one or more leads, each surrounded by an insulating material, from one common shielding layer is encased, which consists of a mixture of plastic with electrically conductive particles, preferably aluminum scales.

This invention differs from the present invention in that instead of plastic with electrically conductive particles, only plastics without the addition of conductive particles (e.g. carbon fiber or non-metallic substances comparable in terms of conductivity) are used.

Metallic materials also serve as the basis for the cable shielding in the further claims 2 to 5, while the present invention relates only to non-metallic, electrically conductive substances.

All further claims are based on claims 1 to 5 or do not deal with the claims specified in the invention.

Prior publications in the technical field of the invention:

The behavior of electromagnetic fields in connection with any materials with regard to their shielding behavior is known, but to date there is no knowledge or publications regarding the use of non-metallic materials for cable shielding against electromagnetic fields.

IM W.Tauber, H.Oswald. Effectiveness of signal screens. Microwave magazine,

Vol. 14, No. 2, 1988. 121 D. Stoll. EMC - electromagnetic compatibility. Interference and

Countermeasures. Berlin: Elitera Verlag 1976. / 3 / A. Schwab. Electro Magnetic Compatibility / EMC '98. 6th International

Trade fair and congress for electromagnetic compatibility, 10.-12. February

1998. Berlin: VDE Verlag 1998. I I Electromagnetic Compatibility 2nd DIN paperback DKE selection series.

Berlin, Cologne: Beuth Verlag 1989.

Several publications exist regarding the electromagnetic shielding attenuation of materials of different electrical conductivities. Plastics vapor-coated with metallic particles are treated as materials with low electrical conductivities. The use of pure fibers with fibers with low electrical conductivity is generally not considered for the purposes of electromagnetic shielding. Disadvantages of the prior art:

Disadvantages of the metallic cable shields currently used are in particular

■ the increasing transfer impedance with increasing frequency due to the inductive and capacitive penetration of the external cable shield current onto the inner conductors;

■ the high weight;

■ the risk of corrosion and

■ the expensive manufacturing processes.

Object of the invention:

The object of the invention is to introduce the wiring with a everywhere cable shield in large and small systems with little additional weight to avoid electromagnetic coupling (within the system and from external fields) or to significantly improve the shielding behavior of metallic shields in the higher frequency range. This also ensures that no other weighty EMC protective measures with regard to radiated electromagnetic fields (be it radiation or radiation) are necessary. The weight reduction can either contribute to energy savings, to longer flight times (for flying platforms) or longer distances (for landing and water vehicles) or to higher speeds (for land vehicles and flying platforms). A deterioration in the system behavior with regard to the electromagnetic behavior due to aging or corrosion can be practically excluded by the invention.

Solution of the task:

This object is achieved by a device having the features of claim 1, the ends of which are connected all around to the connector housings. As an example of mechanical protection, this screen is covered in an exemplary form with an electrically insulating material (e.g. silicone). The area of use as an electromagnetic shield can be varied in a certain frequency range with regard to the lower limit frequency and the damping behavior, depending on the material required. In general, the damping behavior, as long as it is not combined with metallic shields, starts at a few MHz and then has a better behavior than metallic cable shields for higher frequencies. The following alternatives offer themselves as solutions to the objects of the invention:

1. If the shielding behavior of the cable shield is only sought after a few MHz:

In this case, a cable shield according to claim 1 is sufficient; 2. If the entire frequency range is to be attenuated by the cable shield insert:

In this case, a cable shield according to claim 2 can be used.

Advantages of the invention:

Central advantages of the invention are a significantly higher shielding effect compared to conventional metallic shields in the higher frequency range and the weight reduction in systems without restriction / change in their electromagnetic behavior. When using fiber composite materials, the contact between the cable shield and the connector remains unchanged and cannot be negatively influenced by the formation of corrosion between the cable shield and the plug over the course of the years of use. Another advantage of the invention when using appropriate fiber materials is a high mechanical robustness (e.g. higher tensile strength) of the cable. In addition, the production of cables shielded with fiber composite materials requires less energy than metal shielded cables.

Two-wire lines and coax cables (according to claim 5) can advantageously be designed so that, depending on the signal bandwidth to be transmitted, the lines can be designed so that the transmission loss is frequency-independent.

Examples:.

Embodiments of the invention are shown in the drawings and are described in more detail below.

FIG. 1 shows a twisted double conductor in which each of the two conductor fibers is surrounded by an electrical insulating layer and which is electromagnetically shielded by a carbon fiber braid impregnated with a rubber solution according to an exemplary embodiment for claim 3.

FIG. 2 shows a line bundle which is electromagnetically shielded with a possibly metallized carbon fiber braid. An electrically insulating jacket is also drawn over this braid.

In Figure 3, two different conductive fabric layers are arranged around the wire bundle according to claim 4. Again, the resulting cable is surrounded with an electrically insulating jacket for protection.

FIG. 4 shows an example of a coaxial cable which consists of an inner conductor made of highly conductive metal and an outer conductor made of a carbon fiber braid. Figure 5 shows the cross section of a shielded single conductor according to claim 4. In this embodiment, two electrically conductive sheaths (depending on the application, for example, a carbon fiber layer and a layer of ferromagnetic material) are applied in contact with each other. This double layer is separated from the metallic conductor in the center by an electrical insulator.

Claims

Expectations:

1. Device consisting of one or more electrically insulated lines, characterized in that

a single line or the entire line bundle is surrounded by a jacket made of fiber composite materials with a high proportion of electrically conductive fibers (eg carbon fibers) or another non-metallic material with at least one electrical conductivity of approximately 10 ⁴ S / m comparable to carbon fiber materials, which creates an electromagnetic shield.

2. Device according to claim 1, characterized in that

in addition, a ferromagnetic or metallic material is applied.

3. Device according to claim 1 or 2, characterized in that

For total electrical insulation and mechanical strength, the fiber bundle can be soaked and cured with a rubber solution (e.g. silicone, polyurethane) or covered with an electrically insulating tube (e.g. a shrink tube) or an electrically non-conductive braiding material.

4. Apparatus according to claim 1 or 2, characterized in that

electrically conductive braiding material is used simultaneously in two superimposed layers in order to achieve higher electromagnetic shielding or to cover a higher frequency range.

5. Apparatus according to claim 1 or 2, characterized in that

the individual conductors with the sheath made of fiber composite material with a high proportion of electrically conductive fibers can be designed directly as coaxial cables.

6. The device according to claim 1, characterized in that

the conductors of a two-wire line are themselves made of fiber composite material with a high proportion of electrically conductive fibers.

7. The device according to claim 1 or 2, characterized in that

The manufacturing technology is carried out by a special clamping technology that allows all-round contacting of the CFC cable shield with the connector housing.