DE102004010113B4 - Protective cover for protection against electromagnetic radiation - Google Patents

Abstract

Protective cover for protection against electromagnetic radiation in the form of a flat, web-shaped substrate (2) made of electrically conductive materials in a textile production method, or in the form of a film, or as a felt, can be closed by means of a longitudinal closure to form a protective cover, characterized in that the surface material of the electrical conductive layer of the substrate itself a contacting zone (1) is formed for dissipating the radiation, the contacting zone (1) having at least twice the thickness of the substrate (2), for electrical contacting of the conductive substrate and for defined overlap of the conductive substrate and as primary closure of the flat conductive substrate (2) serves for the tubular protective cover.

Description

The invention relates to an enclosure for protection against undesired influences and emissions, in particular electromagnetic radiation for cables, cables and harnesses and in particular for harnesses in mobile applications, and a method for their preparation

Lines, cables and harnesses, hereinafter referred to as "lines", z. As in the automotive and rail vehicles, but also in other areas, in many cases must be bundled in segments and protected from harmful or undesirable influences. The same applies to protect the environment or surrounding systems or components or even people from unwanted emission or interference or disruption or dangers that can cause such lines.

As a prior art, it is necessary to use protective tubes or corrugated pipes. Since it is important in many cases, the protective products also later, or to install sub-segments with branches, or on lines with large-volume end pieces or flanges, as a product or tapes or strips that are closed or wrapped around the tube shape, or corrugated or .Rill tubes used with longitudinal slots. Depending on the influences and material properties, these products offer good bundling and protective effect.

In many cases, pipes must also be subsequently protected against more than one influence or additional emissions. In particular, in many cases additional protection against electromagnetic radiation is required. According to the prior art, open protective sheaths with a layer of metal foil, or braids, knitted or other textile structures made of metal wires or electrically conductive fibers are applied to lines for this purpose. Such protective covers are known from WO 03/001566 A2 and WO 00/68958 , Such covers are generously overlapped applied over the line to ensure a permanent complete coverage. By contacting this layer unwanted electrical rays are derived. To make contact with the conductive layer, and to produce sufficient material thickness of electrically conductive material for further contacting with commercially available electrical connector systems to dissipate the radiation, additional metallic wires, strands or other traces are inserted into the protective sheath by threading or sewing or the like incorporated.

Protective effects can be achieved with the protective covers described above. However, a generous material input is necessary, which causes weight and cost to ensure the functional minimum overlap of the conductive layer. Furthermore, for the contacting of the conductive layer not in all applications and in large series such as z. B. are given in automotive applications, the required process reliability can be ensured.

In order to dissipate electrical radiation, in particular those of high frequency, and thus to ensure a correct functioning of the protective cover, the conductive layer must be contacted under all conditions of use with the lowest resistance, to 0 Ω.

In the subsequent entry of wires, strands or other conductor tracks, which is required for further contact to dissipate the radiation, by threading or sewing or in a similar manner in the textile conductive layer or in the film layer, a repeatability of the process and thus a consistently low contact resistance between the conductive layer and conductor can not be guaranteed, since the contact is made of an arbitrary number of contact points and by undefined pressure of the contacting conductive zones.

In loose contact or too low contact pressure vibrations and shocks of the protective cover, especially those such as in mobile systems such. B. occur in automotive applications, micro-movements of the contacting zones, to intermittent contact withdrawal. Micro-movement in contacting zones of surface-refined metals leads to fretting corrosion or "fretting". As described in numerous attempts and documentation in the field of electrical connectors, this "fretting" leads to high contact resistance and changes the conductivity of the contact system.

Too low pressure between electrically contacting zones, especially in bare metals but also in metals with refined surface can prevail in the further and especially in applications where aggressive environmental conditions such. B. lead in motor vehicle engine compartments, to galvanic corrosion of the contact zones.

Vibrations and vibrations may result in intermittent contact of the protective cover outer layer with nearby components. For protective cover with conductive layer without additional outer layer of this contact can either lead to unwanted noise or mechanical destruction of the protective cover and the underlying line. In cases where a permanent or intermittent contact With a component of different electrical potential comes about, in addition to the mechanical influences, an electrical disturbance in the conductive layer of the protective cover can be initiated.

Under these circumstances, a repeatable manufacturing process, a consistently high level of protection and the permanently required low resistance between the conductive layer of the protective cover and the incorporated conductor track and thus the proper functioning of such products is not given for all applications.

The WO 03/001566 A2 shows a protective cover with RFI / EMI grounding for protection against electromagnetic radiation in the form of a flat, web-shaped substrate made of electrically conductive materials in textile production, which is closed by longitudinal closure to a protective cover.

From the DE 10 2006 024 173 A1 a reinforcing layer for attachment to a wiring harness with laminated body is known, which has in the form of adhesive parts formed closure elements.

The WO 00/74080 A1 Finally, a shielded cable with an extruded or helically band wound MPF shield against RFI / EMI is disclosed.

The object of the invention is to provide an enclosure for lines to protect against electromagnetic radiation in a simple manner of manufacture, which guarantees a functional minimum overlap of the electrically conductive layer without superfluous material input, lines additionally protects against electrical, mechanical or thermal influences and a durable, process-safe and easy contacting of the electrically conductive layer allows.

This object is achieved by the features listed in claim 1.

The advantages achieved by the invention are, in particular, that the critical functionally relevant requirements of protection against electromagnetic radiation, namely a lowest possible electrical resistance between the electrically conductive protective layer and the contacting zone, the defined and permanent minimum overlap of the electrically conductive protective layer and the closure for overlapping protective cover , are given by the invention with one and the same integral part of the protective cover.

The inventive design of the contacting zone of the electrically conductive layer itself additional contact elements and Kontaktierungsmaßnahmen be reduced or eliminated except the application-related contact for the discharge of electrical radiation.

The elimination of additional contact elements and contacting measures avoids sources of error and reduces weight, material costs and production costs. The most important technical advantage of the invention, however, is the lowest possible electrical resistance between the conductive substrate and the contacting zone, since these consist of one and the same functional element.

The additional function of the contacting zone according to the invention as a carrier of a closure component of the web-shaped, flat, electrically conductive substrate to the tubular protective cover serves the defined and permanent functionally relevant overlap of the electrically conductive layer during the closing process, without having to ensure this minimum overlap by superfluous material.

In a preferred embodiment of the invention, the web-shaped electrically conductive substrate is produced in a textile mesh or a textile warp and weft technique, wherein the contacting zone according to the invention by a strip of intense, electrically conductive material input during manufacture of the electrically conductive substrate and without interrupting the mesh - Is formed or warp and weft fibers.

Whereby the conductive material for contacting zone and substrate can be a metal wire with a finished surface but other electrically conductive materials are not excluded. For optimal further processing of the substrate to the protective cover, portions of textile filaments can also be incorporated to produce the electrically conductive substrate. In addition to the preferred mesh or warp and weft technique, flat, electrically conductive substrates in other textile production techniques are also suitable in certain applications or in further processing steps.

In a further preferred embodiment of the invention, the substrate is a film or a felt of electrically conductive materials, in which the contacting zone is formed by folding or shirring of the substrate.

In an alternative preferred variant, the contacting zone according to the invention by formed subsequent mechanical compression of a strip in the substrate.

In all of the above-described preferred embodiments, the contacting zone according to the invention may be formed to extend at one of the longitudinally extending outer ends, or longitudinally parallel and between the outer ends of the electrically conductive sheet-like substrate. Furthermore, the contact zone can be filled with a strip of electrically conductive film in its material thickness.

Preferably, in all embodiments, at least one surface of the conductive substrate, which forms the outer surface of the protective cover in the application, provided with an electrically insulating coating. In rare cases, for specific minimum requirements for the protective product, this insulating coating can also be dispensed with.

The preferred embodiment of the electrically insulating coating is a laminated layer having high abrasion resistance.

In other preferred embodiments, the laminated electrically insulating coating has noise attenuating or heat reflecting properties. Instead of a laminate, viscous and cured coatings are also conceivable.

At the contacting zone according to the invention of the embodiments described above, it is preferable to have on one side a connecting element which, compatible with a parallel outer end of the electrically conductive substrate, allows the substrate to be sealed to the tubular shape.

Preferably, the closure element is an adhesive strip or a Velcro strip.

There are certainly other closure elements, eg. As those conceivable of metal, which are useful for the further function of the application-related Kontaktierungsmaßnahme for the derivation of electrical radiation.

In the following, embodiments of the invention will be explained in more detail with reference to the drawings.

Show it:

1 A protective cover for protection against electromagnetic radiation in the form of a flat, sheet-like, electrically conductive substrate with surface insulation, closure elements and contact-type zone protruding like a flag on one of the two longitudinal outer ends of the substrate.

2 A protective cover for protection against electromagnetic radiation in the form of a flat, electrically conductive web-shaped substrate with surface insulation, closure elements and flag-like outstanding contacting zone parallel between the two longitudinal ends of the substrate.

3 A protective cover for protection against electromagnetic radiation in the form of a flat, sheet-like substrate with surface insulation and closure element on one side of the flag-like protruding contacting zone in unfilled, almost closed to the tube shape state.

4 A protective cover for protection against electromagnetic radiation in the form of a flat, sheet-like substrate with surface insulation and closure elements, filled with lines to be protected and a cable with electrical connector for application-related contacting of the flag-like outstanding contacting zone to dissipate electrical radiation.

5 A protective cover for protection against electromagnetic radiation in the form of a flat, electrically conductive web-shaped substrate with surface insulation, closure elements and, alternatively to the previously illustrated flag-like outstanding Kontaktierungszonen, a contacting zone, which is formed as a strip of double substrate thickness from the substrate.

In the 1 - 5 illustrated protective cover consists of one of the electrically conductive substrate 2 formed contacting zone 1 , with electrically insulating surface layer 3 , primary shutter elements 4a and 4b and a secondary closure element 5 ,

In the 1 - 5 is the flat electrically conductive substrate 2 represented symbolically with grid lines. It may be in textile manufacturing z. B. in mesh or in warp and weft or other textile manufacturing method of metal wires or electrically conductive fibers. In addition to the electrically conductive wires or fibers, further textile fibers can be incorporated into the electrically conductive substrate during the textile production process.

The flat electrically conductive substrate 2 but can also be made in foil or felt form of electrically conductive materials.

The contacting zone 1 is a component of the electrically conductive substrate 2 and either textile-wise, during the manufacturing process of the substrate 2 by a strip of intensively incorporated electrically conductive wires or fibers, or by folding or piling the electrically conductive substrate 2 , or by mechanically compressing a strip of the electrically conductive substrate 2 developed.

The material thickness of the contacting zone 1 is at least twice that of the electrically conductive substrate 2 and can be filled with metal foil for additional material thickness if required.

In 1 becomes the contacting zone 1 at an outer longitudinal end of the electrically conductive substrate 2 flagged outstanding.

At the in 1 shown protruding layer 3 , It is the electrically insulating surface layer 3 , which will be described in more detail below.

In 2 becomes the contacting zone 1 shown in a flag-like protruding parallel between the two longitudinal ends of the substrate. In this illustration, the electrically conductive substrate ends 2 at both longitudinal ends of the protective cover together with the electrically insulating surface layer 3 ,

In the 1 - 5 illustrated electrically insulating surface layer 3 is either on the electrically conductive substrate 2 is laminated or applied in a viscous manner with subsequent curing or it is during the textile manufacturing process of the electrically conductive substrate 2 produced. In addition to the electrically insulating properties, the surface layer 3 depending on the application by the choice of appropriate materials sound-absorbing, abrasion-resistant or heat-reflecting properties have.

4 shows in addition to the in 1 - 3 and 5 illustrated protective cover elements 1 - 5 a trunk group to be protected 6 with a protective function-relevant line 7 connected to an electrical contact element 8th is posted and the application-specific contacting of the contacting zone 1 by means of the electrical contact element 8th serves to dissipate the disturbing electrical radiation.

Before closing the primary fasteners 4a and 4b becomes the contact element 8th together with the ailing wire 7 according to the state of the art in the so-called "piercing crimp", "crimp crimp" or "wave crimp" method wide area with the contacting zone 1 connected and ensures a permanent electrical connection with very low electrical resistance.

This in 1 . 2 and 4 because of perspective view invisible closure element 4a is in 3 and 5 on one side of the contacting zone 1 shown symbolically recognizable. This closure element 4a is compatible with the in 1 . 2 . 4 and 5 symbolically illustrated closure element 4b at the parallel longitudinally extending outer end of the substrate 2 and allows the primary closure of the electrically conductive substrate 2 to the tubular protective cover after filling the protective cover with the lines to be protected 6 and after contacting the line 7 by means of contact element 8th with contact banner 1 , At the same time serve the closure elements 4a and 4b the defined minimum overlap of the electrically conductive substrate 2 after the closure.

The compatible closure elements 4a and 4b are either in front of an adhesive strip, in which case the compatibility would be in the adhesion of the adhered surface and only an adhesive strip either 4a or 4b urgently needed, or the closure elements 4a and 4b are available as velcro and Velcro closure.

There are also other compatible types of closure conceivable, for. As those made of metal, in addition to an electrical contacting of the contacting zone 1 as in 4 by electrical contact element 8th represented, would support.

Alternative to the illustrations in 1 - 4 is in 5 a contacting zone 1 in a flat stripe of at least twice the substrate thickness 2 shown. In such an embodiment of the protective cover becomes the contacting zone 1 by means of a like in 4 illustrated contact element 8th in the so-called "insulation piercing" or "insulation displacement" method, by the insulating surface layer 3 , either before the closure of the elements 4a With 4b and 5 , or contacted after the closure of the aforementioned closure elements.

As a final closure of the electrically conductive substrate 2 after filling with lines 6 and the contacting of wire 7 by means of contact element 8th with contact banner 1 and the primary closure of the elements 4a and 4b , this is done via the contacting zone 1 supernatant electrically conductive substrate 2 , together with surface layer 3 as in 2 shown, or only the electrically insulating surface layer 3 , as in 1 represented by means of closure element 5 , which is preferably present as an adhesive strip, to the protective cover to those in 4 represented to be protected line 6 locked.

Claims (15)

Protective cover for protection against electromagnetic radiation in the form of a flat, web-shaped substrate ( 2 ) made of electrically conductive materials in textile production manner, or in the form of a film, or as a felt, closed by longitudinal closure to a protective cover, characterized in that from the sheet material of the electrically conductive layer of the substrate itself a contacting zone ( 1 ) is formed to dissipate the radiation, wherein the contacting zone ( 1 ) which is at least twice the thickness of the substrate ( 2 ) for electrically contacting the conductive substrate and for defined overlapping of the conductive substrate and as the primary closure of the flat conductive substrate (US Pat. 2 ) to the tubular protective cover is used. Protective cover according to claim 1, characterized in that the contacting zone is formed by single or multiple folding or shirring of the electrically conductive substrate. Protective sheath according to claim 1, characterized in that the contacting zone is formed from the substrate by mechanically compressing a strip in the electrically conductive substrate. Protective cover according to claim 1, characterized in that the contacting zone is formed by an intensive, electrically conductive material input during the textile production of the electrically conductive substrate and without interruption of the electrically conductive fibers. Protective cover according to one of the preceding claims, characterized in that the contacting zone is formed as a protruding from the substrate flag in a height of> 5 mm. Protective cover according to one of the preceding claims, characterized in that the contacting zone extends in at least twice the substrate thickness and a width of> 5 mm in the protective cover. Protective cover according to one of the preceding claims, characterized in that the contacting zone is reinforced in its material thickness by additional feeding with an electrically conductive film. Protective cover according to one of the preceding claims, characterized in that the contacting zone is formed on one of the two longitudinal outer ends of the electrically conductive substrate. Protective cover according to one of the preceding claims, that the contacting zone is formed in parallel between the two longitudinal ends of the electrically conductive substrate. Protective cover according to one of the preceding claims, characterized in that on one side of the contacting zone, a closure element is attached, which closes with one of the parallel and longitudinal ends of the substrate compatible with the tubular shape. Protective cover according to claim 10, characterized in that it is the closure element is a Velcro or Velcro element. Protective cover according to Claim 10, characterized in that the closure element is an adhesive strip. Protective cover according to claim 10, characterized in that it is closure elements made of metal, which are additionally useful for the application-related contact for dissipating electrical radiation. Protective cover according to one of the preceding claims, characterized in that the electrically conductive substrate is provided with an electrically insulating surface layer. Protective cover according to claim 14, characterized in that the electrically insulating surface is produced in a textile-technical manner during the textile manufacturing process of the electrically conductive substrate.

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