CH647887A5 - Coaxial radio-frequency cable for transmitting high-voltage pulses - Google Patents

Description

The invention relates to a coaxial high-frequency cable for the transmission of high-voltage pulses, consisting of a cylindrical inner conductor, an inner conductor smoothing surrounding the inner conductor, a solid plastic insulation surrounding the conductor smoothing, an outer conductor smoothing layer surrounding the plastic insulation, and a flexible, cylindrical layer External manager.

Coaxial high-frequency cables for the purpose mentioned are basically high-voltage cables constructed according to high-frequency technology, which are used to transmit very short high-voltage pulses of uniform polarity (DC voltage pulses). Slope and pulse length result in spectral components that reach up to 50 or 100 MHz. Depending on the structure of the cable, the high-frequency spectral components of the pulse are damped to such an extent that either only short transmission distances can be realized or a high pulse deformation has to be accepted.

High operating voltages of, for example, 100 kV cause such high field strengths at the interfaces of the insulation that it is generally necessary to work with conductor smoothing made of semiconducting thermoplastic material as well as with graphite and semiconducting paper.

It is true that procedural precautions in the case of cylindrical inner conductors made of tubes or solid wires can be used to insulate them here without conductor smoothing, without any significant partial discharge occurring during operation. However, if an inner conductor made of a metallic rope is to be used for reasons of the flexibility of the finished cable, a known conductor smoothing must be applied to the inner conductor for the stated purpose. An outer conductor applied to the insulation, especially if it is to be flexible, inevitably leads to gaps and gaps between the conductor material and the insulation, which lead to partial discharges. If you want to avoid these partial discharges, i.e. to fully utilize the voltage resistance of the insulation, a semiconducting layer made of a suitable thermoplastic or a thin layer of graphite and semiconducting paper wrapped over it must be arranged between the insulation and the outer conductor.

However, such known conductor smoothing provides high additional attenuation at higher frequencies, which can already make up 50% of the total attenuation at about 30 MHz. Even an increase in the conductor dimensions does not bring about a significant reduction in the total attenuation.

A high-frequency coaxial cable for antenna lines is known with a metallic inner conductor, a full dielectric made of plastic surrounding the inner conductor concentrically, an outer conductor enclosing the dielectric made of a metal wire mesh and a plastic film band surrounding it at least on one side, and a plastic sheath surrounding the outer conductor as an outer protective sheath, in which the Plastic foil tape is applied helically with overlapping of its tape edges on the metal wire mesh and the wire mesh only partially covers the dielectric and in which the plastic foil tape is depressed into the spaces between the wires of the wire mesh at the points of the dielectric not covered by the wire mesh (DE-AS 27 11 380).

This known structure of an outer conductor for a coaxial high-frequency cable was developed with a view to a good shielding effect of the cable even after multiple bending stresses. High-voltage considerations did not have to be taken into account with him.

The invention has for its object to provide a coaxial high-frequency cable for the transmission of high-voltage pulses, which avoids the additional attenuation caused by the outer conductor smoothing with a required degree of flexibility and freedom from partial discharge, without complicating the processing of the cable and the assembly of plugs.

This object is achieved according to the invention by an outer conductor structure with the characterizing features of claim 1.

Embodiments of the invention are specified in the dependent claims 2 to 7.

The advantages that can be achieved with the invention are, in particular, that cavities between the conductor smoothing and the metal outer conductor are avoided, which would give rise to sheath currents in the conductor smoothing and would cause the aforementioned high losses. Surprisingly, it was found that a cable with the construction of the outer conductor according to the invention at 30 MHz no longer has any measurable additional attenuation due to the conductor smoothing. Because at this frequency, the high-frequency current due to the skin effect only occurs in the metal layers of the composite film measuring 15 µm in size

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flows, the additional damping of a wire mesh compared to a metal pipe can no longer be effective,

With this construction there is even a reduction in the wave attenuation compared to the version without conductor smoothing. The wave attenuation could be reduced from 2.4 dB / s 100 m with a comparable conventional cable to 0.9 dB / 100 m with a measuring frequency of 30 MHz. If a graphite layer is used as the outer conductor smoothing, the otherwise necessary protective carbon black paper can be dispensed with, since the metal-plastic composite film 10 lies smoothly on the graphite layer, so that it no longer needs external protection.

Similar advantages result if the outer conductor-smoothing layer consists of an extruded semiconducting thermoplastic which, according to the invention, does not have a mechanical, firm connection with the insulation or with the metal layer above it by gluing or welding.

An embodiment of the invention is shown in the drawing and will be described in more detail below. 20th

In the single figure, the structure of a coaxial high-frequency cable for the transmission of high-voltage pulses is shown schematically. The inner conductor is designated 1 and in the example drawn as a solid conductor. But it can also consist of a metal tube or a metal rope. In the latter case, the conductor smoothing 2 surrounding it is unavoidable. The massive insulation 3 surrounding the inner conductor smoothing 2 advantageously consists of polyethylene or a similar thermoplastic with a low dielectric loss factor for the 30 spectral frequencies occurring up to about 100 MHz of e.g. 2 x 10-4. The solid insulation 3 is surrounded by an outer conductor-smoothing layer 4, which advantageously consists of graphite powder. However, it can also consist of an extruded, semiconducting thermoplastic, which must then have no mechanically strong connection with the insulation 3 and the inner layer 5 of the outer conductor. The inner layer 5 of the outer conductor lies over the outer conductor-smoothing layer 4, which consists of one or more axially parallel, metal-coated on both sides

layered plastic tapes with axially parallel overlapping tape edges 6. This inner layer of the outer conductor can basically consist of a single band 5. However, production is considerably simplified if a plurality of belts 5 running in parallel with overlapping belt edges 6 are used. Over the inner layer 5 of the inner conductor there is a second layer of plastic tapes 7 wound helically under tensile stress, likewise coated on both sides with metal, the edges 8 of which overlap by approximately 50% of the width B of the individual tapes. The middle layer of the outer conductor can in principle also be produced from a band 7, but the production of a faultless cable is facilitated by the use of several bands 7 running in parallel. The outer conductor sheath 9 is drawn over the middle layer 7 of the outer conductor, the structure of which is adapted to the requirements of the cable. The conductor sleeve 9 can be designed as a tape winding, as a trap, as a braid or as a tube. Several outer conductor shells can also be attached one above the other. A cable sheath 10 is also drawn over the conductor sleeve 9, which serves to protect the cable during transport and during installation against mechanical damage and the penetration of moisture.

Polyethylene terephthalate is advantageously used as the material for the coated plastic tapes 5 and 7, since this material has good long-term elasticity and can be used to easily produce plastic tapes coated on both sides with metal, which can be stretched by at least 15% without the metal covering pores or even Shows cracks. Furthermore, this material has the necessary higher melting point than the polyethylene used for the insulation 3 and for the cable sheath 10. The metal layers applied to the plastic strips 5 and 7 can consist of copper or aluminum, this can be bare or have a surface finish such as silvering or tinning. For certain applications, the outer conductor sleeve 9 can also consist of such metallized foils.

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1 sheet of drawings

Claims (7)

647 887 1.Coaxial high-frequency cable for the transmission of high-voltage pulses, consisting of a cylindrical inner conductor (1), an inner conductor smoothing (2) surrounding the inner conductor, a solid plastic insulation (3) surrounding the conductor smoothing, and an outer conductor-smoothing layer surrounding the plastic insulation (4) and a flexible, cylindrical outer conductor, characterized in that the outer conductor is made up of A. one or more plastic tapes (5) running parallel to the axis and coated on both sides with metal with tape edges (6) overlapping parallel to the axis, B. one or more helically wound under tension, wound on both sides with fetal coated plastic tapes (7) whose edges (8) overlap by about 50% of the bandwidth (B) and C. one or more conductor sleeves (9) made of metal tape or metal wires. 2. Coaxial cable according to claim 1, characterized in that the outer conductor-smoothing layer (4) consists of graphite powder. 2nd PATENT CLAIMS 3. Coaxial cable according to claim 1, characterized in that the outer conductor-smoothing layer (4) consists of an extruded, semiconducting thermoplastic. 4. Coaxial cable according to claim 3, characterized in that the conductor-smoothing plastic layer (4) has no mechanically firm connection with the insulation and the outer conductor (5). 5. Coaxial cable according to one of claims 1 to 4, characterized in that the plastic strips (5 and 7) coated on both sides with metal consist of a material which has a higher melting point than the material of the insulation (3). 6. Coaxial cable according to one of claims 1 to 5, characterized in that the plastic strips (5 and 7) are coated on both sides with aluminum or copper. 7. Coaxial cable according to one of claims 1 to 6, characterized in that the plastic strips coated on both sides with metal (5 and 7) have a total thickness of about 0.1 mm.