DE1078653B - Flexible coaxial cable with attenuation essentially independent of the frequency - Google Patents

Description

The invention relates to a flexible coaxial cable with an essentially independent frequency Attenuation in which both the inner conductor and the outer conductor are tubular and between them an insulating layer made of a plastic polymer is arranged.

When transmitting a wide frequency band over a single coaxial cable, the suitability of the Cable is limited by the amount of its attenuation. In the case of the known coaxial cables, the changes Attenuation with increasing frequency. If a common coaxial cable is used, then there is a difference The attenuation at the different frequencies causes a distortion of the signals. It exists hence the need for a cable with constant attenuation or attenuation that only deviates a few percent across the entire frequency band. Such a cable has a special one Suitability for use in transmission systems for television and for color television see as well as in all other systems with a wide frequency band or where several channels to be transmitted at different frequencies over a single cable.

The known cables of this type are not satisfactory either in electrical terms or in economic terms Manufacture of long cable lengths, such as those required for transmission over long distances will. Cables of this type are known in which a supporting core with a conductive mass, e.g. B. off Coal or metal powder mixed with a binder is surrounded to create a thin conductive layer. Such thin conductive layers have a relatively small one due to the skin effect Attenuation fluctuation over the frequency range. However, conductive layers of this type are difficult to manufacture and suffer from the lack of uniformity and adhesive strength, so that such cables easily break, flake or have other irregularities when subjected to bending.

Cables of this type are also known in which each of the conductors consists of a large number thin metallic and dielectric cylinder. Such cables are difficult to manufacture because the Requirements for the uniform thickness of the very thin conductive layers corresponding to the many conductive layers are enlarged and they are not suitable for mass production.

It was also known that coaxial cables had metal layers that were wound in opposite directions and placed one on top of the other to be used as a cable ladder. However, these layers are thick and therefore not very flexible and have no frequency-independent attenuation. Another known design uses one as a head Flexible coaxial cable

with essentially of the frequency

independent damping

Applicant:

International Standard Electric
Corporation,

New York, N.Y. (V. St. A.)

Representative: Dipl.-Ing. H. Ciaessen, patent attorney,
Stuttgart-Zuffenhausen, Hellmuth-Hirth-Str. 42

Claimed priority:
V. St. v. America March 23, 1956

George R. Leef 4, Mountain Lakes, NJ (V. St. Α.),
has been named as the inventor

Metal tape and a paper strip wrapped over it and covered with a metal tape. This cable has however, there is also no frequency-independent attenuation and, moreover, has one for the High-frequency transmission has an unsustainable level of dielectric losses.

The invention is therefore based on the object of eliminating these deficiencies and providing an instruction give for the production of a flexible coaxial cable with an attenuation that covers a wide frequency range is frequency independent. The frequency range should be the frequencies from 300 kHz to 3 MHz include. The cable should be very flexible and can also be produced with the usual cable machines permit.

The invention solves the problem by a flexible coaxial cable with attenuation essentially independent of the frequency, in which both the inner conductor and the outer conductor are tubular and an insulating layer made of a plastic polymer is arranged between them and which according to the invention consists of a combination of the following individually known per se Features consists of:
a) both the inner and outer conductors consist of two ribbon-shaped plastic films metallized on one side, which are wound in opposite directions and with the metallized side facing each other,

909765/311

b) the thickness of the metallizations is smaller than that Penetration depth limited by the skin effect and is achieved by vapor deposition, chemical or electrochemical Deposits of silver produced,

c) the plastic films and preferably also the core of the inner conductor consist of such as possible low-loss plastics such as polystyrene, polyethylene, polytetrafluoroethylene, etc.

The ribbon-shaped foils become helical and without overlapping and without any substantial gap wound onto the cable between the edges of the successive turns. The fat the conductive layer created by metallization is much smaller than that limited by the skin effect Penetration depth. The invention is further explained with reference to the drawing depicting an exemplary embodiment. The drawing shows at 1 a load-bearing strand, which consists of both a conductive and preferably of a refractory dielectric material, such as. B. one with fiberglass inserts ver ao see plastic strand, may exist. This supporting strand 1 has the task of producing the To facilitate core 2 after the spraying process. This core 2 can be made of any suitable flexible Insulating material, such as B. polyethylene, polystyrene, polytetrafluoroethylene, plasticized polyvinyl chloride, exist. A metallized tape 3 is wound over this core 2. If this tape was only available as a Metal band is formed, so the application is at the desired extremely small thickness of the tape just as difficult as the production of such a thin tape itself. To avoid this this drawback, metalized plastic strips are used in the new cable, on which the Metal can be applied in extremely low strength.

This metallized tape 3 is helically wound around the core 2 without the tape turns overlap and without a substantial measured from strip edge to strip edge between them Forms space. The film side 4 of the tape rests on the core 2, and the metallized one Page 5 is on the outside. A second tape 6 is then wound onto tape 3 in opposite directions. In the case of this band 6, however, the metallized side 7 is on the inside and the film side is on the outside. The metallized Sides 5 and 7 of the two bands are practically in the area of a conductive cylinder.

The conductive layers can be made of the metals silver, copper and aluminum as well as others Metals. A dielectric layer 9 is sprayed onto the strip 6, which preferably consists of low-loss plastic such. B. polyethylene or polytetrafluoroethylene should exist. On this The outer conductor of the cable, which consists of the metallized strips 10 and 11, is arranged in the 2nd layer. Of the tubular outer conductor is formed in essentially the same way as for the inner conductor has already been described. The two metalized strip-shaped plastic films are therefore in opposite directions Winding direction so wound around the sprayed-on insulating layer 9 that the individual turns neither overlap nor a substantial gap between the edges of adjacent turns arises and the metallized sides of the two plastic strips face each other. Above The jacket 12 can be arranged in a known manner on this outer conductor. Appropriately this coat is sprayed on, for which various plastic polymers and preferably polyethylene be available. A wire mesh can also be arranged on the jacket 12 in a known manner will. The new cable has an attenuation fluctuation that depends essentially on the frequency is independent. This is understood to mean that the attenuation over a large frequency range is only around a few percent, and indeed no more or less than 5%, fluctuates, so that it covers a wide frequency band gives a ratio of 1: 1000.

As an example, the dimensions of a new cable with an impedance of approximately 50 ohms specified, especially for transmission in the frequency range from 300 kHz to 300 MHz suitable is.

A plastic strand filled with glass fibers and having a diameter of 0.76 mm is used as the carrier 1. On this support is a sprayed-on polyethylene layer 2 with a diameter of 1.98 mm. The first plastic strip 3 consists of a film made of polyester resin of 25.4 My, which is coated on one side with silver is steamed. The thickness of this vapor-deposited silver layer is 1.27 My. The plastic tape is 5.6 mm wide and counterclockwise wound around the core 2 without the individual turns If there is still a significant gap between the individual turns. The metallized Side of the tape is on the outside. The diameter over this first band layer 3 is 2.04 mm. That second tape 6, which is also 6.5 mm wide, is wrapped right-hand over the first tape 3, but with the metallized side inside. The diameter over the band layer 6 has now increased to 2.08 mm. As an insulating The intermediate layer is now followed by a sprayed-on polyethylene layer 9 with an outer diameter of 7.1 mm. This is followed by the metallized strips 10 and 11, which are wound up in the same way are like the bands of the inner conductor 3 and 6. Due to the larger winding diameter, however, the Width of the bands 10 and 11 25.4 mm. Measured over the band 11, the diameter is now 7.2 mm, which increases after the application of the polyethylene jacket 12 to an outer cable diameter of 8.24 mm.

The particular suitability of the flexible coaxial cable with essentially independent of the frequency Attenuation for high-volume manufacture relies initially on the use of the Polyester resin, as this has a very high tensile strength and is therefore suitable as a material for the carrier 1 as well as being particularly suitable as a film material for the tapes. Furthermore, the polyester resin has a particular ability to hold thin metallic coatings with great adhesive strength. Similar Polytetrafluoroethylene also has good properties that are suitable for the construction of such a cable is characterized by particularly low dielectric losses.

For applying the metallized layer to the plastic strips in the desired thickness and Various methods are known for uniformity. Both the vapor deposition of metal on the foils as well as chemical or electrochemical deposition can be used to metallize the strips will.

The cables constructed according to the invention exhibit fluctuations in attenuation over the frequency range from 300 kHz to 300 MHz of only ± 5%, measured in db, for 0.3048 m cable length. By doing The cable shows a particularly low frequency range from 60 to 300 MHz, which is still below this value Variation in damping. As a result of this

extremely low attenuation, the cable according to the invention can advantageously be used as a delay or transit time cables can be used. Runtime cables, which are constructed according to the invention, show in the frequency range from 60 to 300 MHz only a fluctuation of the attenuation of no more than 2 db per microsecond delay.

The causes of the attenuation fluctuations over a larger frequency range in coaxial cables are based on the influence of several factors, such as the skin effect, the dielectric losses and the field displacement effect produced by the small spacing of conductors. It is known per se to effectively reduce the amount of damping caused by the field displacement effect. By using particularly low-loss dielectric materials, polyethylene, polystyrene and polytetrafluoroethylene, the corresponding amount of attenuation can be reduced to a small amount at frequencies below 300 MHz. The then remaining attenuation is caused exclusively by the skin effect, which in the cable constructed according to the invention is caused by the extremely small thickness of the combined metallized layer on the plastic strips, which is less than the penetration depth at the relevant frequency limited by the skin effect , is rendered ineffective. In this way, the impedance of the conductor becomes essentially constant over the frequency band used. The penetration depth, which is determined by the skin effect, is denoted by the distance from the conductor surface at which the current density on the surface of the conductor has dropped to He , where He is the reciprocal of the base of the natural logarithms. Calculated accordingly, the new coaxial cable has a penetration depth of 5.08 My at 300 MHz. If metallized layers with a thickness of 1.27 My are used for the cable or a layer thickness of 2.54 My for the facing metallized layers of two tapes, the thickness of the current path provided by the metallization is less than that through the skin -Effect given depth of penetration.

Claims (2)

Patent claims: 1. Flexible coaxial cable with attenuation essentially independent of frequency, in which both the inner conductor and the outer conductor are tubular with an insulating layer between them is arranged from a plastic polymer, characterized by the combination the following individually known characteristics: a) there is both the inner and the outer conductor made of two ribbon-shaped plastic films metallized on one side, which run in opposite directions Winding direction and are wound with the metallized side facing each other, the thickness of the metallizations is smaller than the depth of penetration limited by the skin effect and is by vapor deposition, chemical or electrochemical deposition of silver generated, the plastic films and preferably also the core of the inner conductor consist of such as possible low-loss plastics such as polystyrene, polyethylene, polytetrafluoroethylene, etc. 2. Use of the cable according to claim 1 as a delay or delay cable. Considered publications:
German Patent No. 519 555;
British Patent Nos. 559 518, 734 161. 1 sheet of drawings © 909 768/311 3.60