JP5974992B2 - Coaxial cable for high-frequency signal transmission - Google Patents

Description

  The present invention relates to a high-frequency signal transmission coaxial cable suitable for high-frequency signal transmission.

  The coaxial cable according to the prior art is composed of a braided shield in which a shield layer constituting an outer conductor is formed by braiding strands. In this braided shield, since the strands are knitted in a mesh shape so that the strands intersect, it is difficult for the strands to be scattered during terminal processing, and the change in impedance at the terminal connection portion can be suppressed. In addition, it is possible to suppress the deterioration of noise characteristics at the terminal connection portion.

  However, in the braided shield, the thickness of the shield layer is inevitably more than twice the strand diameter due to the structure, which is an obstacle when aiming to reduce the diameter of the coaxial cable. Further, since the mesh-like gaps are scattered on the surface of the shield layer, there has been a problem that the attenuation characteristic at the time of transmitting a high frequency signal of 1 GHz or more is deteriorated, for example.

  On the other hand, in a coaxial cable composed of a horizontal shield formed by horizontally winding a shield layer, the thickness of the shield layer is the same as the strand diameter, and the strand does not cause a gap. Since it is wound, it is advantageous from the viewpoint of reducing the diameter of the coaxial cable and suppressing the deterioration of the attenuation characteristic with respect to the high-frequency signal.

  However, horizontal winding shields are easily scattered during terminal processing, and the spacing between adjacent strands is increased, so that the impedance at the terminal connection portion changes and desired impedance characteristics cannot be obtained. There is a problem that the noise characteristics at the connection part deteriorate.

  In order to solve this problem, a coaxial cable in which strands are integrated by interposing an adhesive layer between an insulating layer and a shield layer has been proposed (for example, see Patent Document 1 or 2).

  According to this coaxial cable, since the strands are integrated, it is difficult to separate during terminal processing, there is little change in impedance at the terminal connection part, and a desired impedance characteristic can be obtained, and noise at the terminal connection part is obtained. The characteristics are not deteriorated.

JP-A-8-138457 JP-A-54-5591

  By the way, in recent years, since high-speed terminal processing is required, a large number of coaxial cables can be used by using a laser beam such as a YAG laser so that the terminal processing of a large number of coaxial cables can be performed at a time. It is desired to adopt a method of cutting the strands of the lump together.

  In general, the resin that forms the insulating layer is often transparent to laser light in a high-purity state. In order to prevent the laser light leaking from the gap from passing through the insulating layer and reaching the internal conductor, the internal conductor is damaged and disconnected, a coloring agent that absorbs and blocks the laser light is used. It is necessary to make it contain in an insulating layer.

  However, since the colorant is a different material from the insulating layer, and it is technically difficult to disperse the colorant completely and uniformly in the insulating layer, the nonuniform distribution of the colorant causes the insulating layer to disperse. The dielectric constant varies in the longitudinal direction of the cable.

  If the dielectric constant of the insulating layer varies in the longitudinal direction of the cable, the attenuation characteristics at the time of transmitting a high-frequency signal deteriorate, so the coaxial cable used for transmitting a high-frequency signal cannot contain a colorant in the insulating layer. .

  Accordingly, an object of the present invention is to provide a coaxial cable for high-frequency signal transmission that can prevent damage to an internal conductor due to laser light during terminal processing without containing a colorant in an insulating layer. .

  The present invention created to achieve this object includes a conductor, an insulating layer formed around the conductor, a light shielding layer formed around the insulating layer, and an element wire around the light shielding layer. And a covering layer formed around the shield layer, wherein the shield layer is a coaxial cable for high-frequency signal transmission that is adhesively fixed to the light shielding layer. .

  The light shielding layer may include a metal layer opaque to laser light and an adhesive layer formed around the metal layer.

  The light shielding layer may include a resin layer that is opaque to laser light and an adhesive layer formed around the resin layer.

  The light shielding layer may include a conductive adhesive layer that is opaque to laser light.

  The light shielding layer further includes an intervening layer serving as a base material inside the adhesive layer or the conductive adhesive layer, and the adhesive layer or the conductive adhesive layer has a lower melting point than the intervening layer. Good to be.

  The light shielding layer may be formed by wrapping a tape around the insulating layer.

  ADVANTAGE OF THE INVENTION According to this invention, the coaxial cable for high frequency signal transmission which can prevent the damage of an internal conductor by the laser beam in the case of a terminal process without containing a coloring agent in an insulating layer can be provided.

It is sectional drawing which shows the coaxial cable for high frequency signal transmission which concerns on one embodiment of this invention. It is sectional drawing which shows the coaxial cable for high frequency signal transmission which concerns on one embodiment of this invention. It is sectional drawing which shows a tape provided with a metal layer or a resin layer, and an contact bonding layer. It is sectional drawing which shows the tape further provided with an intervening layer.

  Preferred embodiments of the present invention will be described below with reference to the accompanying drawings.

  As shown in FIGS. 1 and 2, the high-frequency signal transmission coaxial cable 100 according to the present embodiment is formed around a conductor 101, an insulating layer 102 formed around the conductor 101, and an insulating layer 102. A light shielding layer 103, a shield layer 105 formed by horizontally winding a strand 104 around the light shielding layer 103, and a covering layer 106 formed around the shield layer 105. The light-shielding layer 103 is adhesively fixed.

  In this high-frequency signal transmission coaxial cable 100, the inner conductor is constituted by a conductor 101 and the outer conductor is constituted by a shield layer 105.

  The conductor 101 is composed of a single wire or a twisted wire (twisted wire in FIGS. 1 and 2) made of a metal having excellent conductivity (for example, copper or aluminum). Considering that the coaxial cable 100 for high-frequency signal transmission is used for high-frequency signal transmission, it is preferable to employ a stranded wire with a large surface area for the purpose of reducing the influence of the skin effect. These single wires or stranded wires may be plated wires that have been plated. As the plating wire, for example, a tin plating wire or a silver plating wire can be used.

  The insulating layer 102 is made of a low dielectric constant resin in order to cope with transmission of a high frequency signal. As the low dielectric constant resin, in order to prevent the dielectric constant from varying in the longitudinal direction of the cable, a high-purity resin that does not contain impurities such as a colorant is used except for inevitable ones. In addition, as the low dielectric constant resin, a fluororesin (for example, tetrafluoroethylene) that is difficult to adhere to an adhesive layer 108 and a conductive adhesive layer 109 described later can be easily exposed so that the insulating layer 102 can be easily exposed during terminal processing. It is preferable to use an ethylene / perfluoroalkyl vinyl ether copolymer (PFA) or a tetrafluoroethylene / hexafluoropropylene copolymer (FEP)).

  The light shielding layer 103 includes a metal layer or resin layer 107 that is opaque to laser light, and an adhesive layer 108 formed around the metal layer or resin layer 107 (see FIG. 1). In particular, when a metal layer is employed, since the solder that flows when the shield layer 105 is solder-connected to the terminals of the substrate contacts the shield layer 105 and the metal layer and conducts, the noise characteristics are further improved. Is possible. The metal layer is made of, for example, a copper film or an aluminum film having a thickness of about 0.1 μm or more and 3 μm or less. The resin layer is made of, for example, a resin containing a colorant whose main material is carbon particles, titanium particles, or titanium oxide particles. As the adhesive layer 108, for example, a hot melt adhesive made of a polyamide resin can be used.

  In addition, the light shielding layer 103 may include a conductive adhesive layer 109 that is opaque to laser light, instead of the metal layer or resin layer 107 and the adhesive layer 108 (see FIG. 2). In the case where the conductive adhesive layer 109 is used, the conductive adhesive layer 109 also functions as the adhesive layer 108, so that the separate adhesive layer 108 is not necessary. The conductive adhesive layer 109 is made of an adhesive containing conductive particles such as carbon black.

  The light shielding layer 103 has a specific configuration as long as it exhibits a function for absorbing (or reflecting) and shielding the laser light so that the laser light does not reach the conductor 101 during terminal processing. Is not particularly limited. The thickness of the light shielding layer 103 may be a minimum thickness that can shield the laser light in consideration of the flexibility characteristics and bending characteristics of the coaxial cable 100 for high frequency signal transmission.

  The light shielding layer 103 further includes an intervening layer serving as a base material inside the adhesive layer 108 or the conductive adhesive layer 109, and the adhesive layer 108 or the conductive adhesive layer 109 has a melting point lower than that of the intervening layer. It does not matter. This intervening layer will be described later.

  For example, as shown in FIG. 3, the light shielding layer 103 is formed by wrapping a tape 300 around the insulating layer 102. The tape 300 includes a metal layer or resin layer 107 and an adhesive layer 108, or includes a conductive adhesive layer 109, and the adhesive layer 108 or the conductive adhesive layer 109 is in contact with the shield layer 105. 108 or conductive adhesive layer 109 is wrapped outside.

  As shown in FIG. 4, the light shielding layer 103 is wrapped around a tape 400 further provided with an intervening layer 401 as a base material inside the adhesive layer 108 or the conductive adhesive layer 109 around the insulating layer 102. It may be formed. As a result, the tape 400 can be reinforced, and the tape 400 can be prevented from being broken during winding.

  The intervening layer 401 preferably has a thickness of 4 μm or more and 6 μm or less. As a result, it is possible to prevent the outer diameter of the high-frequency signal transmission coaxial cable 100 from increasing while the tape 400 is sufficiently reinforced. In addition, as a material of the intervening layer 401, a polyethylene terephthalate (PET) is mentioned.

  The strand 104 is made of a plated wire made of a metal having excellent conductivity (for example, copper or aluminum) and plated, and an adhesive layer is formed so that the adjacent strands 104 do not form a gap. A laterally wound shield is formed by laterally winding around 108. As the plating wire, for example, a tin plating wire or a silver plating wire can be used.

  When the wire 104 is wound horizontally around the adhesive layer 108, the adhesive layer 108 or the conductive adhesive layer 109 is not melted and the shield layer 105 is not fixed, but the shield layer 105 is covered. The adhesive layer 108 or the conductive adhesive layer 109 is melted by the extrusion molding heat when forming the layer 106, and the shield layer 105 is fixed. At this time, as shown in an enlarged view in the lower left of FIGS. 1 and 2, the melted adhesive layer 108 or the conductive adhesive layer 109 may be wrapped around the strand 104 to integrate the strand 104.

  When the wire 104 is made of a tin-plated wire, liquid paraffin is often applied to the surface in order to protect the plating layer, and this liquid paraffin is bonded to the adhesive layer 108 or the conductive adhesive layer 109. Since the adhesion is slightly inhibited, there is an advantage that the shield layer 105 can be easily removed as compared with the case where the wire 104 is made of a silver plating wire.

  The coating layer 106 is made of a fluororesin, and is formed by extrusion coating with extrusion molding heat of 330 ° C. or higher and 360 ° C. or lower. Although the heat of extrusion molding is 330 ° C. or higher and 360 ° C. or lower, which is higher than the melting point of the intervening layer 401, the intervening layer 401 is not melted by the extruding heat because it is cooled immediately after extrusion coating.

  According to the high-frequency signal transmission coaxial cable 100 described so far, since the light shielding layer 103 for shielding laser light is formed between the insulating layer 102 and the shield layer 105, the colorant is added to the insulating layer 102. Without being contained in the conductor 101, it is possible to prevent the conductor 101 from being damaged by the laser light during the terminal processing.

  In addition, in the coaxial cable 100 for high-frequency signal transmission, since the shield layer 105 is fixed by the adhesive layer 108 or the conductive adhesive layer 109, the wire 104 is difficult to be separated at the time of terminal processing, and excellent terminal processing performance is achieved. Can be realized. Therefore, it is difficult to open the interval between adjacent strands 104, and electrical characteristics at the terminal connection portion are improved.

DESCRIPTION OF SYMBOLS 100 Coaxial cable for high frequency signal transmission 101 Conductor 102 Insulating layer 103 Shading layer 104 Wire 105 Shielding layer 106 Covering layer 107 Metal layer or resin layer 108 Adhesive layer 109 Conductive adhesive layer 300 Tape 400 Tape 401 Intervening layer

Claims (6)

Conductors,
An insulating layer formed around the conductor;
A light shielding layer formed around the insulating layer;
A shield layer formed by horizontally winding an element wire around the light shielding layer;
A coating layer formed around the shield layer;
With
The coaxial cable for high-frequency signal transmission, wherein the shield layer is bonded and fixed to the light shielding layer. The light shielding layer is
A metal layer opaque to the laser beam;
An adhesive layer formed around the metal layer;
The coaxial cable for high-frequency signal transmission according to claim 1, comprising: The light shielding layer is
A resin layer opaque to the laser beam;
An adhesive layer formed around the resin layer;
The coaxial cable for high-frequency signal transmission according to claim 1, comprising:   The coaxial cable for high-frequency signal transmission according to claim 1, wherein the light shielding layer includes a conductive adhesive layer that is opaque to laser light. The light shielding layer further comprises an intervening layer serving as a base material inside the adhesive layer or the conductive adhesive layer,
The coaxial cable for high-frequency signal transmission according to any one of claims 2 to 4, wherein the adhesive layer or the conductive adhesive layer has a lower melting point than the intervening layer.   The coaxial cable for high-frequency signal transmission according to any one of claims 1 to 5, wherein the light shielding layer is formed by wrapping a tape around the insulating layer.

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