JP2007265797A - Coaxial cable and its manufacturing method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a coaxial cable in which an outer conductor is arranged through a tape layer at the outer circumference of an insulating layer arranged at the surrounding of a center conductor, in which contraction of an insulator is suppressed low. <P>SOLUTION: The coaxial cable 1 is provided with a center conductor, an insulating layer 4 arranged on the outer circumference of the center conductor 2, a metal resin composite tape 5 arranged on the outer circumference of the insulating layer 4 in vertically parallel, an outer conductor 6 arranged on the outer circumference of the metal resin composite tape 5, and a sheath 7 arranged on the outer circumference of the outer conductor 6. The metal resin composite tape has a metallic layer on both sides of a resin layer and its thickness is 24 μm or more and 40 μm or less, and the overlapping width vertically in parallel is 0.19 times or more and 0.38 times or less of the outer circumference of the insulating layer 4. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a coaxial cable provided with an insulating layer, a tape layer, an outer conductor, and a jacket in order from the inside around a central conductor and a method for manufacturing the same.

  Coaxial cables are widely used as cables used for internal wiring for automobiles and electronic devices. In the coaxial cable, an insulator is coated around a central conductor disposed in the center, and an outer conductor (also called a shield layer) that is braided or laterally wound is provided around the insulator. . A conductive metal such as an annealed copper wire is used for the center conductor and the outer conductor, and a resin such as polyethylene is used for the insulator. Further, in order to protect the outer conductor and the insulator inside the outer conductor, the form of the coaxial cable when wired is usually an outer conductor made of a resin such as polyethylene or polyvinyl chloride around the outer conductor. It is formed.

For such a coaxial cable, various measures are taken in order to improve the shielding performance against noise generated from an external circuit or the like. For example, a cable in which a metal tape layer is provided between an insulating layer and an external conductor is known. (For example, see Patent Documents 1 and 2).
Patent Document 1 discloses a coaxial cable in which a metal foil made of a copper foil or an aluminum foil is provided between a dielectric layer (insulating layer) and an outer conductor layer in order to provide an increased shielding effect and shape maintenance. Are listed. In this coaxial cable, the thickness of the metal foil is set in the range of 1% to 5% of the outer diameter of the derivative layer.
Further, in Patent Document 2, an external conductor is provided on an insulator provided on a central conductor, and the external conductor is applied on a thin metal tape layer formed on the insulator. A coaxial cable is described which consists of a conductor braid, which is fused to a thin metal tape layer. Further, the metal tape thin layer is formed by vertically attaching a composite tape of a metal tape and a plastic tape laminated inside the metal tape with the metal tape on the outside.

JP 2005-158415 A JP 7-326230 A

  By the way, in the case of a coaxial cable having an outer conductor around the insulation layer, if the insulation layer shrinks due to temperature change or aging after wiring, the center conductor and the outer conductor come into contact with each other at the end of the cable, causing a short circuit. It is possible that Further, when the insulating layer contracts, the central conductor may be disconnected. In particular, a coaxial cable used for automobiles has a strict heat shock test set in order to adapt to the severe temperature change environment. For example, a standard capable of withstanding a rapid temperature change of −30 ° C. to + 80 ° C. Is stipulated. Under such severe conditions, there was a problem that the insulating layer contracted.

  Further, when a metal foil made only of metal is used as the tape layer, the metal foil does not stretch and easily breaks when an external force such as tension, bending, or vibration is applied to the coaxial cable. Also, when a composite tape consisting of a tape layer, a metal tape, and a plastic tape laminated on the inside is used with the metal tape on the outside, the surface in contact with the insulation layer is a plastic tape, so the tape layer and the insulation layer May be fused, and when the layers of the coaxial cable are processed step by step (so-called step peeling), the layers cannot be removed well, resulting in poor workability.

  The present invention provides a coaxial cable in which an outer conductor is disposed on the outer periphery of an insulating layer disposed around a central conductor with a tape layer interposed therebetween, and a method for manufacturing the coaxial cable capable of suppressing the shrinkage of the insulator. The purpose is to do.

  The coaxial cable capable of solving the above problems is a central conductor, an insulating layer disposed on the outer periphery of the central conductor, a tape layer of a metal resin composite tape disposed vertically on the outer periphery of the insulating layer, A coaxial cable comprising an outer conductor disposed on the outer periphery of the tape layer and an outer jacket disposed on the outer periphery of the outer conductor, wherein the metal-resin composite tape has metal layers on both sides of the resin layer. And the thickness is 24 μm or more and 40 μm or less, and the vertical overlap width is 0.19 times or more and 0.38 times or less of the outer periphery of the insulating layer.

  In addition, the coaxial cable manufacturing method that can solve the above-described problem is formed by forming an insulating layer by extruding and coating an insulating resin on the outer periphery of the central conductor, and vertically attaching a metal resin composite tape to the outer periphery of the insulating layer. Forming a tape layer, covering the outer periphery of the tape layer with an external conductor, extruding and coating a resin on the outer periphery of the outer conductor to form a jacket, the metal resin composite tape, The metal layer has metal layers on both sides of the resin layer and has a thickness of 24 μm or more and 40 μm or less, and the tape layer has an overlap width of 0.19 times or more and 0.38 times the outer circumference of the insulating layer. As shown below, it is formed vertically along the outer periphery of the insulating layer.

  According to the present invention, the thickness of the metal resin composite tape constituting the tape layer disposed between the insulating layer and the outer conductor is 24 μm or more and 40 μm or less, and the force by which the outer conductor fixes the insulating layer. Is thin enough to work. Since the overlap width of the tapes with the metal resin composite tape vertically attached is 0.19 times or more of the outer periphery of the insulating layer, even if the insulating layer expands due to a temperature rise or the like, the outer periphery of the insulating layer does not leave a gap. It can be covered and the holding power of the insulating layer can be maintained. Further, since the overlap width is 0.38 times or less, the productivity is not lowered due to the overlap width being too large.

  Moreover, since the metal resin composite tape has a structure having metal layers on both sides of the resin layer, the resin layer is appropriately stretched to prevent the tape from being broken even when an external force is applied. Moreover, since the surface which contacts an insulating layer and an external conductor is a metal, a metal resin composite tape does not fuse | melt with them.

Hereinafter, an example of an embodiment of a coaxial cable and a method for manufacturing the same according to the present invention will be described with reference to the drawings.
In FIG. 1, the perspective view of the coaxial cable of this embodiment is shown. In addition, in this figure, in order to show the structure of a cable clearly, the state which exposed each member which comprises a cable in steps is shown.

  As shown in FIG. 1, the coaxial cable 1 has a central conductor 2 disposed in the center, an insulating layer 4 is formed around the central conductor 2, and a metal resin composite tape layer 5 is interposed around the insulating layer 4. The outer conductor 6 is arranged. A jacket 7 is covered around the outer conductor 6.

The center conductor 2 is constituted by using one or a plurality of thin conductive metal wires. In the present embodiment, seven ultra-thin diameter annealed copper wires 3 are used and six annealed copper wires 3 are twisted around one annealed copper wire 3. The center conductor 2 may be plated with tin or silver.
For the insulating layer 4, a resin such as polyethylene or fluororesin is used. For example, a heat-resistant plastic can be preferably used. The resin of the insulating layer 4 is preferably a solid body rather than a foamed one.

The metal resin composite tape layer 5 is formed by vertically attaching a metal resin composite tape having a thickness of 24 μm or more and 40 μm or less around the periphery of the insulating layer 4. This metal resin composite tape has a structure having a metal layer made of metal such as aluminum on both surfaces of a resin layer made of resin such as PET. Each metal layer is bonded and integrated with the resin layer via an adhesive layer. This metal layer enhances the noise shielding effect of the coaxial cable 1 together with the outer conductor 6.
Further, the width of the metal resin composite tape along the outer periphery of the insulating layer 4 is 1.19 times or more and 1.38 times or less than the outer periphery of the insulating layer 4 at room temperature. It is 0.19 times or more and 0.38 times or less of the outer periphery of the insulating layer 4.

  The outer conductor 6 is provided so as to cover the periphery of the metal resin composite tape layer 5 by braiding or laterally winding a plurality of conductive metal thin wire rods (for example, annealed copper wire). The outer conductor 6 of the present embodiment is a braided annealed copper wire.

  Polyethylene, polyvinyl chloride, or the like can be used as the resin that forms the jacket 7. In the coaxial cable 1 of the present embodiment, a jacket 7 is formed of a heat resistant plastic made of polyolefin resin. The outer jacket 7 is formed by extrusion molding with a die and is in close contact with the outer conductor 6. The force with which the outer cover 7 is tightly attached to the outer conductor 6 is about 5.0 kgf / 50 mm (3.5 to 6.5 kgf / 50 mm) for pulling out the outer cover 7 by 50 mm in the longitudinal direction. It is set to become. With the tightening force from the outer jacket 7, the outer conductor 6 tightens the insulating layer 4 to suppress the shrinkage of the insulating layer 4.

In the coaxial cable 1 having such a configuration, the thickness of the metal resin composite tape constituting the metal resin composite tape layer 5 is not less than 24 μm and not more than 40 μm, which is sufficient for the external conductor 6 to fix the insulating layer 4. Thin enough to work. Therefore, even if the metal resin composite tape layer 5 is provided in order to improve the noise shielding property, the rigidity of the external conductor 6 acts against the contraction force of the insulating layer 4 due to temperature change or change over time, The shrinkage of the insulating layer 4 can be reliably suppressed by the tightening force by the external conductor 6.
If the thickness of the metal resin composite tape is less than 24 μm, the moldability and noise shielding properties of the metal resin composite tape are reduced, and if the thickness of the metal resin composite tape exceeds 40 μm, the clamping force of the external conductor 6 is insulated. It becomes difficult to convey to the layer 4.

  The metal resin composite tape layer 5 is insulated even if the insulating layer 4 expands due to a temperature rise or the like because the overlapping width of the vertically attached metal resin composite tapes is 0.19 times or more of the outer periphery of the insulating layer 4. Since the state in which the metal resin composite tape covers the outer periphery of the layer 4 without a gap is maintained, the tightening force transmitted from the external conductor 6 to the insulating layer 4 via the metal resin composite tape can be maintained. If the overlap width is 0.19 times or less of the outer periphery of the insulating layer 4, if the insulating layer 4 expands, there is a possibility that a gap between the metal resin composite tapes is formed on the outer periphery of the insulating layer 4. In such a case, the force of tightening and suppressing the insulating layer 4 that contracts when it becomes smaller becomes insufficient. Moreover, when the overlap width of metal resin composite tapes exceeds 0.38 times the outer periphery of the insulating layer 4, the overlap width is excessively larger than necessary, resulting in a decrease in manufacturability when vertically attaching.

  In addition, since the metal resin composite tape has a structure having metal layers on both sides of the resin layer, the resin layer is appropriately stretched even when an external force such as tension, bending, or vibration is applied to the coaxial cable 1. Tape breakage is prevented. Further, since the surface of the metal resin composite tape that contacts the insulating layer 4 and the external conductor 6 is a metal, the metal resin composite tape is prevented from being fused to the insulating layer 4 and the external conductor 6.

  As described above, the coaxial cable 1 shown in FIG. 1 is suitably used as a vehicle-mounted cable, and is used for, for example, an audio device such as a vehicle-mounted radio or a television, and antenna wiring such as an ETC, satellite radio, tire pressure sensor, Is possible.

Next, a method for manufacturing the coaxial cable 1 will be described.
First, the center conductor 2 is formed by twisting a plurality of annealed copper wires 3 drawn to a predetermined diameter. Then, a resin such as polyethylene serving as the insulating layer 4 is extruded and coated on the outside of the central conductor 2. This insulating layer 4 can be made into an electron beam crosslinked heat-resistant plastic by irradiating an electron beam.

  Next, the above metal resin composite tape is vertically attached to the outer periphery of the insulating layer 4 along the longitudinal direction so that the overlapping width is 1.19 times or more and 1.38 times or less than the outer periphery of the insulating layer 4. While forming the metal resin composite tape layer 5, the outer conductor 6 is provided on the outer periphery thereof. When the braided outer conductor 6 is provided, the insulating layer 4 is fed in the longitudinal direction, the half of the copper wire 6 to be braided is crossed with the right twist and the remaining half with the left twist, and the periphery of the insulating layer 4 Braided into. Thereby, the braided core which consists of the center conductor 2, the insulating layer 4, the metal resin composite tape layer 5, and the outer conductor 5 is formed.

  The braided core is fed into the cross head in an extrusion process, and the outer cover 7 is extruded and covered around the braided core. At that time, the outer jacket 7 is formed in close contact with the outer conductor 6, and acts so as to press the outer conductor 6 against the metal resin composite tape layer 5 to be further adhered thereto. Thereby, the insulating layer 4 is fastened by the external conductor 6 through the metal resin composite tape layer 5.

The coaxial cable 1 on which the jacket 7 is formed is cooled by passing through the water tank, and its shape is stabilized. Thereafter, the coaxial cable 1 is checked for quality by a bump detector, a spark tester or the like, and wound on a winder.
Through the above process, the coaxial cable 1 shipped as a product is manufactured.

The coaxial cable 1 according to the present invention was manufactured by the manufacturing method described in the above embodiment, and the insulation layer contraction was evaluated by a heat shock test. For comparison, various types of metal resin composite tapes with different thicknesses and overlapping widths were prepared, and the coaxial cables were similarly tested.
The common configuration of the coaxial cable to be evaluated is a three-layer structure in which the outer diameter of the insulating layer 4 made of crosslinked polyethylene is 1.68 mm, the outer periphery of the insulating layer 4 is 5.28 mm, and the metal resin composite tape is aluminum-PET-aluminum. The resin of the jacket 7 is a non-crosslinked polyolefin resin, and the outer diameter of the jacket 7 is 3.0 mm.

  The test sample of the coaxial cable used for the heat shock test is a cable cut to a length of 1 m, and is in a state where an insulating layer is exposed about 1 to 2 cm at the terminal portion so that the contraction amount can be easily confirmed. .

The test sample was placed in a -30 ° C constant temperature bath for 30 minutes, and then placed in a 80 ° C constant temperature bath for 30 minutes. This was regarded as one cycle of the test, and 1000 cycles of the test were conducted. Then, the length of the insulating layer 4 after 1000 cycles was measured. And the shrinkage | contraction rate after the test of 1000 cycles with respect to the length before a test of the insulating layer 4 was calculated | required by following Formula (1).
Shrinkage rate (%) = {(L ₀ −L ₁₀₀₀ ) / L ₀ } × 100 (1)
In this formula (1), L ₀ is the length of the insulating layer 4 before the test, and L ₁₀₀₀ is the length of the insulating layer 4 after 1000 cycles.

  Table 1 shows the results of the evaluation of such a heat shock test.

In addition, in the item of each layer thickness of the metal resin composite tape shown in Table 1, the thickness of the adhesive between each layer is not described.
In addition, the items of shrinkage of the insulating layer are represented by symbol A when they are within 0.3% or less, which is an evaluation standard for shrinkage, and by symbol B when they are not.
Examples 2 and 4 to 7 and 9 satisfy the shrinkage criteria, but in Example 9, the overlap width was larger than necessary, so the moldability of the metal-resin composite tape was poor. In Example 8, not only the shrinkage of the insulating layer was large, but also the moldability was poor because the metal resin composite tape was thick. If the moldability of the metal resin composite tape is poor, the tape may be wrinkled or the overlapping portion may be bent.
When comparing Example 1 to Example 7 in comparison with the shrinkage of the insulating layer, in Examples 2 and 4 to 7, which satisfy the shrinkage criteria, the thickness of the metal resin composite tape is 24 μm to 40 μm and overlapped. The width is not less than 0.19 times and not more than 0.38 times the outer periphery of the insulating layer.

  From the above test results, the coaxial cable according to the present invention is such that the configuration of the metal resin composite tape layer is set in an appropriate range so that the tightening force by the external conductor acts on the insulating layer well, and the insulating layer It was found that shrinkage can be effectively suppressed.

It is a perspective view showing one embodiment of a coaxial cable concerning the present invention.

Explanation of symbols

1 Coaxial cable 2 Center conductor 3 Annealed copper wire 4 Insulator 5 Metal resin composite tape layer (tape layer)
6 Outer conductor 7 Outer jacket

Claims (2)

A central conductor; an insulating layer disposed on an outer periphery of the central conductor; a tape layer of a metal-resin composite tape disposed vertically on the outer periphery of the insulating layer; and an outer conductor disposed on the outer periphery of the tape layer; A coaxial cable provided on the outer circumference of the outer conductor,
The metal-resin composite tape has a metal layer on both sides of the resin layer and has a thickness of 24 μm or more and 40 μm or less, and a vertical overlap width is 0.19 times or more and 0.38 times the outer periphery of the insulating layer. A coaxial cable that is: Forming an insulating layer by extruding and covering an insulating resin on the outer periphery of the central conductor, forming a tape layer by vertically attaching a metal resin composite tape to the outer periphery of the insulating layer, covering the outer periphery of the tape layer with an external conductor, A method of manufacturing a coaxial cable that forms a jacket by extruding and coating a resin on the outer periphery of the outer conductor,
The metal resin composite tape has a metal layer on both sides of the resin layer and a thickness of 24 μm or more and 40 μm or less,
A coaxial cable formed by vertically attaching the tape layer to the outer periphery of the insulating layer so that the overlapping width of the metal resin composite tapes is 0.19 to 0.38 times the outer periphery of the insulating layer Production method.

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