JP6780430B2 - Wire identification method and cable unit - Google Patents

Description

The present invention relates to an electric wire identification method and a cable unit.

Since a plurality of electric wires are often bundled and used, it is indispensable to be able to identify each of the plurality of electric wires. The electric wire referred to here has a broad meaning, and includes an electric wire for transmitting an electric power, a communication for transmitting an electric signal, and the like, for example, an electric wire for transmitting an optical signal such as an optical fiber.

The identification of a plurality of electric wires is generally performed by using the color of the outer skin covering the electric wires. Further, in recent years, a pattern pattern in which either or both of the color band spacing and the color are different from each other is used (see, for example, Patent Document 1), or a unique identification mark including a serial number is used (for example,). (See Patent Document 2) and the like have been proposed.

JP-A-2015-108756 Japanese Unexamined Patent Publication No. 2012-003222

However, the electric wire identification by the prior art has the following drawbacks.
For example, in wire identification using the color of the outer skin, there is a limit to the number of color types that can be colored (generally, about 10 colors are the upper limit), so it is not always the case when the number of wires to be identified is large. It is not always possible to respond appropriately. That is, when the number of electric wires increases, it may be difficult to identify the electric wires.
Further, for example, electric wire identification using a pattern pattern or an identification mark requires a certain area area on the outer surface of the electric wire for arranging the pattern pattern or the identification mark, so that the electric wire is not necessarily reduced in diameter. It is not always possible to respond appropriately. That is, it may be difficult to save the wiring space by reducing the diameter of the electric wire.

The present invention provides an electric wire identification method and a cable unit that can appropriately and easily identify a plurality of electric wires while flexibly responding to an increase in the number of electric wires to be identified and a reduction in the diameter of the electric wires. The purpose is to provide.

According to one aspect of the invention
This is an electric wire identification method for identifying a plurality of electric wires whose conductors are covered with an outer skin.
A strip-shaped member is wound around at least one of the plurality of electric wires, and the strip-shaped member is wound around the outer circumference.
The strip-shaped member includes a transparent region portion that makes the outer skin of the electric wire around which the strip-shaped member is wound visible, and a non-transparent region portion that is colored different from the outer skin. using,
The strip-shaped member is wound over the outer circumference of the electric wire so that the pattern formed by the transparent region portion and the non-transparent region portion is exposed on the surface of the overlapping portion of the strip-shaped member.
Provided is an electric wire identification method for identifying the electric wire by the pattern exposed on the surface and the color of the outer skin .

According to the present invention, even when the number of electric wires to be identified increases or the diameter of an electric wire is reduced, it is possible to appropriately and easily identify a plurality of electric wires while flexibly responding to these cases. It becomes possible to do it.

It is a perspective view which shows typically the schematic structure example of the cable unit which concerns on one Embodiment of this invention. It is sectional drawing which shows typically the structural example of the electric wire provided in the cable unit which concerns on one Embodiment of this invention. It is a top view which shows typically the structural example of the band-shaped member provided in the cable unit which concerns on one Embodiment of this invention. It is a perspective view which shows the winding mode of the band-shaped member around the electric wire in the cable unit which concerns on one Embodiment of this invention.

Hereinafter, the electric wire identification method and the cable unit according to the present invention will be described with reference to the drawings.

(1) Configuration of Cable Unit First, the configuration of the cable unit according to the embodiment of the present invention will be described.

(overall structure)
FIG. 1 is a perspective view schematically showing a schematic configuration example of a cable unit according to an embodiment of the present invention.

The cable unit 1 described in the present embodiment is configured to include a plurality of electric wires 10a to 10h. In the illustrated example, the electric wires 10a to 10h are arranged so as to be arranged in a row to form a so-called flat cable, but the arrangement of the electric wires 10a to 10h is limited to this. is not. Further, in the illustrated example, a configuration including eight electric wires 10a to 10h is shown, but the number of electric wires 10a to 10h is not particularly limited. That is, as long as the cable unit 1 is configured to include a plurality of electric wires 10a to 10h, each electric wire 10a to 10h may be arranged in any manner, and the number of electric wires 10a to 10h may be arbitrary. It may be configured.

The conductors 11 of each of the electric wires 10a to 10h constituting the cable unit 1 are covered with outer skins 12a to 12h, and the specific configuration thereof will be described in detail later.

Further, the electric wires 10a to 10h constituting the cable unit 1 are roughly classified into a first electric wire group 13a and a second electric wire group 13b. The outer skins 12a to 12d of each of the electric wires 10a to 10d belonging to the first electric wire group 13a are exposed, but the strip-shaped member 20 is wound around the outer circumference of each of the electric wires 10e to 10h belonging to the second electric wire group 13b. That is, the cable unit 1 is configured by winding a strip-shaped member 20 around the outer circumference of at least one of a plurality of electric wires 10a to 10h (specifically, each of the electric wires 10e to 10h belonging to the second electric wire group 13b). Has been done. Since there is at least one cable unit 1, if the electric wires 10e to 10h around which the band-shaped member 20 is wound are provided, the cable unit 1 is composed of only the second electric wire group 13b, that is, all the electric wires constituting the cable unit 1 are band-shaped. The member 20 may be wound around the member 20. The specific configuration of the strip-shaped member 20 will be described in detail later.

(Composition of electric wire)
FIG. 2 is a cross-sectional view schematically showing a configuration example of an electric wire 10 included in the cable unit 1 according to the embodiment of the present invention.

The electric wire 10 (corresponding to reference numerals 10a to 10h in FIG. 1) constituting the cable unit 1 has a conductor 11 covered with an outer skin 12 (corresponding to reference numerals 12a to 12h in FIG. 1). As long as the conductor 11 is covered with the outer skin 12, the electric wire 10 may be for electric power to transmit electric power or may be for communication for transmitting an electric signal. Further, a glass fiber as a conductor 11 may transmit an optical signal, for example, an optical fiber cable.

An enamel wire is mentioned as a specific example of such an electric wire 10. The enamel wire is formed by covering a conductor 11 made of copper or a copper alloy with an enamel layer which is an outer skin 12. The enamel layer is, for example, polyimide (PI), polyamideimide (PAI), polyesterimide (PEsI), polyetherimide (PEI), polyimide hydrantin-modified polyester, polyamide (PA), formal, polyurethane, polyester (PEst), polyvinyl. It is formed using one or more enamels selected from the group consisting of formal, epoxy and polyimideins.

The diameter d of the enamel wire is formed to be, for example, 0.3 mm or less. That is, the enamel wire corresponds to an ultrafine wire having a diameter of 0.3 mm or less.

Further, the enamel layer constituting the enamel wire is colored with a different color for each of the plurality of enamel wires so that the plurality of enamel wires can be identified.

(Structure of strip-shaped member)
FIG. 3 is a plan view schematically showing a configuration example of a band-shaped member included in the cable unit according to the embodiment of the present invention.

The strip-shaped member 20 is a member formed in a long strip shape. Specifically, for example, a tape formed of polyethylene terephthalate (PET) resin (hereinafter, also referred to as "PET resin tape") can be mentioned.

Further, the strip-shaped member 20 includes a transparent region portion 21 and a non-transparent region portion 22.
The transparent region portion 21 is a portion configured to transmit light in the visible light wavelength region, and specifically has transparency enough to make the outer skin 12 of the electric wire 10 around which the band-shaped member 20 is wound visible. It is a part composed of.
The non-transparent region portion 22 is a portion colored so as not to transmit light in the visible light wavelength region, and specifically, is configured to be colored differently from the outer skin 12 of the electric wire 10 around which the strip-shaped member 20 is wound. It is the part that was done.

The non-transparent region portion 22 may be formed on the surface of the strip-shaped member 20 by, for example, a printing process, but the present invention is not limited to this, and the non-transparent region portion 22 is formed by using another known technique. May be good.

Examples of the formation pattern (pattern) of the transparent region portion 21 and the non-transparent region portion 22 include a pattern in which island-shaped non-transparent region portions 22 are scattered along the longitudinal direction of the strip-shaped member 20 at predetermined intervals. However, the present invention is not limited to this, and any pattern in which the transparent region portion 21 and the non-transparent region portion 22 coexist may be used as other patterns such as a line-and-space pattern and a dot pattern. ..
As for the region portion having a constant width from the edge of the strip-shaped member 20, since the strip-shaped member 20 is overlapped (wrapped) as described in detail later, the non-transparent region portion 22 is not formed and is transparent. It is assumed that it is composed of only the region portion 21.

Regarding the forming width w of the strip-shaped member 20, it is preferable that 3d ≦ w ≦ 10d is satisfied in relation to the diameter d of the electric wire 10 around which the strip-shaped member 20 is wound.
If the width w is less than 3d, it becomes difficult to secure an appropriate wrap ratio (ratio of overlapping widths) when the strip-shaped member 20 is lap-wound, and as a result, lap-wrapping may become difficult. More specifically, for example, it becomes difficult to secure a wrap ratio of 25% or more, and therefore, when the band-shaped member 20 is bent, there are places where the band-shaped member 20 is wound and places where the band-shaped member 20 is not wound. This is because the resistance) is partially different, which may cause damage to the electric wire. Regarding this point, by satisfying the relationship of 3d ≦ w, an appropriate lap ratio (for example, 25% or more) can be guaranteed, and the strip-shaped member 20 can be appropriately and easily lapped. ..
Further, if the width w exceeds 10d, the strip-shaped member 20 becomes too wide, and it may be difficult to uniformly wind the strip-shaped member 20 around the electric wires 10a to 10h. Regarding this point, by satisfying the relationship of w ≦ 10d, the strip-shaped member 20 can be uniformly wound around the electric wire 10.

The forming thickness of the strip-shaped member 20 is not particularly limited, but it may be, for example, about 2.5 μm to 9 μm in consideration of winding around the outer circumference of the electric wire 10.

(2) Electric Wire Identification Method Next, a method for identifying each electric wire 10a to 10h in the cable unit 1 having the above-described configuration, that is, an electric wire identification method according to an embodiment of the present invention, will be specifically described with reference to FIG. explain. In the following description, an example will be given in which the electric wires 10a to 10h constituting the cable unit 1 are enamel wires covered with an enamel layer.

(Identification of each enamel wire)
Of the enamel wires 10a to 10h constituting the cable unit 1, each enamel wire 10a to 10d belonging to the first electric wire group 13a has its own enamel layers 12a to 12d colored in different colors. Therefore, each of the enamel wires 10a to 10d belonging to the first electric wire group 13a can be identified by recognizing the colors of the enamel layers 12a to 12d.

However, there is a limit to the number of color types that can be colored in the enamel layer 12 (specifically, the upper limit is about 10 colors). Moreover, since the enamel wire 10 corresponds to an ultrafine wire having a diameter of 0.3 mm or less, it is not realistic to attach an identification mark or the like to the surface of the enamel layer 12.

Therefore, when the cable unit 1 is provided with the number of enamel wires 10a to 10h exceeding the number of color types that can be colored in the enamel layer 12, it is said that all the enamel wires 10a to 10h can be appropriately identified. Not exclusively.

For this reason, in the cable unit 1 of the present embodiment, the strip-shaped member 20 is wound around the enamel wires 10e to 10h belonging to the second electric wire group 13b. The strip-shaped member 20 has a transparent region portion 21 and a non-transparent region portion 22, and the non-transparent region portion 22 is colored differently from the enamel layers 12e to 12h of the enamel wires 10e to 10h. .. Therefore, the first electric wire group 13a and the second electric wire group 13b can be identified by recognizing the presence / absence of the band-shaped member 20 (more specifically, the presence / absence of the non-transparent region portion 22).

The enamel wires 10e to 10h belonging to the second electric wire group 13b, that is, the enamel wires 10e to 10h around which the strip-shaped member 20 is wound, have their enamel layers 12e to 12h colored in different colors. This point is the same as in the case of the first electric wire group 13a. The type of colored color may be the same as that of the first electric wire group 13a as long as the enamel layers 12e to 12h are different colors.
Further, as the band-shaped member 20 wound around each enamel wire 10e to 10h, the one having the same pattern formed by the transparent region portion 21 and the non-transparent region portion 22 is used.
However, the transparent region portion 21 of the strip-shaped member 20 has enough transparency to make the enamel layers 12e to 12h visible. Therefore, for each of the enamel wires 10e to 10h belonging to the second electric wire group 13b, even when the band-shaped member 20 is wound, the colors of the enamel layers 12e to 12h are recognized through the transparent region portion 21. Each can be identified.

As described above, in the cable unit 1 of the present embodiment, even if the enamel layer 12 is provided with a number of enamel wires 10a to 10h exceeding the number of color types that can be colored, the enamel wires 10a to 10h have a diameter of 0. Even if it is an ultrafine wire of 3 mm or less and it is difficult to attach an identification mark or the like to the surface of the enamel layer 12, the color of the enamel layers 12a to 12h in each enamel wire 10a to 10h and the outer periphery of the enamel wire 10e to 10h By using the band-shaped member 20 to be wound, it is possible to identify each of the total number of enamel wires 10a to 10h constituting the cable unit 1. That is, by using the strip-shaped member 20 having the transparent region portion 21 and the non-transparent region portion 22, identification utilizing the synergistic effect between the color type of the enamel layer 12 and the strip-shaped member 20 can be realized, and the enamel layer can be identified at the maximum. It becomes possible to appropriately identify the number of enamel wires 10 which is twice the number of 12 color types.

In the present embodiment, the case where the strip-shaped member 20 having the same pattern is wound around each of the enamel wires 10e to 10h belonging to the second electric wire group 13b has been described as an example, but a plurality of patterns of the strip-shaped member 20 should be prepared. For example, it is possible to identify the number of enamel layers 12 that is three times or more the number of color types.

(Wrapping of strip-shaped member)
In order to make a distinction utilizing the synergistic effect of the color type of the enamel layer 12 and the strip-shaped member 20, the strip-shaped member 20 having the transparent region portion 21 and the non-transparent region portion 22 is, if necessary, of the enamel wire 10. Wrap around the outer circumference. The band-shaped member 20 is preferably wound around the enamel wire 10 by lap winding (wrap winding).

FIG. 4 is a perspective view showing a mode in which a strip-shaped member is wound around an electric wire in a cable unit according to an embodiment of the present invention.
The illustrated example shows a specific example of a mode in which the strip-shaped member 20 is wound around the enamel wire 10 by lap winding.

In lap winding (wrap winding), the strip-shaped member 20 is spirally wound around the outer circumference of the enamel wire 10, and the strip-shaped members 20 are overlapped so as to have a portion where the strip-shaped members 20 overlap each other on a certain circumference and the next circumference at the time of winding. How to wind.

The wrap ratio (ratio of overlapping width) when performing lap winding is preferably 25% or more and 50% or less of the total width w of the strip-shaped member 20, for example. That is, the exposed width w1 of the strip-shaped member 20 excluding the overlapping width is preferably 50% or more and 75% or less of the total width w of the strip-shaped member 20, for example. With such a wrap ratio, even when the enamel wire 10 is bent, the overlapping width between the band-shaped members 20 can be surely secured, and there are places where the band-shaped members 20 are wound and places where the band-shaped members 20 are not wound. This is because it is possible to avoid such a situation.

Even in the case of lap winding, the strip-shaped member 20 has a portion consisting of only the transparent region portion 21 in the region portion having a constant width from the edge thereof, so that the enamel layer 12 of the enamel wire 10 has a portion. The color does not become difficult to see.

By the way, the band-shaped member 20 may be wound around the enamel wire 10 by, for example, interval winding (gap winding) in addition to the above-mentioned lap winding. Interval winding (gap winding) is a winding method in which when the band-shaped member 20 is spirally wound around the outer circumference of the enamel wire 10, a gap is created between the band-shaped members 20 on one circumference and the next. is there. However, when the strip-shaped member 20 is wound at intervals, there will be a portion where the strip-shaped member 20 is wound and a portion where the strip-shaped member 20 is not wound. Therefore, for example, when the enamel wire 10 is bent, the strip-shaped member 20 becomes The enamel layer 12 may break at the boundary between the wound portion and the unrolled portion.

Regarding this point, if the lap winding as described above is performed, the band-shaped member 20 is wound around the outer circumference of the enamel wire 10 substantially uniformly, and there may be a place where the band-shaped member 20 is not wound. Absent. Therefore, for example, even when the enamel wire 10 is bent, it is possible to suppress the concentration of internal stress at a specific portion and prevent the enamel layer 12 from being broken. ..

As the strip-shaped member 20 to be lap-wound, for example, it is preferable to use a PET resin tape having a thickness of about 2.5 μm to 9 μm and a non-transparent region portion 22 formed by a printing process. Such a PET resin tape has high tensile strength and moderate extensibility, and is therefore very suitable for winding the enamel wire 10 around the outer circumference. Moreover, if the printing process is used, the non-transparent region portion 22 can be easily and efficiently formed, and the non-transparent region portion 22 does not impair the characteristics of the PET resin tape.

(3) Effects of the present embodiment According to the present embodiment, one or more of the following effects are exhibited.

(A) In the present embodiment, a strip-shaped member 20 is wound around at least one outer circumference of a plurality of electric wires (enamel wires) 10, and the strip-shaped member 20 has a transparent region portion 21 and a non-transparent region portion 22. Use the one configured in.
In this way, by using the strip-shaped member 20 having the transparent region portion 21 and the non-transparent region portion 22, the synergistic effect between the color type of the outer skin (enamel layer) 12 of the electric wire (enamel wire) 10 and the strip-shaped member 20 can be obtained. Utilization of identification becomes feasible, and the number of electric wires (enamel wires) 10 exceeding the number of color types that can be colored on the outer skin (enamel layer) 12 can be appropriately identified. That is, even when the number of electric wires (enamel wires) 10 to be identified is large, it can be appropriately dealt with.
Moreover, since the band-shaped member 20 is wound around the outer circumference of the electric wire (enamel wire) 10, a fixed area area for arranging a pattern, an identification mark, or the like is not required on the surface of the outer skin (enamel layer) 12. That is, even if the diameter of the electric wire (enamel wire) 10 is reduced, it can be appropriately dealt with, and it becomes easier to reduce the wiring space by reducing the diameter of the electric wire (enamel wire) 10. To do.
Therefore, according to the present embodiment, even when the number of electric wires (enamel wires) 10 to be identified increases or the diameter is reduced, for example, a plurality of electric wires (enamel wires) can be flexibly dealt with. It becomes possible to properly and easily identify the electric wire (enamel wire) 10.

(B) In the present embodiment, the relationship between the width w of the strip-shaped member 20 and the diameter d of the electric wire (enamel wire) 10 satisfies the relationship of 3d ≦ w ≦ 10d. Therefore, the strip-shaped member 20 can be appropriately and easily lap-wound while ensuring an appropriate wrap ratio (for example, 25% or more), and the strip-shaped member 20 is uniformly wound around the electric wire (enamel wire) 10. Can be done.

(C) In the present embodiment, the strip-shaped member 20 is wound around the electric wire (enamel wire) 10 by lap winding (wrap winding). Therefore, unlike the case where the band-shaped member 20 is wound at intervals (gap winding), there is no place where the band-shaped member 20 is not wound. That is, the strip-shaped member 20 is wound around the outer circumference of the electric wire (enamel wire) 10 substantially uniformly. For example, even when the electric wire (enamel wire) 10 is bent, the outer skin (enamel layer) 12 is broken. It is possible to avoid it.

(D) In the present embodiment, the electric wire (enamel wire) 10 is an ultrafine wire having a diameter of 0.3 mm or less. Even in that case, by using the strip-shaped member 20 having the transparent region portion 21 and the non-transparent region portion 22, it is possible to appropriately and easily identify the ultrafine lines. Moreover, since it is an ultrafine wire, it is very easy to save the wiring space.

(E) In the present embodiment, as the strip-shaped member 20, a PET resin tape having a non-transparent region portion 22 formed by a printing process is used. Therefore, it is very suitable for winding the enamel wire 10 around the outer circumference, and the non-transparent region portion 22 does not impair the characteristics of the PET resin tape.

(4) Modifications and the like Although one embodiment of the present invention has been specifically described above, the technical scope of the present invention is not limited to the above-described embodiment and varies within a range that does not deviate from the gist thereof. It is possible to change.

For example, in the above-described embodiment, the case where the electric wire is an enamel wire having a diameter of 0.3 mm or less is given as an example, but the present invention is not limited thereto. That is, the electric wire to which the present invention is applied is broadly defined, and as long as the conductor is covered with an outer skin, the types of the conductor and the outer skin are not particularly limited, and for example, those for electric power. It may be for electric signal communication, or for optical signal transmission such as an optical fiber cable.

Further, for example, in the above-described embodiment, the case where the strip-shaped member is a PET resin tape and the non-transparent region portion is formed by a printing process has been given as an example, but the present invention is not limited thereto. .. That is, as long as the strip-shaped member is configured to have a transparent region portion and a non-transparent region portion, the forming material thereof is not particularly limited, and the strip-shaped member is formed of a resin material other than PET resin. It may be a thing. Further, the non-transparent region portion may also be colored by a method other than the printing process.

Further, the formation pattern (pattern) of the transparent region portion and the non-transparent region portion of the strip-shaped member is not limited to the mode described in the above-described embodiment, and the strip-shaped member is wound around the outer periphery of the electric wire. As long as the color of the outer skin of the electric wire and the color of the non-transparent region portion of the strip-shaped member can be visually recognized, an appropriately set formation pattern (pattern) may be used.

(5) Preferred Aspects of the Present Invention The preferred embodiments of the present invention will be described below.

[Appendix 1]
According to one aspect of the invention
This is an electric wire identification method for identifying a plurality of electric wires whose conductors are covered with an outer skin.
A strip-shaped member is wound around at least one of the plurality of electric wires, and the strip-shaped member is wound around the outer circumference.
The strip-shaped member includes a transparent region portion that makes the outer skin of the electric wire around which the strip-shaped member is wound visible, and a non-transparent region portion that is colored different from the outer skin. A wire identification method using is provided.

[Appendix 2]
Preferably,
The width w of the strip-shaped member and the diameter d of the electric wire around which the strip-shaped member is wound are
3d ≤ w ≤ 10d
The electric wire identification method according to Appendix 1 that satisfies the relationship is provided.

[Appendix 3]
Preferably,
The electric wire identification method according to Appendix 1 or 2 in which the strip-shaped member is wound around the electric wire by lap winding is provided.

[Appendix 4]
Preferably,
The electric wire identification method according to any one of Supplementary note 1 to 3, wherein the electric wire is an ultrafine wire having a diameter of 0.3 mm or less is provided.

[Appendix 5]
Preferably,
The electric wire identification method according to any one of Appendix 1 to 4, wherein a polyethylene terephthalate resin tape having a non-transparent region portion formed by a printing process is used as the strip-shaped member.

[Appendix 6]
According to another aspect of the invention
It is a cable unit composed of a plurality of electric wires whose conductors are covered with an outer skin.
A strip-shaped member is wound around at least one of the plurality of electric wires.
The strip-shaped member is configured to have a transparent region portion that makes the outer skin of the electric wire around which the strip-shaped member is wound visible, and a non-transparent region portion that is colored different from the outer skin. A cable unit is provided.

[Appendix 7]
According to yet another aspect of the invention.
With the conductor
The exodermis that covers the conductor and
A band-shaped member wrapped around the outer circumference of the exodermis is provided.
The strip-shaped member is provided with an electric wire having a transparent region portion that makes the outer skin visible and a non-transparent region portion that is colored differently from the outer skin.

[Appendix 8]
According to yet another aspect of the invention.
A band-shaped member that is wound around an electric wire whose conductor is covered with an outer skin to distinguish the electric wire from other electric wires.
The transparent area portion that makes the exodermis visible, and
A non-transparent area portion colored differently from the exodermis,
A strip-shaped member configured with the above is provided.

1 ... Cable unit, 10, 10a to 10h ... Electric wire (enamel wire), 11 ... Conductor, 12, 12a to 12h ... Outer skin (enamel layer), 13a ... First electric wire group, 13b ... Second electric wire group, 20 ... Band shape Member, 21 ... Transparent region portion, 22 ... Non-transparent region portion

Claims (3)

This is an electric wire identification method for identifying a plurality of electric wires whose conductors are covered with an outer skin.
A strip-shaped member is wound around at least one of the plurality of electric wires, and the strip-shaped member is wound around the outer circumference.
The strip-shaped member includes a transparent region portion that makes the outer skin of the electric wire around which the strip-shaped member is wound visible, and a non-transparent region portion that is colored different from the outer skin. using,
The strip-shaped member is wound over the outer circumference of the electric wire so that the pattern formed by the transparent region portion and the non-transparent region portion is exposed on the surface of the overlapping portion of the strip-shaped member.
A method for identifying an electric wire based on the pattern exposed on the surface and the color of the outer skin . The width w of the strip-shaped member and the diameter d of the electric wire around which the strip-shaped member is wound are
3d ≤ w ≤ 10d
The electric wire identification method according to claim 1, which satisfies the relationship. It is a cable unit composed of a plurality of electric wires whose conductors are covered with an outer skin.
A strip-shaped member is wound around at least one of the plurality of electric wires.
The belt-shaped member includes a transparent area portion to permit viewing of the outer skin of the wire to which the belt-shaped member is wound, is configured with a, and the non-transparent area portion attached different colors from that of the outer skin ,
The strip-shaped member is wound over the outer circumference of the electric wire so that the pattern formed by the transparent region portion and the non-transparent region portion is exposed on the surface of the overlapping portion of the strip-shaped member.
A cable unit in which an electric wire is identified by the pattern exposed on the surface and the color of the outer skin .

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