JP6883492B2 - Branch cable - Google Patents

Description

The present invention relates to a branch cable including a trunk cable and a branch cable branched from the trunk cable.

Conventionally, a branch cable has been used for the purpose of supplying electric power to each layer of a multi-story building (see, for example, Patent Documents 1 and 2). In this type of branch cable, from the viewpoint of weight reduction and the like, an aluminum electric wire using aluminum or an aluminum alloy may be used as the conductor instead of the copper electric wire using copper as the conductor.

For example, one of the conventional branch cables includes a trunk line cable, a plurality of branch line cables, and an end cable connected to each terminal of the plurality of branch line cables and connected to a distribution board or the like. ing. In this conventional branch cable, aluminum electric wires are used for the trunk cable and the branch cable from the viewpoint of weight reduction, and from the viewpoint of suppressing contact corrosion (galvanic corrosion) of dissimilar metals at the connection point with the distribution board or the like. Therefore, a copper electric wire is used for the end cable (see, for example, Patent Document 1).

Hereinafter, for convenience of explanation, contact corrosion between dissimilar metals (galvanic corrosion) is simply referred to as "corrosion".

JP-A-2016-152089 Japanese Unexamined Patent Publication No. 2010-086837

Due to the structure of the conventional branch cable described above, the end cable is connected to each terminal of the plurality of branch cable. Therefore, as the number of branch line cables increases, the number of steps for connecting the branch cable to the terminal of the branch line cable also increases, and the production of the branch cable may become complicated. Further, the connection point between the branch line cable and the end cable is usually sealed with a resin or the like in order to prevent corrosion between the copper electric wire and the aluminum electric wire. Therefore, the connecting point becomes bloated and it becomes difficult to bend at the connecting point, which may complicate the laying on a building or the like. As described above, although the conventional branch cable can suppress the corrosion in the distribution board and the like, its manufacture and use can be complicated.

However, from the viewpoint of further improving the performance of the branch cable, it is desirable to improve the corrosion resistance of the branch cable and further improve the workability when manufacturing and using the branch cable.

The present invention has been made in view of the above circumstances, and an object of the present invention is to improve the corrosion resistance of the branch cable and the workability when manufacturing and using the branch cable. Is to provide.

In order to achieve the above-mentioned object, the branch cable according to the present invention is characterized by the following (1) and (2).
(1)
A branch cable including a trunk cable, a branch cable connected to the trunk cable so as to branch from the trunk cable at a predetermined branch point, and a waterproof member covering the branch point.
The trunk line cable and the branch line cable
A conductor core wire in which a plurality of wires made of a material containing aluminum or an aluminum alloy are bundled, and a material having a standard electrode potential larger than that of the wire and contacting the outer periphery of the conductor core wire. It has a core wire portion having a conductor coating layer covering the conductor core wire, and an insulating layer covering the core wire portion.
At the turning point
The trunk cable and the branch cable are connected so that the conductor coating layer of the trunk cable and the conductor coating layer of the branch cable are in contact with each other.
Must be a branch cable.
(2)
In the branch cable described in (1) above,
The conductor coating layer is
Composed of materials containing copper, silver, tin, copper alloys, silver alloys or tin alloys,
Must be a branch cable.

According to the branch cable having the configuration of (1) above, both the trunk cable and the branch cable are a conductor core wire in which a plurality of strands made of a material containing aluminum or an aluminum alloy are bundled as a core wire, and a wire. It has a conductor coating layer, which is made of a material having a standard electrode potential larger than that of the wire (for example, copper or a copper alloy generally used as a material for a copper electric wire) and covers the conductor core wire so as to be in contact with the outer periphery of the conductor core wire. There is. Further, at the branch point between the trunk cable and the branch cable, the trunk cable and the branch cable are connected so as to bring the conductor coating layers of both into contact with each other. In addition, the branch point between the main cable and the branch cable is covered with a waterproof member.

Therefore, since the branch point (the contact point between the main cable and the branch line cable) is isolated from the outside by the waterproof member, corrosion at the branch point can be suppressed. Further, at the connection point between the branch cable and the distribution board, the conductor coating layer (made of a material having a higher standard electrode potential than the wire) covering the conductor core wire and the terminal of the distribution board (generally made of copper) are brought into contact with each other. As a result, corrosion at this connection point can be suppressed as compared with the case where the conductor core wire (made of aluminum or aluminum alloy) is brought into contact with the terminal of the distribution board. In addition, unlike the conventional branch cable described above, it is not necessary to provide a connecting point on the branch cable, so that it is easier to lay in a building or the like as compared with the conventional branch cable. Compared with the case of using a general copper electric wire, the weight of the branch cable can be reduced because the conductor core wire is made of a material containing aluminum or an aluminum alloy.

Therefore, the branch cable having this configuration can achieve both improvement in corrosion resistance of the branch cable and improvement in workability when manufacturing and using the branch cable.

According to the branch cable having the configuration of (2) above, the conductor coating layer is composed of a material containing copper, silver, tin, a copper alloy, a silver alloy, or a material containing a tin alloy. This allows the conductor coating layer to be constructed using commonly available materials.

According to the present invention, it is possible to provide a branch cable capable of both improving the corrosion resistance of the branch cable and improving the workability when manufacturing and using the branch cable.

The present invention has been briefly described above. Further, the details of the present invention will be further clarified by reading through the embodiments described below (hereinafter referred to as "embodiments") with reference to the accompanying drawings.

FIG. 1 is a schematic view showing a usage state of a branch cable according to an embodiment of the present invention. FIG. 2 is a schematic view showing the internal structure of the trunk cable and the branch cable constituting the branch cable of FIG. FIG. 3A is a schematic view of a branch point (connection point) of the trunk cable and the branch line cable in the branch cable of FIG. 1, and FIG. 3B is a sectional view taken along the line AA of the branch point. .. FIG. 4A is a schematic view of a terminal portion of the trunk cable in the branch cable of FIG. 1, and FIG. 4B is a cross-sectional view taken along the line BB of the terminal portion.

Hereinafter, the branch cable 100 according to the embodiment of the present invention will be described with reference to the drawings.

As shown in FIG. 1, the branch cable 100 includes a trunk cable 110 and a plurality of branch cable 120 (two in FIG. 1) connected to the trunk cable 110 so as to branch from the trunk cable 110. There is. The branch cable 100 is a cable for supplying electric power to a multi-layered building (for example, a middle-high-rise building or the like), and has, for example, a number of branch line cables 120 corresponding to the number of floors of the multi-layered building.

The branch cable 100 is fixed to the ceiling wall L of the multi-layer building by a jig 101 attached to the upper end of the trunk cable 110. The middle part of the trunk cable 110 is fixed to the wall surface of each floor by a jig (not shown). The trunk cable 110 is connected to the power supply 200 for power supply.

The branch line cable 120 is electrically connected to the main line cable 110 at a branch point 130 with the main line cable 110. Details of the connection structure between the main cable 110 and the branch cable 120 at the branch point 130 will be described later. The branch line cable 120 is connected to the distribution board 300 installed on each floor of the multi-story building, and supplies the electric power supplied through the trunk line cable 110 to the distribution board 300.

As shown in FIG. 2, the trunk cable 110 includes a conductor core wire 111 in which a plurality of strands 111a are bundled, a conductor coating layer 112 that covers the conductor core wire 111 so as to contact the outer periphery of the conductor core wire 111, and a conductor coating layer. It has an insulating layer 113 that covers 112. The conductor core wire 111 and the conductor coating layer 112 form a core wire portion 114 of the trunk cable 110.

The specific method for providing the conductor coating layer 112 so as to cover the conductor core wire 111 is not particularly limited. For example, the conductor coating layer 112 can be provided by extrusion-molding the tubular conductor coating layer 112 so as to cover the conductor core wire 111, as in the so-called clad wire manufacturing method. Further, for example, the conductor coating layer 112 may be provided by winding the tape-shaped conductor coating layer 112 so as to cover the conductor core wire 111.

The strand 111a is made of a material containing aluminum or an aluminum alloy. On the other hand, the conductor coating layer 112 is made of a material having a standard electrode potential larger than that of the wire 111a. Examples of the material constituting the conductor coating layer 112 include a material containing copper, silver, tin, a copper alloy, a silver alloy, or a tin alloy.

Although the internal structure of the trunk cable 110 is shown in FIG. 2, the branch cable 120 also has the same internal structure as the trunk cable 110. Specifically, the branch wire cable 120 includes a conductor core wire 121 in which a plurality of strands 121a are bundled, a conductor coating layer 122 that covers the conductor core wire 121 so as to contact the outer periphery of the conductor core wire 121, and a conductor coating layer 122. It has an insulating layer 123 covering the above. The conductor core wire 121 and the conductor coating layer 122 form a core wire portion 124 of the branch wire cable 120. Further, the wire 121a is made of a material containing aluminum or an aluminum alloy, and the conductor coating layer 122 is made of a material having a standard electrode potential higher than that of the wire 121a (such as copper as described above).

The "standard electrode potential" is a parameter related to the ionization tendency (proneness of corrosion) of the material, and the smaller the standard electrode potential, the greater the ionization tendency and the more easily corroded. The standard electrode potential can be defined, for example, as the electromotive force in the standard state of a battery made by combining an electrode of the material and a standard hydrogen electrode. The standard electrode potential of aluminum is about -1.67V, the standard electrode potential of tin is about -0.14V, the standard electrode potential of copper is about 0.52V, and the standard electrode potential of silver is about 0. It is 80V. The standard electrode potential of an aluminum alloy varies depending on its composition, but is generally smaller than the standard electrode potential of tin, copper, silver and the like described above. Similarly, the standard electrode potentials of tin alloys, copper alloys and silver alloys are generally higher than the standard electrode potentials of aluminum and aluminum alloys described above, depending on their composition.

In this example, the conductor core wire 111 of the trunk cable 110 is a stranded wire obtained by twisting a plurality of strands 111a. However, the plurality of strands 111a may be arranged so as to be parallel to each other while remaining linear. Further, if necessary, another layer (for example, a protective sheath or the like) may be provided so as to cover the insulating layer 113. The same applies to the branch line cable 120.

As shown in FIGS. 3A and 3B, at the branch point 130, the insulating layer 113 of the trunk cable 110 is removed, and the core wire portion 114 of the trunk cable 110 is exposed. Similarly, the insulating layer 123 of the branch line cable 120 is removed, and the core wire portion 124 of the branch line cable 120 is exposed. At the branch point 130, the outer peripheral surface of the core wire portion 114 of the trunk cable 110 (that is, the conductor coating layer 112) and the outer peripheral surface of the core wire portion 124 of the branch wire cable 120 (that is, the conductor coating layer 122) are in contact with each other. In this state, it is fixed while being pressed by the compression connector 140. As a result, the conductor core wire 111 and the conductor coating layer 112 of the trunk cable 110, and the conductor core wire 121 and the conductor coating layer 122 of the branch wire cable 120 are connected so as to be able to transmit power.

At the branch point 130, a waterproof member 150 made of polyethylene or the like is provided so as to cover the core wire portion 114 of the trunk cable 110 and the core wire portion 124 of the branch wire cable 120 connected as described above. As a result, water droplets or the like come into contact with the conductor core wire 121 exposed on the end surface of the core wire portion 124 of the branch wire cable 120 and the conductor coating layer 122, and galvanic corrosion between the conductor core wire 121 and the conductor coating layer 122 occurs. It is possible to suppress the occurrence of (galvanic corrosion).

It is preferable that the above-mentioned processing of the branch point 130 is performed in a factory or the like in advance before installing the branch cable 100 in the multi-layer building. By processing the branch point 130 in a factory where the processing environment is controlled, reliable electrical connection between the main cable 110 and the branch line cable 120 at the branch point 130 and reliable waterproofing of the branch point 130 can be achieved. It can be planned.

As shown in FIGS. 4A and 4B, a terminal 115 for connecting the trunk cable 110 to the power supply 200 is attached to the terminal portion of the trunk cable 110. A through hole 116 is provided at the tip of the terminal 115, and the terminal 115 is fastened to the power supply terminal 220 of the power supply 200 with the bolt 210 inserted through the through hole 116.

The core wire portion 114 is exposed from the end of the trunk cable 110. Then, the core wire portion 114 is crimped to the terminal 115 by the crimping piece 115a of the terminal 115 so that the outer peripheral surface of the core wire portion 114 (that is, the conductor coating layer 112) and the surface of the terminal 115 are brought into pressure contact with each other. Further, the crimping piece 115b is crimped to the end portion (insulating layer 113) of the trunk cable 110 so that the terminal 115 is not separated from the trunk cable 110.

Further, a waterproof coating 117 is provided so as to cover the connection portion between the terminal 115 and the core wire portion 114 (particularly, the conductor core wire 111 and the conductor coating layer 112 exposed on the end surface of the core wire portion 114). As a result, water droplets or the like come into contact with the conductor core wire 111 exposed on the end surface of the core wire portion 114 of the trunk cable 110 and the conductor coating layer 112, and corrosion occurs between the conductor core wire 111 and the conductor coating layer 112. Can be suppressed.

Although the connection structure between the trunk cable 110 and the power supply 200 is shown in FIG. 4, the connection structure between the branch line cable 120 and the distribution board 300 also has the same structure. Specifically, the terminal 125 is attached to the terminal portion of the branch line cable 120. The outer peripheral surface of the core wire portion 124 (that is, the conductor coating layer 122) and the surface of the terminal 125 are in pressure contact with each other. Further, a waterproof coating 127 is provided so as to cover the connection portion between the terminal 125 and the core wire portion 124 (particularly, the conductor core wire 121 and the conductor coating layer 122 exposed on the end surface of the core wire portion 124). As a result, it is possible to prevent corrosion from occurring between the conductor core wire 121 exposed on the end surface of the core wire portion 124 and the conductor coating layer 122.

As described above, according to the branch cable 100 according to the embodiment of the present invention, the trunk cable 110 and the branch cable 120 have a plurality of core wire portions 114 and 124 made of a material containing aluminum or an aluminum alloy. The conductor core wire 111, 121 in which the strands 111a, 121a are bundled, and the conductor coating layer 112, which is composed of a material (copper or the like) having a higher standard electrode potential than the strands 111a, 121a and covers the conductor core wires 111, 121. , 122 ,. Further, at the branch point 130, the trunk line cable 110 and the branch line cable 120 are connected so as to bring the conductor covering layers 112 and 122 into contact with each other.

Since the branch point 130 is isolated from the outside by the waterproof member 150, corrosion at the branch point 130 can be suppressed. Further, at the connection point between the branch cable 120 and the distribution board 300 or the like, if the conductor coating layer 122 covering the conductor core wire 121 and the terminal (generally made of copper) of the distribution board 300 are brought into contact with each other, the conductor core wire 121 (aluminum) Or, as compared with the case where (made of aluminum alloy) is brought into contact with the terminals of the distribution board 300, corrosion at this connection point can be suppressed. The same applies to the connection points between the trunk cable 110 and the power supply 200.

In addition, unlike the conventional branch cable described above, it is not necessary to provide a connecting point on the branch cable 120, so that it is easier to lay in a building or the like as compared with the conventional branch cable. Compared with the case of using a general copper electric wire, the weight of the branch cable 100 can be reduced because the conductor core wires 111 and 121 are made of a material containing aluminum or an aluminum alloy.

Therefore, the branch cable 100 can achieve both improvement in corrosion resistance and improvement in workability during manufacturing and use.

The present invention is not limited to each of the above embodiments, and various modifications can be adopted within the scope of the present invention. For example, the present invention is not limited to the above-described embodiment, and can be appropriately modified, improved, and the like. In addition, the material, shape, dimensions, number, arrangement location, etc. of each component in the above-described embodiment are arbitrary and are not limited as long as the present invention can be achieved.

Here, the features of the above-described embodiment of the branch cable according to the present invention are briefly summarized and listed below (1) and (2), respectively.
(1)
A trunk cable (110), a branch cable (120) connected to the trunk cable so as to branch from the trunk cable at a predetermined branch point (130), and a waterproof member (150) covering the branch point. A branch cable (100) equipped with,
The trunk line cable (110) and the branch line cable (120)
A conductor core wire (111, 121) in which a plurality of wires (111a, 121a) made of a material containing aluminum or an aluminum alloy are bundled, and a material having a standard electrode potential larger than that of the wire and described above. It has a core wire portion (114, 124) having a conductor coating layer (112, 122) covering the conductor core wire so as to contact the outer periphery of the conductor core wire, and an insulating layer (113, 123) covering the core wire portion. And
At the branch point (130)
The trunk cable (110) and the branch cable (120) are connected so that the conductor coating layer (112) of the trunk cable and the conductor coating layer (122) of the branch cable come into contact with each other. ,
Branch cable.
(2)
In the branch cable described in (1) above,
The conductor coating layer (112, 122) is
Composed of materials containing copper, silver, tin, copper alloys, silver alloys or tin alloys,
Branch cable.

100 Branch cable 110 Trunk cable 111,121 Conductor core wire 111a, 121a Wire 112,122 Conductor coating layer 113,123 Insulation layer 114,124 Core wire portion 115,125 Terminal 117,127 Waterproof coating 120 Branch wire cable 130 Branch point 140 Compression Connector 150 Waterproof member 200 Power supply 300 Distribution board

Claims (2)

A branch cable including a trunk cable, a branch cable connected to the trunk cable so as to branch from the trunk cable at a predetermined branch point, and a waterproof member covering the branch point.
The trunk line cable and the branch line cable
A conductor core wire in which a plurality of wires made of a material containing aluminum or an aluminum alloy are bundled, and a material having a standard electrode potential larger than that of the wire and contacting the outer periphery of the conductor core wire. It has a core wire portion having a conductor coating layer covering the conductor core wire, and an insulating layer covering the core wire portion.
At the turning point
The trunk cable and the branch cable are connected so that the conductor coating layer of the trunk cable and the conductor coating layer of the branch cable are in contact with each other.
Branch cable. In the branch cable according to claim 1,
The conductor coating layer is
Composed of materials containing copper, silver, tin, copper alloys, silver alloys or tin alloys,
Branch cable.

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