KR20240016855A - Electric wire and cable - Google Patents

Abstract

(Task) Provide wires and cables that can suppress electrostatic corrosion.
(Solution) The electric wire 1 includes a conductor 2 and an insulator 3 provided to cover the periphery of the conductor 2, and the conductor 2 is a first wire made of aluminum or aluminum alloy ( 211), and a second conductor portion 2b using a second wire 221 made of copper or a copper alloy, the first conductor portion 2a and the second conductor portion It is installed to be inserted between (2b) and is provided with an electrochemical corrosion suppression member (4) that suppresses electrochemical corrosion from occurring between the first conductor portion (2a) and the second conductor portion (2b).

Description

Electric wire and cable{ELECTRIC WIRE AND CABLE}

The present invention relates to electric wires and cables.

Conventionally, insulated wires including a conductor and an insulator provided to cover the periphery of the conductor have been widely used. In Patent Document 1, a metal wire used in a conductor is provided with a core made of aluminum or an aluminum alloy and a metal layer made of copper or a copper alloy covering the outer periphery of the core. A wire using covered wire has been proposed.

Japanese Patent Laid-Open No. 2018-56101

When a wire made of aluminum or an aluminum alloy and a wire made of copper or a copper alloy are used together as a conductor of an electric wire or cable, for example, in a humid environment, electrochemical corrosion (hereinafter referred to as , there is a risk that electrocution may occur, so countermeasures are required.

Therefore, the purpose of the present invention is to provide electric wires and cables that can suppress electrostatic corrosion.

The present invention, for the purpose of solving the above problems, is provided with a conductor and an insulator installed to cover the periphery of the conductor, wherein the conductor includes a first conductor portion using a first wire made of aluminum or an aluminum alloy, and copper or A second conductor portion using a second wire made of copper alloy is installed to be inserted between the first conductor portion and the second conductor portion, and electrochemical corrosion occurs between the first conductor portion and the second conductor portion. An electric wire equipped with an electrostatic suppression member that suppresses this occurrence is provided.

In addition, for the purpose of solving the above problems, the present invention provides a cable including a cable core including a plurality of the electric wires and a sheath provided to collectively cover the circumference of the cable core.

According to the present invention, electric wires and cables capable of suppressing electrostatic corrosion can be provided.

[Figure 1] A diagram showing an electric wire according to the first embodiment of the present invention, where (a) is a cross-sectional view showing a cross section perpendicular to the longitudinal direction, and (b) is a diagram explaining the overlapping of electrostatic suppression members.
[Figure 2] This is an enlarged view of a portion of Figure 1(a).
[Figure 3] (a) is a cross-sectional view showing a corrosion suppression member, and (b) to (d) are views showing modifications thereof.
[Figure 4] (a) and (b) are cross-sectional views showing modified examples of the conductor.
[Figure 5] (a) and (b) are cross-sectional views showing modified examples of the conductor.
[Figure 6] A cross-sectional view showing a cross-section perpendicular to the longitudinal direction of the cable according to the first embodiment of the present invention.

[Embodiment]

In the following, embodiments of the present invention will be described according to the attached drawings.

1 is a diagram showing the electric wire 1 according to this embodiment, where (a) is a cross-sectional view showing a cross section perpendicular to the longitudinal direction, and (b) is a diagram explaining the overlapping of the electrostatic suppression members 4. . Additionally, Figure 1(b) schematically shows a cross section parallel to the longitudinal direction of the electric wire 1.

As shown in Figures 1(a) and 1(b), the electric wire 1 includes a conductor 2 and an insulator 3 provided to cover the periphery of the conductor 2. When the wire 1 is used, for example, as a power wire for power supply, its conductor cross-sectional area is 0.75 mm ² (0.75 SB) or more and 350 mm ² (350 SB) or less. The electric wire 1 according to this embodiment is effective in achieving the effect of reducing the amount of copper used, especially when the outer diameter (outer diameter of the insulator 3) is relatively large, such as 10 mm or more. The conductor cross-sectional area is 60mm ² (60S) or more, more preferably 80mm ² (80S) or more. In this embodiment, the conductor cross-sectional area was set to approximately 100mm ² (100SK). In addition, the wire 1 is not limited to being used as a power line for power supply, and may be used as a signal line for signal transmission, for example. When used as a signal line, the outer diameter of the wire (1) is 0.8 mm or more and 2.0 mm or less, and the conductor cross-sectional area at this time is 0.10 mm ² (0.10 SB) or more and 1 mm ² (1 KB) or less.

(Conductor (2))

The conductor 2 includes a first conductor portion 2a located at the center of the electric wire 1 (center in a cross section perpendicular to the longitudinal direction), and a second conductor portion installed to cover the periphery of the first conductor portion 2a. It is provided with a two-conductor portion (2b).

The first conductor portion 2a uses a plurality of first natural wires 21 obtained by stranding a first element wire 211 made of aluminum or an aluminum alloy. It is composed of two first natural wires (21). Examples of the aluminum alloy used as the first wire 211 include Al-Zr alloy, Al-Ni-Zr alloy, Al-Co-Zr alloy, and Al-Fe-Zr alloy. Additionally, the first wire 211 may contain impurities that are unavoidable during manufacturing. The tensile strength of the first wire 211 is 200 MPa or less, and the elongation at break is 5% or more and 17% or less. The tensile strength and breaking elongation of the first wire 211 are smaller than those of the second wire 221, which will be described later. Here, the first wire 211 made of aluminum with an outer diameter of 0.45 mm was used. The outer diameter of the first wire 211 is, for example, 0.10 mm or more and 0.50 mm or less. The outer diameter of the first wire 211 is preferably equal to or smaller than the outer diameter of the second wire 221. For example, the outer diameter of the first wire 211 may be 90% or more and 100% or less of the outer diameter of the second wire 221. Accordingly, it is easy to obtain the effect of reducing the outer diameter of the conductor 2 while reducing the amount of copper used in the conductor 2.

Each first natural wire 21 constituting the first conductor portion 2a is composed of a plurality of first wires 211 stranded in a set. That is, each first natural wire 21 is composed of a plurality of first strands 211 collectively stranded. By configuring the first natural wire 21 by stranding a plurality of first wires 211 in a set, the first wire 211 becomes easy to move within the first natural wire 21, and the first wire 211 is easily moved by external force. The shape of the natural line 21 becomes easy to change. Therefore, between the first natural wire 21 or between the first natural wire 21 and the second natural wire 22 (described later) due to the force at the time of stranding the second natural wire 22, which will be described later. By reducing the gap, the outer diameter of the conductor 2 can be reduced. In this embodiment, the first natural wire 21 is composed of 16 first strands 211 collectively stranded. Additionally, the number of first wires 211 constituting the first natural wire 21 is not limited to 16. That is, the number of first strands 211 constituting the first natural wire 21 may be at least 16 or more than 16.

In addition, in the present embodiment shown in Fig. 1, the number of first natural wires 21 constituting the first conductor portion 2a is 19, but the number is not limited to this. The number of first natural wires 21 constituting the first conductor portion 2a is the ratio of the number of first natural wires 21 and the number of second natural wires 22, which will be described later (first natural wire ( 21)/number of second natural wires 22) can be appropriately changed within the range of 40/60 or more and 60/40 or less. In addition, the outer diameter of the first natural wire 21 is preferably equal to or smaller than the outer diameter of the second natural wire 22, which will be described later. Accordingly, the first natural wire 21 made of aluminum or aluminum alloy, which is more susceptible to deformation than the second natural wire 22 made of copper or a copper alloy, is more likely to be deformed by the force received from the second natural wire 22. Lose. Therefore, it becomes easy to obtain the effect of reducing the outer diameter of the conductor 2 while reducing the amount of copper used in the conductor 2.

The first conductor portion 2a is composed of a plurality of first natural wires 21 stranded concentrically. In this embodiment, a total of 19 first natural wires 21, including 1 at the center of the electric wire 1, 6 around it, and 12 further around it, are stranded concentrically to form the first conductor portion 2a. was composed. Additionally, the concentric strand configuration of the first conductor portion 2a is not limited to this. For example, the first conductor portion 2a may be configured with one concentric wire at the center and six first natural wires 21 around it. In addition, the first conductor portion 2a is configured as a concentric wire by arranging one at the center, six around the center, twelve around the center, and a plurality of first natural wires 21 further around the center. Even if it is, it’s okay. By configuring the first conductor portion 2a as a concentric strand, the outer diameter can be reduced while increasing the cross-sectional area of the conductor, and the entire conductor 2 is made small, which leads to a smaller diameter of the entire wire 1. In addition, the number of first natural wires 21 used in the first conductor portion 2a is not limited to 19, and for example, the 12 first natural wires 21 in the outermost layer may be reduced to 7. , In addition, 18 additional first natural wires 21 may be added to the outermost layer to make the number 37.

The second conductor portion 2b uses a plurality of second natural wires 22 obtained by stranding a second bare wire 221 made of copper or a copper alloy, and the plurality of second natural wires 22 are connected to the first wire 22. It is constructed by twisting the wire around the conductor portion 2a. The surface of the second wire 221 may be plated with Zn (for example, Zn with an amorphous structure), Ni, Sn, or the like. The tensile strength of the second wire 221 is 220 MPa or more, and the elongation at break is 10% or more. The tensile strength and breaking elongation of the second wire (221) are greater than those of the first wire (211). Here, the second wire 221 made of Sn-plated annealed copper wire with an outer diameter of 0.45 mm, which is the same outer diameter as the first wire 211, was used. The outer diameter of the second wire 221 is, for example, 0.10 mm or more and 0.50 mm or less. The outer diameter of the second wire 221 is preferably equal to or larger than the outer diameter of the first wire 211. Accordingly, it is easy to obtain the effect of reducing the outer diameter of the conductor 2 while reducing the amount of copper used in the conductor 2.

Each second natural wire 22 constituting the second conductor portion 2b is composed of a plurality of second wires 221 stranded in a set. By forming the second natural wire 22 by stranding a plurality of second wires 221 in a set, the second wire 221 becomes easy to move within the second natural wire 22, and the second wire 221 is easily moved by external force. The shape of the natural line 22 becomes easy to change. Therefore, the gap between the second natural wires 22 or between the first natural wire 21 and the second natural wire 22 is reduced due to the force when stranding the second natural wire 22, etc. The outer diameter of the conductor (2) can be reduced. In this embodiment, like the first natural wire 21 described above, the second natural wire 22 is formed by stranding 16 second wires 221 in a set. Additionally, the number of second wires 221 constituting the second natural wire 22 is not limited to 16. The number of second strands 221 constituting the second natural wire 22 may be at least 16 or more than 16.

In addition, in this embodiment shown in FIG. 1, the number of second natural wires 22 constituting the second conductor portion 2b is 18, but the number is not limited to this. The number of second natural wires 22 constituting the second conductor portion 2b is the ratio of the number of first natural wires 21 to the number of second natural wires 22 (first natural wire 21) The number/number of second natural wires 22) can be appropriately changed within the range of 40/60 or more and 60/40 or less. In addition, the outer diameter of the second natural line 22 is preferably equal to or larger than the outer diameter of the first natural line 21. Accordingly, the first natural wire 21 made of aluminum or aluminum alloy, which is more easily deformed than the second natural wire 22 made of copper or a copper alloy, is more likely to be deformed by the force received from the second natural wire 22. (That is, the first natural wire 21 can be easily deformed by the second natural wire 22, which is harder than the first natural wire 21). Therefore, it becomes easy to obtain the effect of reducing the outer diameter of the conductor 2 while reducing the amount of copper used in the conductor 2.

In this embodiment, the first strand 211 and the second strand 221 are used with the same outer diameter, and the number of the first strands 211 constituting the first natural wire 21 and the second natural wire 221 are The number of second strands 221 constituting the line 22 is the same. Therefore, the outer diameters of the first natural line 21 and the second natural line 22 are substantially the same. Accordingly, it is difficult for a gap to occur between the natural lines 21 and 22 due to the concentric strands.

The second conductor portion 2b is composed of 18 second natural wires 22 stranded around the first conductor portion 2a, and thus the entire conductor 2 is composed of concentric strands. . That is, the conductor 2 is composed of a plurality of (here, 19) first natural wires 21 and a plurality of (here, 18) second natural wires 22 stranded concentrically. Accordingly, the outer diameter can be reduced while increasing the cross-sectional area of the conductor, and the entire conductor 2 is made small, which leads to a smaller diameter of the entire wire 1.

The ratio of the number of first natural wires 21 and the number of second natural wires 22 used in the conductor 2 (number of first natural wires 21/number of second natural wires 22) is Anything above 40/60 and below 60/40 is good. In addition, the conductor 2 has a cross-sectional area of the first conductor portion 2a (=the sum of the cross-sectional areas of each first natural wire 21) and a cross-sectional area of the second conductor portion 2b (=each second natural wire 21). It is good if the ratio (sum of the cross-sectional areas of the lines 22) is 40/60 or more and 60/40 or less. Accordingly, the increase in the resistance value of the conductor 2 is suppressed and the amount of heat generated is suppressed, the amount of copper used is reduced, and the wire 1 can be made of a small diameter, making it possible to realize the wire 1 that is lightweight and easy to bend. For example, by reducing the amount of copper used in the conductor 2 and making the wire 1 of a small diameter, the resistance value (=conductor resistance) of the conductor 2 is reduced to reduce the conductivity of the conductor 2. ) is further increased, the ratio of the cross-sectional area of the first conductor portion 2a and the cross-sectional area of the second conductor portion 2b is 40/50 or more and 50/50 or less (more preferably 40/50 or more and 45/55). (below) is good. On the other hand, in the case where the amount of copper used in the conductor 2 is reduced and the wire 1 has a small diameter, and the wire 1 is made lighter and easier to bend, the cross-sectional area of the first conductor portion 2a and the first conductor portion 2a are reduced. The ratio of the cross-sectional areas of the two conductor portions 2b may be 50/50 or more and 60/40 or less (more preferably 55/45 or more and 60/40 or less). In addition, the ratio of the number of first natural wires 21 and the number of second natural wires 22 used in the conductor 2 is changed within the range of 40/60 or more and 60/40 or less to obtain the above-mentioned cross-sectional area. It is possible to obtain the same effect as when changing the ratio.

However, when forming the conductor 2, the second natural wire 22 made of copper or copper alloy is stranded around the first conductor portion 2a made of aluminum or aluminum alloy to form the second conductor portion 2b. ) to form. At this time, since the first conductor portion 2a made of aluminum or aluminum alloy is relatively soft and easily deformed, the second natural wire 22 made of copper or copper alloy has higher rigidity than the first natural wire 21. ) is stranded around the first conductor portion 2a, the first conductor portion 2a is press-fitted (compressed) inward (towards the center of the cable) by the force applied during stranding. As a result, the first natural wire 21 constituting the first conductor portion 2a is pressed, the gap within the first conductor portion 2a becomes smaller, and the outer diameter of the first conductor portion 2a becomes smaller (i.e. , the outer diameter of the first conductor portion 2a becomes smaller compared to the state before stranding the second natural wire 22). As a result, the outer diameter of the entire conductor 2 can be reduced, and the overall diameter of the electric wire 1 can be reduced.

That is, by constructing the first conductor portion 2a of aluminum or aluminum alloy, the outer diameter of the conductor 2 can be reduced while maintaining the conductor cross-sectional area, thereby reducing the overall outer diameter of the electric wire 1. For example, in this embodiment, the conductor cross-sectional area is set to 100 mm ² (100 SB), but the outer diameter of the conductor 2 can be reduced to an outer diameter equivalent to 80 mm ² (80 KB) for a conductor using only conventional copper wires. You can.

Additionally, by constructing the first conductor portion 2a from aluminum or an aluminum alloy, it becomes possible to reduce the weight of the electric wire 1 compared to the case where the entire conductor 2 is comprised of copper or a copper alloy. In addition, since aluminum or aluminum alloy is easier to deform compared to copper or copper alloy, by making the first conductor portion 2a of aluminum or aluminum alloy, it becomes easier to bend the electric wire 1, which reduces the work during wiring work. Performance can be improved.

However, the first wire 211 made of aluminum or aluminum alloy is vulnerable to external damage, and there is a risk that the wire may be easily broken if damaged. By providing the second conductor portion 2b made of alloy, the first wire 211 constituting the first conductor portion 2a is protected from trauma by the second conductor portion 2b, and the first wire 211 ) can be suppressed.

Additionally, bending resistance can be improved by constructing the second conductor portion 2b, where the load is concentrated during bending, of copper or copper alloy with relatively high strength. In addition, by making the second conductor portion 2b of copper or a copper alloy, the resistance value of the conductor 2 can be prevented from becoming too large, and the electrical power is approximately equivalent to that of a conventional electric wire using a conductor made only of copper or a copper alloy. characteristics can be maintained.

Additionally, by constructing the second conductor portion 2b of copper or a copper alloy, connection of the conductor 2 to a terminal, etc. becomes easier compared to the case where the entire conductor 2 is comprised of aluminum or an aluminum alloy. For example, when the entire conductor 2 is made of aluminum or an aluminum alloy, it is necessary to use a terminal of a special structure to maintain the strength of the connection, but the second conductor portion 2b is made of copper or a copper alloy. By doing so, conventionally commonly used terminals (for example, terminals fixed to the end of the conductor 2 by caulking) can be used, and connection by soldering, etc., as usual, is also possible. This improves versatility.

In addition, in the conventional electric wire using only copper or copper alloy as a conductor, there was a case in which it sags under its own weight when wired floating, but in the electric wire 1 according to this embodiment, the first conductor portion 2a is made of aluminum or Because the weight is reduced by using aluminum alloy, and the rigidity of the electric wire 1 can be secured by using copper or copper alloy as the second conductor portion 2b, the electric wire 1 can be floated (for example, U Even if the wiring is bent in a ruler-shaped state, sagging due to its own weight can be suppressed.

(Electrification suppression member (4))

As described above, in this embodiment, the first conductor portion 2a is made of aluminum or an aluminum alloy, and the second conductor portion 2b is made of copper or a copper alloy. Since aluminum and copper have a large standard electrode potential difference, there is a risk that electrochemical corrosion (hereinafter referred to as electrochemical corrosion) may occur depending on the environment in which they are used, such as a humid environment. Therefore, in the present embodiment, the corrosion suppression member 4, which suppresses electrostatic corrosion from occurring between the first conductor portion 2a and the second conductor portion 2b, is connected to the first conductor portion 2a and the second conductor portion 2b. It is installed by inserting it between (2b).

In this embodiment, the corrosion suppression member 4 is made of one or more conductive tape members wound in a spiral shape around the first conductor portion 2a. In this embodiment, the case where the corrosion suppression member 4 is made of one tape member 41 will be described. Details of the tape member 41 will be described later. The second conductor portion 2b is formed by twisting a plurality of second natural wires 22 in a spiral shape around the electrostatic suppression member 4.

As shown in Fig. 1(b), the tape member 41, which is the electrostatic suppression member 4, is formed so that a portion of the tape member 41 in the width direction overlaps (as if laps) the first conductor portion 2a. is wrapped in The wrap length (overlap width) during winding may be 1/3 to 1/2 of the width of the tape member 41. The width of the tape member 41 is, for example, 10 mm or more and 50 mm or less. When the wrap length is 1/3 or more of the width of the tape member, the occurrence of gaps between the tape members is suppressed even when the electric wire 1 is bent. In addition, when the wrap length is 1/2 or less of the width of the tape member, overlapping of three or more tape members is suppressed, and the occurrence of gaps in the wrap portion is suppressed to stabilize the electrical characteristics of the conductor 2. In addition to making this possible, the increase in diameter of the conductor 2 can be suppressed.

In this embodiment, the twisting direction of the first conductor portion 2a and the winding direction of the electrostatic suppression member 4 are reversed. Accordingly, it becomes possible to securely tighten the twist of the first conductor portion 2a with the electrostatic suppression member 4 so that it does not become loose, resulting in an increase in contact resistance due to sagging of the twist or a corresponding decrease in the electrical characteristics of the conductor 2. Deterioration can be suppressed. In addition, the twisting direction of the first conductor portion 2a is the direction in which the first natural wire 21 is rotating from one end to the other end when viewed from one end of the electric wire 1. In addition, the winding direction of the electrostatic suppression member 4 is the direction in which the tape member 41 is rotating from one end to the other end when viewed from one end of the electric wire 1.

Additionally, in this embodiment, the winding direction of the electrostatic suppression member 4 and the twisting direction of the second conductor portion 2a are in the same direction. That is, the twisting direction of the first conductor portion 2a and the twisting direction of the second conductor portion 2a are reversed. Accordingly, by twisting the second conductor portion 2a, the first conductor portion 2a is further tightened to suppress twisting sagging, and the first conductor portion 2a is compressed inward to reduce the overall outer diameter of the conductor 2. It can be made small. Additionally, the twisting direction of the second conductor portion 2b is the direction in which the second natural wire 22 rotates from one end to the other end when viewed from one end of the electric wire 1.

In addition, by setting the winding direction of the electrostatic suppression member 4 and the twisting direction of the second conductor portion 2a in the same direction, as shown in FIG. 2, the electrical corrosion suppression member 4 can be turned inward. By press-fitting, the gap 5 occurring around the electrostatic suppression member 4 can be made smaller. That is, the electrostatic suppression member 4 is press-fitted from the second conductor portion 2b side to the first conductor portion 2a, and the electrostatic suppression member 4 is inserted between the adjacent first natural wires 21. As it is inserted, the gap 5 around the electrostatic suppression member 4 becomes smaller. As a result, since the contact area between the first conductor portion 2a or the second conductor portion 2b and the electrostatic suppression member 4 can be increased, the first conductor portion 2a or the second conductor portion 2b The contact resistance of the electrostatic suppression member 4 can be reduced, and the electrical characteristics of the conductor 2 can be further improved. In addition, even when connecting the terminal to the end of the conductor 2 with caulk, the twist is unlikely to become loose, so it is difficult for an air gap to be created around the electrostatic corrosion suppressing member 4, and the conductor 2 and the terminal are protected from each other. Resistance at the connection part can be reduced.

As shown in Fig. 3(a), the tape member 41 used as the electrostatic suppression member 4 in this embodiment has a first metal layer 411 made of aluminum or aluminum alloy formed on one side. ) and a second metal layer 412 made of copper or a copper alloy formed on the other side, and is provided between the first metal layer 411 and the second metal layer 412 to adhere the two and electrically conduction. It is provided integrally with a conductive adhesive layer 413 for strengthening and a plating layer 414 made of tin formed on the surface of the second metal layer 412 by electroplating. The tape member 41 is formed around the first conductor portion 2a with the first metal layer 411 on the first conductor portion 2a side and the second metal layer 412 on the second conductor portion 2b side. (see Figure 1(b)).

The thickness of the first metal layer 411 made of aluminum or aluminum alloy and the thickness of the second metal layer 412 made of copper or copper alloy may be 7 μm or more and 25 μm or less. By setting the thickness of the first metal layer 411 and the second metal layer 412 to 7 μm or more, it is possible to prevent the tape member 41 from breaking even when, for example, the terminal is fixed to the end by caulking. In addition, by setting the thickness of the first metal layer 411 and the second metal layer 412 to 25 μm or less, the rigidity of the tape member 41 becomes too high to prevent the wire 1 from becoming difficult to bend or the conductor 2 from becoming large in diameter. can be suppressed. In addition, if the thickness of the first metal layer 411 and the second metal layer 412 is greater than 25 μm, the tape member 41 becomes hard, so the edge portion of the spirally wound tape member 41 ( There is a risk that the step occurring in the wrap portion may cause damage to the conductor portions 2a and 2b due to friction with the conductor portions 2a and 2b, but as in the present embodiment, the first metal layer 411 ) and by making the thickness of the second metal layer 412 smaller than 25 μm, such defects can be suppressed.

As the conductive adhesive layer 413, a hot melt type adhesive in which conductive particles are dispersed can be used. As a hot melt adhesive, for example, an acrylic adhesive can be used. As conductive particles, Ni particles can be used, for example. The thickness of the conductive adhesive layer 413 may be determined in consideration of the particle size of the conductive particles used, and may be 1 to 2 times the particle size of the conductive particles. In this embodiment, Ni particles with a particle size of about 6 μm are used as the conductive particles, but in this case, the thickness of the conductive adhesive layer 413 may be 6 μm or more and 12 μm or less.

As shown in Figure 1(b), the tape member 41 is wound so that a portion in the width direction thereof overlaps, so that the first metal layer 411 made of aluminum or aluminum alloy and the first metal layer 411 made of copper or copper alloy are formed. A portion where the second metal layer 412 is in contact occurs, and there is a risk that electrolysis may occur at this contact portion. Therefore, in order to suppress corrosion at the contact portion between the first metal layer 411 and the second metal layer 412, a plating layer 414 made of tin is formed on the surface of the second metal layer 412.

[Table 1]

As shown in Table 1, the standard electrode potential difference between aluminum (Al) and copper (Cu) is as large as 2V or more, and the potential difference is over 0.5V even in a natural potential close to the actual use environment (natural potential in a 0.1 MW aqueous solution). Because of this, it is easy for corrosion to occur. On the other hand, the standard electrode potential of tin (Sn) is closer to that of aluminum compared to copper, and in the natural potential close to the actual use environment (natural potential in 0.1 MW aqueous solution), the potential is almost halfway between that of aluminum and copper. Therefore, by inserting tin between copper and aluminum, the potential difference between adjacent metals can be reduced and electrostatic corrosion can be suppressed. Therefore, by forming the plating layer 414 made of tin on the surface of the second metal layer 412, corrosion in the wrap portion can be suppressed.

Additionally, as the plating layer 414, it is not desirable to use one formed by hot dip plating, and it is desirable to use one formed by electroplating. This is because, in hot dip plating, part of the copper is melted in the molten tin and the copper is included in the plating. In addition, in hot dip plating, a small amount of copper is intentionally included in the molten tin to suppress copper elution, and there are cases where a large amount of copper is included during plating. And, if copper is included during plating, electrostatic corrosion is likely to occur due to the potential difference between the copper and aluminum. Additionally, in hot dip plating, compared to electroplating, the plating thickness is likely to become uneven, and defects such as peeling in areas where the plating is thin are likely to occur. Therefore, during the manufacturing process, it is preferable to form the plating layer 414 by electroplating, which does not contain copper and tends to have a uniform thickness.

However, in this embodiment, a tin-plated annealed copper wire is used as the second wire 221. As the tin plating used for this second wire 221, it is preferable to use hot-dip plating, which has low manufacturing costs and is easy to mass produce. As mentioned above, when tin plating is hot-dip plating, since the plating layer contains a lot of copper, electrostatic corrosion is likely to occur when it comes into direct contact with aluminum or aluminum alloy. Therefore, even in the case of using a tin-plated second wire, it is necessary to form a corrosion suppressing member 4 to suppress corrosion between the first and second conductor portions 2a and 2b.

(Modified example of corrosion suppression member (4))

In the present embodiment, the first metal layer 411 made of aluminum or an aluminum alloy and the second metal layer 412 made of copper or a copper alloy are joined by the conductive adhesive layer 413, but the present invention is not limited to this and is shown in Figure 3 (b). ), a tape member 41a made of a clad material directly bonded to a first metal layer 411 made of aluminum or an aluminum alloy and a second metal layer 412 made of copper or a copper alloy. It may be used as a corrosion suppression member (4).

In addition, as shown in Figure 3 (c), as the electrostatic suppression member 4, plating layers 422 and 423 made of tin were formed on both sides of the metal layer 421 made of copper or copper alloy by electroplating. A tape member made of copper tape 42 may be used. In this case, a plating layer 422 (or 423) made of tin is inserted between the first conductor portion 2a made of aluminum or an aluminum alloy and the metal layer 421 made of copper or a copper alloy to suppress corrosion. In addition, the plating layer 423 (or 422) on the side opposite to the first conductor portion 2a (i.e., on the second conductor portion 2b side) may be omitted, but to prevent discoloration of the metal layer 421, etc. ) It is more preferable to form plating layers 422 and 423 on both sides. By using a tape member made of a tape member 41a or a copper tape 42 as shown in Figure 3(b) or Figure 3(c) as the corrosion suppression member 4, the first metal layer 411 The conductivity of the corrosion-inhibiting member 4 can be increased compared to the tape member 41 in which the conductive adhesive 413 is disposed between the second metal layer 412 and the second metal layer 412. For this reason, when the corrosion-inhibiting member 4 is disposed inside the conductor 2, the conductivity of the conductor 2 becomes difficult to decrease.

However, since the copper tape 42 is relatively hard, it is conceivable that wear may occur on the first conductor portion 2a at the edge portion (steps occurring in the wrap portion). In addition, when forming a terminal by caulking the end of the conductor 2, etc., it is conceivable that the plating layer 422 (or 423) on the first conductor portion 2a may peel off, making it easy for electrostatic corrosion to occur. You can. Therefore, as shown in Fig. 3(d), the electrostatic suppression member 4 further attaches an aluminum tape 43 made of aluminum or an aluminum alloy to the first conductor portion 2a side of the copper tape 42. It's okay to have it. At this time, the aluminum tape 43 and the copper tape 42 are arranged to directly contact each other without an adhesive member interposing them. That is, after wrapping the aluminum tape 43 in a spiral shape around the first conductor portion 2a, the electrostatic suppression member 4 may be formed by wrapping the copper tape 42 in a spiral shape on the aluminum tape 43. . The winding direction of the aluminum tape 43 may be the same as that of the copper tape 42.

Accordingly, the aluminum tape 43 serves as a buffer layer and can suppress wear of the first conductor portion 2a due to friction of the copper tape 42. In addition, even if the plating layers 422 and 423 are peeled off for any reason such as caulking of the terminal fixed to the end of the conductor 2, the metal layer 421 is prevented from coming into direct contact with the first conductor portion 2a, It is possible to suppress electrocution from occurring in the first conductor portion 2a. Additionally, for example, in addition to the tape member 41 in Figure 3(a) or the tape member 41a in Figure 3(b), an aluminum tape 43 may be formed on the first conductive portion 2a. It may be possible.

(Modified example of conductor (2))

In this embodiment, the first conductor portion 2a and the second conductor portion 2b are composed of a composite stranded wire obtained by stranding the natural wires 21 and 22. However, this is not limited to this, and the first conductor portion 2a and The second conductor portion 2b may be a stranded wire obtained by stranding a single metal wire. That is, the first conductor portion 2a may be formed by stranding a plurality of first wires 211 made of aluminum or an aluminum alloy, and the second conductor portion 2b may be composed of a plurality of second wires 211 made of copper or a copper alloy. (221) may be stranded in a spiral shape around the electrostatic suppression member (4).

Additionally, as shown in Figure 4(a), the first conductor portion 2a made of aluminum or aluminum alloy may be a compressed conductor. For example, a plurality of first wires 211 (seven in the example shown in the drawing) are twisted and compressed by passing them through a wire dice to form a first conductor portion 2a made of a compressed conductor. can be formed. The corrosion suppression member 4 is installed around the first conductor portion 2a made of a compressed conductor, and a plurality of second wires 221 made of copper or a copper alloy are stranded around the corrosion suppression member 4. By doing so, the second conductor portion 2b is formed. Additionally, the second conductor portion 2b may be compressed.

Additionally, as shown in Fig. 4(b), the first conductor portion 2a made of aluminum or aluminum alloy may be composed of a single wire having an outer peripheral surface made of a ring. In this case, the outer diameter of the first wire 211 constituting the first conductor portion 2a is preferably larger than the outer diameter of the plurality of second wires 221 constituting the second conductor portion 2b. Also, in this case, the second conductor portion 2b may be compressed.

Since the first conductor portion 2a has a structure as shown in Figure 4(a) or Figure 4(b), the gap between the first conductor portion 2a and the electrostatic suppression member 4 is smaller. Therefore, the contact area between the first conductor portion 2a or the second conductor portion 2b and the electrostatic corrosion suppression member 4 can be further increased. Therefore, the contact resistance between the first conductor portion 2a or the second conductor portion 2b and the electrostatic suppression member 4 is smaller than that of the conductor 2 shown in Fig. 1(a). As a result, the electrical characteristics of the conductor 2 can be further improved.

In addition, in this embodiment, the case where the first conductor portion 2a and the second conductor portion 2b are stranded conductors has been described, but the case is not limited to this, and the first conductor portion 2a and the second conductor portion ( 2b) may be a braided conductor. More specifically, as shown in Figure 5(a), the first conductor portion 2a is a strip-shaped material formed by braiding a plurality of first wires 211 made of aluminum or aluminum alloy. It may be a single braided conductor, and the second conductor portion 2b may be a second braided conductor formed by braiding a plurality of second wires 221 made of copper or a copper alloy.

In the example of Figure 5(a), the first conductor portion 2a is formed by pressing and flattening an annular braided conductor. For example, when manufacturing a coaxial wire, a braided conductor is installed around a core covered with an insulator around the conductor, but in this embodiment, a circular braided conductor is installed without passing through the core. is formed, and then the braided conductor is flattened using a press or the like to form the first conductor portion 2a. Around the first conductor portion 2a, a tape member 41 is wound in a spiral shape as an electrostatic suppression member 4.

The second conductor portion 2b is formed in a cylindrical shape to cover the entire circumference of the first conductor portion 2a. The second conductor portion 2b is formed by using the first conductor portion 2a as a core material and braiding the second wire in an annular manner to cover the periphery. In this way, the first conductor portion 2a made of aluminum or aluminum alloy and the second conductor portion 2b made of copper or copper alloy disposed around the first conductor portion 2b are each made of braided conductors, and between the braided conductors By having a structure in which the electrostatic suppression member 4 is arranged, it is easy to wire to fit the shape of the narrow wiring space between devices, and it is also possible to suppress the decrease in life and electrical characteristics due to electrostatic corrosion. It can be done with electric wire. In addition, when connecting a conductor made only of copper or a copper alloy to a device in the connection between the electric wire 1 and the device, there are certain provisions such as fixing the connector or terminal used to connect the end of the conductor 2. It can be fixed using any of the fixing methods. Therefore, the wire 1 and the device can be connected without using special connectors or terminals.

In the example of Figure 5(a), the case where the second conductor portion 2b is formed to cover the entire circumference of the first conductor portion 2a has been described, but the present invention is not limited to this and is shown in Figure 5(b). As shown, using a pair of second conductor parts 2b formed in a strip shape, in the thickness direction of the conductor 2, the first conductor part 2a is connected to a pair of second conductor parts 2b. The conductor 2 may be configured to be inserted into . In Figure 5(b), the electrostatic suppression member 4 is formed by wrapping the tape member 41 around the first conductor portion 2a, but the electrostatic suppression member 4 is not limited to this, but a pair of sheet-like electrostatic suppression members (4) may be arranged to be inserted between the first conductor portion 2a and the second conductor portion 2b, respectively, and the tape member 41 may be wound around each of the second conductor portions 2b to form the electrostatic suppression member 4. ) may be configured. In the example of Fig. 5(b), the same effect as the example of Fig. 5(a) is obtained.

(Cable (10))

Next, the cable 10 using the electric wire 1 will be described. Fig. 6 is a cross-sectional view showing a cross-section perpendicular to the longitudinal direction of the cable 10 according to this embodiment. As shown in Figure 6, the cable 10 is provided with a cable core 11 including a plurality of wires 1 and a sheath 12 provided to collectively cover the circumference of the cable core 11. there is.

The cable core 11 is stranded so that adjacent electric wires 1 in the cable circumferential direction are in contact with each other. Moreover, in this embodiment, the cable core 11 is comprised by stranding three electric wires 1 and a plurality of thread-like inserts 14. In order to make the outer shape of the cable 10 close to a circular shape, the insert 14 is formed in the gap around the wire 1 (the area surrounded by the three wires 1 including the center of the cable and adjacent wires ( 1) It is arranged to fill the space between each other and the area surrounded by the sheath 12. In this embodiment, jute is used as the insert 14. However, the insert 14 is not limited to jute, and may be made of other materials, such as staple fiber (staple fiber).

In addition, the cable 10 further includes a pressure wound tape 13 wound around the cable core 11 in a spiral shape. The pressure winding tape 13 serves to hold the cable core 11 so that it does not become untwisted. As the pressure wound tape 13, for example, non-woven tape, paper tape, etc. can be used. In this embodiment, a non-woven tape (staple fiber) made of staple fiber was used as the pressure wound tape 13.

The sheath 12 is installed to cover the periphery of the pressure wound tape 13. More specifically, the sheath 12 has a circular cross-section (cross-section perpendicular to the longitudinal direction of the cable) formed by tube extrusion, and is inserted between adjacent electric wires 1. It is installed in a non-functioning state. The sheath 12 is made of a irradiation-crosslinked resin composition that has been irradiation-crosslinked by, for example, electron beam irradiation. Specifically, the sheath 12 can be made of flame-retardant polyethylene (FRPE) that has been irradiated and crosslinked to a heat-resistant temperature of 125 degrees Celsius or higher, for example.

(Action and effect of embodiment)

As described above, in the electric wire 1 according to this embodiment, the conductor 2 is made of copper or a copper alloy and the first conductor portion 2a using the first wire 211 made of aluminum or aluminum alloy. It is provided with a second conductor portion (2b) using a second wire 221, and is installed to be inserted between the first conductor portion (2a) and the second conductor portion (2b) to connect the first conductor portion (2a) and the second conductor portion (221). It is provided with an electrochemical corrosion suppression member (4) that suppresses electrochemical corrosion from occurring between the two conductor portions (2b).

By providing the first conductor portion 2a in which the conductor 2 is made of aluminum or an aluminum alloy, the amount of expensive copper used can be reduced, and an electric wire 1 that is low-cost, lightweight, and easy to bend can be realized. As a result, it is possible to improve handling during wiring and to reduce transportation costs by organizing the wiring compactly during delivery. The present invention relates to a large-diameter wire (1) in which the amount of copper increases when the entire conductor (2) is made of copper or a copper alloy, especially a wire with a conductor cross-sectional area of 60 mm ² (60 SQ) or more and an outer diameter of 10 mm or more. This is especially effective in (1).

Additionally, in this embodiment, since the electrostatic corrosion suppressing member 4 is provided, the first conductor portion 2a made of aluminum or an aluminum alloy and the second conductor portion 2b made of copper or a copper alloy are in contact with each other. It is possible to suppress the occurrence of corrosion caused by Therefore, for example, even in a humid environment, a decrease in life or electrical characteristics due to corrosion can be suppressed.

(Summary of embodiment)

Next, the technical ideas understood from the embodiments described above will be described using the symbols in the embodiments. However, each symbol, etc. in the following description does not limit the components in the claims to members specifically shown in the embodiments.

[1] It is provided with a conductor (2) and an insulator (3) provided to cover the periphery of the conductor (2), wherein the conductor (2) is made of a first wire 211 made of aluminum or an aluminum alloy. It has a first conductor portion (2a) and a second conductor portion (2b) using a second wire 221 made of copper or a copper alloy, and the first conductor portion (2a) and the second conductor portion (2b) An electric wire (1) provided with an electrochemical corrosion suppression member (4) installed to be inserted between the first conductor portion (2a) and the second conductor portion (2b) to suppress electrochemical corrosion from occurring between the first conductor portion (2a) and the second conductor portion (2b).

[2] The first conductor portion 2a is formed by stranding a plurality of first wires 211 or a plurality of first natural wires 21 obtained by stranding the plurality of first wires 211, The electrostatic suppression member (4) is made of one or more tape members (41 to 43) wound in a spiral shape around the first conductor portion (2a) by overlapping, and the second conductor portion (2b) Is composed of a plurality of the second wires 221 or a second natural wire 22 obtained by twisting the plurality of second wires 221 in a spiral shape around the electrostatic suppression member 4. , wire (1) described in [1].

[3] The twisting direction of the first conductor portion (2a) and the winding direction of the electrostatic suppression member (4) are opposite, and the winding direction of the electrostatic suppression member (4) and the twisting direction of the second conductor portion (2b) are opposite to each other. The wire (2) described in [2], which has the same direction.

[4] The first conductor portion 2a is a first braided conductor formed by braiding a plurality of the first wires 211 together, and the second conductor portion 2b is a plurality of the second wires 221. The wire (1) described in [1] is a second braided conductor composed of braiding together.

[5] The electrostatic suppression member 4 includes a first metal layer 411 made of aluminum or aluminum alloy formed on one side, and a second metal layer 411 made of copper or copper alloy formed on the other side. A tape member (41, 41a) is provided that integrally includes a metal layer (412) and a plating layer (414) made of tin formed on the surface of the second metal layer, and the first metal layer (411) is connected to the first metal layer (411). The electric wire 1 described in [1], which is installed with the conductor portion 2a side and the second metal layer 412 on the second conductor portion 2b side.

[6] The electrostatic suppression member 4 is described in [1], which is provided with a copper tape 42 on which plating layers 422 and 423 made of tin are formed on both sides of a metal layer 421 made of copper or a copper alloy. Electric wire (1).

[7] The electrostatic corrosion suppressing member 4 is provided on the first conductor portion 2a side of the copper tape 42 and further includes an aluminum tape 43 made of aluminum or an aluminum alloy. [6 The wire (1) listed in ].

[8] The electric wire (1) described in [1], wherein the first conductor portion (2a) is made of a compressed conductor.

[9] A cable core 11 including a plurality of wires 1 described in any one of [1] to [8], and a sheath installed to collectively cover the circumference of the cable core 11 ( 12), the cable (10) provided.

(bookkeeping)

In the above, embodiments of the present invention have been described, but the embodiments described above do not limit the invention as per the claims. Additionally, it should be noted that not all combinations of features described in the embodiments are essential to the means for solving the problems of the invention. Additionally, the present invention can be implemented with appropriate modifications without departing from its spirit.

One… wire
2… conductor
2a… 1st conductor
2b… 2nd conductor
21… first natural line
211… 1st subline
22… second natural line
221… 2nd line
3… insulator
4… Electrostatic suppression member
41… absence of tape
411… first metal layer
412… Second metal layer
413… Conductive adhesive layer
414… plating layer
42… copper tape
421… metal layer
422, 423… plating layer
43… aluminum tape
10… cable
11… cable core
12… Sis

Claims (9)

conductor,
Insulator installed to cover the surrounding of the conductor
Equipped with
The conductor includes a first conductor portion using a first wire made of aluminum or an aluminum alloy, and a second conductor portion using a second wire made of copper or a copper alloy,
An electrochemical corrosion suppression member installed to be inserted between the first conductor portion and the second conductor portion to suppress electrochemical corrosion from occurring between the first conductor portion and the second conductor portion. Equipped with parts
wire. According to paragraph 1,
The first conductor portion is formed by stranding a plurality of first wires or a plurality of first natural wires obtained by stranding the plurality of first wires,
The electrostatic suppression member is composed of one or more tape members wound in a spiral shape around the first conductor portion by overlapping,
The second conductor portion is formed by twisting a plurality of second wires or a second natural wire (第2子撚線) obtained by stranding a plurality of second wires in a spiral shape around the electrostatic suppression member.
wire. According to paragraph 2,
The twisting direction of the first conductor portion and the winding direction of the electrostatic suppression member are opposite to each other,
The winding direction of the electrostatic suppression member and the twisting direction of the second conductor portion are in the same direction.
wire. According to paragraph 1,
The first conductor portion is a first braided conductor constructed by braiding a plurality of the first wires together,
The second conductor part is a second braided conductor formed by braiding a plurality of the second wires together.
wire. According to paragraph 1,
The corrosion suppression member includes a first metal layer made of aluminum or an aluminum alloy formed on one side, a second metal layer made of copper or a copper alloy formed on the other side, and a surface of the second metal layer. Provided with a tape member integrally equipped with a plating layer made of tin formed in,
The first metal layer is installed on the first conductor side, and the second metal layer is installed on the second conductor side.
wire. According to paragraph 1,
The electrostatic suppression member is equipped with a copper tape having a plating layer made of tin on both sides of a metal layer made of copper or a copper alloy.
wire. According to clause 6,
The electrostatic suppression member further includes an aluminum tape installed on the first conductor portion side of the copper tape and made of aluminum or aluminum alloy.
wire. According to paragraph 1,
The first conductor part is a wire made of a compressed conductor. A cable core including a plurality of electric wires according to any one of claims 1 to 8,
A sheath installed to collectively cover the perimeter of the cable core
Cable provided.