The present invention relates to a metal wire and an electric wire, and also relates to a metal wire produced by at least being subjected to a drawing in which a metallic material is extended in an axial direction, and an electric wire including one or more of the metal wires.
Conventionally, a conductive metal wire (element wire) have been used as a material for electric wire and the like, and a drawing is known as a manufacturing method of the metal wire, where a metallic material is extended to be thin through dies while being stretched in an axial direction (for example, refer to PTL 1). The patent literature 1 describes a manufacturing method in which a conductive material is subjected to a typical drawing and is extended, thereafter a bending where the conductive material is bent (secondary processing) is performed. The element wire obtained by such bending has an increased mechanical strength due to a change of crystal grains contained in a conductor into fine isometric grains.
[PTL 1]
JP-A-2008-218176
However, the metal wire obtained by the conventional manufacturing method as described in patent literature 1 has sufficient mechanical strength, but an improvement of ductibility thereof remains insufficient. Thus, a development of a metal wire having further improved ductibility is demanded.
The present invention aims to provide a metal wire and an electric wire of high mechanical strength and high ductibility having sufficiently improved mechanical strength as well as sufficiently improved ductibility.
In order to achieve the above objectives, the inventors of this application have come to discover a strong correlation between a hardness distribution of a metal wire in cross-section orthogonal to axis and ductibility thereof and the metal wire having high mechanical strength and high ductibility can be realized by imparting a proper hardness distribution thereto.
In accordance with a first aspect of the present invention, a metal wire comprises a hardness distribution in which hardness decreases toward a specific peripheral portion in a specific radial direction from a central portion in a cross-section orthogonal to an axis, wherein the metal wire is manufactured at least by subjecting a metallic material to an extension in an axial direction.
In the first aspect of the present invention, it is preferable that hardness of the specific peripheral portion decreases by equal to or more than 10% of hardness of the central portion at a circumferential surface side being beyond at least ½ of the radius from the center.
In the first aspect of the present invention, it is preferable that hardness of an opposing peripheral portion that opposes to the specific peripheral portion in a radial direction with reference to the central portion falls within plus and minus 10% of the hardness of the central portion, and the hardness of the opposing peripheral portion is higher than the hardness of the specific peripheral portion.
In the first aspect of the present invention, it is preferable that the hardness of the peripheral portion in the radial direction after the extension is higher than the hardness of the central portion, and the hardness of the specific peripheral portion becomes less than the hardness of the central portion by means of a secondary processing performed after the extension.
In the first aspect of the present invention, it is preferable the hardness of the central portion after the secondary processing is higher than the hardness of the central portion before the secondary processing, and the hardness of the specific peripheral portion after the secondary processing decreases by more than 10% with reference to the hardness of the specific peripheral portion before the secondary processing.
In accordance with a second aspect of the present invention, an electric wire comprises one or more of the metal wire of the first aspect of the present invention.
According to the first aspect of the present invention, by having a hardness distribution in which hardness decreases toward a specific peripheral portion from a central portion in a radial direction, a drastic improvement of ductibility can be attained. Here, the specific peripheral portion may be a restricted area in a circumferential direction (e.g., a sector having a center angle of approximately 30 to 90 degrees) in cross-section orthogonal to axis, may be a wider area (e.g., 30 to 180 degrees) than that, or may be an area of approximately entire circumference. As compared with such the metal wire of the present invention, a conventional metal wire to which a typical drawing is merely processed has a hardness distribution in which the hardness of the peripheral portion is higher than the hardness of the central portion. Hence, in the conventional metal wire, although an improvement of mechanical strength can be attained, a sufficient ductibility cannot be attained because the peripheral portion of high hardness thereof is prone to get brittleness. In contrast, the metal wire of the present invention, by having the hardness distribution in which the hardness of the peripheral portion is less than the hardness of the central portion, the softened peripheral portion becomes to show a good malleability as well as a high resistance to cracking, thereby attaining an improvement of ductibility.
According to the preferred aspect of the present invention, the hardness of the specific peripheral portion decreases by equal to or more than 10% with reference to the hardness of the central portion at the periphery side surpassing at least ½ of the radius from the center portion. That is, due to the hardness being equal to or less than 90% with reference to the hardness of the central portion, over half of the region in the specific radial direction can be the specific peripheral portion, and an improvement of ductibility of the metal wire can be more assuredly attained with the softened peripheral portion.
According to the preferred aspect of the present invention, by including the opposing peripheral portion of hardness falling within plus and minus 10% of the hardness of the central portion and the hardness being higher than the specific peripheral portion, and by having the hardness distribution showing non-uniform hardness in between the specific peripheral portion side and the opposing peripheral portion side across the central portion, that is, the hardness distribution being asymmetric with reference to the central axis in the cross-section orthogonal to axis, the mechanical strength and the ductibility of the metal wire can be improved with well-balance.
According to the preferred aspect of the present invention, by subjecting a metallic material having obtained hardness higher in the peripheral portion than in the central portion in the radial direction after the drawing to the secondary processing, an improvement of ductibility can be attained by softening particularly the specific peripheral portion among the peripheral portions that have been hardened by the drawing.
According to the preferred aspect of the present invention, by performing the secondary processing to increase the hardness of the central portion as well as to decrease the hardness of the specific peripheral portion by equal to or more than 10% from the hardness before the secondary processing, the mechanical strength as well as the ductibility of the metal wire can be improved.
According to the preferred aspect of the present invention, due to the electric wire being configured with the metal wire of improved ductibility as described above, a breaking of the metal wire can be prevented when manufacturing an electric wire. In particular, when configuring an electric wire with a twisted wire made by twisting a multiple metallic lines, due to the prevention of breaking while twisting, the production efficiency and the yield of the metal wire can be improved, so that the cost of manufacturing can be reduced.
A metal wire according to one embodiment of the present invention will be described in accordance with
The metal wire 1 is manufactured from a metallic material 2 by subjecting the metallic material 2 to drawing as primary processing and bending as next processing. First, in the drawing, by using a plurality of dies 3 (three for the present embodiment), the metallic material 2 is allowed to pass through the dies having gradually reducing inner diameter, and thereby being stretched in an axial direction (the direction shown by arrows X in the Figures). Each of the plurality of dies 3 includes a shaped hole 4 which allows metallic material 2 to pass therethrough; the shaped hole 4 is adapted to include a conical-shaped, large-diameter portion 4A that opens upstream in the extending direction and a cylindrical-shaped, small-diameter portion 4B that opens downstream in the extending direction.
Next, in the bending work, while stretching the metallic material 2 in an axial direction by using a bending-stretching mold 5 and a tension unit not illustrated and being located downstream thereof, the metallic material 2 is bent at comparatively small bending radius in an intermediate portion thereof, whereby the metallic material 2 is further stretched. The bending-stretching mold 5 is adapted to include a insertion hole 6 internally bent at an approximate right angle and a feed roller 7 arranged inside of the bending portion of the insertion hole 6. The insertion hole 6 is adapted to include a receiving portion 6A that opens upstream (the left side of
The feed roller 7 is adapted to be arranged at intersecting portion of the receiving portion 6A and the forwarding portion 6B and is formed to have a diameter commensurate with the bending radius (inner diameter) “r” of the metallic material 2 as shown in
The stress hysteresis within the cross-section of the metallic material 2 will be described specifically with reference to the conceptual diagram shown in
A measurement result of the tensile strength and the hardness distribution within the cross-section of the metal wire 1 processed as the above will be described with reference to
Next, the graph in
First, referring to the graph shown in
Next, in the graph of
The aforementioned preferred embodiments are described to aid in understanding the present invention and variations may be made by one skilled in the art without departing from the spirit and scope of the present invention.
For example, the metal wire 1 of the above embodiments may not be limited to being manufactured by the drawing (primary processing) with a plurarity of dies 3 and the bending (secondary processing) with the bending-stretching mold 5 and the feed roller 7. That is, the drawing may not be limited to the drawing in which the multiple dies 3 is utilized, a drawing in which the metallic material 2 is extended in an axial direction with drawing unit having consecutive insertion holes may also be available. Further, the secondary processing may not be limited to the bending and may be a processing in which the metallic material 2 after the drawing is lineally stretched, or may be a processing in which the metallic material 2 after the drawing is extended while twisting. Furthermore, the hardness of the specific peripheral portion may be decreased by using a proper thermal treatment (e.g., annealing). Further, the materials constituting the metal wire of the present invention may not be limited to copper, copper alloy, aluminum, and aluminum alloy as aforementioned. The materials having crystal structure except for amorphous metals may also be available. In particular, the metal wire having hyperfine metallographic structure with the grain size thereof being equal to or less than 1 μm may be preferable. Moreover, the materials for the metal wire may consist of either single element or a multiple elements, additional elements may be included therein, or the materials for the metal wire may have metallographic structure formed by a secondary phase precipitation or the like.
1 Metal wire
2 Metallic material
Number | Date | Country | Kind |
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2012-075821 | Mar 2012 | JP | national |
Number | Date | Country | |
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Parent | PCT/JP2013/058726 | Mar 2013 | US |
Child | 14495138 | US |