JPH09237533A - Dies structure of rotary swage working device for manufacturing high compression multilayer concentric strand wire - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a dies structure which can prevent generation of damage of a multilayer concentric strand wire, in the case of manufacturing a high compression multilayer concentric strand wire by reciprocation moving a peripheral surface struck of the multilayer concentric strand wire in its diametric direction and diametrically contracting the multilayer concentric strand wire. SOLUTION: Dies 1 comprising a pair of dies elements 2, 2 are arranged to appear in a peripheral surface 50a of a multilayer concentric strand wire 50A, this die 1, while rotated in a peripheral direction of the multilayer concentric strand wire 50A, is made adjacent to and separate from the peripheral surface 50a, the peripheral surface 50a is intermittently struck by a die surface 2b of each die element 2, the multilayer concentric strand wire 50A is diametrically contracted, a high compression multilayer concentric strand wire is formed. Here, partly of the die surface 2b is formed as a striking surface part 2c contactable with the peripheral surface 50a, a part of the die surface 2b adjacent to the striking surface part 2c in the upstream in a direction of rotation A of the die 1 is formed as a refuge surface part 2e separating in a diametric direction from the peripheral surface 50a when it is struck by the striking surface part 2c.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rotary swaging for striking the circumferential surface of a twisted wire formed by twisting a large number of wires to make the gaps between the wires dense and to highly compress the twisted wires. The present invention relates to the structure of a die for a swaging machine.

[0002]

2. Description of the Related Art Generally, a conductor used for an electric wire is composed of a twisted wire in which many wires are twisted in order to ensure flexibility, and the flexibility of this twisted wire is large. It is widely known that it will improve. And, especially in this kind of twisted wire, high compression is applied to the circumferential surface of the twisted wire to make the gap between the wires dense, and the cross-sectional area of each wire with respect to the area of the circle circumscribing the cross section of the twisted wire The highly-compressed multi-layered concentric stranded wire having a very high ratio of is used for the purpose of preventing the wires from coming off during pressure welding of the terminals.

The manufacturing process of the above-mentioned highly-compressed multi-layered concentric stranded wire will be described. First, as shown in a perspective view in FIG.
The strands 52 are covered with 12 strands 53 having a circular cross section to form a stranded wire, and the stranded wire is twisted at the same pitch in the same direction to form a multi-layered concentric stranded wire 50A. To do. After that, a high compression is applied to the peripheral surface 50a of the multi-layered concentric stranded wire 50A so that the space factor is about 1 as shown in the sectional view of FIG.
A high compression multilayer concentric stranded wire is formed by setting it as 00%.

As a conventional method for producing such a high compression multilayer concentric stranded wire 50, the present applicant has filed Japanese Patent Application No. 6-409.
There is a method and an apparatus for manufacturing a high compression multilayer concentric stranded wire proposed in No. 01.

In this method and apparatus for manufacturing a highly compressed multilayer concentric stranded wire, a plurality of bundled wires are twisted twice by a buncher to form a concentric stranded wire, and a rotary swaging device is provided on the peripheral surface of the concentric stranded wire. High compression is added by. A specific configuration will be described with reference to FIG.
Stranded wire 5 for the center sent from a supply device (not shown)
1 and a plurality of twisted wires 52, 5 which are twisted around the wire 1.
3 is first assembled in the twisting die 122 of the buncher 101. Stranded strands 51, 52, 5 assembled
3 is the first guide roll 123 and the twisting die 122.
In between, the first twist is first applied by the rotation of the fryer 104 to form the twisted wire 50B.

After that, the twisted wire 50B is guided from the first guide roll 123 to the guides 105a, 105b, ...
4 along with the second guide roll 124,
Then, it proceeds to the guide 100 of the fixed system 115 in the buncher 101 via the passage 114 'of the rotary shaft 102'.
Incidentally, reference numeral 104 ′ in FIG. 7 indicates a dummy flyer which is rotatable around the rotary shaft 102 and constitutes a drive system 116 together with the flyer 104. Then, the second twist is applied to the twisted wire 50B between the guide 100 and the second guide roll 124 of the drive system 116, whereby the multilayer concentric twisted wire 50A having a predetermined twist pitch is obtained.

Further, in the rotary swaging machine 90, the multilayer concentric stranded wire 50A passes between the second guide roll 124 and the winding device 126, as will be described later, inside the fixed system 115. Receives high-speed and fine compression processing from its peripheral surface 50a,
At the stage of being wound up by the winding device 126 after passing through the rotary swaging device 90, the multi-layer concentric stranded wire 5
0A is the highly compressed multi-layered concentric stranded wire 50 that is highly compressed to a space factor of approximately 100%.

Next, an example of a concrete configuration of the conventional rotary swaging apparatus 90 disclosed in the above-mentioned Japanese Patent Application No. 6-40901 will be further described with reference to FIGS. 8, 9 and 10. Add. A rotary swaging device 90 shown in a cross-sectional view in FIG. 8 includes a casing 19 in which the multi-layered concentric stranded wire 50A extending from the second guide roll 124 to the winding device 126 is inserted through the through hole 18, and the through hole 18 It has a hollow shaft 20 inserted into a casing 19 from a housing 19 opposite to the housing 19, and a striking device 30 arranged in the casing 19 between the distal end of the hollow shaft 20 and the through hole 18.

The hollow shaft 20 is rotatably supported by a casing 19 by a bearing 21 of a bearing, and is rotatably driven by a driving device (not shown).

The striking device 30 is fixed to the cylindrical inside ring 22 fixed to the inner peripheral wall of the casing 19 and the distal end of the hollow shaft 20, as shown in the sectional view of the contracted state seen from the rear side in FIG. And a spindle 27 which is disposed at a distance in the radial direction of the hollow shaft 20 and is driven to rotate together with the hollow shaft 20 by a drive device (not shown), and is disposed between the spindle 27 and the inside ring 22. A plurality of cylindrical hammer rollers 23 and a pair of expansion / contraction members 24, 24 supported by a spindle 27 so as to be movable in the radial direction of the hollow shaft 20.

The hammer rollers 23 are arranged at equal intervals in the circumferential direction of the inside ring 22, and are supported by an inner casing (not shown) so as to be rotatable without changing the mutual intervals. There is. Then, as shown in FIG. 8, the hammer roller 2
The tapered surface 20 at the tip of the hollow shaft 20
A tapered surface 23a is formed to avoid contact with a. Therefore, the spindle 27 is inscribed in the peripheral surface of each hammer roller 23 and the inside ring 22 is inscribed in the peripheral surface. The hammer roller 23 is rotated in the same direction as the hollow shaft 20 together with the inner casing (not shown) by the rotational force received through the spindle 27 when the hollow shaft 20 is rotationally driven by the driving device. The hammer roller 23 is configured to revolve in the direction opposite to the hollow shaft 20 by the revolution.

As shown in FIG. 9, the spindle 27 has a linear expansion / contraction passage 2 passing through the center of the hollow shaft 20.
7a and the left and right support walls 2 that define the expansion / contraction passage 27a.
7b and 27b, and the outer surface 27c of each support wall 27b
Is formed on an arc surface located on a circle having an outer diameter obtained by subtracting two diameters of the hammer roller 23 from the inner diameter of the inside ring 22, and the inner surfaces 27d of the respective support walls 27b extend parallel to each other. Is configured to exist.

The pair of expansion / contraction members 24, 24 are arranged in the expansion / contraction passage 27a, and are spaced apart from each other along the inner surface 27d of each of the support walls 27b with the center of the hollow shaft 20 interposed therebetween and approach each other in the direction of arrow B in FIG. It is supported by the spindle 27 so that it can be moved to. Each expansion / contraction member 24 has an expansion / contraction passage 27a on the center side of the hollow shaft 20.
It comprises a die 25 arranged at a position and a backer 26 which is arranged adjacent to the die 25 at a position of the expansion / contraction passage 27a outside the die 25 in the radial direction of the hollow shaft 20.

The inner surface 25a of the die 25 of each of the expansion / contraction members 24 facing the die 25 of the other expansion / contraction member 24 is
A concave striking surface 25b is formed by dividing a circle having an inner diameter corresponding to the outer diameter of the high compression multilayer concentric stranded wire 50 into halves. In addition, the backers 26 of the expansion / contraction members 24 have outer surfaces 26a located at both ends of the expansion / contraction path 27a.
7a includes a large diameter portion 26b substantially in the center in the width direction and small diameter portions 26c, 26c on both sides thereof.

In the pair of expansion / contraction members 24, 24, the spindle 27 is rotationally driven by the hollow shaft 20 so that the large diameter portion 26b of the backer 26 abuts the peripheral surface of the hammer roller 23 as shown in FIG. And both dice 2
When the inner surfaces 25a of 5, 25 approach each other with a slight gap, the two striking surfaces 25b, 25b come close to each other, and the striking surfaces 25b, 25b correspond to the outer diameter of the high compression multilayer concentric stranded wire 50. Is formed so that a circle having an inner diameter of In addition, the pair of expansion / contraction members 24, 24
As shown in the cross-sectional view of the expanded state when viewed from the rear side in FIG. 10, when the large diameter portion 26b of the backer 26 is located between the two hammer rollers 23, 23, the spindle 27 is driven to rotate. The centrifugal force of
Each backer 26 on the peripheral surface of one hammer roller 23, 23
The small diameter portions 26c, 26c of the two dies contact each other, and the inner surfaces 25a of the dies 25, 25 are separated from each other by the difference in diameter between the large diameter portion 26b and the small diameter portion 26c.

In the conventional rotary swaging machine 90 thus constructed, the multi-layered concentric stranded wire 50A extending from the second guide roll 124 to the winding device 126 is passed through the through hole 18 to the casing as described above. After being inserted into 19, the striking surface 2 of both dies 25, 25 of the striking device 30
It is pulled out to the outside of the casing 19 through the space between 5b and 25b and the inside of the hollow shaft 20. Then, the rotary swage processing device 90 includes the hollow shaft 20.
In the striking device 30, the backer 2
The state in which the large diameter portion 26b of 6 abuts on the peripheral surface of the hammer roller 23 and the state in which it is located between the two hammer rollers 23 are repeated, whereby both dies 25, 25 are repeatedly approached and separated, The striking surface 25b of each die 25 strikes the peripheral surface of the multi-layered concentric twisted wire 50A, thereby closing the gap between the twisted strands 51, 52, 53 to reduce the outer diameter of the multi-layered concentric twisted wire 50A. It is configured to form a compressed multilayer concentric stranded wire 50.

Since the striking surface 25b of each die 25 of the striking device 30 moves toward and away from the peripheral surface 50a of the multi-layered concentric stranded wire 50A by linear reciprocal movement in the radial direction of the multi-layered concentric stranded wire 50A, The position of the peripheral surface 50a of the multi-layered concentric twisted wire 50A that is hit by the hitting surface 25b changes little by little in the circumferential direction, and the multi-layered concentric twisted wire 50A moves toward the winding device 126. Surface 25b
The position of the peripheral surface 50a of the multi-layered concentric stranded wire 50A, which is hit by, changes little by little even in the extending direction of the multi-layered concentric stranded wire 50A.

In such a conventional rotary swaging machine 90, by increasing the reciprocating speed of the die 25 and the moving speed of the multi-layered concentric twisted wire 50A, the multi-layered concentric twisted wire 5 can be obtained.
It is possible to improve the compression processing speed in which 0A is highly compressed. However, when the moving speed of the die 25 and the multi-layered concentric twisted wire 50A is increased, the striking surface 2 of the die 25 against the peripheral surface 50a of the multi-layered concentric twisted wire 50A is correspondingly increased.
When the 5b starts to contact or separate from each other, the circumferential dimension of the striking surface 25b that continuously contacts a certain circumferential surface 50a in the circumferential direction of the multilayer concentric stranded wire 50A increases.

[0019]

By the way, the rotary swage processing device is originally a device for processing a work material having a high rigidity such as a rod or a tube, and it contacts the work material while rotating the die. Even if it is done, the work material is not deformed, and therefore, no structural measures such as a cushioning mechanism have been made for the contacting manner of the die with the work material. Therefore, in the conventional rotary swaging machine 90, the moving speed of the die 25 and the multi-layered concentric twisted wire 50A is increased, so that the peripheral surface 5 of the multi-layered concentric twisted wire 50A is increased.
When the circumferential dimension of the striking surface 25b that continuously contacts the 0a position becomes large, the wire 53 forming the circumferential surface 50a and the striking surface 2 of the die 25 slidingly contacting the wire 53 are formed.
The degree of friction generated between the wire 5b and 5b is increased, and the twisting force applied to the wire 53 is increased.

However, the strands 53, and thus the multi-layered concentric stranded wire 50A, are not so rigid, unlike a work piece which is originally a work object of a rotary swaging device and has a high rigidity such as a rod or a tube. Rather, since it is a work piece that is required to be flexible, when the twisting force is increased as described above, the strands 53 are broken, or the strands 53 have burr-like burrs. There is a problem that fatal damage may occur to the electric wire conductor, which may impair the function of the high compression multilayer concentric stranded wire 50.

[0021] For example, in Japanese Patent Publication No. 56-20940, by swinging at a rotation angle of about 70 ° while chucking a work material with a drawer and an inserter,
Although the swaging method for preventing the twist of the work piece is disclosed, in the case of manufacturing the multi-layered concentric stranded wire 50A using the buncher 101 of FIG. 7, a complicated movement device such as a drawing device or an insertion device is used. Fixed system 11 of buncher 101
Since the buncher 101 must be housed in the buncher 101, resulting in an increase in the size of the buncher 101 and a limitation on the rotational speed of the fryer 104, it is not practical and practically unusable.

When the material to be processed is a long continuous body such as the multi-layered concentric twisted wire 50A, the above-mentioned problem of twisting causes the multi-layered concentric twisted wire 50A itself to swing. No, and therefore the rotary swaging device 90 would have to be rocked instead, which is practically unusable, similar to housing the drawer or inserter described above in the fixed system 115.

Even if all the problems in accommodating the above-mentioned pull-out device and insertion device in the buncher 101 can be solved, the twisting force applied from the die 25 of the rotary swaging device 90 to the multi-layer concentric twisted wire 50A is eliminated. Therefore, even if the technology of Japanese Patent Publication No. Sho 56-20940 is used, the reciprocating movement speed of the die 25 and the moving speed of the multi-layered concentric twisted wire 50A are increased, and the multi-layered concentric twisted wire 50A is highly compressed. It was not possible to increase the swaging processing speed by applying the heat treatment.

The present invention has been made in view of the above circumstances.
An object of the present invention is to intermittently strike the peripheral surface of a multi-layered concentric stranded wire with a die that reciprocates in the radial direction of the multi-layered concentric stranded wire while rotating in the circumferential direction of the multi-layered concentric stranded wire, To prevent damage to the multi-layered concentric stranded wire due to contact of the dies when the wire is reduced in diameter to form a highly compressed multi-layered concentric stranded wire, the moving speed of the die in the circumferential and radial directions (EN) It is possible to provide a die structure of a rotary swage processing apparatus for producing a highly compressed multi-layered concentric stranded wire which can be prevented irrespective of.

[0025]

In order to achieve the above object, the present invention according to claim 1 arranges a die so as to face a peripheral surface of a multi-layered concentric twisted wire, and the die is placed around the multi-layered concentric twisted wire. While rotating in the direction, they are moved toward and away from the peripheral surface, and the peripheral surface is intermittently struck by the die surface portion facing the peripheral surface by the die to reduce the diameter of the multilayer concentric stranded wire, and a high compression multilayer concentric stranded wire In the rotary swaging device to be, a part of the die surface portion is formed on the striking surface capable of contacting the peripheral surface, and the die surface portion adjacent to the striking surface on the upstream side in the rotating direction of the die, It is characterized in that it is formed on a retracting surface which is separated from the peripheral surface in the radial direction when the peripheral surface is hit by the hitting surface.

According to a second aspect of the present invention, the die comprises a plurality of die elements divided in the circumferential direction of the multilayer concentric stranded wire, and the die element surface facing the circumferential surface by each of the die elements. The striking surface is formed on each part, and the retreat surface is formed on each of the die element surface parts on the downstream side in the rotation direction of the die with respect to the striking surface, and to the peripheral surface of each of the die elements. In the approaching state, the striking surface of each die element is adjacent to the retreat surface of the die element located on the upstream side of the die element in the rotation direction of the die.

Further, in the invention according to claim 3, in the die element, when the die element surface portion between the striking surface and the retreat surface is close to the peripheral surface of each die element, The distance from the center of the multilayer concentric twisted wire gradually increases from the upstream side to the downstream side in the rotating direction A of the die, and the distance change surface gradually moves away from the peripheral surface.

Further, in the present invention as set forth in claim 4, when the die elements are close to the peripheral surface, the striking surface of each die element is upstream of the die element in the rotational direction of the die. Side of the die element is configured to be adjacent to the retreat surface of the die element, the hitting surface of each of the die elements, at the hitting surface portion near the die element adjacent to the upstream side, the rotation of the die. The flanks are formed so as to separate from the peripheral surface in the direction from the downstream side to the upstream side.

According to the first aspect of the present invention, while the striking surface is striking the peripheral surface of the multi-layered concentric stranded wire, the retreat surface on the upstream side in the rotation direction of the die adjacent to the striking surface is a multi-layer. Since the circumferential surface of the concentric stranded wire is separated from the radial direction of the multilayer concentric stranded wire, when the die rotates while the striking surface is in contact with the peripheral surface of the multilayer concentric stranded wire, at the next time, the striking surface The withdrawal surface faces the circumferential surface portion of the multi-layered concentric stranded wire, which was in contact with, in the radial direction of the multi-layered concentric stranded wire. Therefore,
With the rotation of the die, on the same peripheral surface location of the multilayer concentric stranded wire,
The die surface portion facing the peripheral surface of the multi-layered concentric stranded wire is not continuously contacted, and even if the moving speed of the die in the circumferential direction and the radial direction of the multi-layered concentric stranded wire is increased, the die surface It is possible to prevent the peripheral surface of the multi-layered concentric stranded wire from being damaged by breakage, burrs, etc. due to friction caused by sliding contact of parts, and it is possible to improve the speed of rotary swaging using a die. Become.

According to the second aspect of the present invention, in the state in which the plurality of die elements divided in the circumferential direction of the multi-layered concentric stranded wire are close to the circumferential surface of the multi-layered concentric stranded wire, The striking surface formed on each of the die element surface portions facing the peripheral surface is adjacent to the retreat surface on the downstream side of the striking surface in the die element surface portion of the die element located on the upstream side in the rotating direction of the die. It will be. Therefore, when a plurality of die elements are simultaneously approached and separated from the peripheral surface of the multi-layered concentric stranded wire, and a plurality of peripheral surface portions spaced in the circumferential direction of the multi-layered concentric stranded wire are hit with the striking surface of each die element. Even so,
It is possible to prevent each peripheral surface portion of the multilayer concentric stranded wire from being damaged by breakage, burr, or the like due to friction caused by sliding contact of the striking surface of each die element.

Further, according to the third aspect of the present invention,
The stepped portion of the boundary between the striking surface of each die element and the distance change surface on the downstream side in the dicing direction on this striking surface,
Since it is an obtuse angle rather than a substantially right angle, the peripheral surface of the multilayer concentric stranded wire facing the retracting surface of each die element is upstream of the retracting surface of the die element in the rotating direction of the die as the die rotates. When the side striking surface is in sliding contact, the obtuse-angled step portion between the striking surface and the interval changing surface is in slidable contact before this striking surface. Therefore, it is possible to reliably prevent the peripheral surface of the multi-layer concentric stranded wire from being damaged, as compared with the case where the retracting surface and the striking surface are directly adjacent to each other to form a substantially right-angled step.

According to the present invention, the chamfered rounded flank face is located at the striking face of each die element on the striking face portion on the upstream side in the direction of rotation of the die. Since the flank face is adjacent to the retreat face of the die element located on the upstream side of each die element, the die rotation is made at each peripheral surface portion of the multilayer concentric twisted wire where the striking surface of each die element contacts. Along with the striking surface, the flank surface adjacent to this striking surface is in sliding contact with the striking surface of the die element located adjacent to the upstream side of the die element. It is possible to reliably prevent the peripheral surface of the multi-layered concentric stranded wire from being damaged, as compared with the case where the step between the die element and the retracted surface is formed at a substantially right angle.

[0033]

BEST MODE FOR CARRYING OUT THE INVENTION A die structure of a rotary swage processing apparatus for producing a high compression multilayer concentric stranded wire according to an embodiment of the present invention will be described below with reference to the drawings.

First, the die structure according to the first embodiment of the present invention will be described with reference to FIGS. FIG. 1 is an enlarged plan view showing a die structure according to a first embodiment of the present invention which can be used in the rotary swage device shown in FIG.
The die of the present embodiment shown by medium reference numeral 1 is composed of two die elements 2 and 2 corresponding to and used in place of the conventional die 25.

Each die element 2 has an expansion / contraction passage 27a of a spindle 27, like the conventional die 25 shown in FIG.
Are arranged in the expansion / contraction passages 27a on the inner side in the radial direction of the hollow shaft 20 with respect to the pair of backers 26, and in this state, the inner surface 2a of each die element 2a facing the other die element 2 is shown in FIG. Thus, the concave die surface 2b (corresponding to the die surface portion facing the peripheral surface of the multilayer concentric stranded wire) is formed by dividing a circle having an inner diameter larger than the outer diameter of the high compression multilayer concentric stranded wire 50 into halves. . The arrow A in FIG. 1 indicates the rotation direction of the die 1 that rotates together with the hollow shaft 20 and the spindle 27, and B indicates the die elements along the inner surface 27d of each support wall 27b of the expansion / contraction passage 27a as the die 1 rotates. 2A and 2B respectively show moving directions when the two approach and move away from each other.

In each of the die surfaces 2b, the center of curvature C of the die surface 2b is slightly displaced from the middle portion D in the width direction of the inner surface 2a, whereby the striking surface portion 2c on the upstream side in the rotation direction A of the die 1 ( The inner surface 2 extends from the striking surface) to the retreat surface portion 2e (corresponding to the retreat surface) on the downstream side via the midway distance change surface portion 2d (corresponding to the distance change surface).
It is formed so as to gradually separate from the widthwise intermediate portion D of a.

As shown in FIG. 9, when the large diameter portion 26b of the backer 26 is in contact with the peripheral surface of the hammer roller 23, as shown in FIG. When the inner surfaces 2a of the two 2, 2 come close to each other with a slight gap, the two die surfaces 2b,
2b slightly shifts along the inner surface 2a and approaches, and the striking surface portion 2c of each die surface 2b comes into contact with the peripheral surface 50a of the multi-layered concentric stranded wire 50A inserted inside the die surfaces 2b, 2b. Is configured. As described above, since the interval changing surface portion 2d is formed so as to be gradually separated from the widthwise intermediate portion D of the inner surface 2a, the large diameter portion 26b of the backer 26 contacts the peripheral surface of the hammer roller 23. In contact with each other, the interval changing surface portion 2
The distance d from the upstream side to the downstream side in the rotation direction A of the die 1 gradually increases the distance from the center P of the multi-layered concentric stranded wire 50A. Therefore, in the above-described state, the distance changing surface portion 2d and the retracting surface portion 2e are , Away from the peripheral surface 50a.

In addition, the pair of die elements 2 and 2 are as shown in FIG.
As shown in, in the state where the large diameter portion 26b of the backer 26 is located between the two hammer rollers 23, 23,
The small diameter portions 26c and 26c of the respective backers 26 are brought into contact with the peripheral surfaces of the two hammer rollers 23 and 23, respectively, by the centrifugal force acting by the rotational driving of the spindle 27, and as shown in FIG. Inner surface 2 of elements 2 and 2
a is separated from each other by the difference in diameter between the large diameter portion 26b and the small diameter portion 26c, and the two die surfaces 2b and 2b are separated from each other by the peripheral surface 50.
It is configured to be separated from a.

Further, the die surface 2 of each die element 2 is
As shown in FIG. 1, b is provided with a flank 2f chamfering the boundary between the striking surface 2c and the inner surface 2a and a flank 2g chamfering the boundary between the retracting surface 2e and the inner surface 2a. There is. Of these, the flank 2f is formed in a rounded shape away from the center of curvature C of the die surface 2b from the downstream side to the upstream side in the rotation direction A of the die 1, and the flank 2g is It is formed in a rounded shape away from the center of curvature C of the die surface 2b from the upstream side to the downstream side in the rotational direction A of 1.

Next, the operation of the die elements 2 and 2 when the die elements 2 and 2 of the present embodiment having the above-mentioned structure are used in the rotary swage device shown in FIG. 8 in place of the conventional die 25. (Operation) will be described.

First, when the inner surfaces 2a, 2a of the two die elements 2, 2 come into contact with each other at the rotational position of the spindle 27 shown in FIG. 9, as shown in FIG. 1, the striking surface portion 2c of each die element 2 is multi-layered. The peripheral surface 50a of the concentric stranded wire 50A contacts the peripheral surface portion X whose phase is shifted by 180 ° in the peripheral direction and strikes the peripheral surface portion X, whereby the multilayered concentric stranded wire 50A is highly compressed at the impacted peripheral surface portion X. Is added. In this state, the spacing changing surface portion 2d and the retracting surface portion 2e of each die element 2 are separated from the peripheral surface 50a of the multi-layered concentric stranded wire 50A, and thus the peripheral surface hit by the striking surface portion 2c of each die element 2. The die element 2 does not contact the peripheral surface portion Y other than the portion X. Then, from the position shown in FIG.
When the spindle 27 rotates to the position shown in,
The die elements 2 are separated from each other by the centrifugal force together with the backers 26, and the multi-layered concentric stranded wire 50A is attached to the winding device 1.
It is wound on 26 for a predetermined length.

Then, from the position shown in FIG.
With the rotation of the spindle 27 to the position shown in FIG.
The peripheral surface portion X in FIG.
When viewed only in the circumferential direction of the multi-layered concentric stranded wire 50A, the flanks 2f of the die elements 2 adjacent to the die elements 2 on the upstream side in the rotation direction A pass through the flanks 2f of the die elements 2. To the position facing the retracting surface portion 2e of the adjacent die element 2, as shown in FIG. In this case, the flank 2f is
From the downstream side to the upstream side in the rotating direction A of the die 1, the spindle 2 is formed in a round shape so as to be away from the center of curvature C of the die surface 2b.
With the rotation of 7, the die surface 2b is gradually separated from the peripheral surface portion X.

Further, from the position shown in FIG.
The peripheral surface portion of the peripheral surface portion Y in FIG. 1 where the retracting surface portion 2e of each die element 2 was in contact at the rotational position of the spindle 27 shown in FIG. 9 with the rotation of the spindle 27 to the position shown in FIG. Z is a space changing surface portion 2d of each die element 2.
After that, as shown in FIG. 2, it relatively moves to a position facing the striking face portion 2c. In this case, the die surface 2b of each of the die elements 2 is formed so as to gradually separate from the widthwise intermediate portion D of the inner surface 2a as it goes from the striking surface portion 2c to the retracting surface portion 2e via the interval changing surface portion 2d. Then, the die surface 2b is formed so as to gradually approach the widthwise intermediate portion D of the inner surface 2a as it goes from the retracting surface portion 2e to the striking surface portion 2c via the interval changing surface portion 2d, so that further rotation of the spindle 27 is possible. Accordingly, the die surface 2b gradually approaches the peripheral surface portion Y on the downstream side in the rotation direction A with respect to the peripheral surface portion Z, and finally the striking surface portion 2c comes into contact with this peripheral surface portion Y portion.

As described above, according to this embodiment, the die 1
Forming a pair of die elements 2 and 2 that move in the direction of moving closer to and away from each other in synchronism with each other, for forming a high compression on the peripheral surface 50a of the multi-layered concentric stranded wire 50A. The surface 2b is a high compression multilayer concentric stranded wire 50.
As a concave shape that divides a circle with an inner diameter larger than the outer diameter of
The center of curvature C of the die surface 2b is arranged so as to be slightly offset from the middle portion D of the inner surface 2a in the width direction.
b, in the state where the hitting surface portion 2c on the upstream side in the rotating direction A of the die 1 hits the peripheral surface 50a of the multi-layered concentric stranded wire 50A, the interval changing surface portion 2d in the middle is the rotating direction A
The distance from the center P of the multi-layered concentric stranded wire 50A gradually increases from the upstream side to the downstream side, and as a result, the inner surface increases from the striking face portion 2c to the retreat face portion 2e on the downstream side via the gap changing face portion 2d. The distance 2a from the middle portion D in the width direction gradually increases.

Then, the striking surface portion 2c of each die element 2
And the retreat surface portion 2e of the other die element 2 is adjacent on the upstream side in the rotation direction A of the die 1, and the die surface 2 at the boundary between the striking surface portion 2c of each die element 2 and the inner surface 2a.
At the portion b, a flank 2f is formed which is separated from the center of curvature C of the die surface 2b from the downstream side to the upstream side in the rotation direction A of the die 1, and the die surface at the boundary between the retracting surface portion 2e and the inner surface 2a is formed. In the portion 2b, a flank 2g is formed so as to separate from the center of curvature C from the upstream side to the downstream side in the rotation direction A.

Therefore, the peripheral surface 50 of the multi-layered concentric stranded wire 50A is
The contact and separation between a and the die surface 2b of each die element 2 are determined by the drive device (not shown) together with the hollow shaft 20 and the spindle 2
7 is gradually performed as the peripheral surface 50a rotates while the spindle 27 rotates, as compared with the conventional structure in which the entire peripheral surface 50a is the striking surface of the peripheral surface 50a. The degree of sliding contact with the die surface 2b of the element 2 is reduced. Therefore, the degree of friction generated between the wire 53 forming the peripheral surface 50a of the multilayer concentric stranded wire 50A and the die surface 2b of the die element 2 is reduced so that a large twisting force is not applied to the wire 53. In addition, the multi-layered concentric stranded wire 50A, which is a work piece that is required to have flexibility, that is, the strand 53 that constitutes the peripheral surface 50a is broken, or a burr like a burr is generated on the strand 53. It is possible to reliably prevent fatal damage to the conductor for electric wires that would impair the function of the high compression multilayer concentric stranded wire 50.

Moreover, the peripheral surface 50a of the multi-layered concentric stranded wire 50A
Since it is possible to reliably prevent damage to the strands 53 constituting the above, it is possible to process the multi-layered concentric stranded wire 50A by the rotary swaging apparatus 90 at high speed and with a large reduction, thereby improving the productivity of the high-compression multi-layered concentric stranded wire 50. be able to.

Next, a die structure according to the second embodiment of the present invention will be described with reference to FIG. The die of the second embodiment indicated by reference numeral 1A in FIG. 3 is the die 1 of the first embodiment.
Similarly to the above, the hollow shaft 2 is driven by a driving device (not shown).
It consists of three die elements 2A, 2A, 2A which rotate in the rotation direction A as the spindle 27 rotates together with zero.

In the die 1A of the second embodiment, the inner surface 2Aa of each of the die elements 2A is formed into a chevron shape having two surfaces whose tips intersect at 120 °, and the inner surface 2A.
The center of curvature F is placed at a position slightly deviated from the virtual vertex position E of the inner surface 2Aa, and the die 1 of the first embodiment is
Concave die surface 2 formed of an arc having the same diameter as the die surface 2b of
Ab (corresponding to the die surface facing the peripheral surface of the multi-layer concentric stranded wire)
Is different from the die 1 of the first embodiment. In addition, the die 1A of the second embodiment has a flank 2f, a striking face 2c, a striking face 2c, which are formed on the die face 2Ab of each die element 2A in this order from the upstream side in the rotation direction A of the die 1A.
Similar to the die 1 according to the first embodiment, the gap changing surface portion 2d, the retracting surface portion 2e, and the flank surface 2g are configured. The arrows G1 to G3 in FIG.
The moving directions when the respective die elements 2A move toward and away from each other as the die 1A rotates are shown.

According to the die 1A of the second embodiment having such a structure, as the spindle 27 rotates together with the hollow shaft 20 by the driving device (not shown),
As the three die elements 2A, 2A, 2A reciprocate radially in synchronization with each other in the moving directions G1 to G3 whose phases are shifted by 120 °, respectively, as shown in FIG. The state in which the inner surface 2Aa contacts the inner surfaces 2Aa of the two adjacent die elements 2A and the state in which the inner surface 2Aa of each die element 2A is separated from the inner surface 2Aa of the two adjacent die elements 2A are repeated although not shown.

While the inner surface 2Aa of each die element 2A is in contact with the inner surface 2Aa of both adjacent die elements 2A, the striking surface portion 2c of each die element 2A shifts the phase by 120 ° of the multi-layer concentric twisted wire 50A. When the peripheral surface 50a is hit by hitting the peripheral surface 50a, and the inner surface 2Aa of each die element 2A is separated from the inner surface 2Aa of each of the adjacent die elements 2A, the impact surface portion of each die element 2A 2c is separated from the peripheral surface 50a of the multilayer concentric stranded wire 50A. With the die 1A of the second embodiment configured as above, the same effect as that of the die 1 of the first embodiment can be obtained.

Next, a die structure according to the third embodiment of the present invention will be described with reference to FIG. The die of the third embodiment indicated by reference numeral 1B in FIG. 4 has four die elements 2B,
It consists of 2B, 2B and 2B.

In the die 1B of the third embodiment, the inner surface 2Ba of each of the die elements 2B is formed in a chevron shape having two surfaces whose tips intersect at 90 °, and the inner surface 2Ba.
Then, the center of curvature J is placed at a position slightly deviated from the virtual vertex H of the inner surface 2Ba, and the concave die surface 2B formed of an arc having the same diameter as the die surface 2b of the die 1 of the first embodiment.
b (corresponding to the portion of the die surface facing the peripheral surface of the multi-layer concentric stranded wire) is different from the die 1 of the first embodiment. Further, in the die 1B of the third embodiment, the die surface 2Bb of each die element 2B is set to the rotation direction A of the die 1B.
In the same manner as the die 1 of the first embodiment, the flank 2f, the striking face 2c, the interval changing face 2d, the retracting face 2e, and the flank 2g are arranged in this order from the upstream side. It should be noted that arrows K1 to K4 in FIG. 4 respectively indicate moving directions when the respective die elements 2B move away from each other and approach each other as the die 1B rotates.

According to the die 1B of the third embodiment having such a configuration, as the spindle 27 rotates together with the hollow shaft 20 by the driving device (not shown),
As shown in FIG. 4, the four die elements 2B, 2B, 2B, and 2B reciprocate radially in synchronization with each other in movement directions K1 to K4 that are 90 ° out of phase with each other. The inner surface 2Ba of 2D is in contact with the inner surfaces 2Ba of both adjacent die elements 2B, and although not shown, the inner surface 2 of each die element 2B is not shown.
The state in which Ba is separated from the inner surfaces 2Ba of the adjacent die elements 2B is repeated.

Then, in a state where the inner surface 2Ba of each die element 2B is in contact with the inner surface 2Ba of both adjacent die elements 2B, the striking surface portion 2c of each die element 2B shifts the phase by 90 ° of the multilayer concentric twisted wire 50A. Circumferential surface 5
When the peripheral surface 50a is hit by contacting each of the 0a points, and the inner surface 2Ba of each die element 2B is separated from the inner surfaces 2Ba of the adjacent die elements 2B, the hitting surface portions 2c of the die elements 2B are multilayered. Concentric stranded wire 5
It is separated from the peripheral surface 50a of 0A. Also with the die 1B of the third embodiment configured as described above, the same effect as that of the die 1 of the first embodiment can be obtained.

When the dies 1A and 1B of the second and third embodiments described above are used in the rotary swage device shown in FIG. 8 instead of the conventional die 25, the dies 1A and 1B are constructed. The number of die elements 2A and 2B to be moved and the moving directions G1 to G3 and K1 to K of the die elements 2A and 2B.
4, the shape of the expansion / contraction passage 27a of the spindle 27 of the striking device 30 is changed, and the die elements 2A, 2B are changed.
It is necessary to change the number of backers 26 in accordance with the number of backers 26. Further, when the die 1A of the second embodiment is used in the rotary swage device, the hammer roller 2 arranged between the spindle 27 and the inside ring 22 is used.
It is necessary to appropriately change the number and the arrangement interval of the three, the ratio of the large diameter portion 26b of the outer surface 26a of the backer 26 to the small diameter portions 26c, 26c on both sides thereof, and the like.

Further, in each of the above-mentioned embodiments,
Die surfaces 2b, 2Ab, 2 of die elements 2, 2A, 2B
In Bb, the flanks 2g are provided at the boundaries between the retracting surface 2e and the inner surfaces 2a, 2Aa, 2Ba, respectively.
This flank 2g may be omitted, and similarly, the striking face 2
c and the inner surface 2a, 2Aa, 2Ba at the boundary of the die surface 2
b, 2Ab, 2Bb, flank 2f, and die faces 2b, 2A between striking face 2c and retracting face 2e.
At least one of the distance changing surface portions 2d provided on the b and 2Bb portions may be omitted.

[0058]

As described above, according to the present invention as set forth in claim 1, dies are arranged so as to face the peripheral surface of the multi-layered concentric stranded wire, and the dies are arranged in the circumferential direction of the multi-layered concentric stranded wire. While rotating, it is moved closer to and separated from the peripheral surface, and the peripheral surface is intermittently struck by the die surface portion facing the peripheral surface with the die to reduce the diameter of the multilayer concentric stranded wire into a high compression multilayer concentric stranded wire. In the rotary swaging device, a part of the die surface portion is formed on a striking surface capable of contacting the peripheral surface, and the die surface portion adjacent to the striking surface on the upstream side in the rotation direction of the die is hit by the striking portion. When the peripheral surface is hit by a surface, it is formed as a retracting surface that is separated from the peripheral surface in the radial direction.

Therefore, when the die rotates while the striking surface is in contact with the peripheral surface of the multi-layered concentric stranded wire, at the next point in time, the peripheral surface portion of the multi-layered concentric stranded wire with which the striking surface is in contact The retreat surfaces are spaced apart in the radial direction of the multi-layered concentric stranded wire. Therefore, the die surface part facing the outer peripheral surface of the multi-layered concentric stranded wire is located at the same peripheral surface portion of the multi-layered concentric stranded wire as the die rotates. No longer contact continuously. As a result, even if the moving speed of the die in the circumferential and radial directions of the multi-layered concentric twisted wire increases, the circumferential surface of the multi-layered concentric twisted wire is damaged due to friction caused by sliding contact of the die surface portion, such as breakage or burr. It is possible to prevent this from being received, and it is possible to improve the speed of rotary swaging using a die.

According to the present invention as set forth in claim 2, the die comprises a plurality of die elements divided in the circumferential direction of the multilayer concentric stranded wire, and the die elements face the circumferential surface. The striking surface is formed on the die element surface portion, and the retreat surface is formed on each of the die element surface portions on the downstream side of the striking surface in the rotation direction of the die. In the approaching state to the peripheral surface, on the striking surface of each die element,
The retreat surface of the die element located on the upstream side of the die element in the rotational direction of the die is adjacent to the die element.

Therefore, in the state where a plurality of die elements divided in the circumferential direction of the multi-layered concentric twisted wire are close to the circumferential surface of the multi-layered concentric twisted wire, each die element surface portion facing the circumferential surface of the multi-layered concentric twisted wire is The hitting surface thus formed is adjacent to the retreat surface on the downstream side of the hitting surface in the die element surface portion of the die element located on the upstream side in the rotation direction of the die. Therefore, when a plurality of die elements are simultaneously approached and separated from the peripheral surface of the multi-layered concentric stranded wire, and a plurality of peripheral surface portions spaced in the circumferential direction of the multi-layered concentric stranded wire are hit with the striking surface of each die element. Even if there is, it is possible to prevent the peripheral surface portions of the multilayer concentric stranded wire from being damaged by breakage, burrs, or the like due to friction accompanying sliding contact of the striking surface of each die element.

Further, according to the present invention as set forth in claim 3, the die element surface portion between the striking surface and the retreat surface of the die element is in a state of approaching the peripheral surface of each of the die elements. In the above configuration, the distance from the center of the multilayer concentric stranded wire gradually increases from the upstream side to the downstream side in the rotating direction A of the die, and the distance changing surface is gradually separated from the peripheral surface.

Therefore, the step portion at the boundary between the striking surface of each die element and the distance change surface on the downstream side in the dicing direction on this striking surface becomes an obtuse angle rather than a substantially right angle, and the retreat surface of each die element. At each peripheral surface of the multi-layer concentric stranded wire facing
With the rotation of the die, when the striking surface on the upstream side in the rotating direction of the die is in sliding contact with the retreat surface of the die element, the obtuse-angled step portion of the striking surface and the gap changing surface is formed before this striking surface. It will be in sliding contact. Therefore, it is possible to reliably prevent the peripheral surface of the multi-layer concentric stranded wire from being damaged, as compared with the case where the retracting surface and the striking surface are directly adjacent to each other to form a substantially right-angled step.

According to the present invention as set forth in claim 4, when the die elements are close to the peripheral surface, the striking surface of each die element rotates the die more than the die element. Configured to be adjacent to the retreat surface of the die element located adjacent on the upstream side in the direction, in the striking surface of each die element, at the striking surface portion of the die element near the upstream side, the striking surface portion, The flank is formed so as to separate from the peripheral surface from the downstream side to the upstream side in the rotating direction of the die.

Therefore, at each peripheral surface portion of the multi-layered concentric stranded wire with which the striking surface of each die element comes into contact, the retreat surface of the die element located on the upstream side of the die element and adjacent to the die element as the die rotates. When facing, following the striking surface, the flank surface adjacent to this striking surface will be in sliding contact, compared to forming a step between the striking surface and the retreat surface of the adjacent die element at a substantially right angle, It is possible to reliably prevent the peripheral surface of the multilayer concentric stranded wire from being damaged.

[Brief description of drawings]

FIG. 1 is an enlarged plan view showing a state in which a peripheral surface of a multilayer concentric stranded wire is hit with a die structure according to a first embodiment of the present invention which can be used in a conventionally known rotary swage device.

FIG. 2 is an enlarged plan view showing a retracted state in which the die structure of FIG. 1 is separated from a peripheral surface of a multilayer concentric twisted wire.

FIG. 3 is an enlarged plan view showing a state in which a peripheral surface of a multilayer concentric stranded wire is hit with a die structure according to a second embodiment of the present invention.

FIG. 4 is an enlarged plan view showing a state in which a peripheral surface of a multilayer concentric stranded wire is hit with a die structure according to a third embodiment of the present invention.

FIG. 5 is a perspective view showing an example of a configuration of a multi-layer concentric stranded wire formed in a manufacturing process of the high compression multi-layer concentric stranded wire.

FIG. 6 is a cross-sectional view of a highly compressed multilayer concentric stranded wire formed from the multilayer concentric stranded wire shown in FIG.

FIG. 7 is an explanatory diagram showing the configuration of a conventionally known apparatus for manufacturing a high compression multilayer concentric stranded wire.

FIG. 8 is a sectional view showing a specific configuration of a conventional rotary swaging apparatus.

9 is a cross-sectional view of the striking device shown in FIG. 8 in a contracted state viewed from the back side.

10 is a sectional view of the striking device shown in FIG. 8 in an expanded state as seen from the back surface.

[Explanation of symbols]

1, 1A, 1B Die 2, 2A, 2B Die element 2b, 2Ab, 2Bb Die face (die face part facing the peripheral surface of multilayer concentric stranded wire) 2c Hitting face part (hit face) 2d Interval changing face part (distance changing face) 2e Retraction surface part (retraction surface) 2f Relief surface 50 High compression multilayer concentric stranded wire 50A Multilayer concentric stranded wire 50a Multilayer concentric stranded wire peripheral surface A Die rotation direction P Multilayer concentric stranded wire center

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Yasunori Kondo 2771 Ooka, Numazu City, Shizuoka Prefecture Yazaki Electric Cable Co., Ltd.

Claims (4)

[Claims] 1. A die is arranged so as to face a peripheral surface of a multi-layered concentric twisted wire, and the die is moved toward and away from the peripheral surface while rotating in the circumferential direction of the multi-layered concentric twisted wire. In a rotary swage processing apparatus for intermittently striking the peripheral surface with a die surface portion facing the surface to reduce the diameter of the multilayer concentric stranded wire into a high compression multilayer concentric stranded wire, a part of the die surface portion is the peripheral surface. A striking surface that can contact the striking surface, and the die surface portion adjacent to the striking surface on the upstream side in the rotating direction of the die is separated from the circumferential surface in the radial direction when striking the circumferential surface with the striking surface. The die structure of the rotary swage processing machine for manufacturing high compression multi-layered concentric stranded wire, characterized in that it is formed on the retracted surface. 2. The die comprises a plurality of die elements divided in the circumferential direction of the multi-layer concentric twisted wire, and the striking surface is formed on a die element surface portion facing the circumferential surface of each of the die elements. In addition, the retreat surface is formed on each die element surface portion on the downstream side of the striking surface in the rotation direction of the die, and each die element is in a state of approaching the peripheral surface of each die element. The rotary swaging process for producing a high-compression multi-layer concentric twisted wire according to claim 1, wherein the striking face of the element is adjacent to the retracting face of the die element located on the upstream side of the die element in the rotational direction of the die. Equipment die structure. 3. The die element surface portion of the die element between the striking surface and the retreat surface is located downstream from the upstream side in the rotational direction of the die when the die elements are close to the peripheral surface. The rotary swaging apparatus for manufacturing a high-compression multi-layered concentric twisted wire according to claim 2, wherein the distance from the center of the multi-layered concentric twisted wire gradually increases toward the side and is formed on a distance change surface that gradually separates from the peripheral surface. Die structure. 4. Each of the die elements has a striking surface of each of the die elements located adjacent to an upstream side of the die element in the rotational direction of the die in a state of approaching the peripheral surface. The striking surface of each die element is configured to be adjacent to the retreat surface, and the striking surface portion near the die element located on the upstream side adjacent to the striking surface extends from the downstream side to the upstream side in the rotating direction of the die. The die structure of the rotary swage processing apparatus for producing a highly-compressed multi-layered concentric stranded wire according to claim 2 or 3, wherein a flank that separates from the peripheral surface is formed accordingly.