JP6356732B2 - Twist wire manufacturing apparatus and twist wire manufacturing method - Google Patents

Description

  The present invention relates to a twisted wire manufacturing apparatus and a twisted wire manufacturing method for manufacturing a twisted wire by twisting at least two electric wires.

  For example, a wire harness is routed in a vehicle in order to electrically connect devices mounted on an automobile. The wire harness includes a plurality of sub harnesses. The wire harness having such a configuration is manufactured by combining sub-harnesses so as to match a desired circuit pattern. One of the sub-harnesses is a twisted pair wire (twisted wire).

  In FIG. 27, a twisted wire 102 is manufactured by twisting two electric wires 101 together. As an apparatus for manufacturing the twisted wire 102, for example, one disclosed in Patent Document 1 below is known. The twisted wire manufacturing apparatus (wire twisting apparatus) of Patent Document 1 includes a work table, a holding unit that holds one end of two electric wires on the work table, a motor that rotates the holding unit around an axis, A pair of rotation holding parts formed by juxtaposing single-core holding parts that hold the other end of the wire in a rotatable manner around the axis, a movement holding part provided movably along the axis, and this movement The driving unit is configured to move the holding unit along the axis, and the control unit controls the moving speed of the moving holding unit.

JP 2008-277032 A

  In the above prior art, since the twisted wire 102 is manufactured in a linearly long state, in order to manufacture such a twisted wire 102, the installation space of the apparatus is at least longer than the length of the electric wire 101. That is, it has a problem that it must be secured long in the horizontal direction. Further, in the above prior art, when the completed twisted wire 102 is removed from the workbench, it is necessary to walk to the end of the twisted wire 102 one by one, so that workability is deteriorated. Also have.

  Therefore, in order to solve the above problem, the present inventor considered that a twisted wire is manufactured with a half length of the conventional wire by making a U-turn in the middle of the electric wire. The inventor of the present application has found that there is a problem that workability deteriorates unless the electric wire is U-turned in advance and the U-turned electric wire can be pulled out. It was also found that there was a problem that when pulling out the electric wire, the other electric wire was caught and the other electric wire was pulled out together.

  The present invention has been made in view of the above circumstances, and it is an object of the present invention to provide a twisted wire manufacturing apparatus and a twisted wire manufacturing method capable of reducing installation space and the like while ensuring workability. .

  The twisted wire manufacturing apparatus of the present invention according to claim 1, which has been made to solve the above-mentioned problems, is a twisted wire manufacturing device for manufacturing a twisted wire by twisting at least two electric wires. The configuration of the apparatus includes an electric wire twisting unit and an electric wire pulling unit for allowing the two electric wires to be drawn out to the electric wire twisting unit side. One end for accommodating a part or the whole from the U-turn part to one end side of the two electric wires in a state where the U-turn part generated in the middle of the two electric wires is exposed to the side of the electric wire twisting unit Side electric wire accommodating portion, the other end side electric wire accommodating portion for accommodating a part or the whole from the U-turn portion to the other end side of the two electric wires, and one end thereof An electric wire housing portion and an electric wire housing portion swinging device for rocking the other end side electric wire housing portion, and the one end side electric wire housing portion and the other end side electric wire housing portion include the U-turn portion. The other end portion is disposed below the one end portion on the exposed side, and the wire accommodating portion swinging device is disposed to swing the other end portion. Features.

  The present invention according to claim 2 is the twisted wire manufacturing apparatus according to claim 1, wherein the twisted wire manufacturing device further includes a wire lifting unit that lifts the two wires. The structure of the lifting unit includes an electric wire hanging part that hangs by hanging the U-turn part, and the structure of the electric wire twisting unit is provided with the electric wire lifting unit and chucks and twists the two electric wires. In order to perform the operation, the chuck includes one end chuck portion and the other end chuck portion as the chucking portion, and a same direction rotating portion that rotates the one end chuck portion and the other end chuck portion in the same direction. .

  Moreover, the twisted wire manufacturing method of the present invention according to claim 3 made to solve the above-mentioned problem is the twisted wire manufacturing method for manufacturing a twisted wire by twisting at least two electric wires. The wire manufacturing method includes a wire intermediate hooking step in which a U-turn portion generated in the middle of the two electric wires is hung on the electric wire hook portion, and an electric wire end chuck for chucking one end and the other end of the two electric wires, respectively. A wire lifting step of lifting the two wires in a state where the U-turn portion is hung on the wire hanging portion, and a wire twisting step of twisting the two wires after lifting the two wires In the wire intermediate laying step, the wire drawing unit for drawing out the two wires is used, and the wire drawing unit When pulling out the electric wires is characterized by swinging the portion of the wire receiving portion of the wire drawer unit.

  It should be noted that the operation of the present invention having the above-described features will be described in detail in the section of the examples in this specification, and the description here will be omitted.

  According to the first and third aspects of the present invention, since the manufacturing apparatus and the manufacturing method have the above-described configuration, the fact that another electric wire is caught when the electric wire is pulled out is caused by swinging. There is an effect that it can be prevented. Therefore, there is an effect that workability can be ensured.

  According to the present invention described in claim 2, in addition to the effect of claim 1, the following effect is further exhibited. In other words, since the manufacturing apparatus is configured to make the twisted wire U-turn in the middle of the twisted wire so that the length of the twisted wire is half that of the conventional twisted wire, the installation space can be reduced. In addition, according to the present invention, since it becomes a manufacturing apparatus that brings the end position of the completed twisted wire closer, it is possible to remarkably reduce the burden on the operator and improve workability. There is an effect that can be done.

It is a schematic block diagram of the twist wire manufacturing apparatus of this invention. It is an enlarged view of the lower part in the twist line | wire manufacturing apparatus of FIG. FIG. 3 is an enlarged view around a wire twisting unit in FIG. 2. It is an enlarged view of an electric wire twisting unit periphery which shows the state after twisting. It is a schematic block diagram of the electric wire drawer unit of FIG. It is the figure seen from the arrow A direction and B direction of FIG. 5, (a) is a figure which shows the upper end one side electric wire accommodating part and other end side electric wire accommodating part, (b) is the lower end one end side electric wire accommodating part and The figure which shows an other end side electric wire accommodating part, (c) is a figure which shows the state of the edge part arrange | positioned below in the one end side electric wire accommodating part and the other end side electric wire accommodating part. It is a figure of the electric wire lifting part in the electric wire lifting unit of FIG.1 and FIG.2, (a) is a side view, (b) is a front view. It is a figure which shows the state which hung the electric wire middle with respect to FIG. 7, (a) is a side view, (b) is a front view. It is the figure seen from the arrow C direction and D direction of FIG. 8, (a) is a figure which shows the state of OK, (b) is a figure which shows an NG state with an electric wire overlapping. It is a side view which shows the modification of the electric wire lifting part of FIG. It is a front view of the electric wire lifting part of FIG. It is a figure which shows the state which hung the middle of an electric wire with respect to FIG. It is a figure which shows the state which hung the middle of an electric wire with respect to FIG. It is a figure which shows an end and other end chuck | zipper part and an electric wire edge part partition plate, (a) is a figure before a chuck | zipper, (b) is a figure after a chuck | zipper. It is a figure which shows the tape winding process employ | adopted with the tape supply unit of FIG.1 and FIG.2. It is a figure which shows the tape winding process employ | adopted with a tape supply unit. It is a figure which shows the tape winding process employ | adopted with a tape supply unit. It is a figure which shows the tape winding process employ | adopted with a tape supply unit. It is the figure seen from the arrow E direction of FIG. It is a figure which shows the tape winding process employ | adopted with a tape supply unit. It is a figure which shows the wire twisting process employ | adopted with the wire twisting unit of FIG. 1 thru | or FIG. It is a figure which shows the electric wire twisting process employ | adopted with an electric wire twisting unit. It is the schematic which shows the chuck | zipper vertical position change part employ | adopted at the wire twisting process of FIG.21 and FIG.22. It is a figure which shows the twist line | wire payout process employ | adopted with the twist line | wire payout unit of FIG. It is a figure which shows the twist line payout process employ | adopted with a twist line payout unit. It is a figure which shows the twist line payout process employ | adopted with a twist line payout unit. It is a figure which concerns on description of a prior art example, (a) is a figure of the state which arranged two electric wires, (b) is a figure which shows a twist line.

  A twisted wire manufacturing device is a device for manufacturing twisted wires by twisting at least two wires, a wire lifting unit for lifting two wires, and chucking and twisting the two wires. And a wire drawing unit for enabling two wires to be drawn to the side of the wire twisting unit. The twisted wire manufacturing apparatus is configured to swing a part of the wire housing portion in the wire pulling unit with the wire housing swinging device when pulling out two wires from the wire pulling unit.

  Hereinafter, embodiments will be described with reference to the drawings. FIG. 1 is a schematic configuration diagram of a twisted wire manufacturing apparatus according to the present invention. 2 is an enlarged view of the lower portion of the twisted wire manufacturing apparatus of FIG. 1, FIG. 3 is an enlarged view of the vicinity of the wire twisting unit of FIG. 2, and FIG. 4 is the periphery of the wire twisting unit showing the state after twisting. FIG. 5 is a schematic configuration diagram of the electric wire drawing unit of FIG. 1, and FIG. 6 is a view seen from the arrow A direction and the B direction of FIG.

  7 is a diagram of a wire lifting portion in the wire lifting unit of FIGS. 1 and 2, FIG. 8 is a diagram showing a state where the middle of the wire is hung on FIG. 7, and FIG. 9 is a direction of arrows C and D in FIG. 10 to 13 are views showing modifications of the electric wire lifting portion of FIG. 7, and FIG. 14 is a view showing one end / the other end chuck portion and the electric wire end partition plate.

  15 to 20 are diagrams showing a tape winding process employed in the tape supply unit of FIGS. 1 and 2. 21 and 22 are diagrams showing a wire twisting process employed in the wire twisting unit shown in FIGS. 1 to 4, and FIG. 23 is a vertical position of the chuck employed in the wire twisting process shown in FIGS. It is the schematic which shows a change part. 24 to 26 are diagrams showing a twist line payout process employed in the twist line payout unit of FIG.

<About the structure of the twist wire manufacturing apparatus 1 and the twist wire manufacturing method>
In FIG. 1, a twisted wire manufacturing apparatus 1 is an apparatus for manufacturing a twisted wire 102 (see FIGS. 4 and 27), and includes a wire drawing unit 2, a wire lifting unit 3, and a wire twisting unit 4. The tape supply unit 5, the twisted wire dispensing unit 6, a control unit (not shown) for controlling the entire apparatus, and a frame 7 for installing these units at predetermined positions.

  The manufacturing process employed in the twisted wire manufacturing apparatus 1 includes an electric wire drawing process, an electric wire intermediate hooking process, an electric wire end chucking process, an electric wire lifting process, an electric wire twisting process, a tape winding process, and a twisted wire. And a payout process.

<About twisted wire 102>
In FIG. 4, the twisted wire 102 has the same configuration and structure as the twisted wire 102 (conventional example) in FIG. 27, and is manufactured by twisting two electric wires 101 together. In addition, although the number of the electric wires 101 of the present embodiment is two, the wires 101 may be twisted more than this. Specifically, for example, four wires or a total of four wires having different thicknesses may be twisted together.

<About the wire drawer unit 2>
In FIG.1 and FIG.2, the electric wire drawer unit 2 is arrange | positioned in the apparatus back | inner side seeing from an operator. The wire drawing unit 2 having such an arrangement is configured so that the number of wires 101 can be drawn out to the wire twisting unit 4 side.

  In FIG. 5, the wire drawing unit 2 of the present embodiment includes an upper wire drawing portion 8 for drawing wires, a lower wire drawing portion 9 for drawing wires, a wire accommodating portion swinging device 10, and a frame 11. And is configured. The upper-stage-side wire lead-out portion 8 is provided in such a configuration that one of the two wires 101 to be twisted can be drawn out. Further, the lower-stage-side wire lead-out portion 9 is also provided with a configuration that allows the other of the two wires 101 to be twisted to be drawn out. On the other hand, the wire accommodating portion swinging device 10 is provided for swinging portions (described later) disposed below the upper-stage-side wire lead-out portion 8 and the lower-stage-side wire lead-out portion 9. The frame 11 is provided in order to install the upper-stage electric wire lead-out portion 8, the lower-stage electric wire lead-out portion 9, and the electric wire housing portion swing device 10 at predetermined positions. Hereinafter, each of the above configurations will be described in more detail.

<About the upper-side wire lead-out portion 8>
5 and 6, the upper-stage-side wire lead-out portion 8 has a U-turn portion 106 generated in the middle 105 (see FIG. 27) for one of the two wires 101 to be twisted. (See FIGS. 1 and 2). Specifically, the one end side electric wire accommodating portion 12 for accommodating the portion from the U-turn portion 106 to the one end 103 side of the electric wire 101 and the portion from the U-turn portion 106 to the other end 104 side of the electric wire 101 The other end side electric wire accommodating part 13 for accommodating is comprised.

  Regarding the one end side electric wire housing portion 12 and the other end side electric wire housing portion 13, the exposed side of the U-turn portion 106 is set as one end portion 12 a, 13 a, and the opposite side (side away from the U-turn portion 106) is the other side. If it is set as the edge parts 12b and 13b, it arrange | positions so that the other edge part 12b and 13b may be located below.

  The one end side electric wire accommodating part 12 and the other end side electric wire accommodating part 13 of a present Example are comprised by the following parts, respectively. That is, the end corresponds to the cylindrical upper wire housing portions 12c and 13c (first wire housing portion) corresponding to the one end 12a and 13a, and the end corresponds to the other end 12b and 13b. It is comprised in the part which has cylindrical lower side electric wire accommodating part 12d, 13d (2nd electric wire accommodating part), and cylindrical intermediate | middle electric wire accommodating part 12e, 13e arrange | positioned in these. The one end side electric wire accommodating portion 12 and the other end side electric wire accommodating portion 13 are formed in a portion having a shape obtained by dividing the cylinder into three in the longitudinal direction (not limited to the cylinder, for example, by including a shape such as a collar). Be good). The reason for the division is to be able to cope with various wire lengths.

  In addition, as shown in FIG. 5, the one end side electric wire accommodating portion 12 and the other end side electric wire accommodating portion 13 are in a state where the upper electric wire accommodating portions 12 c and 13 c and the intermediate electric wire accommodating portions 12 e and 13 e are loosely angled in the horizontal direction. It is arranged and formed (a state extending in an oblique direction). Further, the lower electric wire accommodating portions 12d and 13d are arranged and formed in a state where the vertical electric direction has a steep angle (a state extending downward).

  In addition, the terminal metal fitting 108 (refer FIG. 27) provided in the one end 103 and the other end 104 of the electric wire 101 is accommodated in the lower side electric wire accommodating portions 12d and 13d. In the drawings of this embodiment (FIGS. 5 and 6, etc.), for the sake of convenience, the number of wires 101 is small and difficult to understand. However, in actuality, several tens of wires 101 and terminal fittings 108 are accommodated. Become so. For this reason, when only one wire 101 is pulled out, if the terminal fittings 108 housed in the lower wire housing portions 12d and 13d are caught with each other, the wire 101 may be prevented from being pulled out. In the present embodiment, consideration is given so that such catching can be eliminated. That is, in order to prevent the lower wire housing portions 12d and 13d from rocking and causing a catching, a wire housing portion rocking device 10 described later is provided.

<About the lower-side wire lead-out portion 9>
In FIG. 5 and FIG. 6, the lower stage wire lead-out portion 9 is configured similarly to the upper stage side wire lead-out portion 8. In other words, the lower-side electric wire lead-out portion 9 makes the U-turn portion 106 generated in the intermediate 105 (see FIG. 27) the electric wire twisting unit 4 (FIGS. 1 and 2) with respect to the other of the two electric wires 101 to be twisted. It is configured so that it can be accommodated in an exposed state on the reference side. Specifically, the one end side electric wire accommodating portion 14 for accommodating the portion from the U-turn portion 106 to the one end 103 side of the electric wire 101 and the portion from the U-turn portion 106 to the other end 104 side of the electric wire 101 are arranged. The other end side electric wire accommodating part 15 for accommodating is comprised.

  With respect to the one end side electric wire accommodating portion 14 and the other end side electric wire accommodating portion 15, the exposed side of the U-turn portion 106 is set as one end portion 14a, 15a, and the opposite side (the side away from the U-turn portion 106) is the other end. If it is set as the edge parts 14b and 15b, it arrange | positions so that the other edge part 14b and 15b may be located below.

  The one end side electric wire accommodating part 14 and the other end side electric wire accommodating part 15 of a present Example are comprised by the following parts, respectively. That is, the end corresponds to the cylindrical upper electric wire accommodating portion 14c, 15c (first electric wire accommodating portion) corresponding to the one end 14a, 15a, and the end corresponds to the other end 14b, 15b. It is comprised in the part which has the cylindrical lower wire accommodating parts 14d and 15d (2nd electric wire accommodating part), and the cylindrical intermediate | middle intermediate | middle electric wire accommodating parts 14e and 15e arrange | positioned in these. The one end side electric wire accommodating portion 14 and the other end side electric wire accommodating portion 15 are formed in a portion having a shape obtained by dividing the cylinder into three in the longitudinal direction (not limited to the cylinder, for example, by including a shape such as a collar). Be good). The reason for the division is to be able to cope with various wire lengths.

  In addition, as shown in FIG. 5, the one end side electric wire accommodating portion 14 and the other end side electric wire accommodating portion 15 are in a state where the upper electric wire accommodating portions 14c and 15c and the intermediate electric wire accommodating portions 14e and 15e are loosely angled in the horizontal direction. It is arranged and formed (a state extending in an oblique direction). Further, the lower wire accommodating portions 14d and 15d are arranged and formed in a state in which the vertical direction has a steep angle (a state extending in the downward direction).

  In addition, although it is the same as that of the above, the terminal metal fitting 108 (refer FIG. 27) provided in the one end 103 and the other end 104 of the electric wire 101 is accommodated in the lower side electric wire accommodating parts 14d and 15d. In the drawings of this embodiment (FIGS. 5 and 6, etc.), for the sake of convenience, the number of wires 101 is small and difficult to understand. However, in actuality, several tens of wires 101 and terminal fittings 108 are accommodated. Become so. For this reason, when only one wire 101 is pulled out, if the terminal fittings 108 housed in the lower wire housing portions 14d and 15d are caught with each other, the wire 101 may be prevented from being pulled out. In the present embodiment, consideration is given so that such catching can be eliminated. That is, in order to prevent the lower wire housing portions 14d and 15d from swinging to cause a catch, a wire housing portion swinging device 10 described later is provided.

<Regarding the wire accommodating portion swinging device 10>
In FIG. 5, the electric wire housing part swinging device 10 includes, for example, two cylinders 16 and 17 that can be expanded and contracted in the horizontal direction. The electric wire housing portion swinging device 10 is configured to be able to swing the lower wire housing portions 12d to 15d through the cylinders 16 and 17 at an appropriate cycle. The electric wire housing part swinging device 10 is provided to eliminate the hooking between the terminal fittings 108 housed in the lower electric wire housing parts 12d to 15d by rocking (if the above hooking can be eliminated, Other devices may be used).

<About the wire drawing process>
1 and 2, in the electric wire drawing process, the U-turn portion 106 of the electric wire 101 is held, and the one end side and the other end side of the electric wire 101 are connected to the one end side electric wire accommodating portions 12 and 14 and the other end side electric wire accommodating portion 13. , 15 is performed. When the electric wire 101 is pulled out to the electric wire twisting unit 4 side, the operation in the next step is performed.

<About the wire lifting unit 3>
1 and 2, the electric wire lifting unit 3 is provided for lifting the two electric wires 101. Such a wire lifting unit 3 includes a unit body 18, a wire lifting portion 19 and a wire hanging portion 20 provided on the front side of the unit body 18, and a lifting drive portion 21 provided on the back side of the unit body 18. Consists of including.

<About the wire lifting part 19>
2 and 7, the electric wire lifting portion 19 is formed in a substantially prismatic portion that protrudes to the front side (to the worker side). Rotating shafts 50 to be described later are respectively provided on the left and right side portions of the electric wire lifting portion 19. Moreover, the wire hook part 20 is provided in the protrusion front-end | tip part. Each rotary shaft 50 is provided with a transfer hook 51 described later.

<About the wire hook 20>
2 and 7, the wire hooking portion 20 is formed as a portion for hanging the U-turn portions 106 of the two electric wires 101 drawn in the wire drawing step. In the present embodiment, the wire hooking portion 20 is formed in a circular roller shape. A concave portion 22 is formed in the electric wire hanging portion 20 once. The concave portion 22 is formed as a portion that makes it difficult to drop the U-turn portion 106.

<About the lifting drive unit 21>
1 and 2, the lifting drive unit 21 includes a motor (not shown), a chain 23, and the like. When the motor is operated, the lifting drive unit 21 is configured such that the unit main body 18 moves up and down by the chain 23 and the like (a state in which the wire lifting unit 19 and the wire hooking unit 20 move up and down).

<About the intermediate wire hanging process>
In FIG. 8, in the wire intermediate hanging process, an operation of hanging the U-turn portions 106 of the two wires 101 drawn from the wire drawing unit 2 on the wire hanging portion 20 is performed. In addition, as shown in FIG. 9, the two electric wires 101 are hung so that each U-turn part 106 may not cross | intersect (it does not overlap up and down) in the electric wire hook part 20. As shown in FIG. This is because the twist pitch (wire pitch) changes when the U-turn portions 106 are crossed (wire crossing state) when twisted together. In order to keep the twist pitch (wire pitch) from changing (to keep the wire pitch from being disturbed), the following modifications are effective. Hereinafter, a modification of the wire lifting portion 19 will be briefly described with reference to FIGS. 10 to 13.

<Variation of electric wire lifting part 19>
10 to 13, the electric wire lifting part 19 as a modification is configured to include an electric wire pressing part 24 provided in the upper part and an electric wire intermediate partition plate 25 provided in the lower part.

<About the wire holding part 24>
In FIG. 10 thru | or FIG. 13, the electric wire holding | suppressing part 24 is comprised so that it may have the rotating shaft 24a, the flat plate part 24b, and the pressing part 24c. The wire pressing portion 24 is provided to hold the U-turn portions 106 from above after the U-turn portions 106 are hung so as not to intersect the concave portions 22 of the wire hooking portions 20. The electric wire holding part 24 is effective for preventing the electric wire from falling off and loosening when it is lifted.

<About the electric wire intermediate divider 25>
In FIG. 10 thru | or FIG. 13, the electric wire intermediate | middle partition plate 25 is comprised so that it may have the rotating shaft 25a, the flat plate part 25b, and the partition part 25c. The wire intermediate partition plate 25 is provided to hang the U-turn portions 106 without crossing the concave portions 22 of the wire hooking portion 20. The partition part 25c is formed so that each U-turn part 106 can be partitioned back and forth. By using this, the wire intermediate partition plate 25 has the advantage that the crossing of wires can be avoided, and as a result, the twist pitch (wire pitch) does not change.

  In addition, it can be said that it is also effective to provide the second electric wire intermediate partition plate 26 below the electric wire intermediate partition plate 25. The second electric wire intermediate partition plate 26 is formed so that the electric wire 101 can be divided into left and right. Although not particularly illustrated, the above-described wire pressing portion 24, the wire intermediate partition plate 25, and further the second wire intermediate partition plate 26 are configured to be separated from the wire 101 when the wires are twisted together.

<About wire lifting process>
1 to 3, the wire lifting process is a process of lifting the U-turn part 106 in a state where it is hung on the wire hooking part 20. After performing the first lifting process for moving the wire hooking portion 20 upward and the wire end chucking step described later, the wire hooking portion 20 is further moved upward in order to apply an appropriate tension to the two electric wires 101. (It is assumed that the process is divided as an example. In FIGS. 2, 4 and 21A, the two electric wires 101 are appropriately tensioned. ).

<About the wire twisting unit 4>
1 to 4, the wire twisting unit 4 is provided for chucking and twisting two wires 101. The wire twisting unit 4 is attached to the wire lifting unit 3. Such a wire twisting unit 4 includes one end chuck portion 27, the other end chuck portion 28, and the same direction rotating portion 29.

<About the one-end chuck portion 27, the other-end chuck portion 28, and the same-direction rotating portion 29>
2 and 3, the one end chuck portion 27 is configured to be able to chuck one end 103 of two electric wires 101. Similarly, the other end chuck portion 28 is configured to be able to chuck the other end 104 of the two electric wires 101. The same-direction rotating unit 29 is configured to rotate the one end chuck unit 27 and the other end chuck unit 28 in the same direction.

  In the process using the wire twisting unit 4 as described above, the wire end chucking process and the wire twisting process are performed.

<About the wire end chuck process>
2 and 3, in the wire end portion chucking step, the work of chucking the one end 103 and the other end 104 of the two wires 101 to the one end chuck portion 27 and the other end chuck portion 28 is performed.

  When the number of twisted wires is larger than that in the present embodiment, a wire end partition plate 30 as shown in FIG. 14 may be used. The electric wire end partition plate 30 is formed in a plate shape that can partition the predetermined electric wires and the electric wires 101 in the vicinity of the one end chuck portion 27 and the other end chuck portion 28 (at the time of wire twisting). Configured to leave). By using the electric wire end part partition plate 30, it has the advantage that it can twist together by correct electric wire arrangement | positioning and can prevent disorder of an electric wire pitch.

<About the wire twisting process>
2 to 4, in the wire twisting step, the one-direction chuck portion 27 and the other-end chuck portion 28 are rotated in the same direction by operating the same-direction rotating portion 29. Twisting occurs in the two electric wires 101, and the twisted portion 107 is formed within a predetermined range by the twisting. When the twist part 107 is formed, twisting is completed. In this embodiment, the tape winding TP for preventing slipping is simultaneously applied during the twisting (the tape winding TP will be described below).

<About the tape supply unit 5>
1 to 4, the tape supply unit 5 is provided for performing tape winding TP. The tape supply unit 5 is attached to the wire twisting unit 4. Such a tape supply unit 5 includes a tape supply unit 32 for supplying the tape 31 for preventing the slip, a tape attaching unit 33 for attaching a part of the tape 31 to a predetermined position of the two electric wires 101, and two It includes a sticking assisting portion 34 that assists in sticking the remaining portion of the tape 31 during the twisting of the electric wires 101.

<About Tape Supply Unit 32>
2 and 15, the tape supply unit 32 is a so-called tape dispenser, and is configured to be able to supply the tape 31 with a predetermined length from two annular tape bodies 35 arranged side by side.

<About the tape attaching part 33>
2 to 4, the tape attaching portion 33 is attached using a pair of attachment plate portions 36 provided on the frame 7. The tape attaching portion 33 includes two pairs of rotating shaft portions 37 and a first U-shaped bar 38 that is rotatably attached to one pair of rotating shaft portions 37 of the two pairs of rotating shaft portions 37. The second U-shaped bar 39 rotatably attached to the other pair of rotating shaft portions 37, and the first U-shaped bar 38 and the second U-shaped bar 39 are rotationally moved (FIG. 16). And a drive unit (not shown).

  The first U-shaped bar 38 is arranged on the near side as viewed from the operator. The second U-shaped bar 39 is arranged on the back side.

  A plurality of pasting blocks 40 are provided on the first U-shaped bar 38. The affixing block 40 is formed at a portion where the operator can put the tape 31 brought from the tape supply unit 32 (at a portion where suction / adsorption or the like can be performed). In addition, a part of the tape 31 is formed in a portion where it can be affixed to a predetermined position (in the vicinity of the one end 103 and the other end 104) of the two electric wires 101 (in a portion where it can be pressed). .

  On the other hand, the second U-shaped bar 39 is provided with a plurality of pressing blocks 41. The pressing block 41 is formed in a portion for preventing the electric wire 101 from being pushed by receiving a pressing force from the bonding block 40 when the tape 31 is bonded. A cushioning material 42 is provided on the pressing block 41.

<About the pasting auxiliary part 34>
2 to 4, the sticking auxiliary portion 34 is configured so that it can also be used as the tape sticking portion 33 in this embodiment. The pasting block 40 provided on the first U-shaped bar 38 is used as the first auxiliary portion 43 of the pasting auxiliary portion 34. The first auxiliary portion 43 is formed in a portion where the tape 31 attached to a predetermined position can be pressed (closed) when the two electric wires 101 are rotated. In the present embodiment, the pressing block 40 of the second U-shaped bar 39 is not used as the sticking auxiliary portion 34. Temporarily, when using this as the sticking auxiliary | assistant part 34, the pressing block 40 shall be called a 2nd auxiliary | assistant part.

<About tape winding process>
Hereinafter, the tape winding process employed in the tape supply unit 5 will be described with reference to FIGS. 15 to 20. In this step, as can be understood from the description of the above configuration, the tape 31 is wound at a predetermined position near the one end 103 and the other end 104. The tape winding process includes a tape supply process, a tape attaching process, and an attaching auxiliary process, and the tape 31 is wound using the rotation at the time of twisting. When the winding of the tape 31 is performed, it becomes possible to prevent the fraying after the two electric wires 101 are twisted together.

  In FIG. 15, in the tape supply process, the tape 31 is supplied from the tape supply unit 32 with a predetermined length. Then, the operator directly holds the tape 31 and adsorbs it, for example, on the affixing block 40 as shown in FIG. 16 (the adhesive layer of the tape 31 is turned up and the non-adhesive layer is adsorbed on the affixing block 40. It should be adsorbed loosely to such an extent that the tape 31 does not fall off).

  In FIG. 16, in the tape affixing process, the affixing block 40 and the pressing block 41 are moved as shown in FIG. The predetermined position of the two electric wires 101 is sandwiched. At this time, a part of the tape 31 is attached to the predetermined position. After a part of the tape 31 is attached to the predetermined position, the pressing block 41 is returned to the original position as shown in FIG. 18 (it is also possible to proceed to the next step without returning). ).

  In FIG. 18 and FIG. 19, in the pasting assisting step, the pasting block 40 left at a predetermined position of the two electric wires 101 is used as the first assisting portion 43 of the pasting assisting portion 34. And if the same direction rotation part 29 is operated, winding of the tape 31 will be performed using the rotation of twisting. Since the first auxiliary portion 43 acts to hold down (push) the tape 31 when the two electric wires 101 are rotated, the tape 31 is reliably wound as shown in FIG. (See FIGS. 20 and 4).

  According to the tape supply unit 5, the anti-slipping tape 31 can be wound using the rotation when the two electric wires 101 are twisted together. That is, tape winding TP can be applied. Of course, according to such a tape supply unit 5, workability is improved.

<About effective twisting>
Hereinafter, effective twisting will be described with reference to FIGS. 21 to 23. In the wire twisting step, the following first to fourth steps are performed in order.

  First, in the first step, one of the one end chuck portion 27 and the other end chuck portion 28 is rotated in a predetermined direction (here, the other end chuck portion 28 is rotated in a predetermined direction). Thereby, the twist part 107 is formed in the one side of the wire hook part 20 (refer FIG. 21 (a)-(b), FIG. 23). Next, in the second step, the position of the other end chuck portion 28 is changed upward, and the position of the one end chuck portion 27 is changed downward. Thereby, the position of the U-turn part 106 hung on the wire hook part 20 in the first step is shifted. In other words, the position of the untwisted portion 109 is shifted (see FIGS. 21 (c) and 22 (a)).

  In this embodiment, in order to change the positions of the one end chuck part 27 and the other end chuck part 28 up and down, a chuck vertical position changing part 44 as shown in FIG. 23 is employed. The chuck vertical position changing unit 44 is provided as one of the configurations of the wire twisting unit 4. The chuck vertical position changing portion 44 includes a pair of racks 45 that are moved in the vertical direction according to the circumferential length of the wire hooking portion 20 (concave portion 22), a pinion gear 46 that meshes with the pair of racks 45, And a drive mechanism (not shown). By shifting the position of the untwisted portion 109, it becomes possible to reliably twist the untwisted portion 109 in the subsequent process.

  Next, in the third step, the one end chuck portion 27 is rotated in a predetermined direction (the other end chuck portion 28 is rotated in the same direction). Thereby, the twist part 107 is formed also in the other side of the wire hook part 20 (refer FIG. 22 (a)-(b)). Finally, in the fourth step, the positions of the one end chuck portion 27 and the other end chuck portion 28 are returned to their original positions. Thereby, the twist part 107 formed in the 3rd process is arrange | positioned in the both sides of the electric wire hanging part 20 in the equal length state.

<About twisted line payout unit 6>
In FIG. 1, the twisted wire payout unit 6 is provided for paying out the twisted wire 102 after twisting (finished twisted wire 102). The twisted wire payout unit 6 is provided alongside the electric wire lifting unit 3 (arranged in a state where the electric wire lifting portion 19 and the upper portion of the frame 7 are separated). Such a twisted wire payout unit 6 includes a pair of twisted wire temporary placing hooks 47 and a twisted wire moving mechanism 48 for moving the completed twisted wires 102 to the paired twisted wire temporary placing hooks 47. It is comprised including.

<About a pair of twisted wire temporary placement hooks 47>
1 and 24, the pair of twisted wire temporary placing hooks 47 is disposed above the electric wire lifting portion 19 (disposed above the electric wire hook portion 20). Specifically, a plate-like hook installation portion 49 is disposed on the upper portion of the frame 7 and is provided in a state of projecting from the front surface of the hook installation portion 49. The pair of twisted wire temporary placement hooks 47 is formed in a substantially L-shaped bar shape with a free end facing downward as shown in the figure. The pair of twisted wire temporary placement hooks 47 is formed so that the finished twisted wire 102 can be hung by a predetermined number (for example, one lot).

<About twist line transfer mechanism 48>
1 and 24, the twist line transfer mechanism 48 is configured to transfer the completed twist line 102 to a pair of twist line temporary placement hooks 47. The twist line transfer mechanism 48 of this embodiment includes a pair of rotating shafts 50, a pair of transfer hooks 51, and a transfer action unit 52.

<Regarding the pair of rotating shafts 50 and the pair of transfer hooks 51>
In FIG. 1, FIG. 7, and FIG. 24, the pair of rotating shafts 50 are disposed on both the left and right sides of the wire lifting portion 19. The pair of rotating shafts 50 are rotatable and are formed in a columnar shape. A transfer hook 51 is provided for each of the pair of rotating shafts 50. In the present embodiment, the pair of transfer hooks 51 are formed in a state where a round bar is bent as shown in FIG. The pair of transfer hooks 51 are formed in a shape that allows the completed twisted wire 102 to be hooked and a shape that can be scooped up.

<About the transfer action part 52>
1 and 24, the transfer action section 52 is configured to be able to rotate and move the pair of transfer hooks 51, respectively. Specifically, a support portion 52a provided on the hook installation portion 49 side, a pair of flat plate portions 52b formed in a shape depending on the support portion 52a, and a lower end of the pair of flat plate portions 52b are provided. And a pair of disk-shaped (roller-shaped) hook contact portions 52c. The pair of hook abutting portions 52c are disposed at positions where the ends of the pair of transfer hooks 51 abut.

<About twist wire payout process>
Hereinafter, the twist line payout process employed in the twist line payout unit 6 will be described with reference to FIGS.

  In FIG. 24, when the finished twisted wire 102 is hung on the wire hooking portion 20, the wire lifting portion 19 is moved upward (the end chuck is released and the wire lifting unit 3 is moved upward). When the rear end of the transfer hook 51 gradually approaches the transfer action portion 52, and the rear end of the transfer hook 51 contacts the transfer action portion 52, the transfer hook 51 rotates as shown in FIG. It rotates about the axis 50. At this time, the twisted wire 102 is scooped up by the transfer hook 51.

  When the wire lifting portion 19 continues to move upward, the twisted wire 102 is paid out to the twisted wire temporary placing hook 47 side by the transfer hook 51 as shown in FIG. When the twisted wire 102 is paid out to the twisted wire temporary placement hook 47 by a predetermined number, the operator bundles the twisted wire 102 and stores it in, for example, a box, thereby completing the production for one lot, for example.

<Effects of twisted wire manufacturing apparatus 1 and manufacturing method>
As described above with reference to FIGS. 1 to 27, according to the twisted wire manufacturing apparatus 1 and the manufacturing method, the space required for manufacturing the twisted wire 102 is not limited to the horizontal direction as in the conventional example, but also in the vertical direction. Since the apparatus and method have a structure and structure that can be secured in the direction as well, the overall length of the apparatus can be remarkably shortened compared to the conventional example.

  In addition, according to the twisted wire manufacturing apparatus 1 and the manufacturing method, since it becomes an apparatus and method having a configuration and structure in which the one end 103 and the other end 104 of the two electric wires 101 are disposed at close positions, the manufacturing is completed. Since the end position of the twist line 102 is close and it is not necessary to walk to the end position as in the conventional example, the burden on the operator can be remarkably reduced as a result.

  Further, according to the twisted wire manufacturing apparatus 1 and the manufacturing method, since the wire drawing unit 2 has a swing function, it is possible to prevent other wires from being caught when the wire 101 is pulled out. Workability can be ensured.

  Therefore, as can be seen from the above, according to the twisted wire manufacturing apparatus 1 and the manufacturing method of the present invention, it is possible to reduce installation space and the like while ensuring workability.

  It goes without saying that the present invention can be variously modified without departing from the spirit of the present invention.

  DESCRIPTION OF SYMBOLS 1 ... Twisted wire manufacturing apparatus, 2 ... Electric wire drawing unit, 3 ... Electric wire lifting unit, 4 ... Electric wire twisting unit, 5 ... Tape supply unit, 6 ... Twist wire paying unit, 7 ... Frame, 8 ... Upper wire drawing part , 9 ... Lower side wire lead-out part, 10 ... Electric wire housing part swinging device, 11 ... Frame, 12, 14 ... One end side electric wire housing part (electric wire housing part), 13, 15 ... Other end side electric wire housing part (electric wire housing) Part), 16, 17 ... cylinder, 18 ... unit main body, 19 ... electric wire lifting part, 20 ... electric wire hanging part, 21 ... hoisting drive part, 22 ... concave part, 23 ... chain, 24 ... electric wire holding part, 25 ... in electric wire Partition plate, 26 ... second electric wire intermediate partition plate, 27 ... one end chuck portion, 28 ... other end chuck portion, 29 ... co-rotating portion, 30 ... electric Line end part partition plate 31 ... Tape 32 ... Tape supply part 33 ... Tape attaching part 34 ... Attaching auxiliary part 35 ... Tape main body 36 ... Mounting plate part 37 ... Rotating shaft part 38 ... No. One U-shaped bar, 39 ... Second U-shaped bar, 40 ... Adhering block, 41 ... Pressing block, 42 ... Cushion material, 43 ... First auxiliary part, 44 ... Chuck vertical position changing part, 45 ...... Rack, 46 ... Pinion gear, 47 ... Twist wire temporary placing hook, 48 ... Twist wire transfer mechanism, 49 ... Hook installation part, 50 ... Rotating shaft, 51 ... Transfer hook, 52 ... Action part during transfer, DESCRIPTION OF SYMBOLS 101 ... Electric wire, 102 ... Twist wire, 103 ... One end, 104 ... Other end, 105 ... Middle, 106 ... U-turn part, 107 ... Twist part, 108 ... Terminal metal fitting, 10 ... twisted no part, TP ... tape-wound

Claims (3)

In a twisted wire manufacturing apparatus for manufacturing a twisted wire by twisting at least two electric wires,
The configuration of the twisted wire manufacturing apparatus includes a wire twisting unit, and a wire drawing unit for allowing the two wires to be drawn to the side of the wire twisting unit,
As a configuration of the electric wire drawing unit, the U-turn portion generated in the middle of the two electric wires is exposed to the electric wire twisting unit side and extends from the U-turn portion to one end side of the two electric wires. One end side electric wire accommodating portion for accommodating a part or all of the above, and the other end side electric wire accommodating portion for accommodating a part or all from the U-turn portion to the other end side of the two electric wires, Including one end side electric wire accommodating portion and the other end side electric wire accommodating portion, and an electric wire accommodating portion swinging device,
Furthermore, the one end side electric wire accommodating portion and the other end side electric wire accommodating portion are disposed below the other end portion, rather than the one end portion on the side where the U-turn portion is exposed,
And the said electric wire accommodating part rocking | swiveling apparatus is arrange | positioned so that said other edge part may be rock | fluctuated. The twist wire manufacturing apparatus characterized by the above-mentioned. The twisted wire manufacturing apparatus according to claim 1,
As the configuration of the twisted wire manufacturing apparatus, further includes an electric wire lifting unit for lifting the two electric wires,
The configuration of the electric wire lifting unit includes an electric wire hanging portion that is hung by hanging the U-turn portion,
As the configuration of the wire twisting unit, there are one end chuck portion and the other end chuck portion as a portion for chucking in order to perform chucking and twisting on the two wires attached to the wire lifting unit. A twisted wire manufacturing apparatus, comprising: a one-direction chuck portion and a same-direction rotating portion that rotates the other end chuck portion in the same direction. In a twisted wire manufacturing method for manufacturing a twisted wire by twisting at least two electric wires,
As a process according to the twisted wire manufacturing method, an electric wire intermediate hanging step of hanging a U-turn portion generated in the middle of the two electric wires on the electric wire hanging portion,
A wire end chucking step for chucking one end and the other end of each of the two wires;
An electric wire lifting step of lifting the two electric wires in a state where the U-turn portion is hung on the electric wire hanging portion;
An electric wire twisting step of twisting the two electric wires after lifting the two electric wires,
In the wire intermediate hooking step, an electric wire drawing unit for allowing the two electric wires to be drawn out is used, and when the two electric wires are drawn from the electric wire drawing unit, A twisted wire manufacturing method characterized by swinging a part.

Images