JP2018063812A - Twist wire production device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a twist wire production device capable of simplifying a device structure or forming a uniform strand pitch.SOLUTION: A twist wire production device 1 is configured by including a rotary feeding device 5, a partition 4, a twist wire winding device 7 and a controller 8. In the twist wire producing device 1, a plurality of electric wires 101 are stranded between the partition 4 and the rotary feeding device 5 to form a twist part 107, thus, a twist wire 102 is produced. The twist wire winding device 7 includes a winding cage 23 for receiving the twist wire 102, and a cage rolling mechanism 24 for rotating the winding cage 23 with the first axis L1 at a center to make a centrifugal force work on the twist wire 102. Furthermore, the controller 8 has a rotation control part 32 for controlling such that a rotation speed of the rotary feeding device 5 and the rotation speed of the winding cage 23 are made different while rolling the winding cage 23 and the rotary feeding device 5 in the same direction.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a twisted wire manufacturing apparatus that manufactures 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. 17, 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.

  Note that reference numerals 103 and 104 in FIG. 17 indicate one end and the other end of the twist line 102. Reference numeral 105 denotes an intermediate, 107 denotes a twist portion, 108 denotes a terminal fitting, and TP denotes tape winding.

JP 2008-277032 A

  In the above prior art, although a large installation space is required, it is possible to manufacture a twisted wire with a certain length. However, it is not suitable as an apparatus for manufacturing a twisted wire that is long enough to be wound in a bundle.

  Therefore, the present inventor has considered that the following apparatus is suitable. That is, an apparatus having a configuration in which wires are pulled out from a plurality of wire reels, twisted together to form a twisted portion, and a twisted wire with a twisted portion is sent out and wound up is suitable. I thought.

  In addition, the inventors of the present application have made studies to realize the above-described apparatus, and found the following problems. That is, when twisting the wires, a force (spring back) that tries to return to the original state is generated in the wires, and the generated force needs to be properly released before winding the twisted wire. Therefore, he found the problem that the device configuration would be complicated if care was not taken to do this. Further, the inventor of the present application has found a problem that the twist pitch is affected.

  The present invention has been made in view of the above-described circumstances, and an object thereof is to provide a twisted wire manufacturing apparatus capable of simplifying the apparatus configuration and forming a uniform twist pitch.

  The twisted wire manufacturing apparatus of the present invention according to claim 1, which has been made to solve the above-described problem, includes a rotary feeding device and a partition disposed on the electric wire supply side with respect to the rotary feeding device. A twist portion is formed by twisting a plurality of electric wires between the partition and the rotary feeding device, and the partition passes through the electric wire for passing the electric wire along a first axis extending in the twist wire feeding direction. A rotating mechanism for rotating itself about the first axis, and a twist line formed with the twist part from the partition along the first axis. A twisting-out mechanism for feeding out to the remote side, and as such a twisted wire manufacturing device, the twisted wire fed from the rotary feeding device along the first axis A twist wire winding device for winding and a control device are further included, and the twist wire winding device has a winding cage for receiving the twist wire, and the winding cage is centered on the first axis. And a rotating mechanism for rotating the winding wire in the same direction as the rotating and feeding device, while the rotating device rotates the winding cage in the same direction as the rotating and feeding device. It has a rotation control part which can vary a rotation speed and a rotation speed of the above-mentioned winding basket.

  According to a second aspect of the present invention, there is provided the twisted wire manufacturing apparatus according to the first aspect, wherein the twisted wire winding device is configured to incline the basket so that the twisted wire that has been wound up can be easily taken out from the winding basket. It further has a mechanism.

  According to a third aspect of the present invention, there is provided the twisted wire manufacturing apparatus according to the first or second aspect, wherein the partition, the rotary feeding device, and the twisted wire winding device are upper, middle, and lower. It arrange | positions in the state arranged in order, It is characterized by the above-mentioned.

  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 aspect of the present invention, the rotary feeding device and the partition are included, and the twisted portion is formed by twisting between them to manufacture the twisted wire, and the twisted wire is rotated by the rotary feeding device. Thus, there is an effect that even a long twisted wire can be easily manufactured. Further, according to the present invention, the twist wire winding device for winding the twist wire fed from the rotary feeding device, and the control device for controlling the twist wire winding device and the rotary feeding device are configured. Therefore, the rotational speed of the rotary feeding device and the rotational speed of the winding cage can be made different while rotating the winding cage in the twist wire winding device in the same direction as the rotary feeding device. Even when a force (spring back) for returning to the original state is generated in the electric wire during twisting of the wires, this force can be appropriately released before winding the twisted wire. As a result, a dedicated device and a complicated device for releasing the force can be eliminated, and as a result, the structure of the twisted wire manufacturing apparatus can be simplified. Further, the release of the force produces an effect that a uniform twist pitch can be formed.

  According to the present invention described in claim 2, in addition to the effect of claim 1, the following effect is further exhibited. That is, since the basket tilting mechanism is further provided, if the winding basket is tilted toward the operator side, it is possible to easily take out the wound twisted wire.

  According to the third aspect of the present invention, in addition to the effect of the first or second aspect, the following effect is further exhibited. In other words, since the device has a configuration in which the space necessary for manufacturing the twisted wire is secured in the vertical direction, the overall length of the device in the horizontal direction (left and right direction) can be significantly shortened compared to the conventional example. .

It is a schematic diagram which shows the structure of the twist wire manufacturing apparatus of this invention (Example 1). It is an enlarged view from the autorotation prevention apparatus of FIG. 1 to a rotation delivery apparatus. It is explanatory drawing which concerns on manufacture of a twist line. FIG. 4 is an enlarged view of the twist line in FIG. 3. It is a schematic diagram which shows the modification of the twist wire winding apparatus of FIG. (Example 2) which is a schematic diagram which shows another modification of a twist wire winding apparatus. It is a schematic diagram which shows the effect | action of the twist wire winding apparatus of FIG. FIG. 8A is a schematic diagram illustrating a state in the winding cage, and FIG. 8B is a schematic diagram illustrating a state after being taken out from the winding cage. (Example 3) which is a schematic diagram which shows another modification of a twist wire winding device. (Example 4) which is a schematic diagram which shows another modification of a twist wire winding apparatus. (Example 5) which is a schematic diagram which shows another modification of a twist wire winding device. (Example 6) which is a schematic diagram which shows another modification of a twist wire winding apparatus. It is a schematic diagram which shows the effect | action of the twist wire winding apparatus of FIG. It is a schematic diagram which shows the effect | action of the twist wire winding apparatus of FIG. It is a schematic diagram which shows the effect | action of the twist wire winding apparatus of FIG. (Example 7) which is a schematic diagram which shows another modification of a twist wire winding device. 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.

  The twist wire manufacturing apparatus includes a rotary feeding device, a partition arranged on the electric wire supply side with respect to the rotary feeding device, a twist wire winding device for winding the twisted wire sent from the rotary feeding device, and the twist And a control device for controlling the wire winding device and the rotary feeding device. In a twisted wire manufacturing apparatus, a twist part is formed by twisting a plurality of electric wires between a partition and a rotary feeding device, and a twisted wire is manufactured.

  An electric wire passage part is formed in the partition. This electric wire passage part is formed so that an electric wire can be passed along the 1st axis | shaft extended in the sending-out direction of a twist line. The rotary delivery device is provided with a rotation mechanism for rotating itself about the first axis, and a delivery mechanism for sending the twist line along the first axis.

  The twist wire winding device includes a winding cage that receives the twisted wire, and a cage rotation mechanism that rotates the winding cage around a first axis to apply a centrifugal force to the twisted wire. Further, the control device has a rotation control unit for controlling the rotation speed of the rotary feeding device and the rotation speed of the winding basket to be different while rotating the winding basket in the same direction as the rotary feeding device.

  When the wires are twisted together, a force (spring back) that tries to return to the original state is generated in the wires, but if the rotation speed of the rotary feeding device and the rotation speed of the winding basket are made different from each other, The above-mentioned force is appropriately released before winding the twisted wire.

  Hereinafter, embodiments will be described with reference to the drawings. FIG. 1 is a schematic diagram showing the configuration of the twisted wire manufacturing apparatus of the present invention. FIG. 2 is an enlarged view from the rotation preventing device to the rotation feeding device of FIG. 1, and FIG. 4 is an enlarged view of the twist line of FIG. 3, and FIG. 5 is a schematic view showing a modification of the twist line winding device of FIG.

  In the following description, specific shapes, materials, numerical values, directions, and the like are examples for facilitating the understanding of the present invention, and can be appropriately changed according to use, purpose, specifications, and the like. To do.

<About the configuration of the twisted wire manufacturing apparatus 1>
In FIG. 1, a twisted wire manufacturing apparatus 1 is an apparatus for manufacturing a single twisted wire 102 by twisting electric wires 101 respectively drawn from two electric wire reels 2. 4, a rotation delivery device 5, a pair of nozzles 6, a twist wire winding device 7, a control device 8, and a frame (not shown). The twist wire manufacturing apparatus 1 is arranged such that when the apparatus is viewed in the vertical direction, the rotation prevention device 3 is at the top, the rotary feed device 5 is at the middle, and the twist wire winding device 7 is at the bottom. . Further, the partition 4 is disposed so as to be between the rotation preventing device 3 and the rotation feeding device 5, and the pair of nozzles 6 is disposed between the rotation feeding device 5 and the twist wire winding device 7. Is done. Each configuration will be described below.

<About two wire reels 2>
In FIG. 1, two electric wire reels 2 are formed by winding different types of electric wires 101 in a cylindrical shape, and known ones are adopted. The two electric wire reels 2 are placed on, for example, a floor of a manufacturing site or a predetermined table (the illustrated position is for convenience and is not particularly limited). As can be seen from the arrangement of the two electric wire reels 2 and the rotation prevention device 3, in this embodiment, the electric wires 101 are drawn upward.

<About twisted wire 102>
1, 3, and 4, the twisted wire 102 is manufactured by twisting the electric wires 101 drawn from the two electric wire reels 2 as described above. The twisted wire 102 of this embodiment is manufactured in a very long state that needs to be wound into a bundle (this is an example. It is also possible to manufacture a length as in the conventional example. ). In the present embodiment, the number of the electric wires 101 is two, but a twisted wire may be manufactured by twisting more than this number. Specifically, twisted wires may be manufactured by twisting together, for example, four electric wires or a total of four electric wires having different thicknesses. The electric wire 101 is a general one and includes a conductor and an insulator covering the conductor.

<About the rotation prevention device 3>
In FIG. 1 and FIG. 2, the two electric wires 101 respectively drawn from the two electric wire reels 2 are supplied to the rotation prevention device 3. The anti-rotation device 3 is configured to generate the back tension necessary for forming the twisted portion 107 of the twisted wire 102 (necessary for twisting). Moreover, the rotation prevention device 3 is configured to cancel the force in the rotation direction generated in the electric wire 102 by twisting. Further, the anti-rotation device 3 is configured to provide the back tension generation and the force cancellation with a simple structure. The anti-rotation device 3 according to the present embodiment includes a pair of feed rollers 9, a pair of anti-rotation rollers 10 disposed on the partition 4 side (downstream side) with respect to the pair of feed rollers 9, and a pair of rotation prevention rollers 10. And a tension adjusting portion 11 that acts on the head.

<About the first axis L1>
In the following description, it is assumed that the center line in the vertical direction in the figure corresponds to the first axis described in the claims (reference numeral is L1). The first axis L1 is a vertical axis along which the twist line 102 is sent out.

<About the pair of delivery rollers 9 and the second shaft L2>
1 and 2, the pair of delivery rollers 9 is disposed on the supply side of the two electric wires 101. The pair of delivery rollers 9 is composed of two rotatable circular rollers, and is arranged so that the two electric wires 101 can pass along the second axis L2 extending in the direction intersecting the first axis L1. Is done. More specifically, the pair of delivery rollers 9 are arranged such that the roller alignment axis L3 is parallel to the first axis L1. The pair of delivery rollers 9 are arranged so that the roller alignment axis L3 is appropriately spaced from the first axis L1. Further, the pair of delivery rollers 9 are arranged so as to suppress the fluttering of the two electric wires 101 between the rollers.

  In this embodiment, since the roller alignment axis L3 is parallel to the first axis L1, the positional relationship is such that the second axis L2 is orthogonal to the first axis L1. Therefore, the two electric wires 101 pass through the pair of delivery rollers 9 in the horizontal direction (left and right direction) (the arrangement in this embodiment is an example, for example, the second axis L2 is horizontal). It may be arranged so as to be inclined at an acute angle obliquely upward with respect to the direction).

<About a pair of rotation prevention roller 10 and the electric wire bending part 12>
1 and 2, the pair of anti-rotation rollers 10 is disposed in the vicinity of the partition 4. The pair of anti-rotation rollers 10 is composed of two rotatable circular rollers, and is arranged such that the roller alignment axis L4 is orthogonal to the first axis L1. Moreover, a pair of rotation prevention roller 10 is arrange | positioned so that the electric wire bending part 12 mentioned later may pass between these rollers. Further, the pair of anti-rotation rollers 10 has the bending start side (electric wire supply side) of the electric wire bending portion 12 placed on the roller on the right side in the figure and the bending of the electric wire bending portion 12 due to the elasticity of the electric wire 101 (conductor). The end side (partition 4 side) is arranged so as to contact the left roller in the figure. In addition, the electric wire bending part 12 is a part formed by bending the two electric wires 101 that have passed through the pair of delivery rollers 9 into a substantially L shape (or a substantially U shape) along the first axis L1. And

<About the tension adjustment unit 11>
1 and 2, the tension adjusting unit 11 changes the position of the left roller (left rotation prevention roller 10) in the drawing where the bending end side of the electric wire bending portion 12 is in contact with the elasticity of the electric wire 101 (conductor). (In other words, the distance between the pair of rotation prevention rollers 10 can be changed). Such a tension adjusting unit 11 is provided to adjust the tension applied to the electric wire bending unit 12. In the present embodiment, although not particularly shown, the cylinder and a driving mechanism for the cylinder are included (assumed to be an example).

<About the effect | action by the rotation prevention apparatus 3>
1 and 2, at the position of the rotation prevention device 3 as described above, the two electric wires 101 are bent to form the electric wire bending portion 12. In the anti-rotation device 3, a pair of anti-rotation rollers 10 is arranged in accordance with the electric wire bending portion 12. Since the two electric wires 101 are elastic, it is necessary to apply a force within the elastic deformation range to the two electric wires 101 in order to bend along the path changing from the second axis L2 to the first axis L1. is there. When the electric wire bending portion 12 is formed by applying a force within the elastic deformation range, a “force to return to the original” is generated in the electric wire bending portion 12, and this is a back tension necessary for twisting the two electric wires 101. become. On the other hand, when twisting is performed, “twisting force” is applied to the two electric wires 101 by the twisting. The “twisting force” is a force necessary for twisting, but is a force that is not desired to be transmitted to the electric wire supply side. For this reason, it is necessary to devise measures to prevent transmission. In the twisted wire manufacturing apparatus 1, since the bending shape of the wire bending portion 12 is maintained by the rotation prevention device 3, the “torsional force” is applied to the position of the wire bending portion 12, but from there the wire bending portion 12 is ahead. The “torsional force” is canceled out by the bent shape of the wire and the “force to return to the original” generated in the wire bending portion 12, and as a result, it is not transmitted to the wire supply side. Although the rotation prevention device 3 in the twisted wire manufacturing apparatus 1 has a simple configuration and structure, it can be seen that it is useful.

<About partition 4>
1 and 2, the partition 4 is a plate-like member and is fixed to a frame (not shown). In the center of such a partition 4, a pair of wire passage portions 13 for allowing the two wires 101 to pass along the first axis L <b> 1 are formed. The pair of electric wire passage portions 13 are arranged and formed so as to be arranged at a predetermined interval in a direction perpendicular to the drawing sheet. In addition, although a pair of electric wire passage part 13 of a present Example is a hole shape, not only this but a slit shape etc. shall be sufficient.

<Regarding the rotary delivery device 5>
1 and 2, the rotary feeding device 5 is a device for forming the twisted portion 107 of the twisted wire 102 by twisting, and is arranged below the partition 4 with a space necessary for twisting. Is done. Such a rotation delivery device 5 delivers the rotation mechanism 14 for rotating itself about the first axis L1 and the twist line 102 to the side away from the partition 4 along the first axis L1 (downward). For this purpose, the feed mechanism 15 and the measuring section 16 for measuring the twisted wire 102 are provided. The rotation delivery device 5 is fixed to a frame (not shown) in a state where the rotation is possible.

<About the rotating mechanism 14>
1 and 2, the rotation mechanism 14 includes a first motor 17 controlled by a rotation control unit 32 of the control device 8 to be described later, a gear box (not shown) that meshes with the first motor 17, and a first shaft L1. And a base member 18 to which the rotary shaft, the first motor 17, the gear box, the delivery mechanism 15 and the like are assembled are arranged. The rotation mechanism 14 is configured to rotate in the direction of arrow P in the drawing.

<About the delivery mechanism 15>
1 and 2, the delivery mechanism 15 includes a second motor 19 controlled by a rotation control unit 32 of the control device 8 described later, a gear box (not shown) that meshes with the second motor 19, and a twist wire 102. A pair of belt drive units 20 for feeding while being sandwiched are configured. The delivery mechanism 15 is configured such that the pair of belt drive units 20 perform a characteristic movement by the operation of the second motor 19 to deliver the twisted wire 102 downward.

<About a pair of belt drive part 20>
1 and 2, each of the pair of belt driving units 20 includes a pair of pulleys 21 arranged along the first axis L1 and a flat belt 22 that is loosely hung on the pair of pulleys 21. Is done. Each belt drive unit 20 has a driving pulley 21 connected to a gear box (not shown). When a driving force is transmitted to the driving pulley 21, the flat belt 22 rotates in the direction of arrow Q in the figure. Configured to do. The flat belt 22 is an endless belt having a sufficient width to sandwich the twisted wire 102, and the outer surface is formed in a state having a relatively large frictional resistance (a frictional resistance that does not affect the twisted wire 102). For example, the formation of a rubber surface or the like is effective). Further, the inner surface of the flat belt 22 is formed in a toothed state.

<About the arrangement of the pair of pulleys 21 and the delivery state of the flat belt 22>
1 and 2, the pair of pulleys 21 in the belt drive unit 20 on the left side in the drawing and the pair of pulleys 21 in the belt drive unit 20 on the right side in the drawing are in a staggered position along the first axis L1. Be placed. Moreover, it arrange | positions also in the position where the other party pulley 21 enters between a pair of pulleys 21 a little. When the pair of pulleys 21 are arranged at such positions, the flat belts 21 in a state where the twisted wire 102 is sandwiched are fed out in a state of substantially meandering on the first axis L1. In the case of feeding in a state of substantially meandering, the tightness of the twisted wires 102 between the flat belts 22 is significantly higher than in the case of non-meandering (when feeding straight down). If the tightness of the twisted wire 102 is high, it is possible to suppress the “force to return twist (spring back)” generated in the electric wire 101 (twist portion 107) when the electric wires 101 are twisted together. In other words, it is possible to suppress the force that the electric wire 101 tries to rotate.

<About the measuring section 16>
In FIG. 1 and FIG. 2, the measuring unit 16 is provided for measuring the twist line 102 sent out by the sending-out mechanism 15. The measuring scale unit 16 includes, for example, a sensor (not shown) for detecting the delivery amount. This sensor is connected to a scale control unit 33 (described later) of the control device 8. In the control device 8, for example, the operations of the first motor 17 and the second motor 19 are controlled based on the detected delivery amount. Since the twisted wire manufacturing apparatus 1 measures the twisted wire 102 by the measuring unit 16, it is possible to manufacture the twisted wire 102 with various lengths.

<About the action of the rotary delivery device 5>
1 and 2, when the first motor 17 and the second motor 19 are operated by the rotation control unit 32 of the control device 8 described later, the rotation delivery device 5 causes the rotation mechanism 14 to move to the arrow P at a preset number of rotations. The twist wire 102 is sent downward by a preset length along the first axis L1 by the delivery mechanism 15. By appropriately setting the rotation speed of the rotation mechanism 14 and the feed speed of the feed mechanism 15, twist portions 107 are formed on the twist wire 102 at a desired twist pitch. The twist line 102 fed downward by the delivery mechanism 15 passes through the pair of nozzles 6. The delivery state is as described above.

<About a pair of nozzles 6>
In FIG. 1 and FIG. 3, the pair of nozzles 6 are provided to guide the twist line 102 fed from the rotary feeding device 5. Such a pair of nozzles 6 is formed in a cylindrical shape into which the twisted wire 102 can be inserted. The pair of nozzles 6 are arranged so that the central axis thereof coincides with the first axis L1 and is aligned vertically. Of the pair of nozzles 6, the upper nozzle 6 is arranged below the rotary delivery device 5 with an interval as long as the tape winding TP as shown in FIG. 3 can be applied. Further, the lower nozzle 6 is arranged in accordance with the position of a winding cage 23 described later of the twisted wire winding device 7 (the arrangement in the drawing is an example). In addition, it arrange | positions so that the upper nozzle 6 and the lower nozzle 6 may leave. Specifically, the twist lines 102 as shown in FIG. 3 are arranged at intervals so as to be cut. In addition, a taper is formed at the opening edge of the pair of nozzles 6 (reference numeral omitted).

<About twisted wire winding device 7>
1 and 3, the twisted wire winding device 7 is provided for winding the twisted wire 102 fed from the rotary feeding device 5 with a predetermined diameter. Such a twisted wire winding device 7 includes a winding cage 23 that receives the twisted wire 102, and a cage rotation for rotating the winding cage 23 around the first axis L <b> 1 to apply a centrifugal force to the twisted wire 102. A mechanism 24 and a basket tilting mechanism 25 for tilting the winding cage 23 are provided.

<About the winding cage 23>
1 and 3, the winding cage 23 is provided as a portion that receives the twisted wire 102 (in other words, provided as a portion that pays out the twisted wire 102). In the present embodiment, a mesh-like cage member (colander-like member) is employed as the take-up cage 23 (this is an example, and may have a shape such as a talai shape). Further, as the take-up cage 23, one that can be appropriately changed according to the take-up size is adopted. Such a winding cage 23 includes a circular bottom portion 26, a circumferential wall 27 that rises upward from the edge of the bottom portion 26, a clamp 28 for holding a “twisted terminal” to be described later of the twisted wire 102, For example, it is formed in the shape shown in the figure. In this embodiment, the circumferential wall 27 is formed in a shape in which the opening edge is narrowed. However, for example, as shown in the modified example of FIG. 5, the circumferential wall 27 has a tapered shape in which the diameter gradually increases upward. It may be formed.

<About the conical portion 29>
1 and 3, the conical portion 29 is formed as a conical portion fixed on the bottom portion 26, or a portion in which the bottom portion 26 protrudes in a conical shape. The cone portion 29 is arranged such that the top cone top portion is aligned with the position of the first axis L1. Further, the bottom surface of the bottom cone is formed in a size matching the diameter of the bottom portion 26. In such a conical portion 29, a guide slope 30 is formed so that the twisted wire 102 slides down.

<About the basket rotation mechanism 24>
1 and 3, the cage rotating mechanism 24 is provided to rotate the winding cage 23 around the first axis L1 as described above. The basket rotation mechanism 24 includes a motor (not shown) controlled by a rotation control unit 32 of the control device 8 to be described later, and a rotating shaft 31 that is rotated by this motor. A bottom portion 26 of the winding cage 23 is fixed to the tip of the rotating shaft 31.

<About the basket tilting mechanism 25>
In FIG. 1 and FIG. 3, the basket tilting mechanism 25 is provided to make it easy for an operator to take out the wound twisted wire 102 from the winding basket 23. In this embodiment, the take-up cage 23 can be tilted toward the operator. In addition, when it is easy to take out even if it does not incline, the setting of the basket inclination mechanism 25 shall be arbitrary.

<About the action of the twisted wire winding device 7>
In FIG. 1, when a motor (not shown) is actuated by a rotation control unit 32 (to be described later) of the control device 8, in the twisted wire winding device 7, the winding cage 23 rotates at a preset rotation speed in the arrow R direction. What is important here is that the rotational speed in the direction of the arrow R in the twisted wire winding device 7 is set to be slightly smaller than the rotational speed in the direction of the arrow P in the rotary delivery device 5. By providing a difference between the number of revolutions in the twist wire take-up device 7 and the number of revolutions in the rotary feeding device 5, the feeding speed (feeding length per unit time) of the twist wire 102 in the rotary feeding device 5 is adjusted. By doing so, the portion indicated by the arrow S below the rotary delivery device 5 can be made a “part where the twist is slightly returned” (in other words, “a part where the twist is slightly unwound”). In the portion indicated by the arrow S, if twisting is performed by releasing the “force to return twist (spring back)” generated when the wires 101 are twisted together, the twist pitch of the twisted wire 102 can be stabilized, Of course, the state after winding of the twisted wire 102 can be stabilized.

  The twisted wire 102 in the winding cage 23 is guided by the inclined surface 30 of the conical portion 29 and is drawn to the circumferential wall 27 of the winding cage 23 by the centrifugal force generated by the rotation.

  The twisted wire take-up device 7 and the rotary feed device 5 stop when the twisted wire 102 is sent out by a preset length (up to the target wire length).

<About the control device 8>
1 to 3, the control device 8 is a known PLC, for example, and is configured to be able to control the entire twisted wire manufacturing device 1. Such a control device 8 includes a rotation control unit for rotating the take-up cage 23 in the same direction as the rotary feed device 5 and controlling the rotational speed of the rotary feed device 5 and the take-up cage 23 to be different. 32 is provided. The control device 8 is also provided with a scale control unit 33 related to the measurement of the twist line 102.

<About manufacturing procedure of twisted wire 102>
Based on the above configuration and structure, a manufacturing procedure of the twisted wire 102 will be described with reference to FIGS. 1, 3, and 4.

  In FIG. 1, first, (1) two electric wires 101 are pulled out from two electric wire reels 2 respectively. Next, (2) The two electric wires 101 are passed through the rotation prevention device 3 and the partition 4 while manually bending the two electric wires 101 to form the electric wire bending portion 12. Next, (3) the terminal portions of the two electric wires 101 are sandwiched between the pair of belt driving units 20 of the rotary feeding device 5 and a switch (not shown) is turned on to perform “preparation stage twisting”. The “preparation stage twisting” is for making a “twisting terminal” of about 50 cm, for example. After the “twisting terminal” of the twisted wire 102 is sent from the rotary feeding device 5, (4) the switch is turned off once. Then, tape winding TP is applied to the “twisted terminal”. Next, (5) the operator manually puts the “twisted terminal” into the winding cage 23 and holds the “twisted terminal” with the clamp 28. This completes the “preparation stage twisting”. (6) The switch is turned on again, and this time "auto twist" is performed up to the target wire length.

  In FIG. 3, (7) when “automatic twisting” to the target line length is completed, the twisted wire 102 is tape-wrapped TP at the upper and lower positions of the pair of nozzles 6, and the upper nozzle 6 and the lower nozzle 6 For example, a cutting means such as scissors 34 is inserted between them. Finally, (8) when the winding cage 23 is tilted toward the operator side and the twisted wire 102 taken up by the winding cage 23 is taken out, the production of the twisted wire 102 is completed. The twist line 102 is manufactured in a state as shown in FIG.

  In FIG. 4, the twisted wire 102 is manufactured so that the “twisted terminal” of the reference numeral 35 is the lowest layer and the “twisted terminal” of the reference numeral 36 is in front. If manufactured in such a state, of course, the work at the site where the twisted wire 102 is used becomes easy.

<About the effect of the twisted wire manufacturing apparatus 1>
As described above with reference to FIGS. 1 to 5, the twisted wire manufacturing apparatus 1 of the present invention twists the two electric wires 101 drawn out from the two electric wire reels 2, and after this, slightly The twisted wire 102 is taken out to the winding cage 23 while being untwisted, and the device is a device for automatically performing most of the production of the twisted wire 102. Compared with the case where a very long twisted wire is manufactured by using and is manually rolled, it can be seen that workability can be remarkably improved. That is, according to this invention, there exists an effect that the twist wire | line manufacturing apparatus 1 with high workability | operativity can be provided.

  Further, according to the twisted wire manufacturing apparatus 1 of the present invention, the rotary feeding device 5 used for twisting the two electric wires 101 has the feeding mechanism 15 for feeding the twisted wire 102. Each of the pair of belt drive units 20 includes a pair of pulleys 21 arranged along the feed direction of the twist wire 102, and a pair of pulleys 21 arranged to feed the twist wire 102 therebetween. A pair of pulleys 21 and a pair of pulleys 21 arranged in a zigzag position (in other words, the other pulley 21 is located between the pulleys 21). The flat belts 22 in a state where the twisted wire 102 is sandwiched are meandered (because they are arranged so as to be slightly inserted). It can be. By feeding out by such meandering, the degree of adhesion of the twisted wires 102 between the flat belts 22 can be increased, and as a result, the effect of suppressing the rotation of the twisted wires 102 during feeding can be achieved.

  In addition, according to the twisted wire manufacturing apparatus 1 of the present invention, the rotary feeding device 5 has the measuring unit 16, so if the measuring unit 16 performs the feeding while measuring, the twisted wire 102 has a desired length. The effect that it can be manufactured is produced.

  In addition, according to the twisted wire manufacturing apparatus 1 of the present invention, the rotation prevention device 3 is included in the structure in connection with the production of the twisted wire 102. Therefore, the pair of feed rollers 9 and the pair of rotation prevention rollers 10 in the rotation prevention device 3 are included. Is placed in a predetermined state so that the bent shape of the wire bending portion 12 formed in a substantially L-shape (or a substantially square shape) is maintained, the back tension is applied to the two wires 101. In addition to being able to be hung, it is possible to cancel the “twisting force” generated in the two electric wires 101 during twisting. This eliminates the need for a dedicated device or a complicated device for applying back tension or canceling the force, and as a result, simplifies the configuration of the twisted wire manufacturing apparatus 1 and reduces the size of the apparatus. There is an effect that it can be achieved.

  Further, according to the twisted wire manufacturing apparatus 1 of the present invention, since the tension adjusting unit 11 is provided, there is an effect that the magnitude of the back tension necessary for twisting can be adjusted.

  Further, according to the twisted wire manufacturing apparatus 1 of the present invention, the twisted wire winding device 7 for winding the twisted wire 102 fed from the rotary feeding device 5, the twisted wire winding device 7, and the rotary feeding device 5. Therefore, the rotational speed and the winding speed of the rotary feeding device 5 are rotated while the winding cage 23 in the twisted wire winding device 7 is rotated in the same direction as the rotary feeding device 5. The rotational speed of the take-up basket 23 can be made different. As a result, even when a force (spring back) is generated to twist the two electric wires 101 back to the original state, this force is twisted. The effect that it can open appropriately before winding of 102 is produced. As a result, a dedicated device and a complicated device for releasing the force can be eliminated, and as a result, the configuration of the twisted wire manufacturing apparatus 1 can be simplified. Further, the release of the force produces an effect that a uniform twist pitch can be formed.

  Further, according to the twisted wire manufacturing apparatus 1 of the present invention, since the basket tilting mechanism 25 is provided, if the winding cage 23 is tilted toward the operator side, the wound twisted wire 102 can be easily taken out. The effect that you can

  Further, according to the twisted wire manufacturing apparatus 1 of the present invention, since the space required for manufacturing the twisted wire 102 is ensured in the vertical direction, the horizontal direction (left-right direction) device as compared with the conventional example is provided. There is an effect that the overall length can be remarkably shortened.

  Embodiment 2 will be described below with reference to the drawings. FIG. 6 is a schematic view showing another modification of the twisted wire winding device. FIG. 7 is a schematic view showing the operation of the twisted wire winding device of FIG. FIG. 8 is related to the twisted line of FIG. 7, (a) is a schematic diagram showing a state in the winding cage, and (b) is a schematic diagram showing a state after being taken out from the winding cage. Note that the same components as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  The purpose of the second embodiment is to solve the following problems (the same applies to the third to seventh embodiments). In other words, if the twisted wire 102 that has been wound is very long, there is a risk that kinks will occur if the twisted wire 102 is changed from the wound state to the expanded state at the work site. To do. The reason for the occurrence of kinks is that, when the twisted wire 102 is wound up, one twist is entered per one turn of winding, and the twisted wire is forced to spread in the state in which this twist has entered. The occurrence of kinks may lead to a reduction in quality. In the case of a short twist line, the terminal rotates and the kink is eliminated when it is spread. However, in the case of the very long twist line 102, the kink is generated because the fins cannot be removed.

  In order to eliminate the kink, it is effective to make the twisted wire 102 “8-shaped winding”. In this embodiment, a structure capable of realizing the “8-shaped winding” is provided. The present embodiment is positioned as a modified example of the twisted wire winding device 7 of the first embodiment (assuming the same applies to the third to seventh embodiments).

<About twisted wire winding device 37>
In FIG. 6, the twisted wire winding device 37 is provided for winding the twisted wire 102 fed from the rotary feeding device 5 into a “8” shape with a predetermined diameter. Such a twisted wire winding device 37 includes a winding cage 38 that receives the twisted wire 102, a cage rotating mechanism that rotates the winding cage 38 and applies a centrifugal force to the twisted wire 102, and a winding cage 38. And a sorting mechanism 39 for sorting the twisted wire 102 vertically in the winding basket 38. The sorting device 39 is provided in order to realize “twisted figure 8” of the twisted wire 102.

<About the winding basket 38>
In FIG. 6, the winding cage 38 is provided as a part that receives the twisted wire 102. In this embodiment, a mesh-like cage member is employed as the take-up cage 38 (assumed as an example). Further, as the take-up basket 38, one that can be appropriately changed according to the take-up size is adopted. Such a winding cage 38 includes a circular bottom 40, a circumferential wall 41 rising upward from the edge of the bottom 40, a clamp 42 for holding a twisted end of the twisted wire 102, and a cone provided inside the cage. For example, it has a shape shown in the figure.

<About the sorting device 39>
6 and 7, the sorting device 39 includes an air cylinder (not shown), one or a plurality of arms 44 provided in the middle of the conical portion 43 and driven by the air cylinder, a bottom 40 and a circumferential wall 41. A lower winding portion 45 disposed in the portion and an upper winding portion 46 disposed in the middle of the circumferential wall 41 are configured. The upper winding portion 46 is formed in a shape like a partition plate extending in an arc shape. Such a sorting device 39 is configured such that the arm 44 is opened and closed substantially up and down by an air cylinder once per winding of the twisted wire 102. In the present embodiment, it is assumed that the driving of the arm 44 is controlled using a position sensor (not shown) (this is an example).

  7A shows that the twist line 102 is guided downward, FIG. 7B shows that the twist line 102 is guided upward, FIG. 7C shows that the twist line 102 is guided downward, and so on. Taking is done. Inside the basket, the twisted wire 102 is wound into a “figure 8” in a state (image) as shown in FIG. Arrows T1 to T3 in FIG. 8 (a) indicate the rubber stopper portion after winding (assuming that the rubber stopper is an example), take out the twisted wire 102 wound up in "8", Later, when the upper bundle portion 47 and the lower bundle portion 48 are expanded to the left and right with the rubber stopper portion T1 as the center, a state as shown in FIG. 8B is obtained.

<About effect>
As described above with reference to FIGS. 6 to 8, “8-shaped winding” can be realized by using the twisted wire winding device 37. Thereby, generation | occurrence | production of a kink is suppressed and there exists an effect that a quality fall can be prevented as a result.

  Embodiment 3 will be described below with reference to the drawings. FIG. 9 is a schematic view showing another modification of the twisted wire winding device. Note that the same components as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

<About twisted wire winding device 49>
In FIG. 9, the twisted wire winding device 49 is provided to wind the twisted wire 102 fed from the rotary feeding device 5 into a “8” shape with a predetermined diameter. Such a twisted wire winding device 49 includes a winding cage 50 that receives the twisted wire 102, a cage rotating mechanism 51 that rotates the winding cage 50 to apply centrifugal force to the twisted wire 102, and a winding cage. 50 is configured to include a basket tilting mechanism for tilting 50 and a sorting section 52 for sorting the twisted wire 102 vertically in the winding basket 50. The sorting unit 52 is provided to realize the “eight-character winding” of the twisted wire 102. Further, a speed change to be described later of the cage rotating mechanism 51 is also necessary to realize “eight-character winding”.

<About the winding basket 50>
In FIG. 9, the winding cage 50 is provided as a portion that receives the twisted wire 102. In the present embodiment, a mesh-shaped cage member is employed as the winding cage 50 (assumed as an example). Further, as the take-up basket 50, one that can be appropriately changed according to the take-up size is adopted. Such a winding basket 50 includes a circular bottom 53, a circumferential wall 54 rising upward from an edge of the bottom 53, and a clamp 55 for holding a twisted end of the twisted wire 102, for example, It is formed into a shape.

<Regarding section 53>
In FIG. 9, the dividing portion 53 includes a conical portion 56 in which the angle of the inclined surface changes midway, and a dividing projection 57 that protrudes from the middle of the inclined surface of the conical portion 56. The dividing protrusion 57 is a protrusion for dividing the twisted wire 102 into the upper bundled portion 58 and the lower bundled portion 59. In the division, the winding wire 50 is taken up once per turn of the twisted wire 102. This is done by increasing or decreasing the rotational speed. When the rotational speed of the winding basket 50 is increased, the winding is accelerated, so that the twisted wire 102 is caught by the dividing projection 57 before being expanded outward by centrifugal force, and is thus wound as the upper bundle portion 58. On the other hand, when the rotational speed of the winding basket 50 is slowed, the twisted wire 102 is sufficiently expanded outward, so that the lower bundle portion 59 is wound on the bottom 53 side.

<About effect>
As described above with reference to FIG. 9, “8-shaped winding” can be realized by employing the twisted wire winding device 49. Thereby, generation | occurrence | production of a kink is suppressed and there exists an effect that a quality fall can be prevented as a result.

  Embodiment 4 will be described below with reference to the drawings. FIG. 10 is a schematic view showing another modification of the twisted wire winding device. Note that the same components as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

<About twisted wire winding device 60>
In FIG. 10, the twisted wire winding device 60 is provided for winding the twisted wire 102 fed from the rotary feeding device 5 into a “8” shape with a predetermined diameter. Such a twisted wire winding device 60 includes a winding cage 61 that receives the twisted wire 102, a cage rotating mechanism 62 that rotates the winding cage 61 to apply a centrifugal force to the twisted wire 102, and a winding cage. A cage raising / lowering and tilting mechanism 63 for raising and lowering 61 is provided, and a section 64 for dividing the twisted wire 102 in the winding basket 61 is provided. The sorting unit 64 is provided to realize the “eight-character winding” of the twisted wire 102. Further, raising and lowering of the winding cage 61 is also necessary to realize “eight-character winding”.

<About the winding basket 61>
In FIG. 10, the winding cage 61 is provided as a part that receives the twisted wire 102. In the present embodiment, a mesh-shaped cage member is employed as the winding cage 61 (assumed as an example). Further, as the take-up cage 61, one that can be appropriately changed according to the take-up size is adopted. Such a winding cage 61 has a circular bottom portion 65, a circumferential wall 66 rising upward from an edge portion of the bottom portion 65, and a clamp 67 for holding a twisted end of the twisted wire 102. It is formed into a shape.

<Regarding section 64>
In FIG. 10, the partitioning portion 64 includes a columnar portion 68 provided on the bottom portion 65, a conical portion 69 integrated with the upper end of the columnar portion 68, and a partitioning protrusion 70 protruding from the middle of the side surface of the columnar portion 68. The dividing protrusion 70 is a protrusion for dividing the twisted wire 102 into the upper bundle portion 71 and the lower bundle portion 72. In the division, the winding basket 61 is provided once per winding of the twisted wire 102. It is done by raising and lowering.

<About effect>
As described above with reference to FIG. 10, “8-shaped winding” can be realized by using the twisted wire winding device 60. Thereby, generation | occurrence | production of a kink is suppressed and there exists an effect that a quality fall can be prevented as a result.

  Embodiment 5 will be described below with reference to the drawings. FIG. 11 is a schematic view showing another modification of the twisted wire winding device. Note that the same components as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

<About twisted wire winding device 73>
In FIG. 11, the twisted wire winding device 73 is provided to wind the twisted wire 102 fed from the rotary feeding device 5 into a “8” shape with a predetermined diameter. Such a twisted wire winding device 73 includes a winding cage 74 that receives the twisted wire 102, a cage rotating mechanism 75 that rotates the winding cage 74 and applies a centrifugal force to the twisted wire 102, and a winding cage. A basket tilting mechanism 76 for tilting 74 and a sorting portion 77 for sorting the twisted wire 102 vertically in the winding basket 74 are configured. The sorting unit 77 is provided to realize “twisted figure 8” of the twisted wire 102.

<About the winding basket 74>
In FIG. 11, the winding cage 74 is provided as a portion that receives the twisted wire 102. In the present embodiment, a mesh-shaped cage member is employed as the winding cage 74 (assumed as an example). Further, as the take-up basket 74, one that can be appropriately changed according to the take-up size is adopted. Such a winding cage 74 has a circular bottom 78, a circumferential wall 79 rising upward from an edge of the bottom 78, and a clamp 80 for holding a twisted end of the twisted wire 102, for example, It is formed into a shape.

<About the sorting section 77>
In FIG. 11, the partitioning portion 77 includes a columnar portion 81 provided on the bottom portion 78, a conical portion 82 integrated with the upper end of the columnar portion 81, a partitioning projection 83 protruding from the middle of the side surface of the columnar portion 81, and the partitioning portion 77. A projection lifting mechanism (not shown) that moves the projection 83 up and down is provided. The dividing protrusion 83 and the protrusion raising / lowering mechanism are protrusions for dividing the twisted wire 102 into the upper bundled portion 84 and the lower bundled portion 85. In the division, the dividing wire is divided once per winding of the twisted wire 102. This is done by raising or lowering the projection 83.

<About effect>
As described above with reference to FIG. 11, “8-shaped winding” can be realized by adopting the twisted wire winding device 73. Thereby, generation | occurrence | production of a kink is suppressed and there exists an effect that a quality fall can be prevented as a result.

  Embodiment 6 will be described below with reference to the drawings. FIG. 12 shows the present invention. 13 to 15 are schematic views showing the operation of the twisted wire winding device of FIG. Note that the same components as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

<About twisted wire winding device 151>
In FIG. 12, a twisted wire winding device 151 is provided for winding the twisted wire 102 into a “8” shape with a predetermined diameter. Such a twisted wire winding device 151 includes a winding cage 152 that receives the twisted wire 102, a cage rotating mechanism 153 that rotates the winding cage 152, and a cage that tilts the winding cage 152. A tilting mechanism 154 and a sorting device 155 for sorting the twisted wire 102 in the winding cage 152 are provided. The sorting device 155 is provided in order to realize “8-shaped winding” of the twisted wire 102.

<About the winding basket 152>
12 to 15, the winding cage 152 is provided as a portion that receives the twisted wire 102. In this embodiment, a mesh-shaped cage member is employed as the take-up cage 152 (assumed as an example). Further, as the take-up basket 152, one that can be appropriately changed according to the take-up size is adopted. Such a winding cage 152 is provided inside the cage, an elliptical bottom portion 156, a peripheral wall 157 rising upward from the edge of the bottom portion 156, a clamp (not shown) for holding the twisted end of the twisted wire 102, and the like. The two conical portions 158 are formed, for example, in the shape shown in the figure.

<About the sorting device 155>
12 to 15, the sorting device 155 includes slide rails 159 and 160 for sliding the winding cage 152 back and forth and right and left, and a drive mechanism (not shown). In such sorting by the sorting device 155, the winding cage 152 is slid back and forth and left and right so that the twist wire 102 is wound once around the “8-shape” around the two conical portions 158, and thereafter, one of the cones One step is to manually or automatically move the twist line 102 of the part 158 to the twist line 102 of the other conical part 158, and this step is repeated.

<About effect>
As described above with reference to FIGS. 12 to 15, “8-shaped winding” can be realized by using the twisted wire winding device 151. Thereby, generation | occurrence | production of a kink is suppressed and there exists an effect that a quality fall can be prevented as a result.

  Embodiment 7 will be described below with reference to the drawings. FIG. 16 is a schematic view showing another modification of the twisted wire winding device. Note that the same components as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

<About twisted wire winding device 161>
In FIG. 16, a twisted wire winding device 161 is provided for winding the twisted wire 102 into a “8” shape with a predetermined diameter. Such a twisted wire winding device 161 includes a winding cage 162 that receives the twisted wire 102, a cage rotating mechanism 163 that rotates the winding cage 162, and a basket that tilts the winding cage 162. A tilting mechanism 164 and a sorting device 165 for sorting the twisted wire 102 in the winding basket 162 are provided. The sorting device 165 is provided in order to realize “8-shaped winding” of the twisted wire 102.

<About the winding basket 162>
In FIG. 16, the winding cage 162 is provided as a part that receives the twisted wire 102. In the present embodiment, a mesh-like cage member is employed as the take-up cage 162 (assumed as an example). Further, as the take-up basket 162, one that can be appropriately changed according to the take-up size is adopted. Such a winding cage 162 is provided inside the cage, an elliptical bottom portion 166, a peripheral wall 167 rising upward from the edge of the bottom portion 166, a clamp (not shown) for holding the twisted end of the twisted wire 102, and the like. The two conical portions 168 are formed, for example, in the illustrated shape.

<About sorting device 165>
In FIG. 16, the sorting device 165 includes a nozzle 169 that regulates the feeding direction of the twist wire 102 and a nozzle moving mechanism (not shown) that moves the nozzle 169 in accordance with the rotation of the winding cage 162. In such sorting by the sorting device 165, the nozzle 169 is moved so that the twist line 102 is wound once around the “eight-shape” around the two conical portions 168, and thereafter, as in the sixth embodiment, One step is to manually or automatically move the twist line 102 of the conical portion 168 to the twist line 102 of the other conical portion 168, and this step is repeated.

<About effect>
As described above with reference to FIG. 16, “8-shaped winding” can be realized by adopting the twisted wire winding device 161. Thereby, generation | occurrence | production of a kink is suppressed and there exists an effect that a quality fall can be prevented as a result.

  In addition, the present invention can of course be modified in various ways within the scope not changing the gist of the present invention.

  DESCRIPTION OF SYMBOLS 1 ... Twist wire manufacturing apparatus, 2 ... Electric wire reel, 3 ... Auto-rotation prevention device, 4 ... Partition, 5 ... Rotation feeding device, 6 ... Nozzle, 7 ... Twist wire winding device, 8 ... Control device, 9 ... Sending roller, DESCRIPTION OF SYMBOLS 10 ... Auto-rotation prevention roller, 11 ... Tension adjustment part, 12 ... Electric wire bending part, 13 ... Electric wire passage part, 14 ... Rotation mechanism, 15 ... Feeding mechanism, 16 ... Measuring part, 17 ... First motor, 18 ... Base member , 19 ... second motor, 20 ... belt drive unit, 21 ... pulley, 22 ... flat belt, 23 ... winding basket, 24 ... cage rotation mechanism, 25 ... cage tilting mechanism, 26 ... bottom part, 27 ... circumferential wall, 28 ... Clamp, 29 ... Conical part, 30 ... Slope, 31 ... Rotating shaft, 32 ... Rotation control part, 33 ... Measuring scale control part, 34 ... Scissors, 35, 36 ... Twist terminal, DESCRIPTION OF SYMBOLS 101 ... Electric wire, 102 ... Twist wire, 103 ... One end, 104 ... Other end, 105 ... Middle, 107 ... Twist part, 108 ... Terminal metal fitting, L1 ... First axis, L2 ... Second axis, L3, L4 ... Roller Alignment axis, TP ... Tape winding

Claims (3)

Comprising a rotary feeding device and a partition arranged on the electric wire supply side from the rotary feeding device,
A twist portion is formed by twisting a plurality of electric wires between the partition and the rotary delivery device,
The partition has an electric wire passage portion for allowing the electric wire to pass along a first axis extending in a twist wire feeding direction,
The rotary delivery device sends a rotation mechanism for rotating itself about the first axis and a twist line formed with the twist portion to the side away from the partition along the first axis. And a delivery mechanism of
Such a twisted wire manufacturing apparatus further includes a twisted wire winding device for winding up the twisted wire fed along the first axis from the rotary feeding device, and a control device. ,
The twisted wire winding device includes a winding cage that receives the twisted wire, and a cage rotation mechanism that rotates the winding cage around the first axis to apply a centrifugal force to the twisted wire. And
The control device has a rotation control unit capable of differentiating the rotation speed of the rotary feeding device and the rotation speed of the winding basket while rotating the winding cage in the same direction as the rotary feeding device. A twisted wire manufacturing apparatus characterized by that. The twisted wire manufacturing apparatus according to claim 1,
The twist wire winding device further includes a basket tilting mechanism for facilitating taking out the twisted wire wound up from the winding cage. In the twisted wire manufacturing apparatus according to claim 1 or 2,
The twisted wire manufacturing apparatus is characterized in that the partition, the rotary feeding device, and the twisted wire winding device are arranged in a state of being arranged in an upper, middle, and lower direction.

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