The present invention relates to an electric wire straightening device for correcting a twist generated around an electric wire axis.
For example, when manufacturing a wire harness and the like, electric wires are withdrawn from an accommodation place such as electric reel by a desired length (see, for example, Patent Document 1). In the technique described above, the electric wire is passed between a plurality of staggered rollers, so that bending and the like of the electric wire are corrected.
[Patent Document]
Here, for example, when withdrawing an electric wire from an accommodation place accommodating the electric wire in a state of being wound like electric wire reel and the like, twist may occur around an axis of the electric wire depending on the way of withdrawing out. The technique described in Patent Document 1 may not completely correct such twist.
Accordingly, the present invention focuses on the above-mentioned problem, and is to provide an electric wire straightening device capable of correcting twist generated around the axis of the electric wire.
In order to solve the above problem, it is characterized that an electric wire straightening device includes: an electric wire holding part provided rotatably around an axis of an electric wire for holding the electric wire having been withdrawn from a predetermined accommodation place so as to further withdraw the electric wire toward a side opposite to the accommodation place and; a rotation driving part for rotating the electric wire holding part in an twisting back direction opposite to a twist around an axis of the electric wire occurring in the electric wire between the accommodation place and the electric wire holding part by further withdrawing the electric wire from the electric wire holding part.
In the electric wire straightening device of the present invention, since the electric wire holding part is provided rotatably around the axis of the electric wire to be held, the electric wire holding part rotates in the twist back direction opposite to the direction of twist around the axis of the electric wire. This rotation of the wire holding part allows the twist around the axis of the electric wire to be corrected.
Hereinafter, one embodiment of the present invention will be described.
The electric wire cutting system 1 shown in
In the present embodiment, the electric wire W1 is withdrawn from the electric wire reel WR1 along a center axis direction D11 of the electric wire reel W1. At this time, the electric wire W1 experiences twist in a twist direction D12 of the electric wire reel WR1. The electric wire straightening device 10 is to correct the twist of the electric wire W1 just in front of preceding scale cutter 20. This electric wire straightening device 10 will be described later in detail.
The scale cutter 20 is an apparatus for withdrawing from the electric wire straightening device 10 and cutting the electric wire W1. The scale cutter 20 is provided with an electric wire pulling part 21 and a scale cutting part 22. The electric wire pulling part 21 is a part for holding and pulling an end portion of the electric wire W1 in a withdrawal direction D111 from the electric wire straightening device 10 so as to pull out the electric wire W1. The scale cutting part 22 is a part, while measuring the withdrawal length of the electric wire W1, cutting the electric wire W1 when the measurement result reaches a preset target withdrawal length.
As described above, the electric wire straightening device 10 is a device for correcting the twist of the electric wire W1 withdrawn out from the electric wire reel WR1, includes a support frame 11, an electric wire holding part 12, and a rotation driving portion 13.
The support frame 11 is a rectangular parallelepiped portion fixed to a not-shown device frame, and the wire holding part 12 is rotatably supported on one end side thereof, and the rotation driving portion 13 is fixed to the other end side.
The electric wire holding part 12 holds the electric wire W1 withdrawn out from the electric wire reel WR1 so as to be further pulled out to the opposite side of the wire reel WR1 by the electric wire pulling part 21 of the scale cutter 20. The electric wire holding part 12 is formed in a substantially cylindrical shape, and the electric wire W1 is held so as to pass through a center of the electric wire holding part 12 and is pulled out in the withdrawal direction D111 by the electric wire pulling part 21. Then, the electric wire holding part 12 is rotatably held by the supporting frame 11 about the axis of the electric wire W1 passing through the center thereof. Further, an inlet port 121 for the wire W1 is provided at an end on the side of the wire reel WR1 of the wire holding part 12 and an outlet port 122 is provided at the other end portion. On the downstream side of the wire holding part 12 in the withdrawal direction D111, a scale cutting part 22 of the scale cutter 20 is arranged.
In this wire holding part 12, a holding mechanism 123 for the electric wire W1 is provided on the downstream side of the inlet 121 in the withdrawal direction D111.
Inside the holding mechanism 123, there is provided a fixed rotation shaft 123a and a movable rotation shaft 123b crossing the withdrawal direction D111. The fixed rotation shaft 123a is fixed to a case 123c of the holding mechanism 123, and the movable rotation shaft 123b is fixed to the case 123c movably along a guide slit 123c-1 provided in the case 123c. The guide slit 123c-1 is provided guiding the movable rotation shaft 123b in a contact/separation direction D13 with respect to the fixed rotation shaft 123a. Further, the movable rotation shaft 123b is biased toward the fixed rotation shaft 123a by a spring 123d provided in the case 123c. And around the fixed rotation shaft 123a and the movable rotation shaft 123b a pair of electric wire clamping rollers 123e are rotatably attached. As the spring 123d urges the movable rotation shaft 123b as described above, the outer periphery of the wire clamping roller 123e of the movable rotation shaft 123b is pressed against the outer periphery of the wire clamping roller 123e of the fixed rotation shaft 123a.
The electric wire W1 taken in from the inlet 121 passes through between the outer peripheries of the pair of wire clamping rollers 123e, so that it can be clamped between the outer peripheries of the pair of wire clamping rollers 123e. Since the pair of wire clamping rollers 123e is rotatable, the electric wire W1 is clamped in a withdrawable manner in the withdrawal direction D111. Further, in the present embodiment, the inlet 121 is formed into a wide mouth shape spreading from the inside to the outside. Then, inlet 121 is provided so that the center thereof is positioned on the central axis of the cylindrical electric wire holding part 10, and a clamping region 123e-1 of the electric wire W1 by the pair of electric wire clamping rollers 123e is also positioned on the central axis of the electric wire holding part 10. That is, in the present embodiment, the electric wire W1 is configured to be held on the axis passing through the center of the inlet 121.
In the electric wire straightening device 10 shown in
At this time, although the rotation of the servomotor 131 is controlled by a control circuit (not shown), the servomotor 131, under the control, rotates the electric wire holding part 12 in the following direction. That is, the servomotor 131 rotates so as to rotate the wire holding part 12 in the twisting back direction D14 opposite to the twist around the axis of the electric wire W1 occurring in the electric wire W1 from the electric wire reel WR up to the electric wire holding part 12 by further pulling out from the electric wire holding part 12.
As described above, when the electric wire W1 is pulled out from the electric wire reel WR1, twist occurs in the winding direction D12 of the electric wire W1 in the electric wire reel WR1 around the axis the electric wire W1. The above-mentioned twisting back direction D14 which is the rotation direction of the wire holding part 12 is an opposite direction to the winding direction D12 of the electric wire W1.
Here, in the scale cutting part 22 of the scale cutter 20, as described above, the target withdrawal length is set in advance at the time of the electric wire W 1 being pulled out to cut. This setting is set by an operational input by an operator, but in the present embodiment, the target withdrawal length, which is the set value at this time, is notified from the scale cutting part 22 of the scale cutter 20 to the rotation driving part 13. In the rotation driving part 13, the control circuit of the servomotor 131 acquires the target withdrawal length via this notification, and controls the servomotor 131 so as to rotate the wire holding part 12 at a number of rotations based on this target withdrawal length.
When the electric wire W 1 is pulled out from the electric wire reel WR1, every time the wire W1 is pulled out for one turn of the electric wire reel WR1, the electric wire W1 becomes twisted around the axis once. That is, how many twists are produced on the wire W1 when the wire W1 is pulled out depends on the withdrawal length of the wire W1.
In the present embodiment, at an initial stage where a distal end of the electric wire W1 withdrawn out from the electric wire reel WR1 is passed through the electric wire holding section 12 of the electric wire straightening device 10 and the scale cutting part 22 of the scale cutter 20, and is set to the wire withdrawing part 21, the operator pulls out the electric wire W1 while correcting the twist. In this initial stage, the twist hardly occurs in the electric wire W1 from the electric wire reel WR1 to the electric wire holding part 12.
Thereafter, in the scale cutter 20, though withdrawal by the target withdrawal length from the wire holding part 12 and cutting are repeatedly performed, but each time the withdrawal by the scale cutter 20 occurs once, new twist corresponding to the target withdrawal length occurs in the electric wire W1 between the electric wire reel WR1 and the electric wire holding part 12. As described above, how many twists occur in the electric wire W1 depends on the withdrawal length of the electric wire W1. In the present embodiment, every time the withdrawal by the scale cutter 20 occurs once, rotating the electric wire holding part 12 at the number of rotations based on the target withdrawal length corresponding to one time withdrawal length corrects the twist of the electric wire corresponding to one time withdrawal length.
Here, how the servomotor 131 is controlled by the control circuit for rotating the electric wire holding part 12 in this way, although not specified in the present embodiment, may be one of the following three types of control.
First, the first control that can be performed by the control circuit of the servomotor 131 in the rotation driving part 13 will be explained. The first control, based on the target withdrawal length at the time of withdrawing and cutting at the previous time, the twist of the electric wire W1 at the previous time is corrected before twisting and cutting are performed at the present time. In this first control, the control circuit of the servomotor 131 obtains the target withdrawal length when the disconnection has been made from the scale cutter 20 at the previous time. Then, before performing scale and cutting at the present time the control circuit controls the rotation of the servomotor 131 so as to rotate the electric wire holding part 12 based on the target withdrawal length. According to this first control, the withdrawal and cutting of the electric wire W1 by the scale cutter 20 starts every time in a condition that the electric wire W 1 is not twisted, and the twist corresponding to one target withdrawal length occurs at a state where withdrawal and cutting for one time is completed. The twist is corrected before withdrawal and cutting at next time.
Next, a second control will be described. The second control is that before the withdrawal and cutting is performed at the present time, anticipating the twist occurring in the electric wire W1 at the present time, before this withdrawal and cutting is performed at the present time, the electric wire W1 is preliminarily twisted in the opposite direction to the twist to occur at the present time at the number of rotations based on the target withdrawal length. In this second control, the control circuit of the servomotor 131 preliminarily obtains the target withdrawal length at the present time from the scale cutter 20. Then, before the withdrawal and cutting is performed at the present time, the control circuit controls the rotation of the servomotor 131 to rotate the electric wire holding part 12 at the number of rotations based on the target withdrawal length. According to this second control, withdrawal and cutting of the electric wire W1 by the scale cutter 20 starts in a state in which the electric wire W1 is twisted in the reverse direction in advance, and withdrawer and cutting by one time is performed so as to correct the preliminary twist. Then, when withdrawal and cutting is completed, the electric wire W1 is in a state where there is no twist.
Next, the third control will be described. The third control performs every time withdrawal and cutting while twisting the electric wire W1 in a direction opposite to the twist occurring at the time at the number of rotations based on the target withdrawal length. Also in this third control, the control circuit of the servomotor 131 obtains the target withdrawal length of the present time in advance from the scale cutter 20. Then, the control circuit starts withdrawing the electric wire W1 and rotates the electric wire holding part 12, and controls the rotation of the servomotor 131 so that the number of rotations till the electric wire W1 is withdrawn out to the target withdrawal length is equal to the number of rotations based on the current target withdrawal length. According to this third control, withdrawal and cutting of the electric wire W1 by the scale cutter 20 starts in a state in which no twist occurs in the electric wire W1, and one withdrawal and cutting is carried out while correcting the twist during the process. Therefore, there is no twist in the electric wire W1 even at a stage that withdrawal and cutting is completed.
In the electric wire straightening device 10 of the present embodiment described above, the wire holding part 12 is provided rotatably around the axis of the supporting electric wire W1, and by the function of the rotation driving part 13 the wire holding part 12 rotates in the twisting back direction D14 opposite to twisting direction about the axis of the wire holding part 12. This rotation of the electric wire holding part 12 can correct the twist around the axis of the electric wire W1.
Further, in the present embodiment, since the electric wire W1 is configured to be withdrawn along the central axis direction D11 of the electric wire reel WR1, the electric wire reel WR1, that tends to be heavy to rotate, can be withdrawn without substantially rotating.
Here, as a configuration for withdrawing out the electric wire W1 from the electric wire reel WR1, unlike the present embodiment, for example, the electric wire W1 is withdrawn out in the tangential direction of the outer periphery of the electric wire reel WR1, and supports the electric wire reel WR1 so as to be able to rotate in accordance with the rotation. However, because the configuration for rotatably supporting the electric wire reel WR1 that tends to be heavy to rotate as described above is cumbersome, the facility cost may increase in such a configuration. Furthermore, in the case of constructing a system that withdraws from the electric wire reel WR1 and cuts the electric wire W1, there is a risk of further increasing the equipment cost in the configuration in which the electric wire reel WR1 is rotatably supported.
On the other hand, in this embodiment in which the wire W1 can be pulled out without substantially rotating the wire reel WR1, since the electric wire reel WR1 needs only be placed on the installation place, the facility cost can be reduced. On the other hand, when the electric wire W1 is pulled out along the central axis direction D11 of the electric wire reel WR1, at the time of withdrawing out, the twist occurs along the winding direction D12 of the electric wire W1 on the reel WR1 around the axis of the electric wire W1. According to the electric wire straightening device 10 in this embodiment, the wire holding part 12 rotates in the direction opposite to the winding direction D12 as the twisting back direction D14, so as to correct the twist of the electric wire W1 in the configuration capable of reducing the equipment cost as described above.
Further, in the present embodiment, the rotation driving part 13 is configured to receive the target withdrawal length from the scale cutter 20, and rotate the electric wire holding part 12 at the number of rotations based on the target withdrawal length. As described above, the twist occurred about the axis by the withdrawing of the electric wire W1 depends on the withdrawal length of the electric wire W1. According to the electric wire straightening device 10 of the present embodiment, the electric wire holding part 12 rotates at the number of rotations based on the withdrawal target length withdrawn by the scale cutter 20, correcting the twist of the electric wire with a high degree of accuracy while also suppressing an over twist back and the like.
In addition, in the above-described first control, before withdrawing and cutting is performed in the present time by the scale cutter 20, the rotation driving part 13 rotates the electric wire holding part 12 at the number of rotations based on the previous target withdrawal length. As a result, the twist caused at the time of the previous withdrawing is canceled and withdrawing and cutting of the current wire W1 at the present time is performed, and the twist of the electric wire W 1 can be corrected with higher accuracy.
In addition, in the second control and the third control described above, before or while the current target withdrawal length is acquired in advance, the rotation driving part 13 rotates the electric wire holding part 12 at the number of rotations based on the target withdrawal length. With this case, in anticipation of the twist occurring in this withdrawal, it is performed to preliminarily produce opposite twist, or to withdraw while correcting the twist, it is possible to correct the twist of the electric wire with higher accuracy.
Further, according to the present embodiment, by clamping the electric wire W1 between the pair of wire clamping rollers 123e, the electric wire W1 can be stably retained and straightened in a state where the electric wire W1 can be pulled out.
Further, in the present embodiment, the inlet 121 of the wire W1 is formed in the wide mouth shape as described above, the holding area 123e-1 held by the pair of electric wire clamping rollers 123e is positioned on the axis passing through the center thereof. Here, as shown in
It is to be noted that the above-described embodiment merely shows a representative form of the present invention, and the present invention is not limited to this embodiment. That is, various deformations within a range not deviating from the gist of the present invention can be carried out. The configuration, as long as the electric wire straightening device of the present invention also is provided, is of course included in the scope of the present invention.
For example, in the above-described embodiment, the electric wire reel WR1 is exemplified as an example of the accommodating place referred to in the present invention. However, the accommodating place referred to in the present invention is not limited to this. The accommodating place referred to in the invention is, for example, only a place where electric wires wound in a ring shape are placed, and as long as a place is accommodated in a state in which the twist around the axis occurs in the electric wire when the electric wire is pulled out, no specific aspect is required.
In the above-described embodiment, as an example of the electric wire straightening device according to the present invention, a substantially cylindrical electric wire holding part 12 is rotatably supported at the one end portion of the rectangular parallelepiped holding frame 11, and the electric wire straightening device 10 to which the rolling driving part 13 is fixed is illustrated at the other end portion. However, the electric wire straightening device referred to in the present invention is not limited to this. The electric wire straightening device according to the present invention can, if provided with the electric wire holding part rotatably provided and the rotation driving part for rotating the electric wire holding part, is arbitrarily set in the shape of each part or the frame structure and the like.
Further, in the above-described embodiment, as an example of the rotation driving part according to the present invention, the rotation driving part 1 having the servomotor 131 as the power source and the drive belt 132 as the power transmission mechanism are exemplified. However, the rotation driving part according to the present invention is not limited to this. The rotation driving part according to the present invention may include a motor or the like other than the servomotor as the driving source or may be provided with a gear mechanism or the like other than the drive belt as the power transmission mechanism.
Further, in the above-described embodiment, as an example of the electric wire holding part according to the present invention, the electric wire holding part 12 for holding the electric wire W1 with the pair of electric wire clamping roller 123e is exemplified. However, the electric wire holding part according to the present invention is not limited to this. The electric wire holding part according to the present invention is not limited to the specific holding structure of the electric wire if holding the electric wire in a state of withdrawal, for example, clamping the electric wire between a plurality of rotating rollers or the like. However, by arranging the electric wire W1 to be clamped by the pair electric wire clamping roller 123e, the electric wire W1 can be stably held as stated above, in a state possible to be pulled out.
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