JP6571246B2 - Peeling device and peeling station - Google Patents

Description

  The present invention relates to a peeling apparatus and a peeling station.

  2. Description of the Related Art Conventionally, there has been known an apparatus that manufactures a coil segment by peeling off an insulating coating and cutting a conductive wire each time an insulated coated conductive wire is sent out (see, for example, Patent Document 1). In this apparatus, a feeding process, a peeling process, a cutting process, and a peeling position changing process are repeatedly performed.

  Moreover, the film peeling apparatus and the film peeling method which peel the film | membrane formed in the outer surface of a wire are known (for example, refer patent document 2). The film peeling apparatus includes a rotating member that penetrates the wire and can rotate around the wire, a pair of cutting tools arranged to sandwich the wire, and a rotating member that rotates together with the pair of cutting tools around the wire. Cutting tool rotating means.

Japanese Patent No. 5682248 Japanese Patent No. 5789908

  In the apparatus described in the above-mentioned Patent Document 1, while performing the feeding process of feeding the conducting wire, the processing steps such as the insulating coating peeling process and the conducting wire cutting process are not performed, Become. For this reason, it took a long time to complete the processing of the conductive wire. Moreover, in the apparatus of the said patent document 2, since a cutting tool is rotated with a rotating member by making a wire rod into a rotation center, the installation containing the said apparatus enlarges. Further, in such a configuration in which the cutting tool is rotated together with the rotating member, it is difficult to increase the rotation speed, and it takes time to rotate, and as a result, it takes time to peel off the coating film of the wire.

  An object of the present invention is to provide a peeling apparatus and a peeling station that can shorten the cycle time of the step of peeling the insulating coating of one conductive wire in view of the problems of the prior art.

  In order to achieve the above object, the present invention provides the above-mentioned insulation of a conductive wire material (for example, a conductive wire material W described later) having a rectangular shape in cross section perpendicular to the longitudinal direction. A peeling device (for example, a peeling device 10 to be described later) for peeling the coating, and an upper die (for example, an upper die to be described later) provided with a peeling blade (for example, a punch 153 to be described later) for peeling the insulating coating. 150), a lower mold (for example, lower mold 110 described later) for supporting the conductive wire material from the lower side of the conductive wire material, and a pressing member (for example, pressing member 130 described later) for preventing the displacement of the conductive wire material. And a rotation mechanism (for example, a work rotation mechanism 21 described later) that rotates the conductive wire around a rotation axis (for example, rotation axis C1 described later) parallel to the axis of the conductive wire. provide.

  According to the present invention, since the conductive wire is rotated by a predetermined angle during the process of peeling off the insulating coating, the time for the standby state in which the processing step is not performed is the time of the stroke in which the upper mold moves and the conductive wire. Only the time for rotating the material is required, and the cycle time can be shortened. That is, the time for rotating the wire at a predetermined angle is shorter than the time for feeding one wire in the axial direction of the wire. And, as described above, instead of sending one wire in the axial direction, the wire at a predetermined angle is rotated, so that the cycle time of the process of peeling the insulation coating of one wire is shortened. be able to.

  The peeling blade has a substantially rectangular parallelepiped shape, and at least a pair of two opposing surfaces have a peeling function for peeling the insulating coating, and the two surfaces having the peeling function are the two conductive wires. The insulation coating can be peeled off at the same time. For this reason, since two conductors can be processed simultaneously, processing efficiency can be improved.

  And the said holding member is matched with the up-and-down width of the side wire holding member in which the clamping width | variety of the said conducting wire material is variable in the direction of the side surface width of the said conducting wire material according to the side surface width of the said conducting wire material. And an upper pressing member in which a holding width of the conductive wire in the vertical direction of the conductive wire is variable.

  For this reason, for example, when the cross-sectional shape of the conducting wire is rectangular, when the conducting wire rotates, the width dimension of the conducting wire in the cross-sectional direction changes, and the distance between the side pressing member and the conducting wire also changes. Moreover, the width dimension (height dimension) of the conducting wire in the vertical direction changes, and the distance between the upper pressing member and the conducting wire also changes. However, since the side pressing member and the upper pressing member are movable, the conductive wire can be reliably positioned and fixed even if the width of the conductive wire changes.

  Moreover, it has a drive mechanism which urges | biases the said side surface pressing member in the direction contact | abutted to the said conducting wire material. For this reason, even if the width | variety of a conducting wire differs because a side surface pressing member contact | abuts to a conducting wire with a drive mechanism, a position can be fixed easily.

  In addition, since the upper pressing member is coupled to the upper mold via an elastic member, the upper pressing member is moved up and down using the stroke of the upper mold when being separated / approached to the lower mold. Can be made. At this time, even if the upper mold continues to approach the lower mold, the movement of the upper pressing member can be stopped at the position where the upper pressing member is in contact with the conducting wire by using the elastic force of the spring. For this reason, it is not necessary to use drive mechanisms, such as a servomotor.

  The present invention also provides a stripping station in which a plurality of stripping molds having the upper mold, the lower mold, and the pressing member are installed side by side in the axial direction of the conductive wire. . For this reason, since several places of conducting wire can be exfoliated simultaneously, processing efficiency improves.

  ADVANTAGE OF THE INVENTION According to this invention, the peeling apparatus and peeling station which can shorten the cycle time of the process of peeling the insulation coating of one conducting wire can be provided.

It is the schematic which shows the peeling station which concerns on one Embodiment of this invention. It is a schematic sectional drawing which shows the peeling apparatus which concerns on one Embodiment of this invention. It is a schematic sectional drawing which shows the workpiece | work rotation mechanism of the peeling apparatus which concerns on one Embodiment of this invention. It is a schematic sectional drawing which shows the eccentric mechanism of the workpiece | work rotation mechanism of the peeling apparatus which concerns on one Embodiment of this invention. It is a schematic sectional drawing which shows a mode that the insulation coating of the 1st side surface of conducting wire is peeled with the peeling apparatus which concerns on one Embodiment of this invention. It is a schematic sectional drawing which shows a mode that the insulation coating of the 4th side surface of conducting wire is peeled with the peeling apparatus which concerns on one Embodiment of this invention. It is a schematic sectional drawing which shows a mode that the insulation coating of the 2nd side surface of conducting wire is peeled with the peeling apparatus which concerns on one Embodiment of this invention. It is a schematic sectional drawing which shows a mode that the insulation coating of the 3rd side surface of conducting wire is peeled with the peeling apparatus which concerns on one Embodiment of this invention. It is a schematic sectional drawing which shows a mode before positioning the conducting wire in the up-down direction when the insulation coating on the first side surface of the conducting wire is peeled by the peeling device according to one embodiment of the present invention. It is a schematic sectional drawing which shows a mode that the conducting wire was positioned in the up-down direction, when peeling the insulation coating of the 1st side surface of a conducting wire with the peeling apparatus which concerns on one Embodiment of this invention. It is a schematic sectional drawing which shows a mode that the insulation coating of the 1st side surface of conducting wire was peeled with the peeling apparatus which concerns on one Embodiment of this invention. It is a schematic sectional drawing which shows a mode before rotating the supporting member of the workpiece | work rotation mechanism of the peeling apparatus which concerns on one Embodiment of this invention. It is a schematic sectional drawing which shows a mode that the rotation pin engaged with the pin engagement part of the protrusion of the support member of the workpiece | work rotation mechanism of the peeling apparatus which concerns on one Embodiment of this invention. It is a schematic sectional drawing which shows a mode that the rotating pin started rotating the support member of the workpiece | work rotation mechanism of the peeling apparatus which concerns on one Embodiment of this invention. It is a schematic sectional drawing which shows a mode that a rotating pin is going to end by rotating the support member of the workpiece | work rotation mechanism of the peeling apparatus which concerns on one Embodiment of this invention. It is a schematic sectional drawing which shows a mode that the rotating pin finished rotating the support member of the workpiece | work rotation mechanism of the peeling apparatus which concerns on one Embodiment of this invention. It is a schematic sectional drawing which shows a mode that a rotation pin has finished rotating the support member of the workpiece | work rotation mechanism of the peeling apparatus which concerns on one Embodiment of this invention, and the rotation pin has retracted | retracted from the support member.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a schematic view showing a peeling station according to an embodiment of the present invention. FIG. 2 is a schematic cross-sectional view showing a peeling apparatus according to an embodiment of the present invention. FIG. 3 is a schematic cross-sectional view showing a workpiece rotation mechanism of the peeling apparatus according to one embodiment of the present invention. FIG. 4 is a schematic cross-sectional view showing the eccentric mechanism of the workpiece rotation mechanism of the peeling apparatus according to one embodiment of the present invention.
As shown in FIG. 1, the peeling station 1 of the present embodiment is configured such that the insulating coating WL at both ends is peeled off from the coil conductor W with the insulating coating WL applied as a long workpiece. It is used to manufacture coil segments manufactured in the above manner.

  As the conducting wire W, a rectangular wire is used. As shown in FIG. 2 etc., the cross section (the cross section orthogonal to the longitudinal direction of the conducting wire W) of the conducting wire W has a rectangular shape. The conducting wire W has a first side surface WS1 and a second side surface WS2 corresponding to each rectangular long side, and a third side surface WS3 and a fourth side surface WS4 corresponding to each short side. The conducting wire W is composed of a conductive portion WP made of copper or the like and an insulating coating WL covering the periphery thereof. The conductive wire W is peeled and cut by the peeling station 1 to have a predetermined length suitable for the coil segment. And many conducting wire materials W are stocked in the state aligned by the palletizing apparatus which is not illustrated.

As shown in FIG. 1, the peeling station 1 includes a peeling device 10 having five peeling molds 11 and a work rotating mechanism 21, an upstream roller 30, a downstream roller 35, and an intermediate roller 40. It has.
The conductive wire W has a predetermined length suitable for the coil segment as described above, and the conductive wire W having a length corresponding to the predetermined four lengths is the number necessary for the manufacture of the coil. Prepared in advance.

  In the peeling station 1, 5 in the direction (hereinafter referred to as “feeding direction”) in which the conductive wire W is sent out between the upstream roller 30 and the downstream roller 35, which is the axial direction of the conductive wire W. A mold 11 for separating the table is arranged. A support member 211 of the work rotation mechanism 21 to be described later is disposed between the first peeling mold 11 and the second peeling mold 11 from the upstream side in the delivery direction. The support member 211 of the workpiece rotation mechanism 21 is disposed between the fourth and fourth peeling molds 11 and 11. The intermediate roller 40 is disposed between the second peeling mold 11 from the upstream side in the delivery direction and the third peeling mold 11 from the upstream side, and the third roller from the upstream side. It arrange | positions between the metal mold | die 11 for peeling, and the metal mold | die 11 for peeling 4th from the upstream. The conducting wire W is passed through the first peeling mold 11 from the upstream side, passes through a through-hole 2111 of a support member 211 (to be described later) of the work rotation mechanism 21 on the upstream side in the delivery direction, and three peeling molds The mold 11 is passed, passes through a through hole 2111 of a support member 211 (to be described later) of the work rotation mechanism 21 on the downstream side in the delivery direction, and is sent out through the fifth peeling mold 11 from the upstream side.

  The upstream roller 30 includes a pair of rollers 31. By rotating the pair of rollers 31, the conductive wire W is sent from the upstream side to the support member 211 of the workpiece rotating mechanism 21 through the first peeling mold 11 between the pair of rollers 31. The downstream roller 35 is composed of a pair of rollers 36. By rotating the pair of rollers 36, the conductive wire W is sent out from the support member 211 of the work rotation mechanism 21 through the fifth peeling mold 11 from the upstream side between the pair of rollers 36.

  The intermediate roller 40 is composed of a pair of rollers 41. By rotating the pair of rollers 41, the conductive wire W is sent out between the pair of rollers 41 to the peeling mold 11 located downstream of the pair of rollers 41 in the sending direction.

  As shown in FIG. 3, the work rotation mechanism 21 includes a support member 211, a protrusion 212, a rotation pin 213, a spring 214 as a rotation pin urging member, a fixed pin 215, and a fixed pin urging member. A spring 216 is provided, and the conducting wire W is rotated by a predetermined angle around a rotation axis C1 parallel to the axis of the conducting wire W in synchronism with the rise of an upper die 150 (to be described later) of the peeling mold 11.

  Specifically, the support member 211 has a cylindrical outer shape, and has a circular shape in a cross section orthogonal to the axis of the support member 211 as shown in FIG. The support member 211 is supported with respect to the lower mold | type 110 so that the axial center position of the support member 211 can be moved. Movement of the axial center position of the support member 211 is performed by an eccentric mechanism 22 described later.

  A through hole 2111 having a square shape is formed in the central portion of the support member 211. The through hole 2111 is formed so as to penetrate the support member 211 in the sending direction, and the conductive wire W fed from the upstream roller 30 is passed through the through hole 2111. Accordingly, the upstream ends of the two conductive wires W are passed one by one through the two support members 211 arranged on the upstream side of the five peeling molds 11 in the delivery direction, The downstream ends of the two conductive wires W are passed one by one through the two support members 211 arranged on the downstream side of the five peeling molds 11 in the delivery direction. The conductive wire W is supported in a parallel positional relationship, and the insulating coating WL is peeled off from the conductive wire W in this state by the peeling mold 11.

  The length of one side of the through hole 2111 shown in FIG. 3 is slightly longer than the length of the long side of the rectangular wire W. The conducting wire W inserted into the through hole 2111 can be moved with respect to the support member 211 in the through hole 2111, but is held by the support member 211 in a state where it cannot rotate with respect to the support member 211. The support member 211 is supported so as to be integrally rotatable with the conductive wire W in a state in which the conductive wire W is supported in the through hole 2111 with the axis of the support member 211 as the rotation axis C1.

  The work rotation mechanism 21 has an eccentric mechanism 22. When the support member 211 rotates integrally with the conductive wire W, axial positions C1 and C2 that are eccentric from the axial position of the support member 211 when the insulation coating WL of the conductive wire W is peeled off as described later, Thus, the support member 211 is temporarily moved by the eccentric mechanism 22. As described above, the support member 211 is temporarily moved by the eccentric mechanism 22, so that the conductive wire W rotates without coming into contact with a die 111, a side pressing member 135, or the like of the peeling mold 11 described later. It becomes possible.

  Specifically, as shown in FIG. 4, the eccentric mechanism 22 has a plurality of belts 2281 and 2282, a plurality of pulleys 221, 222, 223 and 224, and a belt pressing pulley 225. The belt 2281 is hung over the pulley 221 and the pulley 222, and the belt 2282 is hung over the pulley 223 and the pulley 224.

  The pulley 224 is provided on the support member 211 so as to be rotatable with respect to the support member 211 and to be able to move the position of the shaft center integrally with the support member 211. The pulley 222 and the pulley 223 are fixed to the same rotation shaft, and can rotate integrally. The pulley 223 is provided with a cam 2221 at a portion removed from a portion where the belt 2282 is hung. The cam 2221 protrudes outward in the radial direction of the pulley 222 at a part in the circumferential direction of the pulley 222. The pulley 221 is connected to an output shaft of a rotary power device such as a motor (not shown), and rotates when the rotary power device such as a motor (not shown) is driven.

  The belt pressing pulley 225 is rotatably supported at one end of a swinging member 227 that can swing around a swinging shaft 226, and the circumferential surface of the belt pressing pulley 225 abuts on the belt 2282. A cam 2221 can come into contact with the other end of the swing member 227. As the pulley 222 rotates and the cam 2221 contacts the swing member 227, the swing member 227 rotates about the swing shaft 226, and the belt pressing pulley 225 pushes the belt 2282 upward in FIG. As a result, the pulley 224 and the support member 211 move in a direction approaching the rotation axis of the pulley 222 (a direction from the pulley 224 indicated by the one-dot chain line toward the pulley 224 indicated by the solid line). As a result, the conductive wire W supported by the support member 211 is separated from the later-described die 111 and the conductive material abutting wall 113, and the support member 211 supports the conductive wire W and rotates the rotation pin 213. Can be rotated.

  As shown in FIG. 3 and the like, four protrusions 212 are provided on the peripheral surface of the support member 211, and protrude outward in the radial direction of the support member 211 from the peripheral surface of the support member 211. Four protrusions 212 are provided with a central angle about the rotation axis C1 of the circular support member 211 shown in FIG. The protrusion 212 is a central angle of the support member 211 shown in FIG. 3, and is in the range of 0 ° to 90 ° (the 12 o'clock direction when the circular support member 211 shown in FIG. 3 is viewed as a clock face. In the range between 3 o'clock direction and 3 o'clock direction), at the 90 ° position (position in the 3 o'clock direction), the protrusion amount of the support member 211 outward in the radial direction is the smallest, almost 0, and the central angle As the angle approaches 90 ° to 0 ° (position in the 12 o'clock direction), the amount of protrusion gradually increases, and when the central angle is 0 ° (position in the 12 o'clock direction), the amount of protrusion is the largest. Similarly, the range of 360 ° (0 °) to 270 ° (position in the 9 o'clock direction) and 270 ° to 180 ° (position in the 6 o'clock direction) at the central angle of the support member 211 shown in FIG. Even in the range of 180 ° to 90 °, similarly to the range of 90 ° to 0 °, the amount of protrusion gradually increases as the central angle decreases, and the support members 211 have the same shape. That is, the support member 211 shown in FIG. 3 rotates in the clockwise direction, but the protrusion 212 is supported radially outward of the support member 211 from the downstream side in the rotation direction of the conductive wire W toward the upstream side. A pin sliding surface 2121 extending away from the rotation axis C1 of the member 211 is provided.

  The protrusion 212 has a pin engaging portion 2122. Specifically, the upstream end portion of the pin sliding surface 2121 in the rotation direction of the support member 211 is an end portion of four protrusions 212 existing on the peripheral surface of the support member 211, and the radially inner side of the support member 211 It is connected to the surface facing to form a corner. At this corner, the protrusion 212 has a shape (notch shape) that is depressed inward in the radial direction of the support member 211, and the notch-shaped portion is a pin engaging portion 2122. Configure. As shown in FIG. 3 and the like, the pin engaging portion 2122 can engage the rotating pin 213 or the fixed pin 215.

The rotation pin 213 is supported by the upper mold 150 of the peeling mold 11 so as to be movable back and forth with respect to the support member 211, and is synchronized with the vertical movement of the upper mold 150 of the peeling mold 11. Move up and down.
Specifically, as shown in FIG. 3, the rotation pin 213 has a tip portion having a truncated cone shape, a base portion having a cylindrical shape, and a rotation pin biasing force on the base end portion of the base portion. One end of a spring 214 as a member is fixed. The other end of the spring 214 is fixed to a holder 1503 provided on the upper mold 150. The spring 214 biases the rotating pin 213 toward the support member 211. For this reason, the tip of the rotating pin 213 slides in contact with the pin sliding surface 2121 of the protrusion 212 of the support member 211 or engages with the pin engaging portion 2122. The rotating pin 213 is supported by a holder 1503 provided on the upper die 150 so as to move up and down integrally with the upper die 150.

The fixing pin 215 is supported by the lower mold 110 of the peeling mold 11 so that the fixing pin 215 can move forward and backward with respect to the support member 211, and is fixed vertically with respect to the lower mold 110 and the supporting member 211 of the peeling mold 11. The relative position of the direction is fixed.
Specifically, the fixing pin 215 has a tip-conical shape at the tip and a columnar shape at the base, and one end of a spring 216 as a fixing pin biasing member is provided at the base end of the base. The part is fixed. The other end of the spring 216 is fixed to a holder 1103 provided with the lower mold 110. The spring 216 biases the fixing pin 215 toward the support member 211. Therefore, the distal end portion of the fixing pin 215 abuts on the pin sliding surface 2121 of the protrusion 212 of the support member 211 or engages with the pin engaging portion 2122. As shown in FIG. 3, the fixing pin 215 engages with the pin engaging portion 2122, whereby the support member 211 is prevented from rotating counterclockwise in FIG. Further, the fixed pin 215 is supported by the holder 1103 of the lower mold 110 so that the support member 211 can be prevented from rotating in a state where the pin engaging portion 2122 is engaged with the distal end portion of the fixed pin 215. Has been.

  The peeling mold 11 includes a lower mold 110, a pressing member 130, and an upper mold 150. The lower mold 110 has a die 111 and a center guide 112. The die 111 extends in the axial direction of the conductive wire W, and the central guide 112 has a through hole 1111 formed so as to penetrate the die 111 in the vertical direction. The die 111 extends in the axial direction of the conductive wire W, and the center guide 112 is disposed in a through hole 1111 formed so as to penetrate the die 111 in the vertical direction. The center guide 112 moves up and down together with the punch 153 when the punch 153 of the upper die 150 moves downward from the upper surface of the die 111.

  As shown in FIG. 3, on each upper surface of the die 111, two conductive wires W supported by the support member 211 are arranged one by one with the through hole 1111 interposed therebetween. The die 111 of the lower mold 110 supports the conductive wire W from below the conductive wire W. Conductive material contact wall portions 113 extending in the vertical direction are provided on the upstream side and the downstream side of the center guide 112 in the delivery direction (the direction connecting the front surface and the back surface of the paper surface shown in FIG. 2). The width of the conductive material contact wall 113 in the direction orthogonal to the delivery direction and the vertical direction (the horizontal direction in FIG. 2 and hereinafter referred to as “cross-sectional direction”) is the same direction as the central guide 112 is disposed. When the insulation coating WL of the conductive wire W is peeled off, the conductive wire W is pressed against the side surface of the conductive material abutting wall 113 in the same direction, which is equal to the width of the through-hole 1111. .

  The upper mold 150 of the five peeling molds 11 is connected to an upper mold drive unit constituted by a cylinder, an actuator, etc. (not shown) so that all of the upper mold 150 can be moved up and down simultaneously with respect to the lower mold 110. On the lower surface of the upper mold 150, a peeling blade for peeling the insulating coating WL and a punch 153 as a cutting blade are fixed and provided. Accordingly, the upper mold 150 and the punch 153 are integrally moved up and down, which is a direction perpendicular to the axial direction of the conductive wire W.

The punch 153 has a substantially rectangular parallelepiped shape. The two side surfaces 1531 and 1532 of the pair of punches 153 in the left-right direction (cross-sectional direction) shown in FIG. 2 have a peeling function for simultaneously peeling the insulating coating WL of the conductive wire W placed on the die 111 one by one. Have.
That is, the two side surfaces 1531 and 1532 of the pair of punches 153 in the left-right direction (cross-sectional direction) shown in FIG. 2 are the side surfaces of the conductive portion WP of the rectangular conductive wire W by moving the punch 153 downward. It moves downward along any one of the first side surface WS1, the second side surface WS2, the third side surface WS3, and the fourth side surface WS4, and the insulation coating WL of the conductive wire W is cut off and peeled off. This cutting is performed simultaneously for each of the two conductive wires W arranged on the die 111.

  The upper ends of a pair of springs 154 as elastic members are fixed to the lower surface of the upper mold 150. The lower ends of the pair of springs 154 are fixed to the upper surface of the upper pressing member 131 constituting the pressing member 130 and urge the upper pressing member 131 downward with respect to the upper mold 150.

  The pressing member 130 is provided to prevent the displacement of the conductive wire W, and includes an upper pressing member 131 and a side pressing member 135. The upper holding member 131 is disposed above the conductive wire W placed on the die 111 and below the upper die 150, and is coupled to the upper die 150 via a spring 154 as an elastic member. Yes. A through hole 132 is formed in the upper pressing member 131, and a punch 153 passes through the through hole 132.

  The lower end portion of the punch 153 has a positional relationship facing the central guide 112 disposed in the through hole 1111 of the die 111 of the lower mold 110. As the upper mold 150 moves downward, the upper pressing member 131 moves downward together with the upper mold 150. Then, the lower surface of the upper pressing member 131 comes into contact with the conductive wire W and is pressed downward by the biasing amount force of the spring 154, so that the conductive wire W is sandwiched between the upper pressing member 131 and the die 111. The conducting wire W is positioned in the vertical direction, and rotation about the axis of the conducting wire W is prevented.

  The upper holding member 131 has a variable holding width of the conductive wire W in the vertical direction of the conductive wire W in accordance with the vertical width of the conductive wire W. That is, the vertical width of the conductive wire W is such that the conductive wire W is arranged in a state where the cross section of the conductive wire W is vertically long as shown in FIG. The value is different from the case where the wire W is disposed in a state where the cross section is horizontally long. However, the upper pressing member 131 is urged downward with respect to the upper mold 150 by the spring 154, and presses the conductive wire W from above so that the conductive wire W is moved between the upper pressing member 131 and the die 111. Since the conductor W is positioned by sandwiching the conductor W in between, the conductor W can be positioned in the vertical direction corresponding to the state in which the section of the conductor W is vertically long and the section of the conductor W is horizontally long. is there.

  A pair of side pressing members 135 are provided in the delivery direction and the cross-sectional direction, and are each configured to be slidable with respect to the die 111 so as to be separated / approached from each other. It is connected to the. The drive mechanism 140 urges the side pressing member 135 in a direction in which the side pressing member 135 abuts on the conductive wire W. The pair of side surface pressing members 135 come close to each other, abut against the conductive wire material W and press the conductive wire material W against the side surface of the conductive material contact wall portion 113, thereby positioning in the direction of the lateral width of the conductive wire material W. To do.

  In the side pressing member 135, the holding width of the conductive wire W in the direction of the side width of the conductive wire W is variable in accordance with the side width of the conductive wire W. That is, as shown in FIG. 5 and the like, the side surface width of the conductive wire W (the width of the conductive wire in the cross-sectional direction of FIG. 5 and the like) is such that the cross section of the conductive wire W is vertically long. As shown in FIG. 6 and the like, the values are different between the case where the wire W is arranged in a state where the cross section of the wire W is horizontally long. However, the side pressing member 135 positions the conductive wire W by pressing the conductive wire W against the side surface of the conductive material abutting wall 113, so that the cross section of the conductive wire W is in a vertically long state and the cross section of the conductive wire W. Corresponding to the vertically long state, the conductive wire W can be positioned in the vertical direction.

Next, the process of peeling the insulation coating WL of the conducting wire W will be described.
In the peeling mold 11, first, a positioning step is performed.
FIG. 5 is a schematic cross-sectional view showing a state where the insulation coating on the first side surface of the conducting wire is peeled off by the peeling device according to one embodiment of the present invention. FIG. 6 is a schematic cross-sectional view showing a state where the insulating coating on the fourth side surface of the conductive wire is peeled by the peeling device according to the embodiment of the present invention. FIG. 7 is a schematic cross-sectional view showing a state where the insulating coating on the second side surface of the conductive wire is peeled off by the peeling device according to one embodiment of the present invention. FIG. 8 is a schematic cross-sectional view showing a state where the insulating coating on the third side surface of the conductive wire is peeled off by the peeling device according to one embodiment of the present invention. FIG. 9 is a schematic cross-sectional view showing a state before positioning the conducting wire in the vertical direction when the insulating coating on the first side surface of the conducting wire is peeled by the peeling device according to the embodiment of the present invention. FIG. 10 is a schematic cross-sectional view showing a state in which the conducting wire is positioned in the vertical direction when the insulation coating on the first side surface of the conducting wire is peeled off by the peeling device according to the embodiment of the present invention. FIG. 11 is a schematic cross-sectional view showing a state where the insulating coating on the first side surface of the conducting wire is peeled by the peeling device according to the embodiment of the present invention.

  In the positioning step, as shown in FIG. 9 and the like, the conductor W is passed through the through-hole 2111 (see FIG. 12 and the like) of the support member 211 and supported by the support member 211 with the cross section of the conductor W being in a vertically long state. At the same time, it is placed on the upper surface of the die 111 of each peeling mold 11 so that the fourth side surface WS4 is brought into contact with the upper surface of the die 111. Next, as shown in FIGS. 5 and 10, the side surface pressing member 135 is driven by the drive mechanism 140 (see FIG. 2) to come into contact with the second side surface WS <b> 2 of the conductive wire W, respectively. The side surface WS1 is brought into contact with the conducting wire abutting wall 113 (see FIG. 2), the conducting wire W is pressed against the conducting wire abutting wall 113, and the conducting wire W is brought into contact with the conducting wire abutment wall 113 and the side pressing member. The conductive wire W is positioned in the cross-sectional direction so as to be sandwiched between the two. Next, by driving an upper mold driving unit (not shown), the upper mold 150 is moved downward, the upper pressing member 131 is brought into contact with the first side surface WS1, and the conductive wire W is held on the upper pressing member 131. The lead wire W is positioned in the vertical direction so as to be sandwiched between the die 111 and the die 111. The above is the positioning process.

  Next, a peeling process is performed. In the peeling step, the upper die driving unit (not shown) is further driven to move the upper die 150 downward, and the punch 153 projects downward from the lower surface of the upper pressing member 131. Thereby, the two side surfaces of the pair of punches 153 in the cross-sectional direction start to cut off the insulating coating WL on the first side surface WS1. Then, as shown in FIG. 11, by moving the upper die 150 downward until the punch 153 reaches the center guide 112, the insulating coating WL on the first side surface WS1 is cut off and peeled off. The above is the peeling process.

Next, a rotation process is performed.
FIG. 12 is a schematic cross-sectional view illustrating a state before the support member of the workpiece rotation mechanism of the peeling apparatus according to the embodiment of the present invention is rotated. FIG. 13: is a schematic sectional drawing which shows a mode that the rotation pin was engaged with the pin engagement part of the protrusion of the support member of the workpiece | work rotation mechanism of the peeling apparatus which concerns on one Embodiment of this invention. FIG. 14 is a schematic cross-sectional view illustrating a state in which the rotation pin starts to rotate the support member of the workpiece rotation mechanism of the peeling apparatus according to the embodiment of the present invention. FIG. 15 is a schematic cross-sectional view illustrating a state in which a rotating pin is about to end a support member of a workpiece rotating mechanism of a peeling apparatus according to an embodiment of the present invention. FIG. 16 is a schematic cross-sectional view illustrating a state in which the rotation pin has finished rotating the support member of the workpiece rotation mechanism of the peeling apparatus according to the embodiment of the present invention. FIG. 17 is a schematic cross-sectional view illustrating a state in which the rotation pin has finished rotating the support member of the workpiece rotation mechanism of the peeling apparatus according to the embodiment of the present invention, and the rotation pin is in a position retracted from the support member.

  In the rotation step, first, the drive mechanism 140 (see FIG. 2) is driven to move the pair of side surface pressing members 135 away from each other in the cross-sectional direction, and from the second plane of the conductive wire W. Separate. Next, the upper die 150 in a state where the punch 153 has moved downward until reaching the center guide 112 is moved upward. As a result, the upper pressing member 131 moves away from the third plane of the conductive wire W, and the rotating pin 213 moves upward as shown in FIG. Next, the shaft center position of the support member 211 is decentered by the eccentric mechanism 22 from the shaft center position C2 (see FIG. 2) of the support member 211 in the peeling process to the shaft center position C1.

  Further, when the upper mold 150 is moved upward, as shown in FIG. 13, the tip end portion of the rotating pin 213 is engaged with the pin engaging portion 2122. Then, when the upper mold 150 is further moved upward, as shown in FIG. 14, the tip of the rotating pin 213 pushes up the protrusion 212 to rotate the support member 211. When the upper mold 150 is further moved upward, as shown in FIGS. 15 to 16, the support member 211 is rotated 90 degrees (one quarter rotation) from the state shown in FIG. . Then, when the upper mold 150 reaches the top dead center as shown in FIG. 9, the engagement of the rotating pin 213 with the pin engaging portion 2122 is released as shown in FIG. Then, the eccentric position of the support member 211 is decentered by the eccentric mechanism 22 from the axial position C1 (see FIG. 2) of the supporting member 211 that has rotated the supporting member 211 to the axial position C3. The above is the rotation process. After this rotation step, the second side surface WS2 of the conductive wire W is in contact with the upper surface of the die 111.

  Similarly, the insulating coating WL is peeled in the order of the fourth side surface WS4, the second side surface WS2, and the third side surface WS3 of the conductive wire W by repeatedly performing the positioning step, the peeling step, and the rotating step. The

  According to this embodiment, the following effects can be obtained.

  In this embodiment, the peeling apparatus 10 for peeling the insulating coating WL of the conductive wire W having the insulating coating WL and having a quadrangular cross section perpendicular to the longitudinal direction is used as a peeling blade for peeling the insulating coating WL. An upper die 150 provided with a punch 153, a lower die 110 for supporting the conductive wire W from the lower side of the conductive wire W, a pressing member 130 for preventing the displacement of the conductive wire W, and an axial center of the conductive wire W And a work rotation mechanism 21 that rotates the conducting wire W around a parallel rotation axis C1.

  As a result, the wire W as the workpiece is rotated by a predetermined angle during the process of peeling the insulating coating WL, so that the time when the process is in a standby state without performing the process is the time of the stroke for moving the mold 11 Thus, only the time during which the conductive wire is rotated can be achieved, and the cycle time can be shortened. That is, the time for rotating the wire W at a predetermined angle is shorter than the time for feeding one wire W in the axial direction. As described above, instead of sending one wire W in the axial direction, the wire W is rotated at a predetermined angle. Therefore, the cycle of the process of peeling the insulation coating WL of one wire W is performed. Time can be shortened.

  In this embodiment, the punch 153 as the peeling blade has a substantially rectangular parallelepiped shape, and at least a pair of two opposing surfaces have a peeling function of peeling the insulating coating WL. The two surfaces 1531 and 1532 having a peeling function can peel the insulating coating WL of the two conductive wires W at the same time. Thereby, since two conducting wire materials W can be processed simultaneously, processing efficiency can be improved.

  In the present embodiment, the pressing member 130 includes a side pressing member 135 in which the holding width of the conducting wire W in the direction of the side width of the conducting wire W is variable in accordance with the side width of the conducting wire W, and the conducting wire W. And an upper pressing member 131 having a variable holding width of the conductive wire W in the vertical direction of the conductive wire W.

  Thereby, for example, when the cross-sectional shape of the conducting wire W is rectangular, when the conducting wire W rotates, the width dimension of the conducting wire W in the transverse cross-sectional direction changes, and the distance between the side pressing member 135 and the conducting wire W also changes. To do. Moreover, the width dimension (height dimension) of the conducting wire W in the vertical direction changes, and the distance between the upper pressing member 131 and the conducting wire W also changes. However, since the side pressing member 135 and the upper pressing member 131 are movable, even if the width dimension of the conductive wire W changes, the conductive wire W can be reliably positioned and fixed.

  Moreover, in this embodiment, it has the drive mechanism 140 which urges | biases the side surface pressing member 135 in the direction contact | abutted to the conducting wire W. Thereby, even if the width | variety of the conducting wire W differs because the side surface pressing member 135 contact | abuts to the conducting wire W by the drive mechanism 140, a position can be fixed easily.

  In the present embodiment, the upper pressing member 131 is coupled to the upper mold 150 via a spring 154 as an elastic member. Thereby, the upper pressing member 131 can be moved up and down by using the stroke of the upper mold 150 when moving away from or approaching the lower mold 110. At this time, even if the upper mold 150 continues to approach the lower mold 110, the movement of the upper pressing member 131 is stopped at the position where the upper pressing member 131 is in contact with the conductor W using the elastic force of the spring 154. be able to. For this reason, it is not necessary to use drive mechanisms, such as a servomotor.

  Further, in the peeling station 1 according to the present embodiment, a plurality of peeling dies 11 having an upper die 150, a lower die 110, and a pressing member 130 are arranged side by side in the axial direction of the conductive wire W. Thereby, since several places of the conducting wire W can be peel-processed simultaneously, processing efficiency improves.

  Moreover, in the peeling apparatus 10 in this embodiment that peels the insulating coating WL of the conductive wire W as a long workpiece whose outer periphery is covered with the insulating coating WL as a coating, a direction orthogonal to the axial direction of the conductive wire W The punch 153 as a cutting blade that moves up and down in the cross sectional direction, the upper mold 150 provided with the punch 153, the lower mold 110 that supports the conductive wire W, and the conductive wire W in synchronization with the rise of the upper mold 150. And a work rotation mechanism 21 that rotates the conducting wire W by a predetermined angle around a rotation axis C1 parallel to the axis of the workpiece.

  As a result, the wire W as the workpiece is rotated by a predetermined angle during the ascending time or the machining time of the punch 153 as the cutting blade. Cycle time, and the cycle time can be shortened.

  In the present embodiment, the work rotation mechanism 21 includes a support member 211 that can rotate while supporting a conductive wire W as a work, and a rotation pin 213 that moves up and down in synchronization with the up and down movement of the upper mold 150. A spring 214 as a rotation pin urging member that urges the rotation pin 213 toward the support member 211, a fixed pin 215 whose relative position in the vertical direction with respect to the support member 211 is fixed, and a fixed pin A spring 216 serving as a fixed pin urging member that urges 215 toward the support member 211, and a protrusion 212 provided around the support member 211, which supports the workpiece from the downstream side to the upstream side in the rotation direction of the workpiece. A pin sliding surface 2121 extending away from the rotation axis C <b> 1 of the support member 211 outward in the radial direction of the member 211, and a pin sliding surface 212 in the rotation direction of the support member 211. Comprising a rotating pin 213 or the fixed pin 215 positioned upstream end and the pin engaging portion 2122 having a notch shape to engage a protrusion 212 having, a.

Accordingly, when the upper mold 150 is raised, the rotary pin 213 is raised in synchronization with the upper mold 150. The rotation pin 213 pushes the pin engaging portion 2122 upward to rotate the support member 211. The fixing pin 215 slides along the pin sliding surface 2121, the spring 216 as the fixing pin urging member is contracted, the fixing pin 215 is fixed to the pin engaging portion 2122, and the reverse flow (of the support member 211 is Reverse rotation) is prevented.
Further, the support member 211 stops rotating, and the upper mold 150 and the rotation pin 213 are lowered. The conductive wire W as a workpiece is processed again at the rotated position, but a side surface different from the previously processed side surface is processed. That is, the movement of the upper mold 150 and the rotation of the conductive wire W can be synchronized with a simple configuration. The rotation angle can be adjusted according to the number of protrusions 212 and the size of the support member 211.

The present invention is not limited to the above-described embodiment, and modifications, improvements, and the like within the scope that can achieve the object of the present invention are included in the present invention.
For example, although the cross-sectional shape of the conducting wire W has a rectangular shape, it is not limited to this configuration. What is necessary is just to have a square shape, for example, a trapezoid may be sufficient. In addition, although the two conductive wires W have the insulating coating WL peeled off simultaneously, the number is not limited to two.
In addition, the two side surfaces 1531 and 1532 of the pair of punches 153 in the cross-sectional direction have a peeling function for simultaneously peeling the insulating coating WL of the conductive wire W, but are not limited to this configuration. The peeling blade should just have the peeling function which peels the insulation coating WL at least by a pair of two opposing surfaces.
Further, the workpiece rotation mechanism is not limited to the configuration of the workpiece rotation mechanism 21 according to the present embodiment.
For example, the support member 211 rotates in synchronization with the rise of the upper mold 150, but is not limited to this configuration. In synchronization with the raising and / or lowering of the upper mold 150, the conducting wire W may be rotated by a predetermined angle around the rotation axis C1 parallel to the axis of the conducting wire W as a workpiece. Specifically, the conductive wire W may be gripped by a general collet chuck or the like, and the collet chuck may be rotated by a predetermined angle by a servo motor or the like.
The upper pressing member 131 is supported by the upper mold 150 via the spring 154, but is not limited to this configuration. For example, the upper surface pressing portion may be driven relative to the upper mold 150 by a motor.
Moreover, the structure of each part which comprises a peeling apparatus is not limited to the structure of each part of the peeling apparatus 10 in this embodiment. Similarly, the structure of each part which comprises a peeling station is not limited to the structure of each part of the peeling station 1 in this embodiment.

DESCRIPTION OF SYMBOLS 1 ... Peeling station 10 ... Peeling apparatus 21 ... Work rotation mechanism (rotation mechanism)
110 ... Lower mold 130 ... Holding member 131 ... Upper pressing member 135 ... Side pressing member 140 ... Drive mechanism 150 ... Upper mold 153 ... Punch (peeling blade)
154 ... springs 1531 and 1532 ... two side surfaces (two surfaces)
C1 ... Axis center position (rotation axis)
W ... Conducting wire (work)
WL: Insulation coating (coating)

Claims (6)

A stripping device for stripping the insulating coating on the side to be stripped of the conductive wire having a rectangular shape with a cross section perpendicular to the longitudinal direction having an insulating coating,
An upper mold provided with a peeling blade for peeling the insulating coating;
A lower mold for supporting the conductive wire material from below the conductive wire material;
A rotating mechanism for rotating the conducting wire around a rotation axis parallel to the axis of the conducting wire;
An eccentric mechanism for eccentrically rotating the rotation axis of the conducting wire;
A peeling apparatus comprising:   The rotation mechanism has a support member that supports the conductive wire,
  The peeling device according to claim 1, wherein the eccentric mechanism is movably attached to the support member so that the wire does not interfere with the lower mold during rotation.   The support member has a through-hole through which the conductive wire is inserted,
The peeling apparatus according to claim 2, wherein the conductive wire material is supported in the through hole so as to be movable and non-rotatable.   A stripping method for stripping the insulating coating on the side to be stripped of a conductive wire having a rectangular shape with a cross section perpendicular to the longitudinal direction having an insulating coating,
  A positioning step of positioning the conducting wire in the vertical direction and the cross-sectional direction;
  A peeling step of moving the peeling blade to peel the insulating coating from the first side surface of the conducting wire,
  An eccentric step of eccentrically rotating a rotation axis parallel to the axis of the conducting wire;
  And a rotating step of rotating the conductive wire around the rotation axis obtained by decentering the conductive wire.   The peeling method according to claim 4, wherein in the eccentric step, the conducting wire is moved to a position where the conducting wire does not interfere with the lower mold by rotation.   6. The peeling method according to claim 4, further comprising a second eccentric step in which a second side surface different from the first side surface of the conductive wire material is opposed to the peeling blade after the rotating step.

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