JP2010221225A - Bending device and bending machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a bending device 12 which allows the working of bending the three parts in a workpiece W without generating pulling-in of the workpiece W, and ensures good working precision. <P>SOLUTION: A first fixture 13 and a second fixture 14 are connected so as to be freely turnable around a rolling shaft 15. Further, an off-set bending part 18 is arranged at an off-set position on the rolling side of the workpiece W from the rolling shaft 15. A slide part 20 slid by a prescribed amount to a base part 19 and a fixed bending part 21 fixed to the base part 19 are arranged at the second fixture 14. Besides, the slide part 20 is provided with a slide bending part 24. Then, both the fixtures 13, 14 are rolled, further, the slide part 20 is slid, and, without dislocating the workpiece W to the respective suppression parts 16, 23a, 23b, the workpiece W is subjected to bending. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention, for example, bends into a predetermined material such as a circular or rectangular metal wire (for example, a flat wire) constituting a winding (magnet wire) for a rotating electrical machine, or a bar material, pipe material, plate material, or the like. More particularly, the present invention relates to a bending apparatus and a bending machine that can perform a process of bending a plurality of portions of the material without pulling in the material and improve processing accuracy.

  In general, rotating electrical machines such as induction motors and direct current motors (including generators) are widely used as power sources for industrial or vehicle use, and distributed winding with high specific output is often used for the layout of the stator coils. ing. Recently, as a motor used in a hybrid drive vehicle and an electric vehicle, it has been proposed to use a rectangular wire having a high slot space factor as a magnet wire because of output / size requirements and the like.

  The magnet wire used in the rotating electric machine as described above forms a coil by bending a plurality of places. Generally, a material such as a magnet wire is bent only in one direction. The processing apparatus was used while pulling the material into the jig (see Patent Document 1).

  On the other hand, there is also known a structure in which two parts of a material such as a magnet wire are fixed with a clamp, the material is bent while being pulled, and the material is bent at the same time (see Patent Document 2).

JP 2004-104841 A Japanese Utility Model Publication No. 55-122924

  In the case of the structure described in the above-mentioned Patent Document 1, in order to perform bending at a plurality of locations of the material, the operations of bending from the top of the material, then shifting the material and processing again are sequentially repeated. There is a need. For this reason, it is inevitable that the processing time becomes long. In addition, since the material is pulled in during the bending process, it is not possible to perform a process of bending a plurality of parts of the material at the same time.

  On the other hand, in the case of the structure described in Patent Document 2, bending is simultaneously applied to two parts of the material, but a large back tension is applied in the direction in which both clamps for bending the material are separated so that the material does not pull in. (Tensile force) must be applied. For this reason, it is difficult to manage the dimensions of the material during bending, and it is difficult to perform accurate bending.

  Accordingly, an object of the present invention is to provide a bending apparatus and a bending machine that can perform a process of bending a plurality of portions of a material without causing pulling of the material and can improve a processing accuracy.

The present invention provides a bending apparatus (12) for bending a predetermined material (W) at three locations,
A first jig (13) and a second jig (14) connected to be rotatable about a rotation shaft (15);
Arranged on either the first jig (13) or the second jig (14) and offset by a predetermined amount from the rotation shaft (15) to the rotation side of the material (W). And an offset bending part (18) for bending the material (W) by the rotation of both jigs (13, 14),
Said 1st jig | tool (13) has the holding | suppressing part (16) which suppresses the displacement of the said raw material (W) on the opposite side to a rotation direction,
The second jig (14) includes a base (19) rotatably connected to the first jig (13), and slides the material (W) by a predetermined amount relative to the base (19). A slide part (20) to be fixed, and a fixed bending part (21) fixed to the base part (19) and bending the material (W) by sliding of the slide part (20),
The slide portion (20) includes a restraining portion (23a, 23b) that suppresses displacement of both sides of the rotation direction of the material (W), and a slide bending portion that bends the material (W) by sliding of the slide portion (20). (24)
The jigs (13, 14) are rotated and the slide part (20) is slid, so that the material (W) is moved to the holding parts (16, 23a, 23b), the material (W) is bent at three points without being displaced.

  The direction and amount of movement of the slide part (20) are more on the second jig (14) side than the fixed bending part (21) and the slide bending part (24) on the neutral line of the material (W). The predetermined points are determined on the basis of the positions where it is assumed that the two bent portions (21, 24) are not bent and the two bent portions (21, 24) are bent. .

When it is assumed that the fixed bent portion (21) and the slide bent portion (24) are not bent, the position where the predetermined point exists is bent at the start point (Q) and the bent portions (21, 24). When the position where the predetermined point exists is the end point (R),
The slide portion includes the start point (Q) and the end point (R) on a virtual line parallel to a direction in which the material (W) of the second jig (14) passing through the start point (Q) is disposed. And slide along an arc passing through the start point (Q) and the end point (R) with the point (G) existing at the same distance from the center.

  The slide part (20) slides in the direction opposite to the rotation direction with respect to the base part (19), and the fixed bending part (21) sandwiches the offset bending part (18) and the material (W). The slide bending part (24) is arranged on the rotation side of the material (W).

  The predetermined material (W) is a rectangular wire constituting a coil for a rotating electrical machine.

  Further, the bending machine (28) of the present invention is configured such that the bending apparatus (12) includes the first jig (13a, 13b) and the second jig (14a, 14b, 14c). By alternately connecting at the center of rotation, a plurality of them can be arranged in series, and the predetermined material (W) can be bent at a plurality of locations.

The second jigs (14a, 14b, 14c) are rotatably connected to both ends of the first jigs (13a, 13b),
When the second jigs (14a, 14b, 14c) are rotated in the direction approaching each other, the slide part abutting members (29a, 29b) that abut on the respective slide parts (20a, 20b, 20c) With
The second jigs (14a, 14b, 14c) are rotated, and the slide parts (20a, 20b, 20c) of the second jigs (14a, 14b, 14c) are respectively brought into contact with the slide parts. The second jigs (14a, 14b, 14c) are further rotated while being in contact with the members (29a, 29b), thereby rotating the slide parts (20a, 20b, 20c), respectively. Slide in the direction opposite to the direction of movement.

The first jig (13a, 13b) and the second jig (14a, 14b, 14c) are attached to both ends of the first jig (13a, 13b). 14c) are alternately connected so that the five jigs can rotate,
Among the jigs, the second jig (14b) disposed in the middle is hung between two base parts (19b, 19c) that can be divided and relatively displaced, and the two base parts (19b, 19c). A single slide portion (20b) arranged to pass,
During the bending process, both the bases (19b, 19c) are relatively displaced, so that the single slide part (20b) slides with respect to the both bases (19b, 19c).

When the middle second jig (14b) is rotated, a base abutting member (34) that abuts one base (19c) constituting the middle second jig (14b) Have
The second jig (14b) in the middle is rotated in a state where the second jig (14b) in the middle is rotated and the one base (19c) is brought into contact with the base abutting member (34). ) Further rotating, the first jig (13b) connected to the one base part (19c) and the end of the first part connected via the first jig (13b) Together with the second jig (14c), the one base part (19c) is displaced with respect to the other base part (19b) constituting the second jig (14b) in the middle.

  In addition, although the code | symbol in the said parenthesis is for contrast with drawing, it has no influence on the structure of each claim by this.

  According to the first aspect of the present invention, the first jig and the second jig are rotated and the slide portion of the second jig is slid to bend the material at three locations. Therefore, the processing time can be shortened. In addition, since the material is not displaced (no pull-in) with respect to the holding parts constituting both jigs at the time of bending, it is possible to prevent sliding between the material and the holding parts. , It is possible to prevent the material from being damaged. In addition, since no tensile force acts on the material during bending, the material can be accurately bent.

  According to the second aspect of the present invention, it is possible to more reliably prevent the material from being pulled in during bending.

  According to the third aspect of the present invention, the bending process can be performed smoothly, and the pulling of the material during the bending process can be prevented more reliably.

  According to the fourth aspect of the present invention, it is possible to easily and quickly perform a process of bending three portions of the material in opposite directions (bending processes having different bending directions).

  According to the fifth aspect of the present invention, a process for bending three portions of a rectangular wire can be performed with high accuracy, and the enamel layer for insulation is not damaged during the bending process. can get.

  According to the sixth aspect of the present invention, a complicated bent shape can be manufactured with high accuracy in a short time, and the manufacturing cost can be reduced. That is, according to the above bending apparatus, no pulling occurs when the material is bent. Therefore, even if a plurality of such bending apparatuses are combined and bent simultaneously at a plurality of locations of the material, It will not be pulled. Therefore, even if bending is performed simultaneously on a plurality of portions of the material, the dimensions of the material do not change, and a complicated bending shape can be obtained with high accuracy and in a short time. Furthermore, if a coil for a rotating electrical machine is manufactured according to the present invention, the number of joints of the coil can be reduced, so that the manufacturing cost can be reduced and the coil can be reduced in size.

  According to the seventh aspect of the present invention, the slide portions of the second jig connected to both ends of the first jig are slid in conjunction with the rotation of the second jig. Can be bent efficiently.

  According to the present invention of claim 8, the single slide part of the second jig in the middle can be slid with respect to the respective base parts in conjunction with the rotation of the five jigs. Bending with individual jigs can be performed efficiently.

  According to the present invention of claim 9, by displacing the other base part constituting the second jig in the middle, the single slide part is moved in association with the rotation of the five jigs. It can be slid with respect to the base, and can be bent more efficiently.

The perspective view which shows the stator incorporating the coil manufactured by this invention. The perspective view which shows the coil (U phase). The figure which shows the state which bends a raw material with the bending apparatus which concerns on 1st embodiment of this invention. The schematic diagram for demonstrating the relationship between the bending center of an offset bending part, and a rotation center. The schematic diagram which shows the state before and behind the bending process of a raw material by a fixed bending part and a slide bending part. The figure for demonstrating the slide direction of a slide part. The figure which shows the state before giving a bending process with the bending machine which concerns on 2nd embodiment of this invention. Similarly, the figure which shows the 1st state which started the bending process. The figure which shows the 2nd state. The figure which shows a 3rd state. The figure which shows the 4th state. The figure which shows the same 5th state. Similarly, the figure which shows the state after a bending process. The figure which shows the structure which became a problem when deriving 2nd embodiment of this invention.

  Embodiments of the present invention will be described with reference to the drawings. First, a rotary electric (motor, generator, etc.) stator incorporating a coil manufactured according to the present invention will be described with reference to FIGS. The stator 1 constitutes an electric motor (including a generator) together with a rotor, and the electric motor is suitable for application to an electric motor (including a generator) serving as a drive source for electric vehicles and hybrid vehicles, particularly a brushless DC motor. is there. As shown in FIG. 1, the stator 1 includes a stator core 2 in which a large number of thin silicon steel plates are laminated, and a coil 4 around which a magnet wire (conductor, winding) 3 that is a predetermined material is wound. The stator core 2 is formed in a ring shape, and a plurality of slots 5 and teeth 6 that are open on the inner diameter side are alternately formed. The three-phase U, V, W coils 4 (4U, 4V, 4W) are wound between the two slots 5 separated by a predetermined pitch by distributed winding.

  The magnet wire 3 is a rectangular wire having a rectangular cross section, and an insulating coating such as an insulating resin is formed on the entire circumference of a conductor portion made of copper or the like. The three-phase coils 4U, 4V, 4W made of the wires 3 are arranged in the same-phase slot 5 in which a plurality of (for example, four) wires 3 having the same phase are arranged side by side in the radial direction of the stator core 2. In addition, in the one end side coil end portion 8 protruding from the one end surface 7 in the axial direction L of the stator core 2, a plurality of wires 3 having the same phase are arranged side by side in the radial direction (or axial direction) of the stator core 2. In the other end side coil end portion 10 protruding from the other end surface 9 in the axial direction L, a plurality of wires 3 having the same phase are bent toward the radially inner diameter side of the stator core 2 and arranged side by side in the radial direction of the stator core 2. Yes.

  As a representative example, the U-phase coil 4U is adjacent to the coil 4U in such a way that two sets 4U1 and 4U2 are set so as to occupy two adjacent slots 5 and 5, as shown in FIG. The two slots 5 and 5 are configured such that the closer and far ends of the two slots 5 and 5 are connected with a predetermined distance therebetween, and the two sets are connected alternately. Each set of coils 4U1 and 4U2 projects in the circumferential direction M so as to connect the slot conductor portion 11 disposed in the slot 5 and the slot conductor portion 11 protruding from one end surface 7 of the stator core 2 and spaced apart from each other. One end side coil end portion 8 extending from the other end face 9 of the stator core 2 and the other end side coil end extending in the circumferential direction M by bending in the inner diameter direction R1 so as to be connected to the slot conductor portion 11 separated by a predetermined distance. Part 10. Both coil end portions 8 and 10 are bent in a plurality of circumferential directions (for example, Y) or axial directions (for example, X) so that they are arranged without interfering with each other in the axial direction L or the radial direction R ( It is bent).

  As described above, the coil 4 is bent at a plurality of locations by the coil end portions 8, 10 and the like. Further, in these coil end portions 8 and 10, the coil 4 is bent, and the bent portions are formed in a substantially S shape with different bending directions. The outline of the bending apparatus which shape | molds such coil end parts 8 and 10 is demonstrated with reference to FIG. 3 which shows 1st embodiment of this invention.

<First embodiment>
As shown in FIG. 3, the bending apparatus 12 of the present embodiment is formed by connecting a first jig 13 and a second jig 14 so as to be rotatable about a rotation shaft 15. Then, a material W such as a flat wire constituting the coil 4 is disposed on both the jigs 13 and 14, and the material W is bent by rotating both the jigs 13 and 14.

  Of these, the first jig 13 is fixed with a holding portion 16 that suppresses the displacement of the material W on the side opposite to the rotation direction (upper side in FIG. 3). That is, the restraining surface 17 of the restraining portion 16 is brought into contact with the side surface of the material W to restrain the material W from being displaced upward in FIG.

  Further, an offset bending portion 18 is disposed at a position offset by a predetermined amount from the rotation shaft 15 to the rotation side of the material W of the second jig 14. The offset bending portion 18 uses the outer peripheral surface as a cylindrical surface having a curvature radius substantially the same as the curvature radius of the inner peripheral surface of the material W after bending. It bends along. The offset bending portion 18 may be provided on the first jig 13 side. Further, the shape of the outer peripheral surface is not limited to the shape shown in the drawing as long as at least the portion with which the material W abuts during bending is a cylindrical surface having the above-described curvature radius.

  The second jig 14 includes a base portion 19, a slide portion 20, and a fixed bending portion 21. The base portion 19 is rotatably connected to the first jig 13. The slide portion 20 is supported on the base portion 19 so as to be slidable with respect to the base portion 19 in the direction opposite to the rotation direction. This slide mechanism will be described later. Then, the material W is slid by a predetermined amount with respect to the base 19 during bending. The fixed bending portion 21 is fixed to a position where the offset W bending portion 18 on the base 19 and the material W are sandwiched, and the second jig 14 on the material W side of the substantially rectangular fixed block 22. The corner part which exists in the side (lower left of FIG. 3) is formed in a partial cylindrical shape. For this reason, the fixed bending portion 21 cannot slide with respect to the base portion 19. The radius of curvature of the fixed bending portion 21 is substantially the same as the radius of curvature of the inner peripheral surface of the material W after bending. When the material W is slid by the slide portion 20, the material W is bent along the fixed bending portion 21.

  The slide portion 20 is disposed on the rotation side of the material W, holding portions 23a and 23b for suppressing displacement of both sides of the rotation direction of the material W (in FIG. 3B, both sides in the left-right direction). The slide bending portion 24 bends the material W by sliding the slide portion 20. Of these, the holding parts 23a and 23b hold the material W between the holding surfaces 25a and 25b facing each other, and when the jigs 13 and 14 are rotated and the slide part 20 is slid, The material W is prevented from being displaced on both sides in the rotational direction. Moreover, the slide bending part 24 is the 1st jig | tool 13 side (upper right of FIG. 3) in this material W side of the holding | suppressing part 23a arrange | positioned among the said holding | suppressing parts 23a and 23b at the rotation side of the said material W. ) Are formed in a partial cylindrical shape. The slide bending part 24 may be provided separately from the holding part 23a. Moreover, if the slide bending part 24 is also formed on the holding part 23b side as in the example shown in the drawing, the material W can be used even when the slide part 20 is slid in the same direction as the rotation direction, as will be described later. Can be bent.

  Then, both the jigs 13 and 14 are rotated and the slide part 20 is slid, so that the material W is not displaced with respect to the holding parts 16, 23 a and 23 b constituting the jigs 13 and 14. The material W is bent at three locations. That is, the material W is prevented from being pulled in during bending.

For this purpose, the offset amount of the offset bending portion 18 with respect to the rotation shaft 15 is determined as follows. For convenience of explanation, a case where the material W is bent only by the offset bending portion 18 is considered. As shown in FIG. 4, the bending angle of the material W is θ, the thickness of the material W (diameter when the material W is circular in cross section) is T, and the material W is bent from the neutral line N. The ratio of the distance to the rear inner peripheral surface with respect to T is α, the radius of curvature of the offset bending portion 18 is r, and the distance of the bending center P of the offset bending portion 18 to the rotation center O of the rotation shaft 15 is as follows. Among these, the distance in the direction parallel to the linear direction (X direction, left-right direction in FIG. 4) when the state before bending the material W in the bending direction of the material W is a straight line is X, and also the linear direction When the distance in the direction perpendicular to the direction (Y direction, vertical direction in FIG. 4) is Y, the bending center P is at least after the bending process with respect to the rotation center O.
X = (r + T × α) × θ / 2
Y = (r + T × α) × θ / 2 / tan (θ / 2)
0 <θ ≦ π / 2
It is installed at a position that satisfies

  The above formula will be described. First, if the material W is bent in a state where the bending center P and the rotation center O coincide with each other, the material W is (r + T × α) × θ at the position of the neutral line N. , Move with respect to the first jig 13. That is, the material W is drawn by the circumferential length of the bent portion of the neutral line N. Therefore, in order to prevent the material W from being pulled in during bending, the offset bending portion 18 can be moved along the material W by (r + T × α) × θ before and after bending. It ’s fine. As apparent from FIG. 4, it is not necessary to consider the movement distance of the offset bending portion 18 in the Y direction. In this case, since the offset bending portion 18 is moved around the rotation center O, as is apparent from FIG. 4B, the bending center P is moved in the X direction from the rotation center O. The distance is (r + T × α) × θ / 2, which is half the moving distance of the offset bending portion 18.

  Thus, if the distance in the X direction from the rotation center O of the bending center P is known, the distance (r + T × α) × θ / 2 / tan (θ / 2) in the Y direction can be similarly derived from the trigonometric function. The reason why 0 <θ ≦ π / 2 is defined is that, in the case of the present embodiment, when the bending angle is larger than π / 2, the pull-in of the material W cannot be prevented.

  On the other hand, in the case of the present embodiment, the material W is slid by the slide portion 20 in order to bend the material W at three locations. Therefore, it is necessary to prevent the material W from being pulled even by this slide. For this reason, it is assumed that the direction and amount of movement of the slide portion 20 are not bent by the fixed bending portion 21 and the slide bending portion 24, as shown in FIG. This is determined in consideration of the case of being bent at 24.

  That is, it is assumed that the predetermined points Q and R closer to the second jig 14 than the two bent portions 21 and 24 on the neutral line N of the material W are not bent by the two bent portions 21 and 24. In the case (Q) and the case (R) where the two bent portions 21 and 24 are bent, the slide direction and the slide amount of the slide portion 20 are determined based on the existing positions. The points Q and R are from the point S to the point Q, where S is a predetermined point on the first jig 13 side of the bent portions 21 and 24 on the neutral line N of the material W. The length a of the neutral line N is equal to the length b of the neutral line N from the point S to the point R.

  The point Q may be moved to the point R by the slide of the slide part 20 in order to prevent the material W from being pulled in during bending of the slide part 20 by the slide. Therefore, if the deviation between the point Q and the point R is c in the X direction (left-right direction in FIG. 5) and d in the Y direction (up-down direction in FIG. 5), the slide portion 20 is moved in the X direction. If the material is slid in the c and Y directions, the material W will not be pulled.

  In order to realize the configuration as described above, in the case of the present embodiment, as shown in FIG. 6, the pin 27 provided on the base portion 19 is fitted into the slide hole 26 provided in the slide portion 20, and the By moving the slide hole 26 with respect to the pin 27, the slide portion 20 is slid so as to satisfy the above condition. In addition, you may provide a slide hole in the base 19 side and a pin in the slide part 20 side.

  The slide hole 26 is formed by the following arc. Note that the width of the slide hole 26 is determined by the relationship with the diameter of the pin 27. First, when the point Q is the start point and the point R is the end point, the virtual line H on the virtual line H parallel to the direction in which the material W of the second jig 14 passing through the start point Q is disposed, Let G be the point existing at the same distance from the start point Q and the end point R. The point G exists on the first jig 13 side (the upper side in FIG. 6) from the start point Q. The slide hole 26 is formed along an arc passing through the start point Q and the end point R with the point G as the center. In the present embodiment, there are two portions where the slide hole 26 and the pin 27 engage, but each slide hole 26 is formed along an arc that satisfies the above conditions. Thereby, the slide part 20 slides along the arc. At this time, the pin 27 is relatively displaced along the slide hole 26 between the start point Q and the end point R.

  The slide direction of the slide unit 20 described above may be a direction of a straight line connecting the start point Q and the end point R. However, in order to smoothly slide the slide portion 20 so as not to cause the material W to be pulled in, it is preferable to slide along the arc as described above.

  According to the present embodiment configured as described above, the first jig 13 and the second jig 14 are rotated and the slide portion 20 of the second jig 14 is slid. Since the material W is bent at three locations, the processing time can be shortened. In other words, by continuously or simultaneously performing the rotation of the jigs 13 and 14 and the sliding of the slide portion 20, the material W can be bent at three locations in a short time. On the other hand, for example, when the material W is bent at three locations only by turning both the jigs 13 and 14, it is necessary to shift the material W or change the direction of the material W. It is inevitable that the lengthens. On the other hand, in the case of the present embodiment, it is not necessary to shift the material W or change the direction, so that the processing time can be shortened.

  Further, in the case of the present embodiment, the material W is not displaced with respect to the holding portions 16, 23 a, 23 b constituting the jigs 13, 14 at the time of bending (no pulling occurs), so the material W And the holding portions 16, 23a, 23b can be prevented from being slid, and the material W can be prevented from being damaged. In addition, since the tensile force does not act on the material W during the bending process, the bending process of the material W can be performed accurately.

  Further, even when the material W is a rectangular wire constituting the coil 4 as described above, it is possible to accurately perform the process of bending the three portions of the rectangular wire. That is, unlike a round wire having a circular cross section, a flat wire is limited in the bending direction. In particular, in the case of forming the shape as described above, since the bending direction is different, it is more difficult to bend. On the other hand, in the case of the present embodiment, even with a flat wire with a limited bending direction, the bending process performed by changing the bending direction can be performed easily and accurately. In addition, since no pull-in occurs during the bending process, the insulating enamel layer is not damaged during the bending process, and a high-quality coil 4 for a rotating electrical machine can be obtained.

  In the case of the present embodiment, the slide portion 20 is slid in the opposite direction to the rotational direction of the jigs 13 and 14, and the material W is bent in a substantially S shape. The material W can be bent into another shape by sliding 20 in the same direction as the rotation direction. That is, according to a desired shape, the rotation direction and rotation angle of both jigs 13 and 14 and the slide direction and slide amount of the slide part 20 can be adjusted.

<Second Embodiment>
7 to 13 show a bending machine 28 according to the second embodiment of the present invention, which is a combination of a plurality of bending apparatuses 12 as described above. The configuration of the bending apparatus 12 alone is the same as that of the first embodiment described above. First, the outline of the bending machine 28 of this embodiment is demonstrated with reference to FIG.

  The bending machine 28 includes a plurality of bending apparatuses 12 by alternately connecting the first jigs 13 a and 13 b and the second jigs 14 a, 14 b and 14 c at the center of the rotating shaft 15. They are arranged in series so that the material W can be bent at a plurality of locations. For this purpose, five jigs 13a, 13b, 14a, 14b, and so on are alternately arranged so that the second jigs 14a, 14b, 14c are arranged at both ends of the first jigs 13a, 13b. 14c is rotatably connected. That is, the second jig 14a, the first jig 13a, the second jig 14b, the first jig 13b, and the second jig 14c are connected in order from the lower end of FIG. Yes.

  Further, slide portion abutting members 29a and 29b are fixed to the rotating sides of the first jigs 13a and 13b, respectively. 8 to 13, when the second jigs 14a, 14b, 14c at both ends of the first jigs 13a, 13b are rotated in the directions approaching each other, The slide portions 20a, 20b, and 20c are brought into contact with the slide portion contact members 29a and 29b. The slide contact members 29a and 29b move together with the fixed first jigs 13a and 13b in accordance with the rotation of the jigs. Further, as shown in FIG. 13, each of the slide portions 20a to 20c is further rotated by rotating the second jigs 14a to 14c in a state of being in contact with the slide portion contact members 29a and 29b. Slide in a predetermined direction.

  That is, the slide contact member 29a fixed to the first jig 13a is located at the center of the first jig 13a on the rotating side (right side in FIG. 7) of the second jigs 14a and 14b. Two block-shaped contact column portions 31a and 31b project from the arranged block portion 30a. Then, as sequentially shown in FIGS. 8 to 13, by rotating the second jigs 14a and 14b connected to both ends of the first jig 13a, the respective slide parts 20a and 20b are moved. The abutting cylindrical portions 31a and 31b are brought into contact with each other so as to sandwich them. In this state, as shown in FIG. 13, by further rotating the second jigs 14a and 14b, the slide portions 20a and 20b are brought into contact with the column contact portions 31a and 31b. Based on each, it slides on the opposite side to the rotation direction. It should be noted that at least one of the cylindrical contact portions 31a and 31b may be present, but a plurality of the cylindrical contact portions 31a and 31b are preferably arranged in order to slide the slide portions 20a and 20b more reliably.

  The base portions 19a and 19b constituting the second jigs 14a and 14b are formed with notches 32 and 32 at positions aligned with the contact cylindrical portions 31a and 31b on the side surfaces on the rotation side. And when the applicable cylindrical part 31a, 31b contacts and slides on the slide parts 20a, 20b, the corresponding cylindrical part 31a, 31b is prevented from interfering with the base parts 19a, 19b.

  Further, the slide contact member 29b fixed to the first jig 13b is located at the center of the first jig 13b on the rotating side (left side in FIG. 7) of the second jigs 14b and 14c. Two protrusions 33a and 33b are provided on both sides of the arranged block part 30b. Then, as sequentially shown in FIGS. 8 to 13, by rotating the second jigs 14b and 14c connected to both ends of the first jig 13b, the respective slide parts 20b and 20c are moved. The protrusions 33a and 33b are brought into contact with each other so as to sandwich the protrusions 33a and 33b. In this state, as shown in FIG. 13, by further rotating the second jigs 14b and 14c, the slide portions 20b and 20c are brought into contact with the projections 33a and 33b. Slide in the direction opposite to the rotation direction. The protrusions 33a and 33b only need to exist at least on both sides of the block 30b, but a plurality of protrusions 33a and 33b are preferably arranged in order to slide the slides 20a and 20b more reliably.

  Here, the slide portion 20b of the second jig 14b disposed in the middle is pushed in the opposite direction between the first jig 13a side and the first jig 13b side as shown by arrows in FIG. It is. For this reason, it is conceivable to divide the slide portion 20b into a configuration as shown in FIG. 14, but in this configuration, the material W is not tied in the same straight line as shown in FIG. Therefore, the structure shown in FIG. 14 cannot be adopted.

  Therefore, in the case of the present embodiment, the second jig 14b disposed in the middle has two base portions 19b and 19c that are divided and relatively displaceable, and spans between the base portions 19b and 19c. Thus, a single slide portion 20b is arranged. In the bending process, the base portions 19b and 19c are relatively displaced to allow the single slide portion 20b to slide relative to the base portions 19b and 19c.

  Further, as shown in FIG. 13, the middle second jig 14b is rotated to a position adjacent to the arrangement direction of the material W of the first jig 13a (lower side of FIGS. 7 to 13). In this case, a base contact member 34 that contacts the one base 19c constituting the middle second jig 14b is disposed. In this state, by further rotating the second jig 14b in the middle, the first jig 13b connected to the one base portion 19c and the first jig 13b are connected via the first jig 13b. Together with the second jig 14c at the end, the one base 19c is displaced with respect to the other base 19b constituting the middle second jig 14b. As a result, the single slide portion 20b is displaced relative to the one base portion 19c on the side opposite to the rotating side.

  In other words, in the case of the present embodiment, the single slide portion 20b has the slide portion abutting member 29a when the middle second jig 14b rotates with respect to the first jig 13a. Is displaced to the right side of FIG. Further, the one base portion 19c comes into contact with the base contact member 34 and is displaced to the right in FIG. At this time, when the second jig 14b in the middle rotates with respect to the first jig 13b, the single slide part 20b comes into contact with the slide part contact member 29b, and the The single slide portion 20b is prevented from being displaced together with the one base portion 19c. As a result, the single slide portion 20b is displaced to the left in FIG. 13 relative to the one base portion 19c. In order to realize such an operation, the amount of protrusion of the protrusions 33a and 33b of the slide portion contact member 29b is displaced to the right in FIG. 13 by the first jig 13b together with the one base portion 19c. Determine the amount to be determined.

  Thus, in the case of the present embodiment, since the base portions 19b and 19c constituting the second jig 14b in the middle are divided so as to be relatively displaceable, even if the slide portion 20b is single, the slide portion 20b can be slidable with respect to the base portions 19b and 19c. And since this slide part 20b can be made single, the raw material W can be tied together in the same straight line shape, and the problem as shown in above-mentioned FIG. 14 does not arise.

  Moreover, the base 19d which comprises the 2nd jig | tool 14c of the said edge part has provided the finishing pressing member 35 so that it may protrude in the rotation direction side. As shown in FIG. 13, the finishing pressing member 35 comes into contact with the other base portion 19b of the second jig 14b at the center when the rotation of each jig is finished. From this state, the finish pressing member 35 is pressed against the other base 19b by further rotating the second jig 14c at the end. Thereby, each slide part 20a thru | or 20c which comprises each 2nd jig | tool 14a thru | or 14c is slid reliably to a predetermined position, The bending process of the raw material W can be performed accurately and reliably. .

  Note that the slide part abutting members 29a and 29b described above may be configured by protruding members provided on the side surfaces on the rotating side of the slide parts 20a to 20c, similarly to the finishing pressing member 35 described above. In this case, the projecting member may be provided on at least one of the slide portions facing each other at the time of rotation. Then, the projecting members are brought into contact with the opposed slide portions, and the opposed slide portions are slid to the opposite sides.

  According to the bending machine 28 of the present embodiment as described above, it is possible to perform bending in a substantially S shape at each of the four locations of the material W. That is, a total of twelve bending processes can be performed almost simultaneously with the single bending machine 28 without removing the material W or changing the direction. For this reason, a complicated bending shape can be manufactured accurately and in a short time, and the manufacturing cost can be reduced.

  That is, each bending apparatus 12 constituting the bending machine 28 does not pull in when the material W is bent as described in the first embodiment. For this reason, even if a plurality of such bending devices 12 are combined and bending is performed simultaneously on a plurality of locations of the material W, the material W is not pulled. Accordingly, even when bending is performed on a plurality of locations of the material W at the same time, the dimensions of the material W do not change, and a complicated bending shape can be obtained with high accuracy and in a short time.

  Furthermore, if the coil 4 for a rotating electrical machine as shown in FIGS. 1 and 2 is manufactured by the bending machine 28 according to the present embodiment, the number of joints of the coil 4 can be reduced, thereby reducing the manufacturing cost. In addition, the coil 4 can be reduced in size. That is, if bending is performed on the material W as described above, a large number of bent portions can be formed by one processing, so the materials after bending are joined by welding or the like, as shown in FIG. When a simple coil 4 is obtained, the number of joints can be reduced and the manufacturing cost can be reduced. If the number of joints can be reduced, the distance between the coils 4 can be reduced, and the entire coil 4 can be reduced in size.

DESCRIPTION OF SYMBOLS 1 Stator 2 Stator core 3 Magnet wire 4 Coil 5 Slot 6 Teeth 7 One end surface 8 One end side coil end part 9 Other end side 10 Other end side coil end part 11 Slot conductor part 12 Bending apparatus 13, 13a, 13b First jig 14, 14a, 14b, 14c Second jig 15 Rotating shaft 16 Holding portion 17 Holding surface 18 Offset bending portion 19, 19a, 19b, 19c, 19d Base portion 20, 20a, 20b, 20c Slide portion 21 Fixed bending portion 22 Fixed block 23a, 23b Holding part 24 Slide bending part 25a, 25b Holding surface 26 Slide hole 27 Pin 28 Bending machine 29a, 29b Slide part contact member 30a, 30b Block part 31a, 31b Contact cylindrical part 32 Notch 33a, 33b Projection 34 Base contact member 35 Finish pressing member W Material

Claims (9)

In a bending machine that bends a given material at three locations,
A first jig and a second jig that are rotatably connected around a rotation axis;
Arranged on either the first jig or the second jig, offset by a predetermined amount from the rotation axis to the rotation side of the material, and by rotating both the jigs, the material An offset bending portion for bending,
The first jig has a holding portion that suppresses displacement of the material on the side opposite to the rotation direction,
The second jig includes a base that is pivotally connected to the first jig, a slide that slides the material by a predetermined amount relative to the base, and a base that is fixed to the base. A fixed bending portion for bending the material by sliding,
The slide part includes a holding part that suppresses displacement on both sides of the rotation direction of the material, and a slide bending part that bends the material by sliding the slide part,
The two jigs are rotated and the slide portion is slid, and the material is bent at three points without displacing the material with respect to the holding portions constituting the jigs. Bending machine.   The direction and amount of movement of the slide portion are determined so that a predetermined point on the second jig side of the fixed bending portion and the slide bending portion on the neutral line of the material is not bent at both bending portions. The bending apparatus according to claim 1, wherein the bending apparatus is determined based on positions existing in an assumed case and in a case where the bending portion is bent at both bending portions. The position where the predetermined point exists when it is assumed that the fixed bending portion and the slide bending portion are not bent is the start point, and the position where the predetermined point exists when the bending point is bent is the end point. If
The slide part is centered on a point existing at the same distance from the start point and the end point on an imaginary line parallel to a direction in which the material of the second jig passing through the start point is disposed, and the start point and end point The bending apparatus according to claim 2, wherein the bending apparatus slides along an arc passing through.   The slide portion slides on the opposite side of the rotation direction with respect to the base portion, the fixed bending portion is disposed at a position sandwiching the offset bending portion and the material, and the slide bending portion is rotated about the material. The bending apparatus of any one of Claims 1 thru | or 3 arrange | positioned by the side.   The bending apparatus according to any one of claims 1 to 4, wherein the predetermined material is a rectangular wire constituting a coil for rotating electric motor.   A plurality of bending apparatuses according to any one of claims 1 to 5 are connected in series by alternately connecting the first jig and the second jig at the rotation center. The bending machine is characterized in that the predetermined material can be bent at a plurality of locations. The second jig is rotatably connected to both ends of the first jig,
When the second jigs are rotated in a direction approaching each other, provided with slide part contact members that contact the respective slide parts,
The second jigs are further rotated, and the second jigs are further rotated in a state where the slide parts of the second jigs are in contact with the slide part contact members, respectively. The bending machine according to claim 6, wherein each slide part is slid in a direction opposite to the rotation direction. The first jig and the second jig are alternately connected to five jigs so that the second jig is arranged at both ends of the first jig.
Among the jigs, the second jig arranged in the middle is divided into two base parts that can be divided and relatively displaced, and a single slide part arranged so as to span between the two base parts, Have
The bending machine according to claim 6 or 7, wherein the single slide part slides with respect to both the base parts by the relative displacement of the both base parts during the bending process. A base abutting member that abuts one of the bases constituting the middle second jig when the middle second jig is rotated;
The second jig in the middle is rotated, and the second jig in the middle is further rotated in a state where the one base is in contact with the base abutting member. Along with the first jig connected to the base and the second jig at the end connected via the first jig, the one base has the second jig in the middle. The bending machine according to claim 8, wherein the bending machine is displaced with respect to the other base portion.

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