US20100000624A1 - Edgewise bending processing method for rectangular wire and bending processing apparatus - Google Patents
Edgewise bending processing method for rectangular wire and bending processing apparatus Download PDFInfo
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- US20100000624A1 US20100000624A1 US12/374,831 US37483108A US2010000624A1 US 20100000624 A1 US20100000624 A1 US 20100000624A1 US 37483108 A US37483108 A US 37483108A US 2010000624 A1 US2010000624 A1 US 2010000624A1
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Classifications
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02K—DYNAMO-ELECTRIC MACHINES
- H02K15/00—Methods or apparatus specially adapted for manufacturing, assembling, maintaining or repairing of dynamo-electric machines
- H02K15/04—Methods or apparatus specially adapted for manufacturing, assembling, maintaining or repairing of dynamo-electric machines of windings, prior to mounting into machines
- H02K15/0435—Wound windings
- H02K15/0442—Loop windings
- H02K15/045—Form wound coils
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01F—MAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
- H01F41/00—Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties
- H01F41/02—Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties for manufacturing cores, coils, or magnets
- H01F41/04—Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties for manufacturing cores, coils, or magnets for manufacturing coils
- H01F41/06—Coil winding
- H01F41/077—Deforming the cross section or shape of the winding material while winding
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01F—MAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
- H01F41/00—Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties
- H01F41/02—Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties for manufacturing cores, coils, or magnets
- H01F41/04—Apparatus or processes specially adapted for manufacturing or assembling magnets, inductances or transformers; Apparatus or processes specially adapted for manufacturing materials characterised by their magnetic properties for manufacturing cores, coils, or magnets for manufacturing coils
- H01F41/06—Coil winding
- H01F41/082—Devices for guiding or positioning the winding material on the former
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02K—DYNAMO-ELECTRIC MACHINES
- H02K15/00—Methods or apparatus specially adapted for manufacturing, assembling, maintaining or repairing of dynamo-electric machines
- H02K15/08—Forming windings by laying conductors into or around core parts
- H02K15/095—Forming windings by laying conductors into or around core parts by laying conductors around salient poles
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02K—DYNAMO-ELECTRIC MACHINES
- H02K3/00—Details of windings
- H02K3/04—Windings characterised by the conductor shape, form or construction, e.g. with bar conductors
- H02K3/12—Windings characterised by the conductor shape, form or construction, e.g. with bar conductors arranged in slots
- H02K3/14—Windings characterised by the conductor shape, form or construction, e.g. with bar conductors arranged in slots with transposed conductors, e.g. twisted conductors
-
- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02K—DYNAMO-ELECTRIC MACHINES
- H02K3/00—Details of windings
- H02K3/04—Windings characterised by the conductor shape, form or construction, e.g. with bar conductors
- H02K3/18—Windings for salient poles
-
- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01F—MAGNETS; INDUCTANCES; TRANSFORMERS; SELECTION OF MATERIALS FOR THEIR MAGNETIC PROPERTIES
- H01F17/00—Fixed inductances of the signal type
- H01F17/04—Fixed inductances of the signal type with magnetic core
- H01F17/045—Fixed inductances of the signal type with magnetic core with core of cylindric geometry and coil wound along its longitudinal axis, i.e. rod or drum core
- H01F2017/046—Fixed inductances of the signal type with magnetic core with core of cylindric geometry and coil wound along its longitudinal axis, i.e. rod or drum core helical coil made of flat wire, e.g. with smaller extension of wire cross section in the direction of the longitudinal axis
Definitions
- the present invention relates to a technique of edgewise bending a rectangular-section wire and particularly to a technique of restraining an inner periphery part of the wire from bulging in an edgewise bending process.
- a coil having continuous bend portions and linear portions can be produced in such a way as to intermittently pressurize the wire with use of two conical rollers.
- the rectangular-section wire When the straight long, rectangular-section wire is rolled with the conical rollers, the rectangular-section wire is shaped to conform to a trapezoidal space in cross-section formed between the two conical rollers so that the wire has a cross section thin at the outer periphery and thick at the inner periphery.
- a material forming the outer periphery part is squeezed forward and backward, extending the rolled portion, thereby forming a bend (a corner).
- This partial rolling using the conical rollers could consequently produce the coil having continuous bend portions and linear portions.
- the rectangular-section wire is entirely coated with an insulation material.
- JP 2006-288025A discloses a rectangular coil, a manufacturing method for the rectangular coil, and a manufacturing device for the same, whereby a rectangular-section wire is wound edgewise with a jig while an inner side of the wire is supported by a roller. This technique could prevent the inner side of the coil from bulging in the edgewise bending process, thereby avoiding variations in electrical resistance.
- the bend portion of the wire is thin at the outer periphery and thick at the inner periphery.
- the edgewise bending process causes the same principle as that in JP'860A in which the rectangular-section wire is bent with the conical rollers.
- the bend portion at the outer periphery is extended under pressure in the edgewise bending process, which constricts the bend portion at the inner periphery side, causing transfer of the material forming the wire, resulting in a change in thickness.
- the coil is produced in such a manner that a rectangular-section wire previously coated with an insulation coating is inserted in a groove of a roller, the groove having a width equal to the thickness of the wire, and then the wire is bent edgewise with a bending jig, thereby preventing the coil at the inner periphery side from bulging.
- a motor used for driving a vehicle has been required especially to be reduced in size and increased in output power. Therefore, there is an increasingly demand for higher space factor of a conductor to a slot of a rotor or stator.
- the bend portion of the coil made of the rectangular-section wire is purposely deformed into a trapezoidal shape in cross-section.
- the bend portion is thick at the inner periphery and thin at the outer periphery, causing adjacent rectangular-section wires to interfere with one another at the inner periphery side. Consequently, the conductor could not provide a higher space factor to the slot.
- the roller having the groove with a width equal to the length of the short side of the rectangular-section wire in cross-section is used for edgewise bending to solve the problem in JP'860A.
- the edgewise bending of the rectangular-section wire with the roller having the groove with a width equal to the length of the short side of the wire in cross-section could avoid deformation of the rectangular-section wire in a plastic region.
- JP'025A caused a slight increase in length of the short side of the rectangular-section wire. It was therefore found that the space factor of the coil to the slot could not be sufficiently enhanced.
- the increase in length of the short side of the rectangular-section wire resulting from the elastic deformation in the edgewise bending process is just slight.
- the rectangular-section wire has to be wound over ten turns to form a coil and accordingly the increase in length of the short side of the wire is accumulated. This results in a decrease in the space factor of the conductor to the slot.
- the present invention is made in view of the above circumstances and has an object to provide an edgewise bending processing method for a rectangular-section wire and a processing apparatus, whereby an increase in length of a short side of the wire at an inner periphery can be minimized in an edgewise bending process.
- the present invention provides an edgewise bending processing method for a rectangular-section wire comprising the steps of: restraining the rectangular-section wire having a rectangular cross section with long sides and short sides by restraining means in such a way as to press a surface of the wire including the long side and hold the wire in contact with a surface of the wire including the short side; and edgewise bending the rectangular-section wire by bending means; wherein the restraining means restrains part of the wire in a restraining dimension that is shorter than a length of the short side of the wire and in a range of elastic deformation of the wire, and the bending means bends the wire edgewise at the short side of the wire that is in contact with the restraining means.
- the rectangular-section wire is coated with a coating material.
- the restraining means includes a flange whereby the surface of the rectangular-section wire including the long side is pressed, a base provided facing the flange, a shaft inserted through the base, and a spacer having thickness corresponding to the restraining dimension, and the spacer is formed with a chamfer at a corner facing a joint part joining the shaft and the flange.
- One of the methods (1) to (3) preferably, comprises: a first step of feeding the rectangular-section wire by feeding means; a second step of holding the wire in place by clamp means and restraining the wire by the restraining means; a third step of edgewise bending the wire by the bending means while the wire is held by the clamp means; and a fourth step of releasing the rectangular-section wire from the clamp means and the restraining means; the first to fourth steps being repeatedly performed.
- the present invention provides an edgewise bending processing apparatus for rectangular-section wire, the apparatus comprising: restraining means for restraining the rectangular-section wire having a rectangular cross section with long sides and short sides in such a way as to press a surface of the wire including the long side and hold the wire in contact with a surface of the wire including the short side; and bending means for edgewise bending the rectangular-section wire; wherein the restraining means restrains part of the wire in a restraining dimension that is shorter than a length of the short side of the wire and in a range of elastic deformation of the wire, and the bending means bends the wire edgewise at the short side of the wire that is in contact with the restraining means.
- the restraining means includes a flange whereby the surface of the rectangular-section wire including the long side is pressed, a base provided facing the flange, a shaft inserted through the base, and a spacer having thickness corresponding to the restraining dimension, and the spacer is formed with a chamfer at a corner facing a joint part joining the shaft and the flange.
- the above edgewise bending processing method (1) for a rectangular-section wire comprises the steps of: restraining the rectangular-section wire having a rectangular cross section with long sides and short sides by restraining means in such a way as to press a surface of the wire including the long side and hold the wire in contact with a surface of the wire including the short side; and edgewise bending the rectangular-section wire by bending means; wherein the restraining means restrains part of the wire in a restraining dimension that is shorter than a length of the short side of the wire and in a range of elastic deformation of the wire, and the bending means bends the wire edgewise at the short side of the wire that is in contact with the restraining means.
- Some coils to be used for a motor are produced by edgewise bending a rectangular-section wire.
- this rectangular-section wire is made of a metal conductor such as copper.
- the restraining dimension of the rectangular-section wire by the restraining means in the edgewise bending process is determined in consideration of the elastic deformation range of the rectangular-section wire so that the restraining dimension is shorter than the short side of the wire in anticipation of a restoration amount resulting from elastic deformation.
- the length of the short side of the wire can be maintained equally before and after the edgewise bending process.
- the configuration that the length of the short side of the rectangular-section wire can be maintained in the edgewise bending process is important in a case where dimensional accuracy is required in edgewise bending the rectangular-section wire.
- a coil to be used in a stator of a vehicle motor is essentially required to enhance a coil space factor when it is placed in a slot of the stator.
- the elastic deformation has little influence on each of the rectangular-section wires bent edgewise.
- the coil space factor depends on the accuracy because the coil has to be mounted in the slot.
- the space factor of the coil to the slot changes by several percent, which was confirmed by the applicant.
- the coil space factor is desired to increase in consideration of even the influence of the elastic deformation.
- the rectangular-section wire is coated with the coating material. Accordingly, the length of the short side of the wire is influenced by elastic deformation of the coating material in the edgewise bending process and thus tends to increase after the edgewise bending process due to elastic deformation.
- this wire is often made of a copper conductor coated with an insulation coating resin material.
- the insulation coating material is made of for example enamel, polyamide, and amideimide, which tend to largely change in dimension by elastic deformation.
- Resin generally has a higher elastic deformation ratio than metal.
- the length of the short side of the wire is likely to increase because the elastically deformed portion of the bend part of the wire is restored after the edgewise bending process.
- the restraining dimension by the restraining means for edgewise bending is preferably determined in consideration of the elasticity of not only the copper material of the rectangular-section wire but also of the insulation coating material. This makes it possible to maintain the length of the short side of the rectangular-section wire equally before and after the edgewise bending process.
- the restraining means includes a flange whereby the surface of the rectangular-section wire including the long side is pressed, a base provided facing the flange, a shaft inserted through the base, and a spacer having thickness corresponding to the restraining dimension, and the spacer is formed with a chamfer at a corner facing a joint part joining the shaft and the flange.
- the restraining dimension can be ensured by the spacer to always restrain the rectangular-section wire in a constant dimension. It is further possible to determine the dimension in anticipation of the length of the short side of the rectangular-section wire after the edgewise bending.
- the use of the spacer can restrict tilting of the flange, allowing the rectangular-section wire to be bent edgewise without any influence of extension of the shaft and depression of the base.
- the joint part between the shaft and the flange has to be formed with a rounded portion to prevent stress concentration therein. This rounded portion may have an influence on forming of the rectangular-section wire.
- the use of the spacer can prevent the rectangular-section wire from being influenced by such joint part between the shaft and the flange.
- the spacer is formed with a chamfer at a corner facing the joint part between the flange and the shaft. Accordingly, the spacer is prevented from coming into contact with the rounded portion of the joint part formed to mitigate stress concentration.
- a first step of feeding the rectangular-section wire by feeding means a second step of holding the wire in place by clamp means and restraining the wire by the restraining means; a third step of edgewise bending the wire by the bending means while the wire is held by the clamp means; and a fourth step of releasing the rectangular-section wire from the clamp means and the restraining means.
- the first step can be performed just after the fourth step, effectively enabling repetition of the edgewise bending steps.
- the feeding means arranged to feed the rectangular-section wire in the first step is constituted of a mechanism independently of the restraining means and the bending means. While the second to fourth steps are being conducted, the feeding means is preferably returned to the original position. Accordingly, the first step can be started just after termination of the fourth step.
- the apparatus comprises: restraining means for restraining the rectangular-section wire having a rectangular cross section with long sides and short sides in such a way as to press a surface of the wire including the long side and hold the wire in contact with a surface of the wire including the short side; and bending means for edgewise bending the rectangular-section wire; wherein the restraining means restrains part of the wire in a restraining dimension that is shorter than a length of the short side of the wire and in a range of elastic deformation of the wire, and the bending means bends the wire edgewise at the short side of the wire that is in contact with the restraining means. Even when the rectangular-section wire having been bent edgewise is released from the restraining means and the elastically deformed portion of the wire is returned to its original shape, the increase in length of the short side of the wire can be prevented.
- the restraining means includes a flange whereby the surface of the rectangular-section wire including the long side is pressed, a base provided facing the flange, a shaft inserted through the base, and a spacer having thickness corresponding to the restraining dimension, and the spacer is formed with a chamfer at a corner facing a joint part joining the shaft and the flange.
- the restraining dimension by the restraining means is determined depending on the thickness (height) of the spacer. Accordingly, no dimensional error is caused due to mechanical changes of the restraining means. It is therefore possible to prevent an increase in length of the short side of the rectangular-section wire with high accuracy after the edgewise bending process.
- FIG. 1 is a schematic configuration view of an edgewise bending processing apparatus of a preferred embodiment
- FIG. 2 is a sectional view of a bending unit, taken along a line A-A in FIG. 1 ;
- FIG. 3 is an external perspective view of a coil produced by the edgewise bending processing apparatus of the embodiment
- FIG. 4 is a schematic plan view showing a state where a rectangular-section wire is bent edgewise by the edgewise bending processing apparatus
- FIG. 5 is a schematic plan view showing a state where an external guide returns to its original position to release the rectangular-section wire
- FIG. 6 is a schematic plan view showing a state where the rectangular-section wire is fed by a feeding mechanism to edgewise bend a second portion of the wire;
- FIG. 7 is a schematic plan view showing a state where the second portion of the rectangular-section wire is bent edgewise
- FIG. 8 is a schematic plan view showing a state where a fourth portion of the rectangular-section wire is bent edgewise
- FIG. 9 is an enlarged sectional view showing a state where the rectangular-section wire is pressed by a flange.
- FIG. 10 is a graph showing a relationship between elastic deformation and surface pressure of the rectangular-section wire in the present embodiment.
- FIG. 1 is a schematic configuration view of the edgewise bending processing apparatus of the present embodiment.
- An edgewise bending processing apparatus 50 includes an uncoiler 51 holding a bobbin around which a rectangular-section wire (hereinafter, simply referred to as a “wire”) 15 having a rectangular section is wound, a feeding mechanism 52 serving to a feeding means for unwinding and feeding the wire 15 from the bobbin, a clamp mechanism 53 serving as a clamp means for holding the wire 15 against movement in a feeding direction, and a bending unit 55 serving as a bending means for performing edgewise bending.
- the bending unit 55 is coupled to a rotary drive mechanism 54 placed adjacent to the bending unit 55 via gears or the like for drive transmission.
- the feeding mechanism 52 is arranged to reciprocally move to unwind the wire 15 from the uncoiler 51 .
- This feeding mechanism 52 is configured to chuck the wire 15 and then feed it at a constant rate.
- the positioning accuracy to feed the wire 15 is important. Accordingly, the feeding mechanism 52 is preferably a mechanism enabling positioning with high accuracy, such as a servo motor.
- the wire 15 wound on the bobbin is made of a strip-shaped material having low electrical resistance such as copper.
- the surface thereof is coated with an insulation coating 15 a .
- the coating 15 a has a thickness of several tens ⁇ m and is made of a high-insulation resin material such as enamel, polyamide, and amideimide.
- the clamp mechanism 53 is arranged to hold the wire 15 against movement in the feeding direction after the wire 15 has been fed by a predetermined distance by the feeding mechanism 52 .
- the feeding mechanism 52 has to return to the original position after feeding the wire 15 and thus to unchuck the wire 15 once. Prior to the unchucking, the wire 15 is clamped by the clamp mechanism 53 to prevent positional displacement.
- FIG. 2 is a sectional view of the bending unit 55 , taken along a line A-A in FIG. 1 .
- the bending unit 55 includes a base 56 , a restraining mechanism 57 , a spacer 58 , a rotating mechanism 60 , and an external guide- 59 attached to the rotating mechanism 60 .
- An outer periphery of the rotating mechanism 60 engages with gears for transmission of rotation force of the rotary drive mechanism 54 to the rotating mechanism 60 . Accordingly, when the rotary drive mechanism 54 is driven, the rotating mechanism 60 is rotated.
- a rotation angle of the rotating mechanism 60 has only to allow edgewise bending of the wire 15 .
- the wire 15 is to be bent at an angle of 90° and thus the rotation angle of the rotating mechanism 60 is set at 90°. It is to be noted that the rotation angle may be set at more than 90° in consideration of springback of the wire 15 .
- the restraining mechanism 57 includes a flange 57 a and a shaft 57 b which are integrally formed.
- the restraining mechanism 57 is arranged to be movable in a vertical direction with respect to the base 56 . When moved toward the base 56 , the restraining mechanism 57 compresses part of the wire 15 to reduce the thickness (length) of a short side thereof.
- the spacer 58 is a cylindrical member placed around the shaft 57 b and has a thickness (height in FIG. 2 ) equal to the dimension for restraining the wire 15 . This restraining dimension will be mentioned later.
- the spacer 58 is circumferentially formed with a chamfer 58 a at a corner facing the flange 57 a . Specifically, this chamfer 58 a faces a joint part 57 d joining the flange 57 a and the shaft 57 b of the restraining mechanism 57 to avoid contact with a rounded portion of the joint part 57 d.
- the rotating mechanism 60 is provided with bearings or the like so that the rotating mechanism 60 is rotatable with respect to the base 56 .
- the external guide 59 is moved in association with the rotation of the rotating mechanism 60 .
- the external guide 59 is also movable in a direction perpendicular to the shaft 57 b so that the external guide 59 is moved toward the shaft 57 b in holding and restraining the wire 15 .
- the rotating mechanism 60 is rotated by the rotary drive mechanism 54 , thereby edgewise bending the wire 15 .
- the edgewise bending processing apparatus 50 of the present embodiment having the above configuration is operated to produce a coil as follows.
- FIG. 3 is a perspective external view of the coil 10 produced by the edgewise bending processing apparatus 50 .
- the coil 10 is made in such a manner that the wire 15 is bent edgewise. Specifically, the wire 15 is wound for fifteen turns between a start end 10 a and a last end 10 b .
- the shape of the coil 10 is determined to meet a desired shape for a stator or rotor of a motor not shown.
- teeth (a tooth) of the stator has a trapezoidal shape tapering toward the center of the stator. Accordingly, a first turn of the wire 15 on the start end 10 a side is different in length of one turn from a fifteenth turn on the last end 10 b side. Concretely, the fifteenth turn is shorter than the first turn.
- This configuration may be changed appropriately according to the specifications of the motor. It is of course possible to appropriately change the number of turns and which end, 10 a or 10 b , should be placed on the inner side of the stator or rotor.
- FIG. 4 is a schematic plan view showing a state where the wire 15 is bent edgewise.
- FIG. 5 is a schematic plan view showing a state where the external guide 59 returns to the original position to release the wire 15 .
- FIG. 6 is a schematic plan view showing a state where the wire 15 is fed by the feeding mechanism 52 .
- FIG. 7 is a schematic plan view showing a state where a second portion of the wire 15 is bent edgewise to form a second corner.
- FIG. 8 is a schematic plan view showing a state where a fourth portion of the wire 15 is bent edgewise to form a fourth corner.
- the wire is unwound from the uncoiler 51 as shown in FIG. 1 and fed by a predetermined length (distance) by the feeding mechanism 52 .
- the feeding mechanism 52 holds part of the wire 15 by a chuck and feeds it by the predetermined length by the drive mechanism. This length is determined according to the shape of the coil 10 .
- the wire 15 having been fed by the predetermined length is held against movement by the clamp mechanism 53 .
- the chuck of the feeding mechanism 52 is then unlocked and the restraining mechanism 57 and the external guide 59 are moved into contact with the wire 15 to restrain it in the following manner.
- the restraining mechanism 57 includes a lifting mechanism. This lifting mechanism moves the flange 57 a of the restraining mechanism 57 to press part of a surface of the wire 15 including a long side in section.
- the height of the flange 57 a is restricted by the height of the spacer 58 surrounding the shaft 57 b .
- the height of the spacer 58 is slightly shorter than the length of the short side (i.e. the thickness) of the wire 15 . This dimension is explained below referring to FIGS. 9 and 10 .
- FIG. 9 is an enlarged sectional view showing a state where the wire 15 is partly pressed by the flange 57 a.
- the wire 15 is constituted of a copper material 15 b having a rectangular cross section with two opposite short sides A 1 and two opposite long sides B and an insulation coating 15 a entirely coating the material 15 b .
- the flange 57 a restrains the wire 15 by compressing part of the wire 15 , reducing the length of the short side thereof.
- a compression amount (distance) A 2 at that time is set in an elastic deformation range of each of the insulation coating 15 a and the copper material 15 b.
- FIG. 10 is a graph showing a relationship between elastic deformation and surface pressure.
- a vertical axis indicates a returning amount (distance) resulting from the elastic deformation and a lateral axis indicates surface pressure D applied in a direction along the short side A 1 , that is, applied on the surface of the wire 15 including the long side B (the upper surface in FIG. 9 ).
- the insulation coating 15 a is made of enamel.
- the graph also indicates an elastic restoration amount “bd” of copper (“copper elastic restoration amount bd”), which is a returning amount of the copper material 15 b by its elasticity, an elastic restoration amount “be” of enamel (“enamel elastic restoration amount be”), which is a returning amount of the insulation coating 15 a by its elasticity, and a total elastic restoration amount “bd+be” which is a total returning amount of the wire 15 .
- the copper elastic restoration amount “bd” is calculated by dividing the thickness of the copper material 15 b by an elasticity coefficient Ed of copper (“copper elasticity coefficient Ed”) and multiplying a result by the surface pressure D.
- the enamel elastic restoration amount “be” is calculated by dividing the thickness of the insulation coating 15 a by an elasticity coefficient Ee of enamel (“enamel elasticity coefficient Ed”) and multiplying a result by the surface pressure D.
- the surface pressure D applied in the direction along the short side A 1 is determined by analysis of a contact area between the wire 15 and the flange 57 a and others.
- the compression amount A 2 can be determined from the graph showing the total elastic restoration amount “bd+be”.
- the compression amount A 2 is determined by an intersection point of a straight line representing the total elastic restoration amount “bd+be” and a dashed line representing the maximum value X.
- the wire 15 is also pressed by the external guide 59 .
- the guide 59 is in a standby position prior to feeding of the wire 15 so as to allow the wire 15 to be easily fed.
- the guide 59 is moved to a predetermined position after feeding of the wire 15 and pressed by the restraining mechanism 57 .
- the feeding mechanism 52 is unchucked and returned to its original position. This returning to the original position is preferably performed during the following third step.
- the wire 15 is bent edgewise.
- the rotating mechanism 60 is rotated and accordingly the external guide 59 attached on the upper surface of the rotating mechanism 60 is moved while pressing the surface of the wire 15 including the short side A 1 .
- the rotation of the rotating mechanism 60 is caused by power transmitted from the rotary drive mechanism 54 .
- the rotating mechanism 60 is rotatably supported by the base 56 via the bearings or the like and therefore is rotated by the rotary drive mechanism 54 .
- the wire 15 is restrained by the flange 57 a so that the length of the short side (thickness) of the wire 15 is reduced by the compression amount A 2 .
- the wire 15 is pressed by the guide 59 into a clearance defined by the lower surface of the flange 57 a and the upper surface of the base 56 .
- the flange 57 a has a round, lower outer periphery 57 c , so that the wire 15 is smoothly pressed into the clearance between the lower surface of the flange 57 a and the upper surface of the base 56 . Since the compression amount A 2 is about several tens ⁇ m, the above configuration can achieve the edgewise bending process.
- a fourth step the restraining mechanism 57 and the external guide 59 which restrain the wire 15 are moved to release the wire 15 as follows.
- the external guide 59 is moved to the standby position and the rotating mechanism 60 is rotated back to the original position.
- the restraining mechanism 57 is moved apart from the wire 15 to release the restraining force thereon.
- the feeding mechanism 52 chucks the wire 15 and then the clamp mechanism 53 is released.
- the wire 15 is fed by the predetermined length again by the feeding mechanism 52 . This state is shown in FIG. 6 .
- the third step is performed to edgewise bend a second portion of the wire 15 as shown in FIG. 7 , forming a second corner.
- the wire 15 is fed accurately by the feeding mechanism 52 and therefore the wire 15 can be bent edgewise at predetermined portions.
- the edgewise bending processing apparatus 50 of the present embodiment having the above configurations and operations can exhibit the following advantages.
- the coil 10 can be produced without bulging at the inner periphery.
- edgewise bending process for edgewise bending the wire 15 by use of the flange 57 a spaced at a fixed distance from the upper surface of the base 56 , it is possible to prevent the coil 10 from bulging at the inner periphery due to plastic deformation.
- the edgewise bending process is performed by pressing part of the wire 15 which will form the inner periphery part of the coil 10 to reduce the short side of the wire 15 to a length (A 1 (the short side) ⁇ A 2 (the compression amount)). Accordingly, the coil 10 can be prevented from bulging at the inner periphery due to elastic deformation.
- the wire 15 is bent edgewise as above with its part being pressed by the restraining mechanism 57 in consideration of the elastic deformation of the wire 15 . After the edgewise bending process, accordingly, the coil 10 will not bulge at the inner periphery, resulting in an enhanced coil space factor when the coil 10 is mounted in a slot of a stator.
- the space factor of the coil 10 when placed in the slot of the stator is very important.
- the elastic deformation of the wire 15 bent edgewise does not have much influence on the short side A 1 of each turn.
- the finished coil 10 having over ten turns of the wire 15 has to be inserted in a slot and thus such slight returning of the elastically deformed part of the wire 15 will exert an influence on the coil space factor.
- the elastic deformation amount of the insulation coating 15 a is not negligible.
- resin has a higher elastic deformation ratio than metal.
- the insulation coating 15 a is formed with a thickness of just about several tens ⁇ m around the copper material 15 b , the insulation coating 15 a will occupy a high percentage in the increase in the short side A 1 of the edgewise bent wire 15 .
- the copper elasticity coefficient “Ed” is about 70 GPa while the enamel elasticity coefficient “Ee” is about 3000 MPa which is more than twenty times larger than the copper elasticity coefficient.
- the edgewise bent rectangular-section wire bulges at the inner periphery due to the elastic deformation, the coil space factor thereof changes by several percent, which was confirmed by the applicant. Therefore, when the edgewise bending is performed in consideration of even the influence of the elastic deformation to produce the coil 10 to be used in a vehicle motor or others severely demanded for size reduction and high output power, the short side A 1 can be maintained.
- the height of the spacer 58 placed surrounding the shaft 57 b is set to a value “A 1 (the short side) ⁇ A 2 (the compression amount)”, to avoid any influences on the wire 15 in the bending process, such as tilting of the spacer 58 , extension of the shaft 57 b , and depression of the base 56 .
- the restraining mechanism 57 includes the shaft 57 b inserted through the base 56 . Accordingly, the restraining mechanism 57 can move vertically relative to the surface of the wire 15 including the long side B to apply pressure the wire 15 .
- the flange 57 a directly presses the wire 15 against the base 56 without the spacer 58 , only a small part of the lower surface of the flange 57 a contacts with the wire 15 and a large part of the lower surface does not contact with the wire 15 . Accordingly, the flange 57 a is caused to tilt about the shaft 57 b to one side opposite the part pressing the wire 15 . Due to tilting of the flange 57 a , the wire 15 cannot be pressed with high accuracy of dimension. In this configuration, further, the shaft 57 b may be extended and the base 56 may be depressed. Thus, the dimensional accuracy for pressing the wire 15 cannot be ensured. This results in variations in pressure on the wire 15 ; for example, excessive pressure or insufficient pressure.
- the spacer 58 is used in the present embodiment, preventing such tilting of the flange 57 a . Even when the shaft 57 b is extended or the base 56 is depressed, the restraining dimension of the wire 15 is determined by the height of the spacer 58 and therefore the dimensional accuracy can be ensured.
- the spacer 58 offers the advantage of being unrestricted in the shape of the restraining mechanism 57 .
- This mechanism 57 including the integrally formed flange 57 a and shaft 57 b has to be subjected to machining to round the joint part 57 d joining the flange 57 a and the shaft 57 b.
- This rounding is intended to reduce stress concentration in the joint part 57 d between the flange 57 a and the shaft 57 b .
- the spacer 58 is formed with the chamfer 58 a facing the rounded portion of the joint part 57 d , so that the spacer 58 does not interfere with the restraining mechanism 57 .
- the wire 15 comes into contact with the joint part 57 d between the flange 57 a and the shaft 57 b . If the joint part 57 d is formed with a rounded portion, furthermore, a corner of the wire 15 that contacts with the joint part 57 d may be deformed into a rounded surface conforming to the rounded portion of the joint part 57 d . This may cause a decrease in coil space factor. However, the spacer 58 with the chamfer 58 a provided in the present embodiment can avoid such disadvantage.
- the use of the clamp mechanism 53 can enhance the dimensional accuracy of the finished coil 10 .
- the clamp mechanism 53 installed in the edgewise bending processing apparatus 50 serves to hold the wire 15 in the position to which the wire 15 has been fed by the feeding mechanism 52 .
- a strong force may be generated near the restraining mechanism 57 when the external guide 59 is moved in association with the rotation of the rotating mechanism 60 . Without the clamp mechanism 53 , therefore, the wire 15 may be displaced even though restrained by the restraining mechanism 57 .
- the apparatus 50 of the present embodiment includes the clamp mechanism 53 to hold the wire 15 in place, thereby achieving an accurate bending operation.
- the feeding mechanism 52 it is also conceivable to hold the wire 15 by the feeding mechanism 52 instead of the clamp mechanism 53 . If the feeding mechanism 52 holds the wire 15 , the feeding mechanism 52 is not allowed to unchuck the wire 15 as long as the edgewise bending step is in progress by the bending unit 55 . If the feeding mechanism 52 is not permitted to move during the edgewise bending step, the subsequent step may not be started right after termination of the bending step. It is therefore preferable to additionally provide the clamp mechanism 53 .
- the edgewise bending processing apparatus 50 includes the feeding mechanism 52 , the clamp mechanism 53 , and the bending unit 55 , separately. Thus, the time needed for the bending process can be shortened.
- the wire 15 is clamped by the clamp mechanism 53 during the edgewise bending step of the wire 15 by the bending unit 55 . Accordingly, the feeding mechanism 52 is permitted to unchuck the wire 15 and return to the original position. After it is confirmed that the wire 15 is chucked by the clamp mechanism 53 after termination of the first step, the feeding mechanism 52 unchucks the wire 15 and is returned to the original position. This makes it possible to chuck the wire 15 just after the fourth step to start the first step again immediately.
- the schematic configuration of the edgewise bending processing apparatus shown in the above embodiment may be modified or changed as to the chuck technique, the drive technique, and others.
- the above embodiment shows the configuration that the rotating mechanism 60 is operated by the rotary drive mechanism 54 via the gears arranged on the outer periphery of the rotating mechanism 60 .
- the rotating mechanism 60 may be operated by use of a pulley, an index table, etc.
- the materials of each component exemplified in the above embodiment may be replaced with any other appropriate materials.
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Abstract
An edgewise bending processing method and apparatus comprise a restraining mechanism for restraining a rectangular-section wire having a rectangular cross-section with long sides and short sides in such a way as to press a surface of the wire including the long side and hold the wire in contact with a surface of the wire including the short side; and an external guide and a rotating mechanism for edgewise bending the rectangular-section wire. The restraining mechanism restrains part of the wire in a restraining dimension that is shorter than a length of the short side and in a range of elastic deformation of the wire, and the external guide and the rotating mechanism bend the wire edgewise at the short side of the wire that is in contact with the restraining mechanism.
Description
- The present invention relates to a technique of edgewise bending a rectangular-section wire and particularly to a technique of restraining an inner periphery part of the wire from bulging in an edgewise bending process.
- Conventionally, there has been used a technique of winding a round-section wire to provide a coil in a stator or rotor of a motor. In recent years, on the other hand, a technique of edgewise winding a rectangular-section wire to produce a coil has been proposed as one of the techniques for enhancing a space factor of a conductor to a slot.
- According to a motor component and its manufacturing method disclosed in JP2004-80860A, for example, a coil having continuous bend portions and linear portions can be produced in such a way as to intermittently pressurize the wire with use of two conical rollers.
- When the straight long, rectangular-section wire is rolled with the conical rollers, the rectangular-section wire is shaped to conform to a trapezoidal space in cross-section formed between the two conical rollers so that the wire has a cross section thin at the outer periphery and thick at the inner periphery. By this rolling, a material forming the outer periphery part is squeezed forward and backward, extending the rolled portion, thereby forming a bend (a corner). This partial rolling using the conical rollers could consequently produce the coil having continuous bend portions and linear portions. After the rolling, the rectangular-section wire is entirely coated with an insulation material.
- Further, JP 2006-288025A discloses a rectangular coil, a manufacturing method for the rectangular coil, and a manufacturing device for the same, whereby a rectangular-section wire is wound edgewise with a jig while an inner side of the wire is supported by a roller. This technique could prevent the inner side of the coil from bulging in the edgewise bending process, thereby avoiding variations in electrical resistance.
- When the rectangular-section wire is bent edgewise, the bend portion of the wire is thin at the outer periphery and thick at the inner periphery. This results from that the edgewise bending process causes the same principle as that in JP'860A in which the rectangular-section wire is bent with the conical rollers. Specifically, the bend portion at the outer periphery is extended under pressure in the edgewise bending process, which constricts the bend portion at the inner periphery side, causing transfer of the material forming the wire, resulting in a change in thickness.
- In the cross-section of the rectangular-section wire, if a short side of the bend portion at the inner periphery is wider than that at the outer periphery, clearances would be formed between the adjacent wires of a finished coil. In other words, when the coil is mounted in a slot of a stator or rotor, such clearances are liable to decrease a space factor of the coil to the slot.
- Accordingly, in JP'025A, the coil is produced in such a manner that a rectangular-section wire previously coated with an insulation coating is inserted in a groove of a roller, the groove having a width equal to the thickness of the wire, and then the wire is bent edgewise with a bending jig, thereby preventing the coil at the inner periphery side from bulging.
- However, even the conventional technique such as JP'025A would cause a problem that the space factor of the coil mounted in the slot could not be increased sufficiently.
- A motor used for driving a vehicle has been required especially to be reduced in size and increased in output power. Therefore, there is an increasingly demand for higher space factor of a conductor to a slot of a rotor or stator.
- In JP'860A, the bend portion of the coil made of the rectangular-section wire is purposely deformed into a trapezoidal shape in cross-section. In a finished coil, therefore, the bend portion is thick at the inner periphery and thin at the outer periphery, causing adjacent rectangular-section wires to interfere with one another at the inner periphery side. Consequently, the conductor could not provide a higher space factor to the slot.
- In JP'025A, on the other hand, the roller having the groove with a width equal to the length of the short side of the rectangular-section wire in cross-section is used for edgewise bending to solve the problem in JP'860A. The edgewise bending of the rectangular-section wire with the roller having the groove with a width equal to the length of the short side of the wire in cross-section could avoid deformation of the rectangular-section wire in a plastic region.
- This results from that the rectangular-section wire could not change in dimension more than the groove width of the roller in the edgewise bending process, so that the material squeezed out from the bend portion at the inner periphery side could only run off toward the outer periphery side. This intends to avoid plastic deformation of the rectangular-section wire at the inner periphery side to maintain the length of the short side of the rectangular-section wire.
- However, the applicant investigated and concluded that even the technique disclosed in JP'025A caused a slight increase in length of the short side of the rectangular-section wire. It was therefore found that the space factor of the coil to the slot could not be sufficiently enhanced.
- It is conceivable that this slight increase in length of the short side of the rectangular-section wire results from the deformation in an elastic region. In the case where the roller having the groove with a width equal to the length of the short side of the wire, the wire is also elastically deformed. Therefore, when the wire is released from the roller after the edgewise bending process, the elastically deformed part of the wire is restored to its original shape and thus the short side of the wire is slightly increased.
- The increase in length of the short side of the rectangular-section wire resulting from the elastic deformation in the edgewise bending process is just slight. However, the rectangular-section wire has to be wound over ten turns to form a coil and accordingly the increase in length of the short side of the wire is accumulated. This results in a decrease in the space factor of the conductor to the slot.
- For the coil to be used in a vehicle motor required for further size reduction and higher output power, such a slight increase in length of the short side of the rectangular-section wire resulting from the elastic deformation is undesirable.
- The present invention is made in view of the above circumstances and has an object to provide an edgewise bending processing method for a rectangular-section wire and a processing apparatus, whereby an increase in length of a short side of the wire at an inner periphery can be minimized in an edgewise bending process.
- (1) To achieve the above object, the present invention provides an edgewise bending processing method for a rectangular-section wire comprising the steps of: restraining the rectangular-section wire having a rectangular cross section with long sides and short sides by restraining means in such a way as to press a surface of the wire including the long side and hold the wire in contact with a surface of the wire including the short side; and edgewise bending the rectangular-section wire by bending means; wherein the restraining means restrains part of the wire in a restraining dimension that is shorter than a length of the short side of the wire and in a range of elastic deformation of the wire, and the bending means bends the wire edgewise at the short side of the wire that is in contact with the restraining means.
- (2) In the method (1), preferably, the rectangular-section wire is coated with a coating material.
- (3) In the method (1) or (2), preferably, the restraining means includes a flange whereby the surface of the rectangular-section wire including the long side is pressed, a base provided facing the flange, a shaft inserted through the base, and a spacer having thickness corresponding to the restraining dimension, and the spacer is formed with a chamfer at a corner facing a joint part joining the shaft and the flange.
- (4) One of the methods (1) to (3), preferably, comprises: a first step of feeding the rectangular-section wire by feeding means; a second step of holding the wire in place by clamp means and restraining the wire by the restraining means; a third step of edgewise bending the wire by the bending means while the wire is held by the clamp means; and a fourth step of releasing the rectangular-section wire from the clamp means and the restraining means; the first to fourth steps being repeatedly performed.
- (5) According to another aspect, the present invention provides an edgewise bending processing apparatus for rectangular-section wire, the apparatus comprising: restraining means for restraining the rectangular-section wire having a rectangular cross section with long sides and short sides in such a way as to press a surface of the wire including the long side and hold the wire in contact with a surface of the wire including the short side; and bending means for edgewise bending the rectangular-section wire; wherein the restraining means restrains part of the wire in a restraining dimension that is shorter than a length of the short side of the wire and in a range of elastic deformation of the wire, and the bending means bends the wire edgewise at the short side of the wire that is in contact with the restraining means.
- In the apparatus (5), preferably, the restraining means includes a flange whereby the surface of the rectangular-section wire including the long side is pressed, a base provided facing the flange, a shaft inserted through the base, and a spacer having thickness corresponding to the restraining dimension, and the spacer is formed with a chamfer at a corner facing a joint part joining the shaft and the flange.
- An explanation is given below to the operations and advantages of the above edgewise bending processing method for the rectangular-section wire according to the present invention.
- The above edgewise bending processing method (1) for a rectangular-section wire comprises the steps of: restraining the rectangular-section wire having a rectangular cross section with long sides and short sides by restraining means in such a way as to press a surface of the wire including the long side and hold the wire in contact with a surface of the wire including the short side; and edgewise bending the rectangular-section wire by bending means; wherein the restraining means restrains part of the wire in a restraining dimension that is shorter than a length of the short side of the wire and in a range of elastic deformation of the wire, and the bending means bends the wire edgewise at the short side of the wire that is in contact with the restraining means.
- Some coils to be used for a motor are produced by edgewise bending a rectangular-section wire. In many cases, this rectangular-section wire is made of a metal conductor such as copper.
- As mentioned above, such coil has conventionally been produced without considering the influence of elastic deformation. This seems because copper is hard to elastically deform.
- Not only the rectangular-section wire but also most materials are plastically deformed and elastically deformed upon receipt of pressure. When the pressure is released, accordingly, the shape of each material plastically deformed remains unchanged but the shape of each material elastically deformed returns by an amount of deformation.
- This phenomenon is also caused when the rectangular-section wire is bent edgewise. The applicant confirmed, as mentioned above, that when a rectangular-section wire was bent edgewise with a surface including a long side being pressed and restrained according to the method disclosed in JP2006-288025, the length of the short side of the rectangular-section wire was increased, but slightly, due to elastic deformation.
- The restraining dimension of the rectangular-section wire by the restraining means in the edgewise bending process is determined in consideration of the elastic deformation range of the rectangular-section wire so that the restraining dimension is shorter than the short side of the wire in anticipation of a restoration amount resulting from elastic deformation. When the wire is bent edgewise with such restraint, the length of the short side of the wire can be maintained equally before and after the edgewise bending process.
- As above, the configuration that the length of the short side of the rectangular-section wire can be maintained in the edgewise bending process is important in a case where dimensional accuracy is required in edgewise bending the rectangular-section wire.
- For instance, a coil to be used in a stator of a vehicle motor is essentially required to enhance a coil space factor when it is placed in a slot of the stator. The elastic deformation has little influence on each of the rectangular-section wires bent edgewise. However, in a finished coil made of the rectangular-section wire wound over tens turns, the coil space factor depends on the accuracy because the coil has to be mounted in the slot.
- In the case where the coil produced by the edgewise bending process bulges at the inner periphery side due to the elastic deformation, the space factor of the coil to the slot changes by several percent, which was confirmed by the applicant. As to the coil to be used in a vehicle motor or others severely required to be reduced in size and output high power, the coil space factor is desired to increase in consideration of even the influence of the elastic deformation.
- Furthermore, in the above method (2), the rectangular-section wire is coated with the coating material. Accordingly, the length of the short side of the wire is influenced by elastic deformation of the coating material in the edgewise bending process and thus tends to increase after the edgewise bending process due to elastic deformation.
- In light of a problem that the length of the short side of the wire at the inner periphery is increased due to a difference in length between the inner periphery and the outer periphery of the rectangular-section wire when bent edgewise, a conceivable technique is to edgewise bend the rectangular-section wire while restraining a surface of the wire including the long side. However, simply restraining the wire in the length of the short side will cause elastic deformation of the wire. When the restraining in the edgewise bending process is released, therefore, the elastically deformed part is restored to its original shape. This cause a phenomenon of slightly increasing the length of the short side of the bend portion of the wire due to the elastic deformation as mentioned above.
- For instance, when a coil to be used in a stator of a motor is to be produced by edgewise bending a rectangular-section wire, this wire is often made of a copper conductor coated with an insulation coating resin material. The insulation coating material is made of for example enamel, polyamide, and amideimide, which tend to largely change in dimension by elastic deformation.
- Resin generally has a higher elastic deformation ratio than metal. Thus, when the rectangular-section wire is coated with for example a coating resin material, the length of the short side of the wire is likely to increase because the elastically deformed portion of the bend part of the wire is restored after the edgewise bending process.
- Accordingly, the restraining dimension by the restraining means for edgewise bending is preferably determined in consideration of the elasticity of not only the copper material of the rectangular-section wire but also of the insulation coating material. This makes it possible to maintain the length of the short side of the rectangular-section wire equally before and after the edgewise bending process.
- In the method (3), the restraining means includes a flange whereby the surface of the rectangular-section wire including the long side is pressed, a base provided facing the flange, a shaft inserted through the base, and a spacer having thickness corresponding to the restraining dimension, and the spacer is formed with a chamfer at a corner facing a joint part joining the shaft and the flange. The restraining dimension can be ensured by the spacer to always restrain the rectangular-section wire in a constant dimension. It is further possible to determine the dimension in anticipation of the length of the short side of the rectangular-section wire after the edgewise bending.
- In the case where the rectangular-section wire is restrained by a technique of directly pressing the rectangular-section wire against the base by the flange, there may occur problems that the base is depressed, the shaft is extended, and the flange tilts in pressurizing the rectangular-section wire.
- On the other hand, the use of the spacer can restrict tilting of the flange, allowing the rectangular-section wire to be bent edgewise without any influence of extension of the shaft and depression of the base. In the case where the shaft and the flange are formed in an integral component, the joint part between the shaft and the flange has to be formed with a rounded portion to prevent stress concentration therein. This rounded portion may have an influence on forming of the rectangular-section wire. However, the use of the spacer can prevent the rectangular-section wire from being influenced by such joint part between the shaft and the flange.
- The spacer is formed with a chamfer at a corner facing the joint part between the flange and the shaft. Accordingly, the spacer is prevented from coming into contact with the rounded portion of the joint part formed to mitigate stress concentration.
- In the method (4), the following steps are repeated: a first step of feeding the rectangular-section wire by feeding means; a second step of holding the wire in place by clamp means and restraining the wire by the restraining means; a third step of edgewise bending the wire by the bending means while the wire is held by the clamp means; and a fourth step of releasing the rectangular-section wire from the clamp means and the restraining means.
- Accordingly, the first step can be performed just after the fourth step, effectively enabling repetition of the edgewise bending steps.
- The feeding means arranged to feed the rectangular-section wire in the first step is constituted of a mechanism independently of the restraining means and the bending means. While the second to fourth steps are being conducted, the feeding means is preferably returned to the original position. Accordingly, the first step can be started just after termination of the fourth step.
- In the configuration (5), the apparatus comprises: restraining means for restraining the rectangular-section wire having a rectangular cross section with long sides and short sides in such a way as to press a surface of the wire including the long side and hold the wire in contact with a surface of the wire including the short side; and bending means for edgewise bending the rectangular-section wire; wherein the restraining means restrains part of the wire in a restraining dimension that is shorter than a length of the short side of the wire and in a range of elastic deformation of the wire, and the bending means bends the wire edgewise at the short side of the wire that is in contact with the restraining means. Even when the rectangular-section wire having been bent edgewise is released from the restraining means and the elastically deformed portion of the wire is returned to its original shape, the increase in length of the short side of the wire can be prevented.
- In the configuration (6), the restraining means includes a flange whereby the surface of the rectangular-section wire including the long side is pressed, a base provided facing the flange, a shaft inserted through the base, and a spacer having thickness corresponding to the restraining dimension, and the spacer is formed with a chamfer at a corner facing a joint part joining the shaft and the flange. The restraining dimension by the restraining means is determined depending on the thickness (height) of the spacer. Accordingly, no dimensional error is caused due to mechanical changes of the restraining means. It is therefore possible to prevent an increase in length of the short side of the rectangular-section wire with high accuracy after the edgewise bending process.
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FIG. 1 is a schematic configuration view of an edgewise bending processing apparatus of a preferred embodiment; -
FIG. 2 is a sectional view of a bending unit, taken along a line A-A inFIG. 1 ; -
FIG. 3 is an external perspective view of a coil produced by the edgewise bending processing apparatus of the embodiment; -
FIG. 4 is a schematic plan view showing a state where a rectangular-section wire is bent edgewise by the edgewise bending processing apparatus; -
FIG. 5 is a schematic plan view showing a state where an external guide returns to its original position to release the rectangular-section wire; -
FIG. 6 is a schematic plan view showing a state where the rectangular-section wire is fed by a feeding mechanism to edgewise bend a second portion of the wire; -
FIG. 7 is a schematic plan view showing a state where the second portion of the rectangular-section wire is bent edgewise; -
FIG. 8 is a schematic plan view showing a state where a fourth portion of the rectangular-section wire is bent edgewise; -
FIG. 9 is an enlarged sectional view showing a state where the rectangular-section wire is pressed by a flange; and -
FIG. 10 is a graph showing a relationship between elastic deformation and surface pressure of the rectangular-section wire in the present embodiment. - A detailed description of a preferred embodiment of an edgewise bending processing method and apparatus embodying the present invention will now be given referring to the accompanying drawings.
- Firstly, the configuration of the edgewise bending processing method and apparatus of the present embodiment will be explained.
FIG. 1 is a schematic configuration view of the edgewise bending processing apparatus of the present embodiment. - An edgewise bending
processing apparatus 50 includes anuncoiler 51 holding a bobbin around which a rectangular-section wire (hereinafter, simply referred to as a “wire”) 15 having a rectangular section is wound, afeeding mechanism 52 serving to a feeding means for unwinding and feeding thewire 15 from the bobbin, aclamp mechanism 53 serving as a clamp means for holding thewire 15 against movement in a feeding direction, and abending unit 55 serving as a bending means for performing edgewise bending. The bendingunit 55 is coupled to arotary drive mechanism 54 placed adjacent to thebending unit 55 via gears or the like for drive transmission. - The
feeding mechanism 52 is arranged to reciprocally move to unwind thewire 15 from theuncoiler 51. Thisfeeding mechanism 52 is configured to chuck thewire 15 and then feed it at a constant rate. The positioning accuracy to feed thewire 15 is important. Accordingly, thefeeding mechanism 52 is preferably a mechanism enabling positioning with high accuracy, such as a servo motor. - The
wire 15 wound on the bobbin is made of a strip-shaped material having low electrical resistance such as copper. The surface thereof is coated with aninsulation coating 15 a. Thecoating 15 a has a thickness of several tens μm and is made of a high-insulation resin material such as enamel, polyamide, and amideimide. - The
clamp mechanism 53 is arranged to hold thewire 15 against movement in the feeding direction after thewire 15 has been fed by a predetermined distance by thefeeding mechanism 52. - The
feeding mechanism 52 has to return to the original position after feeding thewire 15 and thus to unchuck thewire 15 once. Prior to the unchucking, thewire 15 is clamped by theclamp mechanism 53 to prevent positional displacement. -
FIG. 2 is a sectional view of the bendingunit 55, taken along a line A-A inFIG. 1 . The bendingunit 55 includes abase 56, a restrainingmechanism 57, aspacer 58, arotating mechanism 60, and an external guide-59 attached to therotating mechanism 60. An outer periphery of therotating mechanism 60 engages with gears for transmission of rotation force of therotary drive mechanism 54 to therotating mechanism 60. Accordingly, when therotary drive mechanism 54 is driven, the rotatingmechanism 60 is rotated. A rotation angle of therotating mechanism 60 has only to allow edgewise bending of thewire 15. In the present embodiment, thewire 15 is to be bent at an angle of 90° and thus the rotation angle of therotating mechanism 60 is set at 90°. It is to be noted that the rotation angle may be set at more than 90° in consideration of springback of thewire 15. - The restraining
mechanism 57 includes aflange 57 a and ashaft 57 b which are integrally formed. The restrainingmechanism 57 is arranged to be movable in a vertical direction with respect to thebase 56. When moved toward thebase 56, the restrainingmechanism 57 compresses part of thewire 15 to reduce the thickness (length) of a short side thereof. - The
spacer 58 is a cylindrical member placed around theshaft 57 b and has a thickness (height inFIG. 2 ) equal to the dimension for restraining thewire 15. This restraining dimension will be mentioned later. Thespacer 58 is circumferentially formed with achamfer 58 a at a corner facing theflange 57 a. Specifically, thischamfer 58 a faces ajoint part 57 d joining theflange 57 a and theshaft 57 b of the restrainingmechanism 57 to avoid contact with a rounded portion of thejoint part 57 d. - The
rotating mechanism 60 is provided with bearings or the like so that therotating mechanism 60 is rotatable with respect to thebase 56. Thus, theexternal guide 59 is moved in association with the rotation of therotating mechanism 60. - The
external guide 59 is also movable in a direction perpendicular to theshaft 57 b so that theexternal guide 59 is moved toward theshaft 57 b in holding and restraining thewire 15. After thewire 15 is pressed by theexternal guide 59, the rotatingmechanism 60 is rotated by therotary drive mechanism 54, thereby edgewise bending thewire 15. - The edgewise
bending processing apparatus 50 of the present embodiment having the above configuration is operated to produce a coil as follows. -
FIG. 3 is a perspective external view of thecoil 10 produced by the edgewisebending processing apparatus 50. Thecoil 10 is made in such a manner that thewire 15 is bent edgewise. Specifically, thewire 15 is wound for fifteen turns between astart end 10 a and alast end 10 b. The shape of thecoil 10 is determined to meet a desired shape for a stator or rotor of a motor not shown. - In the present embodiment, teeth (a tooth) of the stator has a trapezoidal shape tapering toward the center of the stator. Accordingly, a first turn of the
wire 15 on the start end 10 a side is different in length of one turn from a fifteenth turn on thelast end 10 b side. Concretely, the fifteenth turn is shorter than the first turn. This configuration may be changed appropriately according to the specifications of the motor. It is of course possible to appropriately change the number of turns and which end, 10 a or 10 b, should be placed on the inner side of the stator or rotor. - A process for winding the coil 10 (the wire 15) will be explained referring to
FIGS. 4 to 8 .FIG. 4 is a schematic plan view showing a state where thewire 15 is bent edgewise.FIG. 5 is a schematic plan view showing a state where theexternal guide 59 returns to the original position to release thewire 15.FIG. 6 is a schematic plan view showing a state where thewire 15 is fed by thefeeding mechanism 52.FIG. 7 is a schematic plan view showing a state where a second portion of thewire 15 is bent edgewise to form a second corner.FIG. 8 is a schematic plan view showing a state where a fourth portion of thewire 15 is bent edgewise to form a fourth corner. - In a first step of edgewise bending the
wire 15, the wire is unwound from theuncoiler 51 as shown inFIG. 1 and fed by a predetermined length (distance) by thefeeding mechanism 52. Thefeeding mechanism 52 holds part of thewire 15 by a chuck and feeds it by the predetermined length by the drive mechanism. This length is determined according to the shape of thecoil 10. - In a second step, the
wire 15 having been fed by the predetermined length is held against movement by theclamp mechanism 53. The chuck of thefeeding mechanism 52 is then unlocked and the restrainingmechanism 57 and theexternal guide 59 are moved into contact with thewire 15 to restrain it in the following manner. - As shown in
FIG. 2 , the restrainingmechanism 57 includes a lifting mechanism. This lifting mechanism moves theflange 57 a of the restrainingmechanism 57 to press part of a surface of thewire 15 including a long side in section. - The height of the
flange 57 a is restricted by the height of thespacer 58 surrounding theshaft 57 b. The height of thespacer 58 is slightly shorter than the length of the short side (i.e. the thickness) of thewire 15. This dimension is explained below referring toFIGS. 9 and 10 . -
FIG. 9 is an enlarged sectional view showing a state where thewire 15 is partly pressed by theflange 57 a. - In
FIG. 9 , thewire 15 is constituted of acopper material 15 b having a rectangular cross section with two opposite short sides A1 and two opposite long sides B and aninsulation coating 15 a entirely coating thematerial 15 b. Theflange 57 a restrains thewire 15 by compressing part of thewire 15, reducing the length of the short side thereof. A compression amount (distance) A2 at that time is set in an elastic deformation range of each of theinsulation coating 15 a and thecopper material 15 b. -
FIG. 10 is a graph showing a relationship between elastic deformation and surface pressure. In the graph, a vertical axis indicates a returning amount (distance) resulting from the elastic deformation and a lateral axis indicates surface pressure D applied in a direction along the short side A1, that is, applied on the surface of thewire 15 including the long side B (the upper surface inFIG. 9 ). In this example, theinsulation coating 15 a is made of enamel. The graph also indicates an elastic restoration amount “bd” of copper (“copper elastic restoration amount bd”), which is a returning amount of thecopper material 15 b by its elasticity, an elastic restoration amount “be” of enamel (“enamel elastic restoration amount be”), which is a returning amount of theinsulation coating 15 a by its elasticity, and a total elastic restoration amount “bd+be” which is a total returning amount of thewire 15. - The copper elastic restoration amount “bd” is calculated by dividing the thickness of the
copper material 15 b by an elasticity coefficient Ed of copper (“copper elasticity coefficient Ed”) and multiplying a result by the surface pressure D. The enamel elastic restoration amount “be” is calculated by dividing the thickness of theinsulation coating 15 a by an elasticity coefficient Ee of enamel (“enamel elasticity coefficient Ed”) and multiplying a result by the surface pressure D. - The surface pressure D applied in the direction along the short side A1 is determined by analysis of a contact area between the
wire 15 and theflange 57 a and others. The compression amount A2 can be determined from the graph showing the total elastic restoration amount “bd+be”. - In the lateral axis in
FIG. 10 , a maximum value of the surface pressure X on thewire 15 exerted by theflange 57 a is indicated. Thus, the compression amount A2 is determined by an intersection point of a straight line representing the total elastic restoration amount “bd+be” and a dashed line representing the maximum value X. By subtracting the thus determined compression amount A2 from the length of the short side A1, the height of thespacer 58 is determined. - After the
wire 15 is pressed by the restrainingmechanism 57, thewire 15 is also pressed by theexternal guide 59. Theguide 59 is in a standby position prior to feeding of thewire 15 so as to allow thewire 15 to be easily fed. Theguide 59 is moved to a predetermined position after feeding of thewire 15 and pressed by the restrainingmechanism 57. - When the
wire 15 is retained by the restrainingmechanism 57 and theexternal guide 59, thefeeding mechanism 52 is unchucked and returned to its original position. This returning to the original position is preferably performed during the following third step. - In a third step, the
wire 15 is bent edgewise. For edgewise bending thewire 15, specifically, the rotatingmechanism 60 is rotated and accordingly theexternal guide 59 attached on the upper surface of therotating mechanism 60 is moved while pressing the surface of thewire 15 including the short side A1. - The rotation of the
rotating mechanism 60 is caused by power transmitted from therotary drive mechanism 54. Therotating mechanism 60 is rotatably supported by thebase 56 via the bearings or the like and therefore is rotated by therotary drive mechanism 54. - The
wire 15 is restrained by theflange 57 a so that the length of the short side (thickness) of thewire 15 is reduced by the compression amount A2. Thus, in the edgewise bending, thewire 15 is pressed by theguide 59 into a clearance defined by the lower surface of theflange 57 a and the upper surface of thebase 56. However, theflange 57 a has a round, lowerouter periphery 57 c, so that thewire 15 is smoothly pressed into the clearance between the lower surface of theflange 57 a and the upper surface of thebase 56. Since the compression amount A2 is about several tens μm, the above configuration can achieve the edgewise bending process. - In a fourth step, the restraining
mechanism 57 and theexternal guide 59 which restrain thewire 15 are moved to release thewire 15 as follows. - After the
wire 15 is bent edgewise, theexternal guide 59 is moved to the standby position and therotating mechanism 60 is rotated back to the original position. At that time, the restrainingmechanism 57 is moved apart from thewire 15 to release the restraining force thereon. - Returning to the first step, the
feeding mechanism 52 chucks thewire 15 and then theclamp mechanism 53 is released. Thewire 15 is fed by the predetermined length again by thefeeding mechanism 52. This state is shown inFIG. 6 . Then, via the second step, the third step is performed to edgewise bend a second portion of thewire 15 as shown inFIG. 7 , forming a second corner. As above, thewire 15 is fed accurately by thefeeding mechanism 52 and therefore thewire 15 can be bent edgewise at predetermined portions. - The above steps are repeated to wind the
wire 15 for each turn as shown inFIG. 8 to complete thecoil 10. - The edgewise
bending processing apparatus 50 of the present embodiment having the above configurations and operations can exhibit the following advantages. - As a first advantage of edgewise bending the
wire 15 as above, thecoil 10 can be produced without bulging at the inner periphery. - By the above edgewise bending process for edgewise bending the
wire 15 by use of theflange 57 a spaced at a fixed distance from the upper surface of thebase 56, it is possible to prevent thecoil 10 from bulging at the inner periphery due to plastic deformation. The edgewise bending process is performed by pressing part of thewire 15 which will form the inner periphery part of thecoil 10 to reduce the short side of thewire 15 to a length (A1 (the short side)−A2 (the compression amount)). Accordingly, thecoil 10 can be prevented from bulging at the inner periphery due to elastic deformation. - The
wire 15 is bent edgewise as above with its part being pressed by the restrainingmechanism 57 in consideration of the elastic deformation of thewire 15. After the edgewise bending process, accordingly, thecoil 10 will not bulge at the inner periphery, resulting in an enhanced coil space factor when thecoil 10 is mounted in a slot of a stator. - For the
coil 10 to be used for a stator of a vehicle motor, the space factor of thecoil 10 when placed in the slot of the stator is very important. The elastic deformation of thewire 15 bent edgewise does not have much influence on the short side A1 of each turn. However, thefinished coil 10 having over ten turns of thewire 15 has to be inserted in a slot and thus such slight returning of the elastically deformed part of thewire 15 will exert an influence on the coil space factor. The applicant confirmed by rough calculation that the increase in the short side A1 due to elastic deformation resulted in a decrease in coil space factor of several percent. - In particularly, when the
wire 15 including theinsulation coating 15 a around thecopper material 15 b as in the present embodiment is to be bent edgewise, the elastic deformation amount of theinsulation coating 15 a is not negligible. In general, resin has a higher elastic deformation ratio than metal. Thus, even though theinsulation coating 15 a is formed with a thickness of just about several tens μm around thecopper material 15 b, theinsulation coating 15 a will occupy a high percentage in the increase in the short side A1 of the edgewisebent wire 15. This is because the copper elasticity coefficient “Ed” is about 70 GPa while the enamel elasticity coefficient “Ee” is about 3000 MPa which is more than twenty times larger than the copper elasticity coefficient. - If the edgewise bent rectangular-section wire bulges at the inner periphery due to the elastic deformation, the coil space factor thereof changes by several percent, which was confirmed by the applicant. Therefore, when the edgewise bending is performed in consideration of even the influence of the elastic deformation to produce the
coil 10 to be used in a vehicle motor or others severely demanded for size reduction and high output power, the short side A1 can be maintained. - As a second advantage, the height of the
spacer 58 placed surrounding theshaft 57 b is set to a value “A1 (the short side)−A2 (the compression amount)”, to avoid any influences on thewire 15 in the bending process, such as tilting of thespacer 58, extension of theshaft 57 b, and depression of thebase 56. - The restraining
mechanism 57 includes theshaft 57 b inserted through thebase 56. Accordingly, the restrainingmechanism 57 can move vertically relative to the surface of thewire 15 including the long side B to apply pressure thewire 15. - For instance, when the
flange 57 a directly presses thewire 15 against thebase 56 without thespacer 58, only a small part of the lower surface of theflange 57 a contacts with thewire 15 and a large part of the lower surface does not contact with thewire 15. Accordingly, theflange 57 a is caused to tilt about theshaft 57 b to one side opposite the part pressing thewire 15. Due to tilting of theflange 57 a, thewire 15 cannot be pressed with high accuracy of dimension. In this configuration, further, theshaft 57 b may be extended and the base 56 may be depressed. Thus, the dimensional accuracy for pressing thewire 15 cannot be ensured. This results in variations in pressure on thewire 15; for example, excessive pressure or insufficient pressure. - On the other hand, the
spacer 58 is used in the present embodiment, preventing such tilting of theflange 57 a. Even when theshaft 57 b is extended or thebase 56 is depressed, the restraining dimension of thewire 15 is determined by the height of thespacer 58 and therefore the dimensional accuracy can be ensured. - Further, the
spacer 58 offers the advantage of being unrestricted in the shape of the restrainingmechanism 57. Thismechanism 57 including the integrally formedflange 57 a andshaft 57 b has to be subjected to machining to round thejoint part 57 d joining theflange 57 a and theshaft 57 b. - This rounding is intended to reduce stress concentration in the
joint part 57 d between theflange 57 a and theshaft 57 b. Thespacer 58 is formed with thechamfer 58 a facing the rounded portion of thejoint part 57 d, so that thespacer 58 does not interfere with the restrainingmechanism 57. - If the
spacer 58 is not provided, thewire 15 comes into contact with thejoint part 57 d between theflange 57 a and theshaft 57 b. If thejoint part 57 d is formed with a rounded portion, furthermore, a corner of thewire 15 that contacts with thejoint part 57 d may be deformed into a rounded surface conforming to the rounded portion of thejoint part 57 d. This may cause a decrease in coil space factor. However, thespacer 58 with thechamfer 58 a provided in the present embodiment can avoid such disadvantage. - As a third advantage, the use of the
clamp mechanism 53 can enhance the dimensional accuracy of thefinished coil 10. - The
clamp mechanism 53 installed in the edgewisebending processing apparatus 50 serves to hold thewire 15 in the position to which thewire 15 has been fed by thefeeding mechanism 52. In the edgewise bending process, a strong force may be generated near the restrainingmechanism 57 when theexternal guide 59 is moved in association with the rotation of therotating mechanism 60. Without theclamp mechanism 53, therefore, thewire 15 may be displaced even though restrained by the restrainingmechanism 57. - To prevent such displacement of the
wire 15, theapparatus 50 of the present embodiment includes theclamp mechanism 53 to hold thewire 15 in place, thereby achieving an accurate bending operation. - It is also conceivable to hold the
wire 15 by thefeeding mechanism 52 instead of theclamp mechanism 53. If thefeeding mechanism 52 holds thewire 15, thefeeding mechanism 52 is not allowed to unchuck thewire 15 as long as the edgewise bending step is in progress by the bendingunit 55. If thefeeding mechanism 52 is not permitted to move during the edgewise bending step, the subsequent step may not be started right after termination of the bending step. It is therefore preferable to additionally provide theclamp mechanism 53. - As a fourth advantage, further, the edgewise
bending processing apparatus 50 includes thefeeding mechanism 52, theclamp mechanism 53, and the bendingunit 55, separately. Thus, the time needed for the bending process can be shortened. - As explained above, the
wire 15 is clamped by theclamp mechanism 53 during the edgewise bending step of thewire 15 by the bendingunit 55. Accordingly, thefeeding mechanism 52 is permitted to unchuck thewire 15 and return to the original position. After it is confirmed that thewire 15 is chucked by theclamp mechanism 53 after termination of the first step, thefeeding mechanism 52 unchucks thewire 15 and is returned to the original position. This makes it possible to chuck thewire 15 just after the fourth step to start the first step again immediately. - The present invention may be embodied in other specific forms without departing from the essential characteristics thereof.
- For instance, the schematic configuration of the edgewise bending processing apparatus shown in the above embodiment may be modified or changed as to the chuck technique, the drive technique, and others. For example, the above embodiment shows the configuration that the
rotating mechanism 60 is operated by therotary drive mechanism 54 via the gears arranged on the outer periphery of therotating mechanism 60. Alternatively, the rotatingmechanism 60 may be operated by use of a pulley, an index table, etc. The materials of each component exemplified in the above embodiment may be replaced with any other appropriate materials.
Claims (10)
1. An edgewise bending processing method for a rectangular-section wire comprising the steps of:
restraining the rectangular-section wire having a rectangular cross-section with long sides and short sides with a restraining device in such a way as to press a surface of the wire including the long side and hold the wire in contact with a surface of the wire including the short side; and
edgewise bending the rectangular-section wire with a bending device;
wherein the restraining device restrains part of the wire in a restraining dimension that is shorter than a length of the short side of the wire and in a range of elastic deformation of the wire, and
the bending device bends the wire edgewise at the short side of the wire that is in contact with the restraining device.
2. The edgewise bending processing method for the rectangular-section wire according to claim 1 , wherein
the rectangular-section wire is coated with a coating material.
3. The edgewise bending processing method for the rectangular-section wire according to claim 1 , wherein
the restraining device includes a flange whereby the surface of the rectangular-section wire including the long side is pressed, a base facing the flange, a shaft inserted through the base, and a spacer having thickness corresponding to the restraining dimension, and
the spacer is formed with a chamfer at a corner facing a joint part joining the shaft and the flange.
4. The edgewise bending processing method for the rectangular-section wire according to claim 1 , the method comprising:
a first step of feeding the rectangular-section wire with a feeding device;
a second step of holding the wire in place with a clamp and restraining the wire with the restraining device;
a third step of edgewise bending the wire with the bending device while the wire is held by the clamp; and
a fourth step of releasing the rectangular-section wire from the clamp and the restraining device;
the first to fourth steps being repeatedly performed.
5. An edgewise bending processing apparatus for rectangular-section wire, the apparatus comprising:
a restraining device to restrain the rectangular-section wire having a rectangular cross-section with long sides and short sides in such a way as to press a surface of the wire including the long side and hold the wire in contact with a surface of the wire including the short side; and
a bending device to edgewise bend the rectangular-section wire;
wherein the restraining device restrains part of the wire in a restraining dimension that is shorter than a length of the short side of the wire and in a range of elastic deformation of the wire, and
the bending device bends the wire edgewise at the short side of the wire that is in contact with the restraining device.
6. The edgewise bending processing apparatus for rectangular-section wire according to claim 5 , wherein
the restraining device includes a flange whereby the surface of the rectangular-section wire including the long side is pressed, a base facing the flange, a shaft inserted through the base, and a spacer having thickness corresponding to the restraining dimension, and
the spacer is formed with a chamfer at a corner facing a joint part joining the shaft and the flange.
7. The edgewise bending processing method for the rectangular-section wire according to claim 2 , wherein
the restraining device includes a flange whereby the surface of the rectangular-section wire including the long side is pressed, a base facing the flange, a shaft inserted through the base, and a spacer having thickness corresponding to the restraining dimension, and
the spacer is formed with a chamfer at a corner facing a joint part joining the shaft and the flange.
8. The edgewise bending processing method for the rectangular-section wire according to claim 2 , the method comprising:
a first step of feeding the rectangular-section wire with a feeding device;
a second step of holding the wire in place with a clamp and restraining the wire with the restraining device;
a third step of edgewise bending the wire with the bending device while the wire is held by the clamp; and
a fourth step of releasing the rectangular-section wire from the clamp and the restraining device;
the first to fourth steps being repeatedly performed.
9. The edgewise bending processing method for the rectangular-section wire according to claim 3 , the method comprising:
a first step of feeding the rectangular-section wire with a feeding device;
a second step of holding the wire in place with a clamp and restraining the wire with the restraining device;
a third step of edgewise bending the wire with the bending device while the wire is held by the clamp; and
a fourth step of releasing the rectangular-section wire from the clamp and the restraining device;
the first to fourth steps being repeatedly performed.
10. The edgewise bending processing method for the rectangular-section wire according to claim 7 , the method comprising:
a first step of feeding the rectangular-section wire with a feeding device;
a second step of holding the wire in place with a clamp and restraining the wire with the restraining device;
a third step of edgewise bending the wire with the bending device while the wire is held by the clamp; and
a fourth step of releasing the rectangular-section wire from the clamp and the restraining device;
the first to fourth steps being repeatedly performed.
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP2007-062191 | 2007-03-12 | ||
JP2007062191A JP4626623B2 (en) | 2007-03-12 | 2007-03-12 | Edgewise bending method and processing apparatus for flat rectangular material |
PCT/JP2008/054835 WO2008114763A1 (en) | 2007-03-12 | 2008-03-10 | Edgewise bending processing method for rectangular wire and bending processing apparatus |
Publications (1)
Publication Number | Publication Date |
---|---|
US20100000624A1 true US20100000624A1 (en) | 2010-01-07 |
Family
ID=39529391
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
US12/374,831 Abandoned US20100000624A1 (en) | 2007-03-12 | 2008-03-10 | Edgewise bending processing method for rectangular wire and bending processing apparatus |
Country Status (7)
Country | Link |
---|---|
US (1) | US20100000624A1 (en) |
EP (1) | EP2052454B1 (en) |
JP (1) | JP4626623B2 (en) |
KR (1) | KR101035433B1 (en) |
CN (1) | CN101606302B (en) |
DE (1) | DE602008001099D1 (en) |
WO (1) | WO2008114763A1 (en) |
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US20100212771A1 (en) * | 2007-12-26 | 2010-08-26 | Toyota Jidosha Kabushiki Kaisha | Edgewise winding method and edgewise winding apparatus |
US20110048092A1 (en) * | 2009-04-24 | 2011-03-03 | Toyota Jidosha Kabushiki Kaisha | Apparatus for producing motor coil |
WO2015124922A1 (en) | 2014-02-18 | 2015-08-27 | Yasa Motors Limited | Machine cooling systems |
US20150302988A1 (en) * | 2013-01-22 | 2015-10-22 | Mitsubishi Electric Corporation | Rectangular wire edgewise-bending processing device and rectangular wire edgewise-bending processing method |
US9197107B2 (en) | 2011-04-05 | 2015-11-24 | Toyota Jidosha Kabushiki Kaisha | Stator, method for manufacturing stator, and flat conductor for winding |
US9748826B2 (en) | 2008-05-21 | 2017-08-29 | Toyota Jidosha Kabushiki Kaisha | Winding method, winding apparatus, and stator |
US9793774B2 (en) | 2012-10-16 | 2017-10-17 | Mitsubishi Electric Corporation | Armature for rotary electric machine |
US10665390B2 (en) | 2016-12-27 | 2020-05-26 | Toyota Jidosha Kabushiki Kaisha | Bending device for a wire |
US11007560B2 (en) * | 2017-10-25 | 2021-05-18 | Toyota Jidosha Kabushiki Kaisha | Winding wire manufacturing device and control method for the same |
EP4307543A1 (en) * | 2022-07-13 | 2024-01-17 | Volkswagen Aktiengesellschaft | Simplified production of flat wire coils |
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JP4656134B2 (en) * | 2007-11-29 | 2011-03-23 | トヨタ自動車株式会社 | Winding device |
JP5531673B2 (en) * | 2009-04-06 | 2014-06-25 | 株式会社デンソー | Method and apparatus for forming coil end of stator coil |
JP2010252588A (en) * | 2009-04-20 | 2010-11-04 | Sumitomo Electric Ind Ltd | Method for forming coil member and assembling device thereof |
JP5293371B2 (en) * | 2009-04-20 | 2013-09-18 | 住友電気工業株式会社 | Coil member assembly device |
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CN104412494B (en) * | 2012-10-31 | 2017-03-08 | 三菱电机株式会社 | The coil of electric rotating machine and electric rotating machine |
JP5548802B2 (en) * | 2013-05-25 | 2014-07-16 | 日特エンジニアリング株式会社 | Coil forming equipment |
JP6426423B2 (en) * | 2014-10-08 | 2018-11-21 | Dowaメタルテック株式会社 | Edgewise coil and method of manufacturing the same |
JP6740145B2 (en) * | 2017-01-30 | 2020-08-12 | トヨタ自動車株式会社 | Flat wire bending device |
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JP2001145286A (en) * | 1999-11-12 | 2001-05-25 | Mitsubishi Electric Corp | Stator of rotating electric machine and method of manufacturing the same |
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- 2008-03-10 CN CN2008800048287A patent/CN101606302B/en not_active Expired - Fee Related
- 2008-03-10 WO PCT/JP2008/054835 patent/WO2008114763A1/en active Application Filing
- 2008-03-10 EP EP08722231A patent/EP2052454B1/en not_active Expired - Fee Related
- 2008-03-10 KR KR1020097002469A patent/KR101035433B1/en not_active IP Right Cessation
- 2008-03-10 DE DE602008001099T patent/DE602008001099D1/en active Active
- 2008-03-10 US US12/374,831 patent/US20100000624A1/en not_active Abandoned
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US4077244A (en) * | 1976-09-16 | 1978-03-07 | Hitachi, Ltd. | Method of and apparatus for continuously winding a rectangular wire |
US4446393A (en) * | 1976-10-29 | 1984-05-01 | The Globe Tool & Engineering Company | Dynamoelectric field assembly and winding therefor |
US4702097A (en) * | 1983-04-06 | 1987-10-27 | Helmut Zahlaus | Process for the bending of rod-like materials |
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Publication number | Priority date | Publication date | Assignee | Title |
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US20100212771A1 (en) * | 2007-12-26 | 2010-08-26 | Toyota Jidosha Kabushiki Kaisha | Edgewise winding method and edgewise winding apparatus |
US8371340B2 (en) * | 2007-12-26 | 2013-02-12 | Toyota Jidosha Kabushiki Kaisha | Edgewise winding method and edgewise winding apparatus |
US9748826B2 (en) | 2008-05-21 | 2017-08-29 | Toyota Jidosha Kabushiki Kaisha | Winding method, winding apparatus, and stator |
US20110048092A1 (en) * | 2009-04-24 | 2011-03-03 | Toyota Jidosha Kabushiki Kaisha | Apparatus for producing motor coil |
US8544307B2 (en) * | 2009-04-24 | 2013-10-01 | Toyota Jidosha Kabushiki Kaisha | Apparatus for producing motor coil |
US9197107B2 (en) | 2011-04-05 | 2015-11-24 | Toyota Jidosha Kabushiki Kaisha | Stator, method for manufacturing stator, and flat conductor for winding |
US9793774B2 (en) | 2012-10-16 | 2017-10-17 | Mitsubishi Electric Corporation | Armature for rotary electric machine |
US20150302988A1 (en) * | 2013-01-22 | 2015-10-22 | Mitsubishi Electric Corporation | Rectangular wire edgewise-bending processing device and rectangular wire edgewise-bending processing method |
US9646764B2 (en) * | 2013-01-22 | 2017-05-09 | Mitsubishi Electric Corporation | Rectangular wire edgewise-bending processing device and rectangular wire edgewise-bending processing method |
WO2015124922A1 (en) | 2014-02-18 | 2015-08-27 | Yasa Motors Limited | Machine cooling systems |
US10665390B2 (en) | 2016-12-27 | 2020-05-26 | Toyota Jidosha Kabushiki Kaisha | Bending device for a wire |
US11007560B2 (en) * | 2017-10-25 | 2021-05-18 | Toyota Jidosha Kabushiki Kaisha | Winding wire manufacturing device and control method for the same |
EP4307543A1 (en) * | 2022-07-13 | 2024-01-17 | Volkswagen Aktiengesellschaft | Simplified production of flat wire coils |
Also Published As
Publication number | Publication date |
---|---|
WO2008114763A1 (en) | 2008-09-25 |
JP4626623B2 (en) | 2011-02-09 |
CN101606302A (en) | 2009-12-16 |
DE602008001099D1 (en) | 2010-06-10 |
EP2052454A1 (en) | 2009-04-29 |
KR20090085568A (en) | 2009-08-07 |
KR101035433B1 (en) | 2011-05-18 |
CN101606302B (en) | 2011-11-09 |
EP2052454B1 (en) | 2010-04-28 |
JP2008228435A (en) | 2008-09-25 |
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