JP6573953B2 - Coil insertion device - Google Patents

Description

  The present invention relates to a coil insertion device in which a coil wound in advance in a slot of a stator core is inserted by being pushed radially outward from the inner peripheral side of the stator core.

  For example, in Patent Document 1 below, a stator formed by inserting one side of a plurality of pre-wound coils into a slot and then inserting the other side of the plurality of coils into another slot, respectively. A first holding groove group formed of a plurality of slit-shaped holding grooves and having a pitch that is an integral multiple of the slot pitch of the stator core, and the same number of holding grooves as the holding grooves of the first holding groove group. A jig having a second holding groove group formed at the same pitch as the first holding groove group is formed on the outer periphery, and one side of a plurality of coils wound in advance is connected to the first holding groove. The other side is inserted into the holding groove adjacent to the holding groove into which the one side is inserted in the second holding groove group, and each coil is moved along the circumference of the jig. And insert this jig into the inner periphery of the stator core One side of each coil is pushed to the outer diameter side by pushing means, inserted into a corresponding slot of the stator core, the jig is rotated by a predetermined angle with respect to the slot of the stator core, and the second holding groove After the group is positioned so as to be aligned with the corresponding slot of the stator core, the other side is pushed out to the outer diameter side by pushing means and inserted into the corresponding slot of the stator core. A method is disclosed. According to the manufacturing method described above, a plurality of coils can be inserted into the slot so as to overlap each other spirally, and the spirally wound stator core can be manufactured mechanically and efficiently.

Japanese Patent No. 4813171

  In the manufacturing method of Patent Document 1, one side of each coil held in the first holding groove group is pushed out to the outer diameter side by pushing means, inserted into the corresponding slot of the stator core, and the coil is held. The tool is rotated by a predetermined angle with respect to the slot of the stator core and positioned so that the second holding groove group is aligned with the corresponding slot of the stator core, and then the other side of the coil is pushed out to the outer diameter side by the pushing means. And insert it into the slot.

  However, when the coil extruded from the holding groove of the jig is inserted into the slot through the enlarged diameter ribs protruding from both sides of the inner teeth of the stator core, it contacts the side surface of the exposed enlarged diameter rib. was there. Further, when the coil is inserted into the slot of the stator core at a high density, the coil may come into contact with the back surface side of the diameter expansion rib of the inner teeth of the stator core. For this reason, there was a possibility that the insulation coating of the conducting wire constituting the coil was damaged.

  Accordingly, an object of the present invention is to provide a coil insertion device in which a coil wound in advance in a slot of a stator core is inserted by being pushed radially outward from the inner peripheral side of the stator core. An object of the present invention is to provide a coil insertion device capable of suppressing damage to an insulating coating.

In order to achieve the above object, the coil insertion device of the present invention has a cylindrical shape as a whole, and has a plurality of holding grooves that are radially formed so as to open from the axial center toward the outer periphery. A jig inserted into the inner periphery of the stator core by inserting and holding the coil side,
A pushing means for extruding a side portion of the coil held in the holding groove radially outward toward a predetermined slot of the stator core and inserting the coil into the slot from the inner peripheral side of the stator core;
A front end surface of the inner teeth of the stator core, a side surface of the enlarged diameter rib projecting from both sides of the inner tooth tip, and a cover member covering the back side of the expanded diameter rib,
A side portion of the coil held in the holding groove is configured to be inserted into the slot through the inner teeth covered by the cover member by the pushing means. .

  According to the coil insertion device of the present invention, the cover member that covers the inner teeth of the stator core, the tip surfaces of the inner teeth of the stator core, the side surfaces of the enlarged diameter ribs protruding from both sides of the inner teeth tips, and the back side of the enlarged diameter rib Since the coil is prevented from coming into direct contact with the side surface or the back surface of the diameter-enlarging rib protruding from both sides of the tip of the inner teeth of the stator core, the coil can be reliably prevented from being damaged.

  In the coil insertion device of the present invention, the cover member includes a tip surface of the inner teeth of the stator core, a side surface of the enlarged rib projecting from both sides of the tip of the inner teeth, a back side of the enlarged rib, and the enlarged rib. It is preferable to form a shape that covers a predetermined length portion of the inner surface of the slot in the radial direction from the back side.

  According to the above aspect, when the insulating sheet is inserted into the inner periphery of the opening portion of the slot after the coil is inserted into the slot, the cover member is removed from the slot so that the cover member on the inner periphery of the slot exists. Since a space is formed at a location, the insulating sheet can be easily inserted.

  The coil insertion device of the present invention preferably further includes a cover member detaching device that moves in the axial direction of the stator core and detaches the cover member to the inner teeth of the stator core.

  According to the above aspect, the cover member can be mechanically detached from the internal teeth of the stator core.

  The coil insertion device of the present invention preferably further includes an insulation sheet insertion device for inserting an insulation sheet into the inner diameter side of the inserted coil after inserting the coil into the slot of the stator core.

  According to the above aspect, by inserting the insulating sheet on the inner diameter side of the inserted coil, the insulating sheet can be used as an interphase insulating sheet or an insulating sheet (so-called wedge) that closes the slot opening.

In the coil insertion device of the present invention, a cover member detaching device that moves in the axial direction of the stator core and detaches the cover member to the inner teeth of the stator core;
An insulating sheet inserting device for inserting an insulating sheet into an inner diameter side of the inserted coil after inserting the coil into the slot of the stator core;
It is preferable that after the coil is inserted into the slot of the stator core, the insulating sheet is inserted by the insulating sheet inserting device in synchronism with the operation of removing the cover member by the cover member detaching device.

  According to the above aspect, since the insulating sheet is inserted by the insulating sheet inserting device while the cover member is extracted by the cover member detaching device, the insulating sheet can be inserted more smoothly.

  According to the coil insertion device of the present invention, the cover member that covers the inner teeth of the stator core, the tip surfaces of the inner teeth of the stator core, the side surfaces of the enlarged diameter ribs protruding from both sides of the inner teeth tips, and the back side of the enlarged diameter ribs Since the coil is prevented from coming into direct contact with the side surface or the back surface of the diameter-enlarging rib protruding from both sides of the tip of the inner teeth of the stator core, the coil can be reliably prevented from being damaged.

It is a perspective view which shows an example of the coil holding jig used for the coil insertion apparatus of this invention. It is a schematic plan view which shows an example of the coil | winding and insertion apparatus used for the coil insertion apparatus of this invention. In one embodiment of the coil insertion device of the present invention, it is a top view showing the state where the coil holding jig which inserted and held the coil was inserted in the inner circumference of the stator core. FIG. 4 is a partially enlarged view of FIG. 3. It is explanatory drawing shown in the state before mounting | wearing with a cover member, which is an example of the cover member removal | desorption apparatus used for the coil insertion apparatus of this invention which remove | desorbs a cover member to the front-end | tip part of the teeth of a stator core. It is explanatory drawing which shows the state which attached the cover member to the front-end | tip part of the teeth of a stator core with the cover member removal | desorption apparatus. It is explanatory drawing which shows the state which attached | attached the cover member to the front-end | tip part of the teeth of a stator core with the cover member removal | desorption apparatus, and retracted the apparatus. It is side surface sectional drawing which shows an example of the pusher (pressing means) used for the coil insertion apparatus of this invention. It is a side view of the pusher (pushing means). It is a perspective view which shows the braid | blade used for the same pusher. It is a perspective view which shows the blade holder used for the same pusher. It is a perspective view which shows the end former used for the same pusher. It is explanatory drawing which shows the state which inserted the coil in the outer diameter side of the slot of a stator core by the coil insertion apparatus of this invention. It is the elements on larger scale which show the state where the coil was inserted in the outer diameter side of the slot of a stator core by the coil insertion apparatus of this invention. It is a partial expanded explanatory view which shows the state which inserted the interphase insulation paper in the slot of the same stator core. It is explanatory drawing which shows the state which inserted the coil in the internal diameter side of the slot of a stator core by the coil insertion apparatus of this invention. It is a partial expansion explanatory view showing the state where a coil was inserted in the inner diameter side of the slot of a stator core by the coil insertion device of the present invention. A cover detaching device for removing a cover member from a stator core into which a coil has been inserted, and an insulating paper inserting device for inserting insulating paper (wedge) into the inner periphery of the opening of the slot of the stator core, where the cover member is still the tip of the inner teeth of the stator core It is explanatory drawing which shows the state with which it was mounted | worn. In the same apparatus, it is explanatory drawing which shows the state which inserted the holder of the cover member removal | desorption apparatus into the stator core inner periphery from the one end surface side of a stator core, and was fitted to the cover member. In the same apparatus, it is explanatory drawing which shows the state which inserts an insulating paper (wedge) in the opening part inner periphery of the slot of a stator core while extracting a cover member from the internal tooth of a stator core with a cover member removal | desorption apparatus. It is the elements on larger scale of the stator core obtained by the coil insertion apparatus of this invention. It is a partial expanded explanatory view which shows the other example of the coil holding jig used for the coil insertion apparatus of this invention. It is a perspective view which shows 1st Embodiment of the cover member used for this invention. It is a perspective view which shows 2nd Embodiment of the cover member used for this invention. It is a fragmentary sectional view which shows the cover member and its holder in the coil insertion apparatus of this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 shows a coil holding jig 100 used in the coil insertion device of the present invention. The coil holding jig 100 has a cylindrical shape as a whole, and has a plurality of holding grooves 101 that are radially formed so as to open from the axial center toward the outer periphery, and the space between the holding grooves 101 extends radially. A plurality of blade portions 102 are formed. As will be described later, the coil holding jig 100 is inserted into the holding groove 101 and inserted into the inner periphery of the stator core 120 (see FIGS. 2 and 3).

  FIG. 2 shows a winding / insertion device 110 that winds the coil C and inserts the coil C into the holding groove 101 of the coil holding jig 100. The winding / insertion device 110 forms a U-phase winding machine 111a that forms a U-phase coil C, a V-phase winding machine 111b that forms a V-phase coil C, and a W-phase coil C. It has a W-phase winding machine 111c (hereinafter collectively referred to as “winding machine 111”).

  Each winding machine 111 includes a motor 112 and a winding frame 113 that is rotated by the motor 112, and a coil C is formed by winding an electric wire supplied from an electric wire supply device (not shown) around the winding frame 113. ing. A plurality of coils C, four in this embodiment, are formed by changing the winding direction along the longitudinal direction of the winding frame 113.

  Each winding machine 111 can be rotated via a rotating shaft 114. After the coil C is wound, the winding machine 111 is rotated around the rotating shaft 114 so that the end surface of the winding frame 113 is moved. It can be directed to the corresponding holding groove 101 of the coil holding jig 100. The coil holding jig 100 is rotatably held by a rotation shaft (not shown) inserted in the shaft hole, and both side portions of the end surface of the winding frame 113 of each winding machine 111 are formed in predetermined holding grooves 101. It can be rotated to align.

  The coil C is attached to the coil holding jig 100 by inserting both side portions of the coil C wound around the winding frame 113 into the corresponding holding grooves 101 of the coil holding jig 100. A U-phase coil C formed by the U-phase winding machine 111a, a V-phase coil C formed by the V-phase winding machine 111b, and a W-phase formed by the W-phase winding machine 111 coil C. The phase coils C can be inserted into the corresponding holding grooves 101 of the coil holding jig 100 at the same time or sequentially.

  When the U-phase, V-phase, and W-phase coils C are inserted, the coil holding jig 100 is rotated by a predetermined angle, and both side portions of the end surface of the winding frame 113 of each winding machine 111 are in the predetermined holding grooves 101. Again, it is rotationally positioned to align. Then, the next coil C wound around each winding machine 111 is inserted and held in the corresponding holding groove 101 in the same manner as described above. In this way, each of the U-phase, V-phase, and W-phase coils C can be inserted and held in the holding groove 101 of the coil holding jig 100 so as to overlap spirally.

  3 and 4 show a state where the coil holding jig 100 in which the coil C is inserted and held in this manner is inserted into the inner periphery of the stator core 120. FIG. The stator core 120 has a cylindrical shape as a whole, and slots 121 are formed at predetermined intervals on the inner periphery thereof, and between the slots 121 are teeth 122. An enlarged rib 123 is formed at the tip of the tooth 122. A slot insulating paper 124 is inserted in the slot 121 in advance.

  A feature of the present invention resides in that a cover member 130 is provided to cover the front end surface of the tooth 122, the side surface of the diameter expansion rib 123, and the back surface of the diameter expansion rib 123. The cover member 130 includes a cover main body 131 that covers the front end surface of the tooth 122, and a rib cover 132 that covers the side surfaces and the back surface of the diameter-enlarging rib 123. The cover member 130 is made of a rod-like member having a cross-sectional shape shown in FIG. 4 and extending in the axial direction of the stator core 120. When viewed in a perspective view, the cover member 130 has the shape shown in FIG. Note that locking holes 133 into which locking pins 152 (see FIGS. 5, 6, 7) to be described later are inserted are formed at both ends of the cover body 131. The cover member 130 is inserted from the end face direction of the stator core 120 so as to be fitted to the diameter-enlarging rib 123 of the tooth 122 in a manner described later.

  The coil holding jig 100 is disposed on the inner periphery of the cover member 130 attached to the end surface of the tooth 122. In the case of this embodiment, the holding grooves 101 of the coil holding jig 100 are arranged at a half of the arrangement interval of the slots 121 of the stator core 120 and are twice as many as the slots 121 of the stator core 120. Yes. In the state shown in FIG. 4, the holding groove 101 in which one side of each coil C is inserted is aligned with the opening of the corresponding slot 121, and the holding groove 101 in which the other side of each coil C is arranged is a cover member. The opening is closed by 130 cover main bodies 131. The holding grooves 101 of the coil holding jig 100 may be arranged at the same arrangement interval as the slots 121 of the stator core 120, and may be the same number as the slots 121 of the stator core 120.

  5, 6, and 7 show a cover member detaching device 140 for attaching and removing the cover member 130 to the tip end portion of the teeth 122 of the stator core 120. The cover member attaching / detaching device 140 includes a base 141 having a ball screw (not shown) built therein, a slide block 142 that is movably installed by being screwed to the ball screw of the base 141, and the slide block 142 is moved by rotating the ball screw. A first servo motor driving device 143 to be driven, a support plate 144 installed so as to rise L-shaped from the upper surface of the slide block 142 in a side view, and a cylindrical shape extending horizontally from the rising surface of the support plate 144 And a holder 145 which forms the following. As shown in FIG. 25, the holder 145 is provided between the rib 154 and a cylindrical main body 153, a rib 154 having a T-shaped cross-section standing radially from the outer periphery of the main body 153, And a housing groove 155 of the cover member 130.

  The cover member 130 is inserted into the housing groove 155 of the holder 145 from the end face direction of the holder 145 and held. A locking hole 133 is formed at the end of the cover member 130. A first air cylinder 146 is installed on the support plate 144, and a cam member 149 is connected to the drive rod 147 so that the cam member 149 moves forward and backward by the operation of the first air cylinder 146. It has become. In relation to this, a cam follower 150 is swingably mounted on the support plate 144 via a support shaft 151. A plurality of cam followers 150 are provided corresponding to the holders 145 that support the cover member 130, and have locking pins 152 that engage and disengage with locking holes 133 formed in the cover member 130. Further, on the outer periphery of the cam member 149, a front inclined surface 149a, a flat surface 149b, and a rear inclined surface 149c are formed. The shape of the bottom surface of the cam follower 150 conforms to the front inclined surface 149a and the flat surface 149b when the cam member 149 is retracted (the state shown in FIG. 5), and the locking pin 152 engages with the locking hole 133. When the cam member 149 moves forward (the state shown in FIG. 7), the locking pin 152 is configured to be detached from the locking hole 133 in conformity with the flat surface 149b and the rear inclined surface 149c.

  Therefore, as shown in FIG. 5, the cover member 130 is supported by the holder 145, the cam member 149 is retracted in that state, and the bottom surface of the cam follower 150 is adapted to the front inclined surface 149a and the flat surface 149b. The cover member 130 can be held by engaging the locking pin 152 with the locking hole 133.

  Next, as shown in FIG. 6, the slide block 142 is advanced by the first servo motor driving device 143, and the cover member 130 is inserted from the end face side of the stator core 120 so as to cover the tip end portion of the teeth 122. At this time, the stator core 120 is held by the core holder 125.

  In this state, the cam member 149 is retracted by the first air cylinder 146, and the cam follower 150 is rotated so that the bottom surface of the cam follower 150 matches the flat surface 149b and the rear inclined surface 149c. Is extracted from the locking hole 133 of the cover member 130 to release the engagement.

  Then, as shown in FIG. 7, the slide block 142 is moved backward by the first servo motor driving device 143, the cover member 130 is left on the stator core 120 side, and the holder 145 is extracted from the stator core 120. Thus, the state where the cover member 130 is attached to the teeth 122 of the stator core 120 is the state shown in FIG.

  Next, based on FIGS. 8 to 12, the side portion of the coil C held in the holding groove 101 of the coil holding jig 100 is extruded radially outward toward a predetermined slot 121 of the stator core 120, so that the stator core A pusher 160 that is inserted into the slot 121 from the inner peripheral side of 120 and corresponds to the pushing means of the present invention will be described.

  As shown in FIGS. 8 and 9, the pusher 160 is inserted into the holding groove 101 of the coil holding jig 100 from one end face side of the coil holding jig 100 (the same number as the number of holding grooves 101). ), A blade holder 170 that holds the base 162 of the blade 161, and an end former 180.

  As shown in FIG. 10, the blade 161 extends in an elongated thin plate shape as a whole, and has a base portion 162, an intermediate portion 163, and a tip portion 164, and one side of the intermediate portion 163 (coil holding jig). A thick wall portion 165 is formed on a side edge disposed on the outer peripheral side of 100, and a coil pressing portion 166 that is inclined so as to become gradually narrower toward the tip is formed on one side of the tip 164. Is formed. In addition, the front end side of the thick part 165 has a tapered shape that gradually decreases in height.

  As shown in FIG. 11, the blade holder 170 is formed between a cylindrical main body 171, a plurality of insertion grooves 172 formed radially from the center of the main body 171 toward the outer periphery, and the insertion grooves 172. A plurality of support pieces 173. The insertion groove 172 is provided corresponding to the slot 121 of the stator core 120. The base 162 of the blade 161 is inserted into each insertion groove 172.

  Furthermore, as shown in FIG. 12, the end holder 180 is configured such that the blade holder 170 is inserted into the inner periphery 181 thereof. A plurality of support grooves 182 into which the base side of the thick part 165 of the blade 161 is inserted are formed at predetermined intervals in the circumferential direction at the upper part of the inner periphery 181.

  Therefore, in a state where the blade holder 170 is disposed on the inner periphery of the end former 180, the base portion 162 of the blade 161 is inserted into the insertion groove 172 of the blade holder 170, and the base end side of the thick portion 165 of the blade 161 is supported by the end former 180. The blade 161 is held by the blade holder 170 and the end former 180 by being inserted into the groove 182. The blade holder 170 and the end former 180 are fixed to each other while holding the blade 161 by fixing means (not shown).

  3 and 4, the tip of the blade 161 of the pusher 160 is inserted into the holding groove 101 from one end face side of the coil holding jig 100 to be held in the corresponding holding groove 101. One side of the coil C is pressed by the coil pressing portion 166 of the blade 161 and is inserted into the slot 121 through the gap of the tooth 122 covered with the cover member 130. Further, when the thick portion 165 of the pusher 160 is inserted into the slot 121, the coil C inserted into the slot 121 is pushed into the back of the slot 121. At this time, since the tip portion of the tooth 122 is covered with the cover member 130, the coil C is not in direct contact with the tooth 122, so that the coil C can be prevented from being damaged.

  Thus, the state in which one side portion of the coil C, which is arranged in alignment with the slot 121 of the stator core 120 and is held in the holding groove 101 of the coil holding jig 100, is inserted into the slot 121 is shown in FIGS. Is shown in In this embodiment, the coil C is inserted into the outer diameter side and the inner diameter side of the slot 121 in two steps. In the state shown in FIGS. It is inserted on the outer diameter side.

  Next, as shown in FIG. 15, interphase insulating paper 185 is inserted into the slot 121. The interphase insulating paper 185 can be inserted by an apparatus similar to the insulating paper inserting apparatus 190 described later. The interphase insulating paper 185 has an elongated plate shape, and both side portions thereof are bent to the outer diameter side, and have a U shape when viewed from the axial direction of the slot 121. In addition, the coil holding jig 100 is rotated at an angle that is half the arrangement interval of the slots 121, and the holding groove 101 that has been closed by the cover main body 131 of the cover member 130 is aligned with the slot 121. Placed in.

  In this state, by inserting the tip of the blade 161 of the pusher 160 into the holding groove 101 again from one end face side of the coil holding jig 100, the other side of the coil C held in the holding groove 101 is inserted. Is pressed by the coil pressing portion 166 of the blade 161 and inserted into the slot 121 through the gap between the teeth 122 covered with the cover member 130. Also at this time, since the tip end portion of the tooth 122 is covered with the cover member 130, the coil C is not in direct contact with the tooth 122, so that the coil C can be prevented from being damaged.

  16 and 17 show a state where all the coils C held in the holding groove 101 of the coil holding jig 100 are inserted into the slots 121 of the stator core 120 in this way. Since the outer diameter side coil C inserted into one slot 121 and the inner diameter side coil C are different-phase coils C, they are separated by interphase insulating paper 185.

  Further, by inserting the coil C into the holding groove 101 of the coil holding jig 100 by the above-described method using the winding / inserting device 110 shown in FIG. It is already held in a state of overlapping in a spiral. Then, by inserting the coil C into the slot 121 of the stator core 120 by the method described above, the coil C can be inserted into the slot 121 of the stator core 120 in a spirally overlapping state, and the motor can be shortened by shortening the coil end. Etc. can be increased.

  Then, the outer diameter side coil C and the inner diameter side coil C inserted into the slot 121 are shifted by one slot in the circumferential direction, and the outer diameter side coil C inserted into one slot 121 and the inner diameter side coil C. By arranging the coil C so as to be a different-phase coil C, the rotation of the motor or the like can be made smooth.

  18 to 20 show an insulating paper inserting device 190 that operates in conjunction with the cover member detaching device 140 described above. The insulating paper inserting device 190 includes a base 191 with a ball screw (not shown), a slide block 192 that is movably arranged by being screwed to the ball screw of the base 191, and the slide block 192 by rotating the ball screw. A second servo motor driving device 193 that moves along the axis 191 is included. On the slide block 192, a wedge magazine 194 is installed, and a plurality of slots (not shown) are formed on the outer periphery of the wedge magazine 194 so as to align with the slots 121 of the stator core 120 at predetermined intervals in the circumferential direction. A punch 195 for inserting the insulating paper 199 into the slot of the wedge magazine 194 is provided on the side of the wedge magazine 194. Further, behind the wedge magazine 194, push rods 196 that push out the insulating paper 199 inserted into a slot (not shown) of the wedge magazine 194 and insert it into the slot 121 from the other end face side of the stator core 120 are arranged in an annular shape. It is held by a holder 197. The holder 197 is connected to the operating rod of the second air cylinder 198 and is moved forward and backward by the second air cylinder 198. The insulating paper insertion device 190 has the same structure as that installed in a general coil insertion device, and therefore detailed description thereof will be omitted.

  In FIG. 18, the coil holding jig 100 extracted from the stator core 120 in the state shown in FIGS. 16 and 17 is installed in the center of the insulating paper inserting device 190 with its axial direction oriented in the horizontal direction. At a position slightly away from one end face of the stator core 120, the cover member detaching device 140 described above is arranged so that the tip of the holder 145 is aligned with the corresponding slot 121 of the stator core 120. The insulating paper 199 held in the slot of the wedge magazine 194 of the insulating paper inserting device 190 is arranged at a position slightly away from the other end face of the stator core 120 so as to be aligned with the slot 121 of the stator core 120.

  In this state, as shown in FIG. 19, the first servo motor driving device 143 of the cover member attaching / detaching device 140 is operated to insert the holder 145 from one end face side of the stator core 120. Then, the holder 145 receives the corresponding cover member 130 and is disposed on the inner periphery of the stator core 120. Then, as shown in FIG. 5, when the cam member 149 is advanced and the cam follower 150 is rotated so that the bottom surface of the cam follower 150 comes into contact with the front inclined surface 149 a and the flat surface 149 b, the locking pin 152. Engages with the locking hole 133, and the cover member 130 is connected to the holder 145. On the other hand, in the insulating paper inserting device 190, the second servo motor driving device 193 is operated to advance the slide block 192, and the tip of the wedge magazine 194 moves to a position close to the other end surface of the stator core 120.

  Next, as shown in FIG. 20, the slide block 142 and the support plate 144 are retracted by the operation of the first servo motor driving device 143 of the cover member detaching device 140, and the cover member 130 held by the holder 145 is moved to the holder 145. And withdrawn from the slot 121 of the stator core 120. Further, the second air cylinder 198 is operated, the push rod 196 is inserted into a slot (not shown) of the wedge magazine 194, the insulating paper 199 held in the slot is pushed out, and the slot from the other end face side of the stator core 120 is pushed. 121 is inserted. In this case, the cover member 130 can be extracted from the slot 121 and the insulating paper 199 can be inserted into the slot 121 in a synchronized manner, whereby the insulating paper 199 is placed in the space from which the cover member 130 is extracted. Thus, the insulating paper 199 can be inserted smoothly.

  Thus, the state in which the insulating paper 199 is inserted into the slot 121 of the stator core 120 is shown in FIG. The cover member 130 is removed from the tip end portion of the tooth 122, and an insulating paper 199 is inserted inside the opening portion of the slot 121 to prevent the coil C from flowing out of the opening portion of the slot 121. Thus, the stator core 120 to which the coil C is mounted in a state in which the coils C of different phases are inserted into the outer diameter side and the inner diameter side of the slot 121 and the coil ends of the coil C protruding from the end face of the stator core 120 are spirally overlapped. Can be obtained.

  A rotating electrical machine such as a motor manufactured by incorporating the stator core 120 has a compact shape in which the coil ends of the stator core 120 are spirally overlapped, and the rotating electrical machine has excellent performance, and smoothes the rotating operation. be able to.

  In the above-described embodiment, the coil C is inserted into the slot 121 of the stator core 120 twice on the outer diameter side and the inner diameter side. However, the coil insertion device of the present invention has the stator core 120. A device that inserts the coil C into the single slot 121 at a time may be used.

  22 and 24 show another example of a cover member used in the coil insertion device according to the present invention. The cover member 200 is formed in a long and narrow bar shape as a whole, and covers a main body 201 that contacts the protruding end surface of the tooth 122, and extends from both sides of the cover main body 201 in the outer diameter direction to expand the ribs of the teeth 122 of the stator core 120. 123, a rib cover 202 that covers 123, and an extending portion 203 that extends from the tip of the rib cover 202 along the side surface of the tooth 122 on the slot 121 side. Similar to the cover member 130, locking holes 133 are formed at both ends of the cover main body 201.

  According to the cover member 200, the extension portion 203 is provided, so that the cover member 200 can be stably attached to the teeth 122 of the stator core 120, and the cover member 200 is extracted from the teeth 122 of the stator core 120, thereby insulating paper. When inserting 199 into the slot 121, the insulating paper 199 can be more easily inserted.

DESCRIPTION OF SYMBOLS 100 Coil holding jig 101 Holding groove 102 Blade | wing part 110 Winding / insertion device 111 Winding machine 111a U phase winding machine 111b V phase winding machine 111c W phase winding machine 112 Motor 113 Reel 114 Rotation Shaft 120 Stator core 121 Slot 122 Teeth 123 Expanded rib 124 Slot insulating paper 130 Cover member 131 Cover main body 132 Rib cover 133 Locking hole 140 Cover member detaching device 141 Base 142 Slide block 143 First servo motor driving device 144 Support plate 145 Holder 146 First air cylinder 147 Drive rod 148 Actuating plate 149 Cam member 149a Front inclined surface 149b Flat surface 149c Back inclined surface 150 Cam follower 151 Support shaft 152 Locking pin 153 Main body 154 Rib 155 Housing groove 160 Pusher 161 Brace 162 Base part 163 Intermediate part 164 Tip part 165 Thick part 166 Coil pressing part 170 Blade holder 171 Main body 172 Insertion groove 173 Support piece 180 End former 181 Inner circumference 185 Interphase insulation paper 190 Insulation paper insertion device 191 Base 192 Slide block 193 Second servo Motor drive device 194 Wedge magazine 195 Punch 197 Holder 198 Second air cylinder 199 Insulating paper 200 Cover member 201 Cover body 202 Rib cover 203 Extension part

Claims (5)

It has a cylindrical shape as a whole, and has a plurality of holding grooves that are radially formed so as to open from the axial center to the outer periphery, and the side portions of the coil are inserted and held in the holding groove to be formed on the inner periphery of the stator core. A jig to be inserted,
A pushing means for extruding a side portion of the coil held in the holding groove radially outward toward a predetermined slot of the stator core and inserting the coil into the slot from the inner peripheral side of the stator core;
A front end surface of the inner teeth of the stator core, a side surface of the enlarged diameter rib projecting from both sides of the inner tooth tip, and a cover member covering the back side of the expanded diameter rib,
The cover member is arranged so as to cover the inner teeth over the entire axial length of the stator core of the inner teeth,
A side portion of the coil held in the holding groove is configured to be inserted into the slot through the inner teeth covered by the cover member by the pushing means. Coil insertion device.   The cover member includes a front end surface of the inner teeth of the stator core, a side surface of the enlarged diameter rib projecting from both sides of the front end of the inner teeth, a back side of the expanded diameter rib, and an inner side surface of the slot from the back side of the expanded diameter rib. The coil insertion device according to claim 1, wherein the coil insertion device has a shape covering a predetermined length portion in the radial direction.   The coil insertion device according to claim 1, further comprising a cover member detaching device that moves in an axial direction of the stator core and detaches the cover member to an inner tooth of the stator core.   The coil insertion device according to any one of claims 1 to 3, further comprising an insulation sheet insertion device for inserting an insulation sheet into an inner diameter side of the inserted coil after inserting the coil into the slot of the stator core. . It has a cylindrical shape as a whole, and has a plurality of holding grooves that are radially formed so as to open from the axial center to the outer periphery, and the side portions of the coil are inserted and held in the holding groove to be formed on the inner periphery of the stator core. A jig to be inserted,
A pushing means for extruding a side portion of the coil held in the holding groove radially outward toward a predetermined slot of the stator core and inserting the coil into the slot from the inner peripheral side of the stator core;
A cover member that covers the front end surface of the inner teeth of the stator core, the side surface of the enlarged diameter rib projecting from both sides of the inner teeth tip, and the back side of the expanded diameter rib
A cover member detaching apparatus that moves in the axial direction of the stator core and detaches the cover member to the inner teeth of the stator core;
An insulating sheet inserting device for inserting an insulating sheet into the inner diameter side of the inserted coil after inserting the coil into the slot of the stator core;
The side portion of the coil held in the holding groove is inserted into the slot through the inner teeth covered by the cover member by the pushing means,
After inserting the coil into the slots of the stator core, in synchronism with the withdrawal operation of the cover member by the cover member desorber, characterized in that it is configured to perform the insertion of the insulating sheet by said insulating sheet insertion device Coil insertion device.

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