JP5103292B2 - Rotor laminated iron core and manufacturing method thereof - Google Patents

Description

The present invention relates to a rotor laminated core formed by effectively using an iron core material and applied to a motor or a generator, and a method for manufacturing the same.

In the manufacture of a rotor laminated core, in order to increase the material yield from which the core pieces are punched, a segmented core is formed by punching and stacking in the form of segment core pieces (also referred to as split core pieces) obtained by dividing the core pieces. Later, there is a method of assembling this divided laminated iron core. As another method, there is a method of manufacturing a rotor laminated core by connecting each segment core piece in a strip shape and punching it into a predetermined shape, and winding this single strip core piece spirally.
In the case of manufacturing a rotor laminated core by winding the strip-shaped core piece, the strip-shaped core piece can be formed by punching straight from a metal plate as a material, so that the material yield can be improved. However, after forming the strip-shaped core pieces by punching and joining the segment core pieces in a desired shape, the strip-shaped core pieces must be wound and sequentially laminated to the desired thickness, and productivity is increased. There was a low problem.

In order to solve such a problem, for example, Patent Document 1 proposes a method for manufacturing a laminated core (stator laminated core) in which strip-shaped core pieces are stacked and integrated and then wound. This state is shown in FIG. 5, belt-shaped core pieces 72 and 73 having magnetic pole piece portions 71 formed at predetermined intervals on the inside of the yoke piece portion 70 are prepared, and these are stacked and integrated into a core bar (inner diameter guide tube). The magnetic pole piece portions 71 of the strip-shaped core pieces 72 and 73 are wound around the periphery of the belt-like iron core pieces 72 and 73 in a spiral manner and stacked. According to the technique of Patent Document 1, the thickness of the wound strip-shaped core piece is increased by the amount integrated and integrated, and the productivity of lamination is improved. Reference numeral 75 denotes an outer diameter guide tube.

However, in the technique of Patent Document 1, when the belt-like core pieces 72 and 73 are overlapped and integrated, for example, welding must be performed, and the manufacturing work becomes complicated. Further, since the band-shaped core pieces that are overlapped and integrated in this way have increased rigidity, when the diameter of the laminated core is small, winding becomes difficult and the molded shape is deteriorated, for example, the pole pieces are shifted in the stacking direction. May cause problems.
Therefore, Patent Document 2 discloses a laminated core in which a plurality of strip-shaped core pieces each having an arc-shaped segment core piece connected by a connecting portion are spirally wound, and the position of the connecting portion is shifted in the vertical direction ( A method of manufacturing a stator laminated iron core has been proposed.

JP-A-11-299136 (FIGS. 3 and 9) JP-A-1-264548 (FIG. 9)

However, since the connecting portion of the strip-shaped core pieces is bent when the laminated iron core is manufactured, the connecting portion bulges in the thickness direction compared to before the bending. For this reason, in the technique of patent document 2, there exists a possibility that the bent connection part may contact | abut to the strip | belt-shaped iron core piece piled up and down, and a clearance gap may arise. As a result, compared with the case where the layers are stacked without any gaps, an extra pressurizing process for eliminating the gaps may be required, or the motor may be reduced in efficiency or vibration, which may cause a reduction in product quality. .

The present invention has been made in view of such circumstances, and it goes without saying that a rotor laminated iron core can be manufactured with high productivity by winding a strip-shaped iron core piece, and a rotor laminated iron core with good shape accuracy and good product quality. It aims at providing the manufacturing method.

The rotor laminated core according to the first aspect of the invention that meets the above object has the same configuration in which arc-shaped segment core pieces each having a plurality of magnetic pole pieces protruding radially outward are connected by a narrow connecting portion. A plurality of strip-shaped iron core pieces bent at the connecting portion and stacked in a spiral manner with the magnetic pole piece portions being stacked one above the other. The connecting portion of the magnetic pole piece portion of the segment core piece portion is located,
Furthermore, a notch is provided on the outer side in the radial direction of the connecting portion so that the bent connecting portion is positioned and a bulge in the thickness direction generated in the connecting portion is accommodated.

In the rotor laminated core according to the first aspect of the present invention, a first engaging groove is formed on the inner side in the radial direction of the coupling portion of the segment core piece, and faces the inner side of the adjacent segment core piece. It is preferable that a second engaging groove formed by the notch is formed.
In the rotor laminated core according to the first aspect of the present invention, it is preferable that the first and second engaging grooves have an inner width extending radially inward.
In the rotor laminated core according to the first aspect, it is preferable that a pilot hole is provided in the segment core piece.

In the rotor laminated core according to the first aspect of the present invention, it is preferable that a magnet insertion portion for inserting a permanent magnet is formed in the segment core piece.
In the rotor laminated iron core according to the first aspect of the present invention, the permanent magnet is inserted into the magnet insertion portion overlapped in the stacking direction, and the permanent magnet is injected into the magnet insertion portion and cured by a resin member. It is preferable to be fixed to the part.

In the rotor laminated core according to the first aspect of the present invention, it is preferable that a concave portion and a convex portion fitted to the concave portion are provided on a side portion of the adjacent segment core piece portions.
In the rotor laminated core according to the first aspect of the present invention, the number of the magnetic pole pieces of the segment core pieces is preferably 2 or 3.
In the rotor laminated core according to the first aspect of the present invention, it is preferable that the side end portions of the adjacent segment core pieces are arranged close to each other.

In the method for manufacturing a rotor laminated core according to the second aspect of the present invention, the arc-shaped segment core pieces having a plurality of magnetic pole pieces protruding outward in the radial direction are respectively connected by the narrow connecting portions. A punching step of forming a plurality of strip-shaped core pieces having the same configuration ,
The strip core pieces, while overlapping the pole piece portion of the bent and respectively the connecting portion in the vertical, possess an annular formation laminating spirally wound,
In addition, in the punching step, the bent connecting portion is located on the radially outer side of the connecting portion of the magnetic pole piece portion of the segment core piece portion positioned above and below the bent connecting portion in the annular forming step. And the notch which accommodates the swelling of the thickness direction which generate | occur | produces in this connection part is formed.

In the method for manufacturing a rotor laminated core according to the second invention, in the punching step, a first engaging groove is formed on the radially inner side of the connecting portion of the segment core piece, and the adjacent segment core pieces are adjacent to each other. A second engaging groove formed by a notch facing the inside of the side portion is formed, and in the annular forming step, the core material provided with the tooth portions to be fitted into the first and second engaging grooves is rotationally driven. And it is preferable to laminate | stack, drawing in the said strip | belt-shaped iron core piece.
In the method for manufacturing a rotor laminated core according to the second invention, a pilot hole is formed in the segment core piece in the punching step, and the segment core piece is positioned by the pilot hole in the annular forming step. It is preferable to perform caulking lamination while performing.

In the method for manufacturing a rotor laminated core according to the second invention, in the annular forming step, the plurality of strip-shaped core pieces are directed in the same tangential direction with respect to the rotor laminated core formed in an annular shape. Preferably it is.
In the method for manufacturing a rotor laminated core according to the second invention, in the annular forming step, the plurality of strip-like core pieces are arranged in tangential directions at different angles with respect to the rotor laminated core formed in an annular shape. It is preferable to face.

The rotor laminated iron core according to claim 1 and the method for producing a rotor laminated iron core according to claims 10 to 14, wherein the bulges in the vertical direction generated when the connecting portion is bent are located above and below the magnetic pole piece. For example, it can be tightly wound without generating a gap between the segment core pieces that are vertically overlapped with each other. Thereby, a rotor lamination iron core provided with good product quality with good shape accuracy can be manufactured with high productivity.
In addition, since the plurality of strip-shaped core pieces are shifted in the position of the connecting portions of the strip-shaped core pieces that overlap each other, there is no relatively inferior strength connecting portion on the same vertical line in the stacking direction, and the strength of the rotor stacked core Will increase.
And since the strip-shaped core pieces are wound without overlapping and integrating a plurality of strip-shaped core pieces as in the prior art, each segment core piece can be smoothly bent via the connecting portion. The shape accuracy of the manufactured rotor laminated core is excellent. Moreover, since the process which integrates belt-shaped core pieces by welding beforehand is unnecessary, it can manufacture with sufficient productivity.

In particular, since the rotor laminated core according to claim 2 and the method for producing the rotor laminated iron core according to claim 11 are provided with engaging grooves that can be engaged with a core material for winding a strip-shaped iron core piece, for example, By rotating and driving the core material, the core material can be stacked while being drawn. Thereby, the rotor lamination | stacking iron core which raised the shape precision can be manufactured.
In the rotor laminated core according to claim 3, since the inner width of the engaging groove is expanded radially inward, for example, the insertion into the tooth portion provided in the core for winding the strip-shaped core piece is performed. Can be smooth.
In the rotor laminated core according to claim 4 and the method for manufacturing the rotor laminated core according to claim 12, since the pilot hole is provided in the segment core piece, positioning when winding the strip-like core piece is performed. It can be performed with high accuracy and ease.

In the rotor laminated core according to the fifth aspect, since the magnet insertion portion for inserting the permanent magnet is formed in the segment core piece, the magnetic pole piece can be formed with a simple configuration.
In the rotor laminated core according to claim 6, since the permanent magnet is inserted into the magnet insertion portion overlapped in the lamination direction and fixed to the magnet insertion portion by the resin member, the resin member is surely provided around the permanent magnet. The permanent magnet can be firmly fixed to the magnet insertion portion.
In the rotor laminated core according to claim 7, the adjacent segment core pieces can be positioned with a simple configuration by providing a concave portion and a convex portion fitted to the side portion of the adjacent segment core piece portion. it can.

The rotor laminated core according to claim 8 is easy to manufacture without complicating the shape of each segment core piece, since the number of magnetic pole pieces of the segment core pieces is 2 or 3.
In the rotor laminated core according to claim 9, since the side end portions of adjacent segment core piece portions are arranged close to each other and contact between the side end portions is prevented, variation in the pitch in the circumferential direction of each segment core piece portion For example, it is possible to prevent displacement of the caulking position of the segment core pieces in the stacking direction. In addition, by arranging them in this manner, for example, even when a tool blade of a die for punching a segment core piece is worn and a burr is generated at the side end, the contact can be prevented. The pitch deviation in the circumferential direction can be prevented.

In the method for manufacturing a rotor laminated core according to claim 13, since the plurality of strip-shaped core pieces are oriented in the same direction, the mold apparatus for forming each strip-shaped core piece can be arranged in the same direction, Can be configured compactly.
In the method for manufacturing a rotor laminated core according to claim 14, since the plurality of strip-shaped core pieces are oriented in different directions, the winding load can be dispersed. Further, since the strip-shaped core pieces do not overlap vertically when each strip-shaped core piece is punched, the punching formation is facilitated. In particular, by making the winding directions of the plurality of strip-shaped core pieces opposite to each other, the work can be performed without generating an unreasonable load on the winding device (for example, a core material disposed in the center).

Next, embodiments of the present invention will be described with reference to the accompanying drawings for understanding of the present invention.
As shown in FIG. 1, a rotor laminated core (hereinafter also simply referred to as a laminated core) 10 according to an embodiment of the present invention includes a plurality (two in this embodiment) of strip-shaped core pieces 11 and 12. Are spirally wound and caulked and laminated. Here, since the strip-shaped core piece 11 and the strip-shaped core piece 12 have the same configuration, for each configuration of the strip-shaped core piece 12, the symbol “a” is attached to the number of each configuration of the strip-shaped core piece 11, Detailed description thereof is omitted.

The strip-shaped core piece 11 constituting the laminated core 10 has a narrow arc-shaped segment core piece 15 having a plurality (two in this embodiment) of magnetic pole pieces 13 and 14 projecting radially outward. The connecting portions 16 are connected in a straight line. The same applies to the strip-shaped iron core piece 12, and the segment iron core pieces 15a including the two magnetic pole piece parts 13a and 14a are connected by the connecting part 16a.
In the completed laminated core 10, the strip-shaped core piece 11 and the strip-shaped core piece 12 are bent at the connecting portions 16 and 16a, respectively, and the magnetic pole piece portion 13 and the magnetic pole piece portion 14a, and the magnetic pole piece portion 14 and the magnetic pole piece portion 13a. While being stacked up and down, they are wound in a spiral manner and stacked by caulking.

The strip-shaped core piece 11 is made of a plurality of segment core pieces 15 formed by stamping a strip material by pressing and connected by connecting portions 16. The strip-shaped iron core pieces 11 and 12 have two magnetic pole piece portions 13 and 14 included in each segment iron core piece portion 15 and two magnetic pole piece portions 13a and 14a included in each segment iron core piece portion 15a. They are stacked one by one. Since the number of magnetic poles of the completed laminated core 10 is 12, as shown in FIG. 1, each of the strip-shaped core pieces 11 and 12 is composed of six segment core pieces 15 and 15a connected to form a single ring. An iron core piece is formed.

Magnet insertion holes (an example of magnet insertion portions) 17 and 18 for inserting permanent magnets (not shown) are formed on the outer side in the radial direction of the segment core piece 15. The magnet insertion holes 17 and 18 are provided at equal intervals on the same circumference around the axis of the laminated core 10.
Thereby, the magnet insertion hole 17 and the magnet insertion hole 18a, and the magnet insertion hole 18 and the magnet insertion hole 17a overlap vertically.
In manufacturing the laminated core 10, after inserting a permanent magnet into the magnet insertion holes 17 and 18 a and the magnet insertion holes 18 and 17 a overlapped in the lamination direction, the magnet insertion holes 17 and 18 a and the magnets are inserted. A resin member (for example, a thermosetting resin such as an epoxy resin or a thermoplastic resin) is injected into the holes 18 and 17a by transfer molding or injection molding, and the resin member is cured to fix the permanent magnet. ing.

A plurality of (two in this case) pilots each having a through hole (for example, a circular cross section) at the center in the width direction of the magnet insertion holes 17 and 18 formed in the segment core piece 15 and radially inward. The holes 19 and 20 are formed at equal intervals on the same circumference around the axis of the laminated core 10.
Thereby, since the pilot hole 19 and the pilot hole 20a and the pilot hole 20 and the pilot hole 19a overlap vertically, each strip-shaped iron core piece 11 and 12 can be caulked and laminated, positioning the segment iron core piece parts 15 and 15a.
Caulking portions 21 are formed on both sides in the circumferential direction around the pilot holes 19 and 20. As this caulking portion, for example, any one or more of a well-known V-shaped caulking, a circular half punching caulking, and a cut and raised caulking can be applied.

The two magnetic pole piece portions 13, 14 are connected by a coupling portion 22 provided at the center in the circumferential direction of the segment core piece 15.
Note that, as described above, the laminated core 10 is formed by laminating the two strip-shaped core pieces 11 and 12 by shifting one magnetic pole piece part pitch. Therefore, the connecting portions 22a of the magnetic pole pieces 13a and 14a of the other strip-shaped core piece 12 are positioned above and below the bent connection portion 16 of the one strip-shaped core piece 11, and the other strip-shaped core piece 12 is bent. The coupling part 22 of the magnetic pole piece parts 13 and 14 of one strip | belt-shaped iron core piece 11 is located above and below the connection part 16a.

For this reason, the notch 23 in which the bent connection part 16a is located is provided outside the coupling part 22 in the radial direction, and the bulge in the thickness direction of the bent connection part 16a is accommodated in the notch 23. The shape of the notch 23 is semicircular in plan view, but may be an elliptical arc shape or a square shape, for example.
Here, the recess of the notch 23 is provided up to a position where at least the bulging portion in the thickness direction generated when the connecting portion 16 a is bent does not contact the coupling portion 22. In the present embodiment, the magnet insertion holes 17 and 18 are formed so as to be arranged at the same position as the circle passing through the maximum recess position of the notch 23 or on the outer side in the radial direction. Thereby, the magnetic pole piece parts 13 and 14 can be protruded to the radial direction outer side of the laminated iron core 10.

A first engaging groove 24 is provided on the radially inner side of the connecting portion 22 of the segment core piece 15, and a first engaging groove 24 a is provided on the radially inner side of the connecting portion 22 a of the segment core piece 15 a. It has been. Further, a second hooking groove 25 formed by facing notches is formed inside the side portions of the adjacent segment core pieces 15, and facing notches are formed inside the side portions of the adjacent segment core pieces 15 a. A second engaging groove 25a formed by the above is formed.

Thereby, as shown in FIG. 2, a columnar (or cylindrical) core metal (an example of a core material) 27 provided around the teeth 26 to be fitted into the engaging grooves 24, 24 a, 25, 25 a, The belt-like core pieces 11 and 12 can be stacked while being drawn in by being rotationally driven by a rotational drive source (not shown). Accordingly, the first engaging groove 24 of the segment core piece 15 and the second engaging groove 25a of the segment core piece 15a, the second engaging groove 25 of the segment core piece 15 and the first of the segment core piece 15a. The engaging groove 24a overlaps.
The engaging grooves 24, 24 a, 25, 25 a have an inner width that increases toward the radially inner side (axial center) of the laminated iron core 10, so that the teeth 26 can be smoothly engaged.

The side portions of the adjacent segment core pieces 15 and 15a are provided with a semicircular concave portion 28 in plan view and a convex portion 29 fitted thereto, and on the side in the radial direction, the connecting portions 16 and 16a are provided. Is provided.
The side end portions of the adjacent segment core pieces 15 including the concave portions 28 and the convex portions 29 are arranged close to each other with a gap of, for example, 20 μm or more and 30 μm or less after the connection portion 16 is bent. May be. Thereby, the mutual positioning of the adjacent segment core piece parts 15 can be implemented with higher accuracy, and the annular accuracy can be improved.
The width (radial length) w of each connecting portion 16 is, for example, about 0.5 mm to 3 mm. Adjacent segment core pieces 15 are mechanically connected by this connecting portion 16, and when the adjacent segment core pieces 15 are bent inward in the radial direction, the bent portions in the case of making the whole into an annular shape are formed. Forming. Therefore, when the segment core piece 15 is linear, that is, immediately after the strip-shaped core piece 11 is formed by punching from the strip, as shown in FIG. 30 is formed.

The cut portion 30 is eliminated when the strip-shaped core piece 11 is formed into an annular shape, and the angle of the opposite cut sides 31 and 32 is 0 degrees. However, in the state of the strip-shaped core piece 10, the angle (α) of the cut sides 31 and 32. Is 60 degrees in this embodiment.
In general, when an annular core piece is divided into m (six in this embodiment) segment core pieces each having n (two in this embodiment) magnetic pole pieces, The angle of the cut side is (360 degrees / m) degrees.

Then, the manufacturing method of the rotor laminated iron core which concerns on the 1st Embodiment of this invention is demonstrated, referring FIG. 1, FIG.
First, the strip is punched out by a press to form a plurality of strip-shaped core pieces 11 and 12.
At this time, a notch 23 is formed on the outer side in the radial direction of the coupling portion 22 of the magnetic pole piece portions 13 and 14 of the segment core piece portion 15 constituting the strip-shaped iron core piece 11. Moreover, the notch which forms the 1st engaging groove 24 and the 2nd engaging groove 25 in the radial direction inner side of the circumferential direction center of the segment core piece 15 and the side inner side of the adjacent segment core piece 15 is formed. Form. Then, pilot holes 19 and 20 are formed in the segment core piece 15. In addition, the above process is the same also about the strip | belt-shaped iron core piece 12. FIG. (End of punching process).

Next, as shown in FIG. 2, the two strip-shaped core pieces 11 and 12 directed in the same tangential direction are aligned with the magnetic pole piece portion 13 and the magnetic pole piece portion 14a, and the magnetic pole piece portion 14 and the magnetic pole piece portion 13a. The connecting portion 16 and the connecting portion 16a are overlapped so that the positions thereof are different, and are wound around the core metal 27 in a spiral shape. In addition, although the end part of the winding start of the strip | belt-shaped iron core pieces 11 and 12 is shifted 180 degree +/- 1 magnetic pole pitch angle (this embodiment is 30 degree | times), for example, as shown by p and q of FIG. It may be the same.
The cored bar 27 used for this winding has a toothed portion 26 that fits into the engaging grooves 24, 24a, 25, 25a. The protruding height in the radial direction of the tooth portion 26 may be about 1 to 0.3 times the radial length (depth) of the engaging grooves 24, 24a, 25, 25a. The core metal 27 is connected to a rotation drive source (not shown) and rotates.
Thereby, by rotating the core metal 27, the tooth portions 26 are fitted into the engaging grooves 24, 24 a, 25, 25 a, and the belt-like core pieces 11, 12 can be stacked while being drawn toward the core metal 27 side.

In this embodiment, the strip-shaped core pieces 11 and 12 are wound around the cored bar 27 with a phase of 30 degrees, so that the positions of the connecting portions 16 and 16a of the upper and lower strip-shaped core pieces 11 and 12 are also different. There is a phase shift of one magnetic pole pitch angle (an angle between adjacent magnetic pole pieces).
In addition, caulking portions 21 and 21a are formed on the segment core pieces 15 and 15a constituting the strip-shaped core pieces 11 and 12, respectively. Thereby, while positioning the segment core pieces 15 and 15a by the pilot holes 19 and 20a and the pilot holes 20 and 19a, the upper and lower belt-like core pieces 11 and 12 are annularly wound so that the top and bottom are accurately overlapped. Thus, the upper and lower segment core pieces 15 and 15a are caulked and laminated by pressing from above with a presser (not shown).
Here, the positioning of the segment core pieces 15, 15a can use the magnet insertion holes 17, 17a, 18, 18a instead of the pilot holes 19, 19a, 20, 20a.

Further, the strip-shaped core pieces 11 and 12 can be laminated by using the product receiving plate 33 shown in FIGS. 3A and 3B without using the cored bar 27 described above. In this case, it is not necessary to provide the above-mentioned engaging groove in the strip-shaped core piece.
The product receiving plate 33 is provided with tapered pilot holes 19 and 20 a and protruding pins 34 that can be inserted into the pilot holes 19 a and 20. A spring material (elastic member) 35 is provided below the projecting pin 34, and the projecting pin 34 can be retracted with respect to the mounting table 36 of the product receiving plate 33. Further, the protruding pins 34 are provided at equal intervals in the circumferential direction of the mounting table 36, and the number thereof is, for example, four or more, which is 1 of the total number of pilot holes of the strip-shaped core piece 11 (or the strip-shaped core piece 12). / 2 to 1/4.

Thus, while positioning the segment core pieces 15 and 15a with the protruding pins 34 protruding from the mounting table 36, the upper and lower belt-like core pieces 11 and 12 are wound in an annular shape so that the upper and lower portions are accurately overlapped. . The winding of the strip-shaped core pieces 11, 12 may rotate the product receiving plate 33, or the strip-shaped core pieces 11, 12 may be wound around the product receiving plate 33.
Then, the upper and lower segment core pieces 15 and 15a can be caulked and stacked by pressing the wound strip-shaped core pieces 11 and 12 from above with a holding jig 38 provided with a tapered caulking positioning pin 37. At this time, the tip of the caulking positioning pin 37 presses the tip of the projecting pin 34, and the projecting pin 34 is retracted into the mounting table 36, so that the caulking positioning pin 37 is connected to the stacked pilot holes 19 and 20a. The pilot holes 19a and 20 are inserted over the entire stacking direction. Accordingly, accurate positioning can be performed, and the wound strip-shaped core pieces 11 and 12 can be sandwiched between the product receiving plate 33 and the holding jig 38 and sufficiently pressed.
Each of the strip-shaped core pieces 11 and 12 shown above may be punched with a press machine immediately before being wound around the core metal 27 (or product receiving plate 33) and laminated, or the strip-shaped core pieces punched in advance. 11 and 12 may be prepared, and this may be wound around the core metal 27 (the annular forming step).

Then, the manufacturing method of the rotor lamination | stacking iron core which concerns on the 2nd Embodiment of this invention is demonstrated, referring FIG.
As shown in FIG. 4, the segment core pieces 15 and 15 a are wound around the core metal 27 by changing the winding phase of the strip-shaped core pieces 11 and 12 by 180 degrees. As a result, no bending moment is applied to the core metal 27, and the work can be performed stably. It should be noted that the winding start of the strip-shaped core pieces 11 and 12 directed in the tangential direction at different angles (180 degrees) has a phase shift of 180 ° ± 1 magnetic pole pitch angle, and each of the strip-shaped core pieces 11 and 12 is configured. It is the same as the manufacturing method of the rotor lamination | stacking iron core which concerns on the 1st Embodiment of the above-mentioned that the crimping | crimped parts 21 and 21a are provided in the predetermined position of the segment core piece parts 15 and 15a to perform. .

As described above, the present invention has been described with reference to the embodiment. However, the present invention is not limited to the configuration described in the above embodiment, and the matters described in the scope of claims. Other embodiments and modifications conceivable within the scope are also included. For example, the case where the rotor laminated core of the present invention and the manufacturing method thereof are configured by combining some or all of the above-described embodiments and modifications are also included in the scope of the right of the present invention.
Moreover, the form of the segment core piece constituting the strip-shaped core piece and the form of the connecting part for connecting the segment core pieces are not limited to the above embodiment, and any form can be adopted. In addition, the structure of the rotor lamination | stacking iron core to manufacture is not limited to the structure of the said embodiment, Another form may be sufficient.

And in the said embodiment, when the thickness of a strip | belt-shaped core piece is thin, when the diameter of the laminated core using this is large, since it is difficult to wind each strip | belt-shaped core piece only by rotation of a metal core. In addition, it is preferable that a separate guide device is used to guide each segment core piece of the strip-shaped core piece at a predetermined angular position and bend at a predetermined angle at the connecting portion. The guide device preferably includes a portion that guides the outer circumferential direction of each segment core piece and a portion that guides the vertical direction of the strip-shaped core piece.
Furthermore, in the above-described embodiment, the case where the rotor laminated core is manufactured using two strip-shaped core pieces has been described. However, three or more (for example, four or six) strip-shaped core pieces are used. A rotor laminated iron core may be manufactured. This strip-shaped iron core piece has been described in which segment iron core pieces having two magnetic pole pieces are connected, but each of the iron core pieces has three, and more than four magnetic pole pieces. But you can.

It is a top view of the rotor lamination | stacking iron core which concerns on one embodiment of this invention. It is explanatory drawing of the manufacturing method of the rotor laminated core which concerns on the 1st Embodiment of this invention. (A), (B) is explanatory drawing of the other lamination | stacking method of the manufacturing method of the same rotor lamination | stacking iron core, respectively. It is explanatory drawing of the manufacturing method of the rotor lamination | stacking iron core which concerns on the 2nd Embodiment of this invention. It is explanatory drawing of the manufacturing method of the laminated core which concerns on a prior art example.

10: Rotor laminated iron core, 11, 12: strip-shaped iron core piece, 13, 13a, 14, 14a: magnetic pole piece part, 15, 15a: segment iron core piece part, 16, 16a: connecting part, 17, 17a, 18, 18a : Magnet insertion hole (magnet insertion part), 19, 19a, 20, 20a: Pilot hole, 21, 21a: Caulking part, 22, 22a: Coupling part, 23, 23a: Notch, 24, 24a, 25, 25a: Engagement groove, 26: Tooth part, 27: Core metal (core material), 28: Recessed part, 29: Convex part, 30: Cut part, 31, 32: Cut edge, 33: Product receiving plate, 34: Projection pin, 35 : Spring material, 36: Mounting table, 37: Positioning pin for caulking, 38: Pressing jig

Claims (14)

A plurality of strip-shaped core pieces having the same configuration, in which arc-shaped segment core pieces each having a plurality of magnetic pole pieces projecting radially outward are connected by narrow connecting portions, are bent at the connecting portions, and A laminated rotor core that is spirally wound and stacked while the magnetic pole piece portions are stacked one above the other, wherein the connecting portions of the magnetic pole piece portions of the segment core piece portions are positioned above and below the bent connecting portion. And
Furthermore, the rotor laminated iron core is provided with a notch in which the bent connecting portion is located on the radially outer side of the connecting portion and accommodates a bulge in the thickness direction generated in the connecting portion. 2. The rotor laminated core according to claim 1, wherein a first hooking groove is formed on a radially inner side of the connecting portion of the segment core piece, and a side facing side of the adjacent segment core piece is opposed to the inner side. The rotor lamination | stacking iron core characterized by the 2nd engaging groove formed by notch being formed. 3. The rotor laminated core according to claim 2, wherein an inner width of each of the first and second engaging grooves extends radially inward. 4. The rotor laminated core according to any one of claims 1 to 3, wherein a pilot hole is provided in the segment core piece. The rotor laminated core according to any one of claims 1 to 4, wherein a magnet insertion part for inserting a permanent magnet is formed in the segment core piece. 6. The rotor laminated core according to claim 5, wherein the permanent magnet is inserted into the magnet insertion portion overlapped in the stacking direction, and the permanent magnet is injected into the magnet insertion portion and cured by the resin member. Rotor laminated iron core characterized by being fixed to the core. The rotor laminated core according to any one of claims 1 to 6, wherein a side portion of the adjacent segment core piece is provided with a concave portion and a convex portion that fits into the concave portion. Rotor laminated iron core. The rotor laminated iron core according to any one of claims 1 to 7, wherein the number of the magnetic pole piece portions of the segment iron core piece portions is two or three. The rotor laminated core according to any one of claims 1 to 8, wherein the side end portions of the adjacent segment core pieces are arranged close to each other. A punching step of forming a plurality of strip-shaped core pieces having the same configuration in which arc-shaped segment core pieces each provided with a plurality of magnetic pole pieces projecting radially outward are respectively connected by narrow connecting portions;
The strip core pieces, while overlapping the pole piece portion of the bent and respectively the connecting portion in the vertical, possess an annular formation laminating spirally wound,
In addition, in the punching step, the bent connecting portion is located on the radially outer side of the connecting portion of the magnetic pole piece portion of the segment core piece portion positioned above and below the bent connecting portion in the annular forming step. And the manufacturing method of the rotor lamination | stacking iron core which forms the notch which accommodates the swelling of the thickness direction which generate | occur | produces in this connection part. The method for manufacturing a rotor laminated core according to claim 10, wherein in the punching step, a first engaging groove is formed on a radially inner side of the coupling portion of the segment core pieces, and the adjacent segment core pieces are formed. A second engaging groove formed by a notch facing the inner side of the side portion is formed, and the core member provided with the tooth portions to be fitted into the first and second engaging grooves is driven to rotate in the annular forming step. A method of manufacturing a rotor laminated core, wherein the laminated core pieces are laminated while being drawn. The method of manufacturing a laminated rotor core according to claim 10 or 11, wherein in the punching step to form a pilot hole in the segment core pieces, with said annular forming step, positioning of the segment core piece by the pilot hole A method for manufacturing a rotor laminated iron core, wherein the lamination is carried out while performing. The method for manufacturing a rotor laminated core according to any one of claims 10 to 12, wherein, in the annular forming step, a plurality of the strip-like core pieces are formed in an annular shape with respect to the rotor laminated core. A method for manufacturing a rotor laminated core, characterized by being directed in the same tangential direction. The method for manufacturing a rotor laminated core according to any one of claims 10 to 12, wherein, in the annular forming step, a plurality of the strip-like core pieces are formed in an annular shape with respect to the rotor laminated core. A method for manufacturing a rotor laminated iron core, characterized by being directed to tangential directions at different angles.

Images