JP2005204476A - Divided laminated stator core - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a divided laminated stator core capable of facilitating assembly work of a yoke laminated body and a pole laminated body at the time of production, and providing excellent shape accuracy as a product. <P>SOLUTION: In this divided laminated stator core, an inner side surface on one side of a joint recessed portion in the yoke laminated body is formed asymmetrically to an inner side surface on the other side of the joint recessed portion. An outer side surface on one side of a joint protruding portion in the pole laminated body is formed in a flat surface which is brought into close contact with the inner side surface on one side of the joint recessed portion in the yoke laminated body under the condition the pole laminated body is jointed and fixed at the yoke laminated body. The outer side surface on the other side of the joint protruding portion of the pole laminated body is formed into a shape which is brought into close contact with the inner side surface on the other side of the joint recessed portion in the yoke laminated body under the condition the pole laminated body is jointed and fixed at the yoke laminated body. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

    The present invention consists of a yoke laminate and a predetermined number of magnetic pole laminates, and a divided laminate comprising a predetermined number of magnetic poles in the radial direction of the yoke by connecting and fixing the magnetic pole laminate to the yoke laminate. It relates to the stator core.

    FIG. 10 shows a conventional laminated stator core A constituting a stator of an electric motor. The laminated stator core A is manufactured by caulking and laminating a predetermined number of core pieces Aa, and an annular yoke portion Ay. And a predetermined number of magnetic pole portions At projecting inward from the yoke portion Ay.

  Each magnetic pole part At in the laminated stator core A is wound, but the yoke part Ay has an annular shape and the interval between adjacent magnetic pole parts At is narrow. The winding work has been extremely difficult.

  As one of the measures for solving the above-described problems, a split laminated stator core B as shown in FIGS. 11 to 13 is provided. The split laminated stator core B includes a predetermined number of yoke pieces Ba. A connecting recess formed in the inner periphery of the yoke laminate By having a ring shape, which is composed of one yoke laminate By that is caulked and a predetermined number of pole laminates Bt that are caulked and laminated with a predetermined number of magnetic pole pieces Bb. The connecting protrusion Bd of the magnetic pole laminate Bt is fitted to Bg, and a predetermined number of magnetic pole laminates Bt are assembled inside the yoke laminate By.

  Here, the connecting concave portion Bg of the yoke laminate By and the connecting convex portion Bd of the magnetic pole laminate Bt are each configured by an ant groove and an ant that fits into the ant groove. As shown in FIG. 13, the connecting recess Bg of the yoke laminate By is configured by a T-shaped groove, and the connecting convex portion Bd of the magnetic pole stack Bt is configured by a T-shaped projection fitted into the T-shaped groove (for example, , See Patent Document 1).

According to the split laminated stator core B having the above-described configuration, after winding the winding L around each magnetic pole laminated body Bt, the magnetic pole laminated body Bt is assembled to the yoke laminated body By, and the laminated stator core B is assembled. Therefore, the winding operation of the winding L around each magnetic pole laminate Bt is extremely easy, and the winding L is wound around the magnetic pole laminate Bt with a good proportion.
JP-A-2-7839

    By the way, in the conventional split laminated stator core B, the connecting concave portion Bg and the connecting convex portion Bd constituted by the dovetail and the dovetail or the T-shaped groove and the T-shaped projection as described above are respectively in the radial direction of the yoke laminate By. Since the axis and the longitudinal axis of the magnetic pole stack Bt are formed symmetrically, when the yoke stack By and the magnetic pole stack Bt are connected and fixed, the connecting recess Bg and the connecting protrusion Bd It is necessary to align the left and right edges with each other.

  The connecting recess Bg and the connecting protrusion Bd are connected to each other in order to firmly connect and fix the yoke stack By and the pole stack Bt and to improve the shape accuracy of the split stacked stator core B. The fitting allowance is set as small as possible.

  For this reason, in the conventional split laminated stator core B, when the yoke laminated body By and the magnetic pole laminated body Bt are connected and fixed by fitting the connecting convex part Bd to the connecting concave part Bg during the production, The inconvenience of requiring a high degree of skill and a great amount of work time cannot be avoided.

  An object of the present invention is to provide a split laminated stator core that can easily perform assembly work of a yoke laminated body and a magnetic pole laminated body at the time of manufacture in view of the above-described situation, and also has excellent shape accuracy as a product. There is to do.

    In order to achieve the above object, a split laminated stator iron core according to the invention of claim 1 includes a yoke laminate formed by caulking and laminating a predetermined number of yoke pieces punched and formed from a metal plate, and a predetermined stamped and formed from a metal plate. A magnetic pole laminate formed by caulking and laminating a number of magnetic pole pieces, and a predetermined number of coupling recesses are provided on the inner periphery of the yoke laminate, while the pole projections are fitted with coupling recesses of the yoke laminate. A split is formed by connecting and fixing a predetermined number of magnetic pole laminates wound with separate windings or coiled bobbins to a yoke laminate by providing a portion and fitting the connection recesses and connection projections together. A laminated stator core, in which one inner side surface of the connecting recess in the yoke laminate is formed on a plane along the radial direction of the yoke stack, and the other inner side surface of the connecting recess in the yoke stack is connected Concave The outer surface of one of the connecting projections in the magnetic pole stack is connected to and fixed to the yoke stack, and one of the connecting recesses in the yoke stack is fixed. The other inner surface of the connecting recess in the yoke laminate is formed in a plane that is in close contact with the inner surface, and the other outer surface of the connecting protrusion in the pole stack is connected and fixed to the yoke stack. It is characterized by its close shape.

  Further, the split laminated stator core according to the invention of claim 2 is the split laminated stator core according to the invention of claim 1, wherein the other inner surface of the connecting recess in the yoke laminate is the inner peripheral surface of the yoke laminate. A parallel surface that is parallel to one inner surface from the middle to the middle, and a widened surface that extends from the middle to the back, and the other outer surface of the connecting convex portion in the magnetic pole stack is a magnetic pole on the yoke stack. In a state in which the stacked bodies are connected and fixed, the stacked body has a parallel surface that is in close contact with the parallel surface of the connection recess and a projecting surface that is in close contact with the expanded surface of the connection recess.

  According to a third aspect of the present invention, the split laminated stator core according to the third aspect of the present invention is the divided laminated stator core according to the first or second aspect of the present invention, wherein the connecting convexities of the magnetic pole laminate fitted into the connecting concave portions of the yoke laminate are provided. It is characterized in that the magnetic pole laminate is connected and fixed to the yoke laminate by pressing and expanding the portion.

According to the split laminated stator core relating to the invention of claim 1, one inner side surface of the coupling recess in the yoke laminate is a plane along the radial direction of the yoke laminate, and the coupling convex in the pole laminate. One of the outer surfaces is a flat surface that is in close contact with one inner surface of the connecting recess in the yoke laminate in a state where the magnetic pole stack is connected and fixed to the yoke stack, so that the connecting protrusion is fitted into the connecting recess. When the magnetic pole stack is connected and fixed to the yoke stack, the connection recess and the connection recess are defined based on one inner surface (plane) of the connection recess and one outer surface (plane) of the connection protrusion. Relative alignment with the connecting convex portion is facilitated, and therefore, the assembly work of the yoke laminate and the magnetic pole laminate at the time of manufacture can be easily performed.
Furthermore, in a state in which the magnetic pole laminate is connected and fixed to the yoke laminate, the one inner side surface (plane) in the connection recess and the one outer surface (plane) of the connection projection are brought into close contact with each other, whereby the yoke laminate is obtained. As a result, the relative assembly shape accuracy between the magnetic pole laminate and the magnetic pole laminate is improved, so that a divided laminated stator core excellent in product shape accuracy can be obtained.

According to the split laminated stator core relating to the invention of claim 2, as with the split laminated stator core relating to the invention of claim 1, the assembly work of the yoke laminate and the magnetic pole laminate can be easily performed at the time of manufacture. In addition, it is possible to obtain excellent shape accuracy as a product.
In addition, a parallel surface and an enlarged surface are provided on the other inner surface of the coupling recess in the yoke laminate, and the pole laminate is coupled and fixed to the yoke laminate on the other outer surface of the coupling projection in the pole laminate. In this state, by providing a parallel surface and a projecting surface that are in close contact with the parallel surface and the enlarged surface of the connection recess, the fitting strength between the connection recess and the connection protrusion is increased, so that the yoke laminate and The coupling strength with the magnetic pole laminate and the assembly accuracy can be improved.

According to the split laminated stator core related to the invention of claim 3, as with the split laminated stator core related to the invention of claim 1, the assembly work of the yoke laminate and the magnetic pole laminate can be easily performed at the time of manufacture. In addition, it is possible to obtain excellent shape accuracy as a product.
Further, the connecting protrusions of the magnetic pole laminate fitted into the connecting recesses of the yoke laminate are pressed and enlarged, and the magnetic pole laminate is connected and fixed to the yoke laminate, thereby coupling the yoke laminate and the magnetic pole laminate. The strength can be greatly improved.

Hereinafter, the present invention will be described in detail with reference to the drawings illustrating embodiments.
1 to 4 show a first embodiment of a divided laminated stator core according to the present invention. This divided laminated core 1 includes one yoke laminated body 10 having a ring shape and the yoke laminated structure. A predetermined number (eight) of magnetic pole laminates 20, 20... Assembled inside the diameter of the body 10.

  The yoke laminate 10 is formed by caulking and laminating a predetermined number of yoke pieces 11, 11,... Punched from a strip steel plate (metal plate) as will be described later. A predetermined number (eight places) of connecting recesses 10A, 10A... Are formed in the part. In addition, the code | symbol 11c in a figure is a crimping part formed in each yoke piece 11,11 ....

  On the other hand, the magnetic pole laminate 20 is configured by caulking and laminating a predetermined number of magnetic pole pieces 21, 21... Punched from a strip steel plate (metal plate) as will be described later. In the base end portion, a connecting convex portion 20A that fits with the connecting concave portion 10A of the yoke laminate 10 described above is formed. In addition, the code | symbol 12c in a figure is the crimping part formed in each magnetic pole piece 21,21 ....

  As shown in FIG. 1, in the above-described split laminated stator core 1, the connecting convex portions 20 </ b> A in the magnetic pole laminate 20 are fitted into the connecting concave portions 10 </ b> A, 10 </ b> A. A predetermined number of magnetic pole laminates 20, 20... Are connected and fixed inside the diameter.

  Here, the connecting recess 10A in the yoke laminate 10 is a groove that opens to the inner peripheral edge of the yoke laminate 10, and one inner side surface 10a thereof is in the radial direction of the yoke laminate 10 (divided laminate stator core). 1 (in the radial direction).

  The other inner side surface 10b of the connecting recess 10A is formed asymmetrically with respect to the one inner side surface 10a, and extends parallel to the one inner side surface 10a from the inner peripheral edge to the middle. 10p and a widened surface 10q that inclines and spreads away from one inner side surface 10a from the middle to the back.

  On the other hand, the connecting convex portion 20A in the magnetic pole laminate 20 is a ridge protruding from the base end of the magnetic pole laminate 20, and one outer side surface 20a thereof is the longitudinal direction of the magnetic pole laminate 20, in other words, a divided laminated stator. It is formed in a plane along the radial direction of the iron core 1 (the radial direction of the yoke laminate 10).

  The other outer surface 20b of the connecting convex portion 20A is formed asymmetrically with respect to the one outer surface 20a, and extends parallel to the one outer surface 20a from the base to the middle. And a projecting surface 20q that inclines and spreads away from one outer surface 20a from the middle to the tip.

  Here, as shown in FIG. 4, in a state in which the connecting convex portion 20 </ b> A of the magnetic pole stack 20 is fitted into the connecting concave portion 10 </ b> A of the yoke stack 10, and the yoke stack 10 and the magnetic pole stack 20 are connected and fixed to each other. The one inner side surface 10a made of a plane in the connecting recess 10A and the one outer side surface 20a made of a plane in the connecting projection 20A are in close contact with each other.

  Further, the other inner side surface 10b of the connecting concave portion 10A and the other outer side surface 20b of the connecting convex portion 20A are in close contact with each other. Specifically, the parallel surface 10p and the enlarged surface 10q of the connecting concave portion 10A and the parallel surface 20p and the protruding surface 20q of the connecting convex portion 20A are in close contact with each other.

Below, an example of the process of manufacturing the split laminated stator core 1 mentioned above is demonstrated.
First, as shown in FIG. 5, the yoke laminate 10 and the pole laminate 20 are formed from a strip steel plate (metal plate) W through processing stations S1 to S8 of a transfer press (not shown).

  That is, the pilot hole P is formed at the processing station S1, the crimping portion Rc for the rotor is formed at the processing station S2, and the rotor piece R is cut out and caulked and laminated at the processing station S3 to manufacture a rotor (not shown). After that, the pole piece caulking portion 21c is formed at the processing station S4, and then the magnetic pole piece 21 is removed / caulked and laminated at the processing station S5 to manufacture the magnetic pole laminate 20 (see FIG. 2A).

  Further, the yoke piece caulking portion 11c is formed at the processing station S6, and then the yoke piece 11 is subjected to the outer shape removal / caulking lamination at the processing station S8 after passing through the play processing station S7 to obtain the yoke laminated body 10 (FIG. )).

  The manufacturing procedure of the yoke laminate 10 and the magnetic pole laminate 20 using the transfer press is not limited to the above-described embodiments, and can be set as appropriate. It is also possible to separately manufacture the body 10 and the magnetic pole laminate 20 using a dedicated breath machine.

  As described above, after the yoke laminate 10 and the pole laminate 20 are manufactured, the winding L (see FIG. 1) is wound around the pole laminate 20 using a dedicated device (not shown). In addition to directly winding the winding L around the magnetic pole laminate 20, a bobbin (not shown) around which the winding L is wound may be attached to the magnetic pole laminate 20 in a separate process. Needless to say.

  Here, when winding the winding L around the magnetic pole laminate 20, the magnetic pole laminate 20 is separated from the yoke laminate 10, so that the winding operation of the winding L around the magnetic pole laminate 20 is extremely easy. As a result, the winding L is wound with a good proportion.

  After the winding L has been wound around the predetermined number of magnetic pole laminates 20, the connecting convex portions 20A in the magnetic pole laminate 20 are arranged in the axial direction of the yoke laminated body 10 with respect to the connecting concave portions 10A in the yoke laminated body 10. The yoke laminate 10 and the pole laminate 20 are connected and fixed to each other.

  At this time, the connecting concave portion of the yoke laminate 10 is brought into contact with the one outer side surface 20a of the connecting convex portion 20A, which is also configured from a flat surface, with one inner side surface 10a of the connecting concave portion 10A formed from a flat surface. By fitting the connecting convex portion 20A of the magnetic pole laminate 20 into 10A, in other words, one inner side surface (plane) 10a of the connecting concave portion 10A, or one outer side surface (plane) 20a of the connecting convex portion 20A, By using the relative reference in the mutual alignment, the relative positioning of the connecting concave portion 10A and the connecting convex portion 20A can be facilitated. Assembling work can be easily performed.

  As described above, the connecting convex portion 20A of the magnetic pole laminate 20 is fitted into the connecting concave portion 10A of the yoke laminate 10, and the yoke laminate 10 and the magnetic pole laminate 20 are connected and fixed to each other, whereby the split laminated stator core 1 is provided. The stator of the motor in which the winding L is wound around each of the magnetic pole laminates 20, 20.

  Here, in a state in which the magnetic pole laminate 20 is connected and fixed to the yoke laminate 10, one inner side surface 10a made of a plane in the connection recess 10A and one outer side surface 20a made of a plane in the connection projection 20A are formed. As a result, the relative assembly shape accuracy of the yoke laminate 10 and the magnetic pole laminate 20 is improved, so that the split laminated stator core 1 having excellent product shape accuracy can be obtained.

  Furthermore, in the state where the magnetic pole laminate 20 is connected and fixed to the yoke laminate 10, as described above, one inner side surface 10a of the connecting recess 10A and one outer side surface 20a of the connecting projection 20A are in close contact with each other. In addition, the parallel surface 10p and the enlarged surface 10q constituting the other inner side surface 10b in the connecting concave portion 10A, and the parallel surface 20p and the projecting surface 20q constituting the other outer surface 20b in the connecting convex portion 20A are in close contact with each other. As a result, the fitting strength between the connecting concave portion 10A and the connecting convex portion 20A increases, and the coupling strength and assembly accuracy between the yoke laminate 10 and the magnetic pole laminate 20 are improved.

  FIG. 6 shows a second embodiment of the divided laminated stator core according to the present invention. This divided laminated stator core 1 'is connected to the connecting recess 10A' of the yoke laminated body 10 'in the magnetic pole laminated body 20'. 'Is connected to connect the yoke laminate 10' and the magnetic pole laminate 20 ', and the tip 20Aa' (cross-hatched region in the figure) of the connection convex 20A 'is connected. The press is enlarged.

  Here, the structure of the divided laminated stator core 1 ′ described above is the same as that of the divided laminated stator core 1 shown in the first embodiment, except that the distal end portion 20Aa ′ of the connecting convex portion 20A ′ is pressed and expanded. There is no change.

  According to the split laminated stator core 1 ′ having the above configuration, as with the split laminated stator core 1 shown in the first embodiment, the assembly work of the yoke laminate and the magnetic pole laminate can be easily performed at the time of manufacture. In addition, excellent shape accuracy as a product can be obtained, and the connecting protrusion 20A ′ is pressed and expanded to connect and fix the magnetic pole stack 20 ′ to the yoke stack 10 ′. It becomes possible to greatly improve the bonding strength with the laminate 20 ′.

  The portion where the connecting convex portion 20A ′ is pressed and enlarged is not limited to the tip portion 20Aa ′ shown in the embodiment, but a part / all of the peripheral edge of the connecting convex portion 20A ′ or the connecting convex portion. Of course, the entire area of 20A 'may be pressed and expanded.

  FIG. 7 shows a third embodiment of the split laminated stator core 100 according to the present invention. In this split laminated stator core 100, the inner side of the connecting recess 110A in the yoke laminate 110 is expanded in a rectangular shape. On the other hand, the tip side portion of the connecting convex portion 120A in the magnetic pole laminate 120 protrudes in a rectangular shape.

  Then, one inner side surface 110a of the coupling recess 110A in the yoke laminate 110 is formed in a plane along the radial direction of the yoke laminate 110, and the other inner side surface 110b of the coupling recess 110A is a parallel surface 110p and an enlarged surface 110q. In addition, one outer surface 120a of the connecting protrusion 120A in the magnetic pole stack 120 is formed in a plane along the longitudinal direction of the magnetic pole stack 120 (the radial direction of the yoke stack 110). The other outer surface 120b of the portion 120A has a parallel surface 120p and a projection surface 120q.

  FIG. 8 shows a fourth embodiment of the split laminated stator core 200 according to the present invention. In this split laminated stator core 200, the inner side of the connecting recess 210A in the yoke laminate 210 expands in a half-moon shape. On the other hand, the tip side portion of the connecting convex portion 220A in the magnetic pole laminate 220 protrudes in a half-moon shape.

  Then, one inner side surface 210a of the connecting recess 210A in the yoke laminate 210 is formed in a plane along the radial direction of the yoke laminate 210, and the other inner side surface 210b of the connecting recess 210A is a parallel surface 210p and an enlarged surface 210q. In addition, one outer surface 220a of the connecting protrusion 220A in the magnetic pole stack 220 is formed in a plane along the longitudinal direction of the magnetic pole stack 220 (the radial direction of the yoke stack 210). The other outer surface 220b of the portion 220A has a parallel surface 220p and a projecting surface 220q.

  FIG. 9 shows a fifth embodiment of a split laminated stator core 300 according to the present invention. In this split laminated stator core 300, one inner side surface 310a of the connecting recess 310A in the yoke laminate 310 is yoke laminated. The other inner side surface 310b of the connecting recess 310A is formed in a plane inclined with respect to the radial direction of the yoke laminate 310, and the connecting protrusion in the magnetic pole laminate 320 is formed in a plane along the radial direction of the body 310. One outer surface 320a of the part 320A is formed in a plane along the longitudinal direction of the magnetic pole stack 320 (the radial direction of the yoke stack 310), and the other outer surface 320b of the connecting protrusion 320A is formed in an inclined plane. ing.

  Here, the divided laminated stator core 100, the divided laminated stator core 200, and the divided laminated stator core 300 described above are divided laminated according to the first embodiment, except for the shapes related to the connecting concave portions and the connecting convex portions. There is no difference from the stator core 1.

  In each of the divided laminated stator cores 100, 200, and 300 described above, as with the divided laminated stator core 1 shown in the first embodiment, the assembly work of the yoke laminated body and the magnetic pole laminated body at the time of manufacture is performed. A split laminated stator core that can be easily implemented and has excellent shape accuracy as a product can be obtained, and the coupling strength and assembly accuracy between the yoke laminate and the pole laminate can be improved.

  Further, in each of the divided laminated stator cores 100, 200, and 300, like the divided laminated stator core 1 'shown in FIG. 6, the connecting projections are pressed and expanded to connect the magnetic pole laminated body to the yoke laminated body. By fixing, the coupling strength between the yoke laminate and the magnetic pole laminate can be greatly improved.

  The shape of the connecting recess in the yoke stack and the shape of the connecting protrusion in the magnetic pole stack are not limited to the above-described embodiments, but are based on various conditions such as the shape of the split-stack stator core. Needless to say, it can be set appropriately.

  In the above-described embodiment, a split laminated stator core composed of a yoke laminated body having an annular shape and eight magnetic pole laminated bodies is illustrated, but the present invention is not limited to the above-described embodiment. Of course, the present invention can also be effectively applied to split laminated stator cores having various configurations.

The whole top view which shows the 1st Example of the division | segmentation laminated | stacked stator core concerning this invention. (a) And (b) is an external appearance perspective view which shows the magnetic pole laminated body and yoke laminated body in the division | segmentation laminated | stacked stator iron core shown in FIG. (a) And (b) is a principal part enlarged plan view which shows the connection recessed part of the yoke laminated body, and the connection convex part of a magnetic pole laminated body in the division | segmentation laminated | stacked stator core shown in FIG. The principal part enlarged plan view which shows the connection fixation aspect of the yoke laminated body and magnetic pole laminated body in the division | segmentation laminated | stacked stator core shown in FIG. The top view which shows the punching process of the metal plate at the time of manufacturing the magnetic pole laminated body and yoke laminated body of the division | segmentation laminated | stacked stator core shown in FIG. The principal part enlarged plan view of the yoke laminated body and magnetic pole laminated body which show the 2nd Example of the division | segmentation laminated | stacked stator core concerning this invention. The principal part enlarged plan view of the yoke laminated body which shows the 3rd Example of the division | segmentation laminated | stacked stator core concerning this invention, and a magnetic pole laminated body. The principal part enlarged plan view of the yoke laminated body which shows the 4th Example of the division | segmentation laminated | stacked stator core concerning this invention, and a magnetic pole laminated body. The principal part enlarged plan view of the yoke laminated body which shows the 5th Example of the division | segmentation laminated | stacked stator core concerning this invention, and a magnetic pole laminated body. The whole perspective view which shows the conventional lamination | stacking stator core. The whole top view which shows the conventional division | segmentation laminated | stacked stator core. The principal part enlarged plan view of the yoke laminated body and magnetic pole laminated body in the conventional division | segmentation laminated | stacked stator iron core shown in FIG. The principal part enlarged plan view which shows the yoke laminated body and magnetic pole laminated body in the other conventional split laminated stator core.

Explanation of symbols

1 ... split laminated stator core,
10 ... Yoke laminate,
10A ... Connection recess,
10a ... one inner surface,
10b ... the other inner surface,
10p ... parallel plane,
10q ... expanded surface,
11 ... Yoke piece,
20 ... magnetic pole laminate,
20A ... Connection convex part,
20a ... one outer surface,
20b ... the other outer surface,
20p ... parallel plane,
20q ... projection surface,
21 ... pole pieces,
L ... Winding,
W: Strip steel plate (metal plate).

Claims (3)

A yoke laminate formed by caulking and stacking a predetermined number of yoke pieces punched from a metal plate; and a magnetic pole stack formed by caulking and stacking a predetermined number of pole pieces punched and formed from the metal plate, the yoke While providing a predetermined number of connecting recesses on the inner periphery of the laminate, the magnetic pole stack is provided with a connecting projection for fitting with the connecting recess of the yoke stack, and the connecting recess and the connecting projection are fitted to each other. By combining, a split laminated stator core formed by connecting and fixing a predetermined number of the magnetic pole laminates separately wound with windings or coiled bobbins to the yoke laminate,
One inner side surface of the connection recess in the yoke laminate is formed on a plane along the radial direction of the yoke laminate, and the other inner side surface of the connection recess in the yoke laminate is formed on the connection recess. Asymmetric with respect to one inner surface,
One outer surface of the connecting projection in the magnetic pole stack is in a plane in close contact with one inner surface of the connecting recess in the yoke stack in a state where the magnetic pole stack is connected and fixed to the yoke stack. And forming the other outer side surface of the connection convex portion in the magnetic pole stack in a state where the magnetic pole stack is connected and fixed to the yoke stack, and the other inner side surface of the connection recess in the yoke stack. A split laminated stator core characterized by a close shape. The other inner side surface of the connecting recess in the yoke laminate extends from the inner peripheral surface of the yoke laminate to the middle, a parallel surface parallel to the one inner surface, and an expansion from the middle to the back. And having a surface,
A parallel surface closely contacting the parallel surface of the connection recess in the state where the other outer surface of the connection protrusion in the magnetic pole stack is connected and fixed to the yoke stack; and the connection recess 2. The split laminated stator core according to claim 1, further comprising: a projecting surface closely contacting the expanded surface. 2. The magnetic pole laminate is connected and fixed to the yoke laminate by pressing and expanding the connection convex portion of the magnetic pole laminate fitted in the connection recess of the yoke laminate. The split laminated stator core according to claim 2.

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