DE112018005461T5 - Stator core and manufacturing method of a stator core - Google Patents

Abstract

A stator core is arranged so as not to allow the accuracy of a front end position of a tooth portion to be lowered or the number of components to be increased, and also to facilitate coil winding operation. The stator core includes a first stator section formed from a stacked assembly of first stator parts, each of which has first engaging tooth portions engageable with and detachable from an annular first yoke portion, and first fixed tooth portions associated with the first yoke portion are formed in one piece, and a second stator section which is stacked on the first stator section, the second stator section being formed from a stacked assembly of second stator parts, each of which has second fixed tooth sections which are formed in one piece with a second yoke section, and second engagement tooth sections has which can be brought into engagement with and detachable from the second yoke section. Furthermore, a coil section is provided for at least the set of the first engagement tooth sections and the second fixed tooth sections and / or the set of the first fixed tooth sections and the second engagement tooth sections by overlapping them with one another.

Description

Technical field

The present invention relates to a stator core composed of a stacked assembly of stator parts having a plurality of tooth portions formed on an inner peripheral surface of an annular yoke. The invention also relates to a manufacturing method of the stator core.

State of the art

As an example of a stator core set up as described above, Patent Document 1 shows a stator core that includes a yoke core, tooth cores that are separate from each other with respect to the yoke core, and a winding core that is inserted on the outside of the tooth cores with a coil wound around them . Patent Document 1 describes, as a manufacturing method of the stator core, a technique according to which the tooth cores are mounted on the yoke core after the coil is wound around the winding core.

According to the technique shown in Patent Document 1, the tooth core is attached to the yoke core. Thus, compared to, for example, an arrangement of the tooth cores that are fixed to the yoke core in advance, there is no need to secure a tool room to enable coil winding in the vicinity of the tooth core. Furthermore, with the technique of Patent Document 1, a silent motor design is possible because there is no design limitation on the shape of the front ends of the ends of the teeth.

Reply list

Patent Document 1: Japanese Patent Laid-Open No. 2013-118749

Summary of the invention

Technical task

However, since the stator core according to Patent Document 1 is arranged so that the tooth cores are supported on the yoke core, there is a tendency for the accuracy of the position of the front ends of each tooth core to deteriorate.

Furthermore, in the stator core according to Patent Document 1, the tooth cores, the yoke core and the winding core are provided separately, and these components must be assembled individually. Thus, in addition to increasing the number of components, the arrangement has the disadvantage that the number of assembly steps is increased, so that there is room for improvement in possible deterioration in the manufacturing efficiency.

For the reasons mentioned above, there is a need for a stator core and a manufacturing method for the stator core which do not allow the accuracy of the front end position of the tooth portion to be lowered or the number of components are not increased, and which also facilitate the coil winding operation.

Solution of the task

• eine erste Statorpartie, die aus einer gestapelten Baugruppe aus ersten Statorteilen besteht, von denen jedes mindestens zwei Gruppen aus einer Vielzahl von ersten Eingriffszahnabschnitten, die an einem Innenumfang eines ringförmigen ersten Jochs abnehmbar gestützt sind, und eine Vielzahl von ersten fixierten Zahnabschnitten hat, die auf dem Innenumfang des ersten Jochabschnitts einstückig ausgebildet sind;
• eine zweite Statorpartie, die aus einer gestapelten Baugruppe von zweiten Statorteilen besteht, wobei die zweite Statorpartie auf der ersten Statorpartie gestapelt ist, wobei jedes zweite Statorteil mindestens zwei Gruppen aus einer Vielzahl von zweiten fixierten Zahnabschnitten, die an Positionen angeordnet sind, die die ersten Eingriffszahnabschnitte überlappen, und auf einem Innenumfang eines zweiten Jochabschnitts einstückig ausgebildet sind, der dieselbe Form hat wie der erste Jochabschnitt, und einer Vielzahl von zweiten Eingriffszahnabschnitten hat, die an Positionen angeordnet sind, die die ersten fixierten Zahnabschnitte überlappen, und an dem Innenumfang des zweiten Jochabschnitts abnehmbar gestützt sind; und
• eine Spulenpartie, die aus einem leitfähigen Draht besteht, der mindestens um einen integrierten Satz aus den ersten Eingriffszahnabschnitten und den zweiten fixierten Zahnabschnitten und/oder einen integrierten Satz aus den ersten fixierten Zahnabschnitten und den zweiten Eingriffszahnabschnitten gewickelt ist, wenn die erste Statorpartie und die zweite Statorpartie aufeinander gestapelt sind.

According to a characteristic feature of a stator core provided by the present invention, the stator core comprises:

• a first stator section consisting of a stacked assembly of first stator parts, each of which has at least two groups of a plurality of first engagement tooth portions detachably supported on an inner periphery of an annular first yoke and a plurality of first fixed tooth portions on the inner circumference of the first yoke section is formed in one piece;
• a second stator section consisting of a stacked assembly of second stator parts, the second stator section being stacked on the first stator section, each second stator section comprising at least two groups of a plurality of second fixed tooth sections arranged at positions that match the first engagement tooth sections overlap, and are integrally formed on an inner periphery of a second yoke portion having the same shape as the first yoke portion and having a plurality of second engagement tooth portions arranged at positions overlapping the first fixed tooth portions and on the inner periphery of the second yoke portion are detachably supported; and
• a coil section consisting of a conductive wire which is wound around at least one integrated set of the first engagement tooth sections and the second fixed tooth sections and / or an integrated set of the first fixed tooth sections and the second engagement tooth sections when the first stator section and the second Stator section are stacked on top of each other.

According to the characteristic arrangement described above, when the first stator section and the second stator section are to be separated from each other, all of the first engagement tooth portions can be separated from the first stator section and moved together while being are stacked on the second fixed tooth sections of the second stator section. Similarly, if the first stator section and the second stator section are to be separated from one another, all of the second engagement tooth sections can be separated from the second stator section and moved together while stacked on the first fixed tooth sections of the first stator section.

In the separated state described above, in the first stator section, clear spaces are formed on the opposite sides of the integrated stacked assembly of the second engaging tooth portions and the first fixed tooth portions in the circumferential direction of the first yoke portion. Thus, if the coil section is to be formed by winding a conductive wire around this integrated assembly, the winding operation of the conductive wire can be carried out easily. Similarly, in the separated state described above, in the second stator section, free spaces are formed on the opposite sides of the integrated stacked assembly from the first engagement tooth portions and the second fixed tooth portions in the circumferential direction of the second yoke portion. Thus, if the coil section is to be formed by winding a conductive wire around this integrated assembly, this winding operation of the conductive wire can also be carried out simply in this case.

More specifically, although the first engagement tooth portions and the second engagement tooth portions are configured to be detachable, the first fixed tooth portions are fixed in one position with respect to the first yoke portion, and the second fixed tooth portions are fixed in one position with respect to the second yoke portion. Therefore, the front end of each tooth portion composed of the combination of the engagement tooth portion and the fixed tooth portion can be maintained at a fixedly designed position. Furthermore, with respect to the first stator part and the second stator part, their fixed tooth portions and the engaging tooth portions can be formed at the same time, if necessary, for example during a press work. Thus, an increase in the number of components can be suppressed.

In this way, a stator core was realized which does not allow the accuracy of the front end positions of the tooth section to be reduced or does not increase the number of components, and which also makes the coil winding operation easier.

• sind die ersten Eingriffszahnabschnitte und die ersten fixierten Zahnabschnitte in der Umfangsrichtung entlang des Innenumfangs des ersten Jochabschnitts abwechselnd angeordnet; und
• sind die zweiten Eingriffszahnabschnitte und die zweiten fixierten Zahnabschnitte in der Umfangsrichtung entlang des Innenumfangs des zweiten Jochabschnitts abwechselnd angeordnet.

According to another contemplated arrangement

• the first engagement tooth portions and the first fixed tooth portions are alternately arranged in the circumferential direction along the inner circumference of the first yoke portion; and
• the second engaging tooth portions and the second fixed tooth portions are alternately arranged in the circumferential direction along the inner periphery of the second yoke portion.

With the arrangement described above, the conductive wire can be wound around the first engagement tooth portions and the second fixed tooth portions stacked on each other in the state in which the first stator section and the second stator section are separated from each other. Similarly, the conductive wire can also be wound around the second engagement tooth portions and the first fixed tooth portions stacked on top of each other in the state in which the first stator section and the second stator section are separated from each other. Namely, the coil winding operation can be carried out in a state in which one of the corresponding tooth portions is missing, which would otherwise be arranged side by side in the alternating arrangement. The coil winding operation is thus facilitated.

In this way, the wire can be wound around one or both of the corresponding paired tooth sections, which are arranged alternately.

According to yet another proposed arrangement
the coil section is formed for only one of either the integrated set of first fixed tooth portions and the second engaging tooth portions stacked on one another or the integrated set of second fixed tooth portions and the first engaging tooth portions stacked on each other;
wherein, if the conductive wire is wound around the first fixed tooth portions and the second engagement tooth portions, the first stator parts have a larger number of stacks than the second stator parts; and
whereas, if the wound wire is wound around the second fixed tooth portions and the first engaging tooth portions, the second stator parts have a larger number of stacks than the first stator parts.

With the arrangement described above, the number of stacks of the first stator parts is set larger than the number of stacks of the second stator parts in a case that the part in which the formation of the coil section is to take place includes the first fixed tooth portions. In the case, however, that the part in which the formation of the If the coil section is to take place, which comprises second fixed tooth sections, the number of stacks of the second stator parts is set greater than the number of stacks of the first stator parts. In this way, with the increase in the number of stacks for the coil section forming section selected between the first fixed tooth sections and the second fixed tooth sections, the wire winding operation for forming the coil section can be carried out in a stable manner.

According to an even more contemplated arrangement
a caulking portion is configured at a junction between the first yoke portion and the second yoke portion to provide a weaker connecting force than a caulking force provided by a caulking portion of a stacking surface for connecting the first stator parts adjacent to each other in the first yoke portion, or as a connecting force provided by a caulking portion of a stack surface for connecting the second stator parts adjacent to each other in the second yoke portion.

With the above-described arrangement, the separating operation can be easily performed by separating the first stator section from the second stator section while maintaining the stacked state of the first yoke section of the first stator section and also maintaining the stacked state of the second yoke section of the second stator section.

• einen Ausbildungsschritt eines ersten Statorteils aus einem Ausbilden eines ersten Statorteils, das mindestens zwei Gruppen von Zahnabschnitten aus einer Vielzahl von ersten Eingriffszahnabschnitten, die an einem Innenumfang eines ringförmigen ersten Jochabschnitts abnehmbar gestützt sind, und einer Vielzahl von ersten fixierten Zahnabschnitten umfasst, die in dem Innenumfang des ersten Jochabschnitts einstückig ausgebildet sind;
• einen Ausbildungsschritt eines zweiten Statorteils aus einem Ausbilden eines zweiten Statorteils, das mindestens zwei Gruppen von Zahnabschnitten aus einer Vielzahl von zweiten Eingriffszahnabschnitten, die an einer Innenumfangsfläche eines ringförmigen zweiten Jochabschnitts abnehmbar gestützt sind, und einer Vielzahl von zweiten fixierten Zahnabschnitten umfasst, die in dem Innenumfang des zweiten Jochabschnitts einstückig ausgebildet sind;
• einen Integrationsschritt aus einem Stapeln einer Vielzahl der ersten Statorteile und einer Vielzahl der zweiten Statorteile, um die ersten Eingriffszahnabschnitte und die zweiten fixierten Zahnabschnitte in der Stapelrichtung zu integrieren, und auch die ersten fixierten Zahnabschnitte und die zweiten Eingriffszahnabschnitte in der Stapelrichtung zu integrieren;
• einen Trennschritt aus einem Bewirken einer Trennung, wobei die zweiten Eingriffszahnabschnitte in einem gestapelten Zustand mit den ersten fixierten Zahnabschnitten integriert sind, und wobei auch die ersten Eingriffszahnabschnitte in einem gestapelten Zustand mit den zweiten fixierten Zahnabschnitten integriert sind, um dadurch eine erste Statorpartie, die die ersten fixierten Zahnabschnitte umfasst, die mit den zweiten Eingriffszahnabschnitten gestapelt sind, sowie eine zweite Statorpartie zu erlangen, die die zweiten fixierten Zahnabschnitte umfasst, die mit den ersten Eingriffszahnabschnitten gestapelt sind;
• einen Spulenpartieausbildungsschritt aus einem Wickeln der leitfähigen Spule mindestens um die ersten fixierten Zahnabschnitte und die zweiten Eingriffszahnabschnitte, die in dem gestapelten Zustand nach dem Trennschritt miteinander integriert sind und/oder die zweiten fixierten Zahnabschnitte und die ersten Eingriffszahnabschnitte, die in dem gestapelten Zustand nach dem Trennschritt miteinander integriert sind; und
• einen Eingriffskopplungsschritt zum Überlappen der ersten Statorpartie und der zweiten Statorpartie miteinander in der Stapelrichtung, sodass das Überlappen bewirkt, dass die ersten Eingriffszahnabschnitte mit dem ersten Jochabschnitt in Eingriff gelangen, und auch bewirkt, dass die zweiten Eingriffszahnabschnitte mit dem zweiten Jochabschnitt in Eingriff gelangen.

According to a characteristic feature of an inventive manufacturing method of a stator core, the method has the following:

• a step of forming a first stator part from forming a first stator part comprising at least two groups of tooth portions made of a plurality of first engaging tooth portions detachably supported on an inner periphery of an annular first yoke portion and a plurality of first fixed tooth portions formed in the inner periphery the first yoke section is formed in one piece;
• a second stator part forming step of forming a second stator part comprising at least two groups of tooth portions made of a plurality of second engaging tooth portions detachably supported on an inner peripheral surface of an annular second yoke portion and a plurality of second fixed tooth portions formed in the inner periphery the second yoke section are formed in one piece;
• an integrating step of stacking a plurality of the first stator parts and a plurality of the second stator parts to integrate the first engaging tooth portions and the second fixed tooth portions in the stacking direction and also integrating the first fixed tooth portions and the second engaging tooth portions in the stacking direction;
• a separating step of effecting separation, wherein the second engaging tooth portions are integrated with the first fixed tooth portions in a stacked state, and wherein the first engaging tooth portions are integrated with the second fixed tooth portions in a stacked state, thereby to provide a first stator portion which includes first fixed tooth portions stacked with the second engagement tooth portions and a second stator section including the second fixed tooth portions stacked with the first engagement tooth portions;
• a coil part formation step of winding the conductive coil at least around the first fixed tooth portions and the second engaging tooth portions which are integrated with each other in the stacked state after the separating step and / or the second fixed tooth portions and the first engaging tooth portions which are in the stacked state after the separating step are integrated with each other; and
• an engagement coupling step for overlapping the first stator portion and the second stator portion with each other in the stacking direction so that the overlap causes the first engagement tooth portions to engage the first yoke portion and also causes the second engagement tooth portions to engage the second yoke portion.

With the characteristic arrangement described above, the first stator part is formed by the formation step of the first stator part, and the second stator part is formed by the formation step of the second stator part. In the integration step, a plurality of first stator parts are stacked, and also a plurality of second stator parts are stacked, whereby the first fixed tooth portions and the second engagement tooth portions are stacked and integrated with each other, and also the first engagement tooth portions and the second fixed tooth portions are stacked and integrated with each other become. In the separation step, the first stator section and the second stator section are to be separated from one another. At this time, the first engaging tooth portions are engaged with the second fixed tooth portions in the stacked state because all of the first engaging tooth portions are from the first Stator section are separated, and the second engagement tooth portions in the stacked state are engaged with the first fixed tooth sections because all of the second engagement tooth sections are separated from the second stator section. As a result of the implementation of the separation step, the space next to the first fixed tooth section is enlarged in the circumferential direction of the first stator section. Similarly, in addition to the second fixed tooth section, the space is also enlarged in the circumferential direction of the second stator section.

As a result of the above, in the coil part formation step, for example, in a case where a coil part is to be formed around the outer periphery of the integrated assembly of the first engaging tooth portions and the second fixed tooth portions, because no second engaging tooth portions or first fixed tooth portions are in the position adjacent to the first Engaging tooth portion and the second fixed tooth portion are integrated with each other in the second stator section, the conductive coil is wound around the coil portion without being disturbed by the presence of the second engaging tooth portion and the first engaging tooth portion. This also applies to the case where the coil section is formed around the outer circumference of the second engagement tooth section and the first fixed tooth section, which are integrated with one another. Next, in the engaging coupling step, the first engaging tooth portions are engaged with the first stator section and the second engaging tooth portions are engaged with the second stator section by overlapping the first stator section with the second stator section in the stacking direction, whereby the stator core can be obtained.

More specifically, although the first engaging tooth portions and the second engaging tooth portions are configured to be detachable, the front end position of each tooth portion composed of the engaging tooth portion and the fixed tooth portion can be maintained at a desired position with high accuracy because they are related the second fixed tooth sections or the first fixed tooth sections are fixed in their position. Furthermore, for the first stator part, for example, the first engagement tooth sections can be formed during a pressing work of the first stator part. And similarly, the second engagement tooth portions can be formed during pressing work of the second stator part. Therefore, it is possible to suppress an increase in the number of components. Therefore, a manufacturing method of a stator core has been realized which does not allow the accuracy of the front end position of the tooth portion to be lowered or the number of components is not increased, and which also facilitates the coil winding operation.

Figure list

• 1 is a perspective view of a stator core,
• 2nd Fig. 3 is a sectional plan view showing the stator core,
• 3rd FIG. 12 is a perspective view showing a first stator part and a second stator part punched out of a magnetic steel plate by a press mill,
• 4th 12 is a perspective view showing a plurality of first stator parts and a plurality of second stator parts,
• 5 12 is a perspective view showing a first stator section and a second stator section overlapped with each other,
• 6 Fig. 3 is a perspective view showing the first stator section and the second stator section separated from each other,
• 7 FIG. 12 is a perspective view showing coil sections formed in the separated second stator section; FIG.
• 8th 12 is a perspective view showing a first engagement tooth portion in its disengaged state;
• 9 Fig. 3 is a perspective view showing a second engaging tooth portion in its disengaged state.
• 10 Fig. 3 is a perspective view showing a main pole tooth portion and insulators.
• 11 FIG. 14 is a flowchart of a manufacturing process of the stator core, and
• 12th is a section showing caulking sections.

Description of embodiments

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

[Basic configuration]

As in 1 and 2nd is shown has a stator core SC an annular yoke for an engine A centered about an axis X, two groups of tooth portions (tooth portions) that have a plurality (six in this embodiment) of main pole teeth B that towards the center from the inner circumference of the yoke A protrude, as well as a variety (six in this embodiment) of secondary pole teeth C. include that in a similar manner in Towards the middle of the yoke A protrude, as well as a variety of coil sections D on, each for the variety of main pole teeth B are provided.

In the stator core SC are the main pole teeth B and the secondary pole teeth C. along the circumferential direction of the yoke A arranged alternately. Every coil section D is formed by a conductive wire 2nd made of a good conductor, such as a copper alloy, to insulators 1 is wound on the outer surface of each of the plurality of main pole teeth B are embedded.

The stator core SC is intended for use in a brushless DC motor or in a three-phase motor and, as in 2nd a rotor is shown R with permanent magnets coaxial with the axis X at the central position of the yoke A is rotatably mounted.

[Stator parts]

As in the 3rd to 5 is shown is the stator core SC set up by a first stator section in the direction along the axis X. 10 consisting of a stacked assembly of a plurality of first stator parts 10a , each of which is made from a magnetic steel plate by a press and a stacked assembly of a plurality of second stator parts 20a exists, each of which is also made by the pressing plant from the magnetic steel plate, are overlaid with each other.

[First stator part]

As in 4th is shown, comprises the first stator part 10a an annular first yoke section 11 , which is centered about the axis X, and wherein there are two formed groups of tooth portions, which consist of a plurality of first engagement tooth portions 12th (Certain examples of the "main pole teeth B “) On the inner circumference of the first yoke section 11 are provided detachably, and a plurality of first fixed tooth sections 13 (certain examples of "auxiliary spur teeth C") exist with the inner circumference of the first yoke section 11 are formed in one piece.

In every first engaging tooth section 12th with reference to 8th , a first edge of engagement 12c that at the base end of the first engagement tooth portion 12th is arranged with a first engagement surface 11c releasably engaged in the inner periphery of the first yoke section 11 is provided. Furthermore, referring to the first engaging tooth portion 12th , during his press work after he has moved from the first yoke section 11 was solved, the first edge of engagement 12c of the first engaging tooth portion 12th with the first engagement surface 11c engaged in the inner circumference of the first yoke section 11 is provided.

[Second stator part]

Referring again to 4th , includes the second stator part 20a an annular second yoke section 21st , which is centered around the axis X and has the same shape as the first yoke section 11 , and which also comprises two groups of tooth sections, which consist of a plurality of second fixed tooth sections 22 (Certain examples of the "main pole teeth B “) With the inner circumference of the second yoke section 21st are integrally formed, and a plurality of second engagement tooth portions 23 (Specific example of the "secondary pole teeth C") exist on the inner circumference of the second yoke section 21st are provided releasably.

In every second engaging tooth section 23 with reference to 9 , a second engagement edge 23c that at the base end of the second engagement tooth portion 23 is arranged with a second engagement surface 21c releasably engaged in the inner circumference of the second yoke section 21st is provided. Referring to the second engaging tooth portion 23 , during his press work after he has moved from the second yoke section 21st was solved, the second edge of engagement 23c of the second engaging tooth portion 23 with the second engagement surface 21c engaged in the inner periphery of the second yoke section 21st is provided.

[Arrangement of Each Component of the Stator Part]

With the stator core SC are like in the 4th and 5 is shown the main pole teeth B built up by the first engaging tooth portions 12th and the second fixed tooth sections 22 be overlaid. And the secondary pole teeth C. are built up by the first fixed tooth sections 13 and the second engaging tooth portions 23 be overlaid

More specifically, is in the stator core SC , as in 12th is shown, both in the first stator section 10 as well as in the second stator section 20 their connection state in the stacking direction by an engagement of a caulking section E maintain that of a projection Ea and a recess Eb consists.

More specifically, by the first stator section 10 and the second stator section 20 are superimposed with one another, the large number of first stator parts 10a by means of the caulking sections E connected to each other, and the plurality of second stator parts 20a with each other by means of the caulking sections E connected. Furthermore, the connected state in the stacking direction is also by means of the caulking section E between the first stator part 10a and the second stator part 20a realized, each at the junction of the first stator section 10 and the second stator section 20 are arranged.

The first fixed tooth sections are in the connection states described above 13 and the second engaging tooth portions 23 that share the secondary pole teeth C. represent, integrated with each other, and are the first engagement tooth sections 12th and the second fixed tooth sections 22 that share the main pole teeth B represent, integrated with each other.

As below in connection with a manufacturing process of the stator core SC The first stator section is described in detail 10 and the second stator section 20 separated after the first stator section 10 and the second stator section 20 were overlaid and then the first stator parts 10a and the second stator parts 20a by means of the caulking sections E were connected. In this regard, the connecting force created by the caulking sections E at the junction of the first yoke section 11 and the second yoke section 21st is provided, reduced in a positive manner, so that the above-described separation operation between the first stator section 10 and the second stator section 20 can be carried out with simplicity while the integrated state between the first fixed tooth sections 13 and the second engaging tooth portions 23 and the integrated state between the first engagement tooth sections 12th and the second fixed tooth sections 22 can be maintained in this state.

With particular reference to the above arrangement, the connecting force is caused by the plurality of caulking sections E for connecting the corresponding components of the first stator parts 10a is provided at their stacking surfaces in the stacking direction, equal to that connecting force established by the plurality of caulking sections E for connecting the corresponding components of the second stator parts 20a is provided at their stacking surfaces in the stacking direction. On the other hand, as in the illustration on the left in 12th is one (or some) of the protrusions Ea of the plurality of caulking sections E at the junction between the first yoke section 11 and the second yoke section 21st omitted (not formed), consequently the connecting force caused by the caulking sections E at the junction between the first yoke section 11 and the second yoke section 21st is provided, is weaker in a positive way.

Also in the stator core SC the conductive wire 2nd around the main pole teeth B that consist of the integrated assembly of the plurality of second fixed tooth sections 22 and the plurality of first engagement tooth portions 12th exist, which are superimposed, wound. In the course of the winding operation, a force arises due to the tension of the conductive wire 2nd on the second fixed tooth sections 22 exercised. Here is how in 6 and in 7 the number of stacks (the number of plates / layers) of the second stator parts is shown 20a that together make up the second stator section 20 represent, set greater than the number of stacks (the number of plates / layers) of the first stator parts 10a which together form the first stator section 10 represent to the location of the corresponding second fixed tooth sections 22 to stabilize against the application of such an external force. As a result of this arrangement, the number of stacks of the second fixed tooth portions is 22 larger than that of the second engaging tooth portions 23 , thereby making the conductive wire 2nd can be wound, the position of the main pole tooth portion being stabilized.

[Manufacturing Process of Stator Core]

If the stator core SC should be manufactured, as in 11 a pressing step is shown ( # 01 ), an integration step ( # 02 ), a separation step ( # 03 ), a coil part formation step ( # 04 ) and an engagement coupling step ( # 05 ) in the order mentioned.

The pressing step ( # 01 ) is a specific example of a “training step of a first stator part” for forming the first stator parts 10a and a "second stator part formation step" for forming the second stator parts 20a .

In the pressing step ( # 01 ), as in 3rd from a magnetic steel plate, a plurality of first stator parts 10a and a plurality of second stator parts 20a manufactured. Each of the first stator parts produced in this way 10a comprises a first yoke section 11 , the large number of first fixed tooth sections 13 and the plurality of first engagement tooth portions 12th , as in 4th is shown. And each of the second stator parts produced in this way 20a includes the second yoke section 21st , the plurality of second fix tooth sections 22 and the plurality of second engaging tooth portions 23 , as in 4th is shown.

Although this is not shown, the pressing step ( # 01 ), for example for the first stator part 10a , using a die consisting of a die and a stamp, the first yoke section 11 and the first fixed tooth sections 13 at the same time in one piece with each other manufactured, and also become the first engaging tooth portions 12th made separately. After that, using a movable pad or the like, the first engaging tooth portions 12th with the first yoke section 11 engaged.

Incidentally, in the pressing step ( # 01 ) to manufacture the second stator parts 20a with a similar operation to that used to manufacture the first stator parts 10a was used, the second engaging tooth sections 23 with the second yoke section 21st engaged.

In the integration step ( # 02 ), as in 4th is shown, the plurality of first stator parts 10a and the plurality of second stator parts 20a stacked and then exposed to pressure acting along the X axis. Thus, as in 5 is shown, an integrated assembly manufactured, the projections Ea and the recesses Eb the corresponding caulking sections E that are fixed together.

The first stator section is in this integrated assembly product 10 that from the multitude of first stator parts 10a is formed, and the second stator section 20 that from the multitude of second stator parts 20a is formed by means of the connection point between them. Integrations are also fixed between the first tooth sections 13 and the second engaging tooth portions 23 by means of the multitude of stem sections E or between the first engagement tooth sections 12th and the second fixed tooth sections 22 by means of the multitude of caulking sections E realized.

In the separation step ( # 03 ) become the first stator section 10 and the second stator section 20 separated from each other while the integrated state between the first fixed tooth sections 13 and the second engaging tooth portions 23 is maintained, and also the integrated state between the first engaging tooth portions 12th and the second fixed tooth sections 22 is maintained.

In the separation step described above ( # 03 ) reference is made to an exemplary integrated product arranged as in 5 is shown in which the first stator section 10 is arranged on the upper side and the second stator section 20 is arranged on the lower side. In the event that the integrated product contained in 5 is used, a first retainer (not shown) abuts against the corresponding top surfaces of the plurality (six) of first engagement tooth portions 12th and a second retainer (not shown) abuts against the corresponding bottom surfaces of the plurality (six) of second engagement tooth portions 23 arranged, and then a separating operation is carried out by moving the first holding device downward and moving the second holding device upward.

As a result of the separation operation described above, as in 6 is maintained, a state in which the first engaging tooth portions 12th from the first yoke section 11 are separated and the first engaging tooth portions 12th on the plurality of second fixed tooth sections 22 are stacked. At the same time, when the second engaging tooth sections 23 from the second yoke section 21st separated, the stacked state of the plurality of second engaging tooth portions 23 on the multitude of first fixed tooth sections 13 maintain.

In the separation step ( # 03 ) thanks to the arrangement described above (omission of one or several protrusion (s) Ea) from fixing the caulking sections E that for connecting at the junction between the first yoke section 11 and the second yoke section 21st serve the separation in an effective and advantageous manner at this junction.

In the coil part forming step ( # 04 ), as in 7 and 10 each of the plurality of main pole teeth is shown B by integration between the plurality of first engaging tooth portions 12th and the plurality of second fixed tooth portions 22 is formed from above and below by the insulators 1 squeezed, which are made of an insulating resin, and then becomes the conductive wire 2nd which is made of a good conductor, such as a copper alloy, around the outer peripheries of the insulators 1 wrapped using a winder. Incidentally, the training company of the coil section D thanks to the increased space available for the operation of a nozzle, the conductive wire can be carried out simply because the winding device is set up 2nd to wind in such a mode that the tubular nozzle (not shown) and the main pole teeth B be offset relative to each other while the conductive wire 2nd is supplied by means of the tubular nozzle.

In the separate state of the second stator section described above 20 from the first stator section 10 , is like in 6 is shown, the second stator section 20 only with the main pole teeth B provided, whereas the secondary pole teeth C. in the first stator section 10 are provided. Because of this, there will be wide and large spaces on opposite sides of everyone Tooth section of the main pole teeth B in the circumferential direction of the second stator section 20 ensured. As a result, the operation may result from forming the coil section D very easy to do.

As described above, the location of the main pole teeth B (more precisely, the second fixed tooth sections 22 ) to stabilize against the application of tensile stress associated with the winding of the conductive wire 2nd is like in 6 and in 7 the number of stacks (the number of plates / layers) of the second stator parts is shown 20a that together make up the second stator section 20 represent, set greater than the number of stacks (the number of plates / layers) of the first stator parts 10a which together form the first stator section 10 represent.

In the engagement coupling step ( # 05 ) become the first stator section 10 and the second stator section 20 , with the coil sections formed therein D moved relative to each other in the directions opposite to their movements in the relative movement in the separation step described above ( # 03 ), with the first stator section 10 and the second stator section 20 be integrated again, thereby the stator core SC is attained in 1 is shown.

More specifically, in the engagement coupling step ( # 05 ) become the first edges of engagement 12c the first engaging tooth portions 12th with the corresponding first engagement surfaces 11c the first yoke sections 11 engaged and also become the second engagement edges 23c of the second engaging tooth portions 23 with the corresponding second engagement surfaces 21c of the second yoke sections 21st engaged. Furthermore, in the engagement coupling step ( # 05 ) the first part of the stator 10a and the second stator part 20a that at the junction between the first stator section 10 and the second stator section 20 are arranged by means of the caulking section E connected with each other.

The stator core SC which is thus finished is then subjected, for example, to a resin molding treatment or the like, and becomes a component of the motor through a step of connecting a lead wire from the coil portions D made into a board.

[Function / Effect of the Embodiment]

If the first stator section 10 and the second stator section 20 were separated from each other in the circumferential direction of the second stator section 20 with the main pole teeth formed in it B creates large spaces without the first fixed tooth sections 13 or the second engaging tooth portions 23 at positions next to the integrated assembly from the first engagement tooth sections 12th and the second engaging tooth portions 23 available. As a result, the winding operation of the conductive wire 2nd for the main pole teeth B just run.

In particular, although the first engaging tooth sections 12th and the second engaging tooth portions 23 are set to be removable are the positions of the first fixed tooth portions 13 with respect to the first yoke section 11 fixed and wherein the second engaging tooth portions 23 in the stacked state with the first fixed tooth sections 13 by means of the caulking sections E are connected. In addition, the positions of the second fixed tooth sections 22 with respect to the second yoke section 21st fixed and are the first engaging tooth sections 12th in the stacked state with the second fixed tooth portions 22 by means of the caulking sections E connected.

As a result, the front ends of the respective tooth portions can be maintained at the appropriate fixed positions.

In addition, an adverse increase in the number of components can be suppressed because the first stator parts 10a and the second stator parts 20a can be formed, wherein the first fixed tooth portions and their engaging tooth portions are formed simultaneously in the pressing operation.

Thanks to the arrangement of determining the number of stacks of the second stator parts 20a to be larger than the number of stacks of the first stator parts 10a , when winding the conductive wire 2nd around the main pole teeth B winding operation with high accuracy with stabilization of the positions of the main pole teeth B be carried out.

The connecting force caused by the multitude of caulking sections E for connecting the corresponding components of the first stator parts 10a on the stacking surfaces, which are opposite to each other in the stacking direction, is determined equal to that connecting force caused by the plurality of caulking sections E for connecting the corresponding components of the second stator parts 20a is provided at the stacking surfaces. Compared to this connecting force is the connecting force of the caulking section E at the junction between the first yoke section 11 and the second yoke section 21st weaker. With this arrangement, the separation step ( # 03 ) can be easily executed.

[Other Embodiments]

In addition or as an alternative to the embodiment described above, the present invention are carried out as follows (in the discussion of other embodiments below, elements or components having the same or similar functions as / as those used in the previous embodiment will be given the same reference numerals / numbers as those in the previous embodiment designated).

(a) A stator core SC can be an annular yoke A , a variety of teeth (tooth sections) coming from the inner circumference of the yoke A protrude and toward the center of the yoke A protrude, as well as coil sections D have, which are formed in all of the plurality of teeth (tooth sections). In this stator core SC can the coil sections D be formed by the same steps as those used in the above embodiment.

In the further embodiment (a) described above, the stator core can SC , as in the previous embodiment, with an arrangement of the first stator section 10 and the second stator section 20 be set up that can be separated from one another by moving them relative to one another in the direction along the axis X.

Furthermore, in this further embodiment (a), as the manufacturing method, the pressing step ( # 01 ), the integration step ( # 02 ), the separation step ( # 03 ), the coil part formation step ( # 04 ) and the engagement coupling step ( # 05 ) are carried out in this order, and wherein in the coil part formation step ( # 04 ) the coil sections D for the first stator section 10 and the second stator section 20 can be formed in their respective separate states by the conductive wire 2nd is wound around the stacked assemblies of integrated teeth (tooth sections). Thereafter, with the engagement coupling in the engagement coupling step ( # 05 ) the stator core SC to get finished.

Incidentally, in the further embodiment (a) in the first stator section 10 and the second stator section 20 common stator parts are used. Thus, the shape obtained in the pressing step ( # 01 ) is used, simplified, and the step itself can also be simplified.

(b) The stator core SC can use teeth (tooth sections) that have a different function than the two sets of main pole teeth B and the secondary pole teeth C. described in the above embodiment. In the case of such a configuration, which has three groups of teeth (tooth sections), their two tooth groups can be in one of the first stator sections 10 and the second stator section 20 be provided, and wherein the teeth on which the coil sections D are formed, in which other of them can be provided, and wherein by separating them from one another in the separating step ( # 03 ) the winding operation of the conductive wire 2nd can be easily executed.

That is, in the embodiment (b), the invention is applied to a stator core SC applied, which has at least three groups of teeth (tooth sections), and even in such a configuration that has three or more groups of teeth, the conductive wire 2nd can be easily wrapped around the bobbin sections D to train.

Industrial applicability

The present invention is applicable to a stator core composed of a stacked assembly of stator parts having a plurality of tooth portions formed on an inner peripheral surface of an annular yoke and a manufacturing method of the stator core.

Reference list

2:

conductive wire

10:

first stator section

10a:

first stator part

11:

first yoke section

12:

first engaging tooth section

13:

first fixed tooth section

20:

second stator section

20a:

second stator part

21:

second yoke section

22:

second fixed tooth section

23:

second engaging tooth section

D:

Coil section

E:

Mortising section

# 01:

Pressing step (training step of a first stator part)

# 01:

Pressing step (training step of a second stator part)

# 02:

Integration step

# 03:

Separation step

# 04:

Coil lot formation step

# 05:

Engagement coupling step

Claims (5)

Stator core, with: a first stator section consisting of a stacked assembly of first stator parts, each of which has at least two groups of a plurality of first engaging tooth portions detachably supported on an inner periphery of an annular first yoke portion and a plurality of first fixed tooth portions on the Inner circumference of the first yoke section are integrally formed; a second stator section consisting of a stacked assembly of second stator parts, the second stator section being stacked on the first stator section, each second stator section comprising at least two groups of a plurality of second fixed tooth sections arranged at positions that overlap the first engagement tooth sections , and are integrally formed on an inner periphery of a second yoke portion that is the same shape as the first yoke portion and has a plurality of second engagement tooth portions arranged at positions that overlap the first fixed tooth portions and on the inner periphery of the second yoke portion are detachably supported; and a coil section consisting of a conductive wire which is wound around at least one integrated set of the first engagement tooth sections and the second fixed tooth sections and / or an integrated set of the first fixed tooth sections and the second engagement tooth sections if the first stator section and the second stator section are stacked on top of each other. Stator core after Claim 1 , wherein: the first engagement tooth portions and the first fixed tooth portions are alternately arranged in the circumferential direction along the inner periphery of the first yoke portion; and the second engagement tooth portions and the second fixed tooth portions are alternately arranged in the circumferential direction along the inner periphery of the second yoke portion. Stator core after Claim 1 or 2nd , wherein: the coil section is formed for only one of the integrated set of the first fixed tooth portions and the second engagement tooth portions stacked on top of each other or the integrated set of second fixed tooth portions and the first engagement tooth portions stacked on top of each other; if the conductive wire is wound around the first fixed tooth portions and the second engagement tooth portions, the first stator parts have a larger number of stacks than the second stator parts; and whereas if the conductive wire is wound around the second fixed tooth portions and the first engagement tooth portions, the second stator parts have a larger number of stacks than the first stator parts. Stator core according to one of the Claims 1 to 3rd , wherein a caulking section at a connection point between the first yoke section and the second yoke section is arranged to have a weaker connecting force than a connecting force provided by a caulking section of a stacking surface for connecting the first stator parts that are adjacent to one another in the first yoke section, or as a connecting force provided by a caulking portion of a stacking surface for connecting the second stator parts adjacent to each other in the second yoke portion. A method of manufacturing a stator core, the method comprising: forming a first stator part by forming a first stator part, the at least two groups of tooth portions from a plurality of first engagement tooth portions detachably supported on an inner periphery of an annular first yoke portion, and a plurality first fixed tooth portions integrally formed in the inner periphery of the first yoke portion; a second stator part forming step of forming a second stator part comprising at least two groups of tooth portions made of a plurality of second engaging tooth portions detachably supported on an inner peripheral surface of an annular second yoke portion and a plurality of second fixed tooth portions formed in the inner periphery the second yoke section are formed in one piece; an integrating step of stacking a plurality of the first stator parts and a plurality of the second stator parts to integrate the first engaging tooth portions and the second fixed tooth portions in the stacking direction and also integrating the first fixed tooth portions and the second engaging tooth portions in the stacking direction; a separating step of effecting separation, wherein the second engaging tooth portions are integrated with the first fixed tooth portions in a stacked state, and also wherein the first engaging tooth portions are integrated with the second fixed tooth portions in a stacked state, thereby to provide a first stator portion which the includes first fixed tooth portions stacked with the second engaging tooth portions, and obtaining a second stator section including the second fixed tooth portions stacked with the first engaging tooth portions, a coil part formation step of winding a conductive coil around at least the first fixed tooth portions and the second Engaging tooth portions that are integrated with each other in the stacked state after the separation step and / or the second fixed tooth portions and the first engagement tooth portions that are integrated with each other in the stacked state after the separation step; and an engagement coupling step for overlapping the first stator portion and the second stator portion in the stacking direction so that this overlap causes the first engagement tooth portions to engage the first yoke portion and also causes the second engagement tooth portions to engage the second yoke portion.

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