JP7254675B2 - Brushless motor and stator manufacturing method - Google Patents

Description

TECHNICAL FIELD The present invention relates to a brushless motor, and more particularly to a brushless motor having a stator composed of a plurality of split stators that are connected to each other.

A brushless motor includes a rotor and a stator arranged inside or outside the rotor. One of the stators provided in conventional brushless motors is a stator configured by a plurality of divided stators (sometimes referred to as "divided stator cores") that are annularly arranged and coupled to each other. Furthermore, one of the conventional segmented stators is a segmented stator composed of a plurality of laminated metal plates. In the following description, individual metal plates that constitute the split stator may be referred to as "stator plates" or "plates."

Each stator plate that constitutes the split stator has two arms that extend in opposite directions. A recess is provided. As a result, a series of connecting projections are formed by a plurality of overlapping connecting protrusions on one side of the split stator, which is a laminate of a plurality of stator plates, and a plurality of overlapping connecting protrusions are formed on the other side of the split stator. A series of connecting grooves are formed by the recesses.

Each divided stator is connected to another divided stator arranged on one side of the divided stator, and connected to another divided stator arranged on the other side of the divided stator to form one stator. Configure. More specifically, the connecting projections of each stator segment are fitted into the connecting grooves of another stator segment arranged on one side of the stator segment, and the connecting groove of each stator segment is fitted to the other stator segment. The connecting projections of the other split stator arranged on the side are fitted.

JP 2019-4642 A

The stator plate is made by stamping. Specifically, a stator plate is made by punching a metal plate, which is a base material, into a predetermined shape. However, the forces applied when stamping the metal plate can cause distortion in the stamped stator plate. In particular, distortion occurs in the vicinity of the connecting recess provided at the tip of the arm, and the width of the connecting recess may become narrower than the predetermined width. When the width of the connecting recesses of each stator plate becomes narrower, the width of the connecting grooves of the divided stators formed by the plurality of overlapping connecting recesses also becomes narrower than the predetermined width. In order to fit the connecting projection into the connecting groove narrower than the predetermined width, it is necessary to apply a stronger force than when fitting the connecting projection into the connecting groove of the predetermined width. In other words, it is necessary to strengthen the pressing force of the connecting protrusions into the connecting grooves.

However, if the pressing force of the connecting projections into the connecting grooves becomes too strong, the residual stress in the stator segments increases, and the magnetic properties of the stator, which is an aggregate of the stator segments, deteriorate. The deterioration of the magnetic properties of the stator that occurs in this manner is a factor that reduces the output torque of the brushless motor.

SUMMARY OF THE INVENTION An object of the present invention is to realize a brushless motor having a stator with good magnetic properties.

A brushless motor of the present invention includes a rotor and a stator provided inside or outside the rotor. The stator is configured by a plurality of segmented stators that are arranged in an annular shape and are connected to each other. Each of the divided stators is composed of a plurality of laminated stator plates. Each of the stator plates includes a leg extending radially of the stator, a first arm and a second arm extending from one end of the leg toward both circumferential sides of the stator, and the first arm. and a connecting recess provided at the end of the second arm. The connecting convex portion of the stator plate forming the first split stator is located on one side of the first split stator and forming the second stator split. It is fitted in the connecting recess. Further, in the connecting recess of the stator plate forming the first split stator, the stator plate forming the third split stator positioned on the other side of the first split stator is provided. The connecting protrusion is fitted. Further, there is a gap between the tip surface of the connecting protrusion and the bottom surface of the connecting recess in which the connecting protrusion is fitted. An outer low portion recessed radially inward of the stator is formed in a region of the outer surface of the second arm portion outside the connecting recess, and the inner surface of the second arm portion includes the connecting portion. An inner low portion recessed radially outward of the stator is formed in the inner region of the recess.

In one aspect of the present invention, the inner surface of the second arm portion of the stator plate that constitutes the first stator segment and the first arm portion of the stator plate that constitutes the third stator segment. There is a step between the arm and the inner surface.

A stator manufacturing method according to the present invention is a method for manufacturing a stator that constitutes a brushless motor. This stator manufacturing method includes leg portions extending in the radial direction of the stator, first and second arm portions extending from one end of the leg portion toward both sides in the circumferential direction of the stator, and the first arm portions. a connecting protrusion provided at the end of the second arm, a connecting recess provided at the end of the second arm, and a region outside the connecting recess among the outer surfaces of the second arm, the an outer low portion recessed radially inward of the stator; and an inner low portion formed in a region of the inner surface of the second arm portion inside the connecting recess and recessed radially outward of the stator. and forming a split stator by stacking a plurality of the stator plates so that the connection protrusions overlap each other and the connection recesses overlap each other. and a divided stator connecting step of connecting the plurality of divided stators to each other. The stator plate forming step includes a first punching step of punching a predetermined region of a metal plate to form the outer lower portion and the inner lower portion; and a second punching step of punching other predetermined regions to form the connecting protrusions and the connecting recesses.

According to the present invention, a brushless motor having a stator with good magnetic properties is realized.

1 is a perspective view of a brushless motor; FIG. 1 is a perspective view of a brushless motor with a housing removed; FIG. It is a top view of a stator. (a) is a perspective view of the stator plate viewed from the front side, and (b) is a perspective view of the stator plate viewed from the back side. 4 is a plan view of a stator plate; FIG. FIG. 4 is an explanatory diagram showing a connecting portion between split stators; It is process drawing of a stator manufacturing method. (a) is a schematic diagram showing a first punching process, and (b) is a schematic diagram showing a second punching process.

An example of a brushless motor to which the present invention is applied will be described in detail below with reference to the drawings. A brushless motor according to this embodiment is mounted on a vehicle as a drive source for an electric brake. However, the application of the brushless motor to which the present invention is applied is not limited to the driving source of the electric brake.

As shown in FIGS. 1 and 2, a brushless motor 1A according to this embodiment includes a base 10, a cylindrical housing 11 having one end fixed to the base 10, a stator 12 and a rotor housed in the housing 11. 13 and. The stator 12 is provided inside or outside the rotor 13 , but the stator 12 in this embodiment is provided outside the rotor 13 . In other words, the rotor 13 in this embodiment is provided inside the stator 12 . An air gap is provided between the stator 12 and the rotor 13, and the rotor 13 is rotatably supported. That is, the brushless motor 1A according to this embodiment is of the "inner rotor type".

As shown in FIG. 2, an output shaft 13a is provided at the center of the rotor 13. As shown in FIG. As shown in FIG. 1, one end of the output shaft 13a penetrates the base 10 and protrudes below the base 10. As shown in FIG. A gear 13b is provided at the end of an output shaft 13a protruding downward from the base 10. As shown in FIG. As shown in FIGS. 1 and 2, the base 10 is provided with a connector connection portion 14 into which a connector provided at the end of a cable (not shown) is inserted and removed.

As shown in FIG. 2, the stator 12 is composed of a plurality of segmented stators 20 that are annularly arranged and connected to each other. Each stator segment 20 is composed of a plurality of stator plates 30 stacked in the axial direction. That is, the stator segment 20 is a laminate of a plurality of stator plates 30 , and the stator 12 is an aggregate of the stator segments 20 . In the following description, the stator plate 30 may be abbreviated as "plate 30". Each stator segment 20 is composed of 30 plates 30 , and the stator 12 is composed of nine stator segments 20 .

As shown in FIG. 2, each of the nine split stators 20 is provided with a coil 21 made of an enamel-coated conductor wire. That is, the brushless motor 1A has nine coils 21. As shown in FIG. Three of the nine coils 21 are U-phase coils, the other three are V-phase coils, and the other three are W-phase coils. A synthetic resin insulator 22 is interposed between the split stator 20 and the coil 21 .

As shown in FIG. 3 , a plurality of permanent magnets 15 are provided on the outer peripheral surface of the rotor 13 . Four permanent magnets 15 are provided on the outer peripheral surface of the rotor 13 in this embodiment, and the permanent magnets 15 are arranged so that their polarities are alternately different along the circumferential direction of the rotor 13 . Therefore, when a current flows through the coils 21 provided in each split stator 20 and the direction of the current flowing in each coil 21 is sequentially switched, the magnetized coils 21 and the permanent magnets provided in the rotor 13 15 repel each other and attract each other. As a result, a rotational force is generated, and the rotor 13 rotatably supported and the output shaft 13a fixed to the rotor 13 rotate. 3, illustration of the insulator 22 shown in FIG. 2 is omitted.

As shown in FIGS. 4A and 4B, each plate 30 constituting the split stator 20 has a leg portion 31 and a first arm extending in opposite directions from one end of the leg portion 31 in the longitudinal direction. It includes a portion 32 and a second arm portion 33 , a connecting projection 34 provided at the end of the first arm 32 , and a connecting recess 35 provided at the end of the second arm 33 . As shown in FIG. 3 , the legs 31 of each plate 30 extend radially of the stator 12 . Also, the first arm portion 32 and the second arm portion 33 of each plate 30 extend from one end of the leg portion 31 toward both circumferential sides of the stator 12 .

Please refer to FIG. 4 again. In the following description, one longitudinal end of the leg 31 on which the first arm 32 and the second arm 33 are formed is defined as the "distal end", and the other longitudinal end is defined as the "base end". Further, the end of the first arm portion 32 provided with the connecting projection 34 is the “tip” of the first arm 32, and the end of the second arm 33 provided with the connecting recess 35 is the second end. It is defined as the “tip” of arm 33 . That is, each plate 30 includes a leg portion 31 extending in the radial direction of the stator 12 ( FIG. 3 ), a first arm portion 32 extending from the tip of the leg portion 31 toward one side in the radial direction of the stator 12 , and the leg portion 31 . A second arm portion 33 extending from the distal end toward the other radial direction of the stator 12 , a connecting protrusion 34 provided at the distal end portion of the first arm portion 32 , and a connecting portion provided at the distal end portion of the second arm portion 33 . and a recess 35 .

As shown in FIG. 5, among the outer surfaces of the second arm portions 33 of the individual plates 30, the region outside the connecting recess 35 has an outer side recessed radially inward of the stator 12 (FIG. 3). A lower portion 33a is formed. An inner lower portion 33 b recessed radially outward of the stator 12 is formed in the inner side surface of the second arm portion 33 of each plate 30 in the area inside the connecting recess 35 . As a result, the width of the tip portion of the second arm portion 33 where the connecting concave portion 35 is provided is narrower than the other portions. In other words, the distal end portion of the second arm portion 33 provided with the connecting concave portion 35 is thinner than the other portions. On the other hand, on the outer surface of the first arm portion 32 of each plate 30, an outer lower portion 32a recessed radially inward of the stator 12 is formed in a region in front of the connecting protrusion 34. As shown in FIG. In addition, the proximal end of the leg portion 31 of each plate 30 is expanded into a bifurcated shape.

As shown in FIGS. 4A and 5, one surface of each plate 30 has three fitting recesses 36 formed therein. On the other hand, as shown in FIG. 4(b), three fitting projections 37 are formed on the other surface of each plate 30. As shown in FIG. In the following description, one side of the plate 30 on which the fitting recesses 36 are formed may be referred to as the "front surface", and the other side of the plate 30 on which the fitting protrusions 37 are formed may be referred to as the "rear surface". The fitting concave portion 36 and the fitting convex portion 37 are formed simultaneously by press working. Specifically, the fitting concave portion 36 and the fitting convex portion 37 are formed by recessing a part of the plate 30 toward the back side of the plate 30 with a punch pressed against the surface of the plate 30. It is a thing. In other words, the fitting concave portion 36 and the fitting convex portion 37 are in a front-back relationship and form a pair. In this embodiment, the leg portion 31 of the plate 30 is formed with a pair of fitting recess 36 and a fitting projection 37, and the first arm portion 32 is formed with another pair of fitting recess 36 and fitting projection 37. Further, another pair of fitting recess 36 and fitting projection 37 are formed in the second arm portion 33 .

Each segmented stator 20 shown in FIGS. 2 and 3 is a laminate in which 30 plates 30 shown in FIGS. 4 and 5 are superimposed. Here, focusing on the two plates 30 directly overlapping each other in the stack, the fitting concave portion 36 (FIG. 4A) formed on the surface of the plate 30 on the lower side in the stacking direction has an upper side in the stacking direction. A fitting protrusion 37 (FIG. 4(b)) formed on the rear surface of the plate 30 is press-fitted. Such press-fitting of the fitting protrusions 37 into the fitting recesses 36 occurs between all the plates 30 directly overlapping each other in the stack. As a result, the 30 plates 30 forming each split stator 20 are fixed and integrated with each other. A through hole (not shown) is formed in place of the fitting concave portion 36 and the fitting convex portion 37 in the lowermost plate 30 in the stacking direction of each stator segment 20 . The fitting protrusion 37 (FIG. 4(b)) formed on the plate 30 (the second plate 30 from the bottom in the stacking direction) stacked on the bottom plate 30 in the stacking direction It is press-fitted into a through hole formed in the bottom plate 30 in the direction.

2 and 3, the first arms 32 and the second arms 33 of the 30 plates 30 constituting each split stator 20 overlap each other. Oriented and stacked. As a result, a series of connecting protrusions 34 are formed on one side of the stator segment 20, which is a stack of 30 plates 30, and a series of connecting protrusions 34 are formed on the other side of the stator segment 20. A series of connecting grooves are formed by the 30 connecting recesses 35 .

As shown in FIG. 3 , a plurality of divided stators 20 having the structure described above are arranged annularly around the rotor 13 and connected to each other to form one stator 12 . Specifically, a given stator segment 20 is connected to another stator segment 20 arranged on one side of the stator segment 20, and is arranged on the other side of the stator segment 20. It is also connected to the stator 20 . For example, when the stator 12 shown in FIG. 3 is likened to the dial of a watch, the connecting protrusion of the first stator segment 20A at the 12 o'clock position is arranged to the left of the first stator segment 20A. The third stator segment 20C is fitted in the connecting groove of the second stator segment 20B, and the connecting protrusion of the third stator segment 20C, which is arranged to the right of the first stator segment 20A, is fitted in the connecting groove of the first stator segment 20A. is mated.

Here, the connecting protrusions and connecting grooves in each of the stator segments 20 are formed by overlapping the connecting protrusions 34 and the connecting recesses 35 of the plurality of plates 30 that constitute the stator segment 20 . Therefore, the fact that the connecting protrusions of the first stator segment 20A are fitted into the connecting grooves of the second stator segment 20B means that the connecting protrusions 34 of the individual plates 30 constituting the first stator segment 20A is synonymous with fitting into the connecting recesses 35 of the individual plates 30 that constitute the second split stator 20B. The fact that the connecting protrusions of the third stator segment 20C are fitted in the connecting grooves of the first stator segment 20A is due to the fact that the connecting recesses 35 of the individual plates 30 that constitute the first stator segment 20A. It is synonymous with fitting of the connecting projections 34 of the individual plates 30 constituting the third stator segment 20C.

FIG. 6 shows an enlarged view of the connecting portion between the first stator segment 20A and the second stator segment 20B and the connecting portion between the first stator segment 20A and the third stator segment 20C. As shown in FIG. 6, the tip surface 34a of the connecting projection 34 of the plate 30 constituting the first stator segment 20A and the connecting recess 35 of the plate 30 constituting the second stator segment 20B are separated from each other. A gap 38 exists between the bottom surface 35a and the bottom surface 35a. Similarly, between the tip surface 34a of the connecting projection 34 of the plate 30 that constitutes the third stator segment 20C and the bottom surface 35a of the connecting recess 35 of the plate 30 that constitutes the first stator segment 20A. There is a gap 38 in .

In other words, a gap 38 exists between the tip surface of the connecting projection of the first stator segment 20A and the bottom surface of the connecting groove of the second stator segment 20B. A gap 38 exists between the tip surface of the connecting projection of the third stator segment 20C and the bottom surface of the connecting groove of the first stator segment 20A. The presence of the gap 38 is such that when the connecting projection of the first stator segment 20A is fitted (press-fitted) into the connecting groove of the second stator segment 20B, the tip surface of the connecting projection comes into contact with the bottom surface of the connecting groove. This means that a strong press-in force is not applied to the Similarly, when the connecting projection of the third stator segment 20C is fitted (press-fitted) into the connecting groove of the first stator segment 20A, a strong press force is applied such that the tip surface of the connecting projection contacts the bottom surface of the connecting groove. It means that it has not been added. In other words, the connecting protrusions of the first stator segment 20A can be connected without applying a press force to the extent that the tip surfaces of the connecting protrusions of the first stator segment 20A contact the bottom surfaces of the connecting grooves of the second stator segment 20B. are fitted (press-fitted) into the connecting grooves of the second split stator 20B. Similarly, even if the tip surface of the connecting projection of the third stator segment 20C does not press against the bottom surface of the connecting groove of the first stator segment 20A, the connecting projection of the third stator segment 20C will not move. It is fitted (press-fitted) into the connecting groove of the first split stator 20A.

Here, taking as an example the first stator segment 20A at the 12 o'clock position in FIG. explained. However, the above structure (the structure in which a gap 38 exists between the tip surface 34a of the connecting protrusion 34 (connecting protrusion) and the bottom surface 35a of the connecting recess 35 (connecting groove)) is not suitable for all of the structures shown in FIG. This structure is common to the connecting portions of the split stators 20 . Therefore, in any of the stator segments 20 shown in FIG. The aggregate stator 12 has good magnetic properties.

Refer to FIG. 5 again. The second arm portion 33 of the plate 30 is formed with an outer lower portion 33a and an inner lower portion 33b, and the first arm portion 32 is formed with an outer lower portion 32a. On the other hand, the first arm portion 32 of the plate 30 does not have a recess or the like corresponding to the inner low portion 33b of the second arm portion 33 . As a result, there is no substantial step between the outer surface of the first arm portion 32 and the outer surface of the second arm portion 33 that are connected, but the inner surface of the first arm portion 32 and the second arm portion A step exists between the inner surface of 33 .

For example, the outer lower portion 33a formed in the second arm portion 33 of the plate 30 constituting the first stator segment 20A shown in FIG. 6 and the plate constituting the third stator segment 20C There is no substantial step between the first arm portion 32 of 30 and the lower outer portion 32a. On the other hand, the inner lower portion 33b formed in the second arm portion 33 of the plate 30 forming the first split stator 20A and the first arm portion 32 of the plate 30 forming the third split stator 20C There is a step 39 between the inner surface of the . The presence or absence of such a step depends on the second arm portion 33 of the plate 30 constituting the second stator segment 20B and the second arm portion 33 of the plate 30 constituting the first stator segment 20A shown in FIG. The same is true between one arm portion 32 and between other adjacent split stator segments 20 .

Next, an example of a method for manufacturing the stator 12 shown in FIGS. 2 and 3 will be described. The stator manufacturing method described here includes at least the steps shown in FIG. That is, the stator manufacturing method includes at least a stator plate forming step (Step 1), a split stator forming step (Step 2), an insulator mounting step (Step 3), a coil forming step (Step 4), and a split stator connecting step (Step 5).

In the stator plate forming step (Step 1) shown in FIG. 7, a plurality of plates 30 shown in FIGS. 4 and 5 are formed. In the divided stator forming step (Step 2), a predetermined number of plates 30 formed in the stator plate forming step (Step 1) are stacked to form a plurality of divided stators 20 shown in FIGS.

In the insulator mounting step (Step 3) shown in FIG. 7, the insulators 22 shown in FIG. 2 are mounted on each split stator 20 formed in the split stator forming step (Step 2). In the coil forming step (Step 4), a conductive wire is wound around the insulator 22 attached to the split stator 20 in the insulator attaching step (Step 3) to form the coil 21 shown in FIGS. In the stator segment connecting step (Step 5), the plurality of stator segment segments 20 provided with the coils 21 in the coil forming step (Step 4) are connected to each other and integrated.

The stator 12 shown in FIGS. 2 and 3 is manufactured through at least the above steps. However, steps other than those shown in FIG. 7 may be added as required. For example, a step of resin-molding the stator segments 20 including the coils 21 may be added after the coil forming step (Step 4). In some cases, a step of collectively resin-molding the plurality of integrated stator segments 20 may be added after the step of connecting the segmented stators (Step 5).

In the stator plate forming step (Step 1) shown in FIG. 7, a metal plate as a base material is prepared, and the prepared metal plate is punched into the shape of the plate 30 shown in FIGS. It is already known that the plate 30 stamped from a metal plate includes a leg portion 31, a first arm portion 32, a second arm portion 33, a connecting projection 34, a connecting recess 35, outer lower portions 32a, 33a and an inner lower portion 33b. As mentioned above. That is, the stator plate forming step (Step 1) is a step of forming the plate 30 including the above portions by punching.

However, in the stator plate forming step (Step 1), different regions of the metal plate, which is the base material, are sequentially punched out to form the plate 30 including the above portions. In other words, the plate 30 including the above parts is not punched out at once.

Specifically, the stator plate forming step (Step 1) shown in FIG. 7 includes a first punching step (Step 1) of punching predetermined regions of the metal plate corresponding to the outer low portion 33a and the inner low portion 33b shown in FIG. -1) is included. The stator plate forming step (Step 1) also includes a second punching step (Step 1-2) of punching other predetermined regions of the metal plate corresponding to the connecting protrusions 34 and connecting recesses 35 shown in FIG. Further, in the stator plate forming step (Step 1), other predetermined regions of the metal plate corresponding to each portion of the plate 30 other than the outer lower portions 32a and 33a, the inner lower portion 33b, the connecting protrusions 34 and the connecting recesses 35 are punched out. A third punching step (Step 1-3) is included.

The first punching step (Step 1-1), the second punching step (Step 1-2) and the third punching step (Step 1-3) are performed in this order. That is, as shown in FIG. 8(a), predetermined regions A and B of the metal plate 50 corresponding to the outer low portion 33a and the inner low portion 33b (FIG. 5) are simultaneously punched out, and then, as shown in FIG. 8(b). As shown, other predetermined regions C, D of the metal plate 50 corresponding to the connecting protrusions 34 and connecting recesses 35 (FIG. 5) are punched out simultaneously. By punching out the metal plate 50 in this order, the leading end of the second arm portion 33 shown in FIG.

8(b) is punched out and then the regions A and B shown in FIG. 8(a) are punched out. If the regions corresponding to the outer low portion 33a and the inner low portion 33b are punched, the tip of the second arm portion 33 and its vicinity may be distorted, and the width of the connecting recess 35 may become narrower than the predetermined width. This is because when the regions A and B shown in FIG. 8A are punched after the region D shown in FIG. D has already been punched out. That is, when the regions A and B are punched, a hole (a hole that will eventually become the connecting recess 35) is formed between the regions A and B. Therefore, the force applied when punching the regions A and B tends to cause distortion in the vicinity of the regions A and B (particularly around the hole that eventually becomes the connecting recess 35).

In the divided stator forming step (Step 2) shown in FIG. 7, the plates 30 shown in FIGS. 4 and 5 are stacked so that the connecting protrusions 34 overlap each other and the connecting recesses 35 overlap each other. As a result, the divided stator 20, which is a stack of plates 30, is formed. At the same time, on one side of the formed stator segment 20, a series of connecting projections consisting of a plurality of overlapping connecting projections 34 are formed, and on the other side of the segmented stator 20, a plurality of overlapping connecting recesses 35 are formed. A series of connecting grooves are formed. At this time, since each of the connecting protrusions 34 and the connecting recesses 35 has a predetermined width, the widths of the connecting protrusions and the connecting grooves also become predetermined widths.

In the divided stator connecting step (Step 5) shown in FIG. 7, the plurality of divided stators 20 that have undergone the insulator mounting step (Step 3) and the coil forming step (Step 4) are connected to each other. Specifically, the connecting protrusion of each stator segment 20 is fitted (press-fitted) into the connecting groove of another stator segment 20 adjacent to the stator segment 20 in question. At this time, since the widths of the connecting protrusions and the connecting grooves of the respective split stators 20 are predetermined widths, the connecting protrusions can be smoothly fitted (press-fitted) into the connecting grooves. In other words, the connecting protrusion can be fitted (press-fitted) into the connecting groove without applying such a strong force that the tip surface of the connecting protrusion contacts the bottom surface of the connecting groove. As a result, a gap 38 (FIG. 6) is formed between the tip end surface of the connecting projection of each split stator 20 and the bottom surface of the fitting groove into which it is fitted (press-fitted).

The present invention is not limited to the above embodiments, and can be modified in various ways without departing from the scope of the invention. For example, the number of stator plates 30 forming each stator segment 20 can be changed as appropriate. Also, the number of divided stators 20 that constitute the stator 12 can be changed as appropriate. Furthermore, the number of permanent magnets 15 provided on the outer peripheral surface of the rotor 13 can also be changed as appropriate.

1A Brushless motor 10 Base 11 Housing 12 Stator 13 Rotor 13a Output shaft 13b Gear 14 Connector connecting portion 15 Permanent magnet 20 Split stator 20A First split stator 20B Second split stator 20C Third split stator 21 Coil 22 Insulator 30 Stator plate (plate)
31 Leg portion 32 First arm portion 32a Outer lower portion 33 Second arm portion 33a Outer lower portion 33b Inner lower portion 34 Connecting convex portion 34a Tip surface 35 Connecting concave portion 35a Bottom surface 36 Fitting concave portion 37 Fitting convex portion 38 Gap 39 Step 50 metal plate

Claims (3)

A brushless motor comprising a rotor and a stator provided inside or outside the rotor,
The stator comprises a plurality of divided stators arranged in a ring and connected to each other,
Each of the divided stators is composed of a plurality of laminated stator plates,
Each of the stator plates includes a leg extending radially of the stator, a first arm and a second arm extending from one end of the leg toward both circumferential sides of the stator, and the first arm. and a connecting protrusion provided at the end of the second arm, and a connecting recess provided at the end of the second arm,
The connecting convex portion of the stator plate forming the first split stator corresponds to the connecting protrusion of the stator plate forming the second split stator located on one side of the first split stator. fitted in the recess,
The connecting recess of the stator plate forming the first split stator is provided with the connecting recess of the stator plate forming the third split stator located on the other side of the first split stator. The convex part is fitted,
A gap exists between the tip surface of the connecting protrusion and the bottom surface of the connecting recess in which the connecting protrusion is fitted,
An outer low portion recessed radially inward of the stator is formed in a region of the outer surface of the second arm portion outside the connecting recess,
An inner low portion recessed radially outward of the stator is formed in a region inside the connecting recess on the inner surface of the second arm,
brushless motor. The inner surface of the second arm of the stator plate that constitutes the first stator segment and the inner surface of the first arm of the stator plate that constitutes the third stator segment. there is a gap between
The brushless motor according to claim 1. A method for manufacturing a stator that constitutes a brushless motor, comprising:
legs extending in the radial direction of the stator; first and second arms extending from one end of the legs toward both sides in the circumferential direction of the stator; a connecting convex portion provided at the end of the second arm portion; a connecting concave portion provided at an end portion of the second arm portion; a stator plate including: an outer lower portion recessed toward the outside; and an inner lower portion formed in a region of the inner surface of the second arm portion inside the connecting recess and recessed radially outward of the stator. a stator plate forming step for forming a
a split stator forming step of forming split stators by stacking a plurality of the stator plates so that the connection protrusions overlap each other and the connection recesses overlap each other;
a divided stator connecting step of connecting the plurality of divided stators to each other;
In the stator plate forming step,
a first punching step of punching a predetermined region of a metal plate to form the outer lower portion and the inner lower portion;
a second punching step of punching another predetermined region of the metal plate to form the connecting protrusion and the connecting recess, which is performed after the first punching step;
Stator manufacturing method.

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