JP3626031B2 - Stator core, split core block and manufacturing method thereof - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a technique for manufacturing a stator core or a split core block.
[0002]
[Prior art]
Conventionally, as a method of manufacturing a stator core composed of a split core block, a split core block 1 'is prepared by fixing several electromagnetic steel plates punched out from a magnetic steel strip with a press by in-mold lamination or laser welding. A method of forming a stator core by arranging a plurality of divided core blocks 1 ′ in a cylindrical shape and welding and fixing the mating portions 6 ′ as shown in FIG. 10 is well known. Further, as a method other than welding and fixing, the split core block can be fixed and the stator core can be formed by press-fitting or shrink-fitting the cylinder to the outer periphery of the split core block arranged in a cylindrical shape. However, in the method of fixing the divided core block by welding, the laminated electrical steel sheets are electrically connected to each other. There is a disadvantage that the characteristics are inferior. In addition, the method of press-fitting or shrink-fitting a cylinder around the outer periphery of the core necessitates the production of a new cylindrical part, which increases the cost.
[0003]
As one means of a welding-less structure, it has been proposed that the respective divided core blocks are stacked while being relatively shifted in the circumferential direction. It is also known that laminated steel cores are formed by fixing and joining electromagnetic steel sheets at caulking parts (see, for example, JP-A-10-136618 and JP-A-10-80078), and this caulking part is used. Thus, it has been studied to fix the upper and lower divided core blocks. However, in order to perform fixing between the divided core blocks by this method, the divided core blocks transported in a continuously stacked state from the punching die are separated for each core block or in a separated state. Although it is necessary to take out, it was difficult with this technique.
[0004]
[Problems to be solved by the invention]
SUMMARY OF THE INVENTION In view of the problems of the prior art, an object of the present invention is to provide a continuous stator core and divided core block that can take out the divided core block in a separated state without lowering the electrical characteristics and reducing the manufacturing cost. It is to provide a manufacturing method.
[0005]
[Means for Solving the Problems]
The present invention provides a stator core in which a plurality of stacked core blocks formed by laminating electromagnetic steel plates and fixed at a steel plate caulking portion are shifted in the circumferential direction, and the split core block includes a steel plate caulking portion and a block caulking portion. A stator core comprising a bottom electromagnetic steel plate, an intermediate electromagnetic steel plate having a steel plate caulking portion, and an upper magnetic steel plate having a steel plate caulking portion, a block caulking portion, and a block caulking separation portion.
[0006]
Moreover, this invention is a stator core which is a groove | channel on the opposite side of the steel plate caulking protrusion which the block caulking part provided in the said upper surface electromagnetic steel plate is a steel plate caulking part.
[0007]
In the present invention, the steel plate caulking portion provided on the lower electromagnetic steel plate is a steel plate caulking hole, and the block caulking separation portion provided on the upper magnetic steel plate is larger than the outer shape of the block caulking portion provided on the lower magnetic steel plate. It is a stator core which is a block caulking separation hole.
[0008]
Further, according to the present invention, the intermediate electromagnetic steel sheet comprises a second intermediate electromagnetic steel sheet in contact with the upper electromagnetic steel sheet and the other first intermediate electromagnetic steel sheet, and the upper electromagnetic steel sheet provided on the second intermediate electromagnetic steel sheet. The steel plate caulking portion is a steel plate caulking hole, and the block caulking separation portion provided in the upper electromagnetic steel plate is a stator core that is a block caulking separation hole larger than the outer shape of the block caulking portion provided in the lower electromagnetic steel plate.
[0009]
Further, the present invention provides a continuous core punching from an electromagnetic steel sheet strip and fixing with a steel plate caulking part to form a split core block, and in the continuous manufacturing method of the split core block, the steel plate caulking part and the block caulking are repeated. Punched into the bottom electromagnetic steel sheet having the part and laminated in the mold, then punched into the intermediate electromagnetic steel sheet having the steel sheet caulking part and laminated in the mold on the bottom electromagnetic steel sheet, and finally, the steel sheet caulking part and the block caulking This is a continuous manufacturing method of a split core block in which a split core block is formed by punching into a top electromagnetic steel plate having a part and a block caulking separation hole and laminating in a mold on a laminated electromagnetic steel plate made of a bottom electromagnetic steel plate and an intermediate electromagnetic steel plate .
[0010]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described.
An embodiment of a method for continuously manufacturing a stator core and divided core blocks according to the present invention will be described with reference to FIGS. FIG. 1 is an explanatory perspective view of a stator core according to an embodiment. FIG. 2 is a perspective explanatory view of a split core block of the stator core of the embodiment. FIG. 3 is a cross-sectional explanatory view of each electromagnetic steel sheet used in the configuration example 1 of the split core block of the stator core of the example. FIG. 4 is a cross-sectional explanatory diagram of Configuration Example 1 of the split core block of the stator core according to the embodiment. FIG. 5 is a cross-sectional explanatory view of each electromagnetic steel sheet used in the configuration example 2 of the split core block of the stator core of the example. FIG. 6 is a cross-sectional explanatory diagram of a configuration example 2 of the split core block of the stator core according to the embodiment. FIG. 7 is an explanatory plan view of an electromagnetic steel sheet used for the split core block of the stator core of the example. FIG. 8 is a cross-sectional explanatory view of the stator core of the embodiment. FIG. 9 is an explanatory diagram of the continuous manufacturing method of the split core block according to the embodiment.
[0011]
The continuous manufacturing method of the stator core and the split core block of the present invention will be described with reference to examples. As shown in FIG. 1, the stator core of this embodiment is composed of a total of 24 divided core blocks 1, six in the circumferential direction and four in the thickness direction.
[0012]
A configuration example 1 of the divided core block will be described. As shown in FIGS. 2 to 4, the split core block 1 of this configuration example includes a bottom electromagnetic steel plate 2, three intermediate electromagnetic steel plates 3, and a top electromagnetic steel plate 4. Since the thickness of the divided core block 1 is determined by the sum of the thicknesses of the lower electromagnetic steel plate 2, the intermediate electromagnetic steel plate 3, and the upper electromagnetic steel plate 4, the number of intermediate electromagnetic steel plates 3 is adjusted by increasing or decreasing. The bottom electromagnetic steel plate 2 has a steel plate crimping hole 21 and a block crimping protrusion 22. The intermediate electromagnetic steel plate 3 has a steel plate caulking projection 31 and a steel plate caulking groove 32, and the steel plate caulking groove 32 is formed on the opposite side when deformed into the steel plate caulking projection 31. The top electromagnetic steel plate 4 has a steel plate caulking projection 41, a block caulking groove 42 and a block caulking separation hole 43, and the block caulking groove 42 is formed on the opposite side when deformed into the steel plate caulking projection 41. The steel plate caulking hole 21, the steel plate caulking projection 31, the steel plate caulking groove 32, and the steel plate caulking projection 41 are respectively steel plate caulking portions. Each of the block crimping protrusion 22 and the block crimping groove 42 is a block crimping portion. The block caulking separation hole 43 is a block caulking separation part. The lower electromagnetic steel plate 2 and the intermediate electromagnetic steel plate 3 are caulked and fixed by the steel plate caulking holes 21 and the steel plate caulking protrusions 31. The intermediate electromagnetic steel plates 3 are fixed by caulking with steel plate caulking protrusions 31 and steel plate caulking grooves 32. The intermediate electromagnetic steel plate 3 and the top electromagnetic steel plate 4 are caulked and fixed by the steel plate caulking groove 32 and the steel plate caulking protrusion 41. The block caulking projection 22 and the steel plate caulking projections 31 and 41 are deformed by forming convex portions or partially notching from the electromagnetic steel plate band using a mold or the like in the continuous manufacturing process of the split core block, and The opposite side of the protrusion is a recess or groove, which becomes a steel plate caulking groove 32 and a block caulking groove 42. The fixing with other divided core blocks and the block caulking separation hole 43 will be described later.
[0013]
A configuration example 2 of the divided core block will be described. As shown in FIGS. 5 and 6, the split core block 1B of this configuration example includes a bottom electromagnetic steel plate 2B, two first intermediate electromagnetic steel plates 3B, a second intermediate electromagnetic steel plate 3C, and an upper electromagnetic steel plate 4B. The second intermediate electrical steel plate 3C is in contact with the top electrical steel plate 4. Since the thickness of the divided core block 1 is determined by the sum of the thicknesses of the lower surface electromagnetic steel plate 2B, the first intermediate electromagnetic steel plate 3B, the second intermediate electromagnetic steel plate 3C, and the upper surface electromagnetic steel plate 4B, the number of the first intermediate electromagnetic steel plates 3B is increased or decreased. And adjust. The bottom electromagnetic steel plate 2B has a block caulking projection 22B and a steel plate caulking groove 23B, and the steel plate caulking groove 23B is formed on the opposite side when deformed into the block caulking projection 22B. The first intermediate electromagnetic steel plate 3B has a steel plate caulking projection 31B and a steel plate caulking hole 33B, and the steel plate caulking groove 32B is formed on the opposite side when deformed into the steel plate caulking projection 31B. Since the steel plate caulking projection 31B provided on the first intermediate electromagnetic steel plate 3B has the same shape as the block caulking projection 22B provided on the lower surface electromagnetic steel plate 2, the first intermediate electromagnetic steel plate 3B is the same as the lower surface electromagnetic steel plate 2B. The second intermediate electromagnetic steel plate 3C has a steel plate caulking protrusion 31C and a steel plate caulking hole 33C. The top electromagnetic steel plate 4B has a steel plate caulking projection 41B, a block caulking groove 42B, and a block caulking separation hole 43B. The block caulking groove 42B is formed on the opposite side when deformed into the steel plate caulking projection 41B. The steel plate crimping protrusions 31B, 31C, 41B, the steel plate crimping grooves 23B, 32B, and the steel plate crimping holes 33C are respectively steel plate crimping portions. Each of the block crimping protrusion 22B and the block crimping groove 42B is a block crimping portion. The block caulking separation hole 43B is a block caulking separation part. The lower surface electromagnetic steel plate 2B and the first intermediate electromagnetic steel plate 3B are fixed by caulking with the steel plate caulking groove 23B and the steel plate caulking protrusion 31B. The first intermediate electromagnetic steel plate 3B and the other first intermediate electromagnetic steel plate 3B and the second intermediate electromagnetic steel plate 3C are caulked and fixed by the steel plate caulking projections 31B and 31C and the steel plate caulking groove 32B. The second intermediate electromagnetic steel plate 3C and the top electromagnetic steel plate 4B are fixed by caulking with the steel plate caulking hole 33C and the steel plate caulking protrusion 41B. The block caulking protrusion 22B and the like are formed in the continuous manufacturing process of the divided core block, similarly to the first structural example.
[0014]
An example of various protrusions and hole formation positions provided on each electromagnetic steel sheet in Configuration Example 1 will be described with reference to FIG. The bottom electromagnetic steel sheet will be described. The positions of the steel plate crimping holes 21 and the block crimping protrusions 22 are relative to the angle θ of the center of the split core block 1 (since the stator core is composed of six split core blocks in the circumferential direction, θ = 60 degrees). , Θ / 8 and θ / 4. With respect to the intermediate electromagnetic steel plate 3, the positions of the steel plate crimping protrusions 31 and the steel plate crimping grooves 32 are provided at the positions of the steel plate crimping holes 21 of the lower surface electromagnetic steel plate 2. With respect to the upper surface electromagnetic steel sheet 4, the positions of the steel sheet caulking protrusion 41 and the block caulking groove 42 are provided at the position of the steel sheet caulking hole 21 of the lower surface electromagnetic steel sheet 2, and the position of the block caulking separation hole 43 is the position of the block caulking protrusion 22. Provided. The size and shape of the block caulking projection 22 and the steel plate caulking projections 31 and 41 are all the same, and the size and shape of the steel plate caulking groove 32 and the block caulking groove 42 are the same, and the block caulking separation hole 43 Is a hole larger than the outer shape of the block steel plate caulking projection 22. In FIG. 5, two protrusions, grooves, and holes are formed. However, the number of protrusions, grooves, and holes can be increased or decreased in consideration of the strength of the caulking fixing portion. The configuration example 2 is formed in the same manner.
[0015]
A plurality of stacked core blocks 1 in the stator core will be described with reference to FIG. The stator core is stacked in a plurality of stages by shifting the divided core block 1 in the circumferential direction. The amount of shift is half of the circumferential length of the divided core block 1, and is shifted by an angle of θ / 2 when shown using the angle θ used in FIG. The block caulking protrusion 22 and the block caulking groove 42 are used to fix the divided core blocks 1a and 1b in the lower or upper stage. The block caulking protrusion 22 provided on the lower electromagnetic steel sheet 2 is inserted into the block caulking groove 42a provided on the upper electromagnetic steel sheet 4a of the lower divided core block 1a and fixed by caulking. The block caulking groove 42 provided on the upper electromagnetic steel plate 4 is fixed by caulking and fixing the block caulking projection 22b provided on the lower electromagnetic steel plate 2b of the upper divided core block 1b. The amount of shifting is required up to a position where the block crimping protrusions 22 and 22b provided on the lower electromagnetic steel plates 2 and 2b and the block crimping grooves 42 and 42a provided on the upper electromagnetic steel plates 4 and 4a coincide.
[0016]
Next, an example of the continuous manufacturing method of the configuration example 1 of the divided core block will be described with reference to FIG. FIG. 9 is an example of a layout in the case of punching the lower electromagnetic steel plate 2, the intermediate electromagnetic steel plate 3 and the upper electromagnetic steel plate 4 from the electromagnetic steel plate strip 5 using one progressive die. In the first step, the block caulking separation holes 43 of the upper electromagnetic steel plate 4 are punched, in the second step, the steel plate caulking holes 21 of the lower electromagnetic steel plate 2 are punched, and in the third step, the block caulking projections 22 of the lower electromagnetic steel plate 2 are formed. . At this time, the punch for punching the holes 43 and 21 in the first step, the second step and the third step and the punch for forming the caulking projection 22 are provided outside the mold (see FIG. The holes 43 and 21 and the caulking projections 22 can be formed on any of the electromagnetic steel sheets 2 to 4 constituting the divided core block 1 by projecting or denting. . In the fourth step, the upper magnetic steel sheet 4 and the steel sheet caulking protrusions 41 and 31 of the intermediate electromagnetic steel sheet 4 are formed. In the fifth step, the electromagnetic steel plates 2 to 4 are punched. The punched electromagnetic steel sheets 3 and 4 are inserted into a laminated mold provided in the lower mold, and are laminated on the electromagnetic steel sheet 2 or 3 previously punched and inserted into the laminated mold. The protrusions 31 and 41 and the steel plate caulking holes 21 or the steel plate caulking grooves 32 are fixed by caulking. Similarly, the lower surface electromagnetic steel sheet 2 is laminated on the upper surface electromagnetic steel sheet 4 which is first punched and laminated in the laminated mold. At this time, the block caulking protrusion 22 is inserted into the block caulking separation hole 43, but is not fixed to the block caulking separation hole 43 having a size larger than that of the block caulking protrusion 22. The divided core block is continuously manufactured by repeating the above.
[0017]
Hereinafter, each electromagnetic steel sheet in the continuous manufacturing method of the structural example 1 of a division | segmentation core block is demonstrated.
(1) In the first step, the punched portion is not formed in the portion to be the lower surface electromagnetic steel plate 2 of the electromagnetic steel strip 5 and the steel plate caulking hole 21 is formed in the second step, and in the third step. Block caulking protrusions 22 are formed and punched into the shape of the bottom electromagnetic steel sheet 2 in the fifth step. In addition, since the steel plate crimping hole 21 has already been formed in the second step, a new projection is not formed at the location where the steel plate crimping projection is formed in the fourth step. The punched bottom electromagnetic steel sheet 2 is laminated in the mold on the top punched and laminated top magnetic steel sheet 4a, but is not fixed by the steel plate crimping hole 21 and the block crimping separation hole 43a. It is not fixed to the divided core block 1a laminated before.
(2) In the first to third steps, the portion to be the intermediate electromagnetic steel plate 3 of the electromagnetic steel strip 5 is not punched to form anything, and the steel plate caulking protrusion 31 is formed in the fourth step, and the fifth step. To punch out the shape of the intermediate electrical steel sheet 3. The punched intermediate electromagnetic steel sheet 3 is laminated in the mold on the previously punched bottom electromagnetic steel sheet 2 or intermediate electromagnetic steel sheet 3, and the steel sheet crimping protrusion 31 and the steel sheet crimping hole 21 provided in the bottom electromagnetic steel sheet 2 or the intermediate electromagnetic steel plate. The steel plate 3 is caulked and fixed with a steel plate caulking groove 32 provided on the steel plate 3.
(3) Block caulking separation holes 43 are formed in the first step on the portion of the electromagnetic steel strip 5 that will be the upper electromagnetic steel plate 4, the steel plate caulking protrusion 41 is formed in the fourth step, and the upper electromagnetic steel plate is formed in the fifth step. Punched into shape 4. In the second to third steps, the punch is dented and nothing is formed. The punched top electromagnetic steel sheet 4 is laminated in the mold on the previously punched intermediate electromagnetic steel sheet 3 and fixed by crimping with the steel plate crimping protrusions 41 and the steel plate crimping grooves 32.
(4) By the above (1) to (3), the divided core block 1 in which the bottom electromagnetic steel plate 2, the plurality of intermediate electromagnetic steel plates 3 and the top electromagnetic steel plate 4 are laminated and fixed by caulking is formed. The lower magnetic steel sheet 2b of the next divided core block 1b is also laminated on the upper magnetic steel sheet 4, but since it is not fixed by the block caulking separation hole 43 and the steel plate caulking hole 21b, it is laminated next. It is not fixed to the divided core block 1b. Therefore, each divided core block 1a, 1, 1b... Can be continuously manufactured in a separated state. Also, the configuration example 2 of the split core block can be continuously manufactured in the same manner as the configuration example 1.
[0018]
【The invention's effect】
According to the present invention, it is possible to manufacture the lower Gaité production costs, the stator core or split core blocks.
[Brief description of the drawings]
FIG. 1 is a perspective explanatory view of a stator core of an embodiment.
FIG. 2 is a perspective explanatory view of a split core block of the stator core of the embodiment.
FIG. 3 is an explanatory cross-sectional view of each electromagnetic steel sheet used in Configuration Example 1 of the split core block of the stator core of the example.
FIG. 4 is a cross-sectional explanatory diagram of a configuration example 1 of a split core block of a stator core according to an embodiment.
FIG. 5 is a cross-sectional explanatory view of each electromagnetic steel sheet used in Structural Example 2 of the split core block of the stator core of the example.
FIG. 6 is a cross-sectional explanatory diagram of a configuration example 2 of the split core block of the stator core according to the embodiment.
FIG. 7 is an explanatory plan view of a magnetic steel sheet used for a split core block of a stator core according to an embodiment.
FIG. 8 is an explanatory cross-sectional view of a stator core according to an embodiment.
FIG. 9 is an explanatory diagram of a continuous manufacturing method of divided core blocks according to an embodiment.
FIG. 10 is a partial explanatory view of a stator core having a welded structure according to the prior art.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1, 1B Core block 2, 2B Bottom electromagnetic steel plate 21 Steel plate crimping hole 22, 22B Block crimping protrusion 23B Steel plate crimping groove 3 Intermediate electromagnetic steel plate 3B 1st intermediate electromagnetic steel plate 3C 2nd intermediate electromagnetic steel plate 31, 31B, 31C Steel plate crimping protrusion 32 , 32B Steel plate caulking groove 33C Steel plate caulking hole 4, 4B Upper surface electromagnetic steel plate 41, 41B Steel plate caulking projection 42, 42B Block caulking groove 43, 43B Block caulking separation hole 5 Electrical steel plate band

Claims (5)

In a stator core in which magnetic steel plates are stacked and divided core blocks formed by fixing at a steel plate caulking portion are shifted in the circumferential direction and stacked in multiple stages,
The divided core block includes a lower surface electromagnetic steel sheet having a steel crimped portion and the block caulking portion, and an intermediate electrical steel sheet having a steel swaged portion, steel caulking portion, and the upper surface electromagnetic steel sheet having a block crimped portion and the block caulking separation unit, the a stator core, wherein Rukoto steel crimped portion and the block crimped portion and the block caulking separation unit are located in different positions. The stator core according to claim 1, wherein
The stator core according to claim 1, wherein the block caulking portion provided on the upper magnetic steel sheet is a groove on the opposite side of the steel plate caulking protrusion which is the steel plate caulking portion. The stator core according to claim 1 or 2,
The steel plate caulking portion provided on the lower surface electromagnetic steel sheet is a steel plate caulking hole, and the block caulking separation portion provided on the upper surface electromagnetic steel plate is a block caulking separation hole larger than the outer shape of the block caulking portion provided on the lower surface electromagnetic steel plate. A stator core characterized by that. The stator core according to claim 1 or 2,
The intermediate electromagnetic steel sheet is composed of a second intermediate electromagnetic steel sheet in contact with the upper surface electromagnetic steel sheet and the other first intermediate electromagnetic steel sheet, and a steel sheet caulking portion with the upper surface electromagnetic steel sheet provided on the second intermediate electromagnetic steel sheet is a steel plate caulking A stator core, wherein the block caulking separation portion provided in the upper electromagnetic steel plate is a block caulking separation hole larger than the outer shape of the block caulking portion provided in the lower electromagnetic steel plate. In a continuous manufacturing method of a split core block that repeats this by forming a split core block by laminating in a continuous punching die from an electromagnetic steel strip and fixing it at a steel plate caulking part,
Punched into the bottom electromagnetic steel plate having the steel plate caulking part and the block caulking part and laminated in the mold, then punched into the intermediate electromagnetic steel sheet having the steel plate caulking part and laminated in the mold on the bottom electromagnetic steel sheet, and finally, A split core block is formed by punching into a top electromagnetic steel plate having a steel plate caulking portion, a block caulking portion, and a block caulking separation hole, and laminating on the laminated electromagnetic steel plate composed of the lower surface electromagnetic steel plate and the intermediate electromagnetic steel plate, and forming the divided core block. A continuous manufacturing method of the split core block.

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