The disclosure of Japanese Patent Application No. 2015-110681 filed on May 29, 2015 including the specification, drawings and abstract is incorporated herein by reference in its entirety.
1. Field of the Invention
The invention relates to a laminated core formed by steel sheets that are laminated together, which is used in a rotor of a rotary electric machine such as a motor or a generator.
2. Description of Related Art
Japanese Patent Application Publication No. 2010-141989 (JP 2010-141989 A) is related art. A plurality of magnet insertion holes are formed by punching at equally-spaced intervals in the circumferential direction in steel sheets described in JP 2010-141989 A. These steel sheets are laminated together in an extending direction of a rotational axis to form a laminated core. Magnets are then loaded into the magnet insertion holes of this laminated core, such that a rotor is formed.
This laminated core may be formed by stacking together a plurality of blocks, each of which is formed by a plurality of steel sheets laminated together by dowel crimping (hereinafter, these blocks will be referred to as “laminated blocks”). In this case, when surface aligning a surface of one laminated block with a surface of another laminated block having the same shape as the first laminated block, a dowel protruding from the surface of the one laminated block may end up hitting the dowel protruding from the surface of the other laminated block. Also, even if the dowels do not hit each other, there will be a gap between the laminated blocks due to the dowels. If there is a gap due to the dowels, the thickness of the laminated core in the rotational axis direction will tend to be uneven in the circumferential direction, which may diminish the rotational balance of the laminated core.
The invention thus provides a laminated core for a rotary electric machine with improved rotational balance.
A first aspect of the invention relates to a laminated core for a rotary electric machine, which includes a disc-shaped first laminated block, a disc-shaped second laminated block, and an end steel sheet. The disc-shaped first laminated block is formed by a plurality of main steel sheets that are laminated together, each of the main steel sheets having a protruding dowel crimping portion that is arranged in a position off from a reference line that extends along a diameter of the first laminated block. The disc-shaped second laminated block is formed by a plurality of main steel sheets that are laminated together, each of the main steel sheets having a protruding dowel crimping portion that is arranged in a position off from a reference line that extends along a diameter of the second laminated block. The second laminated block is front/back reversed with respect to the first laminated block around the reference line of the first laminated block. The end steel sheet has a first dowel insertion hole formed in a position corresponding to the dowel crimping portion of the first laminated block, and a second dowel insertion hole formed in a position symmetrical to the first dowel insertion hole with respect to the reference line of the first laminated block. The first laminated block and the second laminated block are arranged such that the dowel crimping portion of the first laminated block protrudes in a direction toward the second laminated block, and the dowel crimping portion of the second laminated block protrudes in a direction toward the first laminated block, and the reference line of the first laminated block and the reference line of the second laminated block match up. The end steel sheet is arranged in a position between opposing surfaces of the first laminated block and the second laminated block.
In this first aspect, in the laminated core for a rotary electric machine, when the first laminated block and the second laminated block in a state front/back reversed from the first laminated block are surface aligned such that reference lines match up, the dowel protruding from the first dowel insertion hole in the first laminated block is inserted into the second dowel insertion hole in the second laminated block. Also, the dowel protruding from the first dowel insertion hole in the second laminated block is inserted into the second dowel insertion hole in the first laminated block. In this way, the surface of the first laminated block and the surface of the second laminated block are able to be brought into close contact, such that there is no gap due to the dowels between the laminated blocks. As a result, even if the laminated core in which the first laminated block and the second laminated block that is in a front/back reversed state are surface aligned is used, the rotational balance of the laminated core will not be diminished. Also, if there is a gap between the first laminated block and the second laminated block, electrical loss will tend to occur, which will cause a reduction in torque. However, according to the aspect described above, such a situation is extremely unlikely to occur.
In the first aspect described above, the end steel sheet may be provided in plurality, with at least one being provided abutting against a flat end surface of the laminated main steel sheets of the first laminated block, and at least one being provided abutting against a flat end surface of the laminated main steel sheets of the second laminated block. According to this aspect, at least one end steel sheet is arranged as a portion of each of the laminated blocks, so the end steel sheets will not easily separate when arranging the first laminated block and the second laminated block face to face. Also, in the first aspect described above, the end steel sheet being sandwiched between the first laminated block and the second laminated block.
Also, in the aspect described above, the dowel crimping portion, the first dowel insertion hole, and the second dowel insertion hole may be formed between a rotational axis that passes through the center of the first laminated block and the second laminated block, and a plurality of magnet insertion holes arranged in a circumferential direction of the first laminated block and the second laminated block, in the first laminated block and the second laminated block. With this kind of structure, when the magnet insertion holes are compactly arranged in the circumferential direction, deformation is less apt to occur in the steel sheets between the magnet insertion holes and the rotational axis of the laminated block than between the magnet insertion holes and the outer periphery of the laminated block when dowel crimping. Therefore, the steel sheets are able to be reliably dowel crimped together.
According to this aspect, rotational balance of the laminated core is able to be improved.
Features, advantages, and technical and industrial significance of exemplary embodiments of the invention will be described below with reference to the accompanying drawings, in which like numerals denote like elements, and wherein:
Hereinafter, example embodiments of a laminated core for a rotary electric machine according to the invention will be described in detail with reference to the accompanying drawings.
A rotor 1 shown in
The rotor 1 includes a laminated core 3 in which thin steel sheets 2 that are formed by insulation-coated steel sheets that have been punched out in a disc shape, are laminated together in an extending direction of a rotational axis L, and magnets 5 arranged in magnet insertion holes 4 formed punched out of the disc-shaped steel sheets 2. A shaft insertion hole 8 for inserting a shaft 7 is formed in the center of each steel sheet 2. A key portion 2a that is used as a shaft connecting portion is formed on a peripheral edge of the shaft insertion hole 8, and a key groove 7a into which the key portion 2a is inserted is provided in the shaft 7. The key portion 2a is formed protruding toward the rotational axis L. Two of these key portions 2a are arranged at 180° phases in a circumferential direction. A key groove may also be employed as a shaft connecting portion formed in the steel sheet 2.
Also, S-poles and N-poles are arranged alternately in the circumferential direction on the rotor 1, with four magnets 5a to 5d arranged distributed among two magnet insertion holes 4 at each pole. The magnet insertion holes 4 provided for each pole are inclined from the outside toward the inside in the radial direction, and arranged in a V-shape such that an apex M is positioned on the inside. Also, at each pole, first and second magnets 5a and 5b are arranged in one magnet insertion hole 4A, and third and fourth magnets 5c and 5d are arranged in the other magnet insertion hole 4B.
The laminated core 3 is formed by a plurality of (e.g., 10 to 20) laminated blocks B (see
Hereinafter, a case will be described in which the surfaces of the same type of blocks B are surface aligned such that reference lines P (see
As shown in
The first laminated block B1 will now be described.
The first laminated block B1 includes a block main body portion 20 (see
As shown in
The dowel crimping portions 21 each have a long narrow rectangular shape in the radial direction, and are formed between the magnet insertion holes 4 and the rotational axis L that passes through the center. The magnet insertion holes 4 are compactly arranged in the circumferential direction, so deformation is less apt to occur in the main steel sheets 2A between the magnet insertion holes 4 and the rotational axis L of the block main body portion 20 than between the magnet insertion holes 4 and the outer periphery of the block main body portion 20 when dowel crimping. Therefore, the main steel sheets 2A are able to be reliably dowel crimped together.
As shown in
When forming the first laminated block B1, dowels 21b that protrude from the flat end surface 20a of the block main body portion 20 are inserted into the first dowel insertion holes 22 of the end steel sheet 2B. Also, the top portions of the dowels 21b protrude from the surface S1 of the first laminated block B1. The protrusion amount of the dowels 21b is made large to increase the dowel crimping strength. As a result, the dowels 21b pass through the first dowel insertion holes 22 and protrude from the surface S1 of the first laminated block B1.
The reference line P described above extends through the pair of two key portions 2a used as shaft connecting portions. Moreover, as shown in
As shown in
As shown in
In this way, the surface S1 of the first laminated block B1 and the surface S2 of the second laminated block B2 are able to be brought into close contact with one another, such that there is no gap due to the dowels 21b between the first laminated block B1 and the second laminated block B2. As a result, even if the laminated core 3 in which the first laminated block B1 and the second laminated block B2 that is in a front/back reversed state are surface aligned is used, the rotational balance of the laminated core 3 will not be diminished. Also, if there is a gap between the first laminated block B1 and the second laminated block B2, electrical loss will tend to occur, which will cause a reduction in torque. However, with the laminated core 3 according to this example embodiment, such a situation is extremely unlikely to occur.
A disc-shaped first laminated block C1 and a disc-shaped second laminated block C2 are both made from main steel sheets 2A having dowel crimping portions, as shown in
As shown in
When forming a laminated core 33, the dowels 21b that protrude from the flat end surface 30a of the first laminated block C1 are inserted into the first dowel insertion holes 22 of the end steel sheet 40. The dowels 21b that protrude from the flat end surface 30a of the second laminated block C2 are inserted into the second dowel insertion holes 23 of the end steel sheet 40.
The invention is not limited to the example embodiments described above. Various modifications such as those described below are also possible.
For example, the shape of the dowel crimping portions 21 may also be rectangular, square, or circular. The position of the dowel crimping portions 21 may also be between the outer periphery of the laminated block B1, B2, C1, and C2 and the magnet insertion holes 4.
The key portions 2a do not have to be provided on the laminated block B1, B2, C1, and C2 and the end steel sheet 40.
Number | Date | Country | Kind |
---|---|---|---|
2015-110681 | May 2015 | JP | national |