The present invention relates to a stator of a rotary machine such as a motor or an electric generator, and the rotary machine.
A technique related to a stator of a rotary machine has been proposed. For example, a stator for a rotating armature is disclosed in Japanese Unexamined Patent Application Publication No. H09-163690 A. This stator includes a stator core of an inner rotor type. The stator core is formed by combining a plurality of unit cores. The unit core has a yoke portion and a wire wound portion. The yoke portion forms a part of a ring-shaped yoke part of the stator core. Wire is wound around the wire wound portion. The unit core includes a fitting recess portion at one end of the yoke portion, and includes a fitting protrusion portion at the other end. The stator core is combined by fitting the fitting recess portion and the fitting protrusion portion of two adjacent unit cores.
A space factor can be increased by forming a stator core with a plurality of core segments. The plurality of core segments is arranged in a ring shape after coils are formed on the core segments. Consequently, the plurality of core segments forms the ring-shaped stator core. In this case, the plurality of core segments is preferably coupled. If they are coupled, for example, handling upon manufacture of a stator becomes smooth. However, for example, the following is required for the coupling structure of the plurality of core segments. In other words, a coupling structure where the magnetic characteristics of a rotary machine are not reduced is required.
An object of the present invention is to provide a stator and rotary machine having a core segment coupling structure that can suppress influence on magnetic characteristics.
An aspect of the present invention is a stator of a rotary machine including a rotor, including: a ring-shaped stator core formed by coupling a plurality of core segments formed by laminating electrical steel sheets, the core segments including a tooth and a yoke piece; a first insulator made of synthetic resin, the first insulator being mounted on the core segment on a first side in a lamination direction in which the electrical steel sheets are laminated, the first insulator including a first covering portion covering a first end surface of the core segment on the first side in the lamination direction; a second insulator made of synthetic resin, the second insulator being mounted on the core segment on a second side in the lamination direction, the second insulator including a second covering portion covering a second end surface of the core segment on the second side in the lamination direction; and a coil provided to the tooth of the core segment on which the first insulator and the second insulator are mounted, wherein in the core segment, a coupling hole in which the lamination direction is a depth direction is formed in a portion of the yoke piece on a third side in a circumferential direction corresponding to a rotation direction of the rotor, the first insulator includes a first coupling pin protruding toward the second side in the lamination direction, at a portion of the first covering portion on a fourth side in the circumferential direction, and the stator core is formed by coupling the plurality of core segments in a ring shape in a state where the first coupling pin included in the first insulator mounted on the core segment of the core segments adjacent in the circumferential direction that is to the third side in the circumferential direction is inserted in the coupling hole formed in the core segment of the core segments adjacent in the circumferential direction that is to the fourth side in the circumferential direction, and where a side surface on the fourth side in the circumferential direction of the yoke piece in the core segment being to the third side in the circumferential direction and a side surface on the third side in the circumferential direction of the yoke piece in the core segment being to the fourth side in the circumferential direction are in contact with each other.
According to this stator, the first coupling pin included in the first insulator is inserted into the coupling hole formed in the core segment, and accordingly the plurality of core segments can be coupled. While electrical steel sheets are punched into the shape of the core segment, the coupling hole can be formed at a timing when the punched electrical steel sheets are laminated. In other words, the coupling hole is formed by punching a hole that forms the coupling hole upon the punching of the electrical steel sheets, and laminating the electrical steel sheets that have been punched into the shape of the core segment, in which the previously mentioned hole has been formed. The first coupling pin can be formed when the first insulator made of synthetic resin is molded. The first coupling pin is made of synthetic resin, and accordingly the laminated electrical steel sheets can be prevented from being electrically connected with each other by the first coupling pin. In terms of the circumferential direction corresponding to the rotation direction of the rotor, the circumferential direction is a concept including the rotation direction and a counter-rotation direction.
In this stator, the coupling hole may be formed in a portion of the yoke piece on the third side in the circumferential direction and on an opposite side to a rotor side in a radial direction centered at a rotation axis of the rotor, and the first coupling pin may be provided to a portion of the first covering portion on the fourth side in the circumferential direction and on the opposite side to the rotor side in the radial direction. According to this configuration, the coupling hole and the first coupling pin are not arranged on the rotor side in the radial direction. A space between teeth that are adjacent in the circumferential direction can be made effective use for the housing of the coil.
The coupling hole may be a hole having a perfect circle shaped cross section perpendicular to the lamination direction, and the first coupling pin may be a cylindrical shaft corresponding to the perfect circle shape of the coupling hole. According to this configuration, one of adjacent core segments can be rotated with respect to the other with the first coupling pin as a rotation axis in a state where the first coupling pin is inserted in the coupling hole and the plurality of core segments is coupled. The shape of the plurality of coupled core segments can be freely altered. For example, the plurality of core segments can be arranged in a straight line. Upon winding for the formation of the coil, it is possible to arrange the plurality of core segments in a straight line and wind a conductive wire around their teeth. The winding of the conductive wire can be continuously performed on the plurality of teeth. The plurality of core segments arranged in a straight line can be rolled in a ring shape.
The second insulator may include a second coupling pin protruding toward the first side in the lamination direction, at a portion of the second covering portion on the fourth side in the circumferential direction, and the stator core may be formed by coupling the plurality of core segments in a ring shape in a state where the first coupling pin included in the first insulator and the second coupling pin included in the second insulator that are mounted on the core segment of the core segments adjacent in the circumferential direction that is to the third side in the circumferential direction are inserted in the coupling hole formed in the core segment of the core segments adjacent in the circumferential direction that is to the fourth side in the circumferential direction, and where the side surface on the fourth side in the circumferential direction of the yoke piece in the core segment being to the third side in the circumferential direction and the side surface on the third side in the circumferential direction of the yoke piece in the core segment being to the fourth side in the circumferential direction are in contact with each other. According to this configuration, the first coupling pin included in the first insulator and the second coupling pin included in the second insulator are inserted into the coupling hole formed in the core segment, and accordingly the plurality of core segments can be coupled. The second coupling pin can be formed when the second insulator made of synthetic resin is molded. The second coupling pin is made of synthetic resin, and accordingly the laminated electrical steel sheets can be prevented from being electrically connected with each other by the second coupling pin.
The coupling hole may be formed in a portion of the yoke piece on the third side in the circumferential direction and on an opposite side to a rotor side in a radial direction centered at a rotation axis of the rotor, the first coupling pin may be provided to a portion of the first covering portion on the fourth side in the circumferential direction and on the opposite side to the rotor side in the radial direction, and the second coupling pin may be provided to a portion of the second covering portion on the fourth side in the circumferential direction and on the opposite side to the rotor side in the radial direction. According to this configuration, the coupling hole, the first coupling pin, and the second coupling pin are not arranged on the rotor side in the radial direction. A space between teeth that are adjacent in the circumferential direction can be made effective use for the housing of the coil.
The coupling hole may be a hole having a perfect circle shaped cross section perpendicular to the lamination direction, the first coupling pin may be a cylindrical shaft corresponding to the perfect circle shape of the coupling hole, and the second coupling pin may be a cylindrical shaft corresponding to the perfect circle shape of the coupling hole. According to this configuration, one of adjacent core segments can be rotated with respect to the other with the first coupling pin and the second coupling pin as a rotation axis in a state where the first coupling pin and the second coupling pin are inserted in the coupling hole and the plurality of core segments is coupled. The shape of the plurality of coupled core segments can be freely altered. For example, the plurality of core segments can be arranged in a straight line. Upon winding for the formation of the coil, it is possible to arrange the plurality of core segments in a straight line and wind a conductive wire around their teeth. The winding of the conductive wire can be continuously performed on the plurality of teeth. The plurality of core segments arranged in a straight line can be rolled in a ring shape.
Another aspect of the present invention is a rotary machine including the stator of any of the above-mentioned stators, and a rotor. According to this rotary machine, a rotary machine that achieves the above-mentioned functions can be constructed.
According to the present invention, it is possible to obtain a stator and rotary machine having a core segment coupling structure that can suppress influence on magnetic characteristics.
An upper part of
Examples for carrying out the present invention will be described with reference to the drawings. The present invention is not limited to the configurations described below, and various configurations can be employed based on the same technical idea. For example, a part of the configurations shown below may be omitted or may be replaced by another configuration or the like. Another configuration may be included.
A motor 10 as a rotary machine is described with reference to
The rotor 20 includes a rotor core 21, a plurality of permanent magnets, and a shaft 23. In
The shaft 23 is secured to a through-hole formed at the center portion of the rotor core 21. Bearings are attached to the shaft 23 at both sides of the rotor core 21. The bearings are supported by supporting portions provided to the stator 30. The illustration of the bearings and the supporting portions is omitted in
The stator 30 includes a stator core 31, a plurality of coils 50, first insulators 61, and second insulators 71. The stator core 31 includes a yoke 32 and a plurality of teeth 33 as illustrated in
In the example, a direction corresponding to a rotation direction is referred to as the “circumferential direction.” The rotation direction is a direction in which the rotor 20 rotates. The circumferential direction includes the rotation direction and a counter-rotation direction. One side in the circumferential direction is referred to as the “third side.” The other side in the circumferential direction is referred to as the “fourth side.” A direction centered at the shaft 23 serving as the rotation axis is referred to as the “radial direction.” The radial direction agrees with a radiation direction centered at the shaft 23. In the motor 10 of the inner rotation type, the rotor 20 side is the inner side in the radial direction, and an opposite side to the rotor 20 side is the outer side in the radial direction (see
The core segment 40 includes the tooth 33 and a yoke piece 43 as illustrated in an upper part of
The tooth 33 is provided with the coil 50. The yoke pieces 43 form the ring-shaped yoke 32 in the ring-shaped arrangement state. The plurality of core segments 40 is coupled with the yoke pieces 43, respectively. A recess portion 44 and a protrusion portion 45 are formed on the yoke piece 43. The recess portion 44 and the protrusion portion 45 are formed on each side surface in the circumferential direction of the yoke piece 43, respectively. The side surface in the circumferential direction of the yoke piece 43 is a surface of the yoke piece 43, the surface being in contact with the adjacent core segment 40 in the ring-shaped arrangement state. The side surfaces in the circumferential direction of the yoke piece 43 are surfaces along the radial direction. For example, the recess portion 44 is formed in the side surface on the third side in the circumferential direction of the yoke piece 43. The protrusion portion 45 is formed on the side surface on the fourth side in the circumferential direction of the yoke piece 43. Two core segments 40 that are adjacent in the ring-shaped arrangement state are in a state where the recess portion 44 and the protrusion portion 45 are fitted to each other. In other words, in the ring-shaped arrangement state, the recess portion 44 is formed in the side surface on the third side in the circumferential direction of the yoke piece 43 in the core segment 40 that is to the fourth side in the circumferential direction. In the ring-shaped arrangement state, the protrusion portion 45 is formed on the side surface on the fourth side in the circumferential direction of the yoke piece 43 in the core segment 40 that is to the third side in the circumferential direction. The recess portion 44 and the protrusion portion 45 are fitted to each other to suppress a displacement of the core segment 40 in the radial direction in the ring-shaped arrangement state.
The yoke piece 43 includes a first hinge portion 46. The first hinge portion 46 is provided to a portion of the yoke piece 43 on the third side in the circumferential direction and on the counter-rotor side in the radial direction. The first hinge portion 46 is provided at the previously mentioned position in a state of protruding toward the counter-rotor side in the radial direction. A coupling hole 47 is formed in the first hinge portion 46. In other words, the coupling hole 47 is formed in the portion of the yoke piece 43 on the third side in the circumferential direction and on the counter-rotor side in the radial direction. The first hinge portion 46 is protruded toward the counter-rotor side in the radial direction, and accordingly the coupling hole 47 can be provided at a position having small influence on the magnetic characteristics. The coupling hole 47 is rendered into a hole that penetrates the core segment 40 in the lamination direction. The coupling hole 47 is a hole of a perfect circle shape. The first hinge portion 46 in which the coupling hole 47 is formed, together with a second hinge portion 63 and a third hinge portion 73, which will be described below, forms the coupling structure where the plurality of core segments 40 is coupled (see
The coil 50 is formed by a predetermined winding machine, targeted at the core segment 40. The coil 50 is formed by winding a conductive wire around the tooth 33. For example, the coil 50 is formed by concentratedly winding the conductive wire around the tooth 33 (see
A pair of the first insulator 61 and the second insulator 71 electrically insulates the core segment 40 and the coil 50. The first insulator 61 is integrally formed by, for example, synthetic resin injection molding. The second insulator 71 is integrally formed by, for example, synthetic resin injection molding as in the first insulator 61. Polyamide (PA), polybutylene terephthalate (PBT), or polyphenylene sulfide (PPS) is exemplified as the synthetic resin that forms the first insulator 61 and the second insulator 71.
The first insulator 61 is mounted on the core segment 40 on the first side in the lamination direction (see
As illustrated in
The first coupling pin 64 is inserted into the coupling hole 47 formed in the core segment 40 of the core segments 40 adjacent in the circumferential direction that is to the fourth side in the circumferential direction (see
The second insulator 71 is mounted on the core segment 40 on the second side in the lamination direction (see
As illustrated in
The second coupling pin 74 is inserted into the coupling hole 47 formed in the core segment 40 of the core segments 40 adjacent in the circumferential direction that is to the fourth side in the circumferential direction (see
In the second insulator 71, two wall portions aligned in the radial direction with a predetermined space therebetween are formed on the second covering portion 72 as in the first insulator 61. A coil end of the coil 50 is housed between these wall portions on the second side in the lamination direction. Three grooves are formed in a side surface on the counter-rotor side in the radial direction of the wall portion that is to the counter-rotor side in the radial direction, of the two wall portions (see
The winding is performed in, for example, a state where the first insulator 61 and the second insulator 71 are mounted on each of the 12 core segments 40, and the 12 core segments 40 are coupled. In this case, the 12 core segments 40 are set on the winding machine in, for example, a state of being arranged in a straight line. The conductive wire is wound around each of the teeth 33 of the 12 core segments 40. The 12 coils 50 are formed on the core segments 40, respectively (see
According to the example, the following advantageous effects can be obtained.
(1) The core segment 40 is provided with the first hinge portion 46 (see
Hence, the plurality of core segments 40 can be coupled. The plurality of core segments 40 can be arranged in a straight line in the state where the plurality of core segments 40 are coupled. The plurality of core segments 40 can be arranged in a ring shape. While electrical steel sheets are punched into the shape of the core segment 40, the coupling hole 47 can be formed at a timing when the punched electrical steel sheets are laminated. In other words, the coupling hole 47 is formed by punching a hole forming the coupling hole 47 upon the punching of the electrical steel sheets and laminating the electrical steel sheets that have been punched into the shape of the core segment 40, in which the previously mentioned hole has been formed. The first coupling pin 64 and the second coupling pin 74 can be formed when the first insulator 61 and the second insulator 71 are molded respectively. The first coupling pin 64 and the second coupling pin 74 are made of synthetic resin, and accordingly the laminated electrical steel sheets are prevented from being electrically connected with each other by the first coupling pin 64 and the second coupling pin 74. In the stator 30, the coupling structure of the core segments 40 that can suppress influence on the magnetic characteristics is achieved.
(2) In the core segment 40, the coupling hole 47 is provided to the portion of the yoke piece 43 on the third side in the circumferential direction and on the counter-rotor side in the radial direction. In the first insulator 61, the first coupling pin 64 is provided to the portion of the first covering portion 62 on the fourth side in the circumferential direction and on the counter-rotor side in the radial direction. In the second insulator 71, the second coupling pin 74 is provided to the portion of the second covering portion 72 on the fourth side in the circumferential direction and on the counter-rotor side in the radial direction. Hence, the coupling structure is not arranged on the slot 34 side. The slot 34 can be made effective use for the housing of the coil 50.
(3) The coupling hole 47 is rendered into the hole of a perfect circle shape (see
The example can also be configured as follows. Some configurations of modifications illustrated below may also be employed in combination as appropriate. In the following description, points different from the above description are described, and the description of similar points is omitted as appropriate.
(1) In the above description, the stator 30 of the motor 10 has been described as an example (see
(2) In the above description, the motor 10 of the inner rotation type has been described as an example (see
(3) In the above description, the coupling hole 47 is rendered into the hole penetrating in the lamination direction (see
(4) In the above description, the first hinge portion 46 in which the coupling hole 47 is formed is provided to the portion of the yoke piece 43 on the third side in the circumferential direction and on the counter-rotor side in the radial direction in the state of protruding toward the counter-rotor side in the radial direction (see
For example, the first insulator 61 and the second insulator 71, which are similar to those in
(5) In the above description, the recess portion 44 is formed in the side surface on the third side in the circumferential direction of the yoke piece 43 (see
(6) In the above description, the first insulator 61 is provided with the second hinge portion 63 including the first coupling pin 64 and the first base portion 65 (see
The second hinge portion 63 and the third hinge portion 73 may be configured as illustrated in
(7) In the above description, the connection terminal 51 is attached to the first insulator 61 (see
(8) In the above description, the core segment 40 is covered with the first insulator 61 and the second insulator 71 (see
(9) In the above description, for convenience of description, the third side and the fourth side in the circumferential direction are set as follows. In other words, the direction from the third side toward the fourth side in the circumferential direction is set to a counterclockwise direction, and the direction from the fourth side toward the third side in the circumferential direction is set to a clockwise direction in a state where
Number | Date | Country | Kind |
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2014-155672 | Jul 2014 | JP | national |
This is a U.S. national phase application under 35 U.S.C. §371 of International Patent Application No. PCT/JP2015/068721, filed Jun. 29, 2015, and claims benefit of priority to Japanese Patent Application No. 2014-155672, filed Jul. 31, 2014. The entire contents of these applications are hereby incorporated by reference.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2015/068721 | 6/29/2015 | WO | 00 |