JPWO2019026173A1 - Motor and rotor manufacturing method - Google Patents

Abstract

A rotor including a rotor core and a magnet inserted into the rotor core; and a stator provided around the rotor core. The rotor core extends in parallel with a shaft hole into which the shaft is inserted and a rotation axis direction of the shaft. And a magnet insertion portion which is elongated in a cross section orthogonal to the rotation axis direction and has a magnet inserted therein, wherein the magnet includes an outer peripheral surface which is in contact with the magnet insertion portion of the rotor core. The portion is formed at a longitudinal end of the magnet insertion portion in a cross section orthogonal to the rotation axis direction, and includes a protrusion protruding toward the magnet, wherein the protrusion is in contact with the outer peripheral surface of the magnet. And a separated portion separated from the outer peripheral surface of the magnet.

Description

  The present invention relates to a motor and a method for manufacturing a rotor, and more particularly, to a motor including a rotor including a magnet and a method for manufacturing a rotor including a magnet.

  Conventional motors include a rotatable rotor provided in a compressor shell and having a shaft inserted therein, and a stator provided in the compressor shell and provided around the rotor. Some have been proposed (for example, see Patent Document 1). The rotor of the motor disclosed in Patent Document 1 includes a long magnet including a first surface and a second surface opposite to the first surface, and a rotor core having a magnet insertion portion. I have. Note that the rotor core is configured by stacking a plurality of disk-shaped core pieces. A first wall contacting the first surface of the magnet and a second wall contacting the second surface of the magnet and parallel to the first wall are provided in the magnet insertion portion of the rotor core of the motor of Patent Document 1. Are formed. In the technique described in Patent Document 1, the magnet is fixed to the rotor core by being sandwiched between the first wall surface and the second wall surface.

JP-A-9-200982

  When the rotor is rotating, a force may be applied to the magnet in a direction perpendicular to the axial direction of the rotor and parallel to the first wall surface of the magnet insertion portion. Since this force is a force for shifting the position of the magnet, this force is referred to herein as a shift force. When a displacement force is applied to the magnet, a frictional force is generated between the magnet and the magnet insertion portion, which acts so as not to displace the position of the magnet. This frictional force is generated between the first wall surface and the first surface of the magnet, and is generated between the second wall surface and the second surface of the magnet. However, there is a high possibility that the displacement of the magnet cannot be prevented only by the frictional force between the magnet and the magnet insertion portion.

  The present invention has been made in order to solve the above-described problems, and provides a motor that can more reliably prevent a displacement of a magnet provided on a rotor core, and a method of manufacturing a rotor. The purpose is.

  A motor according to the present invention includes a rotor including a rotor core and a magnet inserted into the rotor core, and a stator provided around the rotor core, wherein the rotor core has a shaft hole into which a shaft is inserted, and a shaft hole. A magnet insertion portion that extends in parallel with the rotation axis direction and is elongate in a cross section orthogonal to the rotation axis direction and has a magnet inserted therein, wherein the magnet is in contact with the magnet insertion portion of the rotor core. Including an outer peripheral surface, the magnet insertion portion includes a projection formed at a longitudinal end of the magnet insertion portion in a cross section orthogonal to the rotation axis direction and projecting toward the magnet, and the projection includes an outer periphery of the magnet. A top portion in contact with the surface and a separation portion separated from the outer peripheral surface of the magnet are included.

  According to the present invention, the magnet insertion portion is formed at a longitudinal end of the magnet insertion portion in a cross section orthogonal to the rotation axis direction, and includes a protrusion protruding toward the magnet. For this reason, even if a shifting force is applied to the magnet, the end of the magnet abuts on the protruding portion and the movement of the magnet in the direction of the shifting force is restricted. Therefore, according to the present invention, even if a displacement force is applied to the magnet, the displacement of the magnet can be prevented more reliably.

1 is a schematic sectional view of a scroll compressor 1 according to Embodiment 1. FIG. FIG. 2 is an enlarged explanatory view of a rotor 4a shown in FIG. It is AA sectional drawing shown in FIG. FIG. 4 is a sectional view taken along line BB shown in FIG. 3. FIG. 5 is an explanatory diagram of a magnet insertion portion 4j of a core piece 4c1 of a first group G1 shown in FIG. It is explanatory drawing of the magnet 4d. It is a figure showing the state where magnet 4d was inserted in magnet insertion part 4j of core piece 4c1. FIG. 8 is an enlarged view of a protruding portion tf1 shown in FIG. 7 and its periphery. FIG. 5 is an explanatory diagram of a core piece 4c2 of a second group G2 shown in FIG. It is a figure showing the state where magnet 4d was inserted in magnet insertion part 4j of core piece 4c2. FIG. 8 is a cross-sectional view when the rotor core 4c is viewed in the CC cross section illustrated in FIG. 7. FIG. 9 is a schematic diagram showing a state in which the movement of the magnet 4d in the magnet insertion portion 4j is restricted when a shift force F or the like is applied to the magnet 4d. It is a first modification of the scroll compressor 1 according to the first embodiment. It is a second modification of the scroll compressor 1 according to the first embodiment. It is the figure which showed the state where the magnet 4d was inserted in the magnet insertion part 24j of the core piece 4c1. FIG. 16 is an enlarged view of a protruding portion tf3 shown in FIG. 15 and its surroundings. It is explanatory drawing of the magnet insertion part 34j of the core piece 4c1 of the 1st group G1. It is explanatory drawing of the magnet 43d. It is a figure showing the state where magnet 43d was inserted in magnet insertion part 34j of core piece 4c1. FIG. 13 is a cross-sectional view of a rotor core 4c of a scroll compressor according to Embodiment 4. FIG. 5 is an explanatory diagram of a configuration of a first end-side magnet piece Dv2. The state where the center magnet piece Dv1 is inserted into the magnet insertion portion 44j is shown. The state where the first end side magnet piece Dv2 is inserted into the magnet insertion portion 44j is shown. A state where the second end-side magnet piece Dv3 is inserted into the magnet insertion portion 44j is shown. FIG. 15 is a sectional view of a rotor core 4c of a scroll compressor according to Embodiment 5. FIG. 5 is a configuration explanatory view of a center magnet piece Dv11. A state where the first end side magnet piece Dv12 is inserted into the magnet insertion portion 45j is shown. The state where the second end side magnet piece Dv13 is inserted into the magnet insertion portion 45j is shown. The state where the center magnet piece Dv11 is inserted into the magnet insertion portion 45j is shown.

Embodiment 1 FIG.
Hereinafter, embodiments will be described with reference to the drawings as appropriate. In addition, in the following drawings including FIG. 1, the relationship of the size of each component may be different from the actual one.

<Configuration of First Embodiment>
FIG. 1 is a schematic cross-sectional view of a scroll compressor 1 according to Embodiment 1. The scroll compressor 1 compresses the refrigerant to a high temperature and a high pressure. The scroll compressor 1 forms an outer shell of the scroll compressor 1 and has a shell 2 having an oil reservoir 3a formed at a lower portion, an oil pump 3 housed in the shell 2 and sucking oil from the oil reservoir 3a, and rotatable. , And a motor 4 including a stator 4b fixed to the shell 2. Further, the scroll compressor 1 includes a compression section 5 including a fixed scroll 30 and an orbiting scroll 40, a frame 6 containing the orbiting scroll 40, and a shaft 7 fixed to the rotor 4a. . Further, the scroll compressor 1 includes a suction pipe 11 for guiding the refrigerant into the shell 2 and a discharge pipe 12 for guiding the refrigerant compressed by the compression unit 5 from inside the shell 2 to outside the shell 2.

  The scroll compressor 1 includes a discharge chamber 13 provided on the fixed scroll 30, a valve 13 </ b> A provided on the discharge chamber 13, and a muffler 14 provided on the discharge chamber 13. The scroll compressor 1 includes an Oldham ring 15 for restricting the orbiting scroll 40 from rotating, a cylindrical slider 16 provided at an upper end of the shaft 7, and a main body provided on the frame 6. The bearing includes a bearing 8a and a sleeve 17 provided between the main bearing 8a and the shaft 7. Further, the scroll compressor 1 includes a first balancer 18 provided on the shaft 7, a sub-frame 20 fixed to a lower portion of the shell 2, an auxiliary bearing 8b provided on the sub-frame 20, 6 and an oil drain pipe 21 for discharging excess oil.

  The shell 2 includes a cylindrical body 2A, a dome-shaped upper shell 2a provided at an upper end of the body 2A, and a dome-shaped lower shell 2b provided at a lower end of the body 2A. ing. The oil pump 3 supplies the oil sucked from the oil reservoir 3a to an oil passage 7a formed in the shaft 7. The motor 4 rotates the shaft 7. The motor 4 is provided below the compression unit 5 and above the subframe 20. Electric power is supplied to the stator 4b of the motor 4 from an inverter (not shown). When electric power is supplied to the stator 4b, the rotor 4a rotates. The compression section 5 compresses the refrigerant. The fixed scroll 30 is fixed to the body 2 </ b> A of the shell 2. The discharge chamber 13 is provided on the fixed scroll 30. The orbiting scroll 40 has a hollow cylindrical boss 40a into which the upper end of the shaft 7 is inserted. A swing bearing 8c is provided on the inner peripheral portion of the boss 40a. The orbiting scroll 40 performs an orbiting operation by rotating the shaft 7. The fixed scroll 30 has a spiral wrap portion 31, and the orbiting scroll 40 has a spiral wrap portion 41 that compresses the refrigerant together with the wrap portion 31. In a space between the wrap portion 31 and the wrap portion 41, a compression chamber 5a for compressing the refrigerant is formed. The fixed scroll 30 has a discharge port 30a through which the refrigerant compressed in the compression chamber 5a passes.

  The frame 6 is fixed to the shell 2. The frame 6 supports the shaft 7 via a main bearing 8a. The frame 6 supports the orbiting scroll 40. The frame 6 is provided with a suction port 6a for guiding the refrigerant located below the frame 6 to the compression chamber 5a. The frame 6 has an Oldham space 15b in which the Oldham ring 15 is provided. The frame 6 has a concave space 6d in which the boss 40a is arranged. Further, the frame 6 is provided with a thrust bearing 6b on which the orbiting scroll 40 slides. The shaft 7 transmits the rotational force of the rotor 4a to the orbiting scroll 40. The shaft 7 is rotatably supported by a main bearing 8a and a sub bearing 8b. The suction pipe 11 is provided on the body 2 </ b> A of the shell 2, and the discharge pipe 12 is provided on the upper shell 2 a of the shell 2. The discharge chamber 13 has a space 13a into which the refrigerant flowing through the discharge port 30a of the fixed scroll 30 flows, and a discharge port 13b communicating with the space 13a and closed by a valve 13A. When the pressure in the space 13a becomes higher than a predetermined pressure, the valve 13A separates from the discharge port 13b. The muffler 14 suppresses pulsation of the refrigerant discharged from the discharge chamber 13.

  The slider 16 is provided between the orbiting scroll 40 and the upper end of the shaft 7. The slider 16 is provided inside the swing bearing 8c. The first balancer 18 is provided between the frame 6 and the rotor 4a. The first balancer 18 is housed in the cover 18a. The sub frame 20 supports the shaft 7 via the sub bearing 8b. The upper end of the oil drain pipe 21 is provided in the Oldham space 15b of the frame 6, and the lower end of the oil drain pipe 21 is provided along the peripheral surface of the body 2A.

  FIG. 2 is an enlarged explanatory view of the rotor 4a shown in FIG. FIG. 3 is a sectional view taken along line AA shown in FIG. FIG. 4 is a sectional view taken along line BB shown in FIG. As shown in FIG. 2, the rotor 4a includes a cylindrical rotor core 4c, a first end plate 4e provided on one end surface of the rotor core 4c, and a second end provided on the other end surface of the rotor core 4c. It has a plate 4f and a second balancer 4g provided on the second end plate 4f. The rotor 4a includes a rivet 4h1 inserted into the first end plate 4e, the rotor core 4c, and the second end plate 4f, and the first end plate 4e, the rotor core 4c, the second end plate 4f, and the second end plate 4f. And a rivet 4h2 inserted into the balancer 4g. As shown in FIG. 4, the rotor core 4c is configured by stacking a plurality of core pieces. That is, the rotor core 4c includes a plurality of core pieces 4c1 belonging to the first group G1, a plurality of core pieces 4c2 belonging to the second group G2, and a plurality of core pieces 4c3 belonging to the third group G3. I have. The core piece 4c1, the core piece 4c2, and the core piece 4c3 are disk-shaped. The core piece 4c1 belonging to the first group G1 corresponds to the first core piece, the core piece 4c3 belonging to the third group G3 corresponds to the second core piece, and the core piece 4c2 belonging to the second group G2. Corresponds to the third core piece. The shape of the core piece 4c1 and the shape of the core piece 4c3 are the same, but the shape of the core piece 4c1 and the shape of the core piece 4c2 are different. The second group G2 is arranged between the first group G1 and the third group G3. As shown in FIG. 2, a shaft hole 4i into which the shaft 7 is inserted is formed in the center of the rotor core 4c. The rotation axis direction Dr1 of the shaft 7 is parallel to the direction in which the core pieces of the rotor core 4c are stacked. Further, as shown in FIGS. 3 and 4, a magnet insertion portion 4j extending parallel to the rotation axis direction Dr1 is formed in the rotor core 4c. The magnet insertion portion 4j is formed in a long shape in a cross section orthogonal to the rotation axis direction Dr1. A through hole into which the magnet 4d is inserted is formed in the magnet insertion portion 4j. Six magnet insertion portions 4j are formed in the rotor core 4c. Two adjacent magnet insertion portions 4j are arranged at an angle of 60 degrees with respect to the center of the rotor core 4c. Further, as shown in FIGS. 3 and 4, a plurality of through holes 4L are formed on the outer peripheral surface side of the rotor core 4c with respect to the position where the magnet insertion portion 4j is formed.

  The first end plate 4e and the second end plate 4f prevent the magnet 4d from jumping out of the magnet insertion portion 4j. A shaft hole 4e1 in which the shaft 7 is inserted is formed in the center of the first end plate 4e, and a shaft hole 4e1 in which the shaft 7 is inserted is also formed in the center of the second end plate 4f. The rivet 4h1 is a member for attaching the first end plate 4e and the second end plate 4f to the rotor core 4c. The rivet 4h2 is a member that attaches the first end plate 4e and the second end plate 4f to the rotor core 4c and attaches the second balancer 4g to the second end plate 4f. The second balancer 4g secures the balance between the shaft 7, the rotor 4a and the orbiting scroll 40 when the shaft 7, the rotor 4a and the orbiting scroll 40 are moving.

  FIG. 5 is an explanatory diagram of the magnet insertion portion 4j of the core piece 4c1 of the first group G1 shown in FIG. FIG. 6 is an explanatory diagram of the magnet 4d. FIG. 7 is a diagram illustrating a state where the magnet 4d is inserted into the magnet insertion portion 4j of the core piece 4c1. FIG. 8 is an enlarged view of the protruding portion tf1 shown in FIG. 7 and its surroundings. Note that the direction Dr2 is the longitudinal direction of the magnet insertion portion 4j when the magnet insertion portion 4j is viewed in a cross section orthogonal to the rotation axis direction Dr1. The configuration of the magnet 4d and the configuration of the core piece 4c1 will be described based on FIGS. 5 to 8 and FIGS. 2 to 4 described above. Note that the core piece 4c3 has the same shape as the core piece 4c1, and a description thereof will be omitted.

  As shown in FIG. 6, the magnet 4d includes an outer peripheral surface 4D that is in contact with the magnet insertion portion 4j of the rotor core 4c. The outer peripheral surface 4D includes an inner surface SF1 which is a plane formed on the shaft hole 4i side, and an outer surface SF2 which is a plane parallel to the inner surface SF1. Here, as shown in FIGS. 3 and 6, the distance from the outer surface SF2 to the shaft hole 4i is longer than the distance from the inner surface SF1 to the shaft hole 4i. As shown in FIGS. 4 and 6, the outer peripheral surface 4D includes a first contact surface sf1 provided at a first end 4d1 extending in parallel with the rotation axis direction Dr1, and a first end 4d1. And a second contact surface sf2 provided at a second end 4d2 extending parallel to the portion 4d1. The first end 4d1 is one end of the inner surface SF1 in the direction Dr2, and the second end 4d2 is the other end of the inner surface SF1 in the direction Dr2. The first contact surface sf1 and the second contact surface sf2 have the same shape, and the first contact surface sf1 and the second contact surface sf2 are flat. Further, as shown in FIG. 6, the outer peripheral surface 4D is provided at one end in the direction Dr2 of the outer surface SF2, provided at an end surface SF3 orthogonal to the outer surface SF2, and at the other end in the direction Dr2 of the outer surface SF2. , An end surface SF4 orthogonal to the outer surface SF2. The end face SF3 and the end face SF4 have the same shape, and the end face SF3 and the end face SF4 are flat.

  As shown in FIGS. 5 and 7, the magnet insertion portion 4j has a first surface TF1 facing the inner surface SF1 of the magnet 4d with a gap, and a second surface TF1 in contact with the outer surface SF2 of the magnet 4d. And a surface TF2. The first surface TF1 and the second surface TF2 are planes. As shown in FIGS. 3 and 5, the magnet insertion portion 4j includes a protruding portion tf1 formed at one end in the longitudinal direction of the magnet insertion portion 4j in a cross section orthogonal to the rotation axis direction Dr1, and a rotation axis direction. A projection tf2 formed at the other longitudinal end of the magnet insertion portion 4j in a cross section orthogonal to Dr1. The protruding portion tf1 protrudes toward the first contact surface sf1, and the protruding portion tf2 protrudes toward the second contact surface sf2. As shown in FIGS. 5 to 7, the protrusion tf1 is provided on the first end 4d1 side of the inner surface SF1, and the protrusion tf2 is provided on the second end 4d2 side of the inner surface SF1. One of the protrusions tf1 and tf2 corresponds to the first protrusion, and the other corresponds to the second protrusion.

  Here, the arrangement of the protruding portion tf1 and the protruding portion tf2 is symmetric, but the shape of the protruding portion tf1 and the shape of the protruding portion tf2 are the same. For this reason, here, the description will focus on the shape of the protruding portion tf1. As shown in FIG. 8, the protruding portion tf1 includes a top portion tfa that is in contact with the first contact surface sf1 of the magnet 4d, a separated portion tfb that is separated from the first contact surface sf1 of the magnet 4d, 4d includes a separation portion tfc separated from the first contact surface sf1. The top portion tfa is sandwiched between the separated portion tfb and the separated portion tfc. Although not shown, the projection tf2 has the same shape as the projection tf1. That is, the protruding portion tf2 includes the top portion tfa that is in contact with the second contact surface sf2, the separation portion tfb that is separated from the second contact surface sf2, and the separation portion that is separated from the second contact surface sf2. Section tfc.

  FIG. 9 is an explanatory diagram of the core piece 4c2 of the second group G2 shown in FIG. FIG. 10 is a diagram showing a state where the magnet 4d is inserted into the magnet insertion portion 4j of the core piece 4c2. FIG. 11 is a cross-sectional view when the rotor core 4c is viewed in the CC cross section shown in FIG. Next, the configuration of the core piece 4c2 will be described. The shape of the core piece 4c2 differs from the shape of the core piece 4c1 in the following points, but is otherwise the same. The protruding portions tf1 and tf2 described above are not formed on the core piece 4c2. That is, as shown in FIGS. 9 and 10, the magnet insertion portion 4j contacts the inner peripheral surface TF3 facing the first contact surface sf1 of the magnet 4d without contacting the first contact surface sf1 and the second contact surface sf2 of the magnet 4d. The inner peripheral surface TF4 that faces without being formed. As shown in FIG. 11, the inner peripheral surface TF3 is provided between the protrusion tf1 of the core piece 4c1 and the protrusion tf1 of the core piece 4c3. Further, the inner peripheral surface TF4 is provided between the protrusion tf2 of the core piece 4c1 and the protrusion tf2 of the core piece 4c3.

  As shown in FIG. 11, the first contact surface sf1 of the magnet 4d is in contact with the protrusion tf1 of the core piece 4c1 of the first group G1 and the protrusion tf1 of the core piece 4c3 of the third group G3. , Does not come into contact with the core piece 4c2 of the second group G2. That is, as shown in FIGS. 10 and 11, a gap 4Q is formed between the core piece 4c2 of the second group G2 and the first contact surface sf1. The second contact surface sf2 of the magnet 4d is in contact with the protruding portion tf2 of the core piece 4c1 of the first group G1 and the protruding portion tf2 of the core piece 4c3 of the third group G3, but is in contact with the second group G1. It does not contact the core piece 4c2 of G2. That is, the gap 4Q is formed between the core piece 4c2 of the second group G2 and the second contact surface sf2.

  Further, the shape of the magnet 4d will be described with reference to FIG. As shown in FIG. 11, the magnet 4d has an end 4dt whose width parallel to the direction Dr2 is tapered. The magnet 4d is inserted into the magnet insertion portion 4j of the rotor core 4c, while the end 4dt is a portion of the magnet 4d which is first inserted into the magnet insertion portion 4j.

<Operation of First Embodiment>
The operation of the scroll compressor 1 will be described with reference to FIG. When the stator 4b receives power supply from an inverter (not shown), the rotor 4a rotates. As the rotor 4a rotates, the shaft 7 rotates. As the shaft 7 rotates, the oil in the oil reservoir 3a is pulled up by the oil pump 3 and flows into the oil passage 7a of the shaft 7. The oil that has flowed into the oil passage 7a is supplied to a space 6d formed in the frame 6 after lubricating the swing bearing 8c. The oil in the space 6d is supplied to the Oldham space 15b while lubricating the thrust bearing 6b. The oil supplied to the Oldham space 15b lubricates the Oldham ring 15. The oil supplied to the Oldham space 15b returns to the oil reservoir 3a through the oil drain pipe 21.

  The refrigerant flows into the shell 2 from the suction pipe 11. The refrigerant flowing into the shell 2 flows into the compression chamber 5a through the suction port 6a of the frame 6. Here, the rotation of the rotor 4a causes the orbiting scroll 40 to orbit. As the orbiting scroll 40 makes orbital movement, the refrigerant is compressed in the compression chamber 5a. The refrigerant compressed in the compression chamber 5a flows to the discharge pipe 12 through the discharge port 30a of the fixed scroll 30, the discharge port 13b of the discharge chamber 13, and the muffler 14.

  FIG. 12 is a schematic diagram illustrating a state in which the movement of the magnet 4d is restricted when the displacement force F or the like is applied to the magnet 4d. The force causing the displacement of the magnet 4d, such as the displacement force F, is generated when the rotor 4a is rotating. Here, the direction of the deviation force F is parallel to the direction from the protrusion tf2 to the protrusion tf1. When the displacement force F is applied to the magnet 4d, the magnet 4d receives the reaction force f from the protrusion tf1 because the magnet 4d abuts on the protrusion tf1. The component fx parallel to the direction Dr2 of the reaction force f is equal to the shear force F. That is, even if the displacement force F is applied to the magnet 4d, the first contact surface sf1 of the magnet 4d receives the reaction force f from the protruding portion tf1, so that the movement of the magnet 4d in the direction of the displacement force F is restricted. The component fy orthogonal to the direction Dr2 of the reaction force f acts to press the outer surface SF2 of the magnet 4d against the second surface TF2.

  Although illustration is omitted, when the direction of the deviation force is parallel to the direction from the protrusion tf1 to the protrusion tf2, the magnet 4d strikes the protrusion tf2, and the magnet 4d receives the reaction force f from the protrusion tf2. Accordingly, the movement of the magnet 4d is regulated.

  Further, even if the displacement force F2 is applied to the rotor 4a, the magnet 4d abuts on the protrusions tf1 and tf2, so that the magnet 4d is restricted from moving in the direction of the displacement force F2. Note that the direction of the deviation force F2 is a direction from the first surface TF1 to the second surface TF2. Furthermore, even if the shear force F3 is applied to the rotor 4a, the magnet 4d is restricted from moving in the direction of the shear force F3 because the magnet 4d abuts on the second surface TF2. The direction of the shift force F3 is opposite to the direction of the shift force F2.

<Effect of First Embodiment>
The magnet insertion portion 4j has a protruding portion tf1 formed at a longitudinal end of the magnet insertion portion 4j in a cross section orthogonal to the rotation axis direction Dr1, and protruding toward the magnet 4d. For this reason, even if the displacement force F is applied to the magnet 4d, the magnet 4d receives the reaction force f from the protrusion tf1, and the movement of the magnet 4d in the direction of the displacement force F is restricted. Therefore, when the rotor 4a is rotating, the displacement of the magnet 4d is more reliably prevented. Further, since the displacement of the magnet 4d is more reliably prevented, it is possible to prevent the magnet 4d from colliding with the inner peripheral surface of the magnet insertion portion 4j when the rotor 4a is rotating. As a result, damage to the magnet 4d and the rotor 4a and generation of noise due to collision between the magnet 4d and the inner peripheral surface of the magnet insertion portion 4j are suppressed.

  The protruding portion tf1 includes a top portion tfa, a separated portion tfb, and a separated portion tfc. Although the top portion tfa is in contact with the magnet 4d, the separated portion tfb and the separated portion tfc are not in contact with the magnet 4d, so that the contact area of the core piece 4c1 with the magnet 4d is suppressed. Thereby, when the magnet 4d is pressed into the magnet insertion portion 4j, friction between the outer peripheral surface 4D of the magnet 4d and the inner peripheral surface of the magnet insertion portion 4j can be suppressed. Therefore, the work load when press-fitting the magnet 4d into the magnet insertion part 4j is suppressed.

  The magnet insertion portion 4j includes a protruding portion tf2 having the same configuration as the protruding portion tf1 in addition to the protruding portion tf1. For this reason, the effect of preventing the displacement of the magnet 4d, the effect of preventing the magnet 4d from colliding with the inner peripheral surface of the magnet insertion portion 4j, and the press-fitting of the magnet 4d into the magnet insertion portion 4j. The effect of suppressing the work load when performing is further improved.

  The core piece 4c2 of the second group Gr2 includes an inner peripheral surface TF3 separated from the outer peripheral surface 4D of the magnet 4d, and an inner peripheral surface TF4 separated from the outer peripheral surface 4D of the magnet 4d. For this reason, the contact area of the core piece 4c2 with the magnet 4d is reduced by the inner peripheral surface TF3 and the inner peripheral surface TF4. Thereby, when the magnet 4d is pressed into the magnet insertion portion 4j, the friction between the outer peripheral surface 4D of the magnet 4d and the core piece 4c2 can be suppressed. Therefore, the work load when press-fitting the magnet 4d into the magnet insertion part 4j is suppressed.

  The refrigerant has a higher magnetic resistance than iron or the like forming the rotor core 4c. Therefore, the magnetic flux of the magnet 4d does not easily pass through the refrigerant. Here, the outer surface SF2 of the magnet 4d is in contact with the second surface TF2 of the magnet insertion portion 4j. Therefore, no refrigerant flows between the outer surface SF2 and the second surface TF2. Thereby, the portion of the area around the magnet 4d where the magnetic flux of the magnet 4d is difficult to pass is reduced. Accordingly, a decrease in the operating efficiency of the motor 4 is suppressed.

  In the description of the first embodiment, the form of the rotor core 4c including the core piece 4c2 having a different shape from the core piece 4c1 has been described, but the present invention is not limited to this form. That is, the shape of all the core pieces included in the rotor core 4c may be the same as the shape of the core piece 4c1. Further, in the description of the first embodiment, the form in which the motor 4 is applied to the scroll compressor 1 has been described, but the present invention is not limited to this form. The motor 4 may be applied to objects other than the compressor.

<Modification 1>
FIG. 13 is a first modification of the scroll compressor 1 according to the first embodiment. In the first embodiment, the form in which the protruding portion tf1 is formed in a curved surface has been described, but the present invention is not limited to this form. As shown in FIG. 13, the separation part tfb and the separation part tfc may be flat. Thereby, the top tfa of the first modification is sharper than the top tfa of the first embodiment. As a result, the contact area between the protrusion tf10 of the first modification and the magnet 4d is smaller than the contact area between the protrusion tf1 and the magnet 4d of the first embodiment. The same effect as in the first embodiment can be obtained even in the first modification.

<Modification 2>
FIG. 14 is a second modification of the scroll compressor 1 according to the first embodiment. In the first embodiment, the protrusion tf1 is formed at one longitudinal end of the magnet insertion portion 4j in a cross section orthogonal to the rotation axis direction Dr1, and the protrusion tf2 is formed in the magnet insertion portion 4j in a cross section orthogonal to the rotation axis direction Dr1. It was formed at the other end in the longitudinal direction. However, it is not limited to this mode. In the second modification, a protrusion tf1 is formed at one end in the longitudinal direction of the magnet insertion portion 4j in a cross section orthogonal to the rotation axis direction Dr1. On the other hand, a support surface tf20 is formed instead of the protruding portion tf2 at the other end in the longitudinal direction of the magnet insertion portion 4j in a cross section orthogonal to the rotation axis direction Dr1. The support surface tf20 is in contact with the second contact surface sf2 of the magnet 4d. Note that the support surface tf20 does not need to protrude toward the second contact surface sf2. Even in the second modification, the same effect as in the first embodiment can be obtained.

Embodiment 2 FIG.
In the second embodiment, the same parts as those in the first embodiment are denoted by the same reference numerals, and the description thereof will be omitted. The description will focus on differences from the first embodiment. In the first embodiment, the end of the inner side surface SF1 of the magnet 4d is in contact with the magnet insertion portion 4j. On the other hand, in the second embodiment, the end side of the outer surface SF2 of the magnet 42d is in contact with the magnet insertion portion 24j. FIG. 15 is a diagram illustrating a state where the magnet 4d is inserted into the magnet insertion portion 24j of the core piece 4c1. FIG. 16 is an enlarged view of the protruding portion tf3 shown in FIG. 15 and its surroundings. Since the core piece 4c3 has the same shape as the core piece 4c1, the description of the core piece 4c3 is omitted in the embodiment.

<Configuration of Second Embodiment>
The outer peripheral surface 42D of the magnet 42d has a third contact surface sf3 provided on the third end 4d3 extending parallel to the rotation axis direction Dr1 and a third contact surface sf3 extending parallel to the third end 4d3. 4 includes a fourth contact surface sf4 provided at the end 4d4. The third end 4d3 is one end in the direction Dr2 of the outer surface SF2, and the fourth end 4d4 is the other end in the direction Dr2 of the outer surface SF2. The third contact surface sf3 and the fourth contact surface sf4 have the same shape, and the third contact surface sf3 and the fourth contact surface sf4 are flat. As shown in FIG. 15, the outer peripheral surface 42D includes an end surface SF5 provided at one end in the direction Dr2 of the inner surface SF1 and an end surface SF6 provided at the other end in the direction Dr2 of the inner surface SF1. Contains. The end face SF5 and the end face SF6 have the same shape, and the end face SF5 and the end face SF6 are flat. The first surface TF1 is in contact with the inner surface SF1, and the second surface TF2 is opposed to the outer surface SF2 with a gap.

  The magnet insertion portion 24j has a protrusion tf3 formed at one end in the longitudinal direction of the magnet insertion portion 24j in a cross section orthogonal to the rotation axis direction Dr1, and a magnet insertion portion 24j in a cross section orthogonal to the rotation axis direction Dr1. A protruding portion tf4 formed at the other end in the longitudinal direction. The protruding portion tf3 protrudes toward the third contact surface sf3, and the protruding portion tf4 protrudes toward the fourth contact surface sf4. The protrusion tf3 is provided on the third end 4d3 side of the outer surface SF2, and the protrusion tf4 is provided on the fourth end 4d4 side of the outer surface SF2. Although the arrangement of the protrusions tf3 and tf4 is symmetric, the shapes of the protrusions tf3 and tf4 are the same. For this reason, the description here will focus on the shape of the protruding portion tf3. One of the protrusions tf3 and tf4 corresponds to the third protrusion, and the other corresponds to the fourth protrusion.

  As shown in FIG. 16, the protruding portion tf3 includes a top portion tfa that is in contact with the third contact surface sf3 of the magnet 42d, a separated portion tfb that is separated from the third contact surface sf3 of the magnet 42d, 42d includes a separation portion tfc that is separated from the third contact surface sf3. Although not shown, the protruding portion tf4 has the same shape as the protruding portion tf3. That is, the protruding portion tf4 includes the top portion tfa in contact with the fourth contact surface sf4, the separated portion tfb separated from the fourth contact surface sf4, and the separated portion tfb separated from the fourth contact surface sf4. Section tfc.

  Although not shown, the shape of the core piece 4c2 is the same as that of the core piece 4c1 except that the above-described protrusions tf3 and tf4 are not formed.

<Effect of Embodiment 2>
The second embodiment also has the same effect as the first embodiment.

  Note that the protruding portions tf3 and tf4 may be configured as in Modification Example 1 of Embodiment 1.

Embodiment 3 FIG.
In the third embodiment, the same parts as those in the first and second embodiments are denoted by the same reference numerals, and the description thereof will not be repeated. Embodiment 3 is a mode in which Embodiment 1 and Embodiment 2 are combined. FIG. 17 is an explanatory diagram of the magnet insertion portion 34j of the core piece 4c1 of the first group G1. FIG. 18 is an explanatory diagram of the magnet 43d. FIG. 19 is a diagram illustrating a state where the magnet 43d is inserted into the magnet insertion portion 34j of the core piece 4c1.

<Configuration of Third Embodiment>
The outer peripheral surface 43D of the magnet 43d has the first contact surface sf1 described in the first embodiment, the second contact surface sf2 described in the first embodiment, and the third contact surface described in the second embodiment. sf3 and the fourth contact surface sf4 described in the second embodiment. The outer peripheral surface 43D of the magnet 43d has an end surface SF7 formed from the end of the first contact surface sf1 to the end of the third contact surface sf3, and a fourth contact surface from the end of the second contact surface sf2. and an end face SF8 formed over the end of sf4. The end face SF7 and the end face SF8 have the same shape, and the end face SF7 and the end face SF8 are flat. The first surface TF1 faces the inner surface SF1 with a gap, and the second surface TF2 also faces the outer surface SF2 with a gap.

<Effect of Third Embodiment>
The third embodiment has the following effects in addition to the same effects as the first embodiment. In the third embodiment, the first surface TF1 and the second surface TF2 are not in contact with the magnet insertion part 34j. For this reason, the contact area between the magnet 43d and the magnet insertion portion 34j is further suppressed. Therefore, the work load when the magnet 43d is pressed into the magnet insertion portion 34j is further suppressed.

  Note that the protruding portion tf1, the protruding portion tf2, the protruding portion tf3, and the protruding portion tf4 may have a form as in Modification Example 1 of the first embodiment.

Embodiment 4 FIG.
In the fourth embodiment, the same parts as those in the first to third embodiments are denoted by the same reference numerals, and the description thereof will be omitted. The description will focus on differences from the first to third embodiments.

<Configuration of Embodiment 4>
FIG. 20 is a cross-sectional view of the rotor core 4c of the scroll compressor according to Embodiment 4. FIG. 21 is an explanatory diagram of the configuration of the first end-side magnet piece Dv2. As shown in FIG. 20, the configuration of all the core pieces of the rotor core 4c of the fourth embodiment is the same as the configuration of the core piece 4c1 described in the first embodiment. The magnet 44d is of a split type. In other words, as shown in FIGS. 20 and 21, the magnet 44d has a long central magnet piece Dv1 and an elongated first end side having an end Dvt2 tapered in the thickness direction. It includes a magnet piece Dv2 and a second end magnet piece Dv3 having the same shape as the first end magnet piece Dv2.

<Manufacturing Method of Fourth Embodiment>
FIG. 22 shows a state where the central magnet piece Dv1 is inserted into the magnet insertion portion 44j. FIG. 23 shows a state where the first end-side magnet piece Dv2 is inserted into the magnet insertion portion 44j. FIG. 24 shows a state where the second end-side magnet piece Dv3 is inserted into the magnet insertion portion 44j. First, a plurality of core pieces 4c1 are stacked to produce a rotor core 4c. A magnet insertion portion 44j for inserting the magnet 44d is formed in the rotor core 4c. Next, a center magnet piece Dv1, a first end magnet piece Dv2, and a second end magnet piece Dv3 are prepared. Then, as shown in FIG. 22, the central magnet piece Dv1 is inserted into the magnet insertion portion 44j and pressed into the magnet insertion portion 44j. Subsequently, as shown in FIG. 23, the tapered end Dvt2 of the first end-side magnet piece Dv2 is inserted into the gap Sr1. The gap Sr1 is formed between one end of the central magnet piece Dv1 and the inner peripheral surface of the magnet insertion portion 44j. Then, the first end-side magnet piece Dv2 is pressed into the gap Sr1. Further, as shown in FIG. 24, the tapered end Dvt3 of the second end-side magnet piece Dv3 is inserted into the gap Sr2. The gap Sr2 is formed between the other end of the central magnet piece Dv1 and the inner peripheral surface of the magnet insertion portion 44j. Then, the second end-side magnet piece Dv3 is pressed into the gap Sr2.

<Effect of Embodiment 4>
When power is supplied to the stator, the stator generates magnetism. The rotor rotates by the interaction between the magnetism of the rotor magnet and the magnetism of the stator. The magnetism generated by the stator passes through the magnet of the rotor. Therefore, an eddy current is generated in the magnet of the rotor. When an eddy current is generated in the magnet of the rotor, the magnet generates heat and the magnet is demagnetized, and the operating efficiency of the motor decreases. Here, the magnitude of the eddy current increases in proportion to the increase in the surface area of the magnet of the rotor. In the fourth embodiment, since the magnet 44d is divided into three, the surface area of each magnet can be reduced. That is, the surface area of the central magnet piece Dv1 is smaller than the surface area of the magnet 44d when the magnet 44d is not divided. The same applies to the surface area of the first end magnet piece Dv2 and the surface area of the second end magnet piece Dv3. Therefore, the eddy current generated in the center magnet piece Dv1 is smaller than the eddy current generated in the magnet 44d when the magnet 44d is not divided. The same applies to the eddy current generated in the first end-side magnet piece Dv2 and the eddy current generated in the second end-side magnet piece Dv3. As described above, in the fourth embodiment, the eddy current generated in the central magnet piece Dv1 can be suppressed, so that the heat generation of the central magnet piece Dv1 can be suppressed. In addition, since eddy current generated in the first end-side magnet piece Dv2 can be suppressed, heat generation of the first end-side magnet piece Dv2 can be suppressed. Furthermore, since the eddy current generated in the second end-side magnet piece Dv3 can be suppressed, heat generation of the second end-side magnet piece Dv3 can be suppressed. Therefore, in the fourth embodiment, since the heat generation of each magnet can be suppressed, a decrease in the operating efficiency of the motor can be suppressed. Although the magnet 44d is divided into three in the fourth embodiment, the same effect can be obtained regardless of whether the magnet 44d is divided into two or four or more. That is, regardless of whether the magnet 44d is divided into two or more than four, the heat generation of each magnet can be suppressed, and a decrease in the operating efficiency of the motor can be suppressed.

  When press-fitting the first end-side magnet piece Dv2, the first end-side magnet piece Dv2 generates not only friction with the magnet insertion portion 44j but also friction with the center magnet piece Dv1. For this reason, the work load when press-fitting the first end-side magnet piece Dv2 is likely to increase. However, the end portion Dvt2 of the first end side magnet piece Dv2 is tapered in the thickness direction. Therefore, it is possible to suppress the work load when the first end-side magnet piece Dv2 is pressed into the gap Sr1. Since the end portion Dvt3 of the second end-side magnet piece Dv3 is also tapered in the thickness direction, the work load when the second end-side magnet piece Dv3 is pressed into the gap Sr2 can be suppressed. .

Embodiment 5 FIG.
In the fifth embodiment, the same parts as those in the first to fourth embodiments are denoted by the same reference numerals, and the description thereof will be omitted. The description will focus on differences from the first to fourth embodiments.

<Configuration of Fifth Embodiment>
FIG. 25 is a cross-sectional view of the rotor core 4c of the scroll compressor according to Embodiment 5. FIG. 26 is an explanatory diagram of the configuration of the center magnet piece Dv11. As shown in FIG. 25, the configuration of all the core pieces of the rotor core 4c of the fifth embodiment is the same as the configuration of the core piece 4c1 described in the first embodiment. The magnet 45d is divided into three parts. In other words, as shown in FIGS. 25 and 26, the magnet 45d has a long first end-side magnet piece Dv12, a long second end-side magnet piece Dv13, and a tapered width in the Dr2 direction. And an elongated central magnet piece Dv11 having an end Dvt11. The Dr2 direction is a direction orthogonal to the thickness direction of the magnet 45d.

<Production Method of Fifth Embodiment>
FIG. 27 shows a state where the first end-side magnet piece Dv12 is inserted into the magnet insertion portion 45j. FIG. 28 shows a state where the second end-side magnet piece Dv13 is inserted into the magnet insertion portion 45j. FIG. 29 shows a state where the center magnet piece Dv11 is inserted into the magnet insertion portion 45j. First, a plurality of core pieces 4c1 are stacked to produce a rotor core 4c. A magnet insertion portion 44j for inserting the magnet 44d is formed in the rotor core 4c. Next, a first end magnet piece Dv12, a second end magnet piece Dv13, and a center magnet piece Dv11 are prepared. As shown in FIG. 27, the end of the first end-side magnet piece Dv12 is inserted into the magnet insertion portion 45j. Then, the first end-side magnet piece Dv12 is pressed into the magnet insertion portion 45j. Subsequently, as shown in FIG. 28, the end of the second end-side magnet piece Dv13 is separated from the first end-side magnet piece Dv12 by a predetermined distance Ds between the second end-side magnet piece Dv13. Into the magnet insertion portion 45j in the state of being inserted. Then, the second end-side magnet piece Dv13 is pressed into the magnet insertion portion 45j. The interval Ds is set to be smaller than the width in the direction parallel to the direction Dr2 of the central magnet piece Dv11. Further, as shown in FIG. 29, the tapered end Dvt11 of the central magnet piece Dv11 is inserted between the first end magnet piece Dv12 and the second end magnet piece Dv13. Then, the central magnet piece Dv11 is pressed into the magnet insertion portion 45j.

<Effect of Embodiment 5>
In the fifth embodiment, since the magnet 45d is divided into three parts as in the fourth embodiment, the same effect as in the fourth embodiment can be obtained. That is, since the heat generation of each magnet can be suppressed, a decrease in the operating efficiency of the motor can be suppressed.

  When the central magnet piece Dv11 is press-fitted, not only the friction with the magnet insertion portion 45j, but also the friction with the first end magnet piece Dv12 and the second end magnet piece Dv13 occurs in the central magnet piece Dv11. For this reason, the work load when press-fitting the center magnet piece Dv11 tends to increase. However, the end portion Dvt11 of the central magnet piece Dv11 has a tapered width in the Dr2 direction. Therefore, it is possible to suppress a work load when the central magnet piece Dv11 is pressed into the magnet insertion portion 45j.

  Also, if the dimensions of the center magnet piece Dv11 are appropriately set, even if the dimensions of the first end magnet piece Dv12 and the dimensions of the second end magnet piece Dv13 vary, the magnet 45d is inserted into the magnet insertion portion. 45j can be prevented from rattling. First, it is preferable to prepare a plurality of central magnet pieces Dv11 having different dimensions in the Dr2 direction. Then, after the first end-side magnet piece Dv12 and the second end-side magnet piece Dv13 have been pressed into the magnet insertion portion 45j, the interval Ds is measured. Then, of the central magnet pieces Dv11, those having a dimension in the Dr2 direction larger than the interval Ds are selected. Then, the selected center magnet piece Dv11 is inserted between the first end magnet piece Dv12 and the second end magnet piece Dv13. Thereby, the center magnet piece Dv11 having the optimal size can be press-fitted into the magnet insertion portion 45j, and it is possible to prevent the magnet 45d from rattling inside the magnet insertion portion 45j.

  Reference Signs List 1 scroll compressor, 2 shell, 2A body, 2a upper shell, 2b lower shell, 3 oil pump, 3a oil reservoir, 4 motor, 4D outer peripheral surface, 4L through hole, 4Q gap, 4a rotor, 4b stator, 4c rotor core 4c1 core piece, 4c2 core piece, 4c3 core piece, 4d magnet, 4d1 first end, 4d2 second end, 4d3 third end, 4d4 fourth end, 4dt end, 4e 1 end plate, 4e1 shaft hole, 4f second end plate, 4g second balancer, 4h1 rivet, 4h2 rivet, 4i shaft hole, 4j magnet insertion section, 5 compression section, 5a compression chamber, 6 frame, 6a suction Port, 6b thrust bearing, 6d space, 7 shaft, 7a oil passage, 8a main bearing, 8b auxiliary bearing, 8c swing bearing, 11 suction pipe, 1 Discharge pipe, 13 discharge chamber, 13A valve, 13a space, 13b discharge port, 14 muffler, 15 Oldham ring, 15b Oldham space, 16 slider, 17 sleeve, 18 first balancer, 18a cover, 20 subframe, 21 oil drain Pipe, 24j magnet insertion part, 30 fixed scroll, 30a discharge port, 31 lap part, 34j magnet insertion part, 40 swing scroll, 40a boss part, 41 lap part, 42D outer peripheral surface, 42d magnet, 43D outer peripheral surface, 43d magnet 44d magnet, 44j magnet insertion part, 45d magnet, 45j magnet insertion part, Dv1 center magnet piece, Dv11 center magnet piece, Dv12 first end side magnet piece, Dv13 second end side magnet piece, Dv2 first end Side magnet piece, Dv3 Second end side magnet piece, Dvt end, Dvt11 End, Dvt2 end, Dvt3 end, G1 first group, G2 second group, G3 third group, Gr2 second group, SF1 inner surface, SF2 outer surface, SF3 end surface, SF4 end surface, SF5 End face, SF6 end face, SF7 end face, SF8 end face, Sr1 gap, Sr2 gap, TF1 first face, TF2 second face, TF3 inner face, TF4 inner face, sf1 first contact face, sf2 second face Contact surface, sf3 third contact surface, sf4 fourth contact surface, tf1 protrusion, tf10 protrusion, tf2 protrusion, tf20 support surface, tf3 protrusion, tf4 protrusion, tfa top, tfb separation, tfc separation Department.

Claims (10)

A rotor including a rotor core and a magnet inserted in the rotor core,
A stator provided around the rotor core;
With
The rotor core has a shaft hole into which a shaft is inserted, and a magnet insertion portion which extends in parallel with a rotation axis direction of the shaft and is elongated in a cross section orthogonal to the rotation axis direction, and in which the magnet is inserted. Parts and
The magnet includes an outer peripheral surface that is in contact with the magnet insertion portion of the rotor core,
The magnet insertion portion is formed at a longitudinal end of the magnet insertion portion in a cross section orthogonal to the rotation axis direction, and includes a protrusion protruding toward the magnet,
The motor, wherein the protruding portion includes a top portion that is in contact with the outer peripheral surface of the magnet, and a separated portion that is separated from the outer peripheral surface of the magnet. The outer peripheral surface of the magnet has an inner surface formed on the shaft hole side, an outer surface having a distance from the shaft hole longer than a distance from the shaft hole to the inner surface, and one end of the inner surface. A first contact surface provided at a first end portion extending in parallel with the rotation axis direction.
The motor according to claim 1, wherein the first contact surface is in contact with the top. The outer peripheral surface of the magnet further includes a second contact surface provided at a second end at the other end of the inner surface and extending parallel to the first end,
The projecting portion includes a first projecting portion having the top portion and the spacing portion, and a second projecting portion having the top portion and the spacing portion,
The first contact surface contacts the top of the first protrusion,
The motor according to claim 2, wherein the second contact surface is in contact with the top of the second protrusion. The outer peripheral surface of the magnet has an inner surface formed on the shaft hole side, an outer surface having a distance from the shaft hole longer than a distance from the shaft hole to the inner surface, and one end of the outer surface. A third contact surface provided at a third end portion extending in parallel with the rotation axis direction.
The motor according to claim 1, wherein the third contact surface is in contact with the top. The outer peripheral surface of the magnet further includes a fourth contact surface provided at a fourth end that is the other end of the outer surface and extends parallel to the third end,
The projecting portion includes a third projecting portion having the top portion and the spaced portion, and a fourth projecting portion having the top portion and the spaced portion,
The third contact surface contacts the top of the third protrusion,
The motor according to claim 4, wherein the fourth contact surface is in contact with the top of the fourth protrusion. The outer peripheral surface of the magnet has an inner surface formed on the shaft hole side, an outer surface having a distance from the shaft hole longer than a distance from the shaft hole to the inner surface, and one end of the inner surface. A first contact surface provided at a first end extending parallel to the direction of the rotation axis, and a second end of the inner surface parallel to the first end. A second contact surface provided at the extending second end, and a second contact surface provided at a third end extending parallel to the rotation axis direction at one end of the outer surface. A third contact surface, and a fourth contact surface provided at a fourth end, which is the other end of the outer surface and extends in parallel with the third end,
A first protrusion having the top and the separation portion, a second protrusion having the top and the separation portion, a third protrusion having the top and the separation portion, A fourth protrusion having the top and the spaced portion,
The first contact surface contacts the top of the first protrusion,
The second contact surface contacts the top of the second protrusion,
The third contact surface contacts the top of the third protrusion,
The motor according to claim 1, wherein the fourth contact surface is in contact with the top of the fourth protrusion. The rotor includes a first end plate provided on one end surface of the rotor core, and a second end plate provided on the other end surface of the rotor core,
The rotor core includes a plate-shaped first core piece provided on the first end plate side, a plate-shaped second core piece provided on the second end plate side, A third core piece having a plate shape provided between the first core piece and the second core piece;
The first core piece and the second core piece are formed with the protrusion,
The third core piece includes an inner peripheral surface provided between the protrusion of the first core piece and the protrusion of the second core piece,
The motor according to claim 1, wherein the inner peripheral surface of the third core piece is separated from the outer peripheral surface of the magnet. The motor according to any one of claims 1 to 7, wherein the magnet is a split type. A method for manufacturing a rotor, comprising:
A plurality of core pieces are stacked to produce a rotor core in which a magnet insertion part for inserting a magnet is formed,
An elongated first end-side magnet piece having an end tapered in the thickness direction, and an elongated second end side having an end tapered in the thickness direction. Prepare a magnet piece and a long central magnet piece,
Insert the end of the central magnet piece into the magnet insertion part,
Pressing the central magnet piece into the magnet insertion portion,
Inserting the tapered end of the first end-side magnet piece into a gap between one end of the central magnet piece and the inner peripheral surface of the magnet insertion portion,
Press-fitting the first end-side magnet piece into the magnet insertion portion;
Inserting the tapered end of the second end-side magnet piece into a gap between the other end of the central magnet piece and the inner peripheral surface of the magnet insertion portion,
A method for manufacturing a rotor, wherein the second end-side magnet piece is press-fitted into the magnet insertion portion. A method for manufacturing a rotor, comprising:
A plurality of core pieces are stacked to produce a rotor core in which a magnet insertion part for inserting a magnet is formed,
An elongated first end-side magnet piece, an elongated second end-side magnet piece, and an elongated shape including an end portion whose width in a direction orthogonal to the thickness direction is tapered. Prepare the central magnet piece,
Inserting the end of the first end side magnet piece into the magnet insertion portion,
Press-fitting the first end-side magnet piece into the magnet insertion portion;
Inserting the end of the second end-side magnet piece into the magnet insertion portion in a state where the first end-side magnet piece and the second end-side magnet piece are spaced at a predetermined distance,
Press-fitting the second end-side magnet piece into the magnet insertion portion;
Inserting the tapered end of the central magnet piece between the first end magnet piece and the second end magnet piece,
A method for manufacturing a rotor, wherein the central magnet piece is press-fitted into the magnet insertion portion.

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