JP2019152194A - Motor compressor - Google Patents

Abstract

To provide a motor compressor capable of restricting the removal of a cluster block from an insulator when extracting a conductive member from a conductive member insertion hole, while suppressing an increase in the axial size of a rotary shaft.SOLUTION: An insertion portion 372 of a claw part 37 which a second insulator 32 includes is inserted into a claw part insertion hole 57 of an attachment wall part 56 which a cluster block 52 includes, and thus the second insulator 32 and the cluster block 52 are connected to each other in a relatively movable manner. The second insulator 32 has a standing part 371 on part of the claw part 37 for restricting the movement of the cluster block 52 relative to the second insulator 32 in the direction of extracting the conductive member from the conductive member insertion hole. The cluster block 52 is opposed to an inner peripheral face 35a of an insulator side flange part 35 of the second insulator 32 in the radial direction of the rotary shaft.SELECTED DRAWING: Figure 6

Description

  The present invention relates to an electric compressor.

  For example, an electric compressor disclosed in Patent Document 1 includes a rotation shaft, an electric motor that rotates the rotation shaft, a compression unit that is driven by the rotation of the rotation shaft to compress refrigerant, and a motor that drives the electric motor. A drive circuit and a conductive member electrically connected to the motor drive circuit are provided. A stator of an electric motor includes an annular stator core, an annular insulator disposed on an end surface of the stator core in the axial direction of the rotating shaft, and a coil wound around the stator core and the insulator. In addition, the electric compressor has an insulating cluster block in which a conductive member insertion hole into which the conductive member is inserted is formed and the motor wiring drawn out from the electric motor and the conductive member are electrically connected inside. It has.

  The cluster block is disposed adjacent to the coil in the axial direction of the rotation axis. The cluster block has a fitting hole, and the insulator has an extension. The cluster block is attached to the insulator by fitting the extending portion of the insulator into the fitting hole of the cluster block.

Japanese Patent Laying-Open No. 2015-183668

  In the electric compressor of Patent Document 1, since the cluster block is arranged adjacent to the coil in the axial direction of the rotating shaft, most of the cluster block is opposite to the stator core in the insulator in the axial direction of the rotating shaft. It protrudes from the edge part of the side, and this protruding part contributes to the enlargement of the electric compressor in the axial direction of the rotating shaft.

  In general, in an electric compressor, when an assembly failure occurs or maintenance is performed in a state where the cluster block is attached to the insulator, when the conductive member is pulled out from the conductive member insertion hole, the cluster block is The conductive member may move in the direction of pulling out from the conductive member insertion hole and may come off the insulator.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to reduce the size of the rotating shaft in the axial direction while the cluster block is insulated when the conductive member is pulled out from the conductive member insertion hole. An object of the present invention is to provide an electric compressor that can be controlled from coming off.

  An electric compressor for solving the above problems includes a rotation shaft, an electric motor that rotates the rotation shaft, a compression unit that is driven by the rotation of the rotation shaft to compress refrigerant, and the electric motor. A motor driving circuit to be driven; a conductive member electrically connected to the motor driving circuit; a conductive member insertion hole into which the conductive member is inserted; and a motor wiring drawn from the electric motor; An insulating cluster block electrically connected to a conductive member, and the electric motor includes a rotor that can rotate integrally with the rotating shaft, and a stator, and the stator has an annular shape. Electric compression comprising a stator core, an annular insulator disposed on an end face of the stator core, and a coil wound around the stator core and the insulator The cluster block and the insulator each have an engaging portion that connects to each other so as to be relatively movable, and the insulator has the cluster with respect to the insulator in a direction in which the conductive member is pulled out from the conductive member insertion hole. It has a restricting part for restricting the movement of the block, and the cluster block is opposed to the rotor-side peripheral surface of the insulator in the radial direction of the rotating shaft.

  According to this, the cluster block is opposed to the rotor-side peripheral surface of the insulator in the radial direction of the rotating shaft. For this reason, compared with the case where the cluster block is arranged adjacent to the coil in the axial direction of the rotating shaft as in the prior art, the insulator protrudes from the end of the insulator on the side opposite to the stator core in the axial direction of the rotating shaft. Part is reduced. Therefore, the enlargement of the electric compressor in the axial direction of the rotating shaft can be suppressed.

  In addition, in the state where the cluster block and the insulator are connected, when an assembly failure occurs or maintenance is performed, if the conductive member is pulled out from the conductive member insertion hole, the cluster block inserts the conductive member into the conductive member. Try to move in the direction of pulling out from the hole. At this time, the movement of the cluster block in the direction in which the conductive member is pulled out from the conductive member insertion hole is restricted by the restricting portion. As a result, it is possible to restrict the cluster block from being detached from the insulator. From the above, it is possible to prevent the cluster block from being detached from the insulator when the conductive member is pulled out from the conductive member insertion hole while suppressing the increase in the size of the rotating shaft in the axial direction.

Moreover, about the said electric compressor, it is preferable that the said control part is provided in the said engaging part.
According to this, compared with the case where a control part is provided separately from an engaging part, the structure of an insulator can be simplified.

  ADVANTAGE OF THE INVENTION According to this invention, it can control that a cluster block remove | deviates from an insulator, when pulling out a conductive member from a conductive member insertion hole, suppressing the enlargement to the axial direction of a rotating shaft.

The side sectional view showing the electric compressor in a 1st embodiment. The perspective view of a stator and a cluster block. The disassembled perspective view of a stator and a cluster block. The perspective view of a cluster block. The front view of an electric motor and a cluster block. XX sectional drawing in FIG. The perspective view of the cluster block in 2nd Embodiment. The perspective view of a 2nd insulator. The front view of an electric motor and a cluster block. The YY sectional view taken on the line in FIG.

(First embodiment)
Hereinafter, a first embodiment embodying an electric compressor will be described with reference to FIGS.
As shown in FIG. 1, the housing 11 of the electric compressor 10 is connected to a motor housing 12 having a bottomed cylindrical shape in which an opening 12 a is formed at one end (left end in FIG. 1), and one end of the motor housing 12. A discharge housing 13 having a bottomed cylindrical shape. A bottomed cylindrical inverter cover 14 is attached to the bottom wall 121 of the motor housing 12. A discharge chamber S <b> 1 is defined between the motor housing 12 and the discharge housing 13. A discharge port 15 is formed on the bottom wall of the discharge housing 13, and an external refrigerant circuit (not shown) is connected to the discharge port 15. A suction port (not shown) is formed in the peripheral wall 122 of the motor housing 12, and an external refrigerant circuit is connected to the suction port.

  A rotating shaft 16 is accommodated in the motor housing 12. Further, the motor housing 12 accommodates a compression portion 17 that compresses the refrigerant and an electric motor 18 that drives the compression portion 17. The electric motor 18 drives the rotary shaft 16. The compression unit 17 is driven by the rotation of the rotating shaft 16. The electric motor 18 is disposed closer to the bottom wall 121 (right side in FIG. 1) of the motor housing 12 than the compression portion 17.

  A shaft support member 19 is provided between the compression portion 17 and the electric motor 18 in the motor housing 12. An insertion hole 19 a through which one end of the rotating shaft 16 is inserted is formed at the center of the shaft support member 19. A radial bearing 16 a is provided between the insertion hole 19 a and one end of the rotating shaft 16. One end of the rotating shaft 16 is rotatably supported by the shaft support member 19 via a radial bearing 16a.

  A bearing 121 a is recessed in the bottom wall 121 of the motor housing 12. The other end of the rotating shaft 16 is inserted inside the bearing 121a. A radial bearing 16 b is provided between the bearing portion 121 a and the other end portion of the rotating shaft 16. The other end portion of the rotating shaft 16 is rotatably supported by the bearing portion 121a via a radial bearing 16b.

  Further, the accommodation space S <b> 2 is partitioned by the bottom wall 121 of the motor housing 12 and the inverter cover 14. A motor drive circuit 20 (indicated by a two-dot chain line in FIG. 1) for driving the electric motor 18 is attached to the outer surface of the bottom wall 121 in the accommodation space S2. Therefore, in this embodiment, the compression part 17, the electric motor 18, and the motor drive circuit 20 are arrange | positioned along with the direction (axial direction) where the axis line L of the rotating shaft 16 extends in this order.

  The compression unit 17 includes a fixed scroll 17a fixed in the motor housing 12, and a movable scroll 17b disposed to face the fixed scroll 17a. A compression chamber S3 whose volume can be changed is defined between the fixed scroll 17a and the movable scroll 17b.

The electric motor 18 includes a cylindrical stator 21 and a cylindrical rotor 22 disposed inside the stator 21. The rotor 22 rotates integrally with the rotating shaft 16.
As shown in FIGS. 2 and 3, the stator 21 includes a stator core 23. The stator core 23 includes a cylindrical core base 24 fixed to the inner peripheral surface of the motor housing 12, and a plurality of teeth 25 extending radially inward from the inner peripheral surface of the core base 24. The plurality of teeth 25 are formed at equal intervals in the circumferential direction of the rotating shaft 16. The end surface of each tooth 25 opposite to the core base 24 extends along the outer peripheral surface of the rotor 22. In addition, a pair of core side flanges 26 projecting on both sides in the circumferential direction of the core base 24 are formed at the ends of the teeth 25 opposite to the core base 24. The stator core 23 has a slot open 27 that is a gap between the core side flanges 26 adjacent to each other in the circumferential direction of the core base 24. The dimensions of the teeth 25 in the axial direction of the rotating shaft 16 are the same as the dimensions of the core base 24 in the axial direction of the rotating shaft 16. Further, the dimension of the stator core 23 in the axial direction of the rotating shaft 16 is longer than the dimension of the rotor 22 in the axial direction of the rotating shaft 16.

  As shown in FIG. 1, the stator 21 includes an annular first insulator 31 and a second insulator 32. The circumferential directions of the first insulator 31 and the second insulator 32 coincide with the circumferential direction of the rotating shaft 16. The first insulator 31 is disposed so as to be adjacent to the one end surface 23 a on the compression portion 17 side of the stator core 23 in the axial direction of the rotating shaft 16, and the second insulator 32 is the other end surface 23 b of the stator core 23 on the motor drive circuit 20 side. Are arranged next to each other. Therefore, the stator core 23 is sandwiched between the first insulator 31 and the second insulator 32 in the axial direction of the rotating shaft 16.

  As shown in FIG. 3, each of the first insulator 31 and the second insulator 32 includes a cylindrical base portion 33 and a plurality of columnar extending portions 34 extending radially inward from the inner peripheral surface of the base portion 33. With. The plurality of extending portions 34 are formed at equal intervals in the circumferential direction of the base portion 33. The number of extending portions 34 is the same as the number of teeth 25. Of the end faces in the axial direction of the base 33 of the first insulator 31, the end face opposed to the one end face 23a of the stator core 23 is the first end face 33a, and the end face opposite to the first end face 33a is the second end face 33b. To do. Of the end face in the axial direction of the base 33 of the second insulator 32, the end face opposed to the other end face 23b of the stator core 23 is a first end face 33a, and the end face opposite to the first end face 33a is the second end face. 33b. The end on the base 33 side in each extending portion 34 is continuous with the end on the first end surface 33 a side on the inner peripheral surface of the base 33.

  A plate-like insulator side flange 35 that protrudes toward the second end face 33 b in the axial direction of the base 33 is formed at the end of each extension 34 opposite to the base 33. An inner peripheral surface 35 a that is a surface opposite to the base portion 33 in each insulator-side flange portion 35 is a curved surface that protrudes toward the base portion 33, and is positioned on the rotor 22 side in the first insulator 31 and the second insulator 32. It is a surrounding surface. In the circumferential direction of the base portion 33, the width of the insulator side flange portion 35 is wider than the width of the extending portion 34. The first insulator 31 and the second insulator 32 have an opening 36 that is a gap between the edge portions 35 b of the insulator-side flange portions 35 that are adjacent to each other in the circumferential direction of the base portion 33. The edge portion 35 b extends in the axial direction of the base portion 33. Therefore, the edge portions 35b of the insulator side flange portions 35 adjacent to each other in the circumferential direction of the base portion 33 extend in parallel to each other.

  In the axial direction of the rotating shaft 16, the stator core 23, the first insulator 31 and the second insulator 32 are such that the core base 24 and the base portion 33 are opposed to each other, and the teeth 25 and the extending portion 34 are opposed to each other. The insulator side flange portion 35 is disposed so as to extend in a direction away from the stator core 23 in the axial direction of the rotating shaft 16. Further, in the axial direction of the rotating shaft 16, the openings 36 of the first insulator 31 and the openings 36 of the second insulator 32 are continuous with the slot openings 27 of the stator core 23. Therefore, when viewed from the axial direction of the rotating shaft 16, the openings 36 of the first insulator 31, the openings 36 of the second insulator 32, and the slot openings 27 of the stator core 23 communicate with each other.

  As shown in FIGS. 1 and 2, in the stator 21, the conductive wires are wound in a concentrated manner around the teeth 25 of the stator core 23, the extended portions 34 of the first insulator 31, and the extended portions 34 of the second insulator 32. A plurality of coils 28 formed by being rotated are provided. The coils 28 adjacent to each other in the circumferential direction of the core base 24 and the base 33 are in different phases (U phase, V phase, W phase). A part of each coil 28 passes through a first space 25 a (see FIG. 3) formed between the teeth 25 adjacent in the circumferential direction of the core base 24. Each coil 28 includes a first coil end 281 protruding from the first space 25a on the one end surface 23a side of the stator core 23, and a second coil end 282 protruding from the first space 25a on the other end surface 23b side of the stator core 23. have.

  The first coil end 281 includes a second space 34 a (see FIG. 3) formed between the extending portions 34 adjacent to each other in the circumferential direction of the base portion 33 of the first insulator 31, and a base portion 33 in the radial direction of the base portion 33. Between the inner peripheral surface and the insulator-side flange portion 35 and through a space located on the opposite side of the extension portion 34 from the teeth 25. The second coil end 282 includes a second space 34 a (see FIG. 3) formed between the extending portions 34 adjacent to each other in the circumferential direction of the base portion 33 of the second insulator 32, and a base portion 33 in the radial direction of the base portion 33. Between the inner peripheral surface and the insulator-side flange portion 35 and through a space located on the opposite side of the extension portion 34 from the teeth 25.

  For example, the coil 28 formed by winding a conductive wire around the tooth 25 and the extending portion 34 includes, for example, a wire winding nozzle, a slot open 27 of the stator core 23, an opening 36 of the first insulator 31, and a second insulator 32. The conductive wire is wound around the teeth 25 and the extension portion 34 by concentrated winding while passing through the opening 36. Further, there is a case where the coil 28 in which the conductor is wound in an annular shape is inserted into the first space 25a and the second space 34a via the slot opening 27 and the opening 36 without using the conductor winding nozzle. .

  A portion of the coil 28 that passes through the first space 25a is insulated from the stator core 23 by an insulating sheet (not shown). The first coil end 281 and the second coil end 282 of each coil 28 are in contact with the base portions 33 of the first insulator 31 and the second insulator 32, thereby restricting the movement of the base portion 33 in the radial direction. Further, the first coil end 281 and the second coil end 282 of each coil 28 come into contact with the insulator-side flange portion 35 of the first insulator 31 and the second insulator 32, so that the base 33 is moved inward in the radial direction. It is regulated. The first coil end 281 is insulated from the teeth 25 of the stator core 23 by the extending portion 34 of the first insulator 31. The second coil end 282 is insulated from the teeth 25 of the stator core 23 by the extension 34 of the second insulator 32.

  From the second coil end 282 of the U-phase, V-phase, and W-phase coils 28, one end of the conducting wire is drawn out one by one. And the motor wiring 28a pulled out from the 2nd coil end 282 is formed by putting together the one end part of each conducting wire for every phase. The other end portions of the conducting wires are drawn out one by one from the second coil ends 282 of the U-phase, V-phase, and W-phase coils 28, and the other end portions of the conducting wires of the respective phases are connected to a neutral point (not shown). Are electrically connected to each other.

  As shown in FIG. 3, a claw portion 37 as an engaging portion is provided on the inner peripheral surface 35 a of one insulator side flange portion 35 among the plurality of insulator side flange portions 35 included in the second insulator 32. Yes. The claw portion 37 includes an upright portion 371 as a flat plate-like restricting portion that rises radially inward from the inner peripheral surface 35a of the insulator-side flange portion 35, and an end of the upright portion 371 opposite to the inner peripheral surface 35a. And an elongated thin plate-like insertion portion 372 extending in a direction approaching the stator core 23 in the axial direction of the rotary shaft 16 from the portion. The end portion on the inner peripheral surface 35 a side of the standing portion 371 is continuous with the edge portion on the second end surface 33 b side of the base portion 33 on the inner peripheral surface 35 a of the insulator-side flange portion 35.

  The insertion portion 372 has a hook shape in which a locking piece 373 that protrudes toward the inner peripheral surface 35 a of the insulator side flange 35 is formed at the end of the insertion portion 372 opposite to the standing portion 371. The locking piece 373 has an inclined guide portion 373a. The guide portion 373a is a slope that gradually approaches the inner peripheral surface 35a of the insulator-side flange 35 as it goes from the end on the locking piece 373 side of the insertion portion 372 toward the end on the upright portion 371 side.

  As shown in FIG. 1, a through hole 121 b is formed in the bottom wall 121 of the motor housing 12. An airtight terminal 40 is disposed in the through hole 121b. The hermetic terminal 40 has three conductive members 41 (only one is shown in FIG. 1) corresponding to the U-phase, V-phase, and W-phase coils 28. Each conductive member 41 is a columnar metal terminal extending linearly, and is inserted through the through hole 121b. One end of each conductive member 41 is electrically connected to the motor drive circuit 20 in the accommodation space S2. The other end of each conductive member 41 protrudes into the motor housing 12. In addition, the airtight terminal 40 includes a glass insulating member 42 that fixes each conductive member 41 while being insulated from the bottom wall 121.

  A connector 50 is accommodated in the motor housing 12. The connector 50 includes three connection terminals 51 (only one is shown in FIG. 1) corresponding to the U-phase, V-phase, and W-phase coils 28, and an insulating cluster block 52 that accommodates the three connection terminals 51. I have. The cluster block 52 is disposed inside the second insulator 32 in the radial direction of the rotating shaft 16. The cluster block 52 is disposed adjacent to one end surface of the rotor 22 on the motor drive circuit 20 side in the axial direction of the rotating shaft 16.

  As shown in FIGS. 2 to 4, the cluster block 52 has a flat box shape. The cluster block 52 includes a pair of flat walls 52a and a connecting wall 52b that connects the pair of flat walls 52a. The connecting wall 52b includes a planar first wall 52c, a curved second wall 52d along the inner peripheral surface 35a of the insulator side flange 35, and a stepped third wall 52e. Have. The third wall portion 52e connects the first wall portion 52c and the second wall portion 52d.

  As shown in FIG. 1, an accommodating portion 53 that accommodates the connection terminal 51 is formed inside the cluster block 52. Further, as shown in FIG. 2, three motor wiring insertion holes 54 are formed in the third wall portion 52 e of the cluster block 52. The end of each motor wiring 28 a drawn out from the coil 28 is inserted into each motor wiring insertion hole 54. Each motor wiring 28 a inserted through each motor wiring insertion hole 54 is electrically connected to the connection terminal 51. Further, three conductive member insertion holes 55 into which the conductive member 41 is inserted are formed in one of the pair of flat walls 52 a of the cluster block 52. Hereinafter, the direction in which the conductive member 41 is inserted into the conductive member insertion hole 55 and the direction in which the conductive member 41 is withdrawn from the conductive member insertion hole 55 are referred to as the direction in which the conductive member 41 is inserted into and extracted from the conductive member insertion hole 55. The connecting wall 52 b extends along the direction in which the conductive member 41 is inserted and removed from the conductive member insertion hole 55.

  As shown in FIG. 4, a mounting wall portion 56 as an engaging portion for connecting the cluster block 52 to the second insulator 32 is formed on the outer surface of the second wall portion 52 d of the cluster block 52. The mounting wall portion 56 has a pair of flat plate-like standing walls 56a erected from the outer surface of the second wall portion 52d, and a flat plate-like connection wall 56b that connects the tip portions of the pair of standing walls 56a. . The pair of standing walls 56a extend parallel to each other. A claw portion insertion hole 57 into which the insertion portion 372 of the claw portion 37 is inserted is formed by the outer surface of the second wall portion 52d, the inner surfaces of the pair of standing walls 56a, and the inner surface of the connection wall 56b. Therefore, the attachment wall portion 56 forms the claw portion insertion hole 57. The claw portion insertion hole 57 of the present embodiment penetrates in the direction in which the conductive member 41 is inserted into and removed from the conductive member insertion hole 55.

  As shown in FIGS. 5 and 6, the cluster block 52 and the second insulator 32 are connected to each other by inserting the insertion portion 372 of the claw portion 37 into the claw portion insertion hole 57 formed by the mounting wall portion 56. Has been.

  As a method of connecting the second insulator 32 and the cluster block 52, first, one claw portion insertion hole 57 is engaged with the claw portion 37 in the direction in which the conductive member 41 is inserted into and removed from the conductive member insertion hole 55. The cluster block 52 is disposed inside the second insulator 32 so as to face the piece 373. Next, the cluster block 52 is moved with respect to the second insulator 32 in the direction in which the conductive member 41 is inserted and removed with respect to the conductive member insertion hole 55 so that the attachment wall portion 56 approaches the claw portion 37. Then, the connection wall 56b of the attachment wall portion 56 is guided toward the space between the inner peripheral surface 35a of the insulator side flange portion 35 and the insertion portion 372 by the guide portion 373a of the locking piece 373 of the claw portion 37. In addition, the claw portion 37 is elastically deformed toward the inside in the radial direction of the base portion 33. When the attachment wall portion 56 gets over the locking piece 373, the insertion portion 372 is inserted into the claw portion insertion hole 57. The claw portion 37 that has been elastically deformed radially inward of the base portion 33 is inserted into the claw portion insertion hole 57 and then returns to the original position before elastic deformation.

  In the direction in which the conductive member 41 is inserted into and removed from the conductive member insertion hole 55, the distance between the standing portion 371 of the second insulator 32 and the locking piece 373 is longer than the dimension of the connection wall 56 b of the cluster block 52. Therefore, the cluster block 52 and the second insulator 32 are relatively movable while being connected to each other. The standing portion 371 of the claw portion 37 is located on the side of the direction in which the conductive member 41 is pulled out from the conductive member insertion hole 55 with respect to the connection wall 56 b that is a part of the mounting wall portion 56 of the cluster block 52. The connection wall 56 b faces the upright portion 371 in the direction in which the conductive member 41 is inserted into and removed from the conductive member insertion hole 55. Thereby, the movement of the cluster block 52 with respect to the second insulator 32 in the direction in which the conductive member 41 is pulled out from the conductive member insertion hole 55 is restricted. Further, the connection wall 56 b which is a part of the mounting wall portion 56 faces the locking piece 373 in the direction in which the conductive member 41 is inserted into and removed from the conductive member insertion hole 55. Thereby, the movement of the cluster block 52 with respect to the second insulator 32 in the direction in which the conductive member 41 is inserted into the conductive member insertion hole 55 is restricted.

  The second wall portion 52 d of the cluster block 52 faces the inner peripheral surface 35 a of the insulator side flange portion 35 of the second insulator 32 in the radial direction of the rotating shaft 16. That is, the cluster block 52 is disposed inside the second insulator 32 in the radial direction of the rotating shaft 16. One of the pair of flat walls 52 a of the cluster block 52 is positioned on the motor drive circuit 20 side in the axial direction of the rotating shaft 16, and the other is positioned on the rotor 22 side in the axial direction of the rotating shaft 16. A gap is provided between the cluster block 52 and the rotor 22 in the axial direction of the rotary shaft 16. Thereby, the contact of the cluster block 52 with the rotor 22 is regulated.

  The other end of each conductive member 41 is inserted into each conductive member insertion hole 55 of the cluster block 52 connected to the second insulator 32 and electrically connected to each connection terminal 51. That is, in the cluster block 52, each motor wiring 28 a and each conductive member 41 are electrically connected via each connection terminal 51. Thereby, the electric motor 18 and the motor drive circuit 20 are electrically connected via each motor wiring 28a, each connection terminal 51, and each conductive member 41. Then, electric power is supplied from the motor drive circuit 20 to the electric motor 18 via the conductive members 41, the connection terminals 51, and the motor wirings 28a, whereby the electric motor 18 is driven and the electric motor 18 is driven. Due to the rotation of the rotating shaft 16, the compressor 17 is driven and the refrigerant is compressed by the compressor 17.

Next, the effect of 1st Embodiment is described with an effect | action.
(1-1) The cluster block 52 and the second insulator 32 are connected so as to be relatively movable by inserting the insertion portion 372 of the claw portion 37 into the claw portion insertion hole 57. In a state where the cluster block 52 and the second insulator 32 are connected, the second wall portion 52d of the cluster block 52 is connected to the inner peripheral surface 35a of the insulator-side flange portion 35 of the second insulator 32 in the radial direction of the rotating shaft 16. Opposite. For this reason, compared with the case where the cluster block is arranged adjacent to the coil in the axial direction of the rotating shaft as in the prior art, the side opposite to the stator core 23 in the second insulator 32 in the axial direction of the rotating shaft 16. The part which protrudes from the edge part of this is reduced. Therefore, the enlargement of the electric compressor 10 in the axial direction of the rotating shaft 16 can be suppressed.

  In addition, in the state where the cluster block 52 and the second insulator 32 are connected, when an assembly failure occurs or maintenance is performed, if the conductive member 41 is pulled out from the conductive member insertion hole 55, the cluster block 52 is The conductive member 41 is about to be pulled out from the conductive member insertion hole 55. Specifically, when the conductive member 41 is to be pulled out from the conductive member insertion hole 55, the connection terminal 51 moves in the direction of pulling out the conductive member 41 from the conductive member insertion hole 55, and the inner wall of the housing portion 53 of the cluster block 52 is moved. Pressed against. Then, when the extraction of the conductive member 41 from the conductive member insertion hole 55 is continued in a state where the connection terminal 51 is pressed against the inner wall of the cluster block 52, the cluster block 52 is connected to the conductive member 41 from the conductive member insertion hole 55. Try to move in the direction of pulling out.

  At this time, the connection wall 56 b of the mounting wall portion 56 contacts the upright portion 371 of the claw portion 37, and the claw portion 37 receives a load from the cluster block 52. Thereby, the movement of the cluster block 52 with respect to the second insulator 32 in the direction in which the conductive member 41 is pulled out from the conductive member insertion hole 55 is restricted. As a result, it is possible to restrict the cluster block 52 from being detached from the second insulator 32. From the above, it is possible to restrict the cluster block 52 from being detached from the second insulator 32 when the conductive member 41 is pulled out from the conductive member insertion hole 55 while suppressing an increase in the size of the rotating shaft 16 in the axial direction.

  (1-2) The standing portion 371 that is a part of the claw portion 37 also serves as a restriction portion that restricts the movement of the cluster block 52 relative to the second insulator 32 in the direction in which the conductive member 41 is pulled out from the conductive member insertion hole 55. Yes. Therefore, the configuration of the second insulator 32 can be simplified as compared with the case where the restricting portion is provided in the insulator side flange portion 35 different from the insulator side flange portion 35 provided with the claw portion 37.

  (1-3) Since the claw portion 37 includes the locking piece 373, even if the cluster block 52 tries to move in the direction in which the conductive member 41 is inserted into the conductive member insertion hole 55, the connection wall of the mounting wall portion 56 56 b contacts the locking piece 373 of the claw portion 37, and the claw portion 37 receives a load from the cluster block 52. For this reason, the movement of the cluster block 52 relative to the second insulator 32 in the direction in which the conductive member 41 is inserted into the conductive member insertion hole 55 is suppressed. Therefore, it is possible to prevent the cluster block 52 from being detached from the second insulator 32.

  (1-4) When the conductive member 41 is to be inserted into the conductive member insertion hole 55 in a state where the cluster block 52 and the second insulator 32 are coupled, the cluster block 52 causes the conductive member 41 to be inserted into the conductive member insertion hole 55. Try to move in the direction of insertion. At this time, the connection wall 56 b of the mounting wall portion 56 contacts the locking piece 373 of the claw portion 37, and the claw portion 37 receives a load from the cluster block 52. Thereby, the movement of the cluster block 52 in the direction in which the conductive member 41 is inserted into the conductive member insertion hole 55 is suppressed. As a result, the cluster block 52 can be prevented from being detached from the second insulator 32. Therefore, the cluster block 52 can be prevented from being detached from the second insulator 32 when the conductive member 41 is inserted into the conductive member insertion hole 55.

  (1-5) The locking piece 373 of the claw portion 37 has a guide portion 373a. When the cluster block 52 is connected to the second insulator 32, the mounting wall portion 56 of the cluster block 52 is guided toward the space between the inner peripheral surface 35a of the insulator side flange 35 and the insertion portion 372 by the guide portion 373a. Therefore, the insertion part 372 of the claw part 37 can be easily inserted into the claw part insertion hole 57. Therefore, it becomes easy to connect the cluster block 52 to the second insulator 32.

(Second Embodiment)
Hereinafter, a second embodiment in which the electric compressor is embodied will be described with reference to FIGS. In addition, about the structure same as 1st Embodiment, while attaching | subjecting the same code | symbol as 1st Embodiment, description is abbreviate | omitted.

  As shown in FIG. 7, a claw portion 58 as an engaging portion is provided on the outer surface of the second wall portion 52 d of the cluster block 52. The claw portion 58 has a flat plate-like standing portion 581 that rises from the outer surface of the second wall portion 52d, and an end portion of the standing portion 581 that is opposite to the second wall portion 52d. And a long and thin plate-like insertion portion 582 extending in the direction of pulling out. The nail | claw part 58 is located in the one flat wall 52a side.

  The insertion portion 582 has a bowl shape in which a locking piece 583 protruding toward the outer surface of the second wall portion 52d is formed at the end of the insertion portion 582 opposite to the upright portion 581. The locking piece 583 has an inclined guide portion 583a. The guide portion 583a is a slope that gradually approaches the outer surface of the second wall portion 52d as it goes from the end portion on the locking piece 583 side of the insertion portion 582 toward the end portion on the upright portion 581 side.

  As shown in FIG. 8, among the plurality of insulator side flanges 35 included in the second insulator 32, the cluster block 52 is connected to the second insulator 32 on the inner peripheral surface 35 a of one insulator side flange 35. A mounting wall portion 38 is formed as an engaging portion. The mounting wall portion 38 is a flat plate-shaped plate that connects a pair of flat plate-like standing walls 38a that are erected radially inward from the inner peripheral surface 35a of the insulator-side flange portion 35, and tip portions of the pair of standing walls 38a. And a connecting wall 38b as a restricting portion. The pair of standing walls 38a extend in parallel to each other. And the nail | claw part insertion hole 39 in which the insertion part 582 is inserted is formed by the inner peripheral surface 35a of the insulator side collar part 35, the inner surface of a pair of standing wall 38a, and the inner surface of the connection wall 38b. Therefore, the attachment wall portion 38 forms a claw portion insertion hole 39. The claw insertion hole 39 of the present embodiment penetrates in the axial direction of the base 33.

  As shown in FIGS. 9 and 10, the cluster block 52 and the second insulator 32 are connected to each other by inserting the insertion portion 582 of the claw portion 58 into the claw portion insertion hole 39 formed by the mounting wall portion 38. Is done.

  As a method of connecting the second insulator 32 and the cluster block 52, first, the claw portion 58 is locked in the direction in which one opening of the claw portion insertion hole 39 inserts and removes the conductive member 41 with respect to the conductive member insertion hole 55. The cluster block 52 is arranged inside the second insulator 32 so as to face the piece 583. Next, the cluster block 52 is moved with respect to the second insulator 32 in the direction in which the conductive member 41 is inserted / removed with respect to the conductive member insertion hole 55 so that the claw portion 58 approaches the mounting wall portion 38. Then, the claw portion 58 is guided toward the claw portion insertion hole 39 by the guide portion 583a of the locking piece 583, and is elastically deformed in a direction away from the second wall portion 52d. Then, the insertion portion 582 is inserted into the claw portion insertion hole 39. The claw portion 58 that has been elastically deformed in the direction away from the second wall portion 52d is inserted into the claw portion insertion hole 39, and then returns to the original position before elastic deformation.

  In the direction in which the conductive member 41 is inserted into and removed from the conductive member insertion hole 55, the distance between the standing portion 581 of the cluster block 52 and the locking piece 583 is longer than the dimension of the connection wall 38 b of the second insulator 32. Therefore, the cluster block 52 and the second insulator 32 are relatively movable while being connected to each other. The connection wall 38 b, which is a part of the mounting wall portion 38 of the second insulator 32, is located on the side in the direction of pulling out the conductive member 41 from the conductive member insertion hole 55 with respect to the standing portion 581 of the claw portion 58 of the cluster block 52. The upright portion 581 faces the connection wall 38 b in the direction in which the conductive member 41 is inserted into and removed from the conductive member insertion hole 55. Thereby, the movement of the cluster block 52 with respect to the second insulator 32 in the direction in which the conductive member 41 is pulled out from the conductive member insertion hole 55 is restricted. Further, the locking piece 583 of the claw portion 58 of the cluster block 52 is opposed to the connection wall 38 b which is a part of the mounting wall portion 38 of the second insulator 32 in the direction in which the conductive member 41 is inserted into and removed from the conductive member insertion hole 55. is doing. Thereby, the movement of the cluster block 52 with respect to the second insulator 32 in the direction in which the conductive member 41 is inserted into the conductive member insertion hole 55 is restricted.

  The second wall portion 52 d of the cluster block 52 faces the inner peripheral surface 35 a of the insulator side flange portion 35 of the second insulator 32 in the radial direction of the rotating shaft 16. That is, the cluster block 52 is disposed inside the second insulator 32 in the radial direction of the rotating shaft 16. One of the pair of flat walls 52 a of the cluster block 52 is positioned on the motor drive circuit 20 side in the axial direction of the rotating shaft 16, and the other is positioned on the rotor 22 side in the axial direction of the rotating shaft 16. A gap is provided between the cluster block 52 and the rotor 22 in the axial direction of the rotary shaft 16. Thereby, the contact of the cluster block 52 with the rotor 22 is regulated.

Next, the effect of 2nd Embodiment is described with an effect | action.
(2-1) The cluster block 52 and the second insulator 32 are connected so as to be relatively movable by inserting the insertion portion 582 of the claw portion 58 into the claw portion insertion hole 39. In a state where the cluster block 52 and the second insulator 32 are connected, the second wall portion 52d of the cluster block 52 is connected to the inner peripheral surface 35a of the insulator-side flange portion 35 of the second insulator 32 in the radial direction of the rotating shaft 16. Opposite. For this reason, compared with the case where the cluster block is arranged adjacent to the coil in the axial direction of the rotating shaft as in the prior art, the side opposite to the stator core 23 in the second insulator 32 in the axial direction of the rotating shaft 16. The part which protrudes from the edge part of this is reduced. Therefore, the enlargement of the electric compressor 10 in the axial direction of the rotating shaft 16 can be suppressed.

  In addition, in the state where the cluster block 52 and the second insulator 32 are connected, when an assembly failure occurs or maintenance is performed, if the conductive member 41 is pulled out from the conductive member insertion hole 55, the cluster block 52 is The conductive member 41 is about to be pulled out from the conductive member insertion hole 55. Specifically, when the conductive member 41 is to be pulled out from the conductive member insertion hole 55, the connection terminal 51 moves in the direction of pulling out the conductive member 41 from the conductive member insertion hole 55, and the inner wall of the housing portion 53 of the cluster block 52 is moved. Pressed against. Then, when the extraction of the conductive member 41 from the conductive member insertion hole 55 is continued in a state where the connection terminal 51 is pressed against the inner wall of the cluster block 52, the cluster block 52 is connected to the conductive member 41 from the conductive member insertion hole 55. Try to move in the direction of pulling out.

  At this time, the upright portion 581 of the claw portion 58 comes into contact with the connection wall 38 b of the attachment wall portion 38, and the attachment wall portion 38 receives a load from the cluster block 52. Thereby, the movement of the cluster block 52 with respect to the second insulator 32 in the direction in which the conductive member 41 is pulled out from the conductive member insertion hole 55 is restricted. As a result, it is possible to restrict the cluster block 52 from being detached from the second insulator 32. From the above, it is possible to restrict the cluster block 52 from being detached from the second insulator 32 when the conductive member 41 is pulled out from the conductive member insertion hole 55 while suppressing an increase in the size of the rotating shaft 16 in the axial direction.

  (2-2) The connection wall 38b, which is a part of the mounting wall portion 38, also serves as a restriction portion that restricts the movement of the cluster block 52 relative to the second insulator 32 in the direction in which the conductive member 41 is pulled out from the conductive member insertion hole 55. ing. Therefore, the configuration of the second insulator 32 can be simplified as compared with the case where the restricting portion is provided in the insulator side flange portion 35 different from the insulator side flange portion 35 provided with the attachment wall portion 38.

  (2-3) Since the claw portion 58 includes the locking piece 583, even if the cluster block 52 tries to move in the direction in which the conductive member 41 is inserted into the conductive member insertion hole 55, the locking piece of the claw portion 58 583 contacts the connecting wall 38 b of the mounting wall 38, and the mounting wall 38 receives a load from the cluster block 52. For this reason, the movement of the cluster block 52 in the direction in which the conductive member 41 is inserted into the conductive member insertion hole 55 is suppressed. Therefore, it is possible to prevent the cluster block 52 from being detached from the second insulator 32.

  (2-4) When the conductive member 41 is to be inserted into the conductive member insertion hole 55 in a state where the cluster block 52 and the second insulator 32 are coupled, the cluster block 52 causes the conductive member 41 to be inserted into the conductive member insertion hole 55. Try to move in the direction of insertion. At this time, the locking piece 583 of the claw 58 comes into contact with the connection wall 38 b of the mounting wall 38, and the mounting wall 38 receives a load from the cluster block 52. Thereby, the movement of the cluster block 52 in the direction in which the conductive member 41 is inserted into the conductive member insertion hole 55 is suppressed. As a result, the cluster block 52 can be prevented from being detached from the second insulator 32. Therefore, the cluster block 52 can be prevented from being detached from the second insulator 32 when the conductive member 41 is inserted into the conductive member insertion hole 55.

  (2-5) The locking piece 583 of the claw portion 58 has a guide portion 583a. When the cluster block 52 is connected to the second insulator 32, the claw portion 58 of the cluster block 52 is guided to the claw portion insertion hole 39 of the second insulator 32 by the guide portion 583a. It becomes easy to insert into the claw portion insertion hole 39. Therefore, it becomes easy to connect the cluster block 52 to the second insulator 32.

In addition, you may change each said embodiment as follows.
In each of the above embodiments, the inner peripheral surface 35a as the peripheral surface on the rotor 22 side in the second insulator 32 is not limited to a curved surface, and may be a flat surface.

  In the first embodiment, the standing portion 371 that is a part of the claw portion 37 also serves as a restriction portion, but is restricted to an insulator side flange portion 35 that is different from the insulator side flange portion 35 provided with the claw portion 37. A part may be provided. For example, the restricting portion may be a protruding portion that protrudes from the inner peripheral surface 35a of the insulator-side flange portion 35. In a state where the second insulator 32 and the cluster block 52 are connected, the protrusion is located on the side of the cluster block 52 in the direction of pulling out the conductive member 41 from the conductive member insertion hole 55.

  ○ In the second embodiment, the connection wall 38b, which is a part of the mounting wall portion 38, also serves as a restricting portion, but the insulator side flange portion 35 is different from the insulator side flange portion 35 provided with the mounting wall portion 38. You may provide a control part. For example, the restricting portion may be a protruding portion that protrudes from the inner peripheral surface 35a of the insulator-side flange portion 35. In a state where the second insulator 32 and the cluster block 52 are connected, the protrusion is positioned on the side of the cluster block 52 in the direction of pulling out the conductive member 41 from the conductive member insertion hole 55.

In the first embodiment, the locking piece 373 may not be provided with the guide portion 373a and may be planar.
In the second embodiment, the locking piece 583 does not include the guide portion 583a and may be planar.

In the first embodiment, the locking piece 373 of the claw portion 37 may be omitted.
In the second embodiment, the locking piece 583 of the claw portion 58 may be omitted.
In the first embodiment, the number of the claw portions 37 formed on the second insulator 32 and the number of the attachment wall portions 56 formed on the cluster block 52 may each be two or more.

In the second embodiment, the number of attachment wall portions 38 formed on the second insulator 32 and the number of claw portions 58 formed on the cluster block 52 may be two or more, respectively.
In the first embodiment, when the locking piece 373 is not formed, the claw portion insertion hole 57 located on the side opposite to the upright portion 371 in the direction in which the conductive member 41 is inserted into and removed from the conductive member insertion hole 55. The opening may be closed.

  In the second embodiment, when the locking piece 583 is not formed, the claw portion insertion hole 39 located on the opposite side of the standing portion 581 in the direction of inserting and removing the conductive member 41 with respect to the conductive member insertion hole 55. The opening may be closed.

  In the above embodiments, the shape of the cluster block 52 may be changed as appropriate. For example, the first wall 52c may be a curved surface instead of a flat surface, the second wall 52d may be a flat surface instead of a curved surface, or the third wall 52e may be Instead of a stepped shape, it may be a planar shape.

  In each of the above embodiments, the electric motor 18 may be an outer rotor type electric motor including a cylindrical stator and a rotor disposed outside the stator. Even in this case, the cluster block 52 and the second insulator 32 have engaging portions that connect each other so as to be relatively movable. The second insulator 32 has a restricting portion that restricts the movement of the cluster block 52 with respect to the second insulator 32 in the direction in which the conductive member 41 is pulled out from the conductive member insertion hole 55. The cluster block 52 faces the outer peripheral surface of the base 33 that is the peripheral surface of the second insulator 32 on the rotor 22 side in the radial direction of the rotating shaft 16. That is, the cluster block 52 is disposed outside the second insulator 32 in the radial direction of the rotating shaft 16.

In each of the above embodiments, the number of phases of the coil 28 may be changed.
In each of the above embodiments, the coil 28 may be formed by winding a conductive wire around the tooth 25 and the extending portion 34 with distributed winding.

  In each of the above embodiments, the compression unit 17, the electric motor 18, and the motor drive circuit 20 may not be arranged along the axis L of the rotating shaft 16 in this order. For example, the inverter cover 14 is attached to the peripheral wall 122 of the motor housing 12, and a space defined by the peripheral wall 122 of the motor housing 12 and the inverter cover 14 is defined as a storage space S2, and the motor drive circuit 20 is provided in the storage space S2. It may be accommodated.

  In each of the above embodiments, the compression unit 17 is not limited to the type constituted by the fixed scroll 17a and the movable scroll 17b, and may be changed to, for example, a piston type or a vane type.

DESCRIPTION OF SYMBOLS 10 ... Electric compressor, 16 ... Rotating shaft, 17 ... Compression part, 18 ... Electric motor, 20 ... Motor drive circuit, 21 ... Stator, 22 ... Rotor, 23 ... Stator core, 28 ... Coil, 28a ... Motor wiring, 32 ... Second insulator as an insulator, 35a ... an inner peripheral surface as a peripheral surface, 37 ... a claw portion as an engaging portion, 371 ... a standing portion as a restricting portion, 38 ... a mounting wall portion as an engaging portion, 38b ... restricting Connection wall as a part 41... Conductive member 52. Cluster block 55. Conductive member insertion hole 56. Mounting wall part as an engaging part 58. Claw part as an engaging part.

Claims (2)

A rotation axis;
An electric motor for rotating the rotating shaft;
A compression section that is driven by the rotation of the rotation shaft to compress the refrigerant;
A motor drive circuit for driving the electric motor;
A conductive member electrically connected to the motor drive circuit;
An insulating cluster block in which a conductive member insertion hole into which the conductive member is inserted is formed, and a motor wiring drawn out from the electric motor and the conductive member are electrically connected inside,
With
The electric motor includes a rotor that can rotate integrally with the rotating shaft, and a stator.
The stator is an electric compressor having an annular stator core, an annular insulator disposed on an end face of the stator core, and a coil wound around the stator core and the insulator.
The cluster block and the insulator have engaging portions that connect each other so as to be relatively movable,
The insulator has a restricting portion that restricts movement of the cluster block relative to the insulator in a direction in which the conductive member is pulled out from the conductive member insertion hole.
The electric compressor according to claim 1, wherein the cluster block faces a circumferential surface on the rotor side of the insulator in a radial direction of the rotating shaft. The electric compressor according to claim 1, wherein the restricting portion is provided in the engaging portion.