JP2005233072A - Electric compressor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve assemblage precision in an electric compressor by increasing strength of a housing. <P>SOLUTION: The housing 11 is composed of a motor housing 21, a center housing 22, and a compressor housing 23. A compression part 12 to compress fluid, and an electric motor 13 to drive the compression part 12 are contained in it. The electric motor 13 is composed as a concentrated winding motor. A plurality of reinforcement ribs 32 are radially provided on the inner side of the motor housing 21 to avoid a coil end 35 of a stator 33. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  In particular, the present invention relates to an electric compressor suitable for use in an in-vehicle air conditioner or the like.

  In a conventional electric compressor, an electric motor is disposed at one end inside a hollow housing, and a scroll compression mechanism is disposed at the other end. The electric motor and the scroll compression mechanism are Are coupled to each other via a rotating shaft. That is, the electric motor is fixed by the rotor being fixed to the rotating shaft and the stator being press-fitted into the housing. The scroll compression mechanism includes a fixed scroll having a spiral wrap and a orbiting scroll having a spiral wrap, and the fixed scroll and the orbiting scroll are eccentric from each other by a predetermined distance, and 180 degrees. A plurality of compression chambers are formed by engaging the spiral wound wraps of the two while shifting the angle.

  Therefore, when the electric motor is driven, the orbiting scroll of the scroll type compression mechanism is driven through the rotating shaft, and the fluid gas is taken into the suction chamber in the housing, and this fluid gas is compressed between the spiral wraps. It is discharged after being compressed in the chamber.

  In addition, there exists patent document 1 shown below as such an electric compressor.

Japanese Utility Model Publication No. 04-075186

  In the above-described conventional electric compressor, the housing is composed of a compressor housing that houses a scroll type compression mechanism and a motor housing that houses an electric motor. The motor housing has a cup shape, and the stator of the electric motor is inserted from the open end and fixed by shrink fitting. Therefore, after the motor housing is formed by casting, the motor mounting surface on the inner peripheral surface is cut and finished. In this case, in the motor housing, the cutting tool is inserted into the inside from the open end while the outer side of the bottom portion is held, and the inner peripheral surface is cut.

  However, since the motor housing has a hollow shape, the strength of the unit before assembly is not sufficient. For this reason, when the outside of the motor housing is firmly held by the holder, the motor housing is distorted, and the inside is cut in this distorted state, resulting in a problem that the processing accuracy is lowered. In addition, a bearing portion for supporting the rotating shaft of the electric motor is formed inside the motor housing. If the strength of the motor housing itself is insufficient, the motor housing itself is distorted when heated for shrink fitting. There is also a risk of it.

  The motor housing may be divided into a cylindrical portion and a disc-shaped lid portion without using a cup shape, and the motor mounting surface may be cut while holding the inside of the cylindrical portion and not distorted. . However, when the motor housing is divided, there is a problem that the number of parts increases and the part cost and assembly cost increase.

  The present invention solves such problems, and an object of the present invention is to provide an electric compressor in which the accuracy of assembly is improved by increasing the strength of the housing.

  In order to achieve the above object, an electric compressor of the invention of claim 1 includes a housing having a hollow shape, a compression portion provided on one end side of the housing and compressing fluid sucked into the housing, In the electric compressor including an electric motor provided on the other end side of the housing and driving the compression unit, a reinforcing rib is provided on the other end side of the housing so as to avoid a coil end of the electric motor. It is characterized by that.

  In an electric compressor according to a second aspect of the present invention, the electric motor is a concentrated winding motor, and a plurality of the reinforcing ribs are provided radially between a plurality of concentrated winding stators. .

  The electric compressor according to a third aspect of the present invention is characterized in that a plurality of the reinforcing ribs are provided radially around the rotating shaft of the electric motor and symmetrically in the circumferential direction.

  In the electric compressor according to a fourth aspect of the present invention, a boss portion that supports the rotating shaft of the electric motor is provided on the other end side of the housing, and the reinforcing rib faces the inner peripheral surface of the housing from the boss portion. It is characterized by being formed in a substantially triangular shape.

  In the electric compressor according to a fifth aspect of the present invention, the stator of the electric motor is fixed to the inner peripheral surface of the housing by shrink fitting, and a gap is formed between the end of the stator and the inner peripheral surface of the housing. Is featured.

  In the electric compressor according to a sixth aspect of the present invention, the housing includes a compression portion housing that accommodates the compression portion and a motor housing that accommodates the electric motor. The motor housing has a cup shape and has an open end. An insertion guide portion larger than the outer diameter of the stator is provided from the gap to the gap.

  In an electric compressor according to a seventh aspect of the invention, the insertion guide portion is formed by a casting mold.

  According to the electric compressor of the first aspect of the present invention, the compression portion that compresses the fluid is provided on one end side of the hollow housing, and the electric motor that drives the compression portion is provided on the other end side of the housing. Reinforcing ribs are provided on the other end side to avoid the coil end of the electric motor, so the strength of the housing can be improved by the reinforcing ribs without interfering with the stored electric motor, and deformation during housing processing is suppressed. Thus, it is possible to improve the processing accuracy and the assembly accuracy of the electric motor.

  According to the electric compressor of the second aspect of the invention, the electric motor is a concentrated winding motor, and a plurality of reinforcing ribs are provided radially between the plurality of concentrated winding stators. The housing can be reinforced efficiently.

  According to the electric compressor of the invention of claim 3, since the plurality of reinforcing ribs are provided radially around the rotation shaft of the electric motor and symmetrically in the circumferential direction, the housing is effectively provided by the plurality of reinforcing ribs. Reinforcing makes it possible to reinforce uniformly while suppressing variations in strength.

  According to the electric compressor of the invention of claim 4, the boss portion for supporting the rotating shaft of the electric motor is provided on the other end side of the housing, and the reinforcing rib is formed in a substantially triangular shape from the boss portion toward the inner peripheral surface of the housing. Therefore, the inside of the housing can be reinforced three-dimensionally with a small number of members.

  According to the electric compressor of the fifth aspect of the invention, the stator of the electric motor is fixed to the inner peripheral surface of the housing by shrink fitting, and a gap is provided between the end of the stator and the inner peripheral surface of the housing. Therefore, this gap can suppress the stress concentration between the end portion of the stator and the inner peripheral surface of the housing, thereby improving the overall strength.

  According to the electric compressor of the sixth aspect of the invention, the housing is composed of the compression portion housing that accommodates the compression portion and the motor housing that accommodates the electric motor. Since the insertion guide part larger than the outer diameter is provided, the gap and the insertion guide part can be processed at the same time, and the workability can be improved.

  According to the electric compressor of the seventh aspect of the invention, since the insertion guide portion is formed by the casting mold, the gap can be easily provided without processing and without increasing the cost.

  Embodiments of an electric compressor according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

  FIG. 1 is a sectional view showing a scroll compressor as an electric compressor according to an embodiment of the present invention, and FIG. 2 is a sectional view taken along the line II-II in FIG.

  The scroll compressor according to the present embodiment is mainly used for compressing a refrigerant of a vehicle air conditioner. As shown in FIGS. 1 and 2, the scroll compressor includes a housing 11, a compression portion 12 accommodated in the housing 11, and an electric motor 13 that drives the compression portion 12. . The compression unit 12 and the electric motor 13 are conductively connected by the rotating shaft 14, and the compression unit 12 can be driven by the electric motor 13.

  The housing 11 is disposed horizontally and is configured as a sealed container having a substantially cylindrical shape that wraps the entire scroll compressor. The housing 11 includes a motor housing 21 disposed on the other end side, a center housing 22 disposed adjacent to the motor housing 21 adjacent to the right side thereof, and disposed adjacent to the center housing 22 and adjacent to the right side thereof. The compressor housing 23 is formed. The center housing 22 is sandwiched between the motor housing 21 and the compressor housing 23 and is fixed by a plurality of fastening bolts 25.

  The motor housing 21 accommodates the electric motor 13. In addition, a suction port 27 that opens toward the low-pressure chamber 26 that is a space on the right side of the electric motor 13 is provided in the upper portion of the motor housing 21. The suction port 27 opens toward the rotating shaft 14 that connects the electric motor 13 and the compression unit 12, and is formed at a position that does not face the electric motor 13 and the compression unit 12. The reason why the suction port 27 is opened so as not to face the electric motor 13 is that the refrigerant gas taken into the housing 11 from the suction port 27 rises in temperature due to the heat generated by the motor, resulting in a decrease in compression efficiency and pressure loss. This is to suppress the increase.

  The electric motor 13 housed in the motor housing 21 is a ferrite magnet concentrated winding motor. In this concentrated winding motor, a coil is directly wound around the teeth of cores of a plurality of slots to constitute a stator. Therefore, each coil end of the stator can be shortened, and the electric compressor can be miniaturized by reducing the axial length. Moreover, since the coil resistance is reduced by reducing the coil end, the efficiency of the electric compressor can be increased.

That is, the motor housing 21 has a cup shape, and an insertion guide portion 28 having a predetermined length L ₁ is formed on the inner peripheral surface along the axial direction from the opening end, and is continuous with the insertion guide portion 28. A motor mounting portion 29 is formed over a predetermined length L ₂ along the axial direction, and a cutout portion 30 is formed over the predetermined length L ₃ along the axial direction continuously with the motor mounting portion 29. . In this case, the inner diameters of the insertion guide portion 28 and the notch portion 30 are set to be substantially the same, the inner diameter of the motor mounting portion 29 is slightly smaller than the inner diameter of the insertion guide portion 28 and the notch portion 30, and slightly smaller than the inner diameter of the motor housing 21. It is set large. A boss 31 that supports the end of the rotating shaft 14 is formed in a ring shape inside the bottom of the motor housing 21 at the center. A plurality of reinforcing ribs 32 are formed radially outside the boss portion 31.

  On the other hand, the electric motor 13 has a rotor 34 provided with a predetermined gap inside a stator 33 formed in a ring shape, and the rotating shaft 14 passes through the center of the rotor 34. Coil ends 35 protrude from both sides of the stator 33 in the axial direction.

  In this case, after the motor housing 21 is manufactured by casting, the cutting tool is inserted from the open end while the outer peripheral side of the bottom portion is held, and the insertion guide portion 28, the motor mounting portion 29, and the notch portion 30 are cut. Is done. The electric motor 13 is fixed in the motor housing 21 by shrink fitting. That is, first, the motor housing 21 is heated to a predetermined temperature and thermally expanded. Next, the stator 33 of the electric motor 13 is inserted from the opening end of the motor housing 21 using the insertion guide portion 28, and the outer peripheral surface of the stator 33 is expanded and fitted to the enlarged motor mounting portion 29. At this time, the step portion between the motor attachment portion 29 and the notch portion 30 functions as a stopper, and the stator 33 is positioned. Finally, the motor housing 21 is cooled and contracted, and the stator 33 is firmly held by the motor mounting portion 29. The rotor 34 is rotatably supported at one end of the rotating shaft 14 by the boss 31 via a bearing 36.

  In the motor housing 21 and the electric motor 13 assembled in this way, the reinforcing ribs 32 of the motor housing 21 are located between the coil ends 35 of the stator 33 so that they do not interfere with each other. It is set. The plurality of reinforcing ribs 32 are radially centered on the rotating shaft 14 of the electric motor 13 and are evenly spaced so as to be symmetrical in the circumferential direction from the outer peripheral surface of the boss portion 32 to the inner periphery of the motor housing 21. It is formed in a substantially triangular shape toward the surface. Therefore, the motor housing 21 has sufficient strength, and can be prevented from being deformed during heating for shrink fitting or holding during cutting.

  Further, in a state where the electric motor 13 is fixed to the motor housing 21, there is a gap between the axial end portions of the stator 33 and the inner peripheral surface of the motor housing 21 at the contact surface between the motor mounting portion 29 and the stator 33. S is provided. When the member is sandwiched between the surfaces, stress concentration occurs on the surface facing the end of the member. In this embodiment, by providing the gap S here, stress concentration between the end of the stator 33 and the inner peripheral surface of the housing can be suppressed. The clearance S on the opening end side of the motor housing 21 is provided by extending the insertion guide portion 28 to the motor mounting portion 29. The motor housing 21 is formed by casting such as aluminum die casting using a casting mold, and the gap S can be easily provided without processing and without increasing costs.

  The center housing 22 has a substantially cylindrical shape, and an annular convex portion protruding to the outer periphery is sandwiched between the motor housing 21 and the compressor housing 23 as described above. A bearing 37 is mounted on the inner peripheral portion of the center housing 22, and the rotating shaft 14 is rotatably supported by the bearing 37. A refrigerant gas passage 38 is formed in the center housing 22 so as to penetrate between both end faces along the axial direction. One end of the refrigerant gas passage 38 communicates with the low pressure chamber 26 near the suction port 27.

  The compressor housing 23 has a substantially cylindrical shape and accommodates the compression unit 12. The compressor housing 23 is provided with a suction chamber 39 communicating with the refrigerant gas passage 38 as a space between the compressor housing 12 and a compression chamber 40 partitioned by the compressor 12 itself. The compressor housing 23 is formed with a high pressure chamber 41 as a space between the compressor housing 12 and a discharge chamber 43 communicating with the high pressure chamber 41 via a high pressure gas passage 42. A discharge port 44 is formed in the nozzle.

  The compression unit 12 is a scroll type compression mechanism, and compresses the refrigerant gas absorbed from the suction port 27. This refrigerant gas is a lubricating mist-containing gas in which lubricating oil for lubricating each part in the housing 11 of the electric compressor is contained in a mist form. The compression unit 12 includes a fixed scroll 45 and a turning scroll 46.

  The fixed scroll 45 has a disk 48 fitted to the inner peripheral surface of the compressor housing 23 and fixed to the compressor housing 23 by fastening bolts 47, and a spiral wrap 49 formed on one surface of the disk 48. doing. A discharge port 50 that communicates the compression chamber 40 and the discharge chamber 41 is provided at the center of the disk 48, and the discharge port 50 can be opened and closed by a discharge valve 51.

  The orbiting scroll 46 has a disk 52 and a spiral wrap 53 formed on one surface of the disk 52. The spiral scroll wrap 49 of the orbiting scroll 46 is combined with the spiral wrap 49 of the fixed scroll 45 so that the space between the wraps 49 and 53 is the compression chamber 40. .

  A boss 54 is provided on the opposite surface of the orbiting scroll 46 to the disk 52. On the other hand, an eccentric shaft 55 is provided at a position eccentric to the other end of the rotary shaft 14 by a predetermined amount. The eccentric shaft 55 is rotatably supported by the boss 54 via a drive bush 56 and a bearing 57. Yes. As a result, the orbiting scroll 46 can revolve by the rotation of the rotating shaft 14. Further, a rotation prevention mechanism 58 is interposed between the center housing 22 and the disk 52, and the orbiting scroll 46 is capable of revolving orbiting while preventing rotation. Further, a balance weight 59 for canceling the unbalance amount given to the orbiting scroll 46 is fixed to the rotary shaft 14.

  Here, the operation of the scroll compressor of this embodiment described above will be described.

  When the electric motor 13 is driven, the orbiting scroll 46 is driven through the rotating shaft 14, the eccentric shaft 55, and the like, and the orbiting scroll 46 revolves on the revolution track while being prevented from rotating by the rotation preventing mechanism 58. Then, a low-temperature refrigerant gas containing lubricating oil mist is sucked into the low-pressure chamber 26 of the housing 11 from the suction port 27, passes through the refrigerant gas passage 38 from the low-pressure chamber 26, and is sucked into the compression chamber 40 through the suction chamber 39. It is.

  When the orbiting scroll 46 turns, the compression chamber 40 is gradually narrowed accordingly, and the refrigerant gas inside reaches the center while being compressed, and is discharged to the high pressure chamber 41 through the discharge port 50. The discharge valve 51 opens and closes due to the differential pressure between the compression chamber 40 and the high pressure chamber 41. That is, when the pressure of the refrigerant gas in the compression chamber 40 becomes higher than the pressure in the high pressure chamber 41, the discharge valve 51 is pushed open and the refrigerant gas flows out into the high pressure chamber 41. Thereafter, the refrigerant gas flows from the high pressure chamber 41 through the high pressure gas passage 42 to the discharge chamber 43 and is discharged to the outside through the discharge port 44.

  The refrigerant gas sucked into the housing 11 contains a mist of lubricating oil, and a part of the refrigerant gas passes through the bearings 36, 57 and the like, so that the mist-like lubrication contained in the refrigerant gas is contained. Lubricated with oil.

  As described above, in the scroll compressor according to the present embodiment, the housing 11 includes the motor housing 21, the center housing 22, and the compressor housing 23, and the compressor 12 that compresses the fluid therein and the compressor 12 are driven. The electric motor 13 is housed in a concentrated winding motor, and a plurality of reinforcing ribs 32 are provided radially between the motor housing 21 so as to avoid the coil end 35 of the stator 33. .

  Therefore, the strength of the housing 11 can be improved by providing the plurality of reinforcing ribs 32 without interfering with the coil end 35 of the electric motor 13 accommodated in the housing 11. Therefore, even if the motor housing 21 is heated for shrink fitting, the distortion at that time can be minimized, and the outside is firmly held to cut the inner surface of the motor housing 21. However, the distortion at that time can be sufficiently suppressed. As a result, deformation during processing of the housing 11 can be suppressed, the processing accuracy of the inner surface can be improved, and the assembly accuracy of the electric motor 13 to the housing 11 can be improved.

  Further, in the present embodiment, the plurality of reinforcing ribs 32 are formed radially at the rotating shaft 14 of the electric motor 13 and at equal intervals so as to be symmetrical in the circumferential direction. Therefore, the motor housing 21 can be uniformly and sufficiently strong without interfering with the electric motor 13, and the motor can be reduced in size and efficiency, and the housing 11 can be reinforced efficiently. it can.

  In this case, the reinforcing rib 32 is formed in a substantially triangular shape from the boss portion 31 toward the inner peripheral surface of the motor housing 21. Therefore, the substantially parallel boss portion 31 and the wall surface of the motor housing 21 are connected by a plurality of triangular reinforcing ribs 32. Accordingly, the inside of the motor housing 21 is three-dimensionally reinforced by the reinforcing rib 32, and the motor housing can be effectively reinforced with a simple structure.

  Further, the stator 33 of the electric motor 13 is fixed to the motor mounting portion 29 of the motor housing 21 by shrink fitting, and a gap S is provided between the end of the stator 33 and the motor mounting portion 29. Therefore, the gap S can suppress stress concentration between the end portion of the stator 33 and the inner peripheral surface of the motor housing 21, and the overall strength of the housing 21 can be increased.

  The motor housing 21 is cup-shaped, and an insertion guide portion 28 larger than the outer diameter of the stator 33 (the inner diameter of the motor mounting portion 29) is provided from the opening end to the motor mounting portion 29. Therefore, the clearance S provided between the end portion of the stator 33 and the motor mounting portion 29 can be performed simultaneously with the processing of the insertion guide portion 28, and the workability can be improved. Two gaps S are provided between both end portions of the stator 33 and the motor mounting portion 29. However, even if only the opening end side of the motor housing 21 is provided, stress concentration can be sufficiently avoided.

  In the above-described embodiment, the reinforcing rib 32 is provided in a triangular shape so as to connect the boss portion 31 and the inner surface of the motor housing 21, but any shape may be used. Any structure that does not interfere is acceptable.

  Moreover, although the electric compressor of the present invention has been described as applied to a scroll compressor, any type of compressor may be used, and it can also be applied to a rotary compressor or the like.

  The electric compressor according to the present invention is provided with a reinforcing rib so as to avoid the coil end of the electric motor in the housing to improve the strength, and the electric motor in which the electric motor and the compressor are accommodated in the housing. It is useful when applied to a compressor.

It is sectional drawing showing the scroll compressor as an electric compressor which concerns on the Example of this invention. It is II-II sectional drawing of FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 11 Housing 12 Compression part 13 Electric motor 14 Rotating shaft 21 Motor housing 28 Guide insertion part 29 Motor attachment part 30 Notch part 31 Boss part 32 Reinforcement rib 33 Stator 34 Rotor 35 Coil end 45 Fixed scroll 46 Turning scroll

Claims (7)

  A housing having a hollow shape, a compression portion provided on one end side of the housing for compressing fluid sucked into the housing, and an electric motor provided on the other end side of the housing for driving the compression portion; An electric compressor comprising: a reinforcing rib provided on the other end side of the housing so as to avoid a coil end of the electric motor.   2. The electric compressor according to claim 1, wherein the electric motor is a concentrated winding motor, and a plurality of the reinforcing ribs are provided radially between a plurality of concentrated winding stators.   2. The electric compressor according to claim 1, wherein a plurality of the reinforcing ribs are provided radially around the rotation shaft of the electric motor and symmetrically in the circumferential direction.   4. The electric compressor according to claim 1, wherein a boss portion that supports a rotating shaft of the electric motor is provided on the other end side of the housing, and the reinforcing rib extends from the boss portion to the housing. An electric compressor characterized by being formed in a substantially triangular shape toward the inner peripheral surface of the electric compressor.   5. The electric compressor according to claim 1, wherein the electric motor has a stator fixed to the inner peripheral surface of the housing by shrink fitting, and an end portion of the stator and an inner periphery of the housing. An electric compressor characterized in that a gap is provided between the surface and the surface.   6. The electric compressor according to claim 5, wherein the housing includes a compression portion housing that accommodates the compression portion, and a motor housing that accommodates the electric motor. The motor housing has a cup shape from an open end. An electric compressor characterized in that an insertion guide portion larger than the outer diameter of the stator is provided up to the gap.   The electric compressor according to claim 6, wherein the insertion guide portion is formed by a casting mold.

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