JP6450913B1 - Scroll compressor - Google Patents

Abstract

A scroll compressor having an improved compression ratio while suppressing complication of the entire apparatus is provided. A scroll compressor according to the present invention includes a fixed scroll 21 fixed to the compressor main body side, a movable scroll 20 disposed so as to be rotatable with respect to the fixed scroll 21, a fixed scroll 21, and a movable scroll 20. A compression space 43 formed as a gap, a shaft 18 for applying a driving force to the movable scroll 20, a fan 17 attached to the shaft 18, and a casing 31. In the present invention, the fan 17 rotates together with the shaft 18 to introduce the fluid introduced into the casing 31 into the compression space. [Selection] Figure 2

Description

  The present invention relates to a scroll compressor, and more particularly to a scroll compressor capable of increasing a fluid compression rate.

  In a general scroll compressor, a fixed scroll is fixed to a scroll body, and a movable scroll is combined with the fixed scroll so as to be capable of turning. When the scroll compressor is operated, the movable scroll turns around the turning center as a rotation axis, so that the fluid introduced between the fixed scroll and the movable scroll from the periphery of the scroll compressor is compressed between the two. While moving, it moves toward the center. The fluid that has reached the center is supplied outside the system in a compressed state. A scroll compressor having such a configuration is described in Patent Document 1, for example.

Japanese Patent No. 4635660

  However, in the scroll compressor having the above-described general configuration, it is not easy to obtain a high compression ratio because a fluid that is not so pressurized is introduced into the space between the movable scroll and the fixed scroll. There was a problem.

  In addition, if a compressor for compressing fluid is interposed in the front part of the scroll compressor in order to increase the compression ratio, the fluid pressurized by the compressor can be supplied to the scroll compressor, so that a high compression ratio can be obtained. I can do it. However, since a separate compressor is newly required, there is a problem that leads to an increase in complexity and cost of the entire apparatus.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a scroll compressor having an improved compression ratio while suppressing complication of the entire apparatus.

A scroll compressor according to the present invention is a compressor that compresses a refrigerant used in a vapor compression refrigeration cycle, a fixed scroll fixed to the compressor body side, and a movable scroll arranged to be rotatable with respect to the fixed scroll. A compression space formed between the fixed scroll and the movable scroll, a shaft for applying a driving force to the movable scroll, an axial fan attached to the shaft, a motor for rotating the shaft, A casing, an intake opening that opens in the casing , an introduction space that is a space formed on an axial side of the motor, and the interior of the casing between the fixed scroll, the movable scroll, and the axial fan. An internal housing that divides a space, a circulation port that is formed in the internal housing and through which the refrigerant flows, and Comprises a chromatography data and a flow space is formed a space between the inner housing, the axial flow fan, by rotating together with the shaft, the refrigerant introduced into the interior of the casing, The fixed scroll, the movable scroll, the compression space, the shaft, the motor, and the axial fan introduced into the compression space are built in the casing, and from the upstream side along the flow of the refrigerant, An intake port, the introduction space, the motor, the axial fan, the flow space, the inner housing, and the compression space are disposed, and a storage space is adjacent to the introduction space with a partition wall therebetween, A power conversion circuit is disposed, and a gap through which the refrigerant flows is formed between the inner side surface of the casing and the outer side surface of the motor. The refrigerant introduced from is cooled in the motor via the gap without being introduced into the introduction space, introduced into the compression space, and introduced from another part of the intake port. The refrigerant is introduced into the introduction space, cools the power conversion circuit, cools the motor via the gap, is introduced into the compression space, and the axial fan is rotated, whereby the refrigerant Is introduced into the circulation space via the intake port and the motor, and the refrigerant that has moved to the circulation space is introduced into the compression space via the circulation port by the axial fan. It is characterized by.

  In the scroll compressor, the flow port is formed to be elongated along a circumferential direction of the circular inner housing.

  Further, in the scroll compressor, a part of the intake port through which the fluid is introduced into the casing is disposed on the radial direction side of the motor, and the other part is formed on the axial direction side of the motor. The substrate is disposed on the side of the introduced space in the radial direction, and a substrate in which a power conversion circuit for converting power supplied to the motor is incorporated is adjacent to the introduced space.

  Further, in the scroll compressor, the casing has a contact portion in which an inner side surface thereof partially protrudes radially inward, and the contact portion contacts the outer side surface of the motor, and the contact A gap through which the fluid flows is formed between the inner side surface of the casing where no part is formed and the outer side surface of the motor.

  In the scroll compressor, the contact portion includes a first contact portion and a second contact portion whose projection height is lower than that of the first contact portion, and the first contact portion. And a step formed between the second contact portion and the end surface of the stator of the motor, the position in the axial direction of the stator is fixed, and the second contact The position of the stator in the radial direction is fixed by the portion contacting the outer side surface of the stator.

A scroll compressor according to the present invention is a compressor that compresses a refrigerant used in a vapor compression refrigeration cycle, a fixed scroll fixed to the compressor body side, and a movable scroll arranged to be rotatable with respect to the fixed scroll. A compression space formed between the fixed scroll and the movable scroll, a shaft for applying a driving force to the movable scroll, an axial fan attached to the shaft, a motor for rotating the shaft, A casing, an intake opening that opens in the casing , an introduction space that is a space formed on an axial side of the motor, and the interior of the casing between the fixed scroll, the movable scroll, and the axial fan. An internal housing that divides a space, a circulation port that is formed in the internal housing and through which the refrigerant flows, and Comprises a chromatography data and a flow space is formed a space between the inner housing, the axial flow fan, by rotating together with the shaft, the refrigerant introduced into the interior of the casing, The fixed scroll, the movable scroll, the compression space, the shaft, the motor, and the axial fan introduced into the compression space are built in the casing, and from the upstream side along the flow of the refrigerant, An intake port, the introduction space, the motor, the axial fan, the flow space, the inner housing, and the compression space are disposed, and a storage space is adjacent to the introduction space with a partition wall therebetween, A power conversion circuit is disposed, and a gap through which the refrigerant flows is formed between the inner side surface of the casing and the outer side surface of the motor. The refrigerant introduced from is cooled in the motor via the gap without being introduced into the introduction space, introduced into the compression space, and introduced from another part of the intake port. The refrigerant is introduced into the introduction space, cools the power conversion circuit, cools the motor via the gap, is introduced into the compression space, and the axial fan is rotated, whereby the refrigerant Is introduced into the circulation space via the intake port and the motor, and the refrigerant that has moved to the circulation space is introduced into the compression space via the circulation port by the axial fan. It is characterized by. Accordingly, when the scroll compressor is operated to compress the fluid, the refrigerant blown by the fan inside the casing is introduced into the compression space, so that the compressibility of the fluid in the compression space can be improved. Further, since the fan that introduces the fluid into the compression chamber is rotated by a shaft that applies a driving force to the movable scroll, an increase in the number of parts by providing the fan is suppressed.

  In the scroll compressor, the flow port is formed to be elongated along a circumferential direction of the circular inner housing. Therefore, by setting it as such a shape, a large-area distribution port can be formed on the radially outer side.

  Further, in the scroll compressor, a part of the intake port through which the fluid is introduced into the casing is disposed on the radial direction side of the motor, and the other part is formed on the axial direction side of the motor. The substrate is disposed on the side of the introduced space in the radial direction, and a substrate in which a power conversion circuit for converting power supplied to the motor is incorporated is adjacent to the introduced space. Therefore, the motor can be cooled by the refrigerant flowing from a part of the intake port. Moreover, the power conversion circuit adjacent to the introduction space can be cooled with the refrigerant introduced into the introduction space from another part of the intake port.

  Further, in the scroll compressor, the casing has a contact portion in which an inner side surface thereof partially protrudes radially inward, and the contact portion contacts the outer side surface of the motor, and the contact A gap through which the fluid flows is formed between the inner side surface of the casing where no part is formed and the outer side surface of the motor. Therefore, by circulating the refrigerant between the outer side surface of the motor and the inner side surface of the casing, the motor can be efficiently cooled when the scroll compressor is operated.

  In the scroll compressor, the contact portion includes a first contact portion and a second contact portion whose projection height is lower than that of the first contact portion, and the first contact portion. And a step formed between the second contact portion and the end surface of the stator of the motor, the position in the axial direction of the stator is fixed, and the second contact The position of the stator in the radial direction is fixed by the portion contacting the outer side surface of the stator. Therefore, the stator can be fixed at an accurate position inside the casing.

It is a figure which shows the scroll compressor which concerns on embodiment of this invention, (A) is a perspective view, (B) is the figure which looked at the scroll compressor from the front, (C) is C of (B). It is sectional drawing in the -C line. It is a disassembled perspective view which shows the scroll compressor which concerns on embodiment of this invention. It is a figure which shows the internal housing of the scroll compressor which concerns on embodiment of this invention. It is a figure which shows the scroll compressor which concerns on embodiment of this invention, and is sectional drawing which shows the related structure of a front casing part and a motor. It is a figure which shows the scroll compressor which concerns on embodiment of this invention, (A) is a perspective view which shows a front casing part and a stator, (B) is a perspective view which shows a front casing part partially.

  Hereinafter, the scroll compressor 10 of this embodiment and the manufacturing method thereof will be described with reference to the drawings. In the following description, the same parts are denoted by the same reference numerals, and redundant description is omitted. In the following description, the respective directions of up, down, front, back, left and right are used as appropriate, but the front indicates the upstream side of the fluid flow inside the scroll compressor 10, the rear is the opposite side of the front, and the left and right are scroll compression. The right and left when the machine 10 is viewed from the front are shown.

  With reference to FIG. 1, the structure of the scroll compressor 10 which concerns on this Embodiment is demonstrated. 1A is a perspective view showing the entire scroll compressor 10, FIG. 1B is a side view of the scroll compressor 10 as viewed from the front, and FIG. 1C is FIG. 1B. It is sectional drawing in the CC line.

  With reference to FIG. 1A and FIG. 1B, in the scroll compressor 10, each member functioning as the scroll compressor 10 is accommodated in the casing 31. As shown in FIG. 1C, the casing 31 includes, from the front, a front casing 12, a front casing part 11, a rear casing part 29, and a rear case 22, and accommodates each member. The front casing portion 11 and the rear casing portion 29 form a substantially cylindrical body portion. The front casing 12 closes the front opening of the front casing portion 11. The front casing 12 is fastened to the front portion of the front casing portion 11 by fastening means such as screws. Further, the rear case 22 closes the rear opening of the rear casing portion 29. The rear case 22 is fastened to the rear portion of the rear casing portion 29 by fastening means such as screws. Each member constituting the scroll compressor 10 is made of a metal material such as stainless steel or aluminum.

  Referring to FIG. 1C, an inverter board 15, a motor 16, an internal housing 19, a fan 17, a movable scroll 20, and a fixed scroll 21 are arranged in the casing 31 from the front side. In addition, the discharge port 24 is formed by penetrating the substantially center part of the fixed scroll 21, and the discharge port 24 is covered with the valve body 25 from back. When the refrigerant is compressed between the inner housing 19 and the movable scroll 20, the valve body 25 is opened by the pressure.

  The function of the scroll compressor 10 is to rotate the movable scroll 20 by the driving force of the built-in motor 16 to compress the refrigerant (fluid) introduced from the intake port 13 and to discharge the compressed refrigerant from the exhaust port 14. It is to discharge outside. A refrigerant that has passed through an evaporator (not shown) is introduced from the intake port 13. The scroll compressor 10 is connected to a condenser, an expansion means, and an evaporator (not shown here) via a refrigerant pipe and constitutes a vapor compression refrigeration cycle. This vapor compression refrigeration cycle is used, for example, as a cooling / heating device that cools or heats the interior of a vehicle.

  With reference to FIG. 2, the structure of the scroll compressor 10 which concerns on this embodiment is explained in full detail. In FIG. 2, the members constituting the scroll compressor 10 are shown exploded in the front-rear direction. Further, the center line 27 of the scroll compressor 10 is indicated by a one-dot chain line.

  An inverter board 15 is formed in the storage space 33 formed in the front end portion of the front casing portion 11. The inverter board 15 has an inverter composed of conductive paths and circuit elements incorporated on the surface of a circular board. This inverter includes, for example, a converter circuit that converts input commercial AC power into DC power and an inverter circuit that converts this DC power into AC power having a predetermined frequency. The inverter board 15 supplies AC power to the motor 16 described above. Although the inverter board 15 generates heat during the operation of the scroll compressor 10, as described later, a part of the refrigerant introduced into the casing 31 is circulated in the vicinity of the inverter board 15 to cool the inverter board 15. doing. By doing in this way, the overheating of the inverter board | substrate 15 can be suppressed and an inverter circuit can be operated stably.

  A partition wall 32 is integrally formed on the front end portion side of the front casing portion 11, and the internal space of the front casing portion 11 is partitioned by the partition wall 32 into a front side and a rear side. A front side of the partition wall 32 is a storage space 33 in which the inverter board 15 is stored.

  The intake port 13 is formed by partially opening a side portion of the front casing portion 11 and projecting the opening portion to the side in a cylindrical shape.

  A motor 16 having a substantially cylindrical outer shape is accommodated in the front casing portion 11. As will be described later, a gap that allows the refrigerant to flow is formed between the inner side surface of the front casing portion 11 and the outer side surface of the motor 16.

  The shaft 18 is a substantially cylindrical steel rod, and a front portion thereof is inserted into the motor 16. The shaft 18 is rotated by the driving force of the motor 16.

  A shaft 18 is inserted through the fan 17. The fan 17 rotates with the shaft 18. The fan 17 may be a centrifugal fan that blows radially outward by rotating, or an axial fan that blows backward by rotating.

  The internal housing 19 is a wall-shaped member that partitions the internal space of the casing 31 back and forth. The shaft 18 passes through a hole formed in the central portion of the inner housing 19. A revolving mechanism 23 that revolves the movable scroll 20 by the rotational movement of the shaft 18 is accommodated in the accommodating portion 40 in which the vicinity of the central portion of the inner housing 19 is projected in a substantially cylindrical shape toward the front. The inner housing 19 is fixed to the front end portion of the rear casing portion 26. In addition, by partially opening the inner housing 19, a communication port 28 is formed through which the front space and the rear space of the inner housing 19 communicate with each other and the refrigerant flows. The specific shape of the communication port 28 will be described later.

  The movable scroll 20 is a scroll that is arranged on the rear side of the inner housing 19 and is turned by the turning mechanism 23 described above.

  The fixed scroll 21 is fastened to the rear casing part 29 via fastening means such as screws. As the movable scroll 20 turns with respect to the fixed scroll 21, the refrigerant is compressed in a compression space 43 (FIG. 1C) formed between the movable scroll 20 and the fixed scroll 21. The compressed refrigerant is discharged rearward from a hole (not shown) formed in the central portion of the fixed scroll 21.

  The rear case 22 covers the fixed scroll 21 from the rear. The rear case 22 is fastened to the rear casing portion 29 together with the fixed scroll 21 inserted through fastening means such as bolts. On the side of the rear case 22, an exhaust port 14 that connects the internal space of the casing 31 and the outside is formed. The exhaust port 14 protrudes laterally in a substantially cylindrical shape. The compressed refrigerant compressed by turning the movable scroll 20 with respect to the fixed scroll 21 is discharged to the outside through the exhaust port 14. The refrigerant discharged from the exhaust port 14 is sent to a condenser not shown here.

  Here, with reference to FIG. 1C again, the operation of the scroll compressor 10 having the above-described configuration will be described. First, an inverter circuit incorporated in the inverter board 15 converts power supplied from an external power source into AC power having a predetermined frequency. The motor 16 is rotated at a predetermined speed in a predetermined direction by being supplied with the AC power. The motor 16 rotates the shaft 18. As the shaft 18 rotates, the fan 17 also rotates to send air.

  When the fan 17 rotates, a part of the refrigerant taken in from the intake port 13 is introduced into the introduction space 30. Here, when the intake port 13 is viewed from the left, the rear portion of the intake port 13 is disposed at a position overlapping the motor 16, and the front portion of the intake port 13 is disposed in front of the front end of the motor 16. The That is, the front portion of the intake port 13 is formed on the left side of the introduction space 30 formed in front of the motor 16.

  The refrigerant introduced into the inside of the casing 31 from the rear portion of the intake port 13 is not introduced into the introduction space 30 but proceeds toward the rear, and between the outer side surface of the motor 16 and the inner side surface of the front casing portion 11. To the distribution space 35 formed behind the motor 16. As the refrigerant flows through the gap between the outer side surface of the motor 16 and the inner side surface of the front casing portion 11, the motor 16 is cooled by the refrigerant. Therefore, the motor 16 rotating at high speed is prevented from being overheated.

  On the other hand, the refrigerant introduced into the casing 31 from the front portion of the intake port 13 is introduced into the introduction space 30 formed in front of the motor 16. A partition wall 32 is formed in front of the introduction space 30, and a storage space 33 in which the inverter board 15 is stored is formed in front of the partition wall 32. Therefore, when the refrigerant is introduced into the introduction space 30, the storage space 33 is cooled by the refrigerant through the partition wall 32, and as a result, the inverter board 15 built in the storage space 33 is cooled. Therefore, although a large amount of heat energy is generated from the inverter board 15 by converting a large current, the inverter board 15 is overheated by cooling the inverter board 15 with the refrigerant through the partition wall 32 and the introduction space 30. The inverter circuit incorporated in the inverter board 15 can efficiently convert the power. The refrigerant that has cooled the inverter board 15 in the introduction space 30 passes through the gap between the lower portion of the motor 16 and the lower portion of the inner side surface of the front casing portion 11 and flows into the circulation space 35 in the same manner as described above. Here, in FIG. 1C, the inverter board 15 is disposed on the front side in the storage space 33, but the inverter board 15 is disposed on the rear side of the storage space 33, and the partition wall 32. You may make it contact | abut to the whole surface.

  The refrigerant that has passed through the gap between the motor 16 and the front casing portion 11 toward the rear is blown toward the rear by the fan 17 that rotates together with the shaft 18 after moving to the circulation space 35. Thereafter, the refrigerant is introduced into a compression space 43 formed between the movable scroll 20 and the fixed scroll 21 via a communication port 28 formed in the inner housing 19. In the present embodiment, the refrigerant is blown rearward by the fan 17 rotating at high speed, and the refrigerant is introduced into the compression space 43, so that a so-called supercharged state can be created. Therefore, in the compression space 43, the refrigerant introduced in a compressed state is further compressed, and the compression rate of the scroll compressor 10 as a whole can be improved. Moreover, since the fan 17 for supercharging is rotated by the existing shaft 18, a dedicated member for rotating the fan 17 becomes unnecessary, and an increase in the number of parts and a complicated structure are suppressed.

  Thereafter, the turning mechanism 23 converts the rotational movement of the shaft 18 into the turning movement, whereby the movable scroll 20 turns, and as a result, the refrigerant moves to the center while being compressed. Thereafter, the sufficiently compressed refrigerant moves from the discharge port 24 where the valve body 25 is released to the discharge space 34 and is discharged to the outside via the exhaust port 14.

  Referring to FIG. 3, the inner housing 19 has a substantially circular shape when viewed from the front, and a communication port 28 is formed by partially opening the inner housing 19. Here, two communication ports 28 are formed in the vicinity of the outer peripheral portion of the inner housing 19. Here, the communication port 28 is hatched.

  The communication port 28 is formed on the radially outer side of the inner housing 19. By doing in this way, a refrigerant | coolant can be supplied to the radial direction outer part of the movable scroll 20 shown in FIG.

  Further, the communication port 28 has a symmetrical position and shape. Specifically, the communication port 28 is disposed at a point-symmetrical position with respect to the center point 41 of the inner housing 19. Here, although the communication port 28 is arrange | positioned at an upper end and a lower end, you may arrange | position in another point symmetrical position. By doing in this way, when a refrigerant | coolant distribute | circulates from the introduction space 30 to the distribution | circulation space 35, a refrigerant | coolant can be distribute | circulated over the perimeter of the motor 16, and the motor 16 can be cooled efficiently. .

  Further, the communication port 28 has a point-symmetric shape with respect to the center point 41 of the inner housing 19. Further, the communication port 28 is formed to be elongated along the circumferential direction. By doing in this way, a refrigerant | coolant can be equally supplied to the peripheral part of the movable scroll 20. FIG. Here, the number of the communication ports 28 may be other than two. For example, three or more communication ports 28 may be formed symmetrically.

  With reference to FIG. 4, the related structure of the front casing part 11 and the motor 16 is demonstrated. This figure partially shows a cross section of the front casing portion 11 and the motor 16.

  The motor 16 includes a rotor 36 that rotates together with the shaft 18, and a stator 37 that is circumferentially disposed around the rotor 36. For example, a permanent magnet is disposed near the edge of the rotor 36, an electric magnet is disposed on the stator 37, and current is supplied from the inverter board 15 to the electric magnet of the stator 37, whereby the rotor 36 is It rotates with the shaft 18.

  Further, the motor 16 is built in the front casing portion 11. The abutting portion 38 is formed by partially projecting the inner wall of the front casing portion 11 radially inward. The cross-sectional shape of the contact part 38 is a substantially rectangular shape whose circumferential length is longer than the radial direction. A plurality of contact portions 38 are formed at substantially equal intervals along the circumferential direction of the front casing portion 11. The abutting portion 38 is formed from the front end to the rear end of the motor 16.

  The radially inner end surface of the contact portion 38 has a flat surface or a curved surface that is recessed outward. The position of the motor 16 in the front casing portion 11 is fixed by the radially inner end surface of the contact portion 38 contacting the radially outer side surface of the stator 37 of the motor 16.

  As described above, the gap 42 is formed between the inner side surface of the front casing portion 11 and the outer side surface of the motor 16 by fixing the motor 16 with the contact portion 38 formed on the inner side surface of the front casing portion 11. can do. The gap 42 is formed from the front end to the rear end of the motor 16. Under the operating condition of the scroll compressor 10, the refrigerant flows through the gap 42. Therefore, it is possible to prevent the motor 16 from being cooled by the refrigerant flowing through the gap 42 and being overheated.

  With reference to FIG. 5, the related structure of the front casing part 11 and the stator 37 is demonstrated. FIG. 5A is a perspective view showing the front casing portion 11 and the stator 37, and FIG. 5B is an enlarged perspective view showing the contact portion 38 formed on the inner side surface of the front casing portion 11. As shown in FIG.

  With reference to FIG. 5 (A), the stator 37 which comprises the motor 16 mentioned above is contacting the inner surface of the contact part 38 which raised the inner surface of the front casing part 11 toward radial inside. Here, the inner diameter of the front casing portion 11 in the portion where the contact portion 38 (second contact portion 45 described later) is formed is smaller than the outer diameter of the corresponding portion of the stator 37. This is to secure a large tightening allowance to firmly fix the stator 37. Therefore, when the stator 37 is inserted into the front casing portion 11, so-called shrink fitting is performed. Specifically, the front casing part 11 is heated to a high temperature of about 200 ° C., for example, so that the front casing part 11 is thermally expanded to form a contact part 38 (second contact part 45 described later). The inner diameter of the front casing portion 11 is made larger than the outer shape of the stator 37. In this state, the stator 37 is inserted into the front casing portion 11. Thereafter, when the front casing portion 11 is cooled to room temperature, the front casing portion 11 is thermally contracted, and the contact portion 38 of the front casing portion 11 is firmly in contact with the outer surface of the stator 37. Thereby, the position of the stator 37 in the inside of the front casing part 11 is accurately and firmly fixed.

  With reference to FIG. 5 (B), the contact part 38 is comprised from the 1st contact part 44 which forms a front part, and the 2nd contact part 45 which forms a back part. The height at which the first contact portion 44 protrudes radially inward from the inner surface of the front casing portion 11 is higher than the height at which the second contact portion 45 protrudes radially inward from the inner surface of the front casing portion 11. Also expensive. Thus, a step 47 is formed between the rear end of the first contact portion 44 and the front end of the second contact portion 45. The inner side surface of the second contact portion 45 contacts the outer surface of the stator 37 described above, so that the position of the stator 37 in the radial direction is fixed. Further, the front end portion of the stator 37 abuts on the stepped portion 47, whereby the position of the stator 37 is defined in the front-rear direction. Therefore, in the region where the contact portion 38 is not formed, the gap 42 described above is formed between the inner surface of the front casing portion 11 and the outer surface of the stator 37. The length of the gap 42 in the radial direction is equal to the protruding height of the second contact portion 45. In other words, the first contact portion 44 fixes the motor 16 along the axial direction. The second contact portion 45 fixes the motor 16 along the axial direction.

  A recessed portion 46 is formed between the rear end of the first contact portion 44 and the front end of the second contact portion 45. The concave portion 46 is formed continuously from one end to the other end of the contact portion 38 in the circumferential direction. The protruding height of the contact portion 38 in the portion where the concave portion 46 is formed is lower than that of the second contact portion 45. By forming the concave portion 46, the process of shrink-fitting the stator 37 can be made smooth.

  As mentioned above, although embodiment of this invention was shown, this invention is not limited to the said embodiment.

DESCRIPTION OF SYMBOLS 10 Scroll compressor 11 Front casing part 12 Front casing 13 Inlet 14 Exhaust port 15 Inverter board 16 Motor 17 Fan 18 Shaft 19 Internal housing 20 Movable scroll 21 Fixed scroll 22 Rear case 23 Turning mechanism 24 Discharge port 25 Valve body 26 Back casing Portion 27 center line 28 communication port 29 rear casing portion 30 introduction space 31 casing 32 partition wall 33 storage space 34 discharge space 35 distribution space 36 rotor 37 stator 38 contact portion 40 storage portion 41 center point 42 gap 43 compression space 44 First contact portion 45 Second contact portion 46 Concave portion 47 Step portion

Claims (5)

A compressor that compresses refrigerant used in a vapor compression refrigeration cycle;
A fixed scroll fixed to the compressor main body side, a movable scroll arranged to be rotatable with respect to the fixed scroll, a compression space formed between the fixed scroll and the movable scroll, and the movable scroll A shaft for providing a driving force, an axial fan attached to the shaft, a motor for rotating the shaft, a casing, an intake opening opened in the casing, and a space formed on the axial side of the motor. An internal space that divides the internal space of the casing between the fixed scroll and the movable scroll and the axial fan, and a circulation port that is formed in the internal housing and through which the refrigerant flows. A circulation space that is a space formed between the motor and the inner housing ,
The axial fan rotates together with the shaft to introduce the refrigerant introduced into the casing into the compression space ,
The fixed scroll, the movable scroll, the compression space, the shaft, the motor, and the axial fan are built in the casing,
Along the refrigerant flow, from the upstream side, the inlet, the introduction space, the motor, the axial fan, the flow space, the inner housing, and the compression space are disposed,
A storage space is adjacent to the introduction space across a partition wall, and a power conversion circuit is disposed in the storage space,
A gap through which the refrigerant flows is formed between the inner side surface of the casing and the outer side surface of the motor,
The refrigerant introduced from a part of the intake port is introduced into the compression space after cooling the motor via the gap without being introduced into the introduction space,
The refrigerant introduced from the other part of the intake port is introduced into the introduction space, cools the power conversion circuit, cools the motor via the gap, and is then introduced into the compression space. ,
When the axial fan rotates, the refrigerant is introduced into the circulation space via the intake port and the motor,
The scroll compressor , wherein the refrigerant moved to the circulation space is introduced into the compression space by the axial fan through the circulation port . The scroll compressor according to claim 1 , wherein the circulation port is formed to be elongated along a circumferential direction of the inner housing having a circular shape. The inlet is characterized in that a part is arranged radially side of the motor, the other part is arranged radially side of the introduction space formed in the axial direction side of the motor The scroll compressor according to claim 1 . The casing has an abutting portion in which an inner side surface thereof partially protrudes radially inward,
The contact portion comes into contact with the outer side surface of the motor,
And the inner side surface of the casing in which the not abutting portion is formed, between the outer side surface of the motor, according to claim 1, wherein the refrigerant, characterized in that the gap flows is formed Scroll compressor. The contact portion includes a first contact portion and a second contact portion having a projecting height lower than that of the first contact portion.
The position in the axial direction of the stator is fixed by the stepped portion formed between the first contact portion and the second contact portion contacting the end surface of the stator of the motor. ,
5. The scroll compressor according to claim 4 , wherein a position of the stator in a radial direction is fixed by the second contact portion coming into contact with the outer side surface of the stator.

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