CZ2022182A3 - Rotary compressor and refrigeration cycle equipment - Google Patents

Abstract

The rotary compressor (1) comprises a hermetically sealed housing (5), a circular cylinder (11) housed in a hermetically sealed housing (5), a rolling piston (13) which rotates eccentrically along the inner circumference (11b) of the cylinder (11), a lamella ( 14) which moves back and forth in a lamellar groove (22) formed in the cylinder (11) in the radial direction, a lamellar spring (15) which is a helical spring which pushes the lamella (14) so as to indicate the distal end (14a). ) a lamella (14) in contact with the rolling piston (13), and having a small diameter portion (15a) and a large diameter portion (15b) having a larger diameter than the small diameter portion (15a), and a spring guide (30) , to which the lamella spring (15) is fixed by contact of the large diameter portion (15b) of the lamella spring (15) with the inner surface (30) of the spring guide. The spring guide (30) has one end (30a) inserted into the hermetically sealed housing (5) through an opening (8) formed in the hermetically sealed housing (5) and fixed to the cylinder (11).

Description

Rotary compressor and refrigeration cycle equipment

Field of technology

The present invention relates to a rotary compressor and refrigeration cycle equipment used in an air conditioner, refrigerator, refrigeration unit or other equipment.

State of the art

Patent Document 1: Japanese Utility Model Application without Examination, Publication No. JP 5617388 U

The rotary compressor comprises a circular cylinder housed in a hermetically sealed housing, a rolling piston which rotates eccentrically in the cylinder, and a lamella which is slidably arranged in a lamellar groove formed in the cylinder. The lamella is pressed by a lamella spring and is constantly in contact with the rolling piston at the distal end of the lamella. The lamella divides the space inside the cylinder into a low-pressure space and a high-pressure space. As the rolling piston moves eccentrically in the cylinder, the volume of the low-pressure space is reduced to a high-pressure space and the refrigerant sucked into the cylinder is compressed.

In a hermetically sealed compressor of this type, a lamella spring which pushes the lamella is housed in a lamella spring insertion hole formed in the cylinder and is fixed in the cylinder. In this arrangement, in which the lamella spring is mounted in the cylinder in this way, the length of the lamella spring is subject to limitations with respect to the distance between the lamella end face on the rear end side and the inner circumference of the hermetically sealed housing and can no longer be extended. For this reason, when the lamella is in the fully rearward position of the top dead center, there is a possibility that the total length of the lamella spring will reach the length of tight contact that is achieved when the lamella spring is fully compressed and the stress that the lamella spring is will increase by causing the lamella to undergo fatigue fracture.

There is a technique to prevent fatigue fracture due to excessive stress on the lamella spring by providing space to accommodate the lamella spring outside the hermetically sealed housing and eliminating restrictions on the length of the lamella spring (see, e.g., Patent Document 1).

The essence of the invention

The lamella spring alternates and contracts alternately when the lamella is pressed in a hermetically sealed housing. For this reason, when the installation position and the installation position of the lamella spring deviate, a collision between the lamella spring and the peripheral portion may occur during the expansion and contraction of the lamella spring, and the lamella spring may bend or otherwise deform. As a result, a problem such as a failure, defect and shortening of the life of the lamella spring occurs. Therefore, it is desirable to install the vane spring to the rotary compressor accurately.

In the rotary compressor of Patent Document 1, the vane spring is configured to be located in a spring guide mounted to protrude from the hermetically sealed housing. The hermetically sealed housing is subjected to internal pressure generated by the compressed refrigerant and the hermetically sealed housing changes shape, e.g., by the hermetically sealed housing bulging out. For this reason, in the case of a structure in which the spring guide is fixed to a hermetically sealed housing, the lamella spring deviates from the correct position due to deformation of the hermetically sealed container due to internal pressure, so that it is not possible to install the lamella spring accurately.

- 1 CZ 2022 - 182 A3

The present invention is intended with respect to the situation described above and provides a rotary compressor that allows the precise installation of a vane spring to a cylinder, and a refrigeration cycle equipment.

A rotary compressor according to one embodiment of the present invention comprises a hermetically sealed housing, a circular cylinder housed in a hermetically sealed housing, a rolling piston that rotates eccentrically around the inner circumference of the cylinder, a lamella moving back and forth in a lamellar groove formed in the cylinder. a lamellar spring, i.e. a helical spring which pushes the lamella so as to bring the distal end of the lamella into contact with the rolling piston and which has a small diameter part and a large diameter part having a larger diameter than the small diameter part, and a spring guide to to which the lamella spring is fixed by contact of the large diameter portion of the lamella spring with the inner surface of the spring guide. The spring guide has one end inserted into a hermetically sealed housing through an opening formed in the hermetically sealed housing and secured to the cylinder.

According to an embodiment of the present invention, the spring guide in which the lamella spring is mounted is directly attached to the cylinder, so that the lamella spring can be installed to the cylinder accurately.

Clarification of drawings

Giant. 1 is a sectional view showing a schematic arrangement of a rotary compressor according to Embodiment 1.

Giant. 2 is an enlarged sectional view showing a compression mechanism unit in a rotary compressor according to Embodiment 1.

Giant. 3 is an enlarged view showing the construction of the spring-cylinder guide connection in the rotary compressor according to Embodiment 1.

Giant. 4 is a view showing the construction of a lamella spring mounting to a spring guide in a rotary compressor according to Embodiment 1.

Giant. 5 is a view showing a modification 1 of the rotary compressor spring guide according to Embodiment 1.

Giant. 6 is a view showing a modification 2 of the rotary compressor spring guide according to Embodiment 1.

Giant. 7 is a view showing the construction of a lamella spring mounting to a spring guide in a rotary compressor according to Embodiment 2.

Giant. 8 is a view showing the construction of the lamella spring mounting to the spring guide in the rotary compressor according to Embodiment 3.

Giant. 9 is a view showing a modification of the construction of the lamella spring mounting to the spring guide in the rotary compressor according to Embodiment 3.

Giant. 10 is a view showing the construction of the lamella spring mounting to the spring guide in the rotary compressor according to Embodiment 4.

Giant. is a diagram showing a cooling circuit of a cooling cycle device according to Embodiment 5.

-2GB 2022 - 182 A3

Examples of embodiments of the invention

In Embodiments 1 and 2, a rotary compressor for use in an air conditioner, refrigerator, refrigeration unit, or other device will be described as an example.

Embodiment 1

Giant. 1 is a sectional view showing a schematic arrangement of a rotary compressor according to Embodiment 1. FIG. 2 is an enlarged sectional view showing a compression mechanism unit in a rotary compressor according to Embodiment 1. FIG. 3 is an enlarged view showing the construction of the spring-cylinder guide connection in the rotary compressor according to Embodiment 1. Unless otherwise stated, in this description, the terms "radial direction", "circumferential direction" and "axial direction" mean "radial direction", "circumferential direction "and the" axial direction "of the cylinder.

The rotary compressor J comprises an electrical part 25, a compression part 10 which compresses the refrigerant, and a rotary shaft 17, which transmits the driving force of the electrical part 25 to the compression mechanism unit in the hermetically sealed housing 5.

As shown in Fig. 1, the hermetically sealed housing 5 is schematically a hollow, cylindrical, hermetically sealed housing. The hermetically sealed housing 5 is formed with a thickness to such an extent that the hermetically sealed housing 5 is not deformed by the internal pressure generated by the refrigerant compressed in the compression section 10. By increasing the thickness of the hermetically sealed housing 5 it is possible to reduce the deformation of the hermetically sealed housing 5 when installing the rotary compressor 1 to equipment such as an air conditioner and a refrigerator, for example by arc spot welding.

At the hermetically sealed housing 5, an accumulation vessel 28 is located outside the hermetically sealed housing 5 to reduce refrigerant noise. The storage tank 28 is connected via storage tank tubes 29 to two compression mechanisms (described later) which form the compression part 10. To the upper part of the hermetically sealed housing 5 is connected a discharge pipe 16 which discharges the refrigerant compressed by the compression part 10. At the bottom of the hermetically sealed housing 5 houses a refrigeration unit oil for lubricating the compression part 10. POE (polyol ester), PVE (polyvinyl ether), AB (alkylbenzene) or other materials which are synthetic oils can be used as the refrigeration unit oil.

The electrical part 25 comprises a hollow cylindrical stator 26 fixed to the inner circumference of the hermetically sealed housing 5 and a fixed cylindrical rotor 27 which is rotatably arranged on the inner side of the stator 26. The outer diameter of the stator 26 is larger than the inner diameter of the hermetically sealed housing 5. to the inner circumference of the hermetically sealed housing 5 by means of a hot-pressed bearing. The magnetic poles j are formed by permanent magnets on the rotor 27. The rotor 27 rotates by the action of the magnetic fluxes generated by the magnetic poles on the rotor 27 and the magnetic fluxes generated by the stator 26.

The electric portion 25 and the compression portion 10 are connected by a rotating shaft 17. The rotation of the electric portion 25 is transmitted to the compression portion 10, and the compression portion 10 compresses the refrigerant using the transmitted rotational force. The refrigerant compressed by the compression part 10 is discharged into the hermetically sealed housing 5 through an outlet 21 (see Fig. 2) formed in the compression part 10. Thereby, the interior of the hermetically sealed housing 5 is filled with high and high pressure compressed refrigerant gas.

The compression part 10 comprises two compression mechanisms arranged in the axial direction of the rotary shaft 17, an upper bearing 18, a lower bearing 19 and an intermediate plate 12. In other words, the compression part JO is of the multi-cylinder type comprising two compression mechanisms. The rotary compressor J is not limited to a multi-cylinder type containing a plurality of compression mechanisms, but may be a single-cylinder type containing a single compression mechanism.

-3 CZ 2022 - 182 A3

Because the compression mechanisms are configured similarly, only one of these compression mechanisms will be described for clarity. As shown in Fig. 2, the compression mechanism comprises a cylinder 11, a rolling piston 13, a lamella 14, a lamella spring 15 and a hollow cylindrical spring guide 30 in which the lamella spring 15 is mounted.

Cylinder U is formed by a circular plate. The cylinder chamber 11a in the cylinder 11 is open at both ends in the axial direction and the openings are closed by an intermediate plate 12 and one of the upper bearing 18 and the lower bearing 19. As shown in Figures 2 and 4, the cylinder 11 has a suction port 20 which leads through in the radial direction, and an outlet opening 21 formed on the inner circumference 11b of the cylinder 11. A pipe 29 of the storage container 28 is connected to the suction port 20.

As shown in Fig. 2, the rolling piston 13 is housed in the chamber 11a of the cylinder 11 in a state in which the rolling piston 13 is rotatably mounted to the eccentric portion 17a of the rotary shaft 17. The rolling piston 13 rotates eccentrically along the inner circumference 11b of the cylinder 11.

The cylinder 11 has a lamellar groove 22 which is connected to the cylinder chamber 11a and which extends in the radial direction. The lamella 14 is arranged in the lamella groove 22 so that the lamella 14 can move forwards and backwards in the radial direction. A lamella spring 15 is arranged on the rear side 14b of the lamella 14. A bearing recess is formed on the rear side 14b of the lamella 14, in which one end of the lamella spring 15 is accommodated. FIG. 2 shows a section through a storage depression. One end of the lamella spring 15 is fixed to the lower surface of the receiving recess. The other end of the lamella spring 15 is fixed to the inner surface of the spring guide 30 (described later).

The lamella spring 15 pushes the lamella 14 so as to bring the distal end 14a of the lamella 14 into contact with the rolling piston 13. The lamella 14 is pressed radially inwards by the pushing force of the lamella spring 15. so that the distal end 14a of the lamella 14 is constantly in contact with the rolling piston 13. the distal end 14a of the lamella 14 is thus in contact with the rolling piston 13, the inside of the cylinder chamber 11a is divided into a low-pressure space and a high-pressure space. As the roller piston 13 rotates eccentrically in the cylinder chamber 11a, the lamella 14 moves back and forth in the lamella groove 22, while the distal end 14a is in contact with the outer circumference 13c of the roller piston 13.

The spring guide 30 is made of ferrous material. The spring guide 30 is not limited to a high strength material such as a ferrous material and may be made of a low strength material such as a resin. One end of the spring guide 30 is fixed to a mounting recess 40 formed in the cylinder 11 and the other end of the spring guide 30 protrudes from the hermetically sealed housing 5 through an opening 8 formed in the hermetically sealed housing 5. The inner diameter of the opening 8 of the hermetically sealed housing 5 is larger than the outer diameter. spring guide 30. The spring guide 30 is fixed to the cylinder 11 without being in contact with the hermetically sealed housing 5. The method of fixing the spring guide 30 to the cylinder 11 is fixed in a manner such as assembly, crimping and screwing. Screwing is a fastening method comprising forming an externally threaded portion on one of the outer circumference of the spring guide 30 and the inner circumference of the mounting recess 40 of the cylinder 11 and an internally threaded portion on the other of the outer circumference of the spring guide 30 and the inner circumference of the mounting recess 40 of the cylinder 11 and screwing externally threaded parts with internally threaded part.

At one end of the spring guide 30, portions 31 are formed for the passage of the lamella. The lamella passage portions 31 are each formed by a slit extending from an end face at said one end of the spring guide 30 in the axial direction of the spring guide 30. The two lamella passages 31 are formed symmetrically with respect to the central axis of the spring guide 30. The lamella passage portions 31 are located on the extension line of the lamella groove 22 in the radial direction in a state where the spring guide 30 is fixed to the cylinder 11, as shown in Fig. 3.

Next, the dimensions of the spring guide 30 will be described. The diameter D1 of the spring guide 30 is smaller than the axial length (length in the direction perpendicular to the drawing sheet in Fig. 3) of the lamella 14. The radial width W1 of the part 31 for

-4GB 2022 - 182 A3 the lamella passage is larger than the width of the lamella 14 in the same direction. Thus, the lamella 14 passes through the lamella groove 22, then enters the lamella passage portions 31 without being in contact with the lamella passage portions 31, and returns.

The spring guide 30, to which the lamellar spring 15 is fixed, is arranged in a protruding part 6 positioned so as to protrude out of the hermetically sealed housing 5. The protruding part 6 is a cylindrical element whose cross-sectional shape is circular, rectangular or elongate. As shown in Fig. 2, the protruding portion 6 is installed in the hole 8 formed in the hermetically sealed housing 5 so that the center axis of the protruding portion 6 is perpendicular to the center axis of the cylinder 11. The protruding portion 6 is fixed to the hermetically sealed housing 5 by a press fit. the end of the protruding part 6 into the opening 8 formed in the hermetically sealed housing 5.

A cap portion 7 is attached to the end (hereinafter referred to as the outside end) of the protruding portion 6 opposite the side fixed to the hermetically sealed housing 5. The cap portion 7 is a cap that closes the end on the outside of the protruding portion 6. The cap portion 7 is connected with the end on the outside of the protruding part 6, for example by welding, brazing or other means. When the end on the outside of the protruding portion 6 is closed by the cap portion 7, the protruding portion 6 is hermetically sealed and the hermetically sealed housing 5 is hermetically sealed.

(Rotary compressor operation)

Next, the operation of the rotary compressor according to Embodiment 1 will be described. When electric power is supplied to the electric portion 25, the electric portion 25 rotates the rotary shaft 17. As the rotary shaft 17 rotates, the eccentric portion 17a rotates eccentrically in the cylinder chamber 11a. During the eccentric rotational movement of the eccentric portion 17a, the rolling piston 13 rotates eccentrically in the cylinder chamber 11a, and the low-pressure gaseous refrigerant introduced from the tube 29 of the storage vessel 28 into the cylinder chamber 11a is compressed. When the refrigerant gas compressed in the cylinder chamber 11a reaches the preset pressure, the refrigerant gas is discharged through the outlet 21 into the inner space of the hermetically sealed housing 5. Then, the high pressure gaseous refrigerant discharged into the inner space of the hermetically sealed housing 5 is discharged out of the hermetically sealed housing 5 through the outlet pipe. 16 housed in a hermetically sealed housing 5.

Here, the lamella 14 moves back and forth in the lamella groove 22 with the rotation of the rolling piston 13. As shown in Fig. 2, when the point of contact of the outer circumference 13c of the rolling piston 13 with the inner circumference 11b of the cylinder 11 corresponds in phase to the arrangement of the lamella 14 (hereinafter referred to as when the rolling piston 13 is in the phase position of the lamella groove), the lamella 14 is shifted. backwards, i.e. in the direction away from the cylinder 11. and is in the top dead center position. When the point of contact of the outer circumference 13c of the rolling piston 13 with the inner circumference 11b of the phase cylinder 11 differs by 180 degrees from the arrangement of the lamella 14, the lamella 14 is moved forward, i.e. towards the center of the cylinder 11. and is in the bottom dead center position. In this way, the lamella 14 moves back and forth between the top dead center position and the bottom dead center position. When the rolling piston 13 is rotated 90 degrees from the location of Fig. 2, the lamella 14 is in an intermediate position between the top dead center position and the bottom dead center position.

Thus, the range of reciprocating movement of the lamella 14 between the upper dead center position and the lower dead center position, and the positions of the lamella 14 relative to the spring guide 30 when the lamella 14 is in the upper dead center position, the lower dead center position and the intermediate position, are as follows.

When the lamella 14 is in the top dead center position shown in Fig. 2, the rear side 14b of the lamella 14 is located in the lamella passage portions 31 of the spring guide 30. When the lamella 14 is in the bottom dead center position, the rear side 14b of the lamella 14 is not located in the lamella passage portions 31 of the spring guide 30. When the lamella 14 is in the intermediate position, the rear side 14b of the lamella 14 is not located in the lamella passage portions 31 of the spring guide 30. The reason for the above arrangement is the advantage during production and this point will be described later.

-5GB 2022 - 182 A3

During operation of the rotary compressor 1, so-called liquid backflow can occur, i.e. the liquid refrigerant flows into the hermetically sealed housing 5. In the case of liquid backflow, the internal pressure of the cylinder chamber 11a increases sharply so that the fin 14 is pushed radially outwards. In this case, the lamella 14 is moved radially outwards beyond the top dead center position and stops at the point where the rear side 14b of the lamella 14 is in contact with the lower surfaces 31a of the lamella passage portion 31 of the spring guide 30. In other words, the lower surfaces 31a of the lamella passage portion 31 function as a stop for the lamella 14 in the event of liquid backflow. The radial location of the lower surfaces 31a of the lamella passage portion 31 is adjusted so that the length of the lamella spring 15 does not become a length of tight contact in a situation where the rear side 14b of the lamella 14 is in contact with the lower surfaces 31a of the lamella passage portion 31. For this reason, in the case of backflow of liquid or other events at a time when the internal pressure of the cylinder chamber 11a increases sharply, the pressure spring 15 is not subjected to excessive pressure.

The rotary compressor 1 of Embodiment 1 has a structure in which the protruding portion 6 is mounted so as to protrude out of the hermetically sealed housing 5. Therefore, in a sense, the structure is such that the housing of the rotary compressor 1 extends radially by the installation portion. Therefore, there is no restriction on the distance between the rear side 14b of the lamella 14 and the inner circumference of the hermetically sealed housing 5, and the total length of the lamella spring 15 can be freely adjusted. The length of the lamella spring 15 can be freely adjusted by adjusting the length of the protruding portion 6. Therefore, it is possible to reduce the expansion and contraction of the lamella spring 15 by extending the total length of the lamella spring 15. fatigue resistance under stress which repeatedly acts on the lamella spring 15. in comparison with the use of a spring with a high rate of expansion and contraction. As a result, it is possible to increase the pushing force that pushes the lamella 14 against the rolling piston 13 while ensuring fatigue strength.

If it is not possible to increase the compression force of the lamella spring 15 and the force of the compression lamella 14 against the rolling piston 13 is insufficient, the lamella 14 cannot follow the movement of the rolling piston 13 when the lamella 14 is in the bottom dead center position. In other words, the distal end 14a of the lamella 14 separates from the rolling piston 13. In this case, noise and vibration occur.

Conversely, in Embodiment 1, since the total length of the lamella spring 15 can be freely adjusted as described above, it is possible to provide sufficient fatigue strength by extending the total length of the lamella spring 15 to reduce the expansion and contraction rate of the lamella spring 15. Therefore, it is possible to achieve the necessary compressive forces to constantly press the lamella 14 against the rolling piston 13 while ensuring sufficient fatigue resistance, so that it is possible to suppress the noise and vibrations which occur when the lamella 14 separates from the rolling piston 13.

In embodiment 1, it is possible to freely adjust the distance between the cap portion 7 and the spring guide 30 by adjusting the length of the protruding portion 6, whereby the following advantageous effects can be achieved. When the distance between the cap portion 7 and the spring guide 30 is short, there is a possibility that the heat generated when connecting the cap portion 7 to the protruding portion 6 by welding, brazing or other means will be conducted through the cap portion 7 to the lamellar spring 15 and consequently Conversely, in embodiment 1, the distance between the cap portion 7 and the spring guide 30 can be set freely, so that the deterioration of the lamella spring 15 due to the heat conducted to the lamella spring 15 during connection can be prevented so as to ensure sufficient distance.

Incidentally, the current rotary compressor has a construction in which the vane spring is arranged in a cylindrical spring guide positioned so as to protrude from the hermetically sealed housing. The spring guide is the part that forms part of the rotary compressor housing together with the hermetically sealed housing, and the internal pressure exerted by the refrigerant discharged from the compression unit acts on these housing components. The components of the casing change their shape, eg by bulging out under the influence of internal pressure. For this reason, in a structure in which the spring guide is fixed to the housing components, it is not possible to arrange the spring guide, and consequently the lamella spring, on the intended

-6GB 2022 - 182 A3 location due to deformation of casing components due to internal pressure. The intended point is a point perpendicular to the central axis of the cylinder 11.

Conversely, in embodiment 1, the lamella spring 15 is fixed to the spring guide 30, which is a component that is different from the housing components, and the spring guide 30 is fixed directly to the cylinder H. Therefore, it is possible to install the lamella spring 15 accurately, which allows stable operation springs 15.

Next, the construction of the attachment of the lamella spring 15 to the spring guide 30 will be described. The rotary compressors 1 according to Embodiment 1 and Embodiments 2 to 4 (described later) each have a structure in which the vane spring 15 is fixed to the spring guide 30 by bringing the large diameter portion 15b (see Fig. 4) of the vane spring 15 into contact with the inner surface. spring guide 30 as a common construction. Embodiment 1 relates to the construction of the attachment of the lamella spring 15 to the spring guide 30 by pressing.

Giant. 4 is a view showing the construction of a lamella spring mounting to guide a spring in a rotary compressor according to Embodiment 1. The lamella spring 15 is a coil spring formed by winding a rolled wire made of metal or other materials into a coil shape. The lamella spring 15 has a small diameter portion 15a and a large diameter portion 15b which has a larger diameter than the small diameter portion 15a. The small diameter portion 15a has a non-expandable and non-shrinkable portion 15aa and an expandable and shrinkable portion 15ab that expands and contracts as the lamella 14 moves. tight contact of rolled wire.

The lamella spring 15 is mounted in the cylindrical spring guide 30 at the large diameter portion 15b. In other words, the diameter of the large diameter portion 15b is reduced by pressing the large diameter portion 15b of the lamella spring 15 into the spring guide 30, and the lamella spring 15 is fixed in the spring guide 30 by a return force trying to restore the diameter.

The spring guide 30 shown in Fig. 4 and other drawings has the shape of a hollow cylinder with a uniform inner diameter. Alternatively, the spring guide 30 may be provided as shown in Fig. 5 or Fig. 6 below.

Giant. 5 is a view showing a modification 1 of the rotary compressor spring guide according to Embodiment 1. FIG. 6 is a view showing a modification 2 of the rotary compressor spring guide according to Embodiment 1.

The spring guides 30 of Figs. 5 and 6 are each configured so that the inner diameter D2 of the portion (hereinafter referred to as the non-fixing portion) 32b other than the portion (hereinafter referred to as the fixing portion) 32a. to which the large diameter part of the lamella spring 15 is fixed 15b is wider than the inner diameter D3 of the fixing portion 32a. In this arrangement, it is ensured that the gap between the outer circumference of the small diameter portion 15a and the inner circumference of the non-fixing portion 32b of the spring guide 30 is wider than the gap in the arrangement of Fig. 4. and a spring guide 30 required for pressing. In other words, if the gap is narrow, it may be difficult to insert the lamella spring 15, or it is not possible to insert the lamella spring at all because it will catch on the inner circumference of the spring guide 30 unless the lamella spring 15 slides into the spring guide 30 in perfect alignment between the lamella. spring 15 and spring guide 30.

Conversely, in the arrangement of Figs. between the lamella spring 15 and the spring guide 30.

-7 CZ 2022 - 182 A3

As shown in Fig. 6, the inner circumference of the spring guide 30 may have an inclined surface 33 which seamlessly connects the inner circumference of the mounting portion 32a to the inner circumference of the non-mounting portion 32b. This arrangement improves the rigidity of the spring guide 30. Because the rigidity of the spring guide 30 is improved, it is possible to reduce the deformation of the spring guide 30 from the loading of the large-diameter portion 15b of the lamella spring 15 into the spring guide 30.

Next, the assembly procedure of the relevant part of the rotary compressor L will be described. 5 to which the protruding part 6 is connected. Each of the rollers 11 is fixed to the hermetically sealed housing 5 in a position in which the lamella groove 22 faces the opening 8 of the hermetically sealed housing 5. Then the lamella 14 is inserted into the lamella groove 22 of one of the two of the cylinders 11 fixed to the hermetically sealed housing 5. Subsequently, the spring guide 30 is connected to the cylinder 11 and the lamella spring 15 is inserted into the spring guide 30 and fastened. In the second of the rollers 11, the lamella 14, the spring guide 30 and the lamella spring 15 are fastened similarly. Then the lid part 7 is connected to the protruding part 6.

In said assembly procedure, the spring guide 30 is mounted to the cylinder 11, and then the lamella spring 15 is fixed to the spring guide 30; however, this order may be reversed. In other words, the lamella spring 15 can be attached to the spring guide 30, and then the spring guide 30 can be installed to the cylinder 11.

If the spring guide 30 were not used here and one end of the lamella spring 15 was fixed to the rear side 14b of the lamella 14 and the other end was brought into contact with the cap part 7 to hold the lamella spring 15 in the protruding part 6. In contrast, in embodiment 1, at the moment when the lid portion 7 connects to the protruding portion 6, the lamella spring 15 is fixed to a spring guide 30 connected to the cylinder 11. so that there is no need to press and hold the lamella spring 15. This means assembly is easy.

When the lamella spring 15 is fixed to the spring guide 30, the rolling piston 13 is placed in the phase position of the lamella groove by turning the rotary shaft 17 and the lamella 14 is placed in the bottom dead center position. Thus, in comparison with, for example, when the lamella 14 is in the top dead center position, it is possible to install the lamella spring 15 in a state where the length of the lamella spring 15 is large, i.e. in a state in which the elastic force acting on the lamella spring 15 is , small, which simplifies installation.

The rolling piston 13 in one of the cylinders 11 and the rolling piston 13 in the other cylinder 11 are phase shifted by 180 degrees. For this reason, when the rolling piston 13 in one of the cylinders 11 is in the phase position of the lamellar groove, the rolling piston 13 in the other cylinder 11 is in a position phase shifted by 180 degrees from the phase position of the lamellar groove. Therefore, when inserting the lamella spring 15 into one of the cylinders 11, the rolling piston 13 is initially set to a position which is 180 degrees out of phase with the phase position of the lamella groove, the lamella 14 is placed in the bottom dead center position, and then the lamella spring 15 is inserted. Then, when inserting the lamella spring 15 into the second of the cylinders 11, the rotary shaft 17 rotates 180 degrees, the rolling piston 13 is similarly placed in a position which is 180 degrees out of phase of the lamella groove, the lamella 14 is set to the lower position. dead center, and then the lamella spring 15 is inserted.

When the spring guide 30 is fixed to the cylinder 11 by screwing, the spring guide 30 rotates in a state where one end 30a of the spring guide 30 is inserted into the mounting recess 40. Therefore, when rotating the spring guide 30, the rear side 14b of the lamella 14 is in the lamella passage portions 31 of the spring guide 30, it is not possible to rotate the spring guide 30. Therefore, the operation of rotation by the spring guide 30 is performed in a state where the lamella 14 is positioned so that the rear side 14b of the lamella 14 is not in the lamella passage portions 31. Specifically, for example, the lamella 14 is in the bottom dead center position or the intermediate position described above. The reason why the rear side 14b of the lamella 14 is not in the lamella passage portions 31 when the lamella 14 is in position

-8EN 2022 - 182 A3 bottom dead center or in the intermediate position, is not to impede the rotation of the spring guide 30 at the moment when the spring guide 30 is thus fastened by means of a screw fastening.

As described above, the rotary compressor 1 according to embodiment 1 comprises a hermetically sealed housing 5, a circular cylinder 11 housed in a hermetically sealed housing 5, a rolling piston 13 which rotates eccentrically along the inner circumference 11b of the cylinder 11 and a lamella 14 moving there. and back in the lamellar groove 22 formed in the cylinder 11 in the radial direction. The rotary compressor 1 further comprises a vane spring 15, which is a coil spring which presses on the vane 14 so as to bring the distal end 14a of the vane 14 into contact with the rolling piston 13. and which has a small diameter portion 15a and a large diameter portion 15b. which has a larger diameter than the small diameter portion 15a, and the spring guide 30 to which the lamella spring 15 is fixed by contacting the large diameter portion 15b of the lamella spring 15 with the inner surface of the spring guide 30. The spring guide 30 has one end inserted into the hermetically sealed housing 5 through an opening 8 formed in the hermetically sealed housing 5 and fixed to the cylinder 11.

Since the spring guide 30 in which the lamella spring 15 is mounted is directly attached to the cylinder 11, it is possible in this way to install the lamella spring 15 to the cylinder 11 precisely. As a result, it is possible to operate the lamella spring 15 stably.

The inner diameter of the opening 8 of the hermetically sealed housing 5 is larger than the outer diameter of the spring guide 30. The spring guide 30 is fixed to the cylinder 11 without being in contact with the hermetically sealed housing 5.

Thus, since the spring guide 30 can be fixed to the cylinder without being subjected to the deformation of the hermetically sealed housing 5, it is further possible to precisely install the lamellar spring 15 to the cylinder 11.

The lamella spring 15 is fixed by pressing a large-diameter portion 15b into the spring guide 30.

In this way, it is possible to fasten the lamella spring 15 to the spring guide 30 by pressing a large-diameter part 15b.

The spring guide 30 is configured such that the inner diameter of the non-fixing portion 32b is larger than the inner diameter of the fixing portion 32a.

This provides a wide gap between the outer circumference of the small diameter lamella spring 15a and the inner circumference of the non-fixing portion 32b of the spring guide 30, which facilitates the accuracy of the alignment between the lamella spring 15 and the spring guide 30.

Embodiment 2

The rotary compressor 1 according to Embodiment 2 differs from the rotary compressor according to Embodiment 1 in the manner of fixing the vane spring 15 to the spring guide 30A. In embodiment 1, crimping is used; in contrast, in embodiment 2, a screw fastening is used. Next, the difference between Embodiment 2 and Embodiment 1 will be mainly described, and components not described in Embodiment 2 are similar to the components of Embodiment 1.

Giant. 7 is a view showing the construction of fixing the vane spring to the spring guide in the rotary compressor according to Embodiment 2. In Embodiment 2, a screw fixing is used to fix the vane spring 15 to the spring guide 30A. The hollow cylindrical spring guide 30A according to Embodiment 2 has a threaded groove 34 on the inner circumference at the rear end in the screw insertion direction. The threaded groove 34 is a spiral groove.

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In embodiment 2, the lamella spring 15 is fixed in the spring guide 30A by screwing a large diameter portion 15b of the lamella spring 15 into the threaded groove 34.

In such a screw mounting, the large diameter portion 15b of the lamella spring 15 is installed so as to be guided along the threaded groove 34 of the spring guide 30A. For this reason, the accuracy of the installation location and the position of the lamella spring 15 is improved here.

During operation of the rotary compressor 1, the vane spring 15 is acted upon by the resilient force of the vane spring 15, which expands and contracts as the vane 14 moves. as a result of these forces. For this reason, the threaded groove 34 of the spring guide 30A and the large diameter portion 15b of the lamella spring 15 need to be designed in shapes and dimensions that provide a restraining force that does not deflect the lamella spring 15. Specifically, the cross-sectional shape of the threaded groove 34 is set in the form of a semicircle formed along the rolled wire of the lamellar spring 15, and the diameter of the semicircle is set to a diameter corresponding to the diameter of the wire of the lamellar spring 15. The diameter corresponding to the diameter of the wire of the lamellar spring 15 includes , or which is slightly smaller than the diameter of the lamella spring wire 15.

As described above, the spring guide 30A of the rotary compressor 1 according to Embodiment 2 has a threaded groove 34 on its inner circumference. The lamella spring 15 is fixed to the spring guide by screwing a large diameter portion 15b of the spring guide 30A into the threaded groove 34.

Because the lamella spring 15 is secured to the spring guide 30A by screwing a large diameter portion 15b of the spring guide 30A into the threaded groove 34, the accuracy of the installation location and position of the lamella spring 15 is improved.

The cross-sectional shape of the threaded groove 34 is a semicircle shape, and the diameter of this semicircle corresponds to the wire diameter of the lamellar spring 15.

In this way, it is possible to suppress the deflection of the lamella spring 15 from its original fixed location.

Embodiment 3

The rotary compressor 1 according to embodiment 3 differs from the rotary compressor according to embodiment 1 in the manner of fixing the vane spring 15 to the spring guide 30. The fastening method according to embodiment 3 is a groove fastening. Next, the difference between Embodiment 3 and Embodiment 1 will be mainly described, and components not described in Embodiment 3 are similar to the components of Embodiment 1.

Giant. 8 is a view showing the construction of the vane spring mounting to the spring guide in the rotary compressor according to Embodiment 3. In Embodiment 3, a groove mounting is used to mount the vane spring 15 to the spring guide 3OB. The hollow cylindrical spring guide 3OB according to Embodiment 3 has a circumferential groove 35 with a rectangular cross-sectional shape on its inner circumference. The lamella spring 15 is fixed in the spring guide 30 by pressing the large diameter portion 15b of the lamella spring 15 into the groove 35. The cross-sectional shape is not limited to a rectangular shape and may be another selected shape.

During operation of the rotary compressor 1, the elastic force of the lamella spring 15 acts on the vane spring 15, which expands and contracts according to the movement of the vane 14. inertial force of the vane spring 15 and the vibration force of the rotary compressor 1. caused by contact with the inner circumference of the 3 OB spring guide. The resulting force obtained by taking into account the directions of these forces acts in such a way as to cause the lamella spring 15 to deflect. For this reason, the lamella spring 15 may deviate from its original fixed position during continued operation.

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Therefore, the lamella spring 15 is fixed to the spring guide 3OB using a holding force that prevents it from deviating from a given fixed location. When the lamella spring 15 is attached to the spring guide 3OB, if the overlap of the press fit of the large diameter portion 15b with respect to the groove 35 is too large, it is not possible to insert the lamella spring 15 into the spring guide 30B. On the other hand, when the overlap of the press bearing is small, there is a problem that the lamella spring 15 is easily deflected. .

The overlap of the press bearing is greater than or equal to the overlap of the press bearing by which the large diameter portion 15b of the lamella spring 15 moves radially outward in the groove 35 by the elastic force of the lamella spring 15 when the roller piston 13 is in the phase position of the lamella groove , i.e. when the lamella 14 is in the top dead center position. The overhang of the press fit is less than or equal to the overhang of the press fit by which the large diameter portion 15b does not move in the groove 35 due to the inertial force of the lamella spring 15 itself when the roller piston 13 is 180 degrees out of phase. from the phase location of the lamella groove, i.e. when the lamella 14 is in the bottom dead center position.

Giant. 8 shows an arrangement in which the lamella spring 15 is fixed in the spring guide 3OB by pressing a large-diameter portion 15b of the lamella spring 15 into a groove 35; however, an arrangement as shown in Fig. 9 may be used.

Giant. 9 is a view showing a modification of the design of the vane spring mounting to guide the spring in the rotary compressor according to Embodiment 3. In this modification, a medium diameter portion 15c having a larger diameter than the portion 15a with a larger diameter is arranged between the small diameter portion 15a and the large diameter portion 15b. small diameter and smaller diameter than the large diameter portion 15b. The medium diameter portion 15c is pressed against the inner circumference of the spring guide 30B. By means of this arrangement, where the lamella spring 15 is fixed in the spring guide 3OB of both the large-diameter portion 15b and the medium-diameter portion 15c, it is possible to further increase the holding force, which makes it possible to increase the deflection prevention effect. The arrangement of Fig. 9 can be considered as an arrangement in which the locating portion formed by another large diameter non-expanding and non-shrinking portion is located further radially outward from the large diameter portion 15b of the lamellar spring 15 shown in Fig. 4 and the locating portion is housed in grooves 35.

The spring guide 30 OB of the rotary compressor 1 according to Embodiment 3 has a circumferential groove 35 on its inner circumference, and the vane spring 15 is fixed to the spring guide by accommodating a large diameter portion 15b of the vane spring 15 in the groove 35.

Thus, the lamella spring 15 can be fixed by accommodating the large diameter portion 15b of the lamella spring 15 in a circumferential groove 35 formed on the inner circumference of the spring guide 30B.

The lamella 14 moves back and forth between the position of the bottom dead center at the front, i.e. towards the center of the cylinder 11, and the position of the top dead center at the rear, i.e. away from the cylinder 11. The lamella spring 15 is pressed into the large diameter portion 15b The overlap of the press fit of the large diameter portion 15b relative to the groove 35 is set to be greater than or equal to the overlap of the press fit by which the large diameter portion 15b of the lamella spring 15 moves radially outward in the groove 35. by the elastic force of the lamella spring 15 when the rolling piston 13 is in the phase position of the lamella groove, and was less than or equal to the overlap of the press bearing by which the large diameter portion 15b does not move in the groove 35 by the inertial force of the lamella itself. springs when the rolling piston 13 is in a position which is phase shifted by 180 degrees from the phase position of the lamellar groove.

This makes it possible to prevent the lamella spring 15 from deflecting.

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Embodiment 4

The rotary compressor 1 according to Embodiment 4 differs from the rotary compressor according to Embodiment 1 in the manner of fixing the vane spring 15 to the spring guide 30C. In embodiment 1, crimping is used; in contrast, in embodiment 4, a cap fastening is used. Next, the difference between Embodiment 4 and Embodiment 1 will be mainly described, and components not described in Embodiment 4 are similar to the components of Embodiment 1.

Giant. 10 is a view showing the construction of the vane spring mounting to the spring guide in the rotary compressor according to Embodiment 4. In Embodiment 4, a cap mounting is used to mount the vane spring 15 to the spring guide 30C. In Embodiment 1, the inner diameter of the spring guide 30 is smaller than the outer diameter of the large diameter portion 15b of the lamella spring 15, and the large diameter portion 15b is pressed into the spring guide 30 and fixed therein. In Embodiment 4, the inner diameter of the spring guide 30C is larger than the outer diameter of the large diameter portion 15b of the lamella spring 15, and the entire lamella spring 15 including the large diameter portion 15b is not in contact with the spring guide 30C.

The spring guide 30C according to Embodiment 4 has a hollow cylindrical portion 36 and a spring cap 37 that closes the end of the hollow cylindrical portion 36. The lamella spring 15 is fixed between the lamella 14 and the spring cap 37 in a state where it is permanently shrunk compared to natural length. In this way, the lamella spring 15 is arranged in the spring guide 30C in a contracted state, and the lamella spring 15 is fixed in the spring guide 30C.

Next, the assembly product of the relevant part of the rotary compressor L will first be described. 5 to which the protruding portion 6 is connected. Each of the rollers 11 is fixed to the hermetically sealed housing 5 in a position in which the mounting recess 40 faces the opening 8 of the hermetically sealed housing 5. Then the lamella grooves 22 of one of the two cylinders 11 fixed to the hermetically sealed housing 5. Subsequently, the spring guide 30C is inserted from the end of the opening of the protruding portion 6 and the end of the spring guide 30C is fixed to the mounting recess 40 of the cylinder 11. Then the lamella spring 15 is inserted and in the 30C spring guide. In the second of the rollers 11, the lamella 14 of the spring guide 30C and the lamella spring 15 are fixed similarly. Then the lid part 7 is connected to the protruding part 6.

In said assembly procedure, the spring guide 30 is mounted in the cylinder 11, and then the lamella spring 15 is fixed to the spring guide 30; however, this order may be reversed. In other words, the lamellar spring 15 can be fixed to the spring guide 30, and then the spring guide 30 can be installed in the cylinder 11.

In the rotary compressor 1 according to Embodiment 4, the spring guide 30 has a hollow cylindrical portion 36 and a spring cap 37 which closes the end of the hollow cylindrical portion 36. The lamella spring 15 is fixed between the lamella 14 and the spring cap 37 in a permanently contracted state compared to natural length. In this way, the lamella spring 15 can be fastened in the spring guide 30.

Embodiment 5

Embodiment 5 relates to a refrigeration cycle device comprising a rotary compressor 1 according to any one of Embodiments 1 to 4.

Giant. 11 is a diagram showing a refrigerant circuit of a refrigeration cycle apparatus according to Embodiment 5. The refrigeration cycle apparatus 50 includes a rotary compressor 1 according to any one of Embodiments 1 to 4, a condenser 51, an expansion valve 52 serving as a pressure relief device, and a blast 53. Gaseous refrigerant discharged from of the compressor 1 flows into the condenser 51, exchanges heat with the air passing through the condenser 51 and flows out as a high-pressure liquid refrigerant. AT

-12 CZ 2022 - 182 A3 of high-pressure liquid refrigerant flowing out of the condenser 51, the pressure is reduced by means of the expansion valve 52, whereby the refrigerant changes to low-pressure two-phase gaseous-liquid refrigerant and flows to the outlet 53. Low-pressure two-phase gaseous-liquid refrigerant flowing to the outlet 53 exchanges heat with the air passing through the outlet 53, thus changing the refrigerant to low-pressure gaseous 5, which is reintroduced into the rotary compressor L

The refrigeration cycle device 50 thus configured comprises a rotary compressor 1 according to any one of embodiments 1 to 4, thereby achieving stable operation of the lamella 14 and the lamella spring 15. It is also possible to prevent the spring guide from falling out of the cylinder 11. cycle with high reliability.

The refrigeration cycle device 50 is useful in an air conditioner, refrigerator, refrigeration unit, or other device.

Claims (10)

PATENT CLAIMS A rotary compressor (1), comprising: a hermetically sealed housing (5); a circular cylinder (11) housed in a hermetically sealed housing (5); a rolling piston (13) that rotates eccentrically along the inner circumference (11b) of the cylinder (11); a lamella (14) that moves back and forth in the lamella groove (22) formed in the cylinder (11) in the radial direction; a lamella spring (15), which is a helical spring that presses on the lamella (14) so as to bring the distal end (14a) of the lamella (14) into contact with the rolling piston (13), and which has a small diameter portion (15a) and a large diameter portion (15b) having a larger diameter than the small diameter portion (15a); and a spring guide (30) to which the lamella spring (15) is attached by making contact of the large diameter portion (15b) of the lamella spring (15) with the inner surface of the spring guide (30), the spring guide (30) having one end (30a) ) inserted into the hermetically sealed housing (5) through an opening (8) formed in the hermetically sealed housing (5) and fixed to the cylinder (11). The rotary compressor (1) of claim 1, wherein the inner diameter of the opening of the hermetically sealed housing (5) is configured to be larger than the outer diameter of the spring guide (30), and the spring guide (30) is fixed to the cylinder (11). without being in contact with the hermetically sealed housing (5). A rotary compressor (1) according to claim 1 or 2, wherein the vane spring (15) is mounted such that the large diameter portion (15b) is pressed into the spring guide (30). The rotary compressor (1) according to claim 3, wherein the spring guide (30) is configured such that the inner diameter of the portion other than the portion to which the large diameter lamella spring portion (15b) is attached is larger than the inner the diameter of the part to which the large diameter portion (15) is attached. The rotary compressor (1) according to claim 3, wherein the spring guide (30) has a threaded groove (34) on its inner circumference, and the lamella spring (15) is fixed to the spring guide (30) by screwing in a large diameter portion (15b). guiding (30) the spring into the threaded groove (34). The rotary compressor (1) according to claim 5, wherein the cross-sectional shape of the threaded groove (34) is a semicircle shape, and the diameter of this semicircle corresponds to the wire diameter of the lamellar spring (15). The rotary compressor (1) according to claim 3, wherein the spring guide (30) has a circumferential groove on its inner circumference, and the vane spring (15) is fixed to the spring guide (30) by accommodating a large diameter portion (15b) of the vane spring ( 15) into the groove. A rotary compressor (1) according to claim 7, wherein the vane (14) is configured to move back and forth between the bottom dead center position at the front, i.e. towards the center of the cylinder (11), and the top dead center position at the rear. side, i.e. away from the cylinder (11), the lamella spring (15) is pressed into the groove by fitting a large diameter portion (15b), and the overlap of the pressed large diameter portion (15b) relative to the groove is set to be larger than, or equal to, the overlap of the press bearing by which the large diameter portion (15b) of the lamella spring (15) moves outward in the groove in the radial direction by the elastic force of the lamella spring (15) when the lamella (14) is in position upper dead center, such that it is less than or equal to the overlap of the press bearing, by which the large diameter part (15b) does not move in the groove due to the inertial force of the lamella spring (15) caused by the elastic force of the lamella spring ( 15) when the lamella (14) is in the bottom dead center position. A rotary compressor (1) according to any one of claims 1 to 8, wherein the spring guide (30) has a hollow cylindrical portion (36) and a spring cap (37) which closes the end of the hollow cylindrical portion (36), and a lamella spring (15). ) is fixed between the lamella (14) and the spring cap (37) in a state in which it is permanently shrunk compared to its natural length. - 14GB 2022 - 182 A3 Refrigeration cycle device (50), comprising a rotary compressor (1) according to any one of claims 1 to 9.