KR100524791B1 - Hermetic compressor - Google Patents

Abstract

The present invention relates to a hermetic compressor, comprising: an upper bearing having a discharge flow path through which compressed fluid is discharged on both sides of a cylinder; a cylinder assembly having a lower bearing coupled to form a sealed inner space; and an upper bearing of the cylinder assembly. And a partition plate having a corrugated shape partitioning an inner space of the cylinder assembly on one side of the rotary shaft inserted into the lower bearing, and elastically supported to move in parallel to the longitudinal direction of the rotary shaft and to be in contact with both sides of the partition plate. And a respective vane configured to be compressed to compress the fluid in the inner space of the cylinder assembly partitioned by the partition plate of the rotary shaft according to the rotation of the rotary shaft, and to discharge the fluid through the discharge passage. On the cylinder to reduce overcompression loss and noise At least one resonator into which the fluid discharged through the discharge passage flows is formed, and thus, when the compressed fluid is discharged through the discharge passage, overcompression loss and noise can be reduced by the resonator.

Description

Hermetic rotary compressors {HERMETIC COMPRESSOR}

The present invention relates to a hermetic rotary compressor, and in more detail, a resonator is formed in a cylinder to reduce the overcompression loss and noise of the fluid discharged when the compressed fluid is discharged through the discharge flow path of the hermetic rotary compressor. It relates to a hermetic rotary compressor.

In general, a compressor is a machine for compressing a fluid. The configuration of such a compressor includes a hermetically sealed container having a predetermined internal space, an electric machine part mounted in the hermetically sealed container to generate a driving force, and a fluid received by the driving force of the electric machine part. Compressor section for compressing.

Such compressors are generally classified into various types, such as a rotary compressor, a rotary compressor, and a scroll compressor according to the shape of a compression mechanism for compressing a fluid.

1 to 3 illustrate one of the compressors as an example, and as shown, the compression mechanism of the compressor having a conventional structure includes an internal space V and an internal space V thereof. The rotary shaft 20 is provided so that the suction passage f1 and the discharge passage f2 communicate with each other, and penetrate the center of the inner space V of the cylinder assembly D fixedly coupled to the sealed container 10. Is inserted, the rotary shaft 20 is coupled to the power mechanism (M) for generating a driving force required for rotation.

The cylinder assembly (D) is provided with a cylindrical through hole therein and is fixed to the cylinder 30 fixed to the closed container 10 and the upper and lower surfaces of the cylinder 30 are respectively coupled with the cylinder 30 In addition to forming an inner space (V) and comprises an upper bearing 40 and a lower bearing 50 for supporting the rotating shaft 20, the cylinder 30 has an inner space of the cylinder ( In V), a suction flow path f1 radially penetrated toward the outer circumferential surface is formed.

The upper bearing 40 and the lower bearing 50 protrude to have plate portions 41 and 51 formed to have a predetermined thickness and area, and have a predetermined height and outer diameter on one surface of the plate portions 41 and 51. And the support portions 42 and 52 formed therein, and the shaft insertion holes 43 and 53 formed through the central portions of the plate portions 41 and 51 and the support portions 42 and 52, respectively. The plate portion 41 of the 40 covers the contact surface of the cylinder 30 and is coupled to the shaft insertion hole 43 such that the rotation shaft 20 is interpolated, and the lower bearing 50 is The other side of the cylinder 30 is covered, and the rotation shaft 20 is coupled to the insertion hole 53 so as to be interpolated.

The rotating shaft 20 is formed to have a predetermined outer diameter and a predetermined length is inserted into the shaft insertion hole (43. 53) of the upper bearing 40 and the lower bearing 50, and the shaft portion 21 A partition plate 22 extending from one side thereof and partitioning the internal space V of the cylinder assembly D into the first space V1 and the second space V2 is provided.

The partition plate 22 of the rotating shaft 20 has a predetermined thickness, and is formed in a circular shape when viewed on a plane, and when viewed from a side, an upper convex curved portion r1 having a convex surface and a lower side having a concave surface. It consists of a concave curved surface part r2, and the connection curved surface part r3 which connects the convex curved surface part r1 and the concave curved surface part r2. That is, the partition plate 22 forms a sinusoidal waveform surface, and the convex curved portion r1 and the concave curved portion r2 are formed to have a phase difference of 180 degrees.

The first and second spaces V1a and V2a are respectively elastically supported to be in contact with both side surfaces of the partition plate 22 so that the partition plate 22 rotates. ) And the vanes 70 moving in parallel to the longitudinal direction of the rotation shaft 20 while switching to the compression zones V1b and V2b are respectively provided on the upper bearing 40 and the lower bearing 50 of the cylinder assembly D. FIG. Inserted through and combined.

The vanes 70 are supported by the elastic support means 100 fixed to the upper bearing 40 and the lower bearing 50, the same phase when the cylinder assembly (D) is viewed in a horizontal plane, that is, the partition plate ( 22 and the vanes 70 are inserted into vane slots 44 and 54 formed in the upper bearing 40 and the lower bearing 50 of the cylinder assembly D, respectively.

An opening and closing for discharging the compressed fluid in the compression regions V1b and V2b of the first space V1 and the second space V2 while opening and closing each discharge passage f2 formed in the cylinder assembly D, respectively. The means (80) are respectively coupled, and the suction pipe (90) is coupled to the hermetic container (10) so as to communicate with the suction passage (f1).

Reference numeral 110 is a silencer.

The compressor configured as described above is operated as follows.

When the rotary shaft 20 is rotated by receiving the driving force of the power mechanism (M) operated by the power is applied, the partition plate 22 formed on one side of the rotary shaft 20 is the inside of the cylinder assembly (D). It is rotated in the space (V).

As shown in FIGS. 3 and 4, the vanes 70 of which the front end of the convex curved portion r1 of the partition plate 22 is positioned in the first space V1 and the second space V2 are respectively located. In the first space V1, the discharge of the compressed fluid filled in the compression area V1b is completed through the discharge channel f2 and the suction channel f1 in the first space V1. The suction of the suction region V1a is completed, and the fluid is sucked into the suction region V2a through the suction passage f1 in the second space V2 and the fluid compression is performed in the compression region V2b. It is in a progress state.

Next, the partition plate 22 is rotated so that the front end of the concave curved portion r2 of the partition plate 22 is the first space V1 and the second space V2. When the vanes 70 are positioned at the positions a1 of the vanes 70, the fluid is sucked into the suction region V1a through the suction passage f1 in the first space V1 and at the same time, the compression region V1b. In the second space (V2), the discharge of the compressed fluid filled in the compression area (V2b) is completed through the discharge flow path (f2) and the suction area (V2a) The suction is completed.

As such, each time the partition plate 22 rotates in the inner space V of the cylinder assembly D, the fluid is sucked, compressed, and discharged in the first space V1 and the second space V2, respectively. The operation is performed repeatedly.

However, in the hermetic rotary compressor having the conventional structure as described above, when the compressed fluid is discharged through the discharge passage f2, a pressure pulsation sound is generated due to overcompression, and a noise having a specific frequency is generated. There is this.

An object of the present invention devised in view of the above point is a sealed type provided with a resonator to reduce the overcompression loss and noise when the fluid compressed by the rotation of the partition plate formed on the rotating shaft is discharged through the discharge passage. It is to provide a rotary compressor.

Sealed rotary compressor for achieving the object of the present invention as described above is an upper bearing formed with a discharge passage for discharging the compressed fluid on both sides of the cylinder, and a cylinder assembly for coupling the lower bearing to form a closed inner space; A corrugated partition plate partitioning the inner space of the cylinder assembly on one side of the rotary shaft inserted through the upper bearing and the lower bearing of the cylinder assembly, and moving in parallel with the longitudinal direction of the rotary shaft to be in contact with both sides of the partition plate. Compressors which are elastically supported to have respective vanes for sucking and compressing the fluid, compressing the fluid in the inner space of the cylinder assembly partitioned by the partition plate of the rotating shaft according to the rotation of the rotating shaft and discharging the fluid through the discharge passage. To reduce the overcompression loss and noise of the fluid being discharged. The resonator in the cylinder fluid flows being discharged through the discharge flow path is configured so that at least one is formed.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, an exemplary embodiment of a hermetic rotary compressor will be described in detail with reference to the accompanying drawings.

Figure 6 is a longitudinal sectional view showing a sealed rotary compressor having a resonator is an embodiment of the present invention, Figure 7 is a plan view showing a compression mechanism of the compressor shown in Figure 6, Figure 8 is a compression mechanism shown in Figure 7 As shown in the cross-sectional view of the section "AA", the sealed rotary compressor of one embodiment of the present invention, as shown, the suction passage (f1) is formed in the interior space (V) and communicate with each of the interior space (V), respectively. And a discharge passage f2 are inserted into the inner space V of the cylinder assembly D fixedly coupled to the hermetically sealed container 10 so as to penetrate the center thereof, and the rotating shaft 20 Is coupled to the power mechanism (M) for generating a driving force required for rotation.

The cylinder assembly (D) is provided with a cylindrical through hole therein and is fixed to the cylinder 130 fixed to the sealed container 10, and the upper and lower surfaces of the cylinder 130, respectively coupled with the cylinder 130 In addition to forming an inner space (V) and includes an upper bearing 40 and a lower bearing 50 for supporting the rotating shaft 20, the cylinder 130 has an inner space of the cylinder 130 ( In V), a suction flow path f1 radially penetrated toward the outer circumferential surface is formed.

A volume space 131 having a predetermined space is formed in the cylinder 130, respectively, and compression regions V1b and V2b formed by the cylinder assembly D, the partition plate 22 and the vanes 70, and A resonator 131 including an inlet 131 b connecting the volume space 131 a is formed. At this time, the position where the resonator 131 is formed is preferably formed at the same angle with respect to the rotation axis 20 when viewed directly on a plane.

In addition, a partition plate 22 having a corrugated shape partitioning an inner space of the cylinder assembly D on one side of the rotating shaft 20 inserted into the upper bearing 40 and the lower bearing 50 of the cylinder assembly D. Is formed, and each vane 70 moves in parallel to the longitudinal direction of the rotation shaft 20 and is elastically supported to be in contact with both sides of the partition plate 22 so that the fluid is sucked and compressed to the upper bearing 40. And a discharge flow path which is provided with a lower bearing 50 and discharges the compressed fluid in the internal space of the cylinder assembly D partitioned by the partition plate 22 of the rotation shaft 20 according to the rotation of the rotation shaft 20. (f2) is formed in the upper bearing 40 and the lower bearing 50, respectively.

An opening and closing for discharging the compressed fluid in the compression regions V1b and V2b of the first space V1 and the second space V2 while opening and closing each discharge passage f2 formed in the cylinder assembly D, respectively. The means 80 are coupled, and the suction pipe 90 is coupled to the hermetic container 10 so as to communicate with the suction passage f1.

The process of operating the hermetic compressor configured as described above is the same as the conventional method, and the opening and closing means 80 when the partition plate 22 rotates so that the pressure of the fluid filled in the compression region V1b of the first space V1 becomes higher than a predetermined pressure. ) Is opened and the compressed fluid starts to be discharged through the discharge flow path f2. At this time, a part of the discharged fluid flows into the volume space 131a formed as a predetermined space through the inlet 131b formed in the cylinder 130, thereby reducing the pressure pulsation and the discharge noise generated when the compressed fluid is discharged. will be.

Similarly, when the pressure of the fluid filled in the compression region (V2b) in which the fluid filled in the second space (V2) is compressed becomes a predetermined pressure or more to open the opening and closing means 80 and is discharged through the discharge flow path (f2) is discharged A portion of the fluid is also introduced into the volume space 131a formed into a predetermined space through the inlet 131b formed in the cylinder 130 to reduce the pressure pulsation and the discharge noise.

As described above, in the hermetic rotary compressor according to the present invention, when the pressure of the fluid filled in the compression zones V1b and V2b becomes greater than a predetermined pressure, the opening and closing means 80 is opened and discharged through the discharge passage f2. A portion of the fluid is introduced into the volume space 131a through the inlet 131b formed in the cylinder 130 to reduce the pressure pulsation and the discharge noise generated when the compressed fluid is discharged.

As described above, the hermetic rotary compressor according to the present invention partitions the inside of the cylinder assembly, and when the pressure of the fluid filled in the compression zone by the rotating partition plate is greater than or equal to a predetermined pressure, the opening and closing means is opened and the fluid is discharged through the discharge passage. At the start of the process, the pressure pulsation and the discharge noise generated when the compressed fluid is discharged by the resonator in which a part of the discharged fluid is discharged into the volume space through the inlet introduced into the cylinder can be reduced, thereby improving the compression efficiency. It works.

1 is a longitudinal sectional view showing a compression mechanism of a typical compressor;

2 is a plan view showing the compression mechanism of the compressor shown in FIG.

3 is a perspective view partially showing a compression mechanism of the compressor shown in FIG. 1;

4 and 5 are a plan view showing a process of operating the compression mechanism of the compressor shown in FIG.

6 is a longitudinal sectional view showing a hermetic rotary compressor having a resonator according to one embodiment of the present invention;

7 is a plan view showing the compression mechanism of the compressor shown in FIG.

FIG. 8 is a cross-sectional view illustrating a portion “A-A” of the compression mechanism shown in FIG. 7.

** Description of the symbols for the main parts of the drawings **

20: axis of rotation 22: partition plate

40: upper bearing 50: lower bearing

130: cylinder 131: resonator

131a: Volumetric space 131b: Inlet

D: cylinder assembly f1: suction passage

f2: discharge flow path

Claims (2)

An upper bearing having a discharge flow path through which compressed fluid is discharged on both sides of the cylinder, a cylinder assembly having a lower bearing coupled to form a closed inner space, A partition plate having a corrugated shape partitioning an inner space of the cylinder assembly on one side of a rotation shaft inserted through the upper bearing and the lower bearing of the cylinder assembly; Each vane is provided to move in parallel to the longitudinal direction of the rotary shaft and to be elastically supported so as to be in contact with both sides of the partition plate to suck and compress the fluid, divided by the partition plate of the rotary shaft in accordance with the rotation of the rotary shaft In the compressor for compressing the fluid in the interior space of the cylinder assembly and the discharge through the discharge passage, And at least one resonator into which the fluid discharged through the discharge flow path is formed in the cylinder to reduce the overcompression loss and the noise of the discharged fluid. According to claim 1, Compression region is formed by the cylinder assembly, the partition plate and the vane, The resonator is a volume space formed so as to have a predetermined space in the cylinder, and the volume space and the compression region is in communication with the cylinder Sealed rotary compressor characterized in that the inlet is formed is provided.