KR100332781B1 - Structure for reducing noise and improving capacity in hermetic type rotary compressor - Google Patents

Abstract

The present invention relates to a noise reduction and efficiency improvement structure of the hermetic rotary compressor, and the present invention is provided with a rotating shaft which is rotated by receiving the driving force of the electric mechanism, a rolling piston inserted into the eccentric portion of the rotating shaft, and the rolling piston A cylinder which is inserted to form a space between the outer circumferential surface of the rolling piston and the inner circumferential surface thereof, coupled to the cylinder to seal the space, and penetrates the upper and lower bearings to support the rotating shaft and the main wall of the cylinder. In the rotary compressor having a vane which is coupled so as to linearly reciprocate in the radial direction and coupled to the outer circumferential surface of the rolling piston to convert the space portion of the cylinder into a suction zone and a compression zone in accordance with the rotation of the rotary shaft, Based on the vanes in the closed space of the cylinder, It is configured to form a surge groove located between 80 ° and 90 ° in the direction of rotation of the entire shaft, which reduces the noise caused by the pressure pulsation generated in the process of sucking, compressing and discharging the refrigerant gas, as well as compressing the refrigerant gas. It is to improve the performance by increasing the compression power efficiency.

Description

Noise reduction and efficiency improvement structure of hermetic rotary compressor {STRUCTURE FOR REDUCING NOISE AND IMPROVING CAPACITY IN HERMETIC TYPE ROTARY COMPRESSOR}

The present invention relates to a hermetic rotary compressor, and more particularly, to a noise reduction structure and an efficiency improvement structure of a hermetic rotary compressor capable of reducing noise caused by pressure pulsation generated in the process of sucking, compressing and discharging gas.

Generally, a compressor is a device that compresses a fluid, and there are various types of compressors such as a rotary compressor, a reciprocating compressor, a scroll compressor, and a scroll compressor. Such a compressor is composed of a hermetically sealed container having a predetermined internal space, an electric mechanism part mounted in the hermetically sealed container to generate a driving force, and a compressor mechanism part that compresses gas by receiving a driving force of the electric mechanical part.

As an example of the compressor, in the hermetic rotary compressor, as illustrated in FIGS. 1A and 1B, an electric mechanism part is mounted on one side of the hermetic container 1 formed in a predetermined shape, and the compressor mechanism part is provided at a predetermined distance from the electric mechanism part. Is mounted. The electric machine part includes a stator 2 fixedly coupled to the hermetic container 1 and a rotor 3 rotatably coupled to the stator 2.

And the compression mechanism is formed to have a predetermined length and the eccentric portion (4a) is formed on one side of the rotating shaft (4) is pressed into the inner diameter of the rotor 3, and the internal space (P) where the gas is sucked and compressed Is provided inside the sealed container 1 and seals the cylinder 5 into which the eccentric portion 4a of the rotating shaft is inserted into the inner space P and the inner space P of the cylinder. Upper and lower bearings 7 and 8 that are coupled to the upper and lower portions of the cylinder 5 by fastening the bolts 6 and support the rotating shaft 4, and the eccentric portions 4a of the rotating shaft. A rolling piston (9) inserted into the inner space (P) of the cylinder (5) and revolving in accordance with the rotation of the rotary shaft (4), and inserted into one side of the cylinder (5) so as to reciprocate in a radial direction. In addition, the end thereof is in line contact with the outer circumferential surface of the rolling piston (9), the inner hole of the cylinder (5) Is configured to include a space portion suction region (a) and the vanes (10) for converting the compression region (b) formed by the outer peripheral surface of the inner peripheral surface of the rolling piston (9).

A discharge port 5b is formed such that the inlet port 5a through which the gas is sucked into the cylinder 5 is located at the side of the vane 10, and the compressed gas is discharged from the compression zone b on the other side of the vane 10. Is formed and the suction port 5a, the vane 10 and the discharge port 5b are formed in the order of the discharge port 5b, the vane 10 and the suction port 5a according to the rotational direction of the rotation shaft 4. . Discharge holes 7a are formed in the upper bearing 7 or the lower bearing 8 coupled to the upper and lower portions of the cylinder 5 so as to communicate with the discharge port 5b (shown in the upper bearing in the drawing). ). The suction tube 11 and the discharge tube 12 into which the gas is sucked and discharged are coupled to the sealed container 1, and oil is filled in the bottom surface of the sealed container 1.

Reference numeral 13 is a discharge valve, 14 is a retainer, 15 is a silencer, and 16 is an accumulator.

Compressor as described above is a rolling piston (9) coupled to the eccentric portion (4a) of the rotary shaft by the rotation of the rotary shaft 4 when the rotor 3 rotates while the rotor (3) by the current applied ) Is orbited about the axis center in the cylinder internal space (P) in the state in contact with the vane (10). Due to the volume change of the space portion formed by the inner circumferential surface of the cylinder inner space and the outer circumferential surface of the rolling piston due to the orbital rotation of the rolling piston 9, the low-temperature low-pressure refrigerant gas flows into the cylinder through the suction pipe 11 and the suction port 5a. It is sucked into the negative pressure and compressed to a state of high temperature and high pressure, and the compressed high temperature and high pressure refrigerant gas is discharged through the discharge port 5b and the discharge hole 7a together with the operation of the discharge valve 13.

Referring to the process in which the refrigerant gas is sucked, compressed and discharged in accordance with the rotation of the rotary shaft 4 will be described in more detail. First, as shown in FIG. 2, the long diameter tip d of the eccentric portion 4a of the rotary shaft is vane ( When it comes into contact with 10), the discharge stroke ends and the suction stroke ends. The rotary shaft 4 rotates so that the tip d of the eccentric portion 4a passes through 90 ° with respect to the vane 10, and as shown in FIG. 3, at the position of the vane 10 and 180 °. In the area where the space P is converted into the suction area a and the compression area b by the vane 10, the refrigerant gas is sucked into the suction area a and the volume is reduced in the compression area b. As the gas is gradually compressed. And when the rotating shaft 4 is rotated so that the long-diameter tip of the eccentric portion passes 180 ° and is located in the discharge port 5b, as shown in FIG. 4, the amount of refrigerant gas suction into the suction region a increases. At the same time, when the pressure in the compression zone b increases and the pressure in the compression zone b becomes greater than the discharge gas, the discharge valve 13 opens and the compressed gas discharges through the discharge port 5b and the discharge hole 7a. Is discharged through).

On the other hand, while the rotor 3 rotates during operation of the compressor, the noise caused by the pressure pulsation is generated in the process of continuously repeating the process of inhaling, compressing and discharging the refrigerant gas. In order to reduce the noise caused by the pressure pulsation by providing a resonance effect on the part, researches of various angles are being conducted.

As an example of the conventional structure for reducing the pressure pulsation, as shown in Figures 5a, 5b, having a predetermined inner diameter and depth between 150 ° ~ 270 ° in the rotation direction of the rotation axis with respect to the vanes 30 as a reference The non-penetrating hole 12 is formed.

However, the conventional structure as described above does not fall within an appropriate range in consideration of only the discharge side in terms of pulsation noise reduction, but also does not consider the compression efficiency. That is, in terms of compression efficiency, the performance of the compressor is analyzed based on the P-V diagram. As shown in FIG. The difference in power occurs. If the vane reaches a position of 24 ° in the rotational direction of the rotary shaft, the gain of re-expansion and compression power is small, and if it reaches a position of 90 °, the gain of compression power of the compressed gas is greater than the re-expansion loss. When the temperature reaches 160 °, the compression power gain of the gas becomes smaller than the reexpansion loss. In this state, the area where the efficiency can be maximized by improving the efficiency corresponds to an area of 90 °.

Looking at the noise spectrum during operation of the compressor, as shown in Figure 7, it can be seen that the effect is obvious.

The object of the present invention devised in view of the above point is to minimize the noise generated by the pressure pulsation generated in the compression mechanism during operation of the compressor as well as to reduce the compression driving force required to compress the refrigerant gas. To provide a noise reduction and efficiency improvement structure of a hermetic rotary compressor.

1a, 1b is a front sectional view and a planar sectional view showing a general rotary compressor,

2, 3, and 4 are planar cross-sectional views illustrating an operation process of the rotary compressor, respectively.

5a and 5b are a front view and a plan view showing an example of a conventional rotary compressor noise reduction structure;

6 is a P-V diagram showing the performance of each rotary compressor by angle,

7 is a graph illustrating a noise spectrum generated during operation of the rotary compressor;

8a, 8b is a front cross-sectional view and a planar cross-sectional view of a rotary compressor having a rotary compressor noise reduction and efficiency improvement structure of the present invention,

9, 10 and 11 is a plan view showing the operating state of the rotary compressor noise reduction and efficiency improvement structure of the present invention, respectively;

12a and 12b are graphs showing the noise state during operation of the rotary compressor and the conventional rotary compressor equipped with the noise reduction and efficiency improvement structure of the present invention, respectively;

FIG. 13 is a graph illustrating a noise generation state according to each position of a surge groove constituting the noise reduction and efficiency improvement structure of the rotary compressor of the present invention;

14 is a graph showing the efficiency state according to each position of the surge groove constituting the noise reduction and efficiency improvement structure of the rotary compressor of the present invention,

(Explanation of symbols for the main parts of the drawing)

4 ; Axis of rotation 4a; Eccentric

5; Cylinder 7; Upper bearing

8 ; Lower bearing 9; Rolling piston

10; Vane 20; Surge Home

21; Inner groove portion 22; Opening groove

a; Suction chamber b; Compression chamber

P; Compressed space

In order to achieve the object of the present invention as described above, an eccentric part is provided, and a rotating shaft is rotated by receiving a driving force of the electric mechanism part, a rolling piston inserted into the eccentric part of the rotating shaft, and an inner space into which the rolling piston is inserted. And a cylinder having a space formed between the inner circumferential surface and the outer circumferential surface of the rolling piston, the upper and lower bearings respectively coupled to the cylinder to seal the inner space and supporting the rotating shaft, and penetrate the circumferential wall of the cylinder. In the hermetic rotary compressor having a vane which is coupled to the linear reciprocating motion in the direction and coupled to the outer circumferential surface of the rolling piston and the vane for converting the space of the cylinder into the suction zone and the compression zone in accordance with the rotation of the rotary shaft, the cylinder On the vane within the enclosed inner space of the The direction of rotation in 80 ° ~ 90 ° noise reduction of a hermetic rotary compressor, characterized in that the formation of the groove which is located between the surge and the efficiency improving the structure of the rotary shaft is provided.

Hereinafter, the noise reduction and efficiency improvement structure of the hermetic rotary compressor of the present invention will be described according to the embodiment shown in the accompanying drawings.

8A and 8B illustrate an example of a noise reduction and efficiency improvement structure of the hermetic rotary compressor of the present invention. Referring to this, first, the hermetic rotary compressor transmits a driving force to a driving mechanism that generates a driving force and a driving force thereof. And a compression mechanism portion for compressing the gas. The rotating shaft 4 constituting the compression mechanism portion has a predetermined length, and an eccentric portion 4a is formed at one side thereof and is pressed into the rotor 3 of the electric mechanism portion. And the rolling piston 9 is inserted into the eccentric part 4a of the rotating shaft 4, and the rolling piston 9 is coupled so that it may be located in the internal space P of the cylinder 5. The rolling piston 9 is formed in an annular shape having an inner diameter and a predetermined thickness t corresponding to the outer diameter of the eccentric portion 4a. An inlet port 5a through which gas is sucked into the inner space P is formed in the cylinder 5, and a discharge port 5b through which the compressed gas is discharged from the inner space P is formed at the side thereof. The vane 10 is inserted into the cylinder 5 so as to be located between the discharge port 5b and the suction port 5a, and the end of the vane 10 is inserted into the rolling piston 9 located in the inner space P. Line is contacted. The vane 10 converts the space between the inner circumferential surface of the cylinder inner space P and the outer circumferential surface of the rolling piston 9 into the suction zone a and the compression zone b as the rotation shaft 4 rotates.

Upper and lower bearings 8 and 8 are respectively coupled to upper and lower surfaces of the cylinder 5 to seal the inner space P of the cylinder, and the rotary shaft 4 is upper and lower bearings 7 and 8. Are respectively inserted through to support the rotating shaft (4). A discharge hole 7a is formed in the upper bearing 7 or the lower bearing 8 so as to communicate with the discharge port 5b (shown in the upper bearing in the drawing), and the discharge hole opens and closes the discharge hole 7a. The valve 13 is mounted.

And the surge groove 20 is formed in the sealed inner space (P) of the cylinder so as to be located between 80 ° ~ 90 ° in the rotation direction of the rotary shaft 4 on the basis of the vane (10). The surge groove 20 is, for example, formed in a cylindrical shape having a predetermined inner diameter and a predetermined depth. In another example, the surge groove 20 is formed in an elliptic cylindrical shape having a predetermined depth and having an elliptical cross section. In addition, as another example of the surge groove 20 has a predetermined depth and is formed in the shape of a square cylinder having a rectangular cross section. That is, the surge groove 20 may be formed in various forms. The surge groove 20 may be formed in the upper bearing 7 or the lower bearing 8, but is preferably formed in the lower bearing 8, and the surging volume of the surge groove 20 is an internal space of the cylinder 5. It is formed to be 0.5% to 2% of the volume of the space portion, which is a space between the inner circumferential surface and the outer circumferential surface of the rolling piston 9. In other words, the refrigerant gas is preferably formed to be 0.5% to 2% of the total suction volume.

The surge groove 20 is formed of an inner groove portion 21 of a portion overlapping with the main wall of the cylinder 5 and an opening groove portion 22 of a portion overlapping with the inner space, and is opened at an inner wall of the cylinder 5. The distance L to the end of the groove portion 22 is formed to be 55% or less of the rolling piston thickness t.

Hereinafter, the operational effects of the closed rotary compressor noise reduction and efficiency improvement structure of the present invention will be described.

First, when power is applied to rotate the rotating shaft 4 while the rotor 3 constituting the electric mechanism rotates, the rolling coupled to the eccentric portion 4a of the rotating shaft 4 by the rotation of the rotating shaft 4. The piston 9 is idle in the cylinder internal space P while in contact with the vane 10.

The low temperature low pressure refrigerant gas is sucked into the cylinder internal space P through the suction pipe 11 and the suction port 5a by the volume change of the cylinder space portion partitioned by the vane 10 by the revolution of the rolling piston 9. The compressed high-temperature high-pressure refrigerant gas is discharged through the discharge port 5b and the discharge hole 7a together with the operation of the discharge valve 13. Referring to this process in more detail, first, as shown in Fig. 9, when the eccentric portion 4a of the long axis tip d of the rotating shaft is brought into contact with the vane 10, the discharge stroke ends and the suction is performed. The administration ends. Then, as the rotary shaft 4 rotates so that the tip d of the eccentric portion 4a reaches the position past the surge groove 20, as shown in FIG. As a result, the refrigerant gas is sucked into the suction area a while being converted into the suction area a and the compression area b, and the gas is gradually compressed due to a decrease in volume in the compression area b. In this step, the compression power is made smaller by the furnace 20 than in the prior art. As shown in FIG. 11, in the process in which the rotating shaft 4 rotates so that the long-diameter tip d of the eccentric portion 4a reaches the position of the discharge port 5b after passing through the surge groove 20. When the suction amount of the refrigerant gas to a) increases and the pressure in the compression zone b increases while the pressure in the compression zone b becomes larger than the discharge gas, the discharge valve 13 opens and the compressed gas is opened. Is discharged through the discharge port 5b and the discharge hole 7a.

As the above-described process is continuously repeated, the gas is compressed and the noise caused by the pressure pulsation generated in the process is reduced by the surge groove 20. 12A is a graph measuring noise generated by operating a compressor in a state in which the surge groove 20 is formed, and FIG. 12B illustrates pressure pulsation generated by operating a compressor in a state in which the surge groove 20 is not formed. As a result of the measurement, it can be seen that the noise is remarkably reduced at the portion where compression and suction of the compressed refrigerant gas proceed simultaneously, that is, at a position of 90 °. 13 is a graph measuring noise generated by operating the compressor at various positions of the surge groove 20 at various angles, and as shown in FIG. 13, the surge groove 20 is between 80 ° and 90 °. When installed on the floor, the noise reduction effect is large. In particular, the audible sound, ie emotional noise is reduced.

Since the surge groove 20 is formed, the pressure applied to compress the refrigerant gas can be reduced. 14 is a graph measuring the efficiency of the surge groove 20 formed at various angles and operating the compressor at each position. As shown in the graph, the surge groove 20 is referred to the vane 10. As a result, the maximum effect is obtained when positioned in the range of 80 ° to 90 °. This reduces the compression power required during the compression process.

As described above, the noise reduction and efficiency improvement structure of the hermetic rotary compressor according to the present invention is 80 ° to 90 ° in the direction of rotation of the rotating shaft based on the vanes in the compression space of the cylinder to which the upper bearing and the lower bearing are coupled. By forming a surge groove in the position, it is possible to increase the reliability by reducing the noise caused by the pressure pulsation generated in the process of inhaling, compressing and discharging the refrigerant gas, and also improving the performance by increasing the compression power efficiency required to compress the refrigerant gas. It can be effected.

Claims (4)

An eccentric part is provided, and a rotating shaft which is rotated by receiving a driving force of the electric mechanism part, a rolling piston inserted into the eccentric part of the rotating shaft, and an inner space into which the rolling piston is inserted is formed, and a space is formed between the inner circumferential surface and the outer circumferential surface of the rolling piston. A cylinder formed, an upper and lower bearing coupled to the cylinder to seal the inner space and supporting the rotating shaft, and coupled to allow a linear reciprocating motion in a radial direction through the main wall of the cylinder and the rolling A hermetic rotary compressor having a vane coupled to the outer circumferential surface of a piston to convert the space portion of a cylinder into a suction zone and a compression zone according to the rotation of the rotating shaft, wherein the vane is located within the sealed inner space of the cylinder. Located between 80 ° and 90 ° in the direction of rotation of the rotation axis Noise reduction and efficiency improving structure of a hermetic rotary compressor, characterized in that the formation of the jihom. The noise reduction and efficiency improvement structure of a hermetic rotary compressor according to claim 1, wherein the surge groove has a surging volume corresponding to 0.5% to 2% of the total volume of the space part. The noise reduction and efficiency improvement structure of a hermetic rotary compressor according to claim 1 or 2, wherein the surge groove is formed in the lower bearing. According to claim 1 or 2, wherein the surge groove is formed of the inner groove portion of the portion overlapping with the circumferential wall of the cylinder and the opening groove portion of the portion overlapping with the space portion, from the inner wall of the cylinder to the end of the opening groove portion; Noise reduction and efficiency improvement structure of the hermetic rotary compressor, characterized in that the distance is 55% or less of the rolling piston thickness.