KR20140142956A - 2-stage compressor - Google Patents

Abstract

A two-stage compressor according to the present invention has: a scroll-type first stage compression part at a low-pressure side; and a rotary-type second stage compression part at a high-pressure side, wherein the first stage compression part and the second stage compression part may be arranged on the same plane. Therefore, the two-stage compressor is capable of maintaining a discharge volume, thereby easily designing the stroke volume of the second stage compression part at a high-pressure side. The two-stage compressor is capable of maintaining an intermediate pressure therein. The two-stage compressor is capable of lowering a temperature at the intermediate pressure or allowing oil to be injected thereinto easily as necessary. The two-stage compressor is capable of appropriately responding to the operation condition of a refrigeration cycle by bypassing the part of a refrigerant compressed in a low-pressure ratio operation. The two-stage compressor is capable of allowing the second-stage compression to be easily manufactured by the outer circumferential surface of an orbiting wrap. The two-stage compressor is capable of controlling a final discharge volume freely, thereby controlling a discharge pressure and minimizing insufficient compression on a high-pressure ratio operation condition. And the two-stage compressor is capable of minimizing an axial leakage in the second-stage compression part using a scroll-type back pressure.

Description

2-stage compressor < RTI ID = 0.0 >

The present invention relates to a two-stage compressor, and more particularly to a two-stage compressor having a scroll-side compression section and a rotary-side compression section.

Generally, a refrigerant compressor is applied to a vapor compression refrigeration cycle such as a refrigerator or an air conditioner (hereinafter abbreviated as a refrigeration cycle). The refrigerant compressor has been introduced with a constant-speed compressor driven at a constant speed or an inverter-type compressor controlled in rotation speed.

The refrigerant compressor is generally called a hermetic compressor when a drive motor serving as an electric motor and a compression unit operated by the drive motor are provided together in an internal space of a hermetically sealed casing and the case where the drive motor is separately provided outside the casing is referred to as an open compressor can do. Most of the refrigeration appliances for home use or commercial use are hermetically sealed compressors.

The refrigerant compressor may be classified into a reciprocating type, a scroll type, and a rotary type according to a method of compressing a refrigerant. The rotary compressor compresses the refrigerant by using a rolling piston which eccentrically rotates in the compression space of the cylinder and a vane which divides the compression space of the cylinder into the suction chamber and the discharge chamber in contact with the rolling piston.

BACKGROUND ART [0002] In recent years, there has been known a double rotary compressor in which a plurality of cylinders are provided and a rolling piston and a vane are independently provided in each of a plurality of cylinders, thereby compressing the refrigerant using one driving motor. The double rotary compressor may be divided into a capacity variable type rotary compressor in which a plurality of cylinders are independent from each other to independently compress refrigerant and a two stage type rotary compressor in which a plurality of cylinders communicate with each other to sequentially compress refrigerant.

On the other hand, in the scroll compressor, the fixed scroll is fixed to the inner space of the sealed container, and two pairs of the fixed scroll and the orbiting scroll are continuously moved between the fixed lap of the fixed scroll and the orbiting scroll of the orbiting scroll, Of the compressor.

The scroll compressor is widely used for compressing refrigerant in an air conditioner or the like because it can obtain a relatively high compression ratio as compared with other types of compressors, and smooth suction, compression, and discharge strokes of the refrigerant can be obtained and stable torque can be obtained. However, since the scroll compressor has to be formed so that the fixed lap and the orbiting lap are engaged with each other, fabrication is difficult and a double or twin scroll compressor has not been widely developed.

However, in the conventional rotary compressor as described above, since the eccentric portion compresses the refrigerant while rotating, the vibration noise of the compressor is increased, and in particular, in the case of the two-stage rotary compressor, The intermediate pressure is unstable and the compression efficiency is lowered. On the other hand, in the case of the scroll compressor, since the volume ratio of the scroll compressor is fixed and the low compression ratio is incurred under the high pressure ratio condition in designing the low volume ratio, There has been a limit in manufacturing a high efficiency compressor such as a compressor.

SUMMARY OF THE INVENTION An object of the present invention is to provide a two-stage compressor which is advantageous in balancing maintenance, has a stable intermediate pressure, is easy to manufacture, and can easily adjust a discharge pressure according to operating conditions.

In order to achieve the object of the present invention, A drive motor provided in the hermetically sealed container; A scroll-side compression unit coupled to the drive motor to perform the orbiting movement, the scroll-side compression unit forming a compression chamber together with the stationary wrap to compress the refrigerant by one stage; And a rotary-side compression unit coupled to the drive motor to pivot together with the orbiting wrap to form a compression chamber together with the vane to compress the first-stage compressed refrigerant in two stages by the scroll-side compression unit A two-stage compressor may be provided.

Also, A drive motor provided in the hermetically sealed container; A scroll-side compression unit coupled to the drive motor to swirl to form a compression chamber together with the fixed lap to compress the refrigerant; And a rotary-side compression unit coupled to the drive motor to pivotally move together with the orbiting wrap to form a compression chamber together with the vane to compress the refrigerant, wherein the compression chamber of the scroll- A two-stage compressor may be provided in which the compression chambers of the compression section are formed so as to overlap at least a part in the same plane.

Also, A drive motor provided in the hermetically sealed container; A orbiting scroll which is coupled to the driving motor to perform a swing motion and in which a swinging lap is formed and a rolling piston is formed outside the swinging lap; A fixed scroll having a fixed lap formed to engage with the orbiting scroll to form a scroll side compression chamber and having a compression chamber space formed at one side of the fixed lap to form a rotary side compression chamber while the rolling piston is rotating; And a vane provided in the compression chamber and forming a rotary compression chamber together with the rolling piston.

In the two-stage compressor according to the present invention, since the first-stage compressing section on the low-pressure side is formed by the scroll method, the discharge volume can be maintained constant, and the stroke volume of the second-

In addition, since the first-stage compression section is formed by the scroll system, the intermediate pressure section can be extended to maintain the intermediate pressure uniformly, and the intermediate pressure temperature can be lowered or oil can be easily injected if necessary.

In addition, since the first-stage compressing unit is formed by the scroll system, it is possible to easily bypass some of the refrigerant compressed during the low pressure ratio operation, thereby enabling the compressor to appropriately respond to the operating conditions of the refrigeration cycle.

In addition, since the two-stage compression section is formed by the rotary type, the outer peripheral surface of the orbiting scroll of the orbiting scroll is used, or the two-stage compression section can be easily manufactured by being formed in a different manner from the one-

In addition, since the two-stage compression section is formed in a rotary type having a discharge valve, the discharge volume can be freely adjusted, so that the discharge pressure can be adjusted according to the operating conditions, and the undercompression can be minimized through the discharge delay under the high- .

In addition, since the two-stage compression section is formed in a rotary manner, it is possible to seal the two-stage compression section by using the back pressure of the scroll system which is the one-stage compression section, thereby minimizing the axial leakage of the two-stage compression section.

1 is a longitudinal sectional view showing an example of a two-stage compressor of the present invention,
FIG. 2 is a vertical sectional view enlargedly showing a compression section in the two-stage compressor according to FIG. 1,
3 is a sectional view taken along the line "II" in Fig. 2,
FIG. 4 is a perspective view showing the fixed scroll and the orbiting scroll separated from each other in the compression unit according to FIG. 2,
Fig. 5 is a cross-sectional view showing another embodiment of the compression section in the two-stage compressor according to Fig. 1,
FIGS. 6 to 8 are longitudinal and transverse sectional views showing another embodiment of a refrigerant absorption / discharge path in the two-stage compressor according to FIG. 1;

Hereinafter, a two-stage compressor according to the present invention will be described in detail with reference to an embodiment shown in the accompanying drawings.

FIG. 1 is a longitudinal sectional view showing an example of a two-stage compressor of the present invention, FIG. 2 is a longitudinal sectional view enlargedly showing a compression section in the two-stage compressor according to FIG. 1, FIG. 3 is a cross- 4 is a perspective view in which the fixed scroll and the orbiting scroll are separated from each other in the compression unit according to FIG.

As shown in the drawing, the two-stage compressor according to the present embodiment is provided with a drive motor 2 for generating a rotational force in the internal space 11 of the closed container 1, The frame 3 can be fixedly installed.

A fixed scroll 4 is fixedly mounted on the upper surface of the main frame 3 and is eccentrically engaged with the crankshaft 23 of the drive motor 2 between the main frame 3 and the fixed scroll 4, And the orbiting scroll 5 forming a pair of two compression chambers P continuously moving together with the orbiting scroll 5 can be pivotally installed. Between the fixed scroll (4) and the orbiting scroll (5), an orhering ring (6) for preventing the orbiting scroll (5) from rotating may be provided.

The fixed scroll 4 is formed on the bottom surface of the hard plate 41 so that the fixed lap 42 is formed so as to form the scroll side compression chamber P together with the orbiting wrap 52 of the orbiting scroll 5 have.

The stationary wrap 42 may be formed in an involute shape, or may be formed in a logarithmic spiral or other various shapes.

A first suction port (43) for guiding the refrigerant to the scroll-side outermost compression chamber (P11) may be formed on one side of the fixed plate (41) of the fixed scroll (4). The first suction port 43 may be formed to communicate with only the scroll side outermost compression chamber P11.

A first discharge port 44 for discharging the refrigerant compressed in the scroll side compression chamber P1 to the inner space of the intermediate cover 8 to be described later may be formed at the center of the longitudinal plate 41 of the fixed scroll 4 .

A bypass hole (45) having a bypass valve (not shown) for bypassing a part of the refrigerant compressed in the scroll-side intermediate compression chamber (P12) is formed around the first discharge port (44) . An oil supply hole (not shown) for injecting oil into the scroll-side intermediate compression chamber P12 may be formed around the first discharge port 44.

A compression chamber space 46 having a predetermined depth and width can be formed outside the fixed lap 42 so that the rolling piston 53, which will be described later, is pivotally moved to form the rotary compression chamber P2. The compression chamber space 46 may be formed in an annular shape so that the rolling piston 53, which will be described later, can perform a swing motion. The depth H1 of the compression chamber space 46 may be formed to be lower than the depth H2 of the scroll side compression chamber P1 since the rotary compression chamber P2 forms a two-stage compression chamber .

The fixed scroll 4 may be formed with a vane slot 47 communicating with the outer circumferential surface of one side of the compression chamber space 46 and inserted to allow the vane 7 to slide in the radial direction. A second suction port 48 is formed on one side in the circumferential direction of the vane slot 47 so that the refrigerant compressed in one stage in the scroll side compression chamber P1 is guided to the rotary compression chamber P2, And a second discharge port 49 for discharging the refrigerant compressed in two stages in the rotary compression chamber P2 to the refrigeration cycle may be formed on the other side in the circumferential direction. A discharge valve 49a may be provided at the outlet end of the second discharge port 49 so as to control the discharge pressure of the refrigerant discharged from the rotary compression chamber P2.

The first outlet 44 and the second inlet 49 may be connected to each other by a pipe or a duct. However, the first outlet 44 may be connected to the intermediate cover 8 having an internal space larger than that of the first outlet 44, have. The intermediate cover 8 is formed in a cap shape so as to almost cover the back surface of the fixed scroll 4 and can be bolted to the fixed scroll 4. The inner space 81 of the intermediate cover 8 is filled with the refrigerant compressed in the first stage while the inner space 11 of the sealed container 1 is filled with the refrigerant compressed in the second stage, A pressure difference may be generated between the inner space (81) of the closed container (1) and the inner space (11) of the closed container (1). Therefore, it may be preferable to provide a sealing member 82 between the opening end of the intermediate cover 8 and the back surface of the fixed scroll 4. [

A through hole 83 is formed in the intermediate cover 8 and a first connection pipe 84 is inserted into the through hole 83 to be fixedly coupled. The lower end of the first connection pipe 84 is inserted into the first suction port 43 of the fixed scroll 4 to be sealed and coupled to the fixed scroll 4 while the upper end of the first connection pipe 84 passes through the closed container 1, The second connection pipe 12 to be connected can be sealed.

The first connection pipe 84 may be provided with a flange portion. The flange portion 84a of the first connection pipe 84 can be tightly coupled to the upper surface of the intermediate cover 8 while the second connection pipe 12 can be sealed to the hermetically sealed container 1. [ A sealing member (not shown) is provided between the flange 84a of the first connection pipe 84 and the intermediate cover 8 closely contacting the flange 84a, and between the first connection pipe 84 and the second connection pipe 12, Code) may be preferably provided.

On the other hand, the orbiting scroll 5 protrudes from the upper surface of the hard plate portion 51 and is engaged with the fixed lap 42 to form the swirl wraps 52 so as to form a pair of the scroll side compression chambers P1, The rolling piston 53 may be formed outside the wrap 52 to form the rotary compression chamber P2 while swirling in the compression chamber space portion 46. [ The rolling piston 53 may be formed to be lower than the orbiting wrap 52 in correspondence with the depth of the compression chamber space portion 46. The boss portion 54 may be formed on the bottom surface of the long plate portion 51 of the orbiting scroll 5 so that the pin portion 23a of the crankshaft 23 is inserted to receive the rotational force.

Reference numeral 13 in the drawings denotes a discharge pipe, 31 a bearing hole, 32 a bush pocket, 33 a communicating hole, and 71 a vane spring.

The two-stage compressor according to the present embodiment as described above has the following operational effects.

That is, when power is applied to the drive motor 2 to generate a rotational force, the orbiting scroll 5 eccentrically coupled to the crankshaft 23 of the drive motor 2 rotates, Two scroll-side compression chambers P1 continuously moving between the compression chambers 42 are formed. The scroll side compression chamber (P1) is continuously formed in several stages with the volume gradually becoming smaller toward the center.

The refrigerant supplied from the outside of the hermetically sealed container 1 through the second connection pipe 12 flows directly into the scroll side compression chamber P1 through the first connection pipe 84 and the first suction port 43 in order, This refrigerant is moved in the direction of the scroll-side final compression chamber P13 by the orbiting motion of the orbiting scroll 5 and is compressed in the first compression chamber P13 in the scroll-side final compression chamber P13, And is discharged into the inner space 81 of the intermediate cover 8 through the discharge port 44.

The one-stage compressed refrigerant discharged into the inner space 81 of the intermediate cover 8 is then sucked into the rotary compression chamber P2 through the second suction port 48 of the fixed scroll 4 to be supplied to the rolling piston 53 And then discharged into the inner space 11 of the hermetically sealed container 1 through the second discharge port 49 while being compressed in two stages by the vane 7 and the vane 7. At this time, the rolling piston 53 is integrally formed with the orbiting scroll 5 and is rotated in the compression chamber space portion 46 of the fixed scroll 4 along the orbiting motion of the orbiting scroll 5, To form the rotary compression chamber P2.

Here, since the first-stage compressing section on the low-pressure side is formed by the scroll system, the discharge volume can be kept constant and accordingly the stroke volume of the second-stage compressing section on the high-pressure side can be easily designed.

In addition, since the first-stage compression section is formed by a scroll system having a long path of the compression chamber, not only the intermediate pressure can be uniformly maintained while the intermediate-pressure section is long, the intermediate pressure can be lowered or the oil can be easily injected .

In addition, since the first-stage compressing unit is formed by the scroll system, it is possible to easily bypass some of the refrigerant compressed during the low pressure ratio operation, thereby enabling the compressor to appropriately respond to the operating conditions of the refrigeration cycle.

In addition, since the high-pressure side two-stage compression section is formed by the rotary type, the outer peripheral surface of the orbiting scroll of the orbiting scroll is used or formed in a different manner from the one-stage compression section.

 In addition, since the two-stage compression section is formed in a rotary type having a discharge valve, the discharge volume can be freely adjusted, so that the discharge pressure can be adjusted according to the operating conditions, and the undercompression can be minimized through the discharge delay under the high- .

In addition, since the two-stage compression section is formed in a rotary manner, it is possible to seal the two-stage compression section by using the back pressure of the scroll system which is the one-stage compression section, thereby minimizing the axial leakage of the two-stage compression section.

Meanwhile, another embodiment of the two-stage compressor according to the present invention is as follows.

That is, in the above-described embodiment, the vane is provided so as to abut the outer surface of the rolling piston so that the rotary compression chamber is formed only on the outer side with respect to the rolling piston. However, in this embodiment, The inner end of the compression piston chamber 53 penetrates the vane slot 53a of the rolling piston 53 and the outer end of the compression piston chamber 53 is connected to the inner side surface 46a of the compression chamber space portion 46, The rotary compression chamber P2 can be formed in the rotary side inner compression chamber P21 and the rotary side outer compression chamber P22 around the rolling piston 53, respectively.

In this case, the second suction port 48 and the second discharge port 49 may be formed so as to communicate with the rotary side inner compression chamber P21 and the rotary side outer compression chamber P22, respectively. In this case also, the first discharge port 44 and the second discharge port 49 can be communicated with each other by the intermediate cover 8, the first suction port 43 is connected to the suction pipe, Respectively, to the inner space 11 of the body 1.

The basic configuration and operation effects of the two-stage compressor according to the present embodiment are in contradiction with the above-described embodiments. However, since the rotary compression chambers P21 and P22 are formed on both sides of the rolling piston in this embodiment, the compressor capacity is increased and the gas repulsion force of the rotary compression chambers P21 and P22 So that the behavior of the orbiting scroll 5 can be stabilized.

Meanwhile, another embodiment of the two-stage compressor according to the present invention is as follows.

That is, in the above-described embodiments, the first suction port is connected to the suction pipe, the second discharge port is connected to the inner space of the hermetically sealed container, the first discharge port and the second suction port are directly connected, 6, the first suction port 43 is directly connected to the second connection pipe 12 connected to the suction pipe, and the second discharge port 49 is directly connected to the discharge pipe 13, while the first discharge port 44 and the second suction port 48 are formed to communicate with the inner space 11 of the hermetically sealed container 1, respectively.

The basic configuration and operation effects of the two-stage compressor according to the present embodiment are in contradiction with the above-described embodiments. However, in this embodiment, as the inner space 11 of the closed container 1 is filled with the refrigerant compressed in the scroll-side compression chamber P1 by one stage, the inner space 11 of the closed container 1 is filled with the intermediate pressure portion Respectively. As a result, the cooling efficiency of the drive motor is improved as compared with the above-described embodiments, and the compressor efficiency can be improved.

7, the first suction port 43 is directly connected to the inner space 11 of the hermetically sealed container 1, and the second discharge port 49 is directly connected to the discharge pipe 13, while the first discharge port 44 and the second suction port 48 may be formed to communicate with the inner space 81 of the intermediate cover 8.

The basic configuration and operation effects of the two-stage compressor according to the present embodiment are very similar to those of the above-described embodiments. However, in this embodiment, the inner space 11 of the closed container 1 is filled with the refrigerant sucked through the suction pipe 12, so that the inner space 11 of the closed container 1 forms a low pressure part. Accordingly, the cooling effect of the driving motor is further improved as compared with the above-described embodiments, and the compressor efficiency can be further improved.

Meanwhile, another embodiment of the two-stage compressor according to the present invention is as follows.

That is, in the above-described embodiments, the scroll-side compression section is constituted by the first-stage compression section and the rotary-side compression section is constituted by the second-stage compression section. Fig. 8 shows the configuration in which the rotary- .

To this end, a first suction port 481 and a first discharge port 491 are formed on both sides of the vane slot 47 of the fixed scroll 4, and a second suction port 431 is formed to communicate with the scroll side outermost compression chamber P11. And a second discharge port 441 communicating with the scroll-side final compression chamber P13.

In this case as well, the basic configuration and operation effects of the two-stage compressor such as the intermediate cover or each of the connecting pipes as well as the driving motor are very similar to those of the above-described embodiments. In this case, however, the volume of the rotary compression unit as the first-stage compression unit must be larger than the volume of the scroll-side compression unit as the second-stage compression unit, so that the volume of the rotary compression unit can be maximized and the overall compressor capacity can be improved .

1: sealed container 11: inner space of the sealed container
12: Second connection pipe 13: Discharge pipe
4: fixed scroll 42: stationary wrap
43: first suction port 44: first discharge port
45: bypass hole 46: compression chamber space
47: Vane slot 48: Second inlet
49: second outlet 5: orbiting scroll
52: turning lap 53: rolling piston
7: Vane 8: Middle cover
81: inner space of the intermediate cover 84: first connection pipe
P1: scroll side compression chamber P11: scroll side outermost compression chamber
P12: scroll-side intermediate compression chamber P13: scroll-side final compression chamber
P2: Rotary side compression chamber P21: Rotary side inner compression chamber
P22: Rotary side outer compression chamber

Claims (15)

Airtight container;
A drive motor provided in the hermetically sealed container;
A scroll-side compression unit coupled to the drive motor to perform the orbiting movement, the scroll-side compression unit forming a compression chamber together with the stationary wrap to compress the refrigerant by one stage; And
And a rotary-side compression unit coupled to the drive motor to pivotally move together with the orbiting wrap to form a compression chamber together with the vane to compress the refrigerant having been compressed in the scroll- Two stage compressor. The method according to claim 1,
Wherein the compression chamber formed in the scroll-side compression section and the compression chamber formed in the rotary-side compression section are formed so that at least a part thereof overlaps in the same plane. 3. The method of claim 2,
And the scroll-side compression section is disposed inside the rotary compression section. Airtight container;
A drive motor provided in the hermetically sealed container;
A scroll-side compression unit coupled to the drive motor to swirl to form a compression chamber together with the fixed lap to compress the refrigerant; And
And a rotary-side compression unit coupled to the drive motor and rotating together with the orbiting wrap to form a compression chamber together with the vane to compress the refrigerant,
Wherein the compression chamber of the scroll-side compression section and the compression chamber of the rotary-side compression section are formed so that at least a part thereof overlaps in the same plane. Airtight container;
A drive motor provided in the hermetically sealed container;
A orbiting scroll which is coupled to the driving motor to perform a swing motion and in which a swinging lap is formed and a rolling piston is formed outside the swinging lap;
A fixed scroll having a fixed lap formed to engage with the orbiting scroll to form a scroll side compression chamber and having a compression chamber space formed at one side of the fixed lap to form a rotary side compression chamber while the rolling piston is rotating; And
And a vane provided in the compression chamber and forming the rotary compression chamber together with the rolling piston. 6. The method of claim 5,
And the height of the rolling piston is formed to be lower than or equal to the height of the orbiting wrap. 6. The method of claim 5,
Wherein the vane is inserted into the fixed scroll and the vane slot is formed to contact the rolling piston to perform sliding motion. 8. The method of claim 7,
Wherein the fixed scroll is provided with a discharge port communicating with the rotary compression chamber on the inner side or the outer side with respect to the rolling piston. 6. The method of claim 5,
Wherein the rolling piston is formed with a vane slot so that the vane is inserted so as to penetrate through the rolling piston to perform a sliding motion. 10. The method of claim 9,
Wherein the fixed scroll is provided with a plurality of discharge ports communicating with the rotary compression chamber on the inner side and the outer side on the basis of the rolling piston. 6. The method of claim 5,
The fixed scroll including a first suction port and a first discharge port communicating with the scroll side compression chamber and a second suction port and a second discharge port communicating with the rotary compression chamber,
Wherein the first suction port is directly connected to a suction pipe passing through the sealed container,
And the second discharge port communicates with the inner space of the hermetically sealed container. 12. The method of claim 11,
Wherein the fixed scroll is coupled with an intermediate cover having a predetermined inner space to communicate the first discharge port and the second suction port. 6. The method of claim 5,
The fixed scroll including a first suction port and a first discharge port communicating with the scroll side compression chamber and a second suction port and a second discharge port communicating with the rotary compression chamber,
Wherein the first suction port is directly connected to a suction pipe passing through the sealed container,
Wherein the first discharge port and the second suction port communicate with an inner space of the hermetically sealed container,
And the second discharge port is directly connected to a discharge pipe passing through the sealed container. 6. The method of claim 5,
The fixed scroll including a first suction port and a first discharge port communicating with the scroll side compression chamber and a second suction port and a second discharge port communicating with the rotary compression chamber,
The first suction port communicates with the inner space of the hermetically sealed container,
And the second discharge port is directly connected to a discharge pipe passing through the sealed container. 15. The method of claim 14,
Wherein the fixed scroll is coupled with an intermediate cover having a predetermined inner space to communicate the first discharge port and the second suction port.

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