JP2000073974A - Two stage compressor and air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve efficiency of a compressor without causing abrasion and the like on a blade. SOLUTION: A low stage side compression mechanism 5L and a high stage side compression mechanism 5H are accommodated in a casing 31. The interior of the casing 31 is made in a high pressure atmosphere by having a high pressure refrigerant delivery pipe 2d communicating through it. A suction passage 51 of the low stage side compression mechanism 5L having a suction pipe 2r of a low pressure refrigerant communicating with it, a delivery passage 53 of the low stage side compression mechanism 5L and a suction passage 52 of the high stage side compression mechanism 5H directly communicate with each other through an intermediate passage 55 and a delivery passage 54 of the high stage side compression mechanism 5H is opened in the interior of the casing 31. The intermediate passage 55 has an intermediate pressure refrigerant injection pipe 2B communicating with it. The low stage side compression mechanism 5L and the high stage side compression mechanism 5H, having a blade integrally formed with a ring shape piston 61, constitute a rotary compressor compressing the refrigerant by the oscilating motion of the piston 61.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a two-stage compressor and an air conditioner, and more particularly to a measure for improving compressor efficiency.

[0002]

2. Description of the Related Art Conventionally, a two-stage compressor has been disclosed in
As disclosed in JP-A-133366, there is a configuration in which a low-stage compression mechanism and a high-stage compression mechanism are provided in a casing.

[0003] In the low-stage compression mechanism, a suction-side refrigerant pipe of a refrigerant circuit is connected to a suction port to supply low-pressure refrigerant. On the other hand, the discharge port of the low-stage compression mechanism is connected to the suction port of the high-stage compression mechanism via an intermediate passage, and the intermediate passage is supplied with intermediate-pressure refrigerant from gas-liquid separation provided in the refrigerant circuit. Is done. The discharge port of the high-stage compression mechanism is opened in a casing, and the casing is connected to a suction-side refrigerant pipe of a refrigerant circuit.

[0004] The low-stage compression mechanism sucks the low-pressure refrigerant in the refrigerant circuit and compresses the refrigerant into an intermediate-pressure refrigerant. Thereafter, the intermediate-pressure refrigerant is sucked into the high-stage compression mechanism together with the intermediate-pressure refrigerant supplied from the gas-liquid separator, and the high-stage compression mechanism compresses the intermediate-pressure refrigerant into a high-pressure refrigerant and discharges it.

[0005] In this two-stage compressor, since the intermediate-pressure refrigerant is used, the refrigerating capacity is improved by the economizer effect.

[0006]

However, in the two-stage compressor described above, a rolling piston type rotary compressor is applied to both the low-stage compression mechanism and the high-stage compression mechanism. In this rolling piston type rotary compressor, a piston is eccentrically provided in a cylinder, and a blade is provided so as to be able to protrude and retract in the cylinder. The tip of the blade slides on the outer peripheral surface of the piston to rotate the piston.

Therefore, there is a problem that the blade is worn because the blade comes into contact with the piston. In particular, since the refrigerant is compressed in two stages, the compression ratio becomes high,
Since the temperature of the discharged refrigerant becomes high, the influence of friction appears more remarkably.

As a result, there has been a problem that the foreign matter due to the abrasion flows in the refrigerant circuit, causing problems such as blockage of the capillary tube.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and has as its object to improve compressor efficiency without causing blade wear or the like.

[0010]

[Means for Solving the Problems]

-Summary of the Invention- The present invention is such that a rotary compressor in which a piston and a blade are integrally formed is applied to at least either a low-stage compression mechanism or a high-stage compression mechanism.

-Solution Means- Specifically, a first solution means is that a low-stage compression mechanism (5L) and a high-stage compression mechanism (5H) are housed in a casing (31), and the two compression mechanisms (5H) are housed. 5L, 5H), which presupposes a two-stage compressor that compresses the low-pressure fluid in two stages and discharges the high-pressure fluid.

A high pressure fluid discharge pipe (2d) is connected to the casing (31), and at least the casing (3
A high-pressure atmosphere in which the discharge pipe (2d) communicates with a part of 1) is configured. Further, the suction port (51) of the low-stage compression mechanism (5L) communicates with the suction pipe (2r) for the low-pressure fluid, and the discharge port (53) of the low-stage compression mechanism (5L) communicates with the high stage. The suction port (52) of the side compression mechanism (5H) communicates through the intermediate passage (55), and the discharge port (54) of the high-stage compression mechanism (5H)
It opens to the high-pressure atmosphere in the casing (31). On the other hand, an introduction pipe (2B) for introducing an intermediate pressure fluid intermediate between the low pressure fluid and the high pressure fluid is communicated with the intermediate passage (55). In addition, at least one of the low-stage compression mechanism (5L) and the high-stage compression mechanism (5H) accommodates an eccentric annular piston (61) in a cylinder (60), and the piston (61). ) Is integrally formed with a blade (64) to constitute a rotary compressor in which the piston (61) swings to compress a fluid.

Further, as shown in FIG. 1, the second solution is the same as the first solution, except that the low-stage compression mechanism (5
L) and the high-stage compression mechanism (5H) are both configured as rotary compressors, and the inside of the casing (31) is entirely configured to have a high-pressure atmosphere. And the low stage compression mechanism (5L)
High-stage compression mechanism (5H) above the low-stage cylinder (60)
The high-stage side cylinder (60) is installed along with a middle plate (6m). Further, the lower surface of the lower stage cylinder (60) is closed by the lower plate (6d), while the upper surface of the higher stage cylinder (60) is closed by the upper plate (6u). In addition, the intermediate passage (55) is connected to the discharge port (53) of the low-stage compression mechanism (5L) and the intermediate pressure fluid introduction pipe (2B).
The middle plate (6m) is formed so as to communicate with the suction port (52) of the high-stage compression mechanism (5H).

As shown in FIG. 6, the third solution is the same as the first solution, except that the low-stage compression mechanism (5
L) and the high-stage compression mechanism (5H) are both configured as rotary compressors, and the inside of the casing (31) is entirely configured to have a high-pressure atmosphere. And the low stage compression mechanism (5L)
Above the low-stage cylinder (60) of the high-stage compression mechanism (5
H) High stage side cylinder (60) is middle plate (6m)
It is attached through. Furthermore, low-stage cylinder (60)
Is closed by the lower plate (6d),
The upper surface of the high-stage cylinder (60) is closed by the upper plate (6u). In addition, the intermediate passage (55) is connected to the discharge port (53) of the low-stage compression mechanism (5L), the inlet pipe (2B) for the intermediate-pressure fluid, and the suction port (52) of the high-stage compression mechanism (5H). Are formed from the lower plate (6d) to the high-stage side cylinder (60) via the low-stage cylinder (60) and the middle plate (6m) so that they communicate with each other.

As shown in FIG. 7, the fourth solution is the same as the first solution, except that the low-stage compression mechanism (5
L) and the high-stage compression mechanism (5H) are both configured as rotary compressors, and the inside of the casing (31) is entirely configured to have a high-pressure atmosphere. And the low stage compression mechanism (5L)
High-stage compression mechanism (5H) below the low-stage cylinder (60)
The high-stage side cylinder (60) is installed along with a middle plate (6m). Further, the upper surface of the lower stage cylinder (60) is closed by the upper plate (6u), while the lower surface of the higher stage cylinder (60) is closed by the lower plate (6d). In addition, the intermediate passage (55) is connected to the discharge port (53) of the low-stage compression mechanism (5L) and the intermediate pressure fluid introduction pipe (2B).
The middle plate (6m) is formed so as to communicate with the suction port (52) of the high-stage compression mechanism (5H).

As shown in FIG. 8, the fifth solution is the same as the first solution, except that the low-stage compression mechanism (5
L) and the high-stage compression mechanism (5H) are both configured as rotary compressors, and the inside of the casing (31) is entirely configured to have a high-pressure atmosphere. And the low stage compression mechanism (5L)
High-stage compression mechanism (5H) below the low-stage cylinder (60)
The high-stage side cylinder (60) is installed along with a middle plate (6m). Further, the upper surface of the lower stage cylinder (60) is closed by the upper plate (6u), while the lower surface of the higher stage cylinder (60) is closed by the lower plate (6d). In addition, the intermediate passage (55) is connected to the discharge port (53) of the low-stage compression mechanism (5L) and the intermediate pressure fluid introduction pipe (2B).
From the upper plate (6u), the lower stage cylinder (6) is connected so that the intake port (52) of the higher stage compression mechanism (5H) communicates with
0) and middle plate (6m)
0).

As shown in FIG. 9, the sixth solution is the same as the first solution, except that the low-stage compression mechanism (5
L) is configured as a rotary compressor. In addition, the high-stage side compression mechanism (5H) has a fixed scroll (70) and a revolving scroll (71) that are formed by projecting spiral wraps (7c, 7d) on one side of the end plates (7a, 7b). The orbiting scroll (71) is arranged so as to mesh with each other, and the orbiting scroll (71) is configured as a scroll compressor that performs only orbiting to compress the fluid, and the compressed fluid compressed by the fixed scroll (70) and the orbiting scroll (71) is An auxiliary valve (76) is provided which allows only the discharge of the compressed fluid to the high-pressure atmosphere when the discharge pressure of the high-pressure atmosphere is reached.

According to a seventh aspect of the present invention, as shown in FIG. 10, the high-stage side compression mechanism (5H) is a rotary compressor in the first aspect. In addition, the low-stage compression mechanism (5L) has a fixed scroll (70) and a revolving scroll (71) in which spiral wraps (7c, 7d) protrude from one side of the end plates (7a, 7b). The orbiting scroll (71) is arranged so as to mesh with each other, and the orbiting scroll (71) is configured as a scroll compressor that performs only orbiting to compress the fluid, and the compressed fluid compressed by the fixed scroll (70) and the orbiting scroll (71) is An auxiliary valve (76) that allows only the discharge of the compressed fluid to the intermediate passage (55) when the pressure becomes intermediate.
Is provided.

An eighth solution is the two-stage compressor (30) according to any one of the first to seventh solutions.
And a heat source side heat exchanger (22), a first expansion mechanism (E1), a gas-liquid separator (23), a second expansion mechanism (E2), and a use side heat exchanger (24) are connected in this order, Circulating refrigerant circuit (2
0) is configured. In addition, the two-stage compressor (30)
An inlet pipe (2B) that supplies intermediate-pressure refrigerant from the gas-liquid separator (23) to the two-stage compressor (30) between the gas-liquid separator (23)
Is connected.

According to the present invention, when the low-stage compression mechanism (5L) and the high-stage compression mechanism (5H) are driven, for example, in the sixth solution, the low-stage compression mechanism The rotary compressor of the mechanism (5L) is driven, and the scroll compressor of the high-stage compression mechanism (5H) is driven. On the other hand, in the seventh solution, the scroll compressor of the low-stage compression mechanism (5L) is driven. Then, the rotary compressor of the high-stage compression mechanism (5H) is driven.

The rotary compressor of the low-stage compression mechanism (5L) or the high-stage compression mechanism (5H) is driven. In the high-stage compression mechanism (5H), the piston (61) swings and revolves integrally with the blade (64). For example, in the eighth solution, the low-pressure refrigerant returning from the refrigerant circuit (20) flows into the cylinder chamber (6s) from the suction passage (51) of the low-stage compression mechanism (5L), and the piston (61) ) Is compressed by the swing.

On the other hand, since the intermediate-pressure refrigerant is supplied to the intermediate passage (55) from the gas-liquid separator (23), in the second to seventh solving means, the low-stage compression mechanism ( The discharge port (53) of 5L) opens when the refrigerant pressure reaches an intermediate pressure.
After that, the intermediate-pressure refrigerant discharged from the low-stage compression mechanism (5L) and the intermediate-pressure refrigerant supplied from the gas-liquid separator (23) merge in the intermediate passage (55), and the high-stage compression mechanism (5H) Flows into.

The high-stage compression mechanism (5H) compresses the intermediate-pressure refrigerant and discharges the high-pressure refrigerant into the casing (31). The high-pressure refrigerant flows out to the refrigerant circuit (20), and the refrigerant circulates through the refrigerant circuit (20).

[0024]

Therefore, according to the present invention, at least one of the low-stage compression mechanism (5L) and the high-stage compression mechanism (5H) is provided with a rotary in which the piston (61) and the blade (64) are integrated. Since the compressor is used, the blade (64) and the piston (61) do not come into contact with each other as compared with a rolling piston type rotary compressor. Therefore, wear of the blade (64) can be suppressed.

In particular, in the high-stage compression mechanism (5H),
Although the temperature of the discharged refrigerant increases, there is no wear of the blade (64), so that the influence of friction can be more reliably suppressed.

As a result, foreign matter due to the abrasion does not flow in the refrigerant circuit (20), so that blockage of the circuit and the like can be reliably prevented.

Further, according to the sixth and seventh solutions, the auxiliary valve of the scroll compressor opens when compressed to a fluid of a predetermined pressure, so that over-compression can be reliably prevented.

According to the eighth solution, the intermediate-pressure refrigerant is supplied to the intermediate passage (55) between the low-stage compression mechanism (5L) and the high-stage compression mechanism (5H). Since the cooling capacity and the heating capacity can be improved, the COP (coefficient of performance) can be improved.

Further, since the refrigerant is compressed in two stages, an increase in the discharge temperature of the refrigerant can be suppressed.

[0030]

Embodiment 1 Hereinafter, Embodiment 1 of the present invention will be described in detail with reference to the drawings.

As shown in FIG. 2, the air conditioner (10)
Is a heat pump type air conditioner, which is configured to be switchable between a cooling operation and a heating operation.

The refrigerant circuit (20) of the air conditioner (10)
Are a compressor (30), a four-way switching valve (21), an outdoor heat exchanger (22) as a heat source side heat exchanger, a first expansion valve (E1) as a first expansion mechanism, and a gas-liquid separator ( 23), a second expansion valve (E2) serving as a second expansion mechanism, an indoor heat exchanger (24) serving as a use-side heat exchanger, and an accumulator (25) are sequentially connected by a refrigerant pipe (26). Equipped with a refrigerant circuit (2M).

The four-way switching valve (21) switches between a cooling operation indicated by a solid line in FIG. 2 and a heating operation indicated by a broken line in FIG.

The refrigerant circuit (20) is provided with an injection pipe (2B). The injection pipe (2B) is an introduction pipe for injecting an intermediate-pressure gas refrigerant, which is an intermediate-pressure fluid, into the compressor (30), and has one end connected to the gas-liquid separator (23) and the other end connected to the compressor (30). ). That is, the gas-liquid separator (23) stores an intermediate-pressure refrigerant having an intermediate pressure between the condensing pressure of the refrigerant as the high-pressure fluid and the evaporation pressure of the refrigerant as the low-pressure fluid. The injection pipe (2B) converts the gas-phase intermediate-pressure gas refrigerant of the gas-liquid separator (23) into a compressor (30).
Injection.

The first expansion valve (E1) and the second expansion valve (E2)
Is composed of a motor-operated valve whose opening can be adjusted freely. And
The intermediate-pressure refrigerant depressurized by the first expansion valve (E1) or the second expansion valve (E2) is stored in the gas-liquid separator (23).

The compressor (30) is configured to control the operation capacity in a stepless or multi-step manner. The compressor (30) is a two-stage compressor as a feature of the present invention,
As shown in FIG. 1, a motor (40), a low-stage compression mechanism (5L) and a high-stage compression mechanism (5H) are housed in a closed casing (31).

The motor (40) includes a stator (41) fixed to an inner peripheral surface of a casing (31), and a stator (41).
And a rotor (42) disposed at the center of the rotor.
The drive shaft (32) is connected to the center of the rotor (42). The drive shaft (32) extends downward and is connected to the low-stage compression mechanism (5L) and the high-stage compression mechanism (5H).

The bottom of the casing (31) is formed as a lubricating oil reservoir (33). The lower end of the drive shaft (32) is immersed in the lubricating oil of the oil reservoir (33). ing.
Although not shown, a centrifugal oil pump (not shown) is provided at the lower end of the drive shaft (32), and lubricating oil passes through an oil supply passage (34) in the drive shaft (32) and is compressed at a lower stage. It is supplied to the sliding parts of the mechanism (5L) and the high-stage compression mechanism (5H).

The low-stage compression mechanism (5L) and the high-stage compression mechanism (5H) are located vertically below the motor (40). Each of the low-stage compression mechanism (5L) and the high-stage compression mechanism (5H) is a so-called swing type rotary compressor as a feature of the present invention.

The low-stage compression mechanism (5L) and the high-stage compression mechanism (5H) have substantially the same configuration, and the high-stage compression mechanism (5H) is located above the low-stage compression mechanism (5L). Is arranged. As shown in FIG. 3, the compression mechanisms (5L, 5H) each include a piston (61) housed in a cylinder chamber (6s) formed in a cylinder (60). A middle plate (6 m) is provided between the cylinders (60) of the two compression mechanisms (5L, 5H), and a lower plate (6d) is provided on the lower surface of the low-stage cylinder (60) and closed. The upper surface of the high-stage side cylinder (60) is provided with an upper plate (6u) and is closed.

On the other hand, the piston (61) of each compression mechanism (5L, 5H) is formed in an annular shape, and the eccentric shaft (62) is rotatably fitted therein. The eccentric shaft (62) is formed eccentric to the drive shaft (32).

Each cylinder (60) has a suction passage (51,
52) is formed, and one end of the suction passage (51, 52) opens to the cylinder chamber (6s) to form a suction port. The middle plate (6m) has a discharge passage (53) for the low-stage compression mechanism (5L), while the upper plate (6u) has a discharge passage (54) for the high-stage compression mechanism (5H). ) Is formed,
One end of each of the discharge passages (53, 54) opens to the cylinder chamber (6s) to form a discharge port. Although not shown, each of the discharge passages (53, 54) is provided with a discharge valve that opens a discharge port when a predetermined discharge pressure is reached.

In the cylinder (60), a cylindrical bush hole (63) is formed between the suction port and the discharge port so as to open in the cylinder chamber (6s). The piston (61) has a blade (6
4) is integrally formed. The tip side of the blade (64) has a pair of swinging bushes (6
b) has been inserted through.

The blade (64) is provided in the cylinder chamber (6s).
To the low-pressure chamber and the discharge passage (5
It is divided into a high-pressure chamber that leads to (3, 54). The piston (61) is connected to the swinging bush (6) through the blade (64).
It is configured to swing around the fulcrum b) and revolve around the cylinder chamber (6s) to compress the refrigerant.

The suction passage (5) of the low-stage compression mechanism (5L)
1) is connected to the suction-side refrigerant pipe (2r) of the main refrigerant circuit (2M). The suction-side refrigerant pipe (2r) is configured as a suction pipe that supplies a low-pressure gas refrigerant to the low-stage compression mechanism (5L).

On the other hand, an annular intermediate passage (55) is formed in the middle plate (6m). Then, the injection pipe (2B) is connected to the middle plate (6m), and the injection pipe (2B) communicates with the intermediate passage (55). That is, the intermediate passage (55) is supplied with an intermediate-pressure gas refrigerant and is configured to have an intermediate-pressure atmosphere.

The discharge passage (53) of the low-stage compression mechanism (5L) communicates with the intermediate passage (55), while the suction passage (52) of the high-stage compression mechanism (5H) communicates with the intermediate passage (55). ), And the intermediate-pressure refrigerant is supplied to the high-stage compression mechanism (5H).

The discharge passage (54) of the high-stage compression mechanism (5H) is opened in the casing (31), and the inside of the casing (31) is configured to have a high-pressure atmosphere. The upper part of the casing (31) has a main refrigerant circuit (2
M) is connected to the discharge side refrigerant pipe (2d). The discharge-side refrigerant pipe (2d) is configured as a discharge pipe that discharges a high-pressure gas refrigerant.

The upper plate (6u) has an upper muffler (6) covering the discharge passage (54) of the high-stage compression mechanism (5H).
5) is provided.

-Air Conditioning Operation- Next, the air conditioning operation of the air conditioner (10) will be described.

First, during the indoor cooling operation, the four-way switching valve (21) is switched to the solid line side in FIG. The refrigerant discharged from the compressor (30) exchanges heat with outside air in the outdoor heat exchanger (22) and condenses. This liquid refrigerant is reduced in pressure by the first expansion valve (E1), becomes an intermediate-pressure refrigerant having an intermediate pressure between the condensing pressure and the evaporation pressure, and accumulates in the gas-liquid separator (23).

Among the intermediate-pressure refrigerant in the gas-liquid separator (23), the intermediate-pressure liquid refrigerant is decompressed by the second expansion valve (E2), and then exchanges heat with indoor air in the indoor heat exchanger (24). To evaporate and cool the room air. Thereafter, the gas refrigerant returns to the compressor (30) via the accumulator (25), and performs the refrigerant circulation operation.

On the other hand, during the heating operation, the four-way switching valve (21)
Is switched to the broken line side in FIG. The refrigerant discharged from the compressor (30) exchanges heat with the indoor air in the indoor heat exchanger (24) and condenses while heating the indoor air. Thereafter, the liquid refrigerant is reduced in pressure by the second expansion valve (E2), becomes an intermediate-pressure refrigerant, and accumulates in the gas-liquid separator (23).

Of the intermediate-pressure refrigerant in the gas-liquid separator (23), the intermediate-pressure liquid refrigerant is depressurized by the first expansion valve (E1), and then exchanges heat with the outside air in the outdoor heat exchanger (22). And evaporate. Thereafter, the gas refrigerant returns to the compressor (30) via the accumulator (25), and performs the refrigerant circulation operation.

During the above-described air conditioning operation, the gas-liquid separator (2B) is provided because the injection pipe (2B) is provided.
The intermediate-pressure gas refrigerant of 3) is injected into the compressor (30).

The change in the characteristics of the refrigerant in the refrigerant circuit (20) will now be described in detail with reference to FIG.

First, the refrigerant in the compressor (30) is
It is compressed from the low pressure state at the point E to the high pressure state of the condensation pressure at the point F. This high-pressure gas refrigerant is condensed in the outdoor heat exchanger (22) or the indoor heat exchanger (24) and becomes a high-pressure liquid refrigerant at point G.
The high-pressure liquid refrigerant is reduced to an intermediate-pressure refrigerant at point H by the first expansion valve (E1) or the second expansion valve (E2), stored in the gas-liquid separator (23), and stored in the gas-liquid separator (23). ) To separate into intermediate-pressure liquid refrigerant and intermediate-pressure gas refrigerant.

The separated intermediate-pressure gas refrigerant is injected into the compressor (30) (see the point I) via the injection pipe (2B), while the intermediate-pressure liquid refrigerant is supplied from the point J to the second expansion valve ( E2) or the first expansion valve (E1) reduces the pressure to the low-pressure two-phase refrigerant to point K. The low-pressure two-phase refrigerant evaporates in the indoor heat exchanger (24) or the outdoor heat exchanger (22), changes to point E, and returns to the compressor (30).

As a result, during the heating operation, the refrigerant flowing through the indoor heat exchanger (24) serving as a condenser is added with the intermediate-pressure gas refrigerant, so that the refrigerant circulation amount increases and the heating capacity is improved. .

On the other hand, during the cooling operation, the enthalpy of the low-pressure two-phase refrigerant at the point K from the point H to the point J increases, so that the amount of heat of the refrigerant evaporated in the indoor heat exchanger (24) increases. The cooling capacity is improved.

Further, as shown in FIG. 5, the power of the X portion is reduced.

Next, the compression operation of the compressor (30) will be described.

The drive shaft (32) is driven by driving the motor (40).
Rotates, and the pistons (61) of the low-stage compression mechanism (5L) and the high-stage compression mechanism (5H) swing around the center of the bush hole (63) as a fulcrum to revolve. And the main refrigerant circuit (2M)
The low-pressure gas refrigerant returning from the accumulator (25) flows into the cylinder chamber (6s) from the suction passage (51) of the low-stage compression mechanism (5L), and is compressed by the swing of the piston (61).

On the other hand, since the intermediate-pressure refrigerant is supplied to the intermediate passage (55) from the gas-liquid separator (23), the discharge valve of the low-stage compression mechanism (5L) is located in the cylinder chamber (6s). It opens when the refrigerant pressure reaches an intermediate pressure. After that, the intermediate-pressure refrigerant discharged from the low-stage compression mechanism (5L) and the intermediate-pressure refrigerant supplied from the gas-liquid separator (23) merge in the intermediate passage (55), and the high-stage compression mechanism (5H) Into the cylinder chamber (6s).

The high-stage compression mechanism (5H) compresses the intermediate-pressure refrigerant and discharges the high-pressure refrigerant into the casing (31). This high-pressure refrigerant is supplied to the stator (4) of the motor (40).
It passes between 1) and the rotor (42) and is discharged to the main refrigerant circuit (2M). This high-pressure refrigerant circulates through the refrigerant circuit (20) as described above.

According to the present embodiment, the intermediate-pressure refrigerant is supplied to the intermediate passage (55) between the low-stage compression mechanism (5L) and the high-stage compression mechanism (5H). As a result, the cooling capacity and the heating capacity can be improved, so that the COP (coefficient of performance) can be improved.
Can be improved.

Further, since the refrigerant is compressed in two stages, it is possible to suppress an increase in the discharge temperature of the refrigerant.

Further, since a rotary compressor in which the piston (61) and the blade (64) are integrated is applied, the blade (64) and the piston (61) can be compared with a rolling piston type rotary compressor. Does not come into contact with Therefore, wear of the blade (64) can be suppressed.

In particular, in the high-stage compression mechanism (5H),
Although the temperature of the discharged refrigerant increases, there is no wear of the blade (64), so that the influence of friction can be more reliably suppressed.

As a result, foreign matter due to the abrasion does not flow in the refrigerant circuit (20), and blockage of the circuit can be reliably prevented.

[0071]

Embodiment 2 In this embodiment, as shown in FIG. 6, a discharge passage (53) of a low-stage compression mechanism (5L) is provided in a lower plate (6d). The lower plate (6d) is provided with a lower muffler (66), while the intermediate passage (55) passes through the middle plate (6m) through the lower plate (6d) and the low-stage cylinder (60). , Formed over the high-stage side cylinder (60).

As in the first embodiment, the intermediate passage (55) communicates with the injection pipe (2B) and also communicates with the suction passage (52) of the high-stage compression mechanism (5H).

Accordingly, the refrigerant compressed by the low-stage compression mechanism (5L) passes from the discharge passage (53) through the lower muffler (66), passes through the intermediate passage (55), and is drawn into the high-stage compression mechanism (5H). The refrigerant flows into the passage (52), and the intermediate-pressure refrigerant in the injection pipe (2B) merges in the intermediate passage (55). Other configurations, operations and effects are the same as those of the first embodiment.

[0074]

Third Embodiment In the present embodiment, as shown in FIG. 7, the low-stage compression mechanism (5L) and the high-stage compression mechanism (5H) of the first embodiment are arranged in reverse. The side compression mechanism (5L) is arranged above and the high-stage compression mechanism (5H) is arranged below.

That is, the low-stage compression mechanism (5L) is formed between the upper plate (6u) and the middle plate (6m), and the high-stage compression mechanism (5H) is formed between the middle plate (6m) and the lower plate (6d). ). The lower plate (6d) has a discharge passage (54) for the high-stage compression mechanism (5H) and a lower muffler (66).

A guide passage (56) extends over the lower plate (6d), the high-stage cylinder (60), the middle plate (6m), the low-stage cylinder (60), and the upper plate (6u).
Are formed in the vertical direction. The guide passage (56) communicates with the lower muffler (66) and the upper muffler (65) so as to guide the high-pressure refrigerant from the discharge passage (54) of the high-stage compression mechanism (5H) to the upper muffler (65). It is configured.

Therefore, the refrigerant compressed by the low-stage compression mechanism (5L) flows from the discharge passage (53) to the middle plate (6m).
Flows through the intermediate passage (55) to the suction passage (52) of the high-stage compression mechanism (5H), and the intermediate-pressure refrigerant in the injection pipe (2B) merges in the intermediate passage (55). The high-pressure refrigerant discharged from the high-stage compression mechanism (5H) is discharged from the lower muffler (66) through the guide passage (56), through the upper muffler (65), and into the casing (31). Other configurations, operations and effects are the same as those of the first embodiment.

[0078]

Fourth Embodiment In this embodiment, as shown in FIG. 8, the low-stage compression mechanism (5L) and the high-stage compression mechanism (5H) of the second embodiment are arranged in reverse. The side compression mechanism (5L) is arranged above and the high-stage compression mechanism (5H) is arranged below.

That is, the low-stage compression mechanism (5L) is formed between the upper plate (6u) and the middle plate (6m), and the high-stage compression mechanism (5H) is formed between the middle plate (6m) and the lower plate (6d). ). The upper plate (6u) has a discharge passage (5L) for the low-stage compression mechanism (5L).
3) is formed, while inside the upper muffler (65)
An intermediate muffler (67) is formed to communicate with the discharge passage (53) of the low-stage compression mechanism (5L).

The intermediate passage (55) is formed through the upper plate (6u) and the lower stage cylinder (60), passes through the middle plate (6m), and extends to the higher stage cylinder (60). The intermediate muffler (67) communicates with the suction passage (52) of the high-stage compression mechanism (5H).

On the other hand, the lower plate (6d) has a discharge passage (54) for the high-stage compression mechanism (5H) and a lower muffler (66).

A guide passage (56) extends between the lower plate (6d), the high-stage cylinder (60), the middle plate (6m), the low-stage cylinder (60), and the upper plate (6u).
Are formed in the vertical direction. The guide passage (56) communicates with the lower muffler (66) and the upper muffler (65) so as to guide the high-pressure refrigerant from the discharge passage (54) of the high-stage compression mechanism (5H) to the upper muffler (65). It is configured.

Therefore, the refrigerant compressed by the low-stage compression mechanism (5L) passes through the intermediate muffler (67) from the discharge passage (53), passes through the intermediate passage (55), and is drawn into the high-stage compression mechanism (5H). The refrigerant flows into the passage (52), and the intermediate-pressure refrigerant in the injection pipe (2B) merges in the intermediate passage (55). The high-pressure refrigerant discharged from the high-stage compression mechanism (5H) is discharged from the lower muffler (66) through the guide passage (56), through the upper muffler (65), and into the casing (31). Other configurations, operations and effects are the same as those of the first embodiment.

[0084]

Embodiment 5 In this embodiment, as shown in FIG. 9, the low-stage compression mechanism (5L) is constituted by a rotary compressor as in the first embodiment, while the high-stage compression mechanism (5H) is used. ) Is composed of a scroll compressor.

The scroll type high-stage compression mechanism (5H)
Is constituted by housing a fixed scroll (70) and a revolving scroll (71) in a casing (31). The fixed scroll (70) and the orbiting scroll (71) are provided with spiral (involute) wraps (7c, 7d) standing in front of a disk-shaped end plate (7a, 7b). The two wraps (7c, 7d) are meshed with each other, while the front faces of the two end plates (7a, 7b) face each other and are vertically arranged side by side.

The outer peripheral edge of the end plate (7a) of the fixed scroll (70) is fixed to the casing (31). A cylindrical scroll shaft (7e) protrudes from the center of the rear surface of the end plate (7b) of the orbiting scroll (71).
The rear side (lower side) of the head plate (7b) is a casing (31)
And is slidably mounted on a frame (72) fixed to the frame.

The upper end of the drive shaft is supported by a bearing (73) fixed to a frame (72), and an eccentric portion (74) is formed so as to protrude. The eccentric portion (74) is attached to the scroll shaft (7e). ) Is inserted.

The revolving scroll (71) is prevented from rotating by, for example, an Oldham ring provided between the revolving scroll (71) and the frame (72), and the rotation of the drive shaft (32) causes the axial center of the drive shaft (32) to rotate. It is configured so that only the revolving motion is performed on the fixed scroll (70) with the center as the center. Then, the compression chamber formed between the two wraps (7c, 7d) contracts while moving helically from the outside toward the center and compresses the refrigerant.

On the other hand, in the casing (31) below the frame (72), a discharge passage (5L) of the low-stage compression mechanism (5L) is provided.
3) communicates, and the injection pipe (2B) communicates to form an intermediate pressure atmosphere, which is formed in the intermediate passage (55). The end plate (7a) of the fixed scroll (70)
The inside of the casing (31) above the discharge side refrigerant pipe (2d)
Are connected to form a high-pressure atmosphere.

The outside of the wraps (7c, 7d) is formed as a suction chamber (75), and the suction chamber (75) communicates with a suction passage (52) formed in a frame (72). It communicates with the intermediate passage (55).

The end plate (7a) of the fixed scroll (70) has a discharge passage (54) formed at the center thereof and an auxiliary valve (76). The auxiliary valve (76) opens and closes the auxiliary passage (7f). When the high-pressure refrigerant that is being compressed by the fixed scroll (70) and the revolving scroll (71) reaches the discharge pressure of the high-pressure atmosphere, the auxiliary valve (76) opens. It is configured to allow only discharge to a high-pressure atmosphere.

Therefore, the refrigerant compressed by the low-stage compression mechanism (5L) is discharged to the intermediate passage (55) in the casing (31), and after the intermediate-pressure refrigerant in the injection pipe (2B) merges, Flows into the suction passage (52) of the side compression mechanism (5H).

On the other hand, the orbiting scroll (71) of the high-stage compression mechanism (5H) rotates eccentrically by the rotation of the drive shaft (32), and performs only the orbital movement with respect to the fixed scroll (70). While being formed sequentially between the wraps (7c, 7d),
Shrink while moving toward the center.

The intermediate-pressure refrigerant flows into the compression chamber from the suction chamber (75), is compressed, and is discharged from the discharge passage (54) in principle. During the compression, when the high-pressure refrigerant is compressed to a high-pressure atmosphere, the auxiliary valve (76) opens and discharges into the high-pressure atmosphere.

As a result, the refrigerant is discharged without being over-compressed. Other configurations, operations and effects are the same as those of the first embodiment.

[0096]

Sixth Embodiment In this embodiment, as shown in FIG. 10, contrary to the fifth embodiment, the low-stage compression mechanism (5L)
Is constituted by a scroll compressor, while the high-stage compression mechanism (5H) is constituted by a rotary compressor in the same manner as in the first embodiment.

That is, the low-stage compression mechanism (5L) is shown upside down in FIG. 10 as the fifth embodiment, but has almost the same configuration. The suction-side refrigerant pipe (2r) communicates with the suction chamber (75) of the low-stage compression mechanism (5L), while the rear surface (lower surface) of the end plate (7a) of the fixed scroll (70) An intermediate muffler (77) is provided.
An intermediate passage (55) communicates with the intermediate muffler (77), and the intermediate passage (55) is connected to the high-stage compression mechanism (5H) through the end plate (7a) of the fixed scroll (70) and the frame (72). ) Is in communication with the suction passage (52).

The auxiliary valve (76) of the low-stage side compression mechanism (5L), which is a scroll type compressor, opens when the refrigerant is compressed to an intermediate pressure during compression, and the refrigerant flows through the intermediate muffler (77). To be discharged.

The high-stage compression mechanism (5H) is a rotary compressor in which a piston (81) is housed in a cylinder chamber (8S) in a cylinder (80), and has the same configuration as in the first embodiment. Have been. The upper and lower surfaces of the cylinder chamber (8S) are closed by an upper plate (82) and a lower plate (83), and the piston (81) is eccentrically provided by an eccentric part (84).

The discharge passage (54) of the high-stage compression mechanism (5H) is opened in the casing (31), and the inside of the casing (31) is configured to have a high-pressure atmosphere. Other configurations, operations and effects are the same as those of the fifth embodiment.

[0101]

In the fifth embodiment, almost the majority of the casing (31) is constituted by the intermediate passage (55). However, the discharge passage (53) of the low-stage compression mechanism (5L) is connected to the intermediate passage (55). The suction passage (54) of the high-stage compression mechanism (5H) may be connected to the suction passage (54) by an intermediate passage (55) such as a pipe, so that the entire inside of the casing (31) may be configured to have a high-pressure atmosphere.

Further, in the sixth embodiment, the inside of the casing (31) is constituted entirely in a high-pressure atmosphere. However, similarly to the fifth embodiment, the discharge passage (53) of the low-stage compression mechanism (5L) is connected to the casing (31). An intermediate passage (55) constitutes the majority of the casing (31) in communication with the intermediate passage (55), and the suction passage (52) of the high-stage compression mechanism (5H) communicates with the intermediate passage (55). You may.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view showing a compressor according to a first embodiment.

FIG. 2 is a refrigerant circuit diagram showing the first embodiment.

FIG. 3 is a plan sectional view showing a low-stage compression mechanism and a high-stage compression mechanism.

FIG. 4 is a Mollier chart showing refrigerant characteristics of the refrigerant circuit of the first embodiment.

FIG. 5 is a state diagram showing a relationship between a pressure and a volume of the compressor of the first embodiment.

FIG. 6 is a longitudinal sectional view showing a compressor according to a second embodiment.

FIG. 7 is a longitudinal sectional view showing a compressor according to a third embodiment.

FIG. 8 is a longitudinal sectional view showing a compressor according to a fourth embodiment.

FIG. 9 is a longitudinal sectional view showing a compressor according to a fifth embodiment.

FIG. 10 is a longitudinal sectional view showing a compressor according to a sixth embodiment.

[Explanation of symbols]

 10 Air conditioner 20 Refrigerant circuit 2B Injection pipe (introduction pipe) 30 Compressor 31 Casing 40 Motor 5L Low-stage compression mechanism 5H High-stage compression mechanism 51, 52 Suction passage 53, 54 Discharge passage 55 Intermediate passage 56 Guide passage 60 , 80 cylinder 61, 81 piston 64 blade 70 fixed scroll 71 orbiting scroll 7a, 7b end plate 7c, 7d lap 76 auxiliary valve

Claims (8)

[Claims] A low-stage compression mechanism (5) is provided on a casing (31).
L) and the high-stage compression mechanism (5H) are housed, and the two-stage compression mechanism (5L, 5H) compresses the low-pressure fluid in two stages and discharges the high-pressure fluid. Is connected to a discharge pipe (2d) for high-pressure fluid, and at least a part of the casing (31) forms a high-pressure atmosphere in which the discharge pipe (2d) communicates with the suction pipe (5L). A low pressure fluid suction pipe (2r) communicates with 51), and the discharge port (53) of the low-stage compression mechanism (5L) and the suction port (52) of the high-stage compression mechanism (5H) are intermediate. The discharge port (54) of the high-stage compression mechanism (5H) is open to the high-pressure atmosphere in the casing (31), while the intermediate passage (55) is connected to the low-pressure path through the passage (55). An introduction pipe (2B) for introducing an intermediate-pressure fluid intermediate between the fluid and the high-pressure fluid communicates with the low-stage compression mechanism (5L) and the high-stage compression mechanism. At least one of the 5H), together with the annular piston eccentrically in the cylinder (60) (61) is housed, the piston (61)
The blade (64) is formed integrally with the piston (61)
A rotary compressor for compressing a fluid by oscillating motion. 2. The two-stage compressor according to claim 1, wherein both the low-stage compression mechanism (5L) and the high-stage compression mechanism (5H) are configured as rotary compressors, and the casing (31).
The entire interior is composed of a high-pressure atmosphere, and the high-stage cylinder (60) of the high-stage compression mechanism (5H) is above the middle plate (6m) above the low-stage cylinder (60) of the low-stage compression mechanism (5L). ), The lower surface of the lower cylinder (60) is closed by the lower plate (6d), while the upper surface of the higher cylinder (60) is closed by the upper plate (6u), and the intermediate passage ( 55) is the discharge port (5L) of the low-stage compression mechanism (5L).
3), the intermediate pressure fluid introduction pipe (2B) and the high-stage compression mechanism (5
A two-stage compressor, wherein the middle plate (6m) is formed so as to communicate with the suction port (52) of H). 3. The two-stage compressor according to claim 1, wherein both the low-stage compression mechanism (5L) and the high-stage compression mechanism (5H) are configured as a rotary compressor, and the casing (31).
The entire interior is composed of a high-pressure atmosphere, and the high-stage cylinder (60) of the high-stage compression mechanism (5H) is above the middle plate (6m) above the low-stage cylinder (60) of the low-stage compression mechanism (5L). ), The lower surface of the lower cylinder (60) is closed by the lower plate (6d), while the upper surface of the higher cylinder (60) is closed by the upper plate (6u), and the intermediate passage ( 55) is the discharge port (5L) of the low-stage compression mechanism (5L).
3), the intermediate pressure fluid introduction pipe (2B) and the high-stage compression mechanism (5
H) is formed from the lower plate (6d) to the high-stage cylinder (60) through the low-stage cylinder (60) and the middle plate (6m) so as to communicate with the suction port (52) of H). A two-stage compressor. 4. The two-stage compressor according to claim 1, wherein the low-stage compression mechanism (5L) and the high-stage compression mechanism (5H) are both configured as rotary compressors, and the casing (31).
The interior is entirely composed of a high-pressure atmosphere, and the high-stage cylinder (60) of the high-stage compression mechanism (5H) is placed under the middle plate (6m) below the low-stage cylinder (60) of the low-stage compression mechanism (5L). ), The upper surface of the lower stage cylinder (60) is closed by the upper plate (6u), while the lower surface of the higher stage cylinder (60) is closed by the lower plate (6d), and the intermediate passage ( 55) is the discharge port (5L) of the low-stage compression mechanism (5L).
3), the intermediate pressure fluid introduction pipe (2B) and the high-stage compression mechanism (5
A two-stage compressor, wherein the middle plate (6m) is formed so as to communicate with the suction port (52) of H). 5. The two-stage compressor according to claim 1, wherein the low-stage compression mechanism (5L) and the high-stage compression mechanism (5H) are both configured as a rotary compressor, and the casing (31).
The interior is entirely composed of a high-pressure atmosphere, and the high-stage cylinder (60) of the high-stage compression mechanism (5H) is placed under the middle plate (6m) below the low-stage cylinder (60) of the low-stage compression mechanism (5L). ), The upper surface of the lower stage cylinder (60) is closed by the upper plate (6u), while the lower surface of the higher stage cylinder (60) is closed by the lower plate (6d), and the intermediate passage ( 55) is the discharge port (5L) of the low-stage compression mechanism (5L).
3), the intermediate pressure fluid introduction pipe (2B) and the high-stage compression mechanism (5
H) is formed from the upper plate (6u) to the high-stage cylinder (60) through the low-stage cylinder (60) and the middle plate (6m) so that the suction port (52) of H) communicates with the intake port (52). A two-stage compressor. 6. The two-stage compressor according to claim 1, wherein the low-stage compression mechanism (5L) is configured as a rotary compressor, while the high-stage compression mechanism (5H) includes a head plate (7a, 7b). The fixed scroll (70), which has spiral wraps (7c, 7d) protrudingly formed on one side thereof, and the revolving scroll (71) are arranged so as to mesh with each other. When the compressed fluid compressed by the fixed scroll (70) and the revolving scroll (71) has the discharge pressure of the high-pressure atmosphere, only the discharge of the compressed fluid to the high-pressure atmosphere is permitted. A two-stage compressor, comprising: an auxiliary valve (76) for performing the operation. 7. The two-stage compressor according to claim 1, wherein the high-stage compression mechanism (5H) is configured as a rotary compressor, while the low-stage compression mechanism (5L) includes a head plate (7a, 7b). The fixed scroll (70), which has spiral wraps (7c, 7d) protrudingly formed on one side thereof, and the revolving scroll (71) are arranged so as to mesh with each other. When the compressed fluid compressed by the fixed scroll (70) and the revolving scroll (71) has an intermediate pressure, only discharge of the compressed fluid to the intermediate passage (55) is permitted. Auxiliary valve (7
(2) A two-stage compressor comprising: 8. The two-stage compressor (30) according to any one of claims 1 to 7, a heat source side heat exchanger (22), a first expansion mechanism (E1), and a gas-liquid separator (30). 23) and the second expansion mechanism (E2)
And the use-side heat exchanger (24) are connected in order to form a refrigerant circuit (20) through which the refrigerant circulates, and between the two-stage compressor (30) and the gas-liquid separator (23). Is
An air conditioner, wherein an inlet pipe (2B) for supplying an intermediate-pressure refrigerant from a gas-liquid separator (23) to a two-stage compressor (30) is connected.