KR101891616B1 - Twin rotary compressor and Heat pump having the same - Google Patents

Abstract

The heat pump of the present invention includes a twin rotary compressor in which an intermediate plate is disposed between a first compression chamber and a second compression chamber, and the refrigerant is sucked in the first compression chamber and the second compression chamber to compress and discharge the refrigerant; An outdoor heat exchanger in which the refrigerant is condensed or evaporated; An indoor heat exchanger in which the refrigerant is evaporated or condensed; An expansion mechanism for expanding the refrigerant between the outdoor heat exchanger and the indoor heat exchanger; A twin rotary compressor includes an intermediate plate connecting flow path for guiding the refrigerant guided to the intermediate plate by the injection flow path; And an intermediate plate injection channel in which the refrigerant guided by the intermediate plate connecting flow path is injected into the first compression chamber and the second compression chamber from the intermediate plate after passing through the intermediate plate, There is an advantage that the refrigerant can be injected into both of the first and second compression chambers by a simple structure using an intermediate plate without installing an injection pipe of the refrigerant.

Description

[0001] Twin rotary compressor and heat pump having same [0002]

The present invention relates to a twin rotary compressor and a heat pump having the twin rotary compressor, and more particularly to a twin rotary compressor in which an intermediate plate for partitioning a plurality of compression chambers is disposed, and a heat pump having the twin rotary compressor.

Generally, a heat pump includes a compressor, an outdoor heat exchanger, an expansion mechanism, and an indoor heat exchanger to cool or heat the room.

If the heat pump is operated in a cold condition when the outdoor temperature is too high or in a bad condition where the outdoor temperature is too low, if the compressor is driven in response to the load, the reliability of the heat pump may be low have.

The heat pump may inject the supercooled liquid refrigerant into the compressor in the outdoor heat exchanger or the indoor heat exchanger to lower the discharge temperature of the compressor, or inject the intermediate-pressure gaseous refrigerant separated from the gas-liquid separator into the compressor.

KR 10-2010-0112486 A (2010.10.19)

In the rotary two-stage compressor according to the related art, since the low-pressure side compression assembly and the high-pressure side compression assembly are connected by a connection pipe and the injection pipe is connected to the connection pipe, in the case of a twin rotary compressor in which refrigerant is not compressed in multiple stages, There is a problem that is difficult to lower.

In order to solve the above problems, a twin rotary compressor according to the present invention is a twin rotary compressor for sucking refrigerant in a first compression chamber and a second compression chamber for compression and discharge, An intermediate plate disposed on the intermediate plate; An intermediate plate connecting flow path for guiding the refrigerant guided by the injection flow path to the intermediate plate; And an intermediate plate injection flow path through which the refrigerant guided by the intermediate plate connecting flow path is injected into the first compression chamber and the second compression chamber from the intermediate plate after passing through the intermediate plate.

A heat pump having a twin rotary compressor according to the present invention includes a twin rotary compressor in which an intermediate plate is disposed between a first compression chamber and a second compression chamber and the refrigerant is sucked in the first compression chamber and the second compression chamber to compress and discharge the refrigerant, ; An outdoor heat exchanger in which the refrigerant is condensed or evaporated; An indoor heat exchanger in which the refrigerant is evaporated or condensed; An expansion mechanism for expanding the refrigerant between the outdoor heat exchanger and the indoor heat exchanger; A twin rotary compressor includes an intermediate plate connecting flow path for guiding the refrigerant guided by the injection flow path to an intermediate plate; And an intermediate plate injection flow path through which the refrigerant guided by the intermediate plate connecting flow path is injected into the first compression chamber and the second compression chamber from the intermediate plate after passing through the intermediate plate.

 Wherein the intermediate plate injection flow path includes a common flow passage to which the intermediate plate connecting flow passage is connected, a first compression chamber injection flow passage for communicating the common flow passage and the first compression chamber, and a second compression chamber injection flow passage for communicating the common flow passage with the second compression chamber And a compression chamber injection flow path.

The common flow path may be formed between the upper surface and the lower surface of the intermediate plate.

At least one of the first compression chamber injection path and the second compression chamber injection path may be formed in the intermediate plate at right angles to the common flow path.

One end of the common flow path may be formed on an outer edge of the intermediate plate, and may be formed between an upper surface and a lower surface of the intermediate plate, and the other end may be positioned inside the intermediate plate.

One end of the first compression chamber injection flow path may communicate with the common flow path inside the intermediate plate and the other end may be open to one surface of the intermediate plate. The second compression chamber injection flow path may have one end communicating with the common flow path inside the intermediate plate and the other end opening to the other side of the intermediate plate.

The first compression chamber injection flow path and the second compression chamber injection flow path may be opened vertically at the same position of the intermediate plate.

The first compression chamber injection flow path and the second compression chamber injection flow path may be formed at positions that are not blocked by the rollers when the angle of the rollers is an injection set angle.

The present invention is advantageous in that the refrigerant can be injected into both the first and second compression chambers by a simple structure using an intermediate plate without providing respective injection pipes for injecting the refrigerant into the first and second compression chambers.

Further, the liquid refrigerant can be injected into the first and second compression chambers through the intermediate plate during the heating operation in which the outdoor temperature is low, so that the flow rate of the refrigerant can be increased and the heating performance can be enhanced.

Further, the liquid refrigerant can be injected into the first and second compression chambers through the intermediate plate during the cooling operation in which the outdoor temperature is high, so that the compressor discharge temperature can be reduced, and the frequency of the compressor can be increased by decreasing the compressor discharge temperature. There is an advantage to increase.

1 is a view showing an embodiment of a heat pump according to the present invention,
2 is a cross-sectional view of a twin rotary compressor of one embodiment of a heat pump according to the present invention,
Fig. 3 is a cross-sectional view of the middle plate of Fig. 2,
4 is a plan view showing an example of a compression chamber of a heat pump according to an embodiment of the present invention,
5 is a plan view showing another example of the compression chamber of one embodiment of the heat pump according to the present invention.

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

1 is a view illustrating an embodiment of a heat pump according to the present invention.

1, the heat pump includes a twin rotary compressor 2; An outdoor heat exchanger (4) in which the refrigerant is condensed or evaporated; An indoor heat exchanger (6) for evaporating or condensing the refrigerant; an expansion mechanism (8) for expanding the refrigerant between the outdoor heat exchanger (4) and the indoor heat exchanger (6); And an injection flow path 12 for injecting the refrigerant into the space between the outdoor heat exchanger 4 and the indoor heat exchanger 6.

The twin rotary compressors 2 are capable of compressing refrigerant in two compression chambers by means of a single motor, and can suck and compress the refrigerant in the first compression chamber and the second compression chamber, respectively, and then discharge the refrigerant.

The twin rotary compressor (2) can be composed of an inverter compressor whose compression capacity is variable according to the input frequency.

The twin rotary compressor (2) may be connected to an accumulator (3) for accumulating liquid refrigerant in the refrigerant sucked into the twin rotary compressor (2). The twin rotary compressors 2 may be connected to the accumulators 3 and the suction pipes 2a and 2b. The suction pipes 2a and 2b may be provided in a single or a plurality of suction pipes 2a and 2b.

The outdoor heat exchanger (4) causes the refrigerant to be heat-exchanged with the outdoor air flowing by the outdoor fan (5) to condense or evaporate the refrigerant. The outdoor fan (5) is located outdoors together with the outdoor heat exchanger (4) to allow outdoor air to flow to the outdoor heat exchanger (4).

The heat pump may be composed of a heat pump type air conditioner or a heat pump type hot water supplying device. In the case of the heat pump type air conditioner, the indoor air is heat-exchanged with the refrigerant in the indoor heat exchanger 6, and is then discharged to the room to change the room temperature. In the case of the heat pump type hot water supply device, the liquid heating medium such as water or antifreeze can be used for hot water after heat exchange with the refrigerant in the indoor heat exchanger 6.

The indoor heat exchanger (6) is composed of a fin-tube heat exchanger including a refrigerant tube through which refrigerant passes and at least one pin coupled to the refrigerant tube in the case of a heat pump type air conditioner, And can be heat-exchanged with the refrigerant.

The indoor heat exchanger (6) can exchange indoor air flowing by the indoor fan (7) and refrigerant passing therethrough to condense or evaporate the refrigerant.

In the case of the heat pump type hot water supply device, the indoor heat exchanger (6) can form the first flow path through which the refrigerant passes and the second flow path through which the liquid heating medium flows, and the refrigerant in the first flow path and the liquid heat transfer medium in the second flow path A tube-type heat exchanger or a shell-tube type heat exchanger in which heat is exchanged through a heat transfer member, and the liquid-phase heat medium can be heat-exchanged with the refrigerant through the heat transfer member while passing through the second flow path.

The indoor heat exchanger 6 can be connected to a water tank (or a hot water tank) (not shown) in which a liquid heating medium is placed and a liquid heating medium circulation channel. The liquid heating medium flowing in the water storage tank (or hot water tank) The refrigerant can be evaporated or condensed while passing through the second flow path.

The expansion mechanism 8 may include an outdoor expansion mechanism that is disposed closer to the outdoor heat exchanger 4 than the outdoor heat exchanger 4 and the indoor heat exchanger 6. The outdoor expansion mechanism may include a capillary tube, Valve. The expansion mechanism 8 may further include an indoor expansion mechanism that is disposed closer to the outdoor heat exchanger 4 than the outdoor heat exchanger 4 and the indoor heat exchanger 6. The indoor expansion mechanism may be a capillary tube, And an expansion valve.

One end of the injection flow path 12 can be connected between the outdoor heat exchanger 4 and the indoor heat exchanger 6 and the other end can be connected to the twin rotary compressor 2 itself. The injection flow path 12 may be provided with an injection valve 14 for controlling the refrigerant passing through the injection flow path 12. The injection valve 18 may be an expansion valve for expanding the refrigerant. The injection flow path 12 is provided between the outdoor heat exchanger 4 and the expansion mechanism 8 so that it can be injected into the twin rotary compressor 2 through the outdoor heat exchanger 4 during the cooling operation, And is capable of injecting the subcooled refrigerant through the indoor heat exchanger (6) into the twin rotary compressor (2) during the heating operation. The injection flow path 12 can be connected between the outdoor expansion mechanism and the indoor expansion mechanism when the expansion mechanism 8 can include both the outdoor expansion mechanism and the indoor expansion mechanism.

 The heat pump may further include a flow path switching portion 16. The flow path switching unit 16 causes the refrigerant passing through the indoor heat exchanger 6 to flow toward the twin rotary compressor 2 during the cooling operation and the refrigerant compressed and discharged from the twin rotary compressor 2 to the outdoor heat exchanger 4). ≪ / RTI > The refrigerant passing through the outdoor heat exchanger (4) flows toward the twin rotary compressor (2) during the heating operation and the refrigerant compressed and discharged from the twin rotary compressor (2) flows into the outdoor heat exchanger 4). ≪ / RTI > The four-way valve 16 can change the flow direction of the refrigerant, and the plurality of opening / closing valves can change the flow direction of the refrigerant.

The heat pump can be provided with the compressor 2, the outdoor heat exchanger 4, the outdoor fan 5, the expansion mechanism 8, the injection flow path 12 and the flow path switching portion 16 in the outdoor unit O, The indoor heat exchanger 6 and the indoor fan 7 can be installed in the indoor unit I. [ The heat pump can be installed in the outdoor unit (O) when the expansion mechanism (8) includes the outdoor expansion mechanism and the indoor expansion mechanism, and the indoor expansion mechanism can be installed in the indoor unit (I).

FIG. 2 is a cross-sectional view of a twin rotary compressor of one embodiment of a heat pump according to the present invention, FIG. 3 is an enlarged cross-sectional view of the middle plate of FIG. 2, Fig. 5 is a plan view showing another example of the compression chamber of one embodiment of the heat pump according to the present invention.

The twin rotary compressor 2 is provided with an intermediate plate 26 between the first compression chamber 22 and the second compression chamber 24 and the intermediate plate 26 between the first compression chamber 22 and the second compression chamber 24 The refrigerant is sucked and compressed and discharged.

The twin rotary compressor 2 includes a casing 32, a motor 34 disposed inside the casing 32, a first compression chamber 36 disposed in the casing 32 and compressing the refrigerant at the time of driving the motor 34, A second compression assembly 38 having a first compression assembly 36 having a first compression chamber 22 and a second compression chamber 24 disposed within the casing 32 for compressing refrigerant during operation of the motor 34, .

The casing 32 includes a hollow cylindrical shell, a base coupled to the lower portion of the shell, and a top cover coupled to the upper portion of the shell, and a sealed space may be formed therein.

The casing 32 is provided with a first suction pipe 40 for sucking and guiding the refrigerant to the first compression assembly 36 and a second suction pipe 42 for sucking and guiding the refrigerant to the second compression assembly 38 . The casing 32 may be provided with a discharge pipe 44 for guiding the refrigerant discharged after being compressed in the first compression chamber 22 and the refrigerant discharged after being compressed in the second compression chamber 24 to the outside.

The motor 34 includes a stator 52, a rotor 54, and a rotary shaft 56. The rotary shaft 56 passes through the center of the rotor 54 and is fixed to the rotor 54. When the electric current is applied to the electric motor 34, the rotor 54 is rotated by the mutual electromagnetic force between the stator 52 and the rotor 54, and the rotary shaft 56 fixed to the rotor 54 is rotated by the rotor 54 Rotate together. The rotary shaft 56 extends from the rotor 54 toward the bottom surface of the casing 32 so as to penetrate the central portion of the first compression assembly 36, the intermediate plate 26 and the second compression assembly 38.

Each of the first compression assembly 36 and the second compression assembly 38 may include cylinders 62 and 72 and eccentric portions 64 and 74 and rollers 66 and 76. The first compression assembly 36 and the second compression assembly 38 are provided with a refrigerant inlet 61 and a refrigerant inlet 61 through which the refrigerant is sucked into the compression chambers 22 and 24, The refrigerant discharge ports 63 and 73 through which the refrigerant is discharged can be formed. The first compression assembly 36 and the second compression assembly 38 may further include vanes 67 and 77 mounted on the cylinders 62 and 72 to contact the rollers 66 and 76.

 The first compression assembly 36 includes a first cylinder 62 in which the first compression chamber 22 is formed, a first eccentric portion 64 provided on the rotary shaft 56, a first eccentric portion 64, And a first roller 66 installed on the first cylinder 62 and rotating along the inner diameter of the first cylinder 62. A first vane 67, which is in constant contact with the first roller 66, may be mounted on the first cylinder 62 by being spring-biased. The first compression assembly 36 may further include a first bearing 68 forming a first compression chamber 22 with the first cylinder 62 and rotatably supporting the rotary shaft 56.

The second compression assembly 38 includes a second cylinder 72 in which the second compression chamber 24 is formed, a second eccentric portion 74 provided on the rotary shaft 56, a second eccentric portion 74, And a second roller 76 installed on the second cylinder 72 and rotating along an inner diameter of the second cylinder 72. The second cylinder (72) may be provided with a second vane (77), which is in constant contact with the second roller (76), with the spring mounted on the second cylinder (72). The second compression assembly 38 may further comprise a second bearing 78 forming a second compression chamber 24 with the second cylinder 72 and rotatably supporting the rotary shaft 56. The second eccentric portion (74) may be provided to have a phase difference of 180 ° from the first eccentric portion (64).

  The intermediate plate 26 may be disposed between the first cylinder 62 and the second cylinder 72. The intermediate plate 26 can form the first compression chamber 22 with the first cylinder 62 on one side thereof on both sides. The intermediate plate 26 can form the second compression chamber 24 together with the second cylinder 72 on the other surface of the both surfaces. The intermediate plate 26 may have a through hole 27 through which the rotary shaft 56 passes.

The twin rotary compressor (2) has an intermediate plate connecting flow path (90) for guiding the refrigerant guided to the injection flow path (12) to the intermediate plate (26); The intermediate plate 26 is injected into the first compression chamber 22 and the second compression chamber 24 after the refrigerant guided to the intermediate plate connection passage 90 passes through the intermediate plate 26, (100).

One end of the intermediate plate connection passage 90 may be connected to the injection channel 12 shown in FIG. 1 and the other end may be connected to the intermediate plate injection channel 100 formed in the intermediate plate 26. And a refrigerant pipe through which the refrigerant passes through the intermediate plate connecting passage 90. The middle plate connecting passage 90 may be composed of a refrigerant pipe having one end positioned outside the casing 32 and the other end positioned inside the casing 32 and passing through the casing 32, ) May include a refrigerant pipe connected to the intermediate plate connecting flow path 90 from the outside of the casing 32. The intermediate plate connecting flow path 90 is composed of a refrigerant pipe positioned inside the casing 32 at one end and the other end and the injection flow path 12 passes through the casing 32 and is connected to the intermediate plate connecting flow path 90 And a refrigerant pipe connected to the refrigerant pipe.

The intermediate plate injection channel 100 includes a common channel 102 to which the intermediate plate connection channel 90 is connected and a first compression chamber injection channel 104 for communicating the common channel 102 and the first compression chamber 22, And a second compression chamber injection passage 106 for communicating the common flow passage 102 and the second compression chamber 24 with each other.

 The intermediate plate 26 may be formed of a single plate, and the intermediate plate injection channel 100 may be formed by perforating the single plate.

The intermediate plate 26 can be formed in a groove shape on one surface of the upper surface and the lower surface and the first compression chamber injection path 104 and the second compression chamber injection path 106 can be formed in a groove shape It can be formed to communicate with the common flow path 102.

The intermediate plate 26 has a first plate body in which an upper common flow passage 102 is formed in a groove shape and a first compression chamber injection flow passage 104 communicates with a groove-shaped upper common flow passage, And a second plate body in which a lower common flow passage is formed in a groove shape on an upper surface thereof and a second compression chamber injection flow passage 106 is communicated with a lower common flow passage in a groove shape, and the upper common flow passage and the lower common flow passage are communicated with each other through a common flow passage 102 may be formed.

 The common flow path 102 may be formed between the upper surface and the lower surface of the intermediate plate 26. One end 102a of the common flow path 102 is formed on the outer edge of the intermediate plate 26 and is formed between the upper surface and the lower surface of the intermediate plate 26 and the other end 102b is located inside the intermediate plate 26 can do. The common flow path 102 may be formed horizontally between the upper surface and the lower surface of the intermediate plate 26.

 At least one of the first compression chamber injection path 104 and the second compression chamber injection path 106 may be formed perpendicular to the common flow path 102 in the intermediate plate 26. At least one of the first compression chamber injection path 104 and the second compression chamber injection path 106 may be formed perpendicular to the intermediate plate 26. One end of the first compression chamber injection flow path 104 may communicate with the common flow path 102 in the intermediate plate 26 and the other end may be opened on one side of the intermediate plate 26. One end of the second compression chamber injection passage 106 may communicate with the common flow passage 102 inside the intermediate plate 26 and the other end may be opened to the other surface of the intermediate plate 26.

The first compression chamber injection flow path 104 and the second compression chamber injection flow path 106 can be opened in the vertical direction at the same position of the intermediate plate 26 without having a phase difference with respect to the intermediate plate 26, Since the first eccentric portion 64 and the second eccentric portion 74 have a phase difference of 180 ° with respect to the refrigerant guided through the first compression chamber 22 and the second compression chamber 24, .

The first compression chamber injection flow path 104 and the second compression chamber injection flow path 106 are located at positions where the rollers 66 and 76 are not blocked by the rollers 66 and 76 when the angle? As shown in FIG. The first compression chamber injection flow path 104 and the second compression chamber injection flow path 106 may be blocked by the rollers 66 and 76 when the angle? Here, the angle? Of the rollers 66 and 76 is an angle at which the rollers 66 and 76 rotate about the vanes 67 and 77. And, the injection setting angle can be set to an angle at which the angle [theta] of the rollers 66 and 76 is more than 30 DEG and less than 180 DEG. When the angle? Of the rollers 66 and 76 is 30 degrees or less as shown in Fig. 4 (a), the first compression chamber injection path 104 and the second compression- Is blocked by the rollers 66 and 76 and is not blocked by the rollers 66 and 76 when it is more than 30 degrees and less than 125 degrees as shown in Figure 4 (b) And may be formed at a position blocked by the rollers 66 and 76 when the angle is 125 DEG or more. That is, the injection setting angle may be set to an angle at which the angle [theta] of the rollers 66 and 76 is more than 30 DEG and less than 125 DEG. The first compression chamber injection flow path 104 and the second compression chamber injection flow path 106 are arranged such that when the angle? Of the rollers 66 and 76 is 85 degrees or less as shown in FIG. 5A, Is blocked by the rollers 66 and 76 and blocked by the rollers 66 and 76 as shown in FIG. 5 (c) , It can be formed at a position blocked by the rollers 66 and 76 when the angle is more than 175 degrees. That is, the injection setting angle may be set to an angle at which the angle [theta] of the rollers 66 and 76 is more than 85 DEG and less than 175 DEG.

Hereinafter, the operation of the present invention will be described.

First, in the cooling operation, the twin rotary compressor 2 can be driven, and the outdoor fan 5 and the indoor fan 7 can be rotated. A frequency corresponding to the load can be input to the twin rotary compressor (2).

The twin rotary compressor 2 sucks the refrigerant into the first compression chamber 22 and the second compression chamber 24 and the refrigerant sucked into the first compression chamber 22 is compressed by the first roller 66 The refrigerant sucked into the second compression chamber 24 can be compressed by the second roller 76 and then discharged to the outside of the second compression chamber 24. [ The refrigerant discharged to the outside of the first compression chamber (22) and the refrigerant discharged to the outside of the second compression chamber (24) are discharged to the outside of the twin rotary compressor (2) through the discharge pipe (44).

The refrigerant discharged from the twin rotary compressors 2 flows into the outdoor heat exchanger 4 and is condensed in the outdoor heat exchanger 4 and then expanded in the expansion mechanism 8 and sucked into the twin rotary compressors 2 have.

When the heat pump is in the cooling operation, the injection valve 14 can be opened. When the injection valve 14 is opened, some of the subcooled refrigerant in the outdoor heat exchanger 4 flows into the injection line 12, Can be flowed to the expansion mechanism (8).

The refrigerant flowing into the injection line 12 can be guided to the twin rotary compressor 2 through the injection line 12 in the state of liquid refrigerant and can be guided to the intermediate plate 26 through the intermediate plate connecting passage 90, And may be introduced into the intermediate plate injection channel 100. [ The refrigerant flowing into the intermediate plate injection channel 100 is dispersed in the first compression chamber injection flow path 104 and the second compression chamber injection flow path 106 after passing through the common flow path 102, And the second compression chamber 24, respectively.

The refrigerant flowing into the first compression chamber 22 from the first compression chamber injection path 104 is mixed with the refrigerant compressed by the first roller 66 in the first compression chamber 22 to lower the temperature of the refrigerant, The temperature of the refrigerant discharged from the first compression chamber 22 is lowered. The refrigerant introduced into the second compression chamber 24 from the second compression chamber injection flow path 106 is mixed with the refrigerant compressed by the second roller 76 in the second compression chamber 24, And the temperature of the refrigerant discharged from the second compression chamber (24) is lowered.

The temperature of the refrigerant discharged from the first compression chamber 22 is lowered and the temperature of the refrigerant discharged from the second compression chamber 22 is lowered during the cooling operation so that the stability of the twin rotary compressor 2 is secured And the heat pump can improve the cooling performance by increasing the frequency inputted to the twin rotary compressor 2 before the injection valve 14 is opened. When the outdoor temperature is higher than the preset temperature, the heat pump opens the injection valve 14 to inject the refrigerant through the intermediate plate 26 and increases the frequency of the refrigerant input to the rotary compressor 2 to increase the cooling performance .

On the other hand, in the heating operation, the twin rotary compressor 2 can be driven, and the outdoor fan 5 and the indoor fan 7 can be rotated. A frequency corresponding to the load can be input to the twin rotary compressor (2).

In the heating operation, the twin rotary compressor (2) sucks refrigerant and discharges it after being compressed as in the cooling operation. The refrigerant discharged from the twin rotary compressors 2 flows into the indoor heat exchanger 6 and is condensed in the indoor heat exchanger 6 and then expanded in the expansion mechanism 8 and then sucked into the twin rotary compressors 2 have.

When the heat pump is in the heating operation, the injection valve 14 can be opened. When the injection valve 14 is opened, a part of the refrigerant flowing in the indoor heat exchanger 6 flows into the injection line 12, To the outdoor heat exchanger (4).

The refrigerant introduced into the injection line 12 can be guided to the twin rotary compressor 2 through the injection line 12 in the state of the liquid phase refrigerant and can be guided to the intermediate plate connecting passage 90, And then flows into the first compression chamber 22 and the second compression chamber 24 while being dispersed in the first compression chamber injection flow path 104 and the second compression chamber injection flow path 106, do.

The refrigerant introduced into the first compression chamber 22 from the first compression chamber injection path 104 can lower the temperature of the refrigerant discharged from the first compression chamber 22 as in the cooling operation, The refrigerant introduced into the second compression chamber 24 from the actual injection path 106 can lower the temperature of the refrigerant discharged from the second compression chamber 24 as in the cooling operation.

The temperature of the refrigerant discharged from the first compression chamber 22 is lowered and the temperature of the refrigerant discharged from the second compression chamber 22 is lowered during the heating operation so that the stability of the twin rotary compressor 2 is secured And the heat pump can improve the heating performance by increasing the frequency inputted to the twin rotary compressor 2 before the injection valve 14 is opened. When the outdoor temperature is lower than the set temperature, the heat pump opens the injection valve 14 to inject the refrigerant through the intermediate plate 26, and increases the frequency of the refrigerant input to the rotary compressor 2 to increase the cooling performance .

2: twin rotary compressor 4: outdoor heat exchanger
6: Indoor heat exchanger 8: Expansion mechanism
12: Injection flow path 14: Injection valve
22: first compression chamber 24: second compression chamber
26: Middle plate 90: Middle plate connecting channel
100: intermediate plate injection channel 102: common channel
104: first compression chamber injection channel 106: second compression chamber injection channel

Claims (13)

A first compression assembly having a casing, a motor disposed inside the casing, and a first compression chamber disposed inside the casing and compressing the refrigerant when the motor is driven; A twin rotary compressor comprising a second compression assembly having a second compression chamber for compressing a refrigerant,
An intermediate plate disposed between the first compression chamber and the second compression chamber;
An intermediate plate connecting flow path for guiding the refrigerant guided to the injection flow path to the intermediate plate;
And an intermediate plate injection channel which is injected into the first compression chamber and the second compression chamber from the intermediate plate after the refrigerant guided by the intermediate plate connection channel passes through the intermediate plate,
Wherein each of the first compression assembly and the second compression assembly includes a cylinder, an eccentric portion provided on a rotary shaft of the motor, a roller provided on the eccentric portion and rotating in the cylinder, And a vane which is installed to be in constant contact with the roller,
Wherein each of the eccentric portions is provided so as to have a phase difference of 180 degrees so that the intermediate plate injection path alternately injects the refrigerant into the first compression chamber and the second compression chamber, In a position not blocked by the cap member,
Wherein the angle of the roller is an angle at which the roller is rotated about the vane and the injection set angle is set at an angle at which the angle of the roller is greater than 30 DEG and less than 180 DEG. The method according to claim 1,
Wherein the intermediate plate injection flow path includes a common flow passage to which the intermediate plate connecting flow passage is connected, a first compression chamber injection flow passage for communicating the common flow passage and the first compression chamber, and a second compression chamber injection flow passage for communicating the common flow passage with the second compression chamber A twin rotary compressor having a twin rotary compressor including a compression chamber injection channel. 3. The method of claim 2,
Wherein the common flow path has a twin rotary compressor formed between an upper surface and a lower surface of the intermediate plate. 3. The method of claim 2,
Wherein the common flow path has a twin rotary compressor in which one end is formed on the outer edge of the intermediate plate and the other end is located in the middle of the intermediate plate. 3. The method of claim 2,
One end of the first compression chamber injection path communicates with the common flow path inside the intermediate plate and the other end opens on one surface of the intermediate plate,
Wherein the second compression chamber injection flow path has one end communicated with the common flow path inside the intermediate plate and the other end opened to the other surface of the intermediate plate. A first compression assembly having a casing, a motor disposed inside the casing, and a first compression chamber disposed inside the casing and compressing the refrigerant when the motor is driven; A twin rotary compressor including a second compression assembly having a second compression chamber for compressing the refrigerant;
An outdoor heat exchanger in which the refrigerant is condensed or evaporated;
An indoor heat exchanger in which the refrigerant is evaporated or condensed,
An expansion mechanism for expanding the refrigerant between the outdoor heat exchanger and the indoor heat exchanger;
And an injection flow path for injecting the refrigerant into the twin rotary compressor between the outdoor heat exchanger and the indoor heat exchanger,
In the twin rotary compressor,
An intermediate plate disposed between the first compression chamber and the second compression chamber;
An intermediate plate connecting flow path for guiding the refrigerant guided by the injection flow path to the intermediate plate;
And an intermediate plate injection channel which is injected into the first compression chamber and the second compression chamber from the intermediate plate after the refrigerant guided by the intermediate plate connection channel passes through the intermediate plate,
Wherein each of the first compression assembly and the second compression assembly includes a cylinder, an eccentric portion provided on a rotary shaft of the motor, a roller provided on the eccentric portion and rotating in the cylinder, And a vane which is installed to be in constant contact with the roller,
Wherein each of the eccentric portions is provided so as to have a phase difference of 180 degrees so that the intermediate plate injection path alternately injects the refrigerant into the first compression chamber and the second compression chamber, In a position not blocked by the cap member,
Wherein the angle of the roller is an angle that the roller is rotated about the vane and the injection set angle is set to an angle that the angle of the roller is more than 30 DEG and less than 180 DEG. The method according to claim 6,
Wherein the intermediate plate injection flow path includes a common flow passage to which the intermediate plate connecting flow passage is connected, a first compression chamber injection flow passage for communicating the common flow passage and the first compression chamber, and a second compression chamber injection flow passage for communicating the common flow passage with the second compression chamber And a twin rotary compressor including a compression chamber injection passage. 8. The method of claim 7,
And the common flow path has a twin rotary compressor formed between an upper surface and a lower surface of the intermediate plate. 8. The method of claim 7,
At least one of the first compression-unit-injection-path and the second-compression-unit-injection-path has a twin rotary compressor formed on the intermediate plate so as to be perpendicular to the common flow-path. 8. The method of claim 7,
Wherein the common flow path has a twin rotary compressor in which one end is formed on the outer edge of the intermediate plate and the other end is located in the middle of the intermediate plate. 8. The method of claim 7,
One end of the first compression chamber injection path communicates with the common flow path inside the intermediate plate and the other end opens on one surface of the intermediate plate,
Wherein the second compression chamber injection flow path has a twin rotary compressor in which one end communicates with the common flow path inside the intermediate plate and the other end opens to the other surface of the intermediate plate. 8. The method of claim 7,
Wherein the first compression chamber injection flow path and the second compression chamber injection flow path have a twin rotary compressor opened in the vertical direction at the same position of the intermediate plate. delete

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