KR20130093365A - Twin rotary compressor and heat pump having the same - Google Patents

Abstract

PURPOSE: A twin rotary compressor and a heat pump with the same are provided to inject a refrigerant to first and second compressive chambers with a simple structure which utilize a middle plate without installing injection pipes for injecting the refrigerant to the first and second compressive chambers respectively. CONSTITUTION: A twin rotary compressor includes a middle plate (26), a middle plate connection path (90), and a middle plate injection path (100). The middle plate is arranged between a first compressive chamber (22) and a second compressive chamber (24). The middle plate injection path guides a refrigerant guided to an injection path (12) to the middle plate. The refrigerant guided to the middle plate connection path is injected to each of the first and second compressive chambers from the middle plate after the refrigerant passes through the middle plate.

Description

Twin rotary compressor and heat pump having the same

The present invention relates to a twin rotary compressor and a heat pump having the same, and more particularly, to a twin rotary compressor and a heat pump having the intermediate plate partitioning a plurality of compression chambers.

In general, a heat pump is a device for cooling or heating a room including a compressor, an outdoor heat exchanger, an expansion device, and an indoor heat exchanger.

When the heat pump is operated in a cool condition when the outdoor temperature is too high or when the heat is operated when the outdoor temperature is too low, if the compressor is driven in response to a load, the heat pump may have a high discharge temperature and thus may not be reliable. have.

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

KR 10-2010-0112486 A (2010.10.19)

In the rotary two stage compressor according to the prior art, since the low pressure side compression assembly and the high pressure side compression assembly are connected to the connection pipe and the injection pipe is connected to the connection pipe, in the case of a twin rotary compressor that does not compress the refrigerant in multiple stages, the discharge temperature of the compressor is increased. There is a problem that is difficult to lower.

A twin rotary compressor according to the present invention for solving the above problems is a twin rotary compressor that sucks and compresses a refrigerant in a first compression chamber and a second compression chamber, and discharges it, between the first compression chamber and the second compression chamber. An intermediate plate disposed in the; An intermediate plate connecting passage for guiding the refrigerant guided into the injection passage to the intermediate plate; And a middle plate injection flow path which is injected into the first compression chamber and the second compression chamber from the intermediate plate after the refrigerant guided to the intermediate plate connection flow path passes through the intermediate plate.

A heat pump having a twin rotary compressor according to the present invention includes an intermediate plate disposed between a first compression chamber and a second compression chamber, and a twin rotary compressor for sucking and compressing a refrigerant in the first compression chamber and the second compression chamber, and then discharging 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 a refrigerant between the outdoor heat exchanger and the indoor heat exchanger; An injection flow path for injecting refrigerant between the outdoor heat exchanger and the indoor heat exchanger into the twin rotor compressor, wherein the twin rotary compressor comprises: an intermediate plate connection flow path for guiding the refrigerant guided to the injection flow path to an intermediate plate; And a middle plate injection flow path which is injected into the first compression chamber and the second compression chamber from the intermediate plate after the refrigerant guided to the intermediate plate connection flow path passes through the intermediate plate.

 The intermediate plate injection flow path may include a common flow path to which the intermediate plate connection flow path is connected, a first compression chamber injection flow path communicating the common flow path and the first compression chamber, and a second communication path communicating the common flow path and the second compression chamber. It may include a compression chamber injection flow path.

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

At least one of the first compression chamber injection passage and the second compression chamber injection passage may be formed orthogonal to the common passage in the intermediate plate.

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

One end of the first compression chamber injection passage may communicate with the common passage in the intermediate plate, and the other end may be opened to one surface of the intermediate plate. One end of the second compression chamber injection flow passage may communicate with the common flow passage inside the intermediate plate, and the other end may be opened to the other surface of the intermediate plate.

The first compression chamber injection passage and the second compression chamber injection passage may be opened in the vertical position at the same position of the intermediate plate.

The first compression chamber injection passage and the second compression chamber injection passage may be formed at positions not blocked by the roller when the angle of the roller is an injection setting angle.

The present invention has the advantage of allowing the refrigerant to be injected into both the first and second compression chambers in a simple structure using an intermediate plate without installing each injection pipe for injecting the refrigerant into the first and second compression chambers.

In addition, 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 is low temperature, thereby increasing the refrigerant flow rate and increasing the heating performance.

In addition, liquid cooling can be injected into the first and second compression chambers through the intermediate plate during outdoor cooling operation, thereby reducing the compressor discharge temperature, and increasing the frequency of the compressor as the compressor discharge temperature decreases, thereby improving cooling performance. 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 showing a twin rotary compressor of one embodiment of a heat pump according to the present invention;
3 is an enlarged cross-sectional view of the intermediate plate of FIG.
4 is a plan view showing an example of a compression chamber of one embodiment of a heat pump according to the present invention;
5 is a plan view showing another example of the compression chamber of an embodiment of a 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 diagram showing 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 through which the refrigerant is condensed or evaporated; An indoor heat exchanger 6 through which the refrigerant is evaporated or condensed, and an expansion mechanism 8 for expanding the refrigerant between the outdoor heat exchanger 4 and the indoor heat exchanger 6; It may include an injection flow path 12 for injecting refrigerant to the twin rotor compressor 2 between the outdoor heat exchanger 4 and the indoor heat exchanger 6.

The twin rotary compressor 2 may compress the refrigerant in two compression chambers by one motor, and may suck and compress the refrigerant in each of the first compression chamber and the second compression chamber, and then discharge the refrigerant.

The twin rotary compressor 2 may be made 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 that accumulates liquid refrigerant among refrigerants sucked into the twin rotary compressor 2. The twin rotary compressor 2 may be connected to the accumulator 3 and the suction pipes 2a and 2b. The suction pipes 2a and 2b may be provided in singular or plural.

The outdoor heat exchanger 4 may allow the refrigerant to exchange heat with the outdoor air flowing by the outdoor fan 5 to condense or evaporate the refrigerant. The outdoor fan 5 may be located outdoors with the outdoor heat exchanger 4 to flow outdoor air to the outdoor heat exchanger 4.

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

The indoor heat exchanger (6) consists of a fin tube tube heat exchanger including a refrigerant tube through which a refrigerant passes and a fin tube connected to the refrigerant tube in the case of a heat pump type air conditioner. Can be contacted and heat exchanged with the refrigerant.

The indoor heat exchanger 6 may condense or evaporate the refrigerant by heat-exchanging the indoor air flowing by the indoor fan 7 and the refrigerant passing therein.

In the heat pump type hot water supply device, the indoor heat exchanger 6 may have a first flow path through which a refrigerant passes and a second flow path through which the liquid heat medium passes. The heat exchange member may be a double tube heat exchanger, a plate heat exchanger, or a shell-tube heat exchanger that exchanges heat between the heat transfer members, and the liquid heat medium may exchange heat with the refrigerant through the heat transfer member while passing through the second flow path.

The indoor heat exchanger 6 may be connected to a reservoir (or hot water tank, not shown) in which the liquid heat medium is contained, and a liquid heat medium circulation flow path, and the liquid heat medium flowing in the water tank (or hot water bath) may be transferred to the interior of the indoor heat exchanger 6. The refrigerant may be evaporated or condensed while passing through the second flow path.

The expansion device 8 may comprise an outdoor expansion device installed closer to the outdoor heat exchanger 4 of the outdoor heat exchanger 4 and the indoor heat exchanger 6, which may be a capillary tube or an electronic expansion. It may consist of a valve. The expansion device 8 may further comprise an indoor expansion device installed closer to the outdoor heat exchanger 4 of the outdoor heat exchanger 4 and the indoor heat exchanger 6, the indoor expansion device being a capillary tube or electronic. It may be made of an expansion valve.

The injection passage 12 may have one end connected between the outdoor heat exchanger 4 and the indoor heat exchanger 6, and the other end may be connected to the twin rotary compressor 2 itself. The injection passage 12 may be provided with an injection valve 14 for adjusting the refrigerant passing through the injection passage 12. Injection valve 18 may be made of an expansion valve for expanding the refrigerant. The injection passage 12 is installed between the outdoor heat exchanger 4 and the expansion mechanism 8 so that the cooling medium passes through the outdoor heat exchanger 4 and injects the supercooled refrigerant into the twin rotary compressor 2 during the cooling operation. In addition, during the heating operation, the refrigerant passing through the indoor heat exchanger 6 and supercooled may be injected into the twin rotary compressor 2. The injection passage 12 can be connected between the outdoor and indoor expansion mechanisms when the expansion mechanism 8 can include both outdoor and indoor expansion mechanisms.

 The heat pump may further include a flow path switching unit 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 converts the refrigerant compressed and discharged by the twin rotary compressor 2 into the outdoor heat exchanger ( 4) can be made to flow. The flow path switching unit 16 causes the refrigerant passing through the outdoor heat exchanger 4 to flow toward the twin rotary compressor 2 during the heating operation, and the refrigerant compressed and discharged by the twin rotary compressor 2 is transferred to the outdoor heat exchanger ( 4) can be made to flow. As for the flow path switching part 16, one four-way valve can switch the flow direction of a refrigerant | coolant, and a some open / close valve can also switch the flow direction of a refrigerant | coolant.

The heat pump may include a compressor (2), an outdoor heat exchanger (4), an outdoor fan (5), an expansion mechanism (8), an injection passage (12), and a flow path switching unit (16) in the outdoor unit (O), An indoor heat exchanger 6 and an indoor fan 7 may be installed in the indoor unit I. In the heat pump, when the expansion mechanism 8 includes an outdoor expansion mechanism and an indoor expansion mechanism, the outdoor expansion mechanism may be installed in the outdoor unit O, and the indoor expansion mechanism may be installed in the indoor unit I.

Figure 2 is a cross-sectional view showing a twin rotary compressor of one embodiment of the heat pump according to the present invention, Figure 3 is an enlarged cross-sectional view of the intermediate plate of Figure 2, Figure 4 is a compression chamber of one embodiment of the heat pump according to the present invention An example is the top view shown. 5 is a plan view showing another example of the compression chamber of an embodiment of a heat pump according to the present invention.

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

The twin rotary compressor 2 includes a casing 32, a motor 34 disposed inside the casing 32, and a first compression chamber disposed inside the casing 32 and compressing a refrigerant when the motor 34 is driven. A second compression assembly 38 having a first compression assembly 36 having a 22 and a second compression chamber 24 disposed inside the casing 32 to compress the refrigerant when the motor 34 is driven. It may include.

The casing 32 may include a hollow cylindrical shell, a base coupled to a lower portion of the shell, and a top cover coupled to an 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 guiding the refrigerant to the first compression assembly 36 and a second suction pipe 42 for guiding the refrigerant to the second compression assembly 38. Can be. 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 rotation shaft 56. The rotating shaft 56 passes through the center of the rotor 54 and is fixed to the rotor 54. When a 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 rotating shaft 56 fixed to the rotor 54 is connected to the rotor 54. Rotate together. The axis of rotation 56 extends from the rotor 54 toward the bottom of the casing 32 to penetrate the central portions 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, 72, eccentric portions 64, 74, and rollers 66, 76. The first compression assembly 36 and the second compression assembly 38 are compressed in the refrigerant inlets 61 and 71 where the refrigerant is sucked into the compression chambers 22 and 24 and the compression chambers 22 and 24. Refrigerant discharge ports 63 and 73 through which the refrigerant is discharged may be formed. The first compression assembly 36 and the second compression assembly 38 may further include vanes 67 and 77 installed in the cylinders 62 and 72 to contact the rollers 66 and 76.

 The first compression assembly 36 includes a first cylinder 62 having a first compression chamber 22 formed therein, a first eccentric portion 64 provided on the rotation shaft 56, and a first eccentric portion 64. It may include a first roller 66 is installed in the to rotate along the inner diameter of the first cylinder (62). In the first cylinder 62, a first vane 67, which is in constant contact with the first roller 66, may be supported by a spring. The first compression assembly 36 may further include a first bearing 68 together with the first cylinder 62 to form the first compression chamber 22 and to rotatably support the rotation shaft 56.

The second compression assembly 38 includes a second cylinder 72 having a second compression chamber 24 formed therein, a second eccentric portion 74 provided on the rotation shaft 56, and a second eccentric portion 74. It may include a second roller 76 is installed in the to rotate along the inner diameter of the second cylinder (72). In the second cylinder 72, a second vane 77, which is in constant contact with the second roller 76, may be supported by a spring. The second compression assembly 38 may further include a second bearing 78 that forms the second compression chamber 24 together with the second cylinder 72 and rotatably supports the rotation shaft 56. The second eccentric portion 74 may be installed to have a 180 ° retardation with the first eccentric portion 64.

  The intermediate plate 26 may be disposed between the first cylinder 62 and the second cylinder 72. One side of both surfaces of the intermediate plate 26 may form the first compression chamber 22 together with the first cylinder 62. The intermediate plate 26 may form the second compression chamber 24 along with the second cylinder 72 on the other side of both surfaces. The intermediate plate 26 may have a through hole 27 through which the rotation shaft 56 penetrates at the center thereof.

The twin rotary compressor 2 includes: an intermediate plate connecting passage 90 for guiding the refrigerant guided into the injection passage 12 to the intermediate plate 26; Intermediate plate injection passages in which the refrigerant guided to the intermediate plate connection passage 90 passes through the intermediate plate 26 and are then injected from the intermediate plate 26 into the first compression chamber 22 and the second compression chamber 24, respectively. 100 may be included.

One end of the intermediate plate connection passage 90 may be connected to the injection passage 12 shown in FIG. 1, and the other end thereof may be connected to the intermediate plate injection passage 100 formed on the intermediate plate 26. The intermediate plate connection passage 90 may be formed of a refrigerant pipe through which the refrigerant passes. Intermediate plate connection flow path 90 may be composed of a refrigerant pipe, one end is located outside the casing 32, the other end is located inside the casing 32, and disposed through the casing 32, the injection flow path 12 ) May include a refrigerant pipe connected to the intermediate plate connection flow path 90 outside the casing 32. Intermediate plate connecting flow path 90 is composed of a refrigerant pipe located in the casing 32 at one end and the other end, and the injection flow path 12 passes through the casing 32 to the middle plate connection flow path 90 inside the casing 32. It is possible to include a refrigerant pipe connected to

The intermediate plate injection flow path 100 includes a common flow path 102 to which the intermediate plate connection flow path 90 is connected, and a first compression chamber injection flow path 104 for communicating the common flow path 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.

 The intermediate plate 26 may be formed of one plate body, and the intermediate plate injection flow path 100 may be formed by drilling in one plate body.

The intermediate plate 26 may have a common flow path 102 formed in a groove shape on one of the upper and lower surfaces thereof, and the first compression chamber injection passage 104 and the second compression chamber injection passage 106 may have a groove shape. It is possible to be formed in communication with the common flow path (102).

The intermediate plate 26 is coupled to the first plate body and the first plate body in which the upper common flow passage 102 is formed in a groove shape on the lower surface thereof, and the first compression chamber injection passage 104 communicates with the upper common flow passage in the groove shape. The lower common flow passage is formed in a groove shape on the upper surface thereof, and the second compression chamber injection passage 106 may include a second plate body communicating with the lower common flow passage of the groove shape, and the upper common flow passage and the lower common flow passage are the common flow passage ( Of course, it is also possible to form 102.

 The common flow path 102 may be formed between the upper and lower surfaces of the intermediate plate 26. The common flow path 102 has one end 102a formed at the outer edge of the intermediate plate 26 and is formed between the upper and lower surfaces of the intermediate plate 26, and the other end 102b is positioned inside the intermediate plate 26. can do. The common flow path 102 may be formed horizontally between the upper and lower surfaces of the intermediate plate 26.

 At least one of the first compression chamber injection passage 104 and the second compression chamber injection passage 106 may be formed on the intermediate plate 26 to be orthogonal to the common passage 102. At least one of the first compression chamber injection passage 104 and the second compression chamber injection passage 106 may be formed perpendicular to the intermediate plate 26. One end of the first compression chamber injection passage 104 may communicate with the common passage 102 inside the intermediate plate 26, and the other end may be opened to one surface of the intermediate plate 26. One end of the second compression chamber injection passage 106 may communicate with the common 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 passage 104 and the second compression chamber injection passage 106 may be opened in the up and down direction at the same position of the intermediate plate 26 without having a phase difference in the intermediate plate 26. The refrigerant guided through the 102 is alternately injected into the first compression chamber 22 and the second compression chamber 24 because the first eccentric portion 64 and the second eccentric portion 74 have a 180 ° phase difference. Can be.

The first compression chamber injection passage 104 and the second compression chamber injection passage 106 are not blocked by the rollers 66 and 76 when the angle θ of the rollers 66 and 76 is an injection setting angle. Can be formed on. The first compression chamber injection passage 104 and the second compression chamber injection passage 106 may be formed to be blocked by the rollers 66 and 76 when the angle θ is the injection cutoff setting angle. Here, the angle θ of the rollers 66 and 76 is an angle at which the rollers 66 and 76 are rotated with respect to the vanes 67 and 77. The injection setting angle may be set to an angle at which the angle θ of the rollers 66 and 76 is greater than 30 ° and less than 180 °. The first compression chamber injection flow path 104 and the second compression chamber injection flow path 106, when the angle θ of the roller 66, 76 is 30 ° or less, as shown in Figure 4 (a), Blocked by rollers 66 and 76 and not blocked by rollers 66 and 76 when less than 30 ° and less than 125 °, as shown in FIG. 4B, and as shown in FIG. 4C. As shown, it may be formed at a position blocked by the rollers 66 and 76 when it is 125 degrees or more. That is, the injection setting angle may be set to an angle at which the angle θ of the rollers 66 and 76 is greater than 30 ° and less than 125 °. The first compression chamber injection flow path 104 and the second compression chamber injection flow path 106 have a roller when the angle θ of the rollers 66 and 76 is 85 ° or less, as shown in Fig. 5A. Blocked by (66) (76) and not blocked by rollers (66) 76 when less than 175 ° above 85 °, as shown in (b) of FIG. 5, as shown in (c) of FIG. As such, it may be formed at a position blocked by the rollers 66 and 76 when it is at least 175 °. That is, the injection setting angle may be set to an angle at which the angle θ of the rollers 66 and 76 is greater than 85 ° and less than 175 °.

Hereinafter, the operation of the present invention configured as described above is as follows.

First, during the cooling operation, the twin rotary compressor 2 may be driven, and the outdoor fan 5 and the indoor fan 7 may be rotated. The frequency corresponding to the load may be input to the twin rotary compressor 2.

In the twin rotary compressor 2, refrigerant is sucked 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. Afterwards, the first compression chamber 22 may be discharged to the outside, and the refrigerant sucked into the second compression chamber 24 may be discharged to the outside of the second compression chamber 24 after being compressed by the second roller 76. 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 compressor 2 may flow to the outdoor heat exchanger 4 to condense in the outdoor heat exchanger 4, then expand in the expansion mechanism 8, and be sucked into the twin rotary compressor 2. have.

In the cooling operation, the heat pump may have the injection valve 14 open, and when the injection valve 14 is opened, some of the supercooled refrigerant in the outdoor heat exchanger 4 flows into the injection line 12, and the rest It can flow to the expansion mechanism (8).

The refrigerant introduced into the injection line 12 may be guided to the twin rotary compressor 2 through the injection line 12 in the state of the liquid refrigerant, and pass through the intermediate plate connecting passage 90 to the intermediate plate 26. It may be guided to, it may be introduced into the intermediate plate injection flow path (100). The refrigerant introduced into the intermediate plate injection flow path 100 passes through the common flow path 102, and then is distributed into the first compression chamber injection flow path 104 and the second compression chamber injection flow path 106, and thus the first compression chamber 22. And flow into the second compression chamber 24, respectively.

The refrigerant introduced into the first compression chamber 22 from the first compression chamber injection passage 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 passage 106 is mixed with the refrigerant compressed by the second roller 76 in the second compression chamber 24 to adjust the temperature of the refrigerant. The temperature of the refrigerant discharged from the second compression chamber 24 is lowered.

During the cooling operation, as 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, the twin rotary compressor 2 may be secured. The heat pump can be improved in cooling performance by increasing the frequency input to the twin rotary compressor 2 than before the injection valve 14 is opened. The heat pump increases cooling frequency by increasing the frequency input to the rotary compressor 2 while injecting the refrigerant through the middle plate 26 by opening the injection valve 14 when the outdoor temperature is higher than the set temperature. It is preferable to make it.

Meanwhile, during the heating operation, the twin rotary compressor 2 may be driven, and the outdoor fan 5 and the indoor fan 7 may be rotated. The frequency corresponding to the load may be input to the twin rotary compressor 2.

In the heating operation, the twin rotary compressor 2 is discharged after the refrigerant is sucked in and compressed as in the cooling operation. The refrigerant discharged from the twin rotary compressor 2 may flow to the indoor heat exchanger 6 to condense in the indoor heat exchanger 6, and then be expanded by the expansion mechanism 8 and then sucked into the twin rotary compressor 2. have.

In the heat pump, the injection valve 14 may be opened during the heating operation, and some of the refrigerant flowing in the indoor heat exchanger 6 may be introduced into the injection line 12 when the injection valve 14 is opened, It can be flowed to the outdoor heat exchanger (4).

The refrigerant introduced into the injection line 12 may be guided to the twin rotary compressor 2 through the injection line 12 in the state of the liquid refrigerant, and shared with the intermediate plate connection flow path 90 as in the cooling operation. After passing through the flow path 102 sequentially, it is distributed into the first compression chamber injection passage 104 and the second compression chamber injection passage 106 and flows into the first compression chamber 22 and the second compression chamber 24, respectively. do.

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

During the heating operation, as 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, the twin rotary compressor 2 may be secured. The heat pump can be improved in heating performance by raising the frequency input to the twin rotary compressor 2 than before the injection valve 14 is opened. The heat pump increases cooling frequency by increasing the frequency input to the rotary compressor 2 while injecting the refrigerant through the intermediate plate 26 by opening the injection valve 14 when the outdoor temperature is lower than the set temperature. It is preferable to make it.

2: twin rotary compressor 4: outdoor heat exchanger
6: indoor heat exchanger 8: inflator
12: injection flow path 14: injection valve
22: first compression chamber 24: second compression chamber
26: intermediate plate 90: intermediate plate connection flow path
100: intermediate plate injection euro 102: common euro
104: first compression chamber injection flow path 106: second compression chamber injection flow path

Claims (13)

In a twin rotary compressor that sucks and compresses a refrigerant in a first compression chamber and a second compression chamber, and then discharges the refrigerant.
An intermediate plate disposed between the first compression chamber and the second compression chamber;
An intermediate plate connecting passage for guiding the refrigerant guided into the injection passage to the intermediate plate;
And a middle plate injection passage in which the refrigerant guided to the intermediate plate connection passage passes through the intermediate plate and is respectively injected from the intermediate plate into the first compression chamber and the second compression chamber. The method of claim 1,
The intermediate plate injection flow path may include a common flow path to which the intermediate plate connection flow path is connected, a first compression chamber injection flow path communicating the common flow path and the first compression chamber, and a second communication path communicating the common flow path and the second compression chamber. Twin rotary compressor with twin rotary compressor including compression chamber injection flow path. 3. The method of claim 2,
And said common flow path has a twin rotary compressor formed between an upper surface and a lower surface of said intermediate plate. 3. The method of claim 2,
The common flow path is a twin rotary compressor having a twin rotary compressor, one end of which is formed at an outer edge of the intermediate plate, is formed between an upper surface and a lower surface of the intermediate plate, and the other end is located inside the intermediate plate. 3. The method of claim 2,
One end of the first compression chamber injection passage is in communication with the common passage in the intermediate plate and the other end is opened to one surface of the intermediate plate,
And a second compression chamber injection passage having one end communicating with the common passage in the middle plate and the other end opening to the other surface of the middle plate. A twin rotary compressor having an intermediate plate disposed between the first compression chamber and the second compression chamber, for sucking and compressing the refrigerant in the first compression chamber and the second compression chamber, and then discharging the refrigerant;
An outdoor heat exchanger in which the refrigerant is condensed or evaporated;
An indoor heat exchanger in which refrigerant is evaporated or condensed,
An expansion mechanism for expanding a refrigerant between the outdoor heat exchanger and the indoor heat exchanger;
An injection flow path for injecting refrigerant into the twin rotor compressor between the outdoor heat exchanger and the indoor heat exchanger;
The twin rotary compressor may include: an intermediate plate connecting passage configured to guide the refrigerant guided into the injection passage to the intermediate plate;
And a twin platen compressor including a middle plate injection passage which is injected into the first compression chamber and the second compression chamber from the intermediate plate after the refrigerant guided to the intermediate plate connection passage passes through the intermediate plate. The method according to claim 6,
The intermediate plate injection flow path may include a common flow path to which the intermediate plate connection flow path is connected, a first compression chamber injection flow path communicating the common flow path and the first compression chamber, and a second communication path communicating the common flow path and the second compression chamber. A heat pump having a twin rotary compressor comprising a compression chamber injection flow path. The method of claim 7, wherein
And the common flow passage has a twin rotary compressor formed between an upper surface and a lower surface of the intermediate plate. The method of claim 7, wherein
At least one of the first compression chamber injection passage and the second compression chamber injection passage has a twin rotary compressor formed on the intermediate plate to be orthogonal to the common passage. The method of claim 7, wherein
The common flow path has a twin rotary compressor, one end of which is formed at an outer edge of the intermediate plate, is formed between an upper surface and a lower surface of the intermediate plate, and the other end is located inside the intermediate plate. The method of claim 7, wherein
One end of the first compression chamber injection passage is in communication with the common passage in the intermediate plate and the other end is opened to one surface of the intermediate plate,
And the second compression chamber injection flow passage has a twin rotary compressor having one end communicating with the common flow passage inside the intermediate plate and the other end opening to the other surface of the intermediate plate. The method of claim 7, wherein
And the first compression chamber injection passage and the second compression chamber injection passage have twin rotary compressors opened up and down at the same position of the intermediate plate. The method of claim 7, wherein
And the first compression chamber injection passage and the second compression chamber injection passage are twin rotary compressors formed at positions not blocked by the rollers when the angle of the roller is an injection setting angle.

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