JP2010139205A - Air conditioning device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an air conditioning device capable of keeping a heating capacity even when an outside air temperature is low, and capable of simultaneously performing heating and cooling operations. <P>SOLUTION: This air conditioning device includes: a compressor 2, a plurality of indoor heat exchangers 71A, 71B and a plurality of outdoor heat exchangers 10a, 10b; a plurality of outdoor unit-side flow channel switching sections 30a, 30b connected with the outdoor heat exchangers 10a, 10b, a discharge port of the compressor 2 and a suction port of the compressor 2; a plurality of indoor unit-side flow channel switching sections 80A, 80B, connected with connection ports 76A, 76B of one of the indoor heat exchangers 71A, 71B, the discharge port of the compressor 2 and the suction port of the compressor 2; pipes 25, 92 connecting the other connection ports 12a, 12b of the outdoor heat exchangers 10a, 10b and the other connection ports 77A, 77B of the indoor heat exchangers 71A, 71B; a LEV (linear electronic expansion valve) 6 disposed in the pipe 25; and an injection circuit 40 connected with a branch section 26 of the pipes 25, 92 at one end section, and connected with a compressing stroke of the compressor 2 at the other end section. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an air conditioner, and more particularly to a multi-room air conditioner that includes a plurality of indoor heat exchangers and can be operated simultaneously with cooling and heating.

In an air conditioner equipped with a plurality of indoor heat exchangers (which can be used for air conditioning in a plurality of air-conditioned spaces), the heat exchange capacity of the outdoor heat exchanger (of the heat source machine) In order to efficiently convert (operating capacity), one having a plurality of outdoor heat exchangers has been proposed. As an air conditioner equipped with such a plurality of outdoor heat exchangers, for example, “(A) is a heat source unit, (B), (C), (D) are indoor units connected in parallel as described later. As will be described later, (E) is a first branching unit, a second flow rate control device, a second branching unit, a gas-liquid separation device, a heat exchange unit, and a third flow rate control. Device, relay machine incorporating the fourth flow control device.
(1) is a compressor, (2) is a four-way valve that switches the refrigerant flow direction of the heat source machine, (3) is a heat source machine side heat exchange section, (4) is an accumulator, and is connected to the above equipment, (20) Is a heat source machine side blower with variable air flow rate for blowing air to the heat source machine side heat exchange section (3), and the heat source machine (A) is constituted by these. The heat source unit side heat exchange section (3) has the same heat transfer area as the first heat source unit side heat exchanger (41) and the first heat source unit side heat exchanger (41) connected in parallel to each other. Provided at one end of the heat source unit side heat exchanger (42), the heat source unit side bypass path (43), and the first heat source unit side heat exchanger (41) on the side connected to the four-way valve (2). The first electromagnetic on-off valve (44), the second electromagnetic on-off valve (45) provided at the other end of the first heat source unit side heat exchanger (41), the second heat source unit side heat A third electromagnetic on-off valve (46) provided at one end of the exchanger (42) connected to the four-way valve (2), and the other end of the second heat source unit side heat exchanger (42) A fourth electromagnetic on-off valve (47) provided and a fifth electromagnetic on-off valve (48) provided in the middle of the heat source unit side bypass path (43) are configured. (For example, refer to Patent Document 1).

Japanese Examined Patent Publication No. 7-92296 (pages 4, 5 and 1)

  In a conventional air conditioner (see, for example, Patent Document 1), for example, when heating an air-conditioned space such as a room, the refrigerant evaporation pressure in the outdoor heat exchanger that functions as an evaporator decreases as the outside air temperature decreases. However, the density of refrigerant gas sucked by the compressor is reduced. For this reason, even if the compressor frequency reaches the upper limit of the use range, the refrigerant cannot be compressed to a sufficiently high pressure and high temperature state. Moreover, the refrigerant | coolant flow rate which can be pumped in the indoor heat exchanger which functions as a condenser decreases. Therefore, even if all the outdoor heat exchangers are operated, there is a problem that a desired heating capacity cannot be obtained.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to obtain an air conditioner capable of simultaneously operating cooling and heating, which can maintain a desired heating capacity even at a low outside air temperature. .

  An air conditioner according to the present invention includes a compressor, a plurality of indoor heat exchangers, a plurality of outdoor heat exchangers, one connection port of the outdoor heat exchanger, a discharge port of the compressor, and the compressor A refrigerant flow path through which refrigerant flows from the discharge port of the compressor to one connection port of the outdoor heat exchanger, or from one connection port of the outdoor heat exchanger to the suction port of the compressor A plurality of outdoor unit side channel switching units that switch the refrigerant channel to a refrigerant channel through which the refrigerant flows, one connection port of the indoor heat exchanger, a discharge port of the compressor, and a suction port of the compressor The refrigerant flows from the discharge port of the compressor through which the refrigerant flows to one connection port of the indoor heat exchanger, or from one connection port of the indoor heat exchanger to the suction port of the compressor A plurality of indoor unit side channel switching units that switch the refrigerant channel to the refrigerant channel; A connection pipe connecting the other connection port of the external heat exchanger and the other connection port of the indoor heat exchanger, a decompression device provided in the connection pipe, and one end portion of the decompression device and the indoor unit An injection circuit connected to the connection pipe between the heat exchanger, the other end connected to the compression process of the compressor, and an injection circuit for injecting a refrigerant flowing through the connection pipe into the compression process of the compressor; It is provided.

  In the present invention, since the refrigerant can be injected into the compression process of the compressor via the injection circuit, the compressor can compress the refrigerant into a high pressure and high temperature state even at a low outside air temperature. For this reason, a sufficient amount of refrigerant can be pumped into the indoor heat exchanger that functions as a condenser. Therefore, it is possible to obtain an air conditioner that can maintain a desired heating capacity even at a low outside air temperature and can be operated simultaneously with cooling and heating.

Embodiment 1 FIG.
FIG. 1 is a refrigerant circuit diagram illustrating an example of an air-conditioning apparatus according to Embodiment 1 of the present invention.
The air conditioner 100 includes an outdoor unit 1 and a plurality of indoor units 70. In this Embodiment 1, it is comprised by two indoor units (indoor unit 70A and indoor unit 70B).

  The outdoor unit 1 includes a compressor 2, a LEV6 (Linear Electronic Expansion Valve) that is a decompression device, an outdoor heat exchanger 10a, an outdoor heat exchanger 10b, an outdoor unit side channel switching unit 30a, and an outdoor unit side channel switching unit 30b. And the injection circuit 40 and the like. LEV indicates a linear expansion valve whose opening degree can be controlled.

In the first embodiment, the compressor 2 is configured by connecting a plurality of compressors 2 a and a compressor 2 b in series with a pipe 20. The compressor 2a is a low-compression ratio and efficient variable capacity compressor, and compresses and discharges the sucked low-pressure refrigerant to an intermediate pressure. The compressor 2b is a highly variable capacity compressor having a high compression ratio and efficient, and compresses and discharges the sucked medium-pressure refrigerant to a high pressure.
Note that the decompression device is not limited to LEV, and for example, EEV (Electronic Expansion Valve) or the like may be used.

A pipe 21a is connected to the discharge port of the compressor 2b. This pipe 21a is branched at the branching section 21b into an outdoor unit side branch pipe 21c and an indoor unit side branch pipe 21d. Moreover, the outdoor unit side branch pipe 21c branches into two, and each end is connected to the outdoor unit side flow path switching unit 30a and the outdoor unit side flow path switching unit 30b.
A pipe 22a is connected to the suction port of the compressor 2a. The pipe 22a is branched at the branching portion 22b into an outdoor unit side branch pipe 22c and an indoor unit side branch pipe 22d. Moreover, the outdoor unit side branch piping 22c branches into two, and each end is connected to the outdoor unit side flow path switching unit 30a and the outdoor unit side flow path switching unit 30b.

The outdoor unit side flow path switching unit 30a connected to the outdoor unit side branch pipe 21c and the outdoor unit side branch pipe 22c is connected to the connection port 11a of the outdoor heat exchanger 10a via the pipe 23a. Moreover, the fan 5a which ventilates external air to the outdoor heat exchanger 10a is provided in the vicinity of the outdoor heat exchanger 10a.
The outdoor unit side flow path switching unit 30b connected to the outdoor unit side branch pipe 21c and the outdoor unit side branch pipe 22c is connected to the connection port 11b of the outdoor heat exchanger 10b via the pipe 23b. A fan 5b that blows outside air to the outdoor heat exchanger 10b is provided in the vicinity of the outdoor heat exchanger 10b.

  That is, by switching the outdoor unit side flow switching unit 30a, the refrigerant flows from the discharge port of the compressor 2b to the outdoor heat exchanger 10a, and the refrigerant from the outdoor heat exchanger 10a to the suction port of the compressor 2a. It is possible to switch between the refrigerant flow path through which the gas flows. Further, by switching the outdoor unit side flow path switching unit 30b, the refrigerant flows from the discharge port of the compressor 2b to the outdoor heat exchanger 10b and the refrigerant from the outdoor heat exchanger 10b to the suction port of the compressor 2a. It is possible to switch between the refrigerant flow path through which the gas flows.

  More specifically, the outdoor unit side flow path switching unit 30a includes a first electromagnetic valve 31a and a second electromagnetic valve 32a. The first electromagnetic valve 31a is connected to the outdoor unit side branch pipe 21c. The second solenoid valve 32a is connected to the outdoor unit side branch pipe 22c. And the 1st solenoid valve 31a and the 2nd solenoid valve 32a are connected with the connection port 11a of the outdoor heat exchanger 10a via the piping 23a. By setting one of the first solenoid valve 31a or the second solenoid valve 32a to an open state and the other of the first solenoid valve 31a or the second solenoid valve 32a to a closed state, an outdoor heat exchanger is provided from the discharge port of the compressor 2b. The refrigerant flow path through which the refrigerant flows to 10a and the refrigerant flow path through which the refrigerant flows from the outdoor heat exchanger 10a to the suction port of the compressor 2a can be switched. In addition, you may comprise the 1st solenoid valve 31a and the 2nd solenoid valve 32a with one three-way valve.

Moreover, the outdoor unit side flow path switching unit 30b includes a first electromagnetic valve 31b and a second electromagnetic valve 32b. The first solenoid valve 31b is connected to the outdoor unit side branch pipe 21c. The second solenoid valve 32b is connected to the outdoor unit side branch pipe 22c. And the 1st solenoid valve 31b and the 2nd solenoid valve 32b are connected with the connection port 11b of the outdoor heat exchanger 10b via the piping 23b. By setting one of the first solenoid valve 31b or the second solenoid valve 32b to an open state and the other of the first solenoid valve 31b or the second solenoid valve 32b to a closed state, an outdoor heat exchanger is provided from the discharge port of the compressor 2b. The refrigerant flow path through which the refrigerant flows to 10b and the refrigerant flow path through which the refrigerant flows from the outdoor heat exchanger 10b to the suction port of the compressor 2a can be switched. In addition, you may comprise the 1st solenoid valve 31b and the 2nd solenoid valve 32b with one three-way valve.
Here, the first electromagnetic valve 31a and the first electromagnetic valve 31b correspond to a first outdoor unit side opening / closing device, and the second electromagnetic valve 32a and the second electromagnetic valve 32b correspond to a second outdoor unit side opening / closing device. .

  The connection port 12a of the outdoor heat exchanger 10a is connected to the pipe 24a. The connection port 12b of the outdoor heat exchanger 10b is connected to the pipe 24b. In addition, the pipe 24 a and the pipe 24 b merge at the branch portion 24 c and are connected to the pipe 25. This pipe 25 is provided with LEV 6 in the middle of the pipe, and is connected to the branch portion 26.

  An injection circuit 40 is connected between the branch portion 26 and the pipe 20 connecting the compressor 2a and the compressor 2b. The injection circuit 40 is provided with an internal heat exchanger 34 for exchanging heat between the refrigerant flowing through the pipe 25 and the refrigerant flowing through the injection circuit 40. Further, in this injection circuit 40, an LEV 41 is provided between the branch portion 26 and the internal heat exchanger 34, and an LEV 42 is provided between the internal heat exchanger 34 and the pipe 20. The LEV 42 controls the flow rate of the refrigerant flowing through the injection circuit 40, and corresponds to an injection circuit flow rate control device. A pipe 22a that is a suction side pipe of the compressor 2a is connected to the internal heat exchanger 34 and the LEV 42 of the injection circuit 40 via a pipe 27. The piping 27 is provided with an electromagnetic valve 7.

The compressor 2a is provided with a bypass circuit 45a that connects the pipe 22a that is the suction side pipe of the compressor 2a and the pipe 20 that is the discharge side pipe of the compressor 2a. The bypass circuit 45a is provided with an electromagnetic valve 46a for opening and closing the bypass circuit 45a.
The compressor 2b is provided with a bypass circuit 45b that connects the pipe 20 that is the suction side pipe of the compressor 2b and the pipe 21a that is the discharge side pipe of the compressor 2b. The bypass circuit 45b is provided with an electromagnetic valve 46b for opening and closing the bypass circuit 45b.
Here, the electromagnetic valve 46a and the electromagnetic valve 46b correspond to a bypass circuit switching device.

  The refrigerant circuit constituting the outdoor unit 1 is provided with, for example, a pressure detection device 51 such as a pressure sensor, a pressure detection device 52, and a pressure detection device 53 in order to detect the pressure of the refrigerant flowing through the refrigerant circuit. The pressure detection device 51 is provided in a pipe 21a that is a discharge side pipe of the compressor 2b. The pressure detection device 52 is provided in a pipe 22a that is a suction side pipe of the compressor 2a (more specifically, a pipe 22a between a connection portion of the pipe 27 and the compressor 2a). The pressure detection device 53 is provided between the LEV 6 of the pipe 25 and the internal heat exchanger 34.

  Moreover, in the refrigerant circuit which comprises the said outdoor unit 1, in order to detect the temperature of the refrigerant | coolant which flows through a refrigerant circuit, for example, temperature detectors 61, such as a temperature sensor, temperature detector 62a, temperature detector 62b, and temperature detector 63 is also provided. The temperature detection device 61 is provided in a pipe 21a that is a discharge side pipe of the compressor 2b. The temperature detection device 62a is provided in the pipe 24a connected to the outdoor heat exchanger 10a. The temperature detector 62b is provided in the pipe 24b connected to the outdoor heat exchanger 10b. The temperature detection device 63 is provided in the injection circuit 40 (more specifically, the injection circuit 40 between the connection portion of the pipe 27 and the internal heat exchanger 34).

  The indoor unit 70A includes an indoor heat exchanger 71A, an LEV 73A that controls the flow rate of the refrigerant flowing through the indoor heat exchanger 71A, and the like. The indoor unit 70B includes an indoor heat exchanger 71B, an LEV 73B that controls the flow rate of the refrigerant flowing through the indoor heat exchanger 71B, and the like.

In the vicinity of the indoor heat exchanger 71A, a fan 72A that blows air in an air-conditioned space such as a room to the indoor heat exchanger 71A is provided. The indoor heat exchanger 71A has a connection port 76A connected to the indoor unit side flow path switching unit 80A. Further, the indoor unit side flow path switching unit 80A is connected to the indoor unit side branch pipe 21d and the indoor unit side branch pipe 22d.
In the vicinity of the indoor heat exchanger 71B, a fan 72B that blows air in an air-conditioned space such as a room to the indoor heat exchanger 71B is provided. The indoor heat exchanger 71B has a connection port 76B connected to the indoor unit side flow path switching unit 80B. Further, the indoor unit side flow path switching unit 80B is connected to the indoor unit side branch pipe 21d and the indoor unit side branch pipe 22d.

  That is, by switching the indoor unit side flow path switching unit 80A, the refrigerant flows from the discharge port of the compressor 2b to the indoor heat exchanger 71A and the refrigerant from the indoor heat exchanger 71A to the suction port of the compressor 2a. It is possible to switch between the refrigerant flow path through which the gas flows. Further, by switching the indoor unit side flow path switching unit 80B, the refrigerant flows from the discharge port of the compressor 2b to the indoor heat exchanger 71B and the refrigerant from the indoor heat exchanger 71B to the suction port of the compressor 2a. It is possible to switch between the refrigerant flow path through which the gas flows.

  More specifically, the indoor unit side flow path switching unit 80A includes a first electromagnetic valve 81A and a second electromagnetic valve 82A. The first electromagnetic valve 81A is connected to the indoor unit side branch pipe 21d. The second electromagnetic valve 82A is connected to the indoor unit side branch pipe 22d. The first electromagnetic valve 81A and the second electromagnetic valve 82A are connected to the connection port 76A of the indoor heat exchanger 71A via a pipe. One of the first solenoid valve 81A and the second solenoid valve 82A is opened, and the other of the first solenoid valve 81A and the second solenoid valve 82A is closed, so that the indoor heat exchanger is discharged from the discharge port of the compressor 2b. The refrigerant flow path through which the refrigerant flows to 71A and the refrigerant flow path through which the refrigerant flows from the indoor heat exchanger 71A to the suction port of the compressor 2a can be switched. In addition, you may comprise the 1st solenoid valve 81A and the 2nd solenoid valve 82A with one three-way valve.

Moreover, the indoor unit side flow path switching unit 80B includes a first electromagnetic valve 81B and a second electromagnetic valve 82B. The first electromagnetic valve 81B is connected to the indoor unit side branch pipe 21d. The second electromagnetic valve 82B is connected to the indoor unit side branch pipe 22d. And the 1st solenoid valve 81B and the 2nd solenoid valve 82B are connected with the connection port 76B of the indoor heat exchanger 71B via piping. One of the first electromagnetic valve 81B and the second electromagnetic valve 82B is opened, and the other of the first electromagnetic valve 81B and the second electromagnetic valve 82B is closed, so that the indoor heat exchanger is discharged from the discharge port of the compressor 2b. The refrigerant flow path through which the refrigerant flows to 71B and the refrigerant flow path through which the refrigerant flows from the indoor heat exchanger 71B to the suction port of the compressor 2a can be switched. In addition, you may comprise the 1st solenoid valve 81B and the 2nd solenoid valve 82B with one three-way valve.
Here, the first electromagnetic valve 81A and the first electromagnetic valve 81B correspond to the first indoor unit side opening / closing device, and the second electromagnetic valve 82A and the second electromagnetic valve 82B correspond to the second indoor unit side opening / closing device. .

  A connection port 77A of the indoor heat exchanger 71A is connected to a pipe 91A provided with the LEV 73A. A connection port 77B of the indoor heat exchanger 71B is connected to a pipe 91B provided with a LEV 73B. Further, the pipe 91 </ b> A and the pipe 91 </ b> B merge at the branch portion 91 </ b> C and are connected to the pipe 92. The pipe 92 is connected to the injection circuit 40 via the branch portion 26.

  Further, the refrigerant circuit constituting the indoor unit 70A is provided with a temperature detection device 74A and a temperature detection device 75A such as a temperature sensor, for example, in order to detect the temperature of the refrigerant flowing through the refrigerant circuit. The temperature detection device 74A is provided in a pipe connected to the connection port 76A of the indoor heat exchanger 71A. The temperature detection device 75A is provided in a pipe 91A connected to the connection port 77A of the indoor heat exchanger 71A.

  Similarly, in the refrigerant circuit constituting the indoor unit 70B, a temperature detection device 74B such as a temperature sensor and a temperature detection device 75B are provided in order to detect the temperature of the refrigerant flowing through the refrigerant circuit. The temperature detection device 74B is provided in a pipe connected to the connection port 76B of the indoor heat exchanger 71B. The temperature detection device 75B is provided in the pipe 91B connected to the connection port 77B of the indoor heat exchanger 71B.

(Driving operation)
Next, the operation | movement operation | movement of the air conditioning apparatus 100 in this Embodiment 1 is demonstrated. There are four modes of operation of the air conditioner 100: a heating only operation mode, a heating main operation mode, a cooling only operation mode, and a cooling main operation mode.
The all-heating operation mode is an operation mode in which the indoor unit 70A and the indoor unit 70B can only be heated. The heating main operation mode is an operation mode in which each of the indoor unit 70A and the indoor unit 70B can select a cooling operation and a heating operation, and is a mode used when the heating load is larger than the cooling load. The all-cooling operation mode is an operation mode in which the indoor unit 70A and the indoor unit 70B can only be cooled. The cooling main operation mode is an operation mode in which each of the indoor unit 70A and the indoor unit 70B can select a cooling operation and a heating operation, and is a mode used when the cooling load is larger than the heating load.

(All heating operation mode)
First, the heating only operation mode will be described.
FIG. 2 is a refrigerant circuit diagram showing a refrigerant flow in the heating only operation mode of the air-conditioning apparatus according to Embodiment 1 of the present invention.

When all of the indoor unit 70A and the indoor unit 70B perform the heating operation, the second electromagnetic valve 32a of the outdoor unit side flow switching unit 30a, the second electromagnetic valve 32b of the outdoor unit side flow switching unit 30b, the indoor unit side flow The first electromagnetic valve 81A of the path switching unit 80A and the first electromagnetic valve 81B of the indoor unit side channel switching unit 80B are in an open state. The electromagnetic valve 7, the first electromagnetic valve 31a of the outdoor unit side flow switching unit 30a, the first electromagnetic valve 31b of the outdoor unit side flow switching unit 30b, the second electromagnetic valve 82A of the indoor unit side flow switching unit 80A, and The second electromagnetic valve 82B of the indoor unit side flow path switching unit 80B is in a closed state.
The electromagnetic valve 46 a of the bypass circuit 45 a and the electromagnetic valve 46 b of the bypass circuit 45 b are opened and closed according to the capacity of the compressor 2. Here, description will be made with the electromagnetic valve 46a of the bypass circuit 45a and the electromagnetic valve 46b of the bypass circuit 45b closed. Details of operations of the electromagnetic valve 46a of the bypass circuit 45a and the electromagnetic valve 46b of the bypass circuit 45b will be described later in a second embodiment.

  The low-pressure and low-temperature vapor refrigerant is compressed by the compressor 2a, becomes a medium-pressure vapor refrigerant, and is discharged to the pipe 20. This medium-pressure vapor refrigerant is compressed by the compressor 2b and is discharged into the pipe 21a as a high-pressure and high-temperature vapor refrigerant. The high-pressure and high-temperature vapor refrigerant discharged from the compressor 2b passes through the pipe 21a and the indoor unit side branch pipe 21d and flows into the indoor unit side flow path switching unit 80A and the indoor unit side flow path switching unit 80B.

  The high-pressure and high-temperature vapor refrigerant flowing into the indoor unit side flow path switching unit 80A passes through the first electromagnetic valve 81A and flows into the indoor heat exchanger 71A. Then, it condenses and liquefies while radiating heat to the air in the air-conditioned space sent from the fan 72A, and becomes a high-pressure and low-temperature liquid refrigerant. That is, the air-conditioned space in which the indoor heat exchanger 71A (indoor unit 70A) is installed is heated. The high-pressure liquid refrigerant exiting the indoor heat exchanger 71A flows into the LEV 73A. Then, the pressure is reduced by the LEV 73A to form a two-phase refrigerant and flows into the pipe 91A. In the first embodiment, the LEV 73A is set so that the subcool value, which is a value obtained by subtracting the detected value of the temperature detecting device 75A from the saturated liquid temperature obtained from the detected value of the pressure detecting device 51, is constant (for example, 10 ° C.). The degree of opening is controlled.

  Further, the high-pressure and high-temperature vapor refrigerant flowing into the indoor unit side flow path switching unit 80B passes through the first electromagnetic valve 81B and flows into the indoor heat exchanger 71B. Then, it condenses and liquefies while radiating heat to the air in the air-conditioned space sent from the fan 72B, and becomes a high-pressure and low-temperature liquid refrigerant. That is, the air-conditioned space in which the indoor heat exchanger 71B (indoor unit 70B) is installed is heated. The high-pressure liquid refrigerant that has exited the indoor heat exchanger 71B flows into the LEV 73B. And it is pressure-reduced by LEV73B, becomes a refrigerant | coolant of a two-phase state, and flows in into the piping 91B. In the first embodiment, LEV73B is set so that the subcool value, which is a value obtained by subtracting the detection value of the temperature detection device 75B from the saturated liquid temperature obtained from the detection value of the pressure detection device 51, is constant (for example, 10 ° C.). The degree of opening is controlled.

  The two-phase refrigerant that has exited LEV 73A (flowed into pipe 91A) and the two-phase refrigerant that has exited LEV 73B (flowed into pipe 91B) merge at branch portion 91C and flow into pipe 92. Then, the two-phase refrigerant that has flowed into the pipe 92 is branched at the branch portion 26 and flows into the pipe 25 and the injection circuit 40.

  The two-phase refrigerant that has flowed into the pipe 25 flows into the internal heat exchanger 34. And it cools with the two-phase refrigerant | coolant which flows through the injection circuit 40, and flows in into LEV6. The low-temperature two-phase refrigerant that has flowed into the LEV 6 is depressurized to a predetermined pressure and flows into the branch portion 24c. In the first embodiment, the LEV 6 is controlled so that the detection value of the pressure detection device 53 becomes a constant value (for example, 1.4 MPa).

The low-pressure and low-temperature two-phase refrigerant that has flowed into the branch portion 24c is branched into the pipe 24a and the pipe 24b, and flows into the outdoor heat exchanger 10a and the outdoor heat exchanger 10b.
The low-pressure and low-temperature two-phase refrigerant that has flowed into the outdoor heat exchanger 10a evaporates while absorbing heat from the outside air sent from the fan 5a, and becomes a low-pressure vapor refrigerant. The low-pressure vapor refrigerant exiting the outdoor heat exchanger 10a flows into the outdoor unit side flow path switching unit 30a. The low-pressure vapor refrigerant flowing into the outdoor unit side flow path switching unit 30a flows into the outdoor unit side branch pipe 22c through the second electromagnetic valve 32a.

  The low-pressure and low-temperature two-phase refrigerant that has flowed into the outdoor heat exchanger 10b evaporates while absorbing heat from the outside air sent from the fan 5b, and becomes a low-pressure vapor refrigerant. The low-pressure vapor refrigerant exiting the outdoor heat exchanger 10b flows into the outdoor unit side flow path switching unit 30b. The low-pressure vapor refrigerant flowing into the outdoor unit side flow switching unit 30b flows into the outdoor unit side branch pipe 22c through the second electromagnetic valve 32b, and flows out from the outdoor unit side flow switching unit 30a. Merge with the refrigerant.

  The low-pressure vapor refrigerant flowing into the outdoor unit side branch pipe 22c passes through the branch part 22b and the pipe 22a and is sucked into the compressor 2b.

On the other hand, the two-phase refrigerant that has flowed into the injection circuit 40 is decompressed by the LEV 41 to become a medium-pressure two-phase refrigerant, and flows into the internal heat exchanger 34. Then, the refrigerant absorbs heat from the two-phase refrigerant flowing through the pipe 25 and evaporates to become a medium-pressure vapor refrigerant. In the first embodiment, the opening degree of the LEV 41 is controlled so that the superheat on the discharge side of the compressor 2b becomes a predetermined temperature (depending on the operating conditions). The superheat on the discharge side of the compressor 2b is a value obtained by subtracting the saturated gas temperature obtained from the detection value of the pressure detection device 51 from the detection value of the temperature detection device 61.
The medium-pressure vapor refrigerant exiting the LEV 41 passes through the LEV 42 controlled to a predetermined opening degree and flows into the compression process of the compressor 2 (the pipe 20 connecting the compressor 2a and the compressor 2b) (injection). )

  Note that the capacity (frequency) of the compressor 2a and the compressor 2b and the air volume of the fan 5a and the fan 5b are values in which the saturation temperature obtained from the detection value of the pressure detection device 51 and the saturation temperature obtained from the pressure detection device 52 are constant. It is controlled to become. For example, the capacity (frequency) of the compressor 2a and the compressor 2b and the air volume of the fan 5a and the fan 5b have a saturation temperature obtained from the detected value of the pressure detection device 51 of 50 ° C. and a saturation temperature obtained from the pressure detection device 52. It is controlled to be 0 ° C. In addition, these saturation temperature has shown the average value of saturated liquid temperature and saturated gas temperature.

(Heating main operation mode)
Next, the heating main operation mode will be described.
FIG. 3 is a refrigerant circuit diagram showing a refrigerant flow in the heating main operation mode of the air-conditioning apparatus according to Embodiment 1 of the present invention.

A case where the indoor unit 70A performs the heating operation and the indoor unit 70B performs the cooling operation will be described. The second electromagnetic valve 32a of the outdoor unit side flow switching unit 30a, the second electromagnetic valve 32b of the outdoor unit side flow switching unit 30b, the first electromagnetic valve 81A of the indoor unit side flow switching unit 80A, and the indoor unit side flow The second electromagnetic valve 82B of the path switching unit 80B is open. The electromagnetic valve 7, the first electromagnetic valve 31a of the outdoor unit side flow switching unit 30a, the first electromagnetic valve 31b of the outdoor unit side flow switching unit 30b, the second electromagnetic valve 82A of the indoor unit side flow switching unit 80A, and The first electromagnetic valve 81B of the indoor unit side flow path switching unit 80B is in a closed state.
The electromagnetic valve 46 a of the bypass circuit 45 a and the electromagnetic valve 46 b of the bypass circuit 45 b are opened and closed according to the capacity of the compressor 2. Here, description will be made with the electromagnetic valve 46a of the bypass circuit 45a and the electromagnetic valve 46b of the bypass circuit 45b closed.

  The low-pressure and low-temperature vapor refrigerant is compressed by the compressor 2a, becomes a medium-pressure vapor refrigerant, and is discharged to the pipe 20. This medium-pressure vapor refrigerant is compressed by the compressor 2b and is discharged into the pipe 21a as a high-pressure and high-temperature vapor refrigerant. The high-pressure and high-temperature vapor refrigerant discharged from the compressor 2b flows through the pipe 21a and the indoor unit side branch pipe 21d into the indoor unit side flow path switching unit 80A.

  The high-pressure and high-temperature vapor refrigerant flowing into the indoor unit side flow path switching unit 80A passes through the first electromagnetic valve 81A and flows into the indoor heat exchanger 71A. Then, it condenses and liquefies while radiating heat to the air in the air-conditioned space sent from the fan 72A, and becomes a high-pressure and low-temperature liquid refrigerant. That is, the air-conditioned space in which the indoor heat exchanger 71A (indoor unit 70A) is installed is heated. The high-pressure liquid refrigerant exiting the indoor heat exchanger 71A flows into the LEV 73A. Then, the pressure is reduced by the LEV 73A to form a two-phase refrigerant and flows into the pipe 91A. In the first embodiment, the LEV 73A is set so that the subcool value, which is a value obtained by subtracting the detected value of the temperature detecting device 75A from the saturated liquid temperature obtained from the detected value of the pressure detecting device 51, is constant (for example, 10 ° C.). Is controlled.

  The two-phase refrigerant that has exited LEV 73A (flowed into pipe 91A) is branched by branching section 91C and flows into pipe 91B and pipe 92.

  The two-phase refrigerant that has flowed into the pipe 91B from the indoor unit side flow path switching unit 80A flows into the LEV 73B and is depressurized to become a low-pressure and low-temperature two-phase refrigerant. The low-pressure and low-temperature two-phase refrigerant output from the LEV 73B flows into the indoor heat exchanger 71B. And it evaporates while absorbing heat from the air in the air-conditioned space sent from the fan 72B, and becomes a low-pressure vapor refrigerant. That is, the air-conditioned space in which the indoor heat exchanger 71B (indoor unit 70B) is installed is cooled. The low-pressure vapor refrigerant that has exited the indoor unit side flow path switching unit 80B flows into the indoor unit side flow path switching unit 80B. The low-pressure vapor refrigerant flowing into the indoor unit side flow path switching unit 80B flows into the indoor unit side branch pipe 22d through the second electromagnetic valve 82B and the indoor unit side branch pipe 22d. In the first embodiment, the opening degree of the LEV 73B is controlled so that the superheat value obtained by subtracting the detection value of the temperature detection device 75B from the detection value of the temperature detection device 74B becomes constant (for example, 5).

  The two-phase refrigerant that has flowed into the pipe 92 from the indoor unit side flow path switching unit 80A is branched by the branching section 26 and flows into the pipe 25 and the injection circuit 40.

  The two-phase refrigerant that has flowed into the pipe 25 flows into the internal heat exchanger 34. And it cools with the two-phase refrigerant | coolant which flows through the injection circuit 40, and flows in into LEV6. The low-temperature two-phase refrigerant that has flowed into the LEV 6 is depressurized to a predetermined pressure and flows into the branch portion 24c. In the first embodiment, the LEV 6 is controlled so that the detection value of the pressure detection device 53 becomes a constant value (for example, 1.4 MPa).

The low-pressure and low-temperature two-phase refrigerant that has flowed into the branch portion 24c is branched into the pipe 24a and the pipe 24b, and flows into the outdoor heat exchanger 10a and the outdoor heat exchanger 10b.
The low-pressure and low-temperature two-phase refrigerant that has flowed into the outdoor heat exchanger 10a evaporates while absorbing heat from the outside air sent from the fan 5a, and becomes a low-pressure vapor refrigerant. The low-pressure vapor refrigerant exiting the outdoor heat exchanger 10a flows into the outdoor unit side flow path switching unit 30a. The low-pressure vapor refrigerant flowing into the outdoor unit side flow path switching unit 30a flows into the outdoor unit side branch pipe 22c through the second electromagnetic valve 32a.

  The low-pressure and low-temperature two-phase refrigerant that has flowed into the outdoor heat exchanger 10b evaporates while absorbing heat from the outside air sent from the fan 5b, and becomes a low-pressure vapor refrigerant. The low-pressure vapor refrigerant exiting the outdoor heat exchanger 10b flows into the outdoor unit side flow path switching unit 30b. The low-pressure vapor refrigerant flowing into the outdoor unit side flow switching unit 30b flows into the outdoor unit side branch pipe 22c through the second electromagnetic valve 32b, and flows out from the outdoor unit side flow switching unit 30a. Merge with the refrigerant.

  The low-pressure vapor refrigerant flowing into the outdoor unit side branch pipe 22c merges with the low-pressure vapor refrigerant flowing out of the indoor heat exchanger 71B through the indoor unit side branch pipe 22d. The low-pressure vapor refrigerant is sucked into the compressor 2b through the pipe 22a.

On the other hand, the two-phase refrigerant that has flowed into the injection circuit 40 is decompressed by the LEV 41 to become a medium-pressure two-phase refrigerant, and flows into the internal heat exchanger 34. Then, the refrigerant absorbs heat from the two-phase refrigerant flowing through the pipe 25 and evaporates to become a medium-pressure vapor refrigerant. In the first embodiment, the LEV 41 is controlled so that the superheat on the discharge side of the compressor 2b becomes a predetermined temperature (depending on the operating conditions).
The medium-pressure vapor refrigerant exiting the LEV 41 passes through the LEV 42 controlled to a predetermined opening degree and flows into the compression process of the compressor 2 (the pipe 20 connecting the compressor 2a and the compressor 2b) (injection). )

  Note that the capacity (frequency) of the compressor 2a and the compressor 2b and the air volume of the fan 5a and the fan 5b are values in which the saturation temperature obtained from the detection value of the pressure detection device 51 and the saturation temperature obtained from the pressure detection device 52 are constant. It is controlled to become. For example, the capacity (frequency) of the compressor 2a and the compressor 2b and the air volume of the fan 5a and the fan 5b have a saturation temperature obtained from the detected value of the pressure detection device 51 of 50 ° C. and a saturation temperature obtained from the pressure detection device 52. It is controlled to be 0 ° C. In addition, these saturation temperature has shown the average value of saturated liquid temperature and saturated gas temperature.

Here, when the saturation temperature obtained from the detection value of the pressure detection device 52 is high, the heat exchange capability of the outdoor heat exchanger may be suppressed, so that one of the two outdoor heat exchangers is not used. May be.
FIG. 4 is a refrigerant circuit diagram illustrating an example of another refrigerant flow in the heating main operation mode of the air-conditioning apparatus according to Embodiment 1 of the present invention. For example, as shown in FIG. 4, the refrigerant may be allowed to flow only to the outdoor heat exchanger 10b by closing the second electromagnetic valve 32a of the outdoor unit side flow path switching unit 30a. Further, for example, the refrigerant may be flowed only to the outdoor heat exchanger 10a by closing the second electromagnetic valve 32b of the outdoor unit side flow path switching unit 30b (not shown).

(Cooling mode only)
Next, the cooling only operation mode will be described.
FIG. 5 is a refrigerant circuit diagram showing a refrigerant flow in the cooling only operation mode of the air-conditioning apparatus according to Embodiment 1 of the present invention.

When all of the indoor unit 70A and the indoor unit 70B perform the cooling operation, the electromagnetic valve 7, the first electromagnetic valve 31a of the outdoor unit side flow switching unit 30a, the first electromagnetic valve 31b of the outdoor unit side flow switching unit 30b, The second electromagnetic valve 82A of the indoor unit side flow path switching unit 80A and the second electromagnetic valve 82B of the indoor unit side flow path switching unit 80B are open. The second electromagnetic valve 32a of the outdoor unit side flow switching unit 30a, the second electromagnetic valve 32b of the outdoor unit side flow switching unit 30b, the first electromagnetic valve 81A of the indoor unit side flow switching unit 80A, and the indoor unit side flow The first electromagnetic valve 81B of the path switching unit 80B is in a closed state.
The electromagnetic valve 46 a of the bypass circuit 45 a and the electromagnetic valve 46 b of the bypass circuit 45 b are opened and closed according to the capacity of the compressor 2. Here, description will be made with the electromagnetic valve 46a of the bypass circuit 45a and the electromagnetic valve 46b of the bypass circuit 45b closed.

  The low-pressure and low-temperature vapor refrigerant is compressed by the compressor 2a, becomes a medium-pressure vapor refrigerant, and is discharged to the pipe 20. This medium-pressure vapor refrigerant is compressed by the compressor 2b and is discharged into the pipe 21a as a high-pressure and high-temperature vapor refrigerant. The high-pressure and high-temperature vapor refrigerant discharged from the compressor 2b flows through the pipe 21a and the outdoor unit side branch pipe 21c into the outdoor unit side flow path switching unit 30a and the outdoor unit side flow path switching unit 30b.

The high-pressure and high-temperature vapor refrigerant flowing into the outdoor unit side flow path switching unit 30a passes through the first electromagnetic valve 31a and flows into the outdoor heat exchanger 10a. Then, it condenses and liquefies while radiating heat to the outside air sent from the fan 5a to become a high-pressure and low-temperature liquid refrigerant. The high-pressure liquid refrigerant exiting the outdoor heat exchanger 10a flows into the pipe 24a.
The high-pressure and high-temperature vapor refrigerant that has flowed into the outdoor unit side flow path switching unit 30b passes through the first electromagnetic valve 31b and flows into the outdoor heat exchanger 10b. Then, it condenses and liquefies while radiating heat to the outside air sent from the fan 5b, and becomes a high-pressure and low-temperature liquid refrigerant. The high-pressure liquid refrigerant that has exited the outdoor heat exchanger 10b flows into the pipe 24b.

  The high-pressure and low-temperature liquid refrigerant exiting the outdoor heat exchanger 10a (flowed into the pipe 24a) and the high-pressure and low-temperature liquid refrigerant exiting the outdoor heat exchanger 10b (flowed into the pipe 24b) merged at the branching section 24c. , Flows into the pipe 25. The high-pressure and low-temperature liquid refrigerant flowing into the pipe 25 flows into the internal heat exchanger 34 through the LEV 6. Then, the refrigerant is cooled by the two-phase refrigerant flowing through the injection circuit 40 and flows into the branch portion 26. In the first embodiment, the opening degree of LEV 6 is fully opened.

  The high-pressure and low-temperature liquid refrigerant that has flowed into the branch section 26 is branched and flows into the pipe 92 and the injection circuit 40. The high-pressure and low-temperature liquid refrigerant that has flowed into the pipe 92 is branched at the branching portion 91C and flows into the LEV 73A and the LEV 73B.

  The high-pressure and low-temperature liquid refrigerant flowing into the LEV 73A is reduced in pressure to become a low-pressure and low-temperature two-phase refrigerant and flows into the indoor heat exchanger 71A. And it evaporates while absorbing heat from the air in the air-conditioned space sent from the fan 72A, and becomes a low-pressure vapor refrigerant. That is, the air-conditioned space in which the indoor heat exchanger 71A (indoor unit 70A) is installed is cooled. The low-pressure vapor refrigerant exiting the indoor heat exchanger 71A flows into the indoor unit side flow path switching unit 80A. The low-pressure vapor refrigerant flowing into the indoor unit side flow path switching unit 80A passes through the second electromagnetic valve 82A and flows into the indoor unit side branch pipe 22d. In the first embodiment, the opening degree of the LEV 73A is controlled so that the superheat value, which is a value obtained by subtracting the detection value of the temperature detection device 75A from the detection value of the temperature detection device 74A, is constant (for example, 5 ° C.). Has been.

  The high-pressure and low-temperature liquid refrigerant that has flowed into the LEV 73B is reduced in pressure to become a low-pressure and low-temperature two-phase refrigerant and flows into the indoor heat exchanger 71B. And it evaporates while absorbing heat from the air in the air-conditioned space sent from the fan 72B, and becomes a low-pressure vapor refrigerant. That is, the air-conditioned space in which the indoor heat exchanger 71B (indoor unit 70B) is installed is cooled. The low-pressure vapor refrigerant exiting the indoor heat exchanger 71B flows into the indoor unit side flow path switching unit 80B. The low-pressure vapor refrigerant flowing into the indoor unit side flow path switching unit 80B passes through the second electromagnetic valve 82B and flows into the indoor unit side branch pipe 22d. In the first embodiment, the opening degree of the LEV 73B is controlled so that the superheat value, which is a value obtained by subtracting the detection value of the temperature detection device 75B from the detection value of the temperature detection device 74B, is constant (for example, 5 ° C.). Has been.

  The low-pressure vapor refrigerant exiting the indoor unit side channel switching unit 80A and the low-pressure vapor refrigerant exiting the indoor unit side channel switching unit 80B merge at the indoor unit side branch pipe 22d, and the branch unit 22b and It passes through the pipe 22a and is sucked into the compressor 2b.

  On the other hand, the high-pressure and low-temperature liquid refrigerant that has flowed into the injection circuit 40 is decompressed by the LEV 41 to become a medium-pressure and low-temperature two-phase refrigerant and flows into the internal heat exchanger 34. Then, it absorbs heat from the high-pressure and low-temperature liquid refrigerant flowing through the pipe 25 and evaporates to become a medium-pressure vapor refrigerant. The medium-pressure vapor refrigerant exiting the internal heat exchanger 34 joins the low-pressure vapor refrigerant flowing through the pipe 22a through the pipe 27 and the electromagnetic valve 7, and is sucked into the compressor 2b. In the first embodiment, the superheat that is a value obtained by subtracting the saturated gas temperature obtained from the pressure detection device 52 from the detection value of the temperature detection device 62 (at least one of the temperature detection device 62a and the temperature detection device 62b) is predetermined. The LEV 41 is controlled so that the temperature becomes (for example, 10 ° C.). Moreover, the opening degree of LEV42 is a closed state.

  Note that the capacity (frequency) of the compressor 2a and the compressor 2b and the air volume of the fan 5a and the fan 5b are values in which the saturation temperature obtained from the detection value of the pressure detection device 51 and the saturation temperature obtained from the pressure detection device 52 are constant. It is controlled to become. For example, the capacity (frequency) of the compressor 2a and the compressor 2b and the air volume of the fan 5a and the fan 5b have a saturation temperature calculated from the detection value of the pressure detection device 51 of 45 ° C. and the saturation temperature calculated from the pressure detection device 52. It is controlled to be 0 ° C. In addition, these saturation temperature has shown the average value of saturated liquid temperature and saturated gas temperature.

(Cooling operation mode)
Next, the cooling main operation mode will be described.
FIG. 6 is a refrigerant circuit diagram showing a refrigerant flow in the cooling main operation mode of the air-conditioning apparatus according to Embodiment 1 of the present invention.

A case where the indoor unit 70A performs the cooling operation and the indoor unit 70B performs the heating operation will be described. The electromagnetic valve 7, the first electromagnetic valve 31a of the outdoor unit side flow switching unit 30a, the first electromagnetic valve 31b of the outdoor unit side flow switching unit 30b, the second electromagnetic valve 82A of the indoor unit side flow switching unit 80A, and The first electromagnetic valve 81B of the indoor unit side flow path switching unit 80B is open. The second electromagnetic valve 32a of the outdoor unit side flow switching unit 30a, the second electromagnetic valve 32b of the outdoor unit side flow switching unit 30b, the first electromagnetic valve 81A of the indoor unit side flow switching unit 80A, and the indoor unit side flow The second electromagnetic valve 82B of the path switching unit 80B is in a closed state.
The electromagnetic valve 46 a of the bypass circuit 45 a and the electromagnetic valve 46 b of the bypass circuit 45 b are opened and closed according to the capacity of the compressor 2. Here, description will be made with the electromagnetic valve 46a of the bypass circuit 45a and the electromagnetic valve 46b of the bypass circuit 45b closed.

  The low-pressure and low-temperature vapor refrigerant is compressed by the compressor 2a, becomes a medium-pressure vapor refrigerant, and is discharged to the pipe 20. This medium-pressure vapor refrigerant is compressed by the compressor 2b and is discharged into the pipe 21a as a high-pressure and high-temperature vapor refrigerant. The high-pressure and high-temperature vapor refrigerant discharged from the compressor 2b flows into the pipe 21a. The high-pressure and high-temperature vapor refrigerant that has flowed into the pipe 21a is branched at the branch portion 21b and flows into the outdoor unit-side branch pipe 21c and the indoor unit-side branch pipe 21d.

The high-pressure and high-temperature vapor refrigerant that has flowed into the outdoor unit side branch pipe 21c flows into each of the outdoor unit side flow path switching unit 30a and the outdoor unit side flow path switching unit 30b.
The high-pressure and high-temperature vapor refrigerant flowing into the outdoor unit side flow path switching unit 30a passes through the first electromagnetic valve 31a and flows into the outdoor heat exchanger 10a. Then, it condenses and liquefies while radiating heat to the outside air sent from the fan 5a to become a high-pressure and low-temperature liquid refrigerant. The high-pressure liquid refrigerant exiting the outdoor heat exchanger 10a flows into the pipe 24a.
The high-pressure and high-temperature vapor refrigerant that has flowed into the outdoor unit side flow path switching unit 30b passes through the first electromagnetic valve 31b and flows into the outdoor heat exchanger 10b. Then, it condenses and liquefies while radiating heat to the outside air sent from the fan 5b, and becomes a high-pressure and low-temperature liquid refrigerant. The high-pressure liquid refrigerant that has exited the outdoor heat exchanger 10b flows into the pipe 24b.

  The high-pressure and low-temperature liquid refrigerant exiting the outdoor heat exchanger 10a (flowed into the pipe 24a) and the high-pressure and low-temperature liquid refrigerant exiting the outdoor heat exchanger 10b (flowed into the pipe 24b) merged at the branching section 24c. , Flows into the pipe 25. The high-pressure and low-temperature liquid refrigerant flowing into the pipe 25 flows into the internal heat exchanger 34 through the LEV 6. Then, the refrigerant is cooled by the two-phase refrigerant flowing through the injection circuit 40 and flows into the branch portion 26. The high-pressure and low-temperature liquid refrigerant that has flowed into the branch section 26 is branched and flows into the pipe 92 and the injection circuit 40. In the first embodiment, the opening degree of LEV 6 is fully opened.

  On the other hand, the high-pressure and high-temperature vapor refrigerant flowing into the indoor unit side branch pipe 21d flows into the indoor unit side flow path switching unit 80B. The high-pressure and high-temperature vapor refrigerant flowing into the indoor unit side flow path switching unit 80B passes through the first electromagnetic valve 81B and flows into the indoor heat exchanger 71B. Then, it condenses and liquefies while radiating heat to the air in the air-conditioned space sent from the fan 72B, and becomes a high-pressure and low-temperature liquid refrigerant. That is, the air-conditioned space in which the indoor heat exchanger 71B (indoor unit 70B) is installed is heated. The high-pressure and low-temperature liquid refrigerant exiting the indoor heat exchanger 71B flows into the LEV 73B. And it is decompressed by LEV73B, becomes a low-temperature two-phase refrigerant, and flows into the pipe 91B. In the first embodiment, LEV73B is set so that the subcool value, which is a value obtained by subtracting the detection value of the temperature detection device 75B from the saturated liquid temperature obtained from the detection value of the pressure detection device 51, is constant (for example, 10 ° C.). Is controlled.

  The low-temperature two-phase refrigerant that has flowed into the pipe 91B and the high-pressure and low-temperature liquid refrigerant that has flowed into the pipe 92 merge at the branch portion 91C and flow into the LEV 73A through the pipe 91A. Then, the pressure is reduced to form a low-pressure and low-temperature two-phase refrigerant and flows into the indoor heat exchanger 71A. And it evaporates while absorbing heat from the air in the air-conditioned space sent from the fan 72A, and becomes a low-pressure vapor refrigerant. That is, the air-conditioned space in which the indoor heat exchanger 71A (indoor unit 70A) is installed is cooled. The low-pressure vapor refrigerant exiting the indoor heat exchanger 71A flows into the indoor unit side flow path switching unit 80A. The low-pressure vapor refrigerant flowing into the indoor unit side flow path switching unit 80A passes through the second electromagnetic valve 82A and flows into the indoor unit side branch pipe 22d. In the first embodiment, the opening degree of the LEV 73A is controlled so that the superheat value, which is a value obtained by subtracting the detection value of the temperature detection device 75A from the detection value of the temperature detection device 74A, is constant (for example, 5 ° C.). Has been.

  The low-pressure vapor refrigerant exiting the indoor unit side branch pipe 22d passes through the branch part 22b and the pipe 22a and is sucked into the compressor 2b.

  The high-pressure and low-temperature liquid refrigerant that has flowed into the injection circuit 40 from the branch portion 26 is decompressed by the LEV 41 to become a medium-pressure and low-temperature two-phase refrigerant, and flows into the internal heat exchanger 34. Then, it absorbs heat from the high-pressure and low-temperature liquid refrigerant flowing through the pipe 25 and evaporates to become a medium-pressure vapor refrigerant. The medium-pressure vapor refrigerant exiting the internal heat exchanger 34 joins the low-pressure vapor refrigerant flowing through the pipe 22a through the pipe 27 and the electromagnetic valve 7, and is sucked into the compressor 2b. In the first embodiment, the superheat that is a value obtained by subtracting the saturated gas temperature obtained from the pressure detection device 52 from the detection value of the temperature detection device 62 (at least one of the temperature detection device 62a and the temperature detection device 62b) is predetermined. The LEV 41 is controlled so that the temperature becomes (for example, 10 ° C.). Moreover, the opening degree of LEV42 is a closed state.

  Note that the capacity (frequency) of the compressor 2a and the compressor 2b and the air volume of the fan 5a and the fan 5b are values in which the saturation temperature obtained from the detection value of the pressure detection device 51 and the saturation temperature obtained from the pressure detection device 52 are constant. It is controlled to become. For example, the capacity (frequency) of the compressor 2a and the compressor 2b and the air volume of the fan 5a and the fan 5b have a saturation temperature calculated from the detection value of the pressure detection device 51 of 45 ° C. and the saturation temperature calculated from the pressure detection device 52. It is controlled to be 0 ° C. In addition, these saturation temperature has shown the average value of saturated liquid temperature and saturated gas temperature.

  If the heating operation is performed under a low outside air temperature condition, condensed water adhering to the outdoor heat exchanger 10a and the outdoor heat exchanger 10b may freeze and form frost. Therefore, the air conditioner 100 according to Embodiment 1 performs a defrosting operation in order to remove frost attached to the outdoor heat exchanger 10a and the outdoor heat exchanger 10b. In the first embodiment, the defrosting operation is performed while performing the heating operation.

(Defrosting operation)
FIG. 7 is a refrigerant circuit diagram illustrating an example of a refrigerant flow in the defrosting operation of the air-conditioning apparatus according to Embodiment 1 of the present invention. This figure shows the defrosting operation in the heating only operation mode.

When defrosting the outdoor heat exchanger 10a in the heating only operation mode, the first electromagnetic valve 31a of the outdoor unit side flow switching unit 30a, the second electromagnetic valve 32b of the outdoor unit side flow switching unit 30b, the indoor unit side flow The first electromagnetic valve 81A of the path switching unit 80A and the first electromagnetic valve 81B of the indoor unit side channel switching unit 80B are in an open state. The electromagnetic valve 7, the second electromagnetic valve 32a of the outdoor unit side flow switching unit 30a, the first electromagnetic valve 31b of the outdoor unit side flow switching unit 30b, the second electromagnetic valve 82A of the indoor unit side flow switching unit 80A, and The second electromagnetic valve 82B of the indoor unit side flow path switching unit 80B is in a closed state.
The electromagnetic valve 46 a of the bypass circuit 45 a and the electromagnetic valve 46 b of the bypass circuit 45 b are opened and closed according to the capacity of the compressor 2. Here, description will be made with the electromagnetic valve 46a of the bypass circuit 45a and the electromagnetic valve 46b of the bypass circuit 45b closed.

  The low-pressure and low-temperature vapor refrigerant is compressed by the compressor 2a, becomes a medium-pressure vapor refrigerant, and is discharged to the pipe 20. This medium-pressure vapor refrigerant is compressed by the compressor 2b and is discharged into the pipe 21a as a high-pressure and high-temperature vapor refrigerant. The high-pressure and high-temperature vapor refrigerant discharged from the compressor 2b flows into the pipe 21a. The high-pressure and high-temperature vapor refrigerant that has flowed into the pipe 21a is branched at the branch portion 21b and flows into the outdoor unit-side branch pipe 21c and the indoor unit-side branch pipe 21d.

  The high-pressure and high-temperature vapor refrigerant that has flowed into the indoor unit side branch pipe 21d flows into each of the indoor unit side flow path switching unit 80A and the indoor unit side flow path switching unit 80B.

  The high-pressure and high-temperature vapor refrigerant flowing into the indoor unit side flow path switching unit 80A passes through the first electromagnetic valve 81A and flows into the indoor heat exchanger 71A. Then, it condenses and liquefies while radiating heat to the air in the air-conditioned space sent from the fan 72A, and becomes a high-pressure and low-temperature liquid refrigerant. That is, the air-conditioned space in which the indoor heat exchanger 71A (indoor unit 70A) is installed is heated. The high-pressure liquid refrigerant exiting the indoor heat exchanger 71A flows into the LEV 73A. Then, the pressure is reduced by the LEV 73A to form a two-phase refrigerant and flows into the pipe 91A. In the first embodiment, the LEV 73A is set so that the subcool value, which is a value obtained by subtracting the detected value of the temperature detecting device 75A from the saturated liquid temperature obtained from the detected value of the pressure detecting device 51, is constant (for example, 10 ° C.). The degree of opening is controlled.

  Further, the high-pressure and high-temperature vapor refrigerant flowing into the indoor unit side flow path switching unit 80B passes through the first electromagnetic valve 81B and flows into the indoor heat exchanger 71B. Then, it condenses and liquefies while radiating heat to the air in the air-conditioned space sent from the fan 72B, and becomes a high-pressure and low-temperature liquid refrigerant. That is, the air-conditioned space in which the indoor heat exchanger 71B (indoor unit 70B) is installed is heated. The high-pressure liquid refrigerant that has exited the indoor heat exchanger 71B flows into the LEV 73B. And it is pressure-reduced by LEV73B, becomes a refrigerant | coolant of a two-phase state, and flows in into the piping 91B. In the first embodiment, LEV73B is set so that the subcool value, which is a value obtained by subtracting the detection value of the temperature detection device 75B from the saturated liquid temperature obtained from the detection value of the pressure detection device 51, is constant (for example, 10 ° C.). The degree of opening is controlled.

  The two-phase refrigerant that has exited LEV 73A (flowed into pipe 91A) and the two-phase refrigerant that has exited LEV 73B (flowed into pipe 91B) merge at branch portion 91C and flow into pipe 92. Then, the two-phase refrigerant that has flowed into the pipe 92 is branched at the branch portion 26 and flows into the pipe 25 and the injection circuit 40.

  The two-phase refrigerant that has flowed into the pipe 25 flows into the internal heat exchanger 34. And it cools with the two-phase refrigerant | coolant which flows through the injection circuit 40, and flows in into LEV6. The low-temperature two-phase refrigerant that has flowed into the LEV 6 is depressurized to a predetermined pressure and flows into the branch portion 24c. In the first embodiment, the LEV 6 is controlled so that the detection value of the pressure detection device 53 becomes a constant value (for example, 1.4 MPa).

  The low-pressure and low-temperature two-phase refrigerant that has flowed into the branch portion 24c flows into the outdoor heat exchanger 10b through the pipe 24b. The low-pressure and low-temperature two-phase refrigerant that has flowed into the outdoor heat exchanger 10b evaporates while absorbing heat from the outside air sent from the fan 5b, and becomes a low-pressure vapor refrigerant. The low-pressure vapor refrigerant exiting the outdoor heat exchanger 10b flows into the outdoor unit side flow path switching unit 30b. The low-pressure vapor refrigerant flowing into the outdoor unit side flow switching unit 30b flows into the outdoor unit side branch pipe 22c through the second electromagnetic valve 32b. The low-pressure vapor refrigerant flowing into the outdoor unit side branch pipe 22c passes through the branch part 22b and the pipe 22a and is sucked into the compressor 2b.

The two-phase refrigerant that has flowed into the injection circuit 40 from the branch portion 26 is decompressed by the LEV 41 to become a medium-pressure two-phase refrigerant, and flows into the internal heat exchanger 34. Then, the refrigerant absorbs heat from the two-phase refrigerant flowing through the pipe 25 and evaporates to become a medium-pressure vapor refrigerant. In the first embodiment, the opening degree of the LEV 41 is controlled so that the superheat on the discharge side of the compressor 2b becomes a predetermined temperature (depending on the operating conditions). The superheat on the discharge side of the compressor 2b is a value obtained by subtracting the saturated gas temperature obtained from the detection value of the pressure detection device 51 from the detection value of the temperature detection device 61.
The medium-pressure vapor refrigerant exiting the LEV 41 passes through the LEV 42 controlled to a predetermined opening degree and flows into the compression process of the compressor 2 (the pipe 20 connecting the compressor 2a and the compressor 2b) (injection). )

On the other hand, the high-pressure and high-temperature vapor refrigerant flowing into the outdoor unit side branch pipe 21c flows into the outdoor unit side flow path switching unit 30a. The high-pressure and high-temperature vapor refrigerant flowing into the outdoor unit side flow path switching unit 30a passes through the first electromagnetic valve 31a and flows into the outdoor heat exchanger 10a. Then, the frost adhering to the outdoor heat exchanger 10a is condensed and liquefied to become a high-pressure and low-temperature liquid refrigerant. At this time, the fan 5a is stopped.
The high-pressure and low-temperature liquid refrigerant that has exited the outdoor heat exchanger 10a merges with the low-pressure and low-temperature two-phase refrigerant that has flowed from the pipe 25 at the branch portion 24c, and flows into the pipe 24b.

  The capacity (frequency) of the compressor 2a and the compressor 2b and the air volume of the fan 5b are controlled so that the saturation temperature obtained from the detection value of the pressure detection device 51 and the saturation temperature obtained from the pressure detection device 52 become constant values. Has been. For example, the capacity (frequency) of the compressor 2a and the compressor 2b and the air volume of the fan 5a and the fan 5b have a saturation temperature obtained from the detected value of the pressure detection device 51 of 50 ° C. and a saturation temperature obtained from the pressure detection device 52. It is controlled to be 0 ° C. In addition, these saturation temperature has shown the average value of saturated liquid temperature and saturated gas temperature.

In addition, what is necessary is just to do as shown in FIG. 8, when performing defrosting of the outdoor heat exchanger 10b at the time of heating only operation mode.
FIG. 8 is a refrigerant circuit diagram illustrating another example of the refrigerant flow in the defrosting operation of the air-conditioning apparatus according to Embodiment 1 of the present invention. The refrigerant flow shown in FIG. 8 is basically the same as the refrigerant flow shown in FIG. However, the second electromagnetic valve 32a of the outdoor unit side flow switching unit 30a and the first electromagnetic valve 31b of the outdoor unit side flow switching unit 30b are in an open state, and the second electromagnetic valve 32a of the outdoor unit side flow switching unit 30a is open. 7 is different from FIG. 7 in that the first electromagnetic valve 31a and the second electromagnetic valve 32b of the outdoor unit side flow path switching unit 30b are closed.

Thereby, the high-pressure and high-temperature vapor refrigerant flowing into the outdoor unit side branch pipe 21c flows into the outdoor heat exchanger 10b through the first electromagnetic valve 31b of the outdoor unit side flow path switching unit 30b. Then, the frost adhering to the outdoor heat exchanger 10b is condensed and liquefied to become a high-pressure and low-temperature liquid refrigerant.
Further, the low-pressure and low-temperature two-phase refrigerant that has flowed in from the pipe 25 and the high-pressure and low-temperature liquid refrigerant that has exited the outdoor heat exchanger 10a flow into the outdoor heat exchanger 10a through the pipe 24a. The low-pressure and low-temperature two-phase refrigerant that has flowed into the outdoor heat exchanger 10a evaporates while absorbing heat from the outside air sent from the fan 5a, and becomes a low-pressure vapor refrigerant.

(Control during heating)
Then, an example of the control method at the time of the heating operation of the air conditioning apparatus 100 which concerns on this Embodiment 1 is demonstrated. In the following, description will be given focusing on opening / closing control of an electromagnetic valve provided in the refrigerant circuit of the air conditioner 100 and opening degree control of LEV.

FIG. 9 is a flowchart illustrating an example of a control method during heating operation of the air-conditioning apparatus according to Embodiment 1 of the present invention.
When the all heating operation or the heating main operation is started (step S1), the outdoor unit side channel switching unit 30a, the outdoor unit side channel switching unit 30b, the indoor unit side channel switching unit 80A, and the indoor unit side channel switching. The flow path of the part 80B or the like is set as a flow path in the heating only operation mode or the heating main operation mode. For example, in the heating only operation mode, the second electromagnetic valve 32a of the outdoor unit side flow switching unit 30a, the second electromagnetic valve 32b of the outdoor unit side flow switching unit 30b, and the first electromagnetic of the indoor unit side flow switching unit 80A. The valve 81A and the first electromagnetic valve 81B of the indoor unit side flow path switching unit 80B are opened. The electromagnetic valve 7, the first electromagnetic valve 31a of the outdoor unit side flow switching unit 30a, the first electromagnetic valve 31b of the outdoor unit side flow switching unit 30b, the second electromagnetic valve 82A of the indoor unit side flow switching unit 80A, and The second electromagnetic valve 82B of the indoor unit side flow path switching unit 80B is closed. Further, the opening degree of LEV6 is fully opened, the opening degree of LEV41 is fully closed, and the opening degree of LEV42 is set to an arbitrary opening degree (step S2).

  Immediately after the start of the heating operation (until the refrigerant flow in the refrigerant circuit is stabilized), the refrigerant in the injection circuit 40 is in a low density state. If this low-density refrigerant is injected into the compression process of the compressor 2 (pipe 20 connecting the compressor 2a and the compressor 2b), the temperature of the refrigerant discharged from the compressor 2b will rise excessively. Immediately after the start of the heating operation (until the refrigerant flow in the refrigerant circuit is stabilized), it is possible to prevent an excessive increase in the temperature of the refrigerant discharged from the compressor 2b by fully opening the opening of the LEV 41. Further, immediately after the start of the heating operation (until the refrigerant flow in the refrigerant circuit is stabilized), the capacity of the compressor 2 is increased by reducing the pressure of the refrigerant sucked by the compressor 2a by fully opening the opening of the LEV 6. Insufficiency can be prevented.

  In addition, the air volume of the fan 5a and the fan 5b is controlled so that the saturation temperature calculated | required from the detected value of the pressure detection apparatus 51, and the saturation temperature calculated | required from the pressure detection apparatus 52 become a constant value as mentioned above. For example, the capacity (frequency) of the compressor 2a and the compressor 2b and the air volume of the fan 5a and the fan 5b have a saturation temperature obtained from the detected value of the pressure detection device 51 of 50 ° C. and a saturation temperature obtained from the pressure detection device 52. It is controlled to be 0 ° C.

  In step S3, it is determined whether or not a predetermined time (for example, 10 minutes) has elapsed since the start of the all heating operation or the heating main operation. If a predetermined time (for example, 10 minutes) has elapsed since the start of the all heating operation or the heating main operation, the process proceeds to step S4, and the predetermined time (for example, 10 minutes) has elapsed since the start of the total heating operation or the heating main operation. If not, the process returns to step S2.

  In step S4, it is determined whether the all heating operation or the heating main operation is continued. If the all heating operation or the heating main operation is continued, the process proceeds to step S5, and if the all heating operation or the heating main operation is not continued, the process returns to step S2. In step S5, LEV 41 is opened to a predetermined opening, and LEV 6 is throttled to a predetermined opening. In step S6, a control target value (for example, 1.4 MPa) of the pressure detection device 53 is set. Also, a superheat control target value on the discharge side of the compressor 2b is set. Note that the initial control target value of superheat on the discharge side of the compressor 2b is an arbitrary set value.

In step S7, the opening degree of LEV6 is adjusted so that the detection value of the pressure detection device 53 becomes the control target value (for example, 1.4 MPa) set in step S6. Further, the opening degree of the LEV 41 is adjusted so that the superheat on the discharge side of the compressor 2b becomes the control target value set in step S6.
In step S8, it is determined whether or not a predetermined time (for example, 1 minute) has elapsed since the control target value of the pressure detection device 53 and the control target value of the superheat on the discharge side of the compressor 2b are set. If the predetermined time has not elapsed, the process returns to step S7, and the opening degree of the LEV 6 is adjusted so that the detection value of the pressure detection device 53 becomes the control target value (for example, 1.4 MPa) set in step S6. Further, the opening degree of the LEV 41 is adjusted so that the superheat on the discharge side of the compressor 2b becomes the control target value set in step S6. If the predetermined time has elapsed, the process returns to step S6, and the control target value of the pressure detection device 53 and the control target value of the superheat on the discharge side of the compressor 2b are reset according to the operating conditions of the air conditioner 100 and the like. .

  Here, when the control target value of the superheat on the discharge side of the compressor 2b is reset in step S6, for example, the control target value is set based on the frequencies of the compressor 2a and the compressor 2b indicating the capacity of the compressor 2. decide. For example, when the frequency of the compressor 2a and the compressor 2b is 70 Hz or higher, the superheat control target value on the discharge side of the compressor 2b is set to 10 ° C. For example, when the frequency of the compressor 2a and the compressor 2b is 40 Hz or more and less than 70 Hz, the superheat control target value on the discharge side of the compressor 2b is set to 30 ° C. For example, when the frequency of the compressor 2a and the compressor 2b is less than 40 Hz, the superheat control target value on the discharge side of the compressor 2b is set to 50 ° C.

  When the outside air temperature decreases, in order to absorb heat from the outside air, it is necessary to reduce the evaporation pressure of the refrigerant flowing through the outdoor heat exchanger 10a and the outdoor heat exchanger 10b that function as an evaporator. At this time, in order to heat the air-conditioned space to a desired temperature, it is necessary to maintain the condensation pressure of the refrigerant flowing through the indoor heat exchanger 71A and the indoor heat exchanger 71B functioning as a condenser. For this reason, it is necessary to increase the capacity (frequency) of the compressor 2a and the compressor 2b. However, when the capacity (frequency) of the compressor 2a and the compressor 2b is increased, the temperature of the refrigerant discharged from the compressor 2b excessively increases. Therefore, in order to maintain reliability, the capacities (frequencies) of the compressor 2a and the compressor 2b cannot be greater than a certain value. For this reason, when the outside air temperature is further lowered, the refrigerant cannot be compressed to a sufficiently high pressure and high temperature state even if the capacities (frequencies) of the compressor 2a and the compressor 2b reach the upper limit of the use range. Therefore, by injecting the refrigerant from the injection circuit 40 into the compression process of the compressor 2 (the pipe 20 connecting the compressor 2a and the compressor 2b), an excessive temperature rise of the refrigerant discharged from the compressor 2b is prevented. However, it is necessary to increase the capacity (frequency) of the compressor 2a and the compressor 2b.

  In the first embodiment, the refrigerant injection amount from the injection circuit 40 to the compressor 2 is controlled by the superheat control target value on the discharge side of the compressor 2b. This injection amount is adjusted by the opening degree of LEV42. For example, the refrigerant injection amount from the injection circuit 40 to the compressor 2 increases as the superheat control target value on the discharge side of the compressor 2b decreases. Thereby, the refrigerant | coolant compression capability of the compressor 2 can be enlarged. For example, the refrigerant injection amount from the injection circuit 40 to the compressor 2 decreases as the superheat control target value on the discharge side of the compressor 2b increases. Thereby, the operating efficiency of the compressor 2 can be improved. In the first embodiment, the frequencies of the compressor 2a and the compressor 2b constituting the compressor 2 are controlled to be the same, but the frequencies of the compressor 2a and the compressor 2b are controlled to different frequencies. Also good.

  Next, an example of a control method in the case where the outdoor heat exchanger is defrosted in the heating operation mode will be described.

FIG. 10 is a flowchart illustrating an example of a control method during the defrosting operation of the air-conditioning apparatus according to Embodiment 1 of the present invention.
When the all heating operation or the heating main operation is started (step S11), the outdoor unit side flow switching unit 30a, the outdoor unit side flow switching unit 30b, the indoor unit side flow switching unit 80A, and the indoor unit side flow switching. The flow path of the part 80B or the like is set as a flow path in the heating only operation mode or the heating main operation mode. For example, in the heating only operation mode, the second electromagnetic valve 32a of the outdoor unit side flow switching unit 30a, the second electromagnetic valve 32b of the outdoor unit side flow switching unit 30b, and the first electromagnetic of the indoor unit side flow switching unit 80A. The valve 81A and the first electromagnetic valve 81B of the indoor unit side flow path switching unit 80B are opened. The electromagnetic valve 7, the first electromagnetic valve 31a of the outdoor unit side flow switching unit 30a, the first electromagnetic valve 31b of the outdoor unit side flow switching unit 30b, the second electromagnetic valve 82A of the indoor unit side flow switching unit 80A, and The second electromagnetic valve 82B of the indoor unit side flow path switching unit 80B is closed. Further, the opening degree of LEV6 is set to fully open, the opening degree of LEV41 is fully closed, and the opening degree of LEV42 is set to an arbitrary opening degree (step S12).

  Immediately after the start of the heating operation (until the refrigerant flow in the refrigerant circuit is stabilized), the refrigerant in the injection circuit 40 is in a low density state. If this low-density refrigerant is injected into the compression process of the compressor 2 (pipe 20 connecting the compressor 2a and the compressor 2b), the temperature of the refrigerant discharged from the compressor 2b will rise excessively. Immediately after the start of the heating operation (until the refrigerant flow in the refrigerant circuit is stabilized), the temperature of the refrigerant discharged from the compressor 2b can be prevented from rising excessively by fully closing the opening of the LEV 41. Further, immediately after the start of the heating operation (until the refrigerant flow in the refrigerant circuit is stabilized), the capacity of the compressor 2 is increased by reducing the pressure of the refrigerant sucked by the compressor 2a by fully opening the opening of the LEV 6. Insufficiency can be prevented.

  In addition, the air volume of the fan 5a and the fan 5b is controlled so that the saturation temperature calculated | required from the detected value of the pressure detection apparatus 51, and the saturation temperature calculated | required from the pressure detection apparatus 52 become a constant value as mentioned above. For example, the capacity (frequency) of the compressor 2a and the compressor 2b and the air volume of the fan 5a and the fan 5b have a saturation temperature obtained from the detected value of the pressure detection device 51 of 50 ° C. and a saturation temperature obtained from the pressure detection device 52. It is controlled to be 0 ° C.

In step S13, it is determined whether or not a predetermined time (for example, 10 minutes) has elapsed since the start of the all heating operation or the heating main operation. If a predetermined time (for example, 10 minutes) has elapsed since the start of the all-heating operation or the main heating operation, the process proceeds to step S14, and the predetermined time (for example, 10 minutes) has elapsed since the start of the total heating operation or the main heating operation. If not, the process returns to step S12.
Note that steps S11 to S13 are the same as steps S1 to S3 during the heating operation (FIG. 9).

  In step S14, it is determined whether the all heating operation or the heating main operation is continued. If the all heating operation or the heating main operation is continued, the process proceeds to step S15, and it is determined whether or not the detection values of the temperature detection device 62a and the temperature detection device 62b are lower than a predetermined temperature (for example, −10 ° C.). If the heating only operation or the heating main operation is not continued, the process proceeds to step S16, and the temperature detection by the temperature detection device 62a and the temperature detection device 62b is not performed.

As described above, in step S15, it is determined whether or not the detection values of the temperature detection device 62a and the temperature detection device 62b are lower than a predetermined temperature (for example, −10 ° C.).
When frost adheres to the outdoor heat exchanger 10a or the outdoor heat exchanger 10b, the heat exchange capacity of the outdoor heat exchanger 10a or the outdoor heat exchanger 10b is reduced. For this reason, the air conditioner 100 reduces the temperature of the refrigerant flowing into the outdoor heat exchanger 10a and the outdoor heat exchanger 10b in order to maintain the heat exchange capability of the outdoor heat exchanger 10a and the outdoor heat exchanger 10b. . In the first embodiment, the temperature of the refrigerant flowing into the outdoor heat exchanger 10a and the outdoor heat exchanger 10b (the detection value of the temperature detection device 62a and the temperature detection device 62b) is lower than a predetermined temperature (for example, −10 ° C.). In this case, it is determined that the amount of frost that needs to be removed has adhered to the outdoor heat exchanger 10a and the outdoor heat exchanger 10b.

  If the detection values of the temperature detection device 62a and the temperature detection device 62b are lower than a predetermined temperature (for example, −10 ° C.) (when it is determined that frost has adhered to the outdoor heat exchanger 10a or the outdoor heat exchanger 10b), step S17. Proceed to Moreover, when the detection value of the temperature detection apparatus 62a and the temperature detection apparatus 62b is more than predetermined temperature (for example, -10 degreeC) (when it is judged that frost adhered to the outdoor heat exchanger 10a or the outdoor heat exchanger 10b, or frost) If it is determined that the heat exchanging capacity of the outdoor heat exchanger 10a or the outdoor heat exchanger 10b can be maintained even if is attached), the process returns to step S14.

  In step S17, the first electromagnetic valve 31b of the outdoor unit side flow path switching unit 30b is opened, and the second electromagnetic valve 32b is closed. Further, the fan 5b is stopped. Thereby, the high-pressure and high-temperature vapor refrigerant discharged from the compressor 2b flows into the outdoor heat exchanger 10b, and the frost attached to the outdoor heat exchanger 10b can be melted (defrosting is performed).

In step S18, it is determined whether or not the detected value of the temperature detecting device 62b is higher than a predetermined temperature (for example, 10 ° C.). As the frost adhering to the outdoor heat exchanger 10b melts, the temperature of the refrigerant flowing out of the outdoor heat exchanger 10b (that is, the temperature of the refrigerant detected by the temperature detection device 62b) increases. In this Embodiment 1, when the detected value of the temperature detection apparatus 62b becomes higher than predetermined temperature (for example, 10 degreeC), it is judged that the defrosting of the outdoor heat exchanger 10b was completed.
When the detection value of the temperature detection device 62b is a predetermined temperature (for example, 10 ° C.) or less, the defrosting operation is continued, and when the detection value of the temperature detection device 62b is higher than the predetermined temperature (for example, 10 ° C.), step S19. Proceed to

  In step S19, the first electromagnetic valve 31b of the outdoor unit side flow path switching unit 30b is closed and the second electromagnetic valve 32b is opened. That is, the flow path is returned so that the outdoor heat exchanger 10b can function as an evaporator. Further, the fan 5b is rotated so as to have a predetermined air volume.

  Subsequently, in order to melt the frost of the outdoor heat exchanger 10a (defrosting is performed), in step S20, the first electromagnetic valve 31a of the outdoor unit side flow path switching unit 30a is opened and the second electromagnetic valve 32a is closed. Further, the fan 5a is stopped. As a result, the high-pressure and high-temperature vapor refrigerant discharged from the compressor 2a flows into the outdoor heat exchanger 10a, and the frost attached to the outdoor heat exchanger 10a can be melted (defrosting is performed).

  In step S21, it is determined whether or not the detection value of the temperature detection device 62a is higher than a predetermined temperature (for example, 10 ° C.). When the detection value of the temperature detection device 62b is a predetermined temperature (for example, 10 ° C.) or less, the defrosting operation is continued. When the detected value of the temperature detector 62b is higher than a predetermined temperature (for example, 10 ° C.), it is determined that the defrosting of the outdoor heat exchanger 10a is completed, and the process proceeds to step S22.

  In step S22, the first electromagnetic valve 31a of the outdoor unit side flow path switching unit 30a is closed and the second electromagnetic valve 32a is opened. That is, the flow path is returned so that the outdoor heat exchanger 10a can function as an evaporator. Further, the fan 5a is rotated so as to have a predetermined air volume. Thereafter, the process returns to step S13.

  In the first embodiment, the outdoor heat exchanger is defrosted sequentially in a predetermined order, but a device for detecting frost formation is provided in the outdoor heat exchanger 10a and the outdoor heat exchanger 10b. The defrosted outdoor heat exchanger may be defrosted. If the defrosting of both the outdoor heat exchanger 10a and the outdoor heat exchanger 10b is not performed at the same time, it is possible to defrost the outdoor heat exchanger while continuing the heating operation.

  In the air conditioner 100 configured as described above, the refrigerant can be injected into the compression process of the compressor 2 (the pipe 20 connecting the compressor 2a and the compressor 2b) via the injection circuit 40. Even at the low outside air temperature, the compressor 2 can compress the refrigerant into a high pressure and high temperature state. Therefore, a sufficient amount of refrigerant can be pumped to the indoor heat exchanger 71A and the indoor heat exchanger 71B that function as a condenser. Therefore, it is possible to obtain an air conditioner 100 that can maintain a desired heating capacity even at a low outside air temperature and can be operated simultaneously with cooling and heating. In the first embodiment, the internal heat exchanger 34 and the LEV 41 are provided in the injection circuit 40. However, even if these are not provided, it is possible to maintain a desired heating capacity even at a low outside air temperature.

  In addition, since the LEV 42 is provided in the injection circuit 40, the amount of refrigerant injected into the compression process of the compressor 2 (the pipe 20 connecting the compressor 2a and the compressor 2b) can be adjusted. For this reason, it is possible to inject an appropriate amount of refrigerant according to the operating conditions of the air conditioner 100.

  Further, since the compressor 2 is composed of a plurality of compressors 2a and 2b, the operation efficiency of the compressor 2 can be controlled by controlling the capacity (frequency) of each compressor to an appropriate capacity (frequency). Can be improved. Note that the number of the compressors 2 is not necessarily two, and can be configured by an arbitrary number of compressors such as three.

  Further, each of the outdoor unit side flow switching unit 30a, the outdoor unit side flow switching unit 30b, the indoor unit side flow switching unit 80A, and the indoor unit side flow switching unit 80B is configured by a two-way valve electromagnetic valve. Therefore, the outdoor unit side flow switching unit 30a, the outdoor unit side flow switching unit 30b, the indoor unit side flow switching unit 80A, and the indoor unit side flow switching unit 80B can be manufactured at low cost.

  In the first embodiment, two indoor units 70A and 70B are provided in the air conditioner 100. However, the number of indoor units provided in the air conditioner 100 is arbitrary. Moreover, although the outdoor unit 1 is provided with the two outdoor heat exchangers 10a and 10b, the number of outdoor heat exchangers is also arbitrary. For example, the outdoor unit 1 may be provided with three outdoor heat exchangers.

Embodiment 2. FIG.
In the second embodiment, operations of the electromagnetic valve 46a of the bypass circuit 45a and the electromagnetic valve 46b of the bypass circuit 45b will be described. In the second embodiment, items that are not particularly described are the same as those in the first embodiment, and the same functions and configurations are described using the same reference numerals.

  As shown in FIG. 1, when the compressor 2 includes a plurality of compressors 2a and 2b, depending on the operating conditions of the air conditioner 100, it is preferable to drive only one of the compressors. 100 operating efficiency may be good.

  For example, when the capacity of the compressor 2 is large, both the compressor 2a and the compressor 2b are driven. For this reason, both the solenoid valve 46a and the solenoid valve 46b are closed so that the refrigerant does not flow into the bypass circuit 45a and the bypass circuit 45b.

  For example, when the refrigerant load of the indoor heat exchanger 71A and the indoor heat exchanger 71B (or either one) is small in the cooling only operation mode or the cooling main operation mode, the pressure of the refrigerant discharged from the compressor 2b (pressure detection device) The pressure detected at 51) can be reduced, and the heat radiation capacity of the outdoor heat exchanger 10a and the outdoor heat exchanger 10b (or either one) can be reduced. That is, the condensation pressure (condensation temperature) of the refrigerant flowing through the outdoor heat exchanger 10a and the outdoor heat exchanger 10b (or one of them) can be reduced. In this case, the driving efficiency of the air conditioner 100 is improved by driving only the efficient compressor 2a with a low compression ratio. Therefore, the solenoid valve 46b is opened, the refrigerant flows through the bypass circuit 45b, and the driving of the compressor 2b is stopped.

  For example, when the heating load of the indoor heat exchanger 71A and the indoor heat exchanger 71B (or one of them) is small in the heating only operation mode or the heating main operation mode, the outdoor heat exchanger 10a and the outdoor heat exchanger 10b (or which one) On the other hand, the endothermic ability can be reduced. That is, the evaporation pressure (evaporation temperature) of the refrigerant flowing in the outdoor heat exchanger 10a and the outdoor heat exchanger 10b (or either one) can be increased. In this case, the driving efficiency of the air conditioner 100 is improved by driving only the efficient compressor 2b with a high compression ratio. Therefore, the electromagnetic valve 46a is opened, the refrigerant flows through the bypass circuit 45a, and the driving of the compressor 2a is stopped.

In the air conditioning apparatus 100 configured as described above, only one of the compressor 2a and the compressor 2b can be driven by opening and closing the electromagnetic valve 46a and the electromagnetic valve 46b. Therefore, the operating efficiency of the air conditioner 100 is improved.
In addition, operation | movement of said electromagnetic valve 46a and electromagnetic valve 46b is an example. In the cooling only operation mode or the cooling main operation mode, the solenoid valve 46a may be opened to allow the refrigerant to flow through the bypass circuit 45a and stop the driving of the compressor 2a. In the all heating operation mode or the heating main operation mode, the solenoid valve 46b may be opened to allow the refrigerant to flow through the bypass circuit 45b, and the drive of the compressor 2b may be stopped.

Embodiment 3 FIG.
In the first embodiment and the second embodiment, the compressor 2 is configured by the two compressors 2a and 2b. However, the compressor 2 may be configured by one compressor. In Embodiment 3, items that are not particularly described are the same as those in Embodiment 1 or Embodiment 2, and the same functions and configurations are described using the same reference numerals.

FIG. 11 is a refrigerant circuit diagram illustrating an example of an air-conditioning apparatus according to Embodiment 3 of the present invention.
The refrigerant circuit of air-conditioning apparatus 100 according to Embodiment 3 is basically the same as the refrigerant circuit of air-conditioning apparatus 100 shown in Embodiment 1. However, in the air-conditioning apparatus 100 according to Embodiment 3, the compressor 2 is configured with a single compressor. An injection circuit 40 is connected to the refrigerant compression process of the compressor 2.

  Even in the air conditioning apparatus 100 configured as described above, since the refrigerant can be injected into the compression process of the compressor 2 via the injection circuit 40, the compressor 2 can supply the refrigerant to the high pressure and high temperature even at a low outside air temperature. Can be compressed to a state. Therefore, a sufficient amount of refrigerant can be pumped to the indoor heat exchanger 71A and the indoor heat exchanger 71B that function as a condenser. Therefore, it is possible to obtain an air conditioner 100 that can maintain a desired heating capacity even at a low outside air temperature and can be operated simultaneously with cooling and heating.

2 is a refrigerant circuit diagram illustrating an example of an air-conditioning apparatus according to Embodiment 1. FIG. 3 is a refrigerant circuit diagram illustrating a refrigerant flow in a heating only operation mode of the air-conditioning apparatus according to Embodiment 1. FIG. 3 is a refrigerant circuit diagram illustrating a refrigerant flow in a heating main operation mode of the air-conditioning apparatus according to Embodiment 1. FIG. FIG. 6 is a refrigerant circuit diagram illustrating an example of another refrigerant flow in the heating main operation mode of the air-conditioning apparatus according to Embodiment 1. 3 is a refrigerant circuit diagram illustrating a refrigerant flow in a cooling only operation mode of the air-conditioning apparatus according to Embodiment 1. FIG. 4 is a refrigerant circuit diagram illustrating a refrigerant flow in a cooling main operation mode of the air-conditioning apparatus according to Embodiment 1. FIG. 2 is a refrigerant circuit diagram illustrating a refrigerant flow in a defrosting operation of the air-conditioning apparatus according to Embodiment 1. FIG. It is a refrigerant circuit figure showing another example of the refrigerant | coolant flow of the defrost operation of the air conditioning apparatus which concerns on Embodiment 1. FIG. It is a flowchart which shows an example of the control method at the time of the heating operation of the air conditioning apparatus which concerns on Embodiment 1 of this invention. 3 is a flowchart illustrating an example of a control method during defrosting operation of the air-conditioning apparatus according to Embodiment 1. 6 is a refrigerant circuit diagram illustrating an example of an air-conditioning apparatus according to Embodiment 3. FIG.

Explanation of symbols

  1 outdoor unit, 2 (2a, 2b) compressor, 5a, 5b fan, 6 LEV, 7 solenoid valve, 10a, 10b outdoor heat exchanger, 11a, 11b connection port, 12a, 12b connection port, 20 piping, 21a piping 21b Branch part, 21c Outdoor unit side branch pipe, 21d Indoor unit side branch pipe, 22a pipe, 22b Branch part, 22c Outdoor unit side branch pipe, 22d Indoor unit side branch pipe, 23a, 23b pipe, 24a, 24b pipe, 24c branch part, 25 pipe, 26 branch part, 27 pipe, 30a, 30b outdoor unit side flow path switching part, 31a, 31b first solenoid valve, 32a, 32b second solenoid valve, 34 internal heat exchanger, 40 injection circuit , 41 LEV, 42 LEV, 45a, 45b Bypass circuit, 46a, 46b Solenoid valve, 51 Pressure detector, 52 Pressure detector Device, 53 pressure detection device, 61 temperature detection device, 62a, 62b temperature detection device, 63 temperature detection device, 70A, 70B indoor unit, 71A, 71B indoor heat exchanger, 72A, 72B fan, 73A, 73B LEV, 74A, 74B temperature detection device, 75A, 75B temperature detection device, 76A, 76B connection port, 77A, 77B connection port, 80A, 80B indoor unit side flow path switching unit, 81A, 81B first solenoid valve, 82A, 82B second solenoid valve 91A, 91B piping, 91C branch, 92 piping, 100 air conditioner.

Claims (7)

A compressor, a plurality of indoor heat exchangers, and a plurality of outdoor heat exchangers;
The refrigerant is connected to one connection port of the outdoor heat exchanger, the discharge port of the compressor, and the suction port of the compressor, and the refrigerant flows from the discharge port of the compressor to one connection port of the outdoor heat exchanger. A plurality of outdoor unit side channel switching units that switch the refrigerant channel to a refrigerant channel or a refrigerant channel through which refrigerant flows from one connection port of the outdoor heat exchanger to the suction port of the compressor;
The refrigerant is connected to one connection port of the indoor heat exchanger, the discharge port of the compressor, and the suction port of the compressor, and the refrigerant flows from the discharge port of the compressor to one connection port of the indoor heat exchanger. A plurality of indoor unit side channel switching units that switch the refrigerant channel to a refrigerant channel or a refrigerant channel through which refrigerant flows from one connection port of the indoor heat exchanger to the suction port of the compressor;
A connection pipe connecting the other connection port of the outdoor heat exchanger and the other connection port of the indoor heat exchanger;
A pressure reducing device provided in the connection pipe;
One end is connected to the connection pipe between the decompression device and the indoor heat exchanger, the other end is connected to the compression process of the compressor, and the refrigerant flowing through the connection pipe is transferred to the compressor An injection circuit that injects into the compression process of
An air conditioner comprising: The indoor unit side flow path switching unit connected to the indoor heat exchanger provided in the air-conditioned space to be cooled is connected to one connection port of the indoor heat exchanger and the suction port of the compressor. Switched to
The indoor unit side flow path switching unit connected to the indoor heat exchanger provided in the conditioned space to be heated is connected to one connection port of the indoor heat exchanger and the discharge port of the compressor. The air conditioner according to claim 1, wherein the air conditioner is switched to.   The air conditioning apparatus according to claim 1 or 2, wherein the injection circuit is provided with an injection circuit flow rate control device that controls a flow rate of the refrigerant flowing through the injection circuit. The compressor is configured by connecting a plurality of compressors in series,
The other end of the injection circuit is
The air conditioner according to any one of claims 1 to 3, wherein the air conditioner is connected to a connection pipe that connects the plurality of compressors. At least one of the plurality of compressors includes
A bypass circuit connecting the suction side piping and the discharge side piping of the compressor;
A bypass circuit switching device for opening and closing the bypass circuit;
The air conditioning apparatus according to claim 4, further comprising: The outdoor unit side flow path switching unit is
A first outdoor unit side opening / closing device connected to a discharge port of the compressor and opening and closing a refrigerant flow path through which the refrigerant flows from the discharge port of the compressor to one connection port of the outdoor heat exchanger;
A second outdoor unit side opening / closing device connected to the suction port of the compressor and opening and closing a refrigerant flow path through which the refrigerant flows from one connection port of the outdoor heat exchanger to the suction port of the compressor;
The air conditioner according to any one of claims 1 to 5, further comprising: The indoor unit side flow path switching unit is
A first indoor unit side opening / closing device that is connected to a discharge port of the compressor and opens and closes a refrigerant flow path through which the refrigerant flows from the discharge port of the compressor to one connection port of the indoor heat exchanger;
A second indoor unit side opening / closing device connected to the suction port of the compressor and opening and closing a refrigerant flow path through which the refrigerant flows from one connection port of the indoor heat exchanger to the suction port of the compressor;
The air conditioning apparatus according to any one of claims 1 to 6, further comprising:

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