JP7471465B2 - Air Conditioning Equipment - Google Patents

Description

The present disclosure relates to an air conditioning device having two heat source side circuits in one indoor unit.

Conventionally, air conditioners are known in which one indoor unit is equipped with two heat source circuits. Patent Document 1 discloses such an air conditioner in which two heat exchangers and two fans are housed in one housing, and air that has been heat exchanged in each heat exchanger is blown out of two air outlets by each fan.

JP 2003-83272 A

The air conditioning device disclosed in Patent Document 1 sends out conditioned air to spaces where no indoor users are present. As a result, the air conditioning device of Patent Document 1 wastes electricity for air conditioning in spaces where no users are present.

This disclosure has been made to solve the problems described above, and aims to reduce power consumption in an air conditioning device equipped with two heat source side circuits in one indoor unit.

The air conditioning apparatus according to the present disclosure includes a housing, a first heat exchanger provided within the housing, a second heat exchanger provided within the housing , a third heat exchanger provided within the housing, a fourth heat exchanger provided within the housing, a first fan provided within the housing and sending air to the first heat exchanger, a second fan provided within the housing and sending air to the second heat exchanger, a third fan provided within the housing and sending air to the third heat exchanger, a fourth fan provided within the housing and sending air to the fourth heat exchanger, and a cooling fan for cooling the first heat exchanger, the second heat exchanger, and a cooling fan for cooling the first heat exchanger, the second heat exchanger, and a cooling fan for cooling the second heat exchanger . a control valve that controls the flow of refrigerant to the heat exchanger , the third heat exchanger, and the fourth heat exchanger, and a control device that controls the control valve, the first fan , the second fan , the third fan, and the fourth fan , and the housing has a first suction port formed on a side surface through which air sent to the first heat exchanger passes, a second suction port formed on the side surface through which air sent to the second heat exchanger passes, a third suction port formed on the side surface through which air sent to the third heat exchanger passes, and a fourth suction port formed on the side surface through which air sent to the fourth heat exchanger passes. the control device has a first air outlet formed on the underside and blowing out air that has been heat exchanged by the first heat exchanger, a second air outlet formed on the underside and blowing out air that has been heat exchanged by the second heat exchanger , a third air outlet formed on the underside and blowing out air that has been heat exchanged by the third heat exchanger, and a fourth air outlet formed on the underside and blowing out air that has been heat exchanged by the fourth heat exchanger, and the control device sets a first area corresponding to the first air outlet, a second area corresponding to the second air outlet, a third area corresponding to the third air outlet, and a fourth area corresponding to the fourth air outlet in the air-conditioned space, detects the presence of a person in each of the first area, the second area, the third area, and the fourth area, and controls the control valve, the first fan, the second fan , the third fan, and the fourth fan so as to air-condition the first area and blow air in the second area , the third area, and the fourth area when the control device detects the presence of a person in the first area but not the presence of a person in the second area , the third area, and the fourth area .

The air conditioning device of the present disclosure conditions air in a first area where people are present, and blows air in a second area where no people are present. Therefore, unnecessary air conditioning is not performed in the second area, reducing power consumption. Also, the conditioned air blown into the first area is prevented from flowing toward the second area by the air blown into the unoccupied area. Therefore, air conditioning is concentrated in the first area, and the temperature set by the user can be efficiently maintained, reducing power consumption. As described above, according to the present disclosure, it is possible to reduce power consumption in an air conditioning device equipped with two heat source side circuits in one indoor unit.

1 is a circuit diagram showing an air conditioning device 1 according to a first embodiment. 1 is a schematic cross-sectional view showing an indoor unit 3 of an air conditioning apparatus 1 pertaining to Embodiment 1. FIG. FIG. 2 is a diagram for explaining the arrangement of an air-conditioned space and an air-conditioning device 1 according to the first embodiment. FIG. 2 is a functional block diagram showing a control device 21 according to the first embodiment. 1 is a diagram for explaining the air conditioning action of the air conditioner 1 according to the first embodiment. FIG. 4 is a flowchart showing an operation of a control device 21 according to the first embodiment. FIG. 11 is a circuit diagram showing an air conditioning device 101 according to a second embodiment. FIG. 11 is a perspective view showing an indoor unit 103 of an air conditioning apparatus 101 pertaining to embodiment 2. FIG. 11 is a diagram for explaining the internal configuration of an air conditioning device 101 according to a second embodiment. FIG. 11 is a functional block diagram showing a control device 131 according to a second embodiment.

Embodiment 1.
An air conditioner 1 according to the first embodiment will be described below with reference to the drawings. Various specific setting examples described in this embodiment are merely examples, and the present invention is not limited to the described setting examples. Fig. 1 is a circuit diagram showing an air conditioner 1 according to the first embodiment. As shown in Fig. 1, the air conditioner 1 has an outdoor unit 2, an indoor unit 3, and a refrigerant pipe 4.

As shown in FIG. 1, the outdoor unit 2 has a compressor 5, a flow switching valve 6, an outdoor heat exchanger 7, an outdoor fan 8, and an expansion valve 9. The indoor unit 3 has a first heat exchanger 10, a second heat exchanger 11, a first fan 12, a second fan 13, a first control valve 14, and a second control valve 15. The refrigerant piping 4 is a piping that connects the compressor 5, the flow switching valve 6, the outdoor heat exchanger 7, the expansion valve 9, the first heat exchanger 10, the second heat exchanger 11, the first control valve 14, and the second control valve 15, and through which the refrigerant flows. The refrigerant piping 4 and each device connected to the refrigerant piping 4 form a refrigerant circuit. The refrigerant circuit has a load side circuit of the outdoor unit 2, and a heat source side circuit that branches into the first heat exchanger 10 side and the second heat exchanger 11 side of the indoor unit 3. That is, the indoor unit 3 is formed with two heat source side circuits.

The compressor 5 draws in a low-temperature, low-pressure refrigerant, compresses it, and discharges it as a high-temperature, high-pressure refrigerant. The flow path switching valve 6 switches the flow direction of the refrigerant in the refrigerant circuit, and is, for example, a four-way valve. The outdoor heat exchanger 7 exchanges heat between the refrigerant and the outdoor air, and is, for example, a fin-and-tube type heat exchanger. The outdoor heat exchanger 7 acts as a condenser during cooling operation and as an evaporator during heating operation. The outdoor fan 8 is a device that sends outdoor air to the outdoor heat exchanger 7. The expansion valve 9 reduces the pressure of the refrigerant to expand it, and is, for example, an electronic expansion valve.

The first heat exchanger 10 and the second heat exchanger 11 are indoor heat exchangers that exchange heat between indoor air and refrigerant. The first heat exchanger 10 and the second heat exchanger 11 act as evaporators during cooling operation and as condensers during heating operation. The first fan 12 is a device that sends indoor air to the first heat exchanger 10, and is, for example, a cross-flow fan. The second fan 13 is a device that sends indoor air to the second heat exchanger 11, and is, for example, a cross-flow fan.

The first control valve 14 and the second control valve 15 are three-way valves having three ports (not shown). The first control valve 14 and the second control valve 15 control the flow of refrigerant to the first heat exchanger 10 and the second heat exchanger 11 by switching the open/closed state of the ports. The ports of the first control valve 14 are connected to the flow path switching valve 6, the first heat exchanger 10, and the second heat exchanger 11. The ports of the second control valve 15 are connected to the expansion valve 9, the first heat exchanger 10, and the second heat exchanger 11. In addition, the open/closed states of the ports of the first control valve 14 and the second control valve 15 can be in a first mode, a second mode, and a third mode.

The first mode is a mode in which refrigerant flows only through the first heat exchanger 10, and does not flow through the second heat exchanger 11. In the first mode, the first control valve 14 opens the port on the flow path switching valve 6 side, opens the port on the first heat exchanger 10 side, and closes the port on the second heat exchanger 11 side. The second control valve 15 also opens the port on the expansion valve 9 side, opens the port on the first heat exchanger 10 side, and closes the port on the second heat exchanger 11 side.

The second mode is a mode in which refrigerant does not flow through the first heat exchanger 10, but only flows through the second heat exchanger 11. In the second mode, the first control valve 14 opens the port on the flow path switching valve 6 side, closes the port on the first heat exchanger 10 side, and opens the port on the second heat exchanger 11 side. In addition, the second control valve 15 opens the port on the expansion valve 9 side, closes the port on the first heat exchanger 10 side, and opens the port on the second heat exchanger 11 side.

The third mode is a mode in which refrigerant flows through both the first heat exchanger 10 and the second heat exchanger 11. In the third mode, the first control valve 14 opens all of its ports. The second control valve 15 also opens all of its ports.

Here, the operation of the air conditioning device 1 will be described. First, the cooling operation when the first control valve 14 and the second control valve 15 are in the first mode will be described. The air conditioning device 1 performs cooling operation by switching the flow path switching valve 6 so that the discharge side of the compressor 5 and the outdoor heat exchanger 7 are connected. In cooling operation, the refrigerant sucked into the compressor 5 is compressed by the compressor 5 and discharged in a high-temperature, high-pressure gas state. The high-temperature, high-pressure gas state refrigerant discharged from the compressor 5 passes through the flow path switching valve 6 and flows into the outdoor heat exchanger 7 acting as a condenser. The refrigerant that flows into the outdoor heat exchanger 7 is heat exchanged with the outdoor air sent by the outdoor fan 8, condensed, and liquefied. The liquid state refrigerant flows into the expansion valve 9, where it is decompressed and expanded to become a low-temperature, low-pressure gas-liquid two-phase refrigerant. The gas-liquid two-phase refrigerant flows into the first heat exchanger 10 acting as an evaporator. The refrigerant that has flowed into the first heat exchanger 10 exchanges heat with the indoor air sent by the first fan 12, evaporates, and gasifies. At that time, the indoor air is cooled, and cooling is performed in the room. The evaporated refrigerant in a low-temperature, low-pressure gas state then passes through the flow path switching valve 6 and is sucked into the compressor 5.

Next, the cooling operation when the first control valve 14 and the second control valve 15 are in the second mode will be described. In this case, the flow of the refrigerant discharged from the compressor 5 until it passes through the flow path switching valve 6, the outdoor unit 2 heat exchanger, and the expansion valve 9 is the same as in the first mode. The refrigerant in a gas-liquid two-phase state that passes through the expansion valve 9 flows into the second heat exchanger 11 that acts as an evaporator. The refrigerant that flows into the second heat exchanger 11 exchanges heat with the indoor air sent by the second fan 13, evaporates, and gasifies. At that time, the indoor air is cooled to perform cooling in the room. The evaporated low-temperature, low-pressure gaseous refrigerant then passes through the flow path switching valve 6 and is sucked into the compressor 5.

Next, the cooling operation when the first control valve 14 and the second control valve 15 are in the third mode will be described. In this case, the flow of the refrigerant discharged from the compressor 5 until it passes through the flow path switching valve 6, the outdoor unit 2 heat exchanger, and the expansion valve 9 is the same as in the first and second modes. The refrigerant in a gas-liquid two-phase state that passes through the expansion valve 9 flows into the first heat exchanger 10 and the second heat exchanger 11 that act as evaporators. The refrigerant that flows into the first heat exchanger 10 is heat exchanged with the indoor air sent by the first fan 12, and is evaporated and gasified. In addition, the refrigerant that flows into the second heat exchanger 11 is heat exchanged with the indoor air sent by the second fan 13, and is evaporated and gasified. At that time, the indoor air is cooled to perform cooling in the room. The evaporated low-temperature and low-pressure gas state refrigerant then passes through the flow path switching valve 6 and is sucked into the compressor 5.

In addition, the heating operation when the first control valve 14 and the second control valve 15 are in the first mode will be described. The air conditioning device 1 performs heating operation by switching the flow path switching valve 6 so that the discharge side of the compressor 5 and the first heat exchanger 10 are connected. In heating operation, the refrigerant sucked into the compressor 5 is compressed by the compressor 5 and discharged in a high-temperature, high-pressure gas state. The high-temperature, high-pressure gas state refrigerant discharged from the compressor 5 passes through the flow path switching valve 6 and flows into the first heat exchanger 10 acting as a condenser. The refrigerant that flows into the first heat exchanger 10 exchanges heat with the indoor air sent by the first fan 12, condenses, and liquefies. At that time, the indoor air is warmed, and heating is performed in the room. The liquid state refrigerant flows into the expansion valve 9, where it is decompressed and expanded to become a low-temperature, low-pressure gas-liquid two-phase refrigerant. The gas-liquid two-phase refrigerant flows into the outdoor heat exchanger 7 acting as an evaporator. The refrigerant that has flowed into the outdoor heat exchanger 7 evaporates and gasifies through heat exchange with outdoor air sent by the outdoor fan 8. The evaporated refrigerant in a low-temperature, low-pressure gas state then passes through the flow path switching valve 6 and is sucked into the compressor 5.

Next, the heating operation when the first control valve 14 and the second control valve 15 are in the second mode will be described. In this case, in the heating operation, the refrigerant sucked into the compressor 5 is compressed by the compressor 5 and discharged in a high-temperature, high-pressure gas state. The high-temperature, high-pressure gas state refrigerant discharged from the compressor 5 passes through the flow path switching valve 6 and flows into the second heat exchanger 11 acting as a condenser. The refrigerant that flows into the second heat exchanger 11 exchanges heat with the indoor air sent by the second fan 13, condenses, and liquefies. At that time, the indoor air is warmed, and heating is performed in the room. After that, the flow of the liquid state refrigerant that has passed through the second heat exchanger 11 passes through the expansion valve 9, the evaporator, and the outdoor heat exchanger 7 until it is sucked into the compressor 5 is the same as in the first mode.

Next, the heating operation when the first control valve 14 and the second control valve 15 are in the third mode will be described. In this case, in the heating operation, the refrigerant sucked into the compressor 5 is compressed by the compressor 5 and discharged in a high-temperature and high-pressure gas state. The high-temperature and high-pressure gas state refrigerant discharged from the compressor 5 passes through the flow path switching valve 6 and flows into the first heat exchanger 10 and the second heat exchanger 11 acting as condensers. The refrigerant that flows into the first heat exchanger 10 exchanges heat with the indoor air sent by the first fan 12, condenses, and liquefies. In addition, the refrigerant that flows into the second heat exchanger 11 exchanges heat with the indoor air sent by the second fan 13, condenses, and liquefies. At that time, the indoor air is warmed, and heating is performed in the room. After that, the flow of the liquid state refrigerant that has passed through the first heat exchanger 10 and the second heat exchanger 11 passes through the expansion valve 9, the evaporator, and the outdoor heat exchanger 7 until it is sucked into the compressor 5 is the same as in the first and second modes.

The air conditioning device 1 also has a control device 21, a first temperature detection device 22, a second temperature detection device 23, and an infrared sensor 24. The control device 21 controls the operation of the entire air conditioning device 1 including the indoor unit 3 and the outdoor unit 2 based on setting information such as the target temperature, air volume, and air direction of the air conditioning received from a remote controller (not shown), as well as various information received from each part of the indoor unit 3 and the outdoor unit 2. The first temperature detection device 22 and the second temperature detection device 23 are non-contact temperature sensors that detect the temperature of the space. The infrared sensor 24 is a sensor that detects infrared rays in the space. The first temperature detection device 22, the second temperature detection device 23, and the infrared sensor 24 are wirelessly connected to the control device 21 so as to be able to communicate with the control device 21. A detailed description of the control device 21, the first temperature detection device 22, the second temperature detection device 23, and the infrared sensor 24 will be described later.

Figure 2 is a schematic cross-sectional view showing the indoor unit 3 of the air conditioning device 1 according to embodiment 1. Although not shown, the indoor unit 3 has a generally rectangular parallelepiped shape overall. The indoor unit 3 is installed by hanging or embedding it in the ceiling of the room that is the space to be air-conditioned. Figure 2 shows a cross section of the indoor unit 3 in the installed state cut in the vertical direction. As shown in Figure 2, the indoor unit 3 has a housing 30, a first heat exchanger 10, a second heat exchanger 11, a first fan 12, and a second fan 13. The housing 30 has an external casing 31, a first internal casing 32, a second internal casing 33, a partition 34, a first air deflector 35, and a second air deflector 36.

The external casing 31 constitutes the outer shell of the outdoor unit 2. The external casing 31 is formed with a first suction port 41, a second suction port 42, a first air outlet 43, and a second air outlet 44. The first suction port 41 is formed on one side of the external casing 31 and is an opening that draws in indoor air. The second air inlet 42 is formed on the other side opposite the one side of the external casing 31 and is an opening that draws in indoor air. The first air outlet 43 is formed on the lower surface of the external casing 31 and is an opening that blows out air that has been heat exchanged by the first heat exchanger 10. The second air outlet 44 is formed on the lower surface of the external casing 31 and is an opening that blows out air that has been heat exchanged by the second heat exchanger 11. The second air outlet 44 is formed separately from the first air outlet 43.

The first internal casing 32 is provided inside the external casing 31 and is located above the first fan 12. The surface of the first internal casing 32 facing the first fan 12 is curved. The space surrounded by the external casing 31 and the first internal casing 32 and communicating from the first suction port 41 to the first blowing port 43 becomes the first air passage 51. The second internal casing 33 is provided inside the external casing 31 and is located above the second fan 13. The surface of the second internal casing 33 facing the second fan 13 is curved. The space surrounded by the external casing 31 and the second internal casing 33 and communicating from the second suction port 42 to the second blowing port 44 becomes the second air passage 52. The partition 34 is provided between the first air passage 51 and the second air passage 52. The partition 34 divides the inside of the housing 30 so that the air flowing through the first air passage 51 and the air flowing through the second air passage 52 do not interfere with each other. The partition 34 is plate-shaped and has approximately the same shape as the side surface of the housing 30.

The first heat exchanger 10 is disposed in the first air passage 51 at an angle to one side surface on which the first air outlet 43 is formed. The second heat exchanger 11 is disposed in the second air passage 52 at an angle to the other side surface on which the second air outlet 44 is formed. The first fan 12 is disposed downstream of the first heat exchanger 10 in the first air passage 51. The first fan 12 is, for example, a cross-flow fan, and is placed horizontally so that its rotation axis is approximately horizontal. The second fan 13 is disposed downstream of the second heat exchanger 11 in the second air passage 52. The second fan 13 is placed horizontally so that its rotation axis is approximately horizontal.

The housing 30 has a plurality of first air deflectors 35 and a plurality of second air deflectors 36. The plurality of first air deflectors 35 are arranged to cover the first air outlet 43 when the air conditioning device 1 is stopped. The plurality of first air deflectors 35 rotate vertically while the air conditioning device 1 is operating, adjusting the direction of the air blown out from the first air outlet 43. The plurality of second air deflectors 36 are arranged to cover the second air outlet 44 when the air conditioning device 1 is stopped. The plurality of second air deflectors 36 rotate vertically while the air conditioning device 1 is operating, adjusting the direction of the air blown out from the second air outlet 44.

Here, the air flow in the indoor unit 3 of the air conditioning device 1 will be explained. Here, an example will be explained in which the first control valve 14 and the second control valve 15 are in the third mode. First, air drawn in from the first suction port 41 by the rotation of the first fan 12 passes through the first heat exchanger 10 for heat exchange. The heat-exchanged air is sent indoors from the first outlet 43. In addition, air drawn in from the second suction port 42 by the rotation of the second fan 13 passes through the second heat exchanger 11 for heat exchange. The heat-exchanged air is sent indoors from the second outlet 44. The indoor unit 3 draws in air from the side of the housing 30 and blows it out downward, suppressing short cycles.

3 is a diagram for explaining the arrangement of the air-conditioned space and the air-conditioning device 1 according to the first embodiment. FIG. 3 is a schematic diagram showing a top view of a room in which the indoor unit 3 is provided, which is the air-conditioned space. The indoor unit 3 of the air-conditioning device is installed approximately in the center of the room. The control device 21 is stored inside the housing 30 of the indoor unit 3. The memory device 25 (FIG. 4) in the control device 21 stores in advance a setting that the area in which air conditioning is performed by the air blown out from the first air outlet 43, that is, the area on one side of the air-conditioned space where the first air outlet 43 is formed, is the first area. The memory device 25 also stores in advance a setting that the area in which air conditioning is performed by the air blown out from the second air outlet 44, that is, the area on the other side of the air-conditioned space where the second air outlet 44 is formed, is the second area. In other words, when the air-conditioning device 1 is installed in the room, the first area and the second area in the room are determined. In FIG. 3, of the two areas obtained by dividing the room, area A1 corresponds to the first area and area A2 corresponds to the second area.

The first temperature detection device 22 is provided on a wall surface of the first area and detects the temperature of the first area. The first temperature detection device 22 transmits temperature information of the first area detected by the first temperature detection device 22 to the control device 21. The second temperature detection device 23 is provided on a wall surface of the second area and detects the temperature of the second area. The second temperature detection device 23 transmits temperature information of the second area detected by the second temperature detection device 23 to the control device 21. The infrared sensor 24 is provided in the housing 30 of the indoor unit 3 and detects infrared rays throughout the entire space to be air-conditioned and transmits the detection results to the control device 21.

(Configuration of control device 21)
The control device 21 controls the operating frequency of the compressor 5, the rotation speeds of the outdoor fan 8, the first fan 12, and the second fan 13, and the open/closed states of the ports of the first control valve 14 and the second control valve 15. The control device 21 is composed of dedicated hardware or a CPU (also called a central processing unit, processing device, arithmetic device, microprocessor, microcomputer, or processor) that executes a program stored in the storage device 25. When the control device 21 is dedicated hardware, the control device 21 corresponds to, for example, a single circuit, a composite circuit, an ASIC (Application Specific Integrated Circuit), an FPGA (Field-Programmable Gate Array), or a combination of these. Each of the functional units realized by the control device 21 may be realized by individual hardware, or each functional unit may be realized by one piece of hardware.

When the control device 21 is a CPU, each functional unit executed by the control device 21 is realized by software, firmware, or a combination of software and firmware. The software and firmware are written as programs and stored in the storage device 25. The CPU realizes each function by reading and executing the programs stored in the storage device 25. Here, the storage device 25 is, for example, a non-volatile or volatile semiconductor memory such as RAM, ROM, flash memory, EPROM, EEPROM, etc. It is also possible to realize some of the functions of the control device 21 by dedicated hardware and some by software or firmware.

Figure 4 is a functional block diagram showing the control device 21 according to embodiment 1. As shown in Figure 4, the control device 21 has, as functional units, an area setting unit 61, a temperature receiving unit 62, a thermal image creating unit 63, an occupancy determining unit 64, and an air conditioning control unit 65.

The area setting unit 61 stores in the storage device 25 the setting that the first temperature detection device 22 is installed in the first area. The area setting unit 61 also stores in the storage device 25 the setting that the second temperature detection device 23 is installed in the second area. In other words, the area setting unit 61 sets the correspondence between the first temperature detection device 22 and the first area, and the correspondence between the second temperature detection device 23 and the second area. The area setting by the area setting unit 61 is performed when the placement of at least one of the indoor unit 3, the first temperature detection device 22, or the second temperature detection device 23 of the air conditioning device 1 is changed. The timing of the implementation in this case is instructed by the user or installer via a remote controller or the like.

The temperature receiving unit 62 receives temperature information of the first area from the first temperature detection device 22. The temperature receiving unit 62 also receives temperature information of the second area from the second temperature detection device 23.

The thermal image creation unit 63 creates a thermal image of the room from the infrared detection results received from the infrared sensor 24. The process for creating the thermal image may be a conventional process.

The occupancy determination unit 64 calculates coordinate ranges corresponding to the first area and the second area for the thermal image created by the thermal image creation unit 63, and detects people in each coordinate range. The process for detecting people may be a conventionally known process. The occupancy determination unit 64 sets an area where a person is detected as a occupancy area, and determines an area where a person is not detected as an absence area.

When at least one of the first area and the second area is set as a resident area, the air conditioning control unit 65 controls each device to condition the air in the resident area based on the setting information set by the user and to blow air in the unoccupied area.

Specifically, when the first area is an occupied area and the second area is an unoccupied area, the first control valve 14 and the second control valve 15 are controlled to switch to the first mode in which refrigerant flows only through the first heat exchanger 10. Also, the operating frequency of the compressor 5 and the rotation speed of the outdoor fan 8 are adjusted to control the amount of refrigerant flowing through the first heat exchanger 10 so that the temperature of the first area becomes the temperature set by the user. Then, both the first fan 12 and the second fan 13 are operated and the first air deflector 35 is rotated to achieve the set air volume and direction. Also, the second air deflector 36 is maintained at a predetermined opening degree.

Furthermore, when the first area is an unoccupied area and the second area is an occupied area, the first control valve 14 and the second control valve 15 are controlled to switch to the second mode in which refrigerant flows only to the second heat exchanger 11 side. Furthermore, the operating frequency of the compressor 5 and the rotation speed of the outdoor fan 8 are adjusted to control the amount of refrigerant flowing to the second heat exchanger 11 so that the temperature of the second area becomes the temperature set by the user. Then, both the first fan 12 and the second fan 13 are operated and the second wind deflector 36 is rotated so as to achieve the set air volume and direction. Furthermore, the first wind deflector 35 is maintained at a predetermined opening degree.

In addition, when both the first area and the second area are occupied areas, the first control valve 14 and the second control valve 15 are controlled to switch to the third mode in which refrigerant flows through both the first heat exchanger 10 and the second heat exchanger 11. In addition, the operating frequency of the compressor 5 and the rotation speed of the outdoor fan 8 are adjusted to control the capacity of the refrigerant flowing through the first heat exchanger 10 and the second heat exchanger 11 so that the temperatures of the first area and the second area become the temperature set by the user. Then, both the first fan 12 and the second fan 13 are operated, and the first air deflector 35 and the second air deflector 36 are rotated to achieve the set air volume and direction.

In addition, the air conditioning control unit 65 stops operation of the air conditioning unit 1 when both the first area and the second area are vacant areas.

Figure 5 is a diagram for explaining the air conditioning action of the air conditioning device 1 according to embodiment 1. For the purpose of explanation, each of the first airflow direction vane 35 and the second airflow direction vane 36 is shown enlarged. Also, an example is shown in which the first area A1 is an occupied area and the second area A2 is an unoccupied area. Also, the opening degree of the first airflow direction vane 35 is indicated by θv1 with 0° in the closed state as the reference. The opening degree of the second airflow direction vane 36 is indicated by θv2 with 0° in the closed state as the reference. Also, the air flow is indicated by arrows.

The air conditioning control unit 65 rotates the first air deflector 35 in a range where the opening angle θv1 is 0° to 90°. That is, the first air deflector 35 rotates so that the direction of the air blown out is toward the first area. The air conditioning control unit 65 also causes the second air deflector 36 to maintain a predetermined opening angle of the opening angle θv2 between 0° and 90°. For example, in FIG. 5, the opening angle of the second air deflector 36 is about 80°. That is, the second air deflector 36 maintains the opening angle so that the direction of the air blown out from the second air outlet 44 is away from the first area. As shown in FIG. 5, the conditioned air blown out from the first air outlet 43 to the first area is prevented from flowing to the second area by the air blown out to the non-occupied area. As a result, air conditioning is concentrated in the first area, which is the occupied area, and the temperature set by the user can be efficiently maintained.

(Operation of control device 21)
Here, the operation of the control device 21 will be described. FIG. 6 is a flowchart showing the operation of the control device 21 according to the first embodiment. First, the thermal image creation unit 63 creates a thermal image of the room from the infrared sensor 24 (S1). Next, the occupancy determination unit 64 detects people in each area and sets the occupied area and the unoccupied area (S2). Then, the air conditioning control unit 65 determines whether the first area and the second area of the air conditioned space are occupied areas (S3). If there is an occupied area (S3: YES), the air conditioning control unit 65 controls each device to perform air conditioning in the occupied area and to blow air in the unoccupied area (S4). If all the air conditioned spaces are unoccupied areas (S3: NO), the air conditioning control unit 65 stops the operation of the air conditioning device 1 (S5). The above processing is repeatedly executed at a predetermined cycle during the operation of the air conditioning device 1.

In the first embodiment, the air conditioning device 1 conditions the air in the first area where people are present, and blows air in the second area where no one is present. Therefore, unnecessary temperature control is not performed in the second area, and power consumption is reduced. In addition, the conditioned air blown into the first area is prevented from flowing to the second area by the air blown into the unoccupied area. Therefore, air conditioning is concentrated in the first area, and the temperature set by the user can be efficiently maintained, thereby reducing power consumption. As described above, according to the first embodiment, power consumption can be reduced in the air conditioning device 1 in which one indoor unit 3 is equipped with two heat source side circuits.

Furthermore, according to this embodiment, the housing 30 has a partition 34 provided between the first air passage 51 and the second air passage 52. This prevents the air flowing through the first air passage 51 and the second air passage 52 from interfering with each other, and prevents the force of the air blown out from the first air outlet 43 and the second air outlet 44 from decreasing.

Furthermore, according to this embodiment, the first air outlet 43 and the second air outlet 44 are formed on the underside of the housing 30. Therefore, the air conditioning device 1 can provide a larger area for air conditioning compared to a case in which the first air outlet 43 and the second air outlet 44 are formed on the side of the housing 30, thereby improving the comfort of the user.

Embodiment 2.
Fig. 7 is a circuit diagram showing an air-conditioning apparatus 101 according to embodiment 2. As shown in Fig. 7, embodiment 2 differs from embodiment 1 in that the indoor unit 103 is equipped with four heat source side circuits. In embodiment 2, the same parts as those in embodiment 1 are given the same reference numerals and their explanations are omitted, and the explanation will focus on the differences from embodiment 1.

As shown in FIG. 7, the indoor unit 103 of the air conditioning device 101 has a first heat exchanger 111, a second heat exchanger 112, a third heat exchanger 113, and a fourth heat exchanger 114 as indoor heat exchangers. A heat source side circuit that branches into the first heat exchanger 111 side, the second heat exchanger 112 side, the third heat exchanger 113 side, and the fourth heat exchanger 114 side of the indoor unit 103 is connected to the load side circuit of the outdoor unit 2. That is, the indoor unit 103 is provided with four heat source side circuits. The indoor unit 103 also has a first fan 115, a second fan 116, a third fan 117, and a fourth fan 118. The first fan 115 is a device that sends air to the first heat exchanger 111. The second fan 116 is a device that sends air to the second heat exchanger 112. The third fan 117 is a device that sends air to the third heat exchanger 113. The fourth fan 118 is a device that sends air to the fourth heat exchanger 114.

Furthermore, the indoor unit 103 has a first control valve 121, a second control valve 122, a third control valve 123, a fourth control valve 124, a fifth control valve 125, and a sixth control valve 126. The first control valve 121, the second control valve 122, the third control valve 123, the fourth control valve 124, the fifth control valve 125, and the sixth control valve 126 are three-way valves. The flow of refrigerant to the first heat exchanger 111, the second heat exchanger 112, the third heat exchanger 113, and the fourth heat exchanger 114 is controlled by a combination of the open/closed states of the ports of the first control valve 121, the second control valve 122, the third control valve 123, the fourth control valve 124, the fifth control valve 125, and the sixth control valve 126.

The port of the first control valve 121 is connected to the flow path switching valve 6, the first heat exchanger 111, and the third control valve 123. The port of the second control valve 122 is connected to the expansion valve 9, the first heat exchanger 111, and the fourth control valve 124. The port of the third control valve 123 is connected to the second heat exchanger 112, the first control valve 121, and the fifth control valve 125. The port of the fourth control valve 124 is connected to the second heat exchanger 112, the second control valve 122, and the sixth control valve 126. The port of the fifth control valve 125 is connected to the third heat exchanger 113, the fourth heat exchanger 114, and the third control valve 123. The port of the sixth control valve 126 is connected to the third heat exchanger 113, the fourth heat exchanger 114, and the fourth control valve 124.

Figure 8 is a perspective view showing the indoor unit 103 of the air conditioning apparatus 101 according to embodiment 2. As shown in Figure 8, the housing 140 of the indoor unit 103 has a flattened cylindrical shape. A first intake port 161, a second intake port 162, a third intake port (not shown), and a fourth intake port (not shown) are formed on the side of the housing 140 of the indoor unit 103. In addition, a first outlet 165, a second outlet 166, a third outlet 167, and a fourth outlet 168 are formed on the underside of the housing 140 of the indoor unit 103.

As in the first embodiment, the memory device 25 prestores a setting that the area where air conditioning is performed by the air blown out from the first air outlet 165, i.e., the area corresponding to the first air outlet 165 in the air-conditioned space, is the first area. The memory device 25 also prestores a setting that the area where air conditioning is performed by the air blown out from the second air outlet 166, i.e., the area corresponding to the second air outlet 166 in the air-conditioned space, is the second area. The memory device 25 also prestores a setting that the area where air conditioning is performed by the air blown out from the third air outlet 167, i.e., the area corresponding to the third air outlet 167 in the air-conditioned space, is the third area. The memory device 25 also prestores a setting that the area where air conditioning is performed by the air blown out from the fourth air outlet 168, i.e., the area corresponding to the fourth air outlet 168 in the air-conditioned space, is the fourth area.

Returning to Figure 7, the indoor unit 103 of the air conditioning apparatus 101 has a first temperature detection device 132, a second temperature detection device 133, a third temperature detection device 134, a fourth temperature detection device 135, and an infrared sensor 24. The first temperature detection device 132 detects the temperature in the first area and transmits the temperature information to the control device 131. The second temperature detection device 133 detects the temperature in the second area and transmits the temperature information to the control device 131. The third temperature detection device 134 detects the temperature in the third area and transmits the temperature information to the control device 131. The fourth temperature detection device 135 detects the temperature in the fourth area and transmits the temperature information to the control device 131. The infrared sensor 24 detects infrared rays from the entire space to be air-conditioned.

9 is a diagram for explaining the internal configuration of the air conditioning device 101 according to the second embodiment. In FIG. 9, only the portion in which the first air outlet 165 of the indoor unit 103 is formed is shown. The space surrounded by the housing 140 and communicating from the first air inlet 161 to the first air outlet 165 is the first air duct 171. Here, the first air duct 171 is used as an example for explanation, but the configurations of the second air duct (not shown), the third air duct (not shown), and the fourth air duct (not shown) are also similar to the first air duct 171. The first air inlet 161 is formed on the side of the housing 140. The first air outlet 165 is formed on the lower surface of the external casing 31. The first fan 115 is, for example, a cross-flow fan, and is placed horizontally with respect to the housing 140 so that the rotation axis is approximately horizontal. The housing 140 also has four partitions 141. The four partitions 141 divide the inside of the housing 140 so that the air flowing through the first air passage 171, the second air passage, the third air passage, and the fourth air passage does not interfere with each other.

(Configuration of control device 131)
FIG. 10 is a functional block diagram showing the control device 131 according to the second embodiment. Each functional unit of the control device 131 is common to that of the first embodiment, except that it corresponds to four areas, the first area, the second area, the third area, and the fourth area. That is, the area setting unit 181 sets the correspondence between the first temperature detection device 132, the second temperature detection device 133, the third temperature detection device 134, and the fourth temperature detection device 135 and each area. The temperature receiving unit 182 acquires temperature information of the first area, the second area, the third area, and the fourth area from the first temperature detection device 132, the second temperature detection device 133, the third temperature detection device 134, and the fourth temperature detection device 135. The thermal image creating unit 183 creates a thermal image of the entire air-conditioned space. The presence determining unit 184 determines whether the first area, the second area, the third area, and the fourth area are a presence area or an absence area based on the detection result of the infrared rays received from the infrared sensor 24. Then, when at least one of the first area, second area, third area, and fourth area is set as an occupied area, the air conditioning control unit 185 controls each device to perform air conditioning in the occupied area and to blow air in the unoccupied area.

For example, when the first area is a resident area and the second, third, and fourth areas are unoccupied areas, the first control valve 121 opens the port on the flow path switching valve 6 side, opens the port on the first heat exchanger 111 side, and closes the port on the third control valve 123 side. The second control valve 122 opens the port on the expansion valve 9 side, opens the port on the first heat exchanger 111 side, and closes the port on the fourth control valve 124 side. The third control valve 123, the fourth control valve 124, the fifth control valve 125, and the sixth control valve 126 close all of their ports. The operating frequency of the compressor 5 and the rotation speed of the outdoor fan 8 are also adjusted to control the volume of refrigerant circulating in the first heat exchanger 111. Then, the first fan 115, the second fan 116, the third fan 117, and the fourth fan 118 are operated and the first air deflector 151 is rotated so as to achieve the set air volume and direction. Also, the second air deflector 152, the third air deflector 153, and the fourth air deflector 154 are maintained at a predetermined opening degree. As a result, the refrigerant flows only on the first heat exchanger 111 side, and air conditioning is performed only in the first area. Also, air is blown in the second area, the third area, and the fourth area.

Even in cases other than those exemplified above, the control device 131 controls each control valve so that refrigerant flows only through the indoor heat exchanger corresponding to the area set as the occupied area, and refrigerant flow is blocked to the indoor heat exchanger corresponding to the area set as the unoccupied area.

According to the second embodiment, the air conditioning device 101 divides the room into four areas, and performs air conditioning in the occupied areas based on the setting information set by the user, and sends air to the unoccupied areas. Therefore, compared to the air conditioning device 101 in the first embodiment, the air conditioning device 101 in the second embodiment can further limit the area in the air-conditioned space where air conditioning is concentrated. Therefore, according to the second embodiment, it is possible to further reduce the power consumption in the air conditioning device 101 in which multiple heat source side circuits are provided in a single housing 140.

The above is an explanation of the embodiment, but the present disclosure is not limited to the above embodiment, and various modifications are possible without departing from the spirit of the present disclosure. For example, in the first embodiment, the first control valve 14 and the second control valve 15 are three-way valves, but a combination of four-way valves or two-way valves may be used to achieve the same function.

In addition, the first temperature detection device 22 and the second temperature detection device 23 in the first embodiment may be installed at different locations and in different numbers, as long as they can detect the temperature of each area individually. For example, the first temperature detection device 22 and the second temperature detection device 23 may be provided in the housing 30 of the indoor unit 3. The temperature inside the room may be detected by a thermal image created based on infrared rays detected by the infrared sensor 24. A mobile terminal such as a smartphone or a device such as a PC carried by the user may be wirelessly connected to the control device 21 so as to communicate with the mobile terminal or the PC, etc., and the temperature detected by the mobile terminal or the PC may be obtained. In this case, the first temperature detection device 22 and the second temperature detection device 23 may be omitted.

In addition, the infrared sensor 24 in the first embodiment may not only acquire infrared rays from the space to be air-conditioned, but also have a function for creating a thermal image. In this case, the thermal image creation unit 63 of the control device 21 may be omitted.

In addition, the occupancy determination unit 64 in the first embodiment may determine whether an area is occupied or unoccupied based on the presence or absence or the strength of a signal received from a device such as a mobile terminal or a PC, rather than a thermal image. In this case, the infrared sensor 24 may be omitted.

In addition, in the first embodiment, wireless communication may be performed in one section and wired communication may be performed in another section. Also, communication from one device to another device may be performed by wired communication, and communication from another device to one device may be performed by wireless communication.

In the first embodiment, the timing of the area setting by the area setting unit 61 is instructed by a user or an installer via a remote controller or the like. As a modified example, the area setting unit 61 may be automatically set upon detecting a change in the relative positional relationship with the first temperature detection device 22 or the second temperature detection device 23 based on a change in the strength of the signals received from the first temperature detection device 22 and the second temperature detection device 23.

In addition, in embodiment 1, if all areas are determined to be vacant areas, the operation of the air conditioning device 1 is stopped, but it is also possible to blow air in all areas.

In addition, in the first embodiment, the shape of the housing 30 and the arrangement of the air inlets and air outlets may be appropriately changed from the configuration disclosed as the embodiment. For example, the first air inlet 41 and the second air inlet 42 may be formed on the bottom surface of the housing 30, and the first air outlet 43 and the second air outlet 44 may be formed on the side surface of the housing 30.

In addition, in the first embodiment, the air volume in the unoccupied area is set by the user, but the air volume in the unoccupied area may be set to be greater than the air volume in the occupied area. In this case, it is possible to more reliably prevent the conditioned air blown into the occupied area from flowing into the unoccupied area due to the air blown into the unoccupied area.

In addition, in embodiment 1, the opening angle θv2 of the second air deflector 36 in the unoccupied area was approximately 80°, but the opening angle θv2 can be maintained anywhere in the range of 0° to 90° so that the air blown out from the second air outlet 44 is directed away from the first area. For example, by setting the opening angle θv2 to 90°, the air blown out from the second air outlet 44 is directed directly below the air conditioning device 1. In this case, the momentum of the air blown out from the second air outlet 44 is unlikely to weaken before it comes into contact with the air blown out from the first air outlet 43, so that the flow of air from the first area to the second area can be further suppressed.

In addition, in the first and second embodiments, the airflow direction vanes in the occupied area are controlled to rotate, but it is also possible to maintain a predetermined opening degree. Furthermore, as long as each airflow direction vane is provided so that the direction of the air blown out of the corresponding air outlet is directed away from areas other than the corresponding area, it is also possible for the vanes to be provided with a fixed orientation on the housing and the rotating function to be omitted.

Furthermore, the open/closed state of each control valve is not limited to that disclosed in embodiments 1 and 2, so long as refrigerant flows only through the indoor heat exchanger corresponding to the area determined to be a resident area and the flow of refrigerant to the indoor heat exchanger corresponding to the area determined to be an unoccupied area is blocked. Furthermore, in embodiments 1 and 2, some of the control valves may be omitted, so long as refrigerant flows only through the indoor heat exchanger corresponding to the area determined to be a resident area and the flow of refrigerant to the indoor heat exchanger corresponding to the area determined to be an unoccupied area is blocked.

1 Air conditioning device, 2 Outdoor unit, 3 Indoor unit, 4 Refrigerant piping, 5 Compressor, 6 Flow path switching valve, 7 Outdoor heat exchanger, 8 Outdoor fan, 9 Expansion valve, 10 First heat exchanger, 11 Second heat exchanger, 12 First fan, 13 Second fan, 14 First control valve, 15 Second control valve, 21 Control device, 22 First temperature detection device, 23 Second temperature detection device, 24 Infrared sensor, 25 Storage device, 30 Housing, 31 External casing, 32 First internal casing, 33 Second internal casing, 34 Partition, 35 First wind direction plate, 36 Second wind direction plate, 41 First intake port, 42 Second intake port, 43 First air outlet, 44 Second air outlet, 51 First air duct, 52 Second air duct, 61 Area setting unit, 62 Temperature receiving unit, 63 Thermal image creation unit, 64 Occupancy determination unit, 65 Air conditioning control unit, 101 Air conditioning device, 103 Indoor unit, 111 First heat exchanger, 112 Second heat exchanger, 113 Third heat exchanger, 114 Fourth heat exchanger, 115 First fan, 116 Second fan, 117 Third fan, 118 Fourth fan, 121 First control valve, 122 Second control valve, 123 Third control valve, 124 Fourth control valve, 125 Fifth control valve, 126 Sixth control valve, 131 Control device, 132 First temperature detection device, 133 Second temperature detection device, 134 Third temperature detection device, 135 Fourth temperature detection device, 140 Housing, 141 Partition, 151 First wind deflector, 152 Second wind deflector, 153 Third wind deflector, 154 Fourth wind deflector, 161 First air inlet, 162 Second intake port, 165 first outlet, 166 second outlet, 167 third outlet, 168 fourth outlet, 171 first air duct, 181 area setting section, 182 temperature receiving section, 183 thermal image creating section, 184 occupancy determining section, 185 air conditioning control section.

Claims (6)

A housing and
A first heat exchanger provided in the housing;
A second heat exchanger provided within the housing;
A third heat exchanger provided within the housing;
A fourth heat exchanger provided in the housing;
a first fan provided in the housing and configured to send air to the first heat exchanger;
a second fan provided in the housing and configured to send air to the second heat exchanger;
a third fan provided in the housing and configured to send air to the third heat exchanger;
a fourth fan provided in the housing and configured to send air to the fourth heat exchanger;
a control valve that controls the flow of refrigerant to the first heat exchanger , the second heat exchanger , the third heat exchanger, and the fourth heat exchanger ;
a control device that controls the control valve, the first fan , the second fan , the third fan, and the fourth fan,
The housing includes:
a first intake port formed on a side surface through which air to be sent to the first heat exchanger passes;
a second intake port formed on the side surface through which air to be sent to the second heat exchanger passes;
a third intake port formed on the side surface through which air to be sent to the third heat exchanger passes;
a fourth intake port formed on the side surface through which air to be sent to the fourth heat exchanger passes;
a first air outlet formed on a lower surface thereof and configured to blow out air that has been heat exchanged by the first heat exchanger;
a second air outlet formed on the lower surface and configured to blow out air that has been heat exchanged by the second heat exchanger;
a third air outlet formed on the lower surface and configured to blow out air that has been heat exchanged by the third heat exchanger;
a fourth air outlet formed on the lower surface and blowing out air that has been heat exchanged by the fourth heat exchanger,
The control device includes:
an air conditioning device that sets, in a space to be air-conditioned, a first area corresponding to the first air outlet, a second area corresponding to the second air outlet, a third area corresponding to the third air outlet, and a fourth area corresponding to the fourth air outlet, detects the presence of people in each of the first area, the second area, the third area, and the fourth area, and when it detects the presence of a person in the first area but not the second area , the third area, or the fourth area, controls the control valve, the first fan, the second fan , the third fan, and the fourth fan so as to perform air conditioning in the first area and to blow air in the second area, the third area, and the fourth area . The control device includes:
2. The air conditioning apparatus of claim 1, wherein when the presence of a person is detected in the first area but not in the second area, the control valve is controlled to allow refrigerant to flow through the first heat exchanger and the first fan is operated, and the control valve is controlled to block the flow of refrigerant to the second heat exchanger and the second fan is operated. The housing includes:
a first air passage in which the first fan is disposed;
a second air passage in which the second fan is disposed;
The air conditioning apparatus according to claim 1 or 2, further comprising a partition provided between the first air passage and the second air passage. A first airflow direction plate that adjusts the direction of air blown out from the first air outlet;
A second airflow direction plate that adjusts the direction of air blown out from the second air outlet,
The control device includes:
The air conditioning apparatus according to any one of claims 1 to 3, wherein when the presence of a person is detected in the first area and the presence of a person is not detected in the second area, the second air deflector is controlled so that the direction of air blown out of the second air outlet is directed away from the first area. Further comprising an infrared sensor for detecting infrared rays in the space to be air-conditioned,
The control device includes:
The air conditioning apparatus according to any one of claims 1 to 4, wherein the infrared sensor is used to detect the presence of a person in each of the first area and the second area. Further comprising a temperature detection device that detects the temperature of the air-conditioned space,
The control device includes:
The air conditioning apparatus according to any one of claims 1 to 5, wherein the control valve, the first fan, and the second fan are controlled so that the first area and the second area each reach a target temperature.

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