JP2016200311A - Air Conditioning System - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress uneven indoor temperature distribution in an air conditioning system in which a plurality of indoor units including human detection sensors are disposed in the same indoor space.SOLUTION: In an air conditioning system, a plurality of indoor units 30 including human detection sensors 10 are disposed in the same indoor space 2a, and the plurality of indoor units are connected to an outdoor unit through a refrigerant pipe. Each indoor unit is constituted to individually control louvers 20a-20h disposed on a plurality of supply ports for changing wind direction on the basis of information detected by the human detection sensors, and the human detection sensor information by each area detected by the human detection sensors is shared by the indoor units. In an overlapping detection area where the presence of a human 70 in the same area is detected by the plurality of human detection sensors, air is distributed by directing the louver of the predetermined indoor unit to the direction of the human detected in the overlapping detection area, and the louvers of the other indoor units distribute the air in directions different from the direction of the human.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an air conditioning system in which a plurality of indoor units (air conditioners) are installed in the same indoor space, and more particularly to a system in which each indoor unit includes a human sensor.

  Japanese Unexamined Patent Application Publication No. 2012-149858 (Patent Document 1) discloses a plurality of indoor units provided with human sensors in the same indoor space.

  In this patent document 1, the presence / absence of a person in a space to be air-conditioned or the amount of activity of a person is detected by the human sensor, and an air-conditioning load is determined based on the detection information, and power saving control is performed. Control is performed.

  In addition, there is a unit in which a single indoor unit provided with a human sensor detects a person with the human sensor and blows air toward the detected person to perform comfortable control.

JP 2012-149858 A

  When multiple indoor units are installed in the same indoor space to blow air toward the person detected by the motion sensor, each of the motion sensors of the plurality of indoor units detects a person in the same area. The air may be blown toward the detected person. That is, the louver is controlled in each indoor unit for the overlap detection area when the human sensor of a plurality of indoor units detects a person in the same area, and the wind is directed toward the person in the same area. However, there is a problem that temperature unevenness (indoor temperature distribution unevenness) is likely to occur between places where the air is concentrated, such as the upper and lower portions of the overlap detection area, and places where the air is not blown or reduced.

  An object of the present invention is to obtain an air conditioning system capable of suppressing occurrence of uneven indoor temperature distribution in a case where a plurality of indoor units including human sensors are installed in the same indoor space. .

  In order to achieve the above object, the present invention provides an air conditioning system in which a plurality of indoor units including human sensors are installed in the same indoor space, and the plurality of indoor units are connected to an outdoor unit via a refrigerant pipe. The indoor sensor provided in each indoor unit is a human sensor capable of detecting the presence of a person in a plurality of areas, and each indoor unit includes a plurality of louvers for changing the wind direction. An air outlet is provided, and each of the indoor units is configured to individually control the wind direction changing louvers provided in the plurality of air outlets based on information detected by the human sensor. The human sensor information for each area detected by the human sensor of each indoor unit is shared by each indoor unit and provided in each of the indoor units. For overlap detection areas where the presence of a person in the same area is detected by a plurality of human sensors, the direction of the person detected in the overlap detection area for a predetermined indoor unit louver among the corresponding indoor units The louvers of other indoor units corresponding to the overlap detection area are configured to blow in a direction different from the direction of the person detected in the overlap detection area. It is characterized by.

  Another feature of the present invention is an air conditioning system in which a plurality of indoor units including human sensors are installed in the same indoor space, and the plurality of indoor units are connected to an outdoor unit through a refrigerant pipe. The human sensor provided in each indoor unit is a human sensor capable of detecting the presence of a person in a plurality of areas, and each indoor unit has a plurality of air outlets provided with louvers for changing the wind direction. Each indoor unit is configured to individually control the louvers for changing the wind direction provided in the plurality of air outlets based on information detected by the human sensor, The human sensor information for each area detected by the human sensor of the unit is shared by each indoor unit, and a plurality of human sensors provided in each of the indoor units are provided. For the overlap detection area where the presence of a person in the same area is detected, the louvers of the corresponding indoor units are blown so that the air detected air does not directly hit the person detected in the overlap detection area. The direction is controlled, and the corresponding louvers of the plurality of indoor units are configured to blow in different directions.

  ADVANTAGE OF THE INVENTION According to this invention, in the thing in which the indoor unit provided with the human sensitive sensor is installed in two or more in the same indoor space, the air conditioning system which can suppress generation | occurrence | production of indoor temperature distribution nonuniformity can be obtained. effective.

BRIEF DESCRIPTION OF THE DRAWINGS The schematic block diagram explaining Example 1 of the air conditioning system of this invention. The bottom view which shows the structure of the one indoor unit shown in FIG. FIG. 2 is a diagram for explaining a problem that occurs when a plurality of indoor units including human sensors are installed in the same indoor space, corresponding to FIG. 1.

  Hereinafter, specific examples of the air conditioning system of the present invention will be described with reference to the drawings. In addition, the part which attached | subjected the same code | symbol in each figure has shown the part which is the same or it corresponds.

A first embodiment of an air conditioning system of the present invention will be described with reference to FIGS.
FIG. 1 is a schematic diagram illustrating a first embodiment of an air conditioning system according to the present invention.

  The air conditioning system 1 shown in FIG. 1 shows a state during cooling operation, and the air conditioning system 1 has a plurality of (three in this example) indoor units in the room 2, that is, in the same indoor space 2a. (Air conditioner) 30 (30a, 30b, 30c) is configured to be air-conditioned. The plurality of indoor units are installed on the ceiling of the room 2 as shown in FIG. In addition, an outdoor unit 40 including a compressor, an outdoor heat exchanger, and the like is installed outdoors, and the outdoor unit 40 and the plurality of indoor units 30 are connected by a refrigerant pipe (not shown), Constitutes a cycle.

  Each of the indoor units 30 (30a, 30b, 30c) includes a human sensor 10 (10a, 10b, 10c) that can detect the presence and activity of a person, and a plurality of louvers that can control the wind direction in an arbitrary direction. 20 (20a, 20b, 20e, 20f, 20g, 20h).

  The indoor units 30 shown in FIG. 1 have the same structure, and the indoor units 30 and the outdoor units 40 are connected to each other via an indoor / outdoor signal transmission line 50. In this example, the indoor units 30 A remote controller 60 is connected to 30a. The operation of the outdoor unit 40 and the indoor units 30a to 30c is controlled based on the ON / OFF by the remote controller 60, the operation mode such as cooling or heating, the set temperature, etc. set by the remote controller 60. It is configured.

  Each indoor unit 30 is provided with an indoor control device (not shown), and the louver, indoor fan (not shown), and indoor expansion valve (not shown) provided in each indoor unit 30. ) And so on. The indoor fan is controlled by the indoor control device based on information set by the remote controller 60, and the indoor expansion valve is detected by a suction temperature sensor (not shown) provided on the suction side of each indoor unit 30. The indoor control device controls the temperature information and the set temperature set by the remote controller 60. Note that a remote control may be connected to the indoor unit 30b or the indoor unit 30c to control each indoor unit 30 individually.

The outdoor unit 40 is provided with an outdoor control unit (not shown), and is configured to control the capacity of a compressor (not shown) according to the air conditioning load of the air conditioning target space.
The indoor control unit of each indoor unit 30 and the outdoor control unit of the outdoor unit 40 are connected to each other via the indoor / outdoor signal transmission line 50.

  Next, the structure of one of the plurality of indoor units 30 shown in FIG. 1 will be described in detail with reference to FIG. The other indoor units 30b and 30c have the same configuration.

  2 is a bottom view showing the configuration of one indoor unit 30a shown in FIG. 1. In FIG. 2, 3 is a suction port provided at the center of the bottom surface of the indoor unit 30a, 4 (4a, 4b, 4c, 4d). Is a blower outlet provided in four directions on the lower surface of the indoor unit 30a. Each of these blower outlets 4 is provided with a louver 20 (20a, 20b, 20c, 20d) for controlling the blown direction of the conditioned air. .

  The indoor unit 30a includes a human sensor 10a that can detect the presence of a person in a plurality of areas. In other words, the human sensor 10a is composed of four human sensor elements so that a person in the human detection area 11 (11a, 11b, 11c, 11d) in the four directions shown in FIG. 2 can be detected. Based on the signal from the human sensor 10a, the indoor control device provided in the indoor unit 30a uses the louver 20 (for changing the wind direction) provided in each of the plurality of outlets 4 (4a to 4d). 20a to 20d) are individually controlled.

  For example, when a person enters the person detection area 11a and the presence of the person is detected by the human sensor 10a, the indoor control device controls the louver 20a and air-conditions toward the person detected from the outlet 4a. It is controlled so that air is blown out.

  More specifically, the human sensor 10a detects the amount of activity of the person, identifies the area where the person exists, controls the wind direction changing louvers 20 (20a to 20d) corresponding to the area, and the wind direction The direction is changed, and the conditioned air is blown out in the direction in which a person exists.

  For example, if the person is in the human detection area 11a when the wind detection mode is set with the remote control, the human sensor 10 detects the person in the human detection area 11a and sets the wind direction angle of the louver 20a to the lower side. Can wind the detected person.

  In addition, it is also possible to control not to directly apply the conditioned air to the person detected by the human sensor 10a, but to directly blow the conditioned air to the person detected by the human sensor 10a. is there.

  A problem that occurs when a plurality of indoor units 30 having human sensors shown in FIG. 2 are installed in the same indoor space will be described with reference to FIG. 3. FIG. 3 is a diagram corresponding to FIG. 1 described above, and the same or corresponding parts as in FIG.

  The air conditioning system 1 in FIG. 3 is also configured so that the same indoor space 2 a can be air-conditioned by three indoor units 30 (30 a to 30 c), and the three indoor units are installed on the ceiling of the room 2. Has been. Each of the indoor units 30 (30a to 30c) includes a human sensor 10 (10a to 10c) and a plurality of louvers 20 (20a, 20b, 20e to 20h) capable of controlling the wind direction in an arbitrary direction. Is provided.

  Each indoor unit 30 includes a human sensor 10 that can detect the presence of a person in a plurality of areas. Based on the signal from the human sensor 10, the indoor control device provided in each indoor unit 30 has the louver 20 for changing the wind direction provided in each of the plurality of air outlets 4 (see FIG. 2). It is configured to be controlled individually.

  For this reason, as shown in FIG. 3, when a plurality of indoor units 30a to 30c are installed so as to air-condition the same room 2a, the presence of the same person 70 in the same room 2a is represented by a plurality of indoor units 30 (this In the example, the human sensors 10 (30a and 30b) (in this example, 10a and 10b) are individually detected. For this reason, since the corresponding louvers 20b and 20e of the corresponding indoor units 30a and 30b are controlled to blow air toward the detected person, there is temperature distribution unevenness in the upper and lower parts of the area where the person is present. It is easy to generate. In addition, about the other louvers 20a and 20f-20h, since it does not detect that there is a person in the corresponding area by the human sensor 10, each is controlled to arbitrary directions.

  More specifically, in FIG. 3, the human detection area 11a is detected only by the human sensor 10a, and the human detection area 11h is detected only by the human sensor 10c. The human detection area 11b to be detected and the human detection area 11e detected by the human sensor 10b are overlapped detection areas 11A that overlap each other. Further, the human detection area 11f detected by the human sensor 10b and the human detection area 11g detected by the human sensor 10c are also overlapping detection areas 11B.

  When the human sensor 10 of each indoor unit 30 individually detects a person in the overlap detection area 11A or 11B, the corresponding louver 20 of each corresponding indoor unit 30 individually blows air toward the person. Because it is controlled, the amount of air flow in the direction of the person increases, uneven temperature distribution occurs at the upper and lower parts of the overlap detection area, and excessive air is blown toward the person, which may cause discomfort. .

  For example, when a plurality of indoor units 30a and 30b enters a duplication detection area 11A during cooling operation, the human sensor 10a installed in the indoor unit 30a and the human sensor 10b installed in the indoor unit 30b. Detects the person 70, and the angles of the louvers 20b and 20e are changed to the direction toward the person. For this reason, in the overlap detection area 11A, the cold spreads only in the direction in which the lower person is present and the temperature is lowered, but since the cold is not blown out on the upper part, the temperature is increased and uneven temperature distribution is generated.

  An embodiment of the present invention for solving this problem will be described with reference to FIG. In the present embodiment, the human sensor information for each area detected by the human sensor 10 of each indoor unit 30 is shared by each indoor unit 30, and a plurality of human sensors provided in each indoor unit 30 are provided. 10, for the overlap detection areas 11 </ b> A and 11 </ b> B in which the presence of a person in the same area is detected, the louver 20 of a predetermined indoor unit among the corresponding indoor units 30 is controlled to detect in the overlap detection area. The other indoor unit 30 corresponding to the duplication detection area is configured not to blow air in the direction of the person detected in the duplication detection area.

  As described above, in this embodiment, the sensor information for each area detected by each indoor unit 30 is shared by the other indoor units 30, and the presence of people in the same area is detected by human sensors of the plurality of indoor units 30. By controlling the corresponding plurality of indoor units 30 in conjunction with the detected overlapping detection area, the angle of the corresponding plurality of louvers is adjusted to a direction different from the direction of the person and the direction of the person. In addition, the occurrence of uneven temperature distribution is suppressed and comfort is improved.

The interlock control of the indoor unit 30 in the air conditioning system 1 that is operated in the air blowing mode that blows air toward the person 70 detected by the human sensor 10 will be described with reference to FIG.
Each of the plurality of indoor units 30 (30a, 30b, 30c) has a machine number setting (address setting) for recognizing each indoor unit, and the direction of each louver 20 provided in each indoor unit 30 In addition, numbers (codes) that identify the detection directions (human detection areas 11 a, 11 b, 11 e, 11 f, 11 g, and 11 h) in each human sensor 10 are assigned, and these pieces of information are stored in the remote controller 60. This information is shared by the indoor control device of each indoor unit 30 via the indoor / outdoor signal transmission line 50, and each indoor control device has an overlap detection area where duplication is detected by the human sensors 10 of the plurality of indoor units 30. , And the information detected by each human sensor 10 is shared by each indoor control device, so that it is possible to control the overlapping detection area so that the wind direction does not overlap, and temperature unevenness can be eliminated. .

  For example, when a switch for setting an indoor unit number (address) is mounted on the control board (indoor control device) of each indoor unit 30a, 30b, 30c, the indoor unit number is set by the switch. Then, the remote controller 60 is made to recognize the unit number via the indoor / outdoor signal transmission line 50 connecting the indoor unit 30 and the outdoor unit 40. Next, a machine number corresponding to each indoor unit 30 (30a-30c) is selected from the remote controller 60, and each element (four-direction human detection area) of each human sensor 10 (10a-10c) of each indoor unit 30 is selected. Numbers are assigned to the four human sensor elements corresponding to.

  As a result, the remote controller 60 stores the number of each indoor unit 30 and the number of each element of each human sensor 10, and based on this, the human sensor 10 of each indoor unit 30 is identified. Whether the detection areas overlap, that is, the overlap detection area is recognized by the indoor control device of each indoor unit 30.

  Specifically, first, the unit number of the indoor unit 30a is selected from the remote controller 60, and the overlap detection area 11A (the human detection area 11b detected by the human sensor 10a and the human sensor is detected for the indoor unit 30a. The number of the other indoor unit 30b having the human detection area 11e detected in 10b) and the human detection for detecting the overlap detection area 11A (human detection area 11e) in the human sensor 10b of the indoor unit 30b. Enter the sensor element number to make it recognized.

  Similarly, for the indoor units 30b and 30c, the number of the other indoor units 30b and 30c having the overlap detection area 11B and the overlap detection area 11B (in the human sensors 10b and 10c of the indoor units 30b and 30c) The number of the human sensor element that detects the human detection areas 11f and 11g) is input and recognized.

  Further, when it is detected that there is a person in the overlap detection areas 11A and 11B, the louver 20 of any of the corresponding indoor units 30 is blown toward the detected person ( It is stored in advance in each of the indoor control devices so that it blows out in a direction (for example, a horizontal direction) different from the direction of the person to the louvers of other indoor units.

  For example, as shown in FIG. 1, when a plurality of indoor units 30 are installed side by side, a person who is detected using the louver 20e of the indoor unit 30b as the air blowing mode for the overlap detection area 11A. The louver 20b of the indoor unit 30a is controlled so as not to be applied to a person, that is, in a direction different from the detected direction of the person (more horizontal in the example of FIG. 1). As previously determined. The other louvers 20a and 20f to 20h corresponding to the areas where the presence of the person is not detected by the human sensor 10 are controlled in arbitrary directions.

  For the duplication detection area 11B, the louver 20g of the indoor unit 30c is controlled to blow air toward the detected person with the louver 20g as the air blowing mode, and the louver 20f of the indoor unit 30b is not directed to the person. That is, it is determined in advance that the air is blown in a direction different from the detected direction of the person.

  It should be noted that it is possible to arbitrarily set which louver is directed to the person with respect to the overlap detection areas 11A and 11B, and move the louvers 20b and 20f of the indoor units 30a and 30b to the direction in which the person is present. You may set so that the louvers 20e and 20g of 30c may face in another direction. If the louver angle directed in the direction in which the person is present is, for example, the lower direction, the interlock control is performed so that the louver angle directed in the other direction is set, for example, in the upper direction (a direction close to horizontal). This is the same for both cooling and heating.

  As described above, in this embodiment, the indoor control device of each indoor unit 30 recognizes the overlap detection areas 11A and 11B, shares the human sensor information of each indoor unit 30, and prevents the wind direction directions from overlapping. As a result, the temperature distribution unevenness in the overlap detection area can be suppressed.

  The operation of this embodiment will be described in detail. When a person 70 enters the overlap detection area 11A of the indoor units 30a and 30b, the human sensor 10a installed in the indoor unit 30a and the indoor unit 30b are installed. The human sensor 10b detects the person 70. Information of the human sensor 10a is transmitted to the indoor control device (the microcomputer of the control board) of the indoor unit 30b via the indoor / outdoor signal transmission line 50. Similarly, the information of the human sensor 10b is also transmitted to the indoor control device of the indoor unit 30a. Since the signal is transmitted through the indoor / outdoor signal transmission line 50, each indoor control device can share the detection information of each human sensor.

  As a result, the indoor units 30a and 30b can detect and recognize that there is a person 70 in the overlap detection area 11A (11b, 11e) of both indoor units 30a and 30b. The angle of the louver 20e of the unit 30b is controlled in a direction toward the person (downward direction, for example, an angle range of 52 ° to 64 ° with respect to the horizontal direction), and the louver 20b of the indoor unit 30a is, for example, in the upper direction (for example, The angle is controlled in the direction of an angle range of 28 ° to 40 ° with respect to the horizontal direction.

  As a result, the louver 20e of the indoor unit 30b spreads the cold air in the direction in which the lower person exists, and the louver 20b of the indoor unit 30a further spreads the cold air to the upper portion of the indoor 2a. Temperature unevenness can be eliminated, and comfort can be improved.

  In addition, although the said Example demonstrated the case where it was the wind address mode which ventilates toward the detected person, the mode (non-wind) which suppresses that the air detected air hits the person detected with the human sensor 10 directly. The present invention can be similarly implemented when operating in the addressing mode.

  That is, a plurality of corresponding indoor units louvers are overlapped with respect to an overlapping detection area in which the presence of a person in the same area is detected by the plurality of human sensors 10 provided in each of the indoor units 30. It is also possible to control the blowing direction so that the air detected air does not directly hit the person detected in the detection area, and the corresponding louvers of the plurality of indoor units can be configured to blow in different directions.

  For example, for a louver that controls the blowing direction so that air conditioned air does not directly hit a person detected in the overlap detection area, the blowing direction is set to the upper direction (for example, an angle of 28 ° to 40 ° with respect to the horizontal direction). The other louvers of the plurality of indoor units corresponding to the direction of the range are not directly exposed to the detected person, and the louver is directed in the upper direction and the air flow thereof. Interlock control is performed so that the direction is set to the middle direction (for example, the direction in the angle range of 40 ° to 52 ° with respect to the horizontal direction) so that the directions are not the same. If comprised in this way, temperature distribution nonuniformity can be eliminated and the comfort can be improved, preventing that air-conditioning air hits a person directly.

  In addition, this invention is not limited to an above-described Example, Various modifications are included. For example, in the above-described embodiment, an example in which the number of indoor units is three has been described. However, the present invention can be similarly applied even when there are two or more indoor units.

The above-described embodiments have been described in detail for easy understanding of the present invention, and are not necessarily limited to those having all the configurations described. Furthermore, it is possible to add, delete, and replace other configurations for a part of the configuration.
Information such as a program for realizing each function, each determination value (threshold value), each measurement value, and each set time is stored in a memory, a hard disk, a recording device such as an SSD (Solid State Drive), or an IC card, SD. It can be placed on a recording medium such as a card or DVD.
In addition, the functions of a plurality of calculation means may be combined into one calculation means, and a plurality of or all of the calculation means may be configured by a single microcomputer.

1: air conditioning system, 2: room, 2a: indoor space,
3: Suction port, 4 (4a-4d): Air outlet,
10 (10a to 10c): human sensor,
11a, 11b, 11e to 11h: human detection area, 11A, 11B: overlap detection area,
20 (20a-20h): louver,
30 (30a-30c): indoor unit, 40: outdoor unit,
50: indoor / outdoor signal transmission line, 60: remote control, 70: human.

Claims (8)

In an air conditioning system in which a plurality of indoor units equipped with human sensors are installed in the same indoor space, and the plurality of indoor units are connected to an outdoor unit via a refrigerant pipe,
The human sensor provided in each indoor unit is a human sensor capable of detecting the presence of a person for a plurality of areas,
Each indoor unit is provided with a plurality of air outlets including louvers for changing the wind direction,
Each of the indoor units is configured to individually control the louvers for changing the wind direction provided in the plurality of air outlets based on information detected by the human sensor,
Each indoor unit shares human sensor information for each area detected by the human sensor of each indoor unit,
For overlapping detection areas where the presence of a person in the same area is detected by a plurality of human sensors provided in each of the indoor units, a predetermined indoor unit louver among the corresponding indoor units is used. Control to blow toward the direction of the person detected in the overlap detection area,
The louver of another indoor unit corresponding to the overlap detection area is configured to blow air in a direction different from the direction of the person detected in the overlap detection area.   2. The air conditioning system according to claim 1, wherein each of the indoor units and the outdoor unit is connected via an indoor / outdoor signal transmission line, and the human sensor information detected by the human sensor of each of the indoor units is used. The air conditioning system is configured such that each indoor unit is shared by using the indoor / outdoor signal transmission line.   3. The air conditioning system according to claim 2, wherein each of the indoor units includes an indoor control device, the outdoor unit includes an outdoor control device, and the indoor control device and the indoor control device transmit the indoor / outdoor signal transmission. The air conditioning system is characterized in that the human sensor information of each indoor unit is connected via a wire and is shared by each indoor control device of each indoor unit using the indoor / outdoor signal transmission line.   4. The air conditioning system according to claim 3, wherein each indoor unit is set with a machine number (address setting) for recognizing each indoor unit, and the direction of each louver provided in each indoor unit and each A code indicating the detection direction of the human sensor is assigned, and this information is shared by the indoor control devices of each indoor unit, and each indoor control device detects duplicates by human sensors of a plurality of indoor units. Recognizing the area and sharing the information detected by each human sensor with each indoor control device to control the louver corresponding to the overlap detection area so that the wind direction does not overlap the overlap detection area Air conditioning system characterized by   4. The air conditioning system according to claim 3, wherein when it is detected that a person is present in the overlap detection area, among the corresponding indoor units, the direction of the person who detected the louver of which indoor unit is directed. The air conditioning system is prestored in each of the indoor control devices so as to blow air in a direction different from the direction of the person with respect to the louvers of the other indoor units.   5. The air conditioning system according to claim 4, wherein the louver wind direction control with respect to the overlap detection area is performed by changing the angle of each louver of the corresponding indoor unit to be above and below the overlap detection area where a person is present. An air conditioning system characterized by blowing air over the entire overlap detection area so as to suppress the occurrence of temperature unevenness.   2. The air conditioning system according to claim 1, wherein among the louvers of the indoor units corresponding to the overlap detection area, the angle of the louver that blows toward the direction of the person detected in the overlap detection area is relative to the horizontal direction. The angle of the louver that is controlled in the direction of the angle range of 52 ° to 64 ° and blows in a direction different from the direction of the person detected in the overlap detection area is 28 ° to 40 ° with respect to the horizontal direction. An air conditioning system characterized by being controlled in direction. In an air conditioning system in which a plurality of indoor units equipped with human sensors are installed in the same indoor space, and the plurality of indoor units are connected to an outdoor unit via a refrigerant pipe,
The human sensor provided in each indoor unit is a human sensor capable of detecting the presence of a person for a plurality of areas,
Each indoor unit is provided with a plurality of air outlets including louvers for changing the wind direction,
Each of the indoor units is configured to individually control the louvers for changing the wind direction provided in the plurality of air outlets based on information detected by the human sensor,
Each indoor unit shares human sensor information for each area detected by the human sensor of each indoor unit,
For the overlap detection area in which the presence of a person in the same area is detected by the plurality of human sensors provided in each of the indoor units, the louvers of the corresponding plurality of indoor units are used in the overlap detection area. The air conditioning is characterized in that the air blowing direction is controlled so that the detected air does not directly hit the detected person, and the louvers of the corresponding indoor units are arranged to blow in different directions. system.

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