JP7174986B2 - air conditioning system - Google Patents

Description

This embodiment relates to an air conditioning system.

Conventionally, by using an air conditioner such as an air conditioner that performs indoor cooling and heating (cooling or heating) in combination with a blower such as a fan and a circulator, the effect of cooling and heating by the air conditioner (cooling effect or heating Techniques for improving the effect) have been proposed.

Japanese Patent Application Laid-Open No. 2016-130600

Conventional air conditioning systems do not disclose specific operating conditions for improving practicality, energy saving, and comfort using air conditioners and blowers.

The present embodiment can automatically adjust the operating conditions of the air conditioner and the fan based on the indoor information detected in the room, and can improve practicality, energy saving, and comfort. Provide a harmonized system.

According to one aspect of the present embodiment, an air conditioner placed in a room, a fan placed in the room, a terminal device placed in the room, the air conditioner, the fan, and the terminal and an indoor information detecting means arranged in the room, wherein the air conditioner controls the blower based on the indoor information obtained by the indoor information detecting means. An air conditioning system is provided comprising:

According to this embodiment, it is possible to automatically adjust the operating conditions of the air conditioner and the fan based on the indoor information detected in the room, thereby improving practicality, energy saving and comfort. It is possible to provide an air conditioning system that can

1 is a block diagram showing the functional configuration of an air conditioning system according to an embodiment to which the present technology is applied; FIG. 1 is a block diagram showing a functional configuration (specific configuration of a communication unit) of an air conditioning system according to an embodiment to which the present technology is applied; FIG. 5 is a flowchart showing an example of control during cooling operation of an air conditioning system according to an embodiment to which the present technology is applied; 4 is a flowchart showing an example of control during heating operation of an air conditioning system according to an embodiment to which the present technology is applied; 4 is a flowchart showing an example of control during clothes drying operation of an air conditioning system according to an embodiment to which the present technology is applied;

Embodiments will be described with reference to the drawings. In the following description of the drawings, the same or similar parts are denoted by the same or similar reference numerals.

In addition, the embodiments shown below are examples of devices and methods for embodying technical ideas, and the materials, shapes, structures, layouts, etc. of components are not specified as follows. . Various modifications can be made to this embodiment within the scope of the claims.

An air conditioning system 10 according to an embodiment to which the present technology is applied will be described with reference to FIGS. 1 to 5. FIG.

[Example of functional configuration of air conditioning system]
FIG. 1 is a functional block diagram of an air conditioning system 10 according to an embodiment to which the present technology is applied.

As shown in FIG. 1, the air conditioning system 10 includes an air conditioner (air conditioner) 11, a fan (fan or circulator) 30 placed indoors, and a remote controller ( 40, and child devices (markers) 50A and 50B as terminal devices placed indoors.

The air conditioner 11 includes an air conditioner body (indoor unit) 12 arranged indoors, and an outdoor unit 13 arranged outdoors. Air conditioner 11 can operate in conjunction with blower 30 .

The air conditioner body 12 includes a control unit 14 that controls the entire air conditioner 11, a communication unit 15, and indoor unit components (heat exchanger 16, indoor fan 17, up/down wind direction plate 18, left/right wind direction plate 19, up/down a first motor M<b>1 that drives the wind deflector 18 , a second motor M<b>2 that drives the left/right wind deflector 19 , etc.), and a sensor unit 20 .

The control unit 14 controls operating conditions (air temperature, air humidity, air volume, wind direction range, operating time, etc.) of the air conditioner 11 .

Specifically, the control unit 14 drives the first motor M1 to swing (rock) the vertical wind direction plate 18 in the vertical direction. The control unit 14 also drives the second motor M2 to swing (rock) the left/right wind direction plate 19 in the left/right direction. As a result, the air blown from the air outlet (not shown) of the air conditioner main body 12 swings vertically and horizontally, and can be blown over a wide area (any direction) in the room.

The communication unit 15 may be connected to other devices (blower 30, remote control 40, child 50A, 50B). The control unit 14 controls the communication unit 15 to transmit and receive information to and from the blower 30, the remote controller 40, and the child devices 50A and 50B.

In addition, the communication unit 15 may have a function for allowing the operator to set the operating conditions of the air conditioning system 10 from the outside using his or her own mobile terminal such as a smartphone, smart watch, and tablet terminal. . With such a function, the operating conditions can be set in advance before the operator enters the room, the air conditioning system 10 can be controlled, and when the operator returns to the room, the indoor environment can be made more comfortable. It becomes possible to

The outdoor unit 13 is connected to the air conditioner body 12 . The outdoor unit 13 is arranged outdoors, for example, and includes a compressor 21 for compressing refrigerant, a heat exchanger 22, an outdoor fan 23, an expansion valve (not shown), and the like. The compressor 21, the heat exchanger 22 of the outdoor unit 13, the expansion valve and the heat exchanger 16 of the air conditioner main body (indoor unit) 12 are connected in this order by refrigerant pipes to form a refrigerant cycle in which the refrigerant circulates.

The heat exchanger 22 of the outdoor unit 13 air-cools the high-temperature, high-pressure refrigerant gas compressed by the compressor 21 by the outdoor fan 23 to condense it. The heat generated by the heat exchanger 22 of the outdoor unit 13 due to the condensation of the refrigerant gas is given to the air sucked from the suction port of the outdoor unit 13 by the outdoor fan 23 and is blown out of the outdoor unit 13 .

The expansion valve decompresses the refrigerant from the heat exchanger 22 of the outdoor unit 13 , and the decompressed refrigerant gas evaporates in the heat exchanger 22 of the outdoor unit 13 . The air sucked into the air conditioner main body 12 by the indoor fan 17 absorbs heat by the heat exchanger 16 of the air conditioner main body 12 . This heat-absorbed air is blown out of the air conditioner body 12 . As described above, the condensation and evaporation of the refrigerant cause heat exchange between the air in the outdoor unit 13 and the air conditioner main body 12, and the indoor air is conditioned.

The sensor unit 20 includes, for example, a human sensor (human detection means) that detects the presence or absence of people in the room, a temperature sensor that detects the temperature around the air conditioner main body 12, and a humidity sensor that detects the humidity around the air conditioner main body 12. It comprises a sensor, a position detection sensor (position detection means) for detecting the positions of the blower 30, the remote control 40 and the slave units 50A and 50B in the room, a wind direction sensor, an air volume sensor, and the like. A human sensor (human detection means) detects at least one of the presence, movement, and position of a person in a room, and is composed of, for example, an infrared sensor or an imaging device.

The remote control 40 is a type of terminal device, and includes a control unit 41 for controlling the entire remote control 40 , a communication unit 42 , an operation unit 43 , a display unit 44 and a sensor unit 45 . The remote controller 40 can be placed at any position in the room and is movably installed in the room.

The communication unit 42, like the communication unit 15 of the air conditioner main body 12, for example, uses a short-range wireless communication method such as WiFi, Bluetooth, or Wi-SUN, or infrared communication, etc. to communicate with other devices (air conditioner main body 12, It is an interface for communicating with the blower 30 and slave units 50A and 50B). The control unit 41 controls the communication unit 42 to transmit/receive information to/from the air conditioner body 12 . Specifically, the control unit 41 transmits, via the communication unit 42 , the content of the operation performed by the operation unit 43 and various information detected by the sensor unit 45 to the air conditioner main body 12 .

The operation unit 43 includes an operation start/stop button for instructing the start and stop of operation, a temperature adjustment button for adjusting the temperature, an airflow direction switching button for switching the airflow direction, a cooling operation mode, a heating operation mode, and an automatic operation. It includes various buttons such as an operation mode switching button for selecting a mode or a clothes drying operation mode, and accepts an operator's operation.

Similar to the sensor unit 20 of the air conditioner main body 12, the sensor unit 45 includes, for example, a human sensor (human detection means) that detects the presence or absence of a person in the room, a temperature sensor that detects the temperature around the remote controller 40, and a temperature sensor that detects the temperature around the remote controller 40. A humidity sensor for detecting the ambient humidity, a position detection sensor (position detection means) for detecting the positions of the air conditioner body 12, the blower 30, and the slave units 50A and 50B in the room, a wind direction sensor, an air volume sensor, and the like. be. A human sensor (human detection means) detects at least one of the presence, movement, and position of a person in a room, and is composed of, for example, an infrared sensor or an imaging device.

The child devices 50A and 50B are a type of portable device and function as markers. Each of the child devices 50A and 50B has a communication section 51 and a sensor section 52 . The sub-units 50A and 50B can be placed at arbitrary positions in the room, and are movably installed in the room.

The communication unit 51, like the communication unit 15 of the air conditioner main body 12, for example, uses a short-range wireless communication method such as WiFi, Bluetooth, or Wi-SUN, or infrared communication, etc. to communicate with other devices (air conditioner main body 12, It is an interface for communicating with the blower 30 and the remote control 40).

Similar to the sensor section 20 of the air conditioner body 12, the sensor section 52 includes, for example, a human sensor (human detection means) that detects the presence or absence of a person in the room, and a temperature sensor that detects the temperature around the child units 50A and 50B. , a humidity sensor for detecting the humidity around the child units 50A and 50B, a position detection sensor (position detection means) for detecting the positions of the air conditioner body 12, the fan 30 and the remote control 40 in the room, a wind direction sensor, an air volume sensor, and the like. consists of A human sensor (human detection means) detects at least one of the presence, movement, and position of a person in a room, and is composed of, for example, an infrared sensor or an imaging device.

Note that the child devices 50A and 50B may have a switch for turning on/off the power. In addition, in the illustrated example, the air conditioning system 10 includes two slave units 50A and 50B, but it may be equipped with only one slave unit, or may be equipped with a plurality of slave units of three or more. good too.

The blower 30 includes a control section 31 that controls the entire blower 30 , a communication section 32 and a sensor section 33 . Blower 30 can operate in conjunction with air conditioner 11 . Also, the blower 30 can be placed at any position in the room, and is movably installed in the room.

The control unit 31 controls the operating conditions (air volume, wind direction range, operating time, etc.) of the blower 30 .

The communication unit 32, like the communication unit 15 of the air conditioner main body 12, for example, uses a short-range wireless communication method such as WiFi, Bluetooth, or Wi-SUN, or infrared communication, etc. to communicate with other devices (air conditioner main body 12, It is an interface for communicating between the remote controller 40 and the child devices 50A and 50B).

The sensor unit 33, like the sensor unit 20 of the air conditioner body 12, includes, for example, a human sensor (human detection means) that detects the presence or absence of a person in the room, a temperature sensor that detects the temperature around the blower 30, and a temperature sensor that detects the temperature around the blower 30. It comprises a humidity sensor for detecting the ambient humidity, a position detection sensor (position detection means) for detecting the positions of the air conditioner body 12, the remote control 40 and the slave units 50A and 50B in the room, a wind direction sensor, an air volume sensor, and the like. be. A human sensor (human detection means) detects at least one of the presence, movement, and position of a person in a room, and is composed of, for example, an infrared sensor or an imaging device.

The blower 30 has at least a switch for turning on/off the power. Also, in the illustrated example, the air conditioning system 10 includes only one blower 30, but may include two or more blowers.

[Specific configuration example of communication unit]
FIG. 2 is a functional block diagram of an air conditioning system 10 according to an embodiment to which the present technology is applied.

The air conditioning system 10 shown in FIG. 2 includes an air conditioner 11 , a blower 30 , a remote controller 40 , a child device (marker) 50 and a relay device (router) 60 .

For example, wireless communication by WiFi is performed between the communication unit 15 of the air conditioner 11 and the relay device 60 . The relay device 60 is connected to a mobile terminal or other terminal device such as a smart speaker in an internal network (local area network) 100 via wireless communication using WiFi, for example. Also, the relay device 60 is connected to, for example, a cloud server or the like in the external network 200 via an Internet line.

For example, infrared communication is performed between the communication unit 15 of the air conditioner 11 and the communication unit 42 of the remote controller 40 .

On the other hand, between the communication unit 15 of the air conditioner 11 and the communication unit 32 of the fan 30, and between the communication unit 15 of the air conditioner 11 and the communication unit 51 of the child device 50, for example, Bluetooth Wireless communication takes place.

Since the remote controller 40 is generally operated while facing the air conditioner 11 , it can communicate with the air conditioner 11 by infrared communication without any obstacles. On the other hand, depending on where the blower 30 and the cordless handset 50 are placed, there may be an obstacle between them and the air conditioner 11, and communication by infrared communication may become incomplete or unstable. Therefore, the communication between the air conditioner 11 and the blower 30 and the communication between the air conditioner 11 and the slave unit 50 employ wireless communication to eliminate obstacles between the air conditioner 11 and the communication. It is possible to stably transmit and receive information even if there is

[Control during cooling/heating operation in which the air conditioner and the fan are interlocked]
The air conditioner 11 has cooling and heating functions (cooling function and heating function). Moreover, as described above, the air conditioner 11 can operate in conjunction with the blower 30 .

When the cooling/heating operation of the air conditioner 11 is started, the control unit 14 of the air conditioner 11 controls both the air conditioner 11 and the blower 30 so that the operating conditions are increased air volume operation in which the air volume is increased compared to normal operation. Control.

Further, the control unit 14 of the air conditioner 11 determines that the indoor temperature, which is one of the indoor information obtained by the indoor information detection means (sensor units 20, 33, 45, 52), is set to the set temperature when the air conditioner 11 is in cooling and heating operation. is reached, the air conditioner 11 is controlled so that the operating condition is an air volume suppression operation (energy saving mode) in which the air volume is suppressed more than during normal operation, and the blower 30 is controlled so that the operating condition is normal operation. to control. Note that the control unit 14 of the air conditioner 11 may obtain the indoor temperature from the sensor unit 20 provided in the air conditioner 11, the sensor unit 33 provided in the blower 30, or the remote controller. It may be acquired by the sensor unit 45 provided in the remote device 40, or may be acquired by the sensor unit 52 provided in the child devices 50A, 50B, and 50. FIG.

During the period from the start of operation of the air conditioner 11 until the room temperature reaches the set temperature, both the air conditioner 11 and the blower 30 are operated at maximum operation (maximum capacity operation), for example, so that the room temperature reaches the set temperature quickly. can be completed in Further, after the room temperature reaches the set temperature, the air volume from the air conditioner 11 is reduced as much as possible, and the air blower 30 is mainly operated to improve the cooling and heating efficiency.

Furthermore, the control unit 14 of the air conditioner 11, when the indoor information detecting means (sensor units 20, 33, 45, 52) detects a person in the room during cooling/heating operation of the air conditioner 11, To control an air conditioner 11 and a blower 30 so that air blown from the air conditioner 11 does not directly hit people in a room. Note that the control unit 14 of the air conditioner 11 may acquire the position information of the person using the sensor unit 20 provided in the air conditioner 11 or the sensor unit 33 provided in the blower 30. , may be acquired by the sensor section 45 provided in the remote controller 40, or may be acquired by the sensor section 52 provided in the child devices 50A, 50B, and 50. FIG.

In addition, when the room temperature or the surface temperature of a person is equal to or higher than a predetermined threshold value during cooling operation of the air conditioner 11, the control unit 14 of the air conditioner 11 controls the blowing air from the air conditioner 11 so that the person is present. If it is lower than the threshold, the air from the air conditioner 11 may not be directed in the direction in which people are present.

In addition, when the indoor temperature or the surface temperature of a person is equal to or lower than a predetermined threshold value during the heating operation of the air conditioner 11, the control unit 14 of the air conditioner 11 controls the blowing air from the air conditioner 11 so that the person is present. If it is higher than the threshold, the air from the air conditioner 11 may not be directed in the direction in which people are present.

In addition, when the air conditioner 11 is in steady operation, the control unit 14 of the air conditioner 11 prevents the air from the air conditioner 11 from being directed toward people, and directs the air from the air conditioner 11 mainly. You may make it direct to the direction in which the air blower 30 is arrange|positioned.

When the air conditioner 11 is in cooling operation, the air blower 30 circulates the cold air from the air conditioner 11 that tends to accumulate in the lower part of the room, so that the cooling effect of the air conditioner 11 can be enhanced and comfort can be improved. can be improved. In addition, by preventing the air from the air conditioner 11 from hitting people in the room directly, it is possible to reduce the burden (too cold) on people's bodies, and to further improve comfort. become.

During the cooling operation of the air conditioner 11, during the period from the start of operation of the air conditioner 11 until the room temperature reaches the set temperature, the blowing air from the air conditioner 11 is maximized, and after the room temperature reaches the set temperature By suppressing the blowing of air from the air conditioner 11, it is possible to obtain an energy saving effect (power saving effect). In general, it is said that if the set temperature of the air conditioner 11 (the set temperature for cooling) is increased by 2° C. in summer, the electricity bill can be saved by about 20%.

On the other hand, during the heating operation of the air conditioner 11, the warm air from the air conditioner 11, which tends to accumulate in the upper part of the room, is circulated by the blower 30, so that the heating effect of the air conditioner 11 can be enhanced, and comfort can be improved. can be improved. In addition, by preventing the air from the air conditioner 11 from directly hitting people in the room, it is possible to reduce the burden (overheating) on the human body and improve comfort. become.

During the heating operation of the air conditioner 11, during the period from the start of operation of the air conditioner 11 until the room temperature reaches the set temperature, the blowing of air from the air conditioner 11 is maximized, and after the room temperature reaches the set temperature By suppressing the blowing of air from the air conditioner 11, it is possible to obtain an energy saving effect (power saving effect). In general, it is said that if the set temperature of the air conditioner 11 (the set temperature during heating) is lowered by, for example, 2° C. in winter, the electricity bill can be saved by about 20%.

[Control during clothes drying operation in which the air conditioner and the fan are interlocked]
Due to its structure, the air conditioner 11 has a dehumidifying function of discharging moisture in the room to the outside. In addition, as described above, the air conditioner 11 can operate in conjunction with the blower 30, and the air conditioning system 10 uses the dehumidifying function of the air conditioner 11 and the blowing of the blower 30 to perform washing after washing. It is possible to implement a clothes drying operation that accelerates the drying of clothes.

The control unit 14 of the air conditioner 11 controls the operation condition of the air conditioner 11 during the clothes drying operation (during the dehumidifying operation) so that the air volume suppression operation (energy saving mode) in which the air volume is suppressed more than during normal operation is performed. At the same time, the air blower 30 is controlled so that the operating condition is the air volume increasing operation in which the air volume is increased compared to the normal operation.

By operating the air conditioner 11 at a reduced air volume during the clothes drying operation, it is possible to ensure a sufficient amount of dehumidification by the air conditioner 11 . In addition, when the clothes are dried, the air blower 30 is operated with an increased air volume so that the moisture (moisture) of the laundry (clothes) can be blown off and the clothes can be dried quickly, effectively promoting the drying of the clothes. becomes possible. These synergistic effects make it possible to effectively shorten the time required to dry clothes.

The control unit 14 of the air conditioner 11 further controls the blower 30 so that the air blowing from the blower 30 directly hits the clothes in the room when the clothes are dried (during the dehumidification operation). Note that the control unit 14 of the air conditioner 11 may acquire the position information of the clothes from the sensor unit 20 provided in the air conditioner 11 or from the sensor unit 33 provided in the blower 30. , may be acquired by the sensor section 45 provided in the remote controller 40, or may be acquired by the sensor section 52 provided in the child devices 50A, 50B, and 50. FIG.

In addition, the air conditioner 11 has a timer function (automatic operation stop function), and the control unit 14 of the air conditioner 11 automatically stops the operation of the air conditioner 11 when the set time of the timer elapses. You may make it

Furthermore, the control unit 14 of the air conditioner 11 detects indoor information (indoor humidity), the operation of the air conditioner 11 may be automatically stopped.

[Example of control during cooling operation]
An example of cooling operation control of the air conditioning system 10 according to an embodiment to which the present technology is applied will be described with reference to FIG. 3 .

FIG. 3 is a flowchart showing an example of cooling operation control of the air conditioning system 10 according to an embodiment to which the present technology is applied.

When the cooling operation of the air conditioner 11 is started, in step S10, the air conditioner 11 is operated under the maximum operating condition (maximum capacity operation), and the blower 30 is operated under the maximum operating condition (maximum capacity operation). driving).

In step S11, it is determined whether or not the room temperature detected by the sensor unit 45 of the remote controller 40 is lower than the set temperature TC1 during cooling operation. repeats the determination process of step S11.

In step S<b>12 , the direction of the wind from the air conditioner 11 is controlled so that the air from the air conditioner 11 is blown to a place other than where the remote control 40 is located.

In step S13, it is determined whether or not the room temperature detected by the sensor unit 20 of the air conditioner 11 is higher than the set temperature TC1. The determination process of step S13 is repeatedly performed.

In step S14, the air conditioner 11 is operated under the air volume suppression operation (energy saving mode), and the blower 30 is operated under the normal operation condition.

In step S15, it is determined whether or not the room temperature detected by the sensor unit 45 of the remote controller 40 is higher than the set temperature TC1. is repeated.

In step S16, it is determined whether or not the room temperature detected by the sensor unit 45 of the remote controller 40 is higher than the second set temperature (threshold value) TC2 for cooling operation. NO", the process proceeds to step S17. The second set temperature TC2 is set higher than the set temperature TC1.

In step S17, the operation condition of the blower 30 is changed from normal operation to strong operation, and the process returns to step S15.

Note that this control process ends when the operation mode of the air conditioner 11 is changed, or when the operation of either the air conditioner 11 or the fan 30 is stopped.

[Example of control during heating operation]
An example of heating operation control of the air conditioning system 10 according to an embodiment to which the present technology is applied will be described based on FIG. 4 .

FIG. 4 is a flowchart showing an example of control during heating operation of the air conditioning system 10 according to one embodiment to which the present technology is applied.

When the heating operation of the air conditioner 11 is started, in step S20, the air conditioner 11 is operated with the operating condition set to the maximum operation (maximum capacity operation), and the blower 30 is set to the maximum operation condition (maximum capacity operation). driving). At this time, in order to circulate the warmed air discharged from the air conditioner 11 into the room, the air blower 30 is controlled to blow air upward.

In step S21, it is determined whether or not the room temperature detected by the sensor unit 45 of the remote controller 40 is higher than the set temperature TW1 during heating operation. repeats the determination process of step S21.

In step S<b>22 , the direction of the wind from the air conditioner 11 is controlled so that the air from the air conditioner 11 is blown to a place other than where the remote control 40 is located. At this time, the operating condition of the air conditioner 11 is switched from maximum operation to normal operation.

In step S23, it is determined whether or not the indoor temperature detected by the sensor unit 20 of the air conditioner 11 is higher than the set temperature TW1. The determination process of step S23 is repeatedly performed.

In step S24, the air conditioner 11 is operated under maximum operation conditions, and the blower 30 is operated under normal operation conditions.

In step S25, it is determined whether or not the room temperature detected by the sensor unit 45 of the remote controller 40 is lower than the second set temperature (threshold value) TW2 for heating operation. NO", the determination process of step S25 is repeated. The second set temperature TW2 is set lower than the set temperature TW1.

Note that this control process ends when the operation mode of the air conditioner 11 is changed, or when the operation of either the air conditioner 11 or the fan 30 is stopped.

[Example of control during clothes drying operation]
An example of the clothes drying operation control of the air conditioning system 10 according to an embodiment to which the present technology is applied will be described based on FIG. 5 .

FIG. 5 is a flowchart showing an example of control during the clothes drying operation of the air conditioning system 10 according to one embodiment to which the present technology is applied.

When the clothes drying operation of the air conditioner 11 is started, in step S30, the air conditioner 11 is operated with the operation condition set to the air volume suppression operation (energy saving mode), and the blower 30 is set to the maximum operation (maximum It is operated with the ability operation).

In step S31, it is determined whether or not a predetermined time T has passed since the clothes drying operation of the air conditioner 11 was started. do. That is, in the case of "YES", the clothes drying operation (dehumidifying operation) of the air conditioner 11 is stopped.

In step S32, it is determined whether or not the indoor humidity detected by the sensor units 52 of the child devices 50A, 50B, and 50 is lower than the predetermined humidity H. If "YES", the process returns to step S31. , the determination process of step S32 is repeated.

[Other embodiments]
As described above, although described by way of example, the discussion and drawings forming part of this disclosure are illustrative and should not be construed as limiting. Various alternative embodiments, implementations and operational techniques will become apparent to those skilled in the art from this disclosure.

Thus, this embodiment includes various embodiments and the like that are not described here.

The air conditioning system of the present embodiment can be applied to cooling, heating, dehumidification, etc. in ordinary homes, offices, and the like.

DESCRIPTION OF SYMBOLS 10... Air conditioning system, 11... Air conditioner, 12... Air conditioner main body, 13... Outdoor unit, 14... Control part, 15... Communication part (communication means), 16... Heat exchanger, 17... Indoor fan, 18 Vertical wind direction plate 19 Left and right wind direction plate 20 Sensor part (indoor information detection means) 21 Compressor 22 Heat exchanger 23 Outdoor fan 30 Blower 31 Control part 32 Communication Part (communication means), 33... Sensor part (indoor information detection means), 40... Remote control (terminal device), 41... Control part, 42... Communication part (communication means), 43... Operation part, 44... Display part, 45 ... sensor section (indoor information detection means), 50A, 50B, 50 ... child device (marker, terminal device), 51 ... communication section (communication means), 52 ... sensor section (indoor information detection means), 60 ... relay device ( router), 100... internal network, 200... external network, M1... first motor, M2... second motor

Claims (5)

An air conditioner having an indoor unit arranged indoors and an outdoor unit arranged outdoors, wherein the indoor unit and the outdoor unit constitute a refrigerant cycle;
a blower arranged in the room;
a terminal device movably arranged at an arbitrary position in the room;
a communication means for communicating between the air conditioner, the fan, and the terminal device;
indoor information detection means having a sensor unit that detects the temperature or humidity around the terminal device provided in the terminal device;
a control unit that controls the air conditioner in conjunction with the blower based on the temperature or humidity around the terminal device, which is the indoor information obtained by the indoor information detection means;
air conditioning system. The control unit operates the air conditioner when the temperature around the fan or the temperature around the terminal device reaches a set temperature detected by the indoor information detection means during cooling and heating operation of the air conditioner. 2. The air conditioning system according to claim 1 , wherein the control is performed so that air volume suppression operation is performed in which the air volume is suppressed more than during normal operation, and the blower is controlled so that the operating condition is normal operation. During the heating operation of the air conditioner, the control unit controls the air 2. The method according to claim 1 , wherein both the conditioner and the blower are controlled so that the operating conditions are increased air volume operation in which the air volume is increased compared to normal operation, and the blower is controlled so that the air blow direction is upward. Air conditioning system as described. An air conditioner having an indoor unit arranged indoors and an outdoor unit arranged outdoors, wherein the indoor unit and the outdoor unit constitute a refrigerant cycle;
a fan movably arranged at an arbitrary position in the room;
a communication means for communicating between the air conditioner and the blower;
Position detection means having a sensor unit provided in the air conditioner for detecting position information of clothes in the room and a sensor unit provided in the blower for detecting position information of clothes around the blower;
a control unit that controls the blower so that air from the blower directly hits the clothes based on the position information of the clothes obtained by the position detection means;
air conditioning system. When drying clothes, the control unit controls the air conditioner so that the operating condition is an air volume suppression operation in which the air volume is suppressed more than in normal operation, and the air blower is controlled in an operating condition in which the air volume is lower than that in normal operation. 5. The air conditioning system according to claim 4 , wherein control is performed to increase the air volume in which the air volume is increased.

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