JP6885234B2 - Whole building air conditioning system - Google Patents

Description

An embodiment of the present invention relates to a whole building air conditioning system that air-conditions a plurality of areas of a house with one air conditioning unit.

Conventionally, in the whole building air conditioning system, as a remote controller for operating the control contents of the air conditioning unit, a master unit is installed in one area and a slave unit is installed in each other area. The master unit is a device that can instruct air conditioning in all areas. In addition, the slave unit is a device capable of instructing air conditioning in the area in charge of the installed area. In this case, the slave unit transmits the setting contents input by the user to the master unit. Then, the master unit controls the air conditioning unit according to the setting contents received from the slave unit. As a result, the user can control the air conditioning in the area where the slave unit is installed by operating the slave unit without operating the master unit.

In such a configuration, it is necessary to correctly set in advance the correspondence relationship between the area where the air conditioning control is performed by the operation of each slave unit and the area where the slave unit is actually installed. If this initial setting is not performed correctly, for example, when a user tries to control the air conditioning in an area and operates a slave unit installed in that area, the air conditioning in another area is erroneously controlled. This is because the situation occurs.

Therefore, in the conventional configuration, when making the initial setting, the user first decides to which area the control area controlled by the air conditioning unit is actually assigned, that is, to which room the air conditioning duct of the air conditioning unit is actually assigned. Know if they are connected. This control area is grasped by, for example, arranging a person who operates the master unit and a person who confirms the operation of air conditioning in each area individually, and operating the master unit to actually operate the air conditioning unit. It was. Then, the user operates the master unit and the slave unit, and by associating each slave unit with each area and storing the slave unit, the area to be installed, that is, the area in charge is set for each slave unit, and then the area in charge is set. , I was doing the work of installing each slave unit according to the set area in charge.

However, in such a conventional configuration, each slave unit is actually installed in the area in charge after the area in charge is set. For this reason, the user may accidentally install the slave unit in a different area. Furthermore, as described above, at least two workers are required to grasp the control area of the air conditioning unit, and the workers must operate the master unit one by one to check the operation of the air conditioning. Therefore, it took time and effort to grasp the control area of the air conditioning unit.

Japanese Unexamined Patent Publication No. 2016-143275

The present invention has been made in view of the above circumstances, and an object of the present invention is to save the labor of work in the initial setting, and to control the air conditioning by each slave unit and the area where the slave unit is actually installed. The purpose is to provide an air-conditioning system for the entire building that can reduce mistakes in the correspondence with.

(Claim 1)
The whole building air-conditioning system according to claim 1 communicates with an air-conditioning unit capable of individually air-conditioning a plurality of areas, a master unit that instructs the air-conditioning unit to control the air-conditioning in each area, and the master unit. It is provided with a plurality of slave units which are possible and are installed in each of the areas and transmit control contents input from the user to the master unit. The slave unit has an environmental information acquisition unit that acquires environmental information in the area where the slave unit is installed. As an initial setting for associating each of the slave units with each area in which the slave units are installed, the master unit operates the air conditioning unit in cooperation with the slave units to operate the slave units in each of the areas. Environmental change processing that air-conditions one of the areas to change the environment of the one area, and slave unit identification processing that identifies the slave unit whose environmental information acquired by the environmental information acquisition unit has changed among the slave units. And the area allocation process of allocating the one area air-conditioned by the environmental change process to the installation area of the slave unit specified by the slave unit identification process.

That is, in the conventional configuration, the user associates each slave unit with the area where the slave unit is to be installed, and then installs each slave unit in each of the linked areas. That is, in the conventional configuration, when the user brings the slave unit to each area, the slave unit and the area are already linked. Therefore, a situation may occur in which the user mistakenly installs the slave unit in a different area. On the other hand, in this configuration, after each slave unit is installed in each area, each slave unit is linked to the area where the slave unit is actually installed. Therefore, it is possible to prevent an error in the correspondence between the area where the air conditioning control is performed by each slave unit and the area where the slave unit is actually installed.

Further, according to this configuration, unlike the conventional configuration, when the user brings the slave unit to each area, the slave unit and the area are not yet linked. Therefore, the user can install each slave unit in an arbitrary area without being aware of the correspondence between each slave unit and the area. Further, according to this configuration, the slave unit installed in each area is automatically specified by the master unit. Therefore, the user does not need to grasp the control area of the air conditioning unit at the time of initial setting as in the conventional configuration. As a result, the workability at the time of installing each slave unit, that is, at the time of initial setting is improved, and the time and effort required for the initial setting of the user can be saved. From the above, according to this configuration, in the initial setting, it is possible to save the labor of the user's work, and the correspondence relationship between the area where the air conditioning control is performed by each slave unit and the area where the slave unit is actually installed. Mistakes can be reduced.

(Claim 2)
In the whole building air-conditioning system of claim 2, the slave unit has at least one of a temperature sensor, a barometric pressure sensor, and a humidity sensor as the environmental information acquisition unit. Temperature, atmospheric pressure, and humidity are environmental information that is easily changed by air conditioning. Therefore, when the slave unit detects at least one of temperature, atmospheric pressure, and humidity, the slave unit can more accurately detect the change in the surrounding environment caused by the environmental change processing. As a result, more accurate initial setting can be performed.

By the way, temperature and atmospheric pressure are more susceptible to air conditioning than humidity. Therefore, it is preferable that the slave unit has at least one of a temperature sensor and a barometric pressure sensor as an environmental information acquisition unit. According to this, more accurate initial setting can be performed as compared with the case where the slave unit has only the humidity sensor.

(Claim 1 )
Here, it is premised that one slave unit is installed in each area, and in the environmental change processing, air conditioning is performed only in one area. Nevertheless, the fact that two or more slave units are identified in the slave unit identification process means that the specified slave units are installed in the same air-conditioned area, or are air-conditioned. It is probable that the environment changed due to factors other than air conditioning, for example, due to the opening and closing of doors and windows in other areas where the above was not performed.

Furthermore, even though air conditioning is performed for one area in the environmental change processing, the fact that one slave unit is not specified even after a predetermined period has passed in the slave unit identification processing means that the air-conditioned area is affected. In areas where no slave units are installed or where air conditioning is performed, the effects of air conditioning are less likely to occur, for example, air from air conditioning is leaking to the outside due to the opening of doors and windows. It is considered to be a situation. In any case, in these cases, since the one-to-one correspondence between each slave unit and each area cannot be specified, the allocation of the slave unit to the area fails.

Therefore, in the whole building air-conditioning system of claim 1 , when the master unit specifies two or more slave units in the slave unit identification process, or when one slave unit is not specified even after a predetermined period has passed, the master unit is not specified. Without performing the area allocation process, the initial setting is performed again for the area whose environment has been changed in the environmental change process. According to this, if the association between the area where the slave unit is installed and the slave unit cannot be specified for some reason, the master unit automatically performs the initial setting for the area again. As a result, even if the initial setting fails, it is not necessary for the user to associate the slave unit with the area, and as a result, the user's trouble can be saved.

(Claim 3 )
The master unit executes the processing after the initial environmental storage processing on the condition that all the changes in the environmental information received from the slave units are stable within a predetermined range. According to this, the initial setting can be performed in a state where the influence other than the air conditioning by the air conditioning unit is eliminated as much as possible. Therefore, more accurate initial setting can be performed.

The figure which shows typically an example of the structure of the whole building air-conditioning system by one Embodiment A diagram schematically showing the interrelationship of each configuration of the entire building air conditioning system according to one embodiment. A block diagram schematically showing the electrical configuration of a slave unit in the entire building air conditioning system according to one embodiment. A block diagram schematically showing the electrical configuration of the master unit in the entire building air conditioning system according to one embodiment. Flow chart showing the control contents of the initial setting in the whole building air conditioning system according to one embodiment The figure which shows an example of the state which the environment of each area is stable in the whole building air-conditioning system by one Embodiment. The figure which shows an example of the case where the environment change processing is executed in the whole building air-conditioning system by one Embodiment The figure which shows an example of the state in which the environmental information acquired by each slave unit is stable in the whole building air-conditioning system by one Embodiment. The figure which shows an example of the change rate of the environmental information when two slave units are specified by the slave unit identification process in the whole building air-conditioning system by one Embodiment. The figure which shows an example of the change rate of the environmental information in the case where the slave unit is not specified by the slave unit identification process in the whole building air-conditioning system according to one embodiment. The figure which shows an example of the allocation state between a slave unit and an area in the whole building air-conditioning system by one Embodiment. The figure which conceptually shows the signal transmitted from each slave unit to the master unit in the whole building air-conditioning system by one Embodiment. The figure which conceptually shows the signal transmitted from each slave unit to the master unit in the whole building air-conditioning system by another embodiment.

Hereinafter, one embodiment will be described with reference to the drawings.
The entire building air conditioning system 10 shown in FIG. 1 is provided in the house 100. The house 100 has a plurality of areas. This area is not limited to living rooms such as living rooms and bedrooms, and may include bathrooms, toilets, entrances, atriums, and the like. In the present embodiment, for the sake of simplification of the explanation, a house 100 having four areas 1 to 4 will be described as an example, but the number of areas and the composition thereof, that is, the number of rooms and the composition thereof are not limited to those of the house 100. ..

The whole building air-conditioning system 10 air-conditions a plurality of areas in the house 100, in this case, four areas 1 to 4, by one air-conditioning unit 20. In the present embodiment, the entire building air conditioning system 10 includes an air conditioning unit 20, air conditioning ducts 111 to 114, a remote controller master unit 30 (hereinafter referred to as a master unit 30), and a remote controller slave unit 40 (hereinafter referred to as a slave unit 40). I have.

The air conditioning unit 20 is composed of, for example, a well-known heat exchanger such as a heat pump having an indoor unit 21 shown in FIG. 1 and an outdoor unit (not shown). In the air conditioning unit 20, each area 1 to 4 is used as an air conditioning control area. The air conditioning ducts 111 to 114 are provided corresponding to the areas 1 to 4, and connect the indoor unit 21 of the air conditioning unit 20 and the areas 1 to 4, respectively. The air conditioning unit 20 has a plurality of, in this case, four on-off valves 221 to 224. The on-off valves 221 to 224 correspond to the areas 1 to 4, and are provided in the middle or at the end of the air-conditioning ducts 111 to 114, respectively, and open and close the air-conditioning ducts 111 to 114.

The air conditioning unit 20 performs air conditioning in each of the areas 1 to 4 as follows, for example. That is, the air conditioning unit 20 takes in the air in each of the areas 1 to 4, that is, the inside air, exchanges heat with the indoor unit 21, and takes in the outside air from the outside of the house 100 through a filter (not shown). Then, the air conditioning unit 20 mixes the heat-exchanged inside air and the outside air, thereby adjusting the humidity and temperature to generate air in which air conditioning is performed. Then, the air conditioning unit 20 selectively supplies air that has been air-conditioned to each of the areas 1 to 4 by controlling the opening and closing of the on-off valves 221 to 224. In this way, the air conditioning unit 20 performs air conditioning for each of the areas 1 to 4.

Further, the air conditioning unit 20 can set an air conditioning target temperature for each of the areas 1 to 4. In this case, the air conditioning unit 20 adjusts the opening / closing and opening degree of the on-off valves 221 to 224 according to the difference between the indoor temperature of each of the areas 1 to 4 and the air conditioning target temperature, and supplies the air to each of the areas 1 to 4. Adjust the amount. As a result, the air conditioning unit 20 maintains the indoor temperatures of the areas 1 to 4 at the set air conditioning target temperature. As described above, the air conditioning unit 20 is configured to be able to individually air-condition the areas 1 to 4.

In the present embodiment, as shown in FIG. 2, the air conditioning unit 20 includes one master unit 30 and four slave units 40 corresponding to the numbers of 1 to 4 in each area. In the following description, when each slave unit 40 is distinguished, it is referred to as a slave unit 40 (A), a slave unit 40 (B), a slave unit 40 (C), and a slave unit 40 (D). Each of the slave units 40 (A) to (D) has a unique identification ID set so as not to be duplicated.

In the case of the present embodiment, one of the four slave units 40 is incorporated in the master unit 30. That is, of the four slave units 40, the slave unit 40 (A) is also used as the master unit 30. Each slave unit 40 is configured to be able to communicate with the master unit 30 wirelessly or by wire. The master unit 30 is installed in any of the areas 1 to 4. The slave units (B) to (D) other than the slave unit 40 (A) built in the master unit 30 are installed one by one in the area where the master unit 30 and the slave unit 40 (A) are not installed. Each slave unit 40 inputs setting contents such as an air conditioning target temperature from the user, and transmits the input setting contents to the master unit 30.

The master unit 30 is configured to be able to communicate with the air conditioning unit 20, and transmits the setting contents such as the air conditioning target temperature received from each slave unit 40 to the air conditioning unit 20. As a result, the master unit 30 instructs the air conditioning unit 20 to control the air conditioning in each of the areas 1 to 4. Then, the air conditioning unit 20 performs air conditioning for each of the areas 1 to 4 according to the control content received from the master unit 30.

As shown in FIG. 3, the slave unit 40 has a temperature sensor 41, a barometric pressure sensor 42, a humidity sensor 43, an operation unit 44, a display unit 45, a communication unit 46, and a control unit 47. The temperature sensor 41 detects the temperature around the slave unit 40, that is, the temperature in the area where the slave unit 40 is installed. The atmospheric pressure sensor 42 detects the atmospheric pressure around the slave unit 40, that is, the atmospheric pressure in the area where the slave unit 40 is installed. The humidity sensor 43 detects the humidity around the slave unit 40, that is, the humidity in the area where the slave unit 40 is installed. The temperature sensor 41, the atmospheric pressure sensor 42, and the humidity sensor 43 acquire the environmental information around the slave unit 40, that is, the environment for acquiring the temperature, atmospheric pressure, humidity, etc. of the area as the environmental information of the area where the slave unit 40 is installed. Functions as an information acquisition unit.

The operation unit 44 receives an input operation from the user, and is composed of, for example, a mechanical switch, an electric touch switch, or the like. The display unit 45 is, for example, a liquid crystal panel or the like, and displays various information such as input contents from the user, current setting contents, and environmental information around the slave unit 40 detected by the sensors 41 to 43. The communication unit 46 has a function of performing wireless or wired communication with the master unit 30, and the detection results of the sensors 41 to 43 and the setting information input by the operation unit 44 with respect to the master unit 30. Etc. are sent.

The control unit 47 is mainly composed of a microcomputer having a storage area 472 such as a CPU 471, a ROM, a RAM, and a rewritable flash memory, and controls the entire slave unit 40. That is, the control unit 47 controls the operations of the temperature sensor 41, the barometric pressure sensor 42, the humidity sensor 43, the operation unit 44, the display unit 45, and the communication unit 46.

As shown in FIG. 4, the master unit 30 has a temperature sensor 41, a barometric pressure sensor 42, a humidity sensor 43, an operation unit 44, and a display unit 45 as functions of the slave unit 40. Further, the master unit 30 has a control unit 31. The control unit 31 is mainly composed of a microcomputer having a storage area 312 such as a CPU 311, a ROM, a RAM, and a rewritable flash memory, and controls the entire master unit 30 and the air conditioning unit 20. ing. In this case, the master unit 30 is communicably connected to the air conditioning unit 20 by, for example, a communication line. The master unit 30 may be communicably connected to the air conditioning unit 20 by wireless communication.

The storage area 312 stores various control programs for controlling the air conditioning unit 20 and initial setting programs for performing initial settings. The initial setting program consists of an area where air conditioning is controlled by operating the slave units 40 (A) to (D) and areas 1 to 4 where the slave units 40 (A) to (D) are actually installed. This is a program for setting the correspondence. By making initial settings, the master unit 30 stores each slave unit 40 in association with each area 1 to 4 in which each slave unit 40 is actually installed.

That is, the control unit 31 executes the initial setting program in the CPU 311 to convert the initial environment storage processing unit 32, the environment change processing unit 33, the slave unit identification processing unit 34, the area allocation processing unit 35, and the like into software. Realize. Even if the initial environment storage processing unit 32, the environment change processing unit 33, the slave unit identification processing unit 34, the area allocation processing unit 35, and the like are realized as an integrated circuit integrated with the control unit 31, for example, in terms of hardware. Good. The initial environment storage processing unit 32, the environment change processing unit 33, the slave unit identification processing unit 34, and the area allocation processing unit 35 constitute a function as the master unit 30.

The initial environment storage processing unit 32 executes the initial environment storage processing. The initial environment storage process is a process of storing the current environment information acquired from each slave unit 40 as initial environment information or storing it in each slave unit 40. The environment change processing unit 33 executes the environment change processing. The environmental change processing is executed after the initial environmental storage processing, and the air conditioning unit 20 is operated to air-condition one of the areas 1 to 4, and the environment of that one area, that is, the temperature, atmospheric pressure, or It is a process of changing at least one of the humidity.

The slave unit identification processing unit 34 executes the slave unit identification process. The slave unit identification process is executed after the environmental change process, and among the slave units 40, the environmental information acquired by the environmental information acquisition unit, that is, the temperature detected by the temperature sensor 41 and the atmospheric pressure sensor 42 are detected. The slave unit in which either the atmospheric pressure or the humidity detected by the humidity sensor 43 has changed is identified. Then, the area allocation processing unit 35 executes the area allocation processing. The area allocation process is executed after the slave unit identification process, and is a process of allocating one area air-conditioned by the environmental change process to the installation area of the slave unit specified by the slave unit identification process.

Specifically, the master unit 30 executes the control contents shown in FIG. 5 at the time of initial setting. This initial setting is started, for example, when the user performs a predetermined operation on the operation unit 44 of the master unit 30. When the initial setting is executed, it is assumed that each slave unit 40 is already installed in each of the areas 1 to 4 as shown in FIG. Further, it is assumed that the air conditioning unit 20 is not operating when the initial setting is executed.

When the initial setting is started, the master unit 30 first sets the number of areas N in step S11 shown in FIG. To set the number of areas N, for example, the user operates the operation unit 44 of the master unit 30 to input the number of areas 1 to 4 of the house 100 targeted by the entire building air conditioning system 10, in this case "4". Do it with.

Next, in step S12, the master unit 30 sets the area to be allocated to the area (N). N is a variable, and the number of areas, in this case, "4" is the maximum value. The area (N) is changed each time one slave unit 40 is assigned. In this case, the master unit 30 allocates each slave unit 40 in the order of area 4, area 3, area 2, and area 1.

In step S13, the master unit 30 receives the detection results of the sensors 41, 42, and 43 from each slave unit 40. As a result, the master unit 30 acquires environmental information in areas 1 to 4 in which each slave unit 40 is installed, that is, temperature, atmospheric pressure, and humidity. In this case, the master unit 30 may request each slave unit 40 to transmit the detection results of the sensors 41, 42, and 43. Further, when the power of each slave unit 40 is turned on, the detection results of the sensors 41, 42, and 43 may be automatically transmitted from each slave unit 40 to the master unit 30.

Next, in step S14, the master unit 30 determines whether or not the environmental information of each area 1 to 4 acquired in step S13 is stable within a certain range. Regarding the environmental information of a certain area, for example, when the environmental information during a predetermined period, for example, the rate of change in temperature is less than ΔT1, the master unit 30 determines that the environment of the area is stable. .. If there is an area where the environment is not stable even in one of the areas 1 to 4 (NO in step S14 of FIG. 5), the master unit 30 waits until the environment of all the areas 1 to 4 becomes stable. In this case, at least one of temperature, atmospheric pressure, and humidity may be used as the environmental information to determine whether or not the environment is stable, but these may be used in combination.

Then, when the master unit 30 determines that the environment of each of the areas 1 to 4 is stable (YES in step S14), the master unit 30 executes the initial environment storage process in step S15. As a result, the master unit 30 stores the initial environmental information of each of the areas 1 to 4, that is, the initial environmental information of the state in which the air conditioning unit 20 is not operating. The master unit 30 may store the initial environmental information of each slave unit 40 in each slave unit 40 without storing it by itself.

Next, the master unit 30 executes the environment change process in step S16. In this case, for example, if the area to be allocated is area 1, the master unit 30 controls the air conditioning unit 20 so as to perform air conditioning in area 1. Then, as shown in FIG. 7, the air conditioning unit 20 opens the on-off valve 221 corresponding to the area 1 and supplies the air-conditioned air to the area 1. As a result, the environment of the air-conditioned area 1, that is, the temperature, the atmospheric pressure, and the humidity changes.

Next, the master unit 30 executes the slave unit identification process in step S17. As a result, the slave unit 40 whose surrounding environment has changed is identified. In this case, in the initial environment storage process of step S15, if the master unit 30 stores the initial environment information, the master unit 30 can identify the slave unit 40 as follows.

That is, in this case, the master unit 30 sets a threshold value ΔT2 for use in identifying the slave unit 40. The threshold value ΔT2 is, for example, the threshold value of the rate of change of the current environmental information with respect to the initial environmental information stored in the initial environmental information processing. For example, after the start of the initial setting, the master unit 30 acquires environmental information from each slave unit 40 at any time or periodically. Then, the master unit 30 compares the acquired current environmental information with the initial environmental information stored in the initial environmental storage process, and as shown in FIG. 8, the rate of change of the environmental information exceeds the threshold value ΔT2. By detecting the slave unit 40, the slave unit 40 whose surrounding environment has changed is specified.

Further, in the initial environment storage process of step S15, if each slave unit 40 stores the initial environmental information, the master unit 30 can identify the slave unit 40 as follows. That is, the master unit 30 sets a common threshold value ΔT2 for each slave unit 40 for each slave unit 40. The slave unit 40 acquires environmental information at any time or periodically by the sensors 41 to 43, for example, after the start of the initial setting. Then, the slave unit 40 compares the acquired current environmental information with the initial environmental information stored in the initial environmental storage process, and as shown in FIG. 8, the rate of change of the environmental information exceeds the threshold value ΔT2. In this case, a signal indicating that effect, that is, the rate of change exceeds the threshold value ΔT2 is transmitted to the master unit 30. When the master unit 30 receives a signal from the slave unit 40 that the rate of change exceeds the threshold value ΔT2, the master unit 30 identifies the slave unit 40 that transmits the signal.

Next, the master unit 30 determines in step S18 of FIG. 5 whether or not the slave unit 40 specified in step S17 is one. That is, whether or not the master unit 30 has not specified two or more slave units 40 in the slave unit identification process in step S17, and has not specified any slave unit 40 even after the lapse of a predetermined period. To judge.

Here, it is premised that one slave unit 40 is installed in each of the areas 1 to 4, and in the environmental change processing in step S16, air conditioning is performed only in one area. Nevertheless, the fact that two or more slave units are specified in the slave unit identification process in step S17, that is, changes in the surrounding environmental information of the two or more slave units 40, for example, as shown in FIG. The fact that the rate has changed beyond the threshold ΔT2 means that the specified plurality of slave units 40 are installed in the same air-conditioned area or in other non-air-conditioned areas, for example. It is considered that the environment is changing due to factors other than air conditioning, such as the intrusion of outside air due to the opening of doors and windows.

Further, even though the air conditioning is performed for one area, one slave unit is not specified in the slave unit identification process in step S17, that is, in all the slave units 40, for example, as shown in FIG. The fact that the rate of change of the surrounding environment information does not exceed the threshold value ΔT2 means that none of the slave units 40 are installed in the air-conditioned area, or in the air-conditioned area, for example, a door or It is considered that the environment is changing due to factors other than air conditioning, such as the intrusion of outside air due to the opening of the windows. In any case, since the one-to-one correspondence between each slave unit 40 and each area 1 to 4 cannot be specified, the allocation of the slave unit 40 to the area fails.

Therefore, when the number of slave units 40 specified in step S17 of FIG. 5 is other than one (NO in step S18), the master unit 30 controls the air conditioning unit 20 in step S23 to control the environment in step S16. Stop individual air conditioning for one area performed in the change process. After that, as shown in step S24, the master unit 30 displays a caution on the display unit 45 of the master unit 30 and the slave unit 40. This caution display eliminates as much as possible the effects other than the effects of air conditioning by the air conditioning unit 20, such as whether windows and doors are closed and whether other air conditioning equipment is used in each area 1 to 4. This is a display to encourage you to do so.

After that, the master unit 30 returns the process to step S13. As a result, the master unit 30 does not perform the area allocation process in step S19, but re-initializes the area where the environment is changed in the environment change process in step S16, that is, the area which is the target of the allocation of the slave unit 40. Make settings.

On the other hand, when the number of slave units 40 specified in step S17 is one (YES in step S18), the master unit 30 executes the area allocation process in step S19. As a result, the master unit 30 allocates one area individually air-conditioned in the environmental change processing in step S16 to the installation area of the slave unit 40 specified in the slave unit identification processing in step S17. Next, the master unit 30 controls the air conditioning unit 20 in step S20 to stop the individual air conditioning for one area performed in the environmental change processing in step S16.

Next, in step S21, the master unit 30 subtracts 1 from the number of areas N to change the area to be allocated. The master unit 30 repeats steps S12 to S22 until the number of areas N becomes 0, and assigns corresponding slave units 40 (A) to (D) to all the areas 1 to 4 as shown in FIG. Then, when the number of areas N becomes 0 (YES in step S22 in FIG. 5), the master unit 30 determines that the allocation of the slave units 40 has been completed for all areas 1 to 4 and ends a series of processes (YES). End).

Incidentally, in the case of the present embodiment, the allocation result of each slave unit 40 to each of the areas 1 to 4 is stored in the storage area 312 of the master unit 30 as shown in FIG. In this case, each slave unit 40 has an identification ID unique to each slave unit 40. When the user operates the slave unit 40, the slave unit 40 that has received the operation transmits its own identification ID to the master unit 30 together with the input operation command. Then, the master unit 30 performs air conditioning control for the areas 1 to 4 assigned to the received identification ID based on the received operation command.

According to the embodiment described above, the master unit 30 cooperates with each slave unit 40 as an initial setting for associating each slave unit 40 with each area 1 to 4 in which each slave unit 40 is installed. , Initial environment storage processing, environment change processing, slave unit identification processing, and area allocation processing are executed in sequence. According to this, after each slave unit 40 (A) to (D) is installed in each area 1 to 4, each slave unit 40 (A) to (D) and its slave units 40 (A) to (D) Is linked to areas 1 to 4 where is actually installed. Therefore, the correspondence between the areas 1 to 4 in which the air conditioning is controlled by the slave units 40 (A) to (D) and the areas 1 to 4 in which the slave units 40 (A) to (D) are actually installed. No mistakes will occur.

Further, according to the present embodiment, when the user brings the slave units 40 (A) to (D) to the respective areas 1 to 4, the slave units 40 (A) to (D) and each area are still present. It is in a state where it is not linked with 1 to 4. Therefore, the user can use the slave units 40 (A) to (D) in the arbitrary areas 1 to 1 without being aware of the correspondence between the slave units 40 (A) to (D) and the areas 1 to 4. It can be installed in 4.

Further, according to the present embodiment, the master unit 30 automatically identifies the slave units 40 (A) to (D) installed in each of the areas 1 to 4. Therefore, the user does not need to grasp the control area of the air conditioning unit 20 at the time of initial setting. As a result, the workability at the time of installation of each of the slave units 40 (A) to (D), that is, at the time of initial setting is improved, and the time and effort required for the initial setting of the user can be saved. From the above, according to the present embodiment, in the initial setting, it is possible to save the labor of the user's work, and the areas 1 to 4 in which the air conditioning control is actually performed by the slave units 40 (A) to (D). It is possible to reduce mistakes in the correspondence relationship with the areas 1 to 4 in which the slave units 40 (A) to (D) are installed.

Further, in the whole building air conditioning system 10, the slave units 40 (A) to (D) have at least one of a temperature sensor 41, a barometric pressure sensor 42, and a humidity sensor 43 as an environmental information acquisition unit. Temperature, atmospheric pressure, and humidity are environmental information that is easily changed by air conditioning. Therefore, the slave units 40 (A) to (D) detect at least one of temperature, atmospheric pressure, and humidity, and the slave units 40 (A) to (D) are generated by the environmental change processing. Changes in the surrounding environment can be detected more accurately, and as a result, more accurate initial settings can be made.

By the way, temperature and atmospheric pressure are more susceptible to air conditioning than humidity. Therefore, it is preferable that the slave units 40 (A) to (D) have at least one of the temperature sensor 41 and the barometric pressure sensor 42 as the environmental information acquisition unit. According to this, more accurate initial setting can be performed as compared with the case where the slave units 40 (A) to (D) have only the humidity sensor 43.

Further, when the master unit 30 specifies two or more slave units in the slave unit identification process shown in step S17 of FIG. 5, or when one slave unit is not specified even after the lapse of a predetermined period, the master unit 30 of step S19. The initial setting is performed again for the area (N) whose environment has been changed in the environment change process in step S16 without performing the area allocation process. According to this, if for some reason the association between the areas 1 to 4 where the slave units 40 (A) to (D) are installed and the slave units 40 (A) to (D) cannot be specified, The master unit 30 automatically performs initial settings for the areas 1 to 4 again. As a result, even if the initial setting fails, it is not necessary for the user to associate the slave units 40 (A) to (D) with the areas 1 to 4, and as a result, the user's trouble is saved. Can be done.

Further, the master unit 30 is after the initial environmental storage process shown in step S15 of FIG. 5, provided that all changes in the environmental information received from the slave units 40 (A) to (D) are stable within a predetermined range. Execute the process. According to this, the initial setting can be performed in a state where the influence other than the air conditioning by the air conditioning unit 20 is eliminated as much as possible. Therefore, more accurate initial setting can be performed.

It should be noted that the embodiment of the present invention is not limited to the embodiments described above and in the drawings, and various modifications and extensions can be made without departing from the gist thereof.
For example, in the above embodiment, the slave unit 40 (A) is configured to be built in the master unit 30, but the slave unit 40 (A) and the master unit 30 may be configured separately.

Further, in the above embodiment, the initial setting is configured to perform the environmental change processing shown in step S16 of FIG. 5 for all areas 1 to 4. However, the present invention is not limited to this, for example, when the target area N = 1, that is, when the number of unallocated areas becomes 1, the remaining one area is used as the remaining one handset. It may be configured to be assigned to 40. According to this, the number of areas for which environmental change processing is performed can be reduced by one. Therefore, the time required for the initial setting can be shortened.

Further, in the above embodiment, the master unit 30 stores the result of associating the slave units 40 (A) to (D) with the areas 1 to 4, and each slave unit 40 together with the input operation command. It is configured to transmit its own identification ID to the master unit 30. However, the present invention is not limited to this, and the configuration may be as shown in FIG. 13, for example. That is, in the example of FIG. 13, each slave unit 40 stores its own assigned areas 1 to 4 associated with each other. In this case, when an operation is input to the slave unit 40 by the user, the slave unit 40 that receives the input transmits information about its own area 1 to 4 to the master unit 30 together with the input operation command. Then, the master unit 30 performs air conditioning control for the received areas 1 to 4 based on the received operation command. Also by this, the same action and effect as those of the above-described embodiment can be obtained.

In the drawing, 10 is the whole building air conditioning system, 20 is the air conditioning unit, 30 is the master unit, 40 is the slave unit, 41 is the temperature sensor (environmental information acquisition unit), 42 is the barometric pressure sensor (environmental information acquisition unit), and 43 is the humidity sensor. (Environmental information acquisition department).

Claims (3)

An air conditioning unit that can individually air-condition multiple areas,
A master unit that instructs the air conditioning unit to control the air conditioning in each area.
It is provided with a plurality of slave units that can communicate with the master unit and are installed in each of the areas and transmit control contents input from the user to the master unit.
The slave unit has an environmental information acquisition unit that acquires environmental information of the area where the slave unit is installed.
The master unit cooperates with each slave unit as an initial setting for associating each slave unit with each area in which each slave unit is installed.
Environmental change processing that operates the air conditioning unit to air-condition one of the areas and changes the environment of the one area.
Among the above-mentioned slave units, a slave unit identification process for identifying a slave unit whose environmental information acquired by the environmental information acquisition unit has changed, and
Area allocation processing that allocates the one area that has been air-conditioned by the environmental change processing to the installation area of the slave unit specified by the slave unit identification processing, and
As well as
When two or more slave units are specified in the slave unit identification process, or when one slave unit is not specified even after a predetermined period has passed, the master unit does not perform the area allocation process and the environment. Perform the above initial settings again for the area where the environment was changed in the change processing.
Whole building air conditioning system. The slave unit has at least one of a temperature sensor, a barometric pressure sensor, and a humidity sensor as the environmental information acquisition unit.
The whole building air conditioning system according to claim 1. The master unit executes the environmental change process on condition that all changes in the environmental information received from the slave units are stable within a predetermined range.
The whole building air conditioning system according to claim 1 or 2.

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