JP7003321B2 - Control device and control method - Google Patents

Description

The present invention relates to the control of an air conditioner.

As a control of the air conditioner, the temperature of the blown air (hereinafter, also referred to as the blown air temperature) may be adjusted for the purpose of preventing a feeling of cold air and preventing dew condensation. For example, Patent Document 1 discloses a technique of detecting a blown air temperature and controlling an air conditioner according to the detected blown air temperature.

Japanese Patent No. 504935

There is an air conditioning system in which the duct from the outside air processing unit branches and an outlet to the indoor space is provided at each branch destination. In such an air conditioning system, the blown air temperature is generally controlled based on a single air temperature in the duct.

However, due to the absorption and heat dissipation in the duct connecting the outside air processing unit and the indoor space, the temperature measured in the duct and the blown air temperature may actually differ. In addition, the temperature of the blown air may differ depending on the outlet.

If it is desired to prevent the blown air temperature from dropping too much, it is conceivable to control so that the lowest blown air temperature among the plurality of blown air temperatures does not fall below the specified temperature. Further, when it is desired to prevent the blown air temperature from rising too much, it is conceivable to control so that the highest blown air temperature among the plurality of blown air temperatures does not exceed the specified temperature. However, in the above-mentioned conventional system, it is not possible to grasp the temperature of the blown air at each outlet. Therefore, in the above-mentioned conventional system, it is unclear which outlet has the lowest or highest outlet air temperature.
Therefore, in the conventional system, there is a problem that comfort is lowered due to an excessive feeling of cold air due to an excessively low temperature of the blown air or an excessive feeling of warm air caused by an excessively high temperature of the blown air.

An object of the present invention is to solve such a problem. More specifically, the main purpose is to effectively prevent a decrease in comfort due to an excessive feeling of cold air or an excessive feeling of warm air.

The control device according to the present invention is
A blowout air temperature acquisition unit that acquires the temperature of the blown air at each of the plurality of outlets from which the air from the air conditioner is blown out as the blown air temperature, and
A representative selection unit that selects a representative outlet from the plurality of outlets based on the outlet air temperature acquired by the outlet air temperature acquisition unit.
It has an operation control unit that controls the operation of the air conditioner based on the temperature of the blown air of the representative outlet.

According to the present invention, it is possible to effectively prevent a decrease in comfort due to an excessive feeling of cold air or an excessive feeling of warm air.

The figure which shows the structural example of the air conditioning system which concerns on Embodiment 1. The figure which shows the hardware composition example of the control apparatus which concerns on Embodiment 1. FIG. The figure which shows the functional structure example of the control apparatus which concerns on Embodiment 1. FIG. The figure which shows the structural example of the refrigerant circuit which concerns on Embodiment 1. FIG. The figure which shows the structural example of the outside air processing unit which concerns on Embodiment 1. FIG. The figure explaining the representative outlet determination method which concerns on Embodiment 1. The flowchart which shows the operation example of the control apparatus which concerns on Embodiment 1. The figure which shows the structural example of the air conditioning system which concerns on Embodiment 2. The figure which shows the structural example of the air conditioning system which concerns on Embodiment 3. The figure which shows the functional structure example of the control apparatus which concerns on Embodiment 3. FIG. The figure explaining the representative outlet determination method which concerns on Embodiment 3. The flowchart which shows the operation example of the control apparatus which concerns on Embodiment 3. The figure explaining the representative outlet determination method which concerns on Embodiment 4. The flowchart which shows the operation example of the control apparatus which concerns on Embodiment 4.

Embodiment 1.
*** Explanation of configuration ***
FIG. 1 shows a configuration example of an air conditioning system according to the present embodiment.
The air conditioning system according to the present embodiment includes an outdoor unit 10, an outside air processing unit 20, and a control device 100. The outdoor unit 10 and the outside air processing unit 20 are collectively referred to as an air conditioner.

The outdoor unit 10 and the outside air processing unit 20 are connected by a refrigerant pipe 30.
Further, the outside air processing unit 20 is connected to the outdoor space by a duct 81 and a duct 82. The outside air processing unit 20 blows out indoor air through a duct 81. Further, the outside air processing unit 20 takes in outdoor air through a duct 82.
Further, the outside air processing unit 20 is connected to the interior space 90 by a duct 40.
The duct 40 is branched, and an outlet is provided at each branch destination. Air from the outside air processing unit 20 is blown out from each outlet. That is, the outside air processing unit 20 according to the present embodiment is not provided with a mechanism for individually controlling the temperature of the blown air at each outlet.
In the configuration of FIG. 1, the outlet 41A, the outlet 41B, and the outlet 41C are provided at the branch destination of the duct 40. In the following, when it is not necessary to distinguish between the outlet 41A, the outlet 41B and the outlet 41C, the outlet 41A, the outlet 41B and the outlet 41C are collectively referred to as the outlet 41.
Further, each outlet 41 is provided with a temperature measuring device 50. That is, the air outlet 41A is provided with a temperature measuring device 50A. A temperature measuring device 50B is provided at the outlet 41B. A temperature measuring device 50C is provided at the outlet 41C. When it is not necessary to distinguish between the temperature measuring device 50A, the temperature measuring device 50B, and the temperature measuring device 50C, the temperature measuring device 50A, the temperature measuring device 50B, and the temperature measuring device 50C are collectively referred to as a temperature measuring device 50. Each temperature measuring device 50 measures the temperature of the blown air (the blown air temperature) at the corresponding outlet 41. The temperature measuring device 50 is, for example, a temperature sensor.
Further, the outside air processing unit 20 is connected to the interior space 90 by a duct 43. The suction port 42 is provided in the 43. The outside air processing unit 20 takes in indoor air through the suction port 42.

The control device 100 controls the operation of the air conditioner. That is, the control device 100 controls the operation of the outdoor unit 10 and the outside air processing unit 20.
The operation performed by the control device 100 corresponds to the control method.

FIG. 2 shows a configuration example of the control device 100 according to the present embodiment.

The control device 100 according to the present embodiment is a computer.
The control device 100 includes a processor 901, a main storage device 902, an auxiliary storage device 903, and a communication device 904 as hardware.
Further, the control device 100 includes a blown air temperature acquisition unit 101, a set temperature acquisition unit 102, a representative selection unit 103, and an operation control unit 104 as functional configurations.
The auxiliary storage device 903 stores a program that realizes the functions of the blown air temperature acquisition unit 101, the set temperature acquisition unit 102, the representative selection unit 103, and the operation control unit 104.
These programs are loaded from the auxiliary storage device 903 into the main storage device 902. Then, the processor 901 executes these programs to operate the blown air temperature acquisition unit 101, the set temperature acquisition unit 102, the representative selection unit 103, and the operation control unit 104, which will be described later.
FIG. 2 schematically shows a state in which the processor 901 is executing a program that realizes the functions of the blown air temperature acquisition unit 101, the set temperature acquisition unit 102, the representative selection unit 103, and the operation control unit 104.

FIG. 3 shows an example of a functional configuration of the control device 100.

In FIG. 3, the blown air temperature acquisition unit 101 acquires the blown air temperature at each of the plurality of outlets 41. That is, the blown air temperature acquisition unit 101 acquires the blown air temperature at each outlet 41 from each temperature measuring device 50.

The set temperature acquisition unit 102 acquires the set temperature at the outlet of the blown air for each outlet 41.
For example, when the indoor space 90 is divided into a plurality of rooms and the outlet 41 is provided for each room, the set temperature acquisition unit 102 sets the set temperature for each room where the outlet 41 is provided. get. For example, when a user who uses each room sets a set temperature using a remote controller, the set temperature acquisition unit 102 receives a radio wave from the remote controller and acquires the set temperature.

The representative selection unit 103 selects a representative outlet from the plurality of outlets 41 based on the outlet air temperature acquired by the outlet air temperature acquisition unit 101 and the set temperature acquired by the set temperature acquisition unit 102.
More specifically, the representative selection unit 103 calculates the temperature difference between the outlet air temperature and the set temperature for each outlet 41, and selects the representative outlet based on the calculated temperature difference. For example, when the air conditioner is in the cooling operation, the representative selection unit 103 represents the outlet 41 in which the outlet air temperature is lower than the set temperature and the temperature difference between the outlet air temperature and the set temperature is larger. Select for the exit. Further, when the air conditioner is in the heating operation, the representative selection unit 103 sets the outlet air outlet 41 in which the outlet air temperature is higher than the set temperature and the temperature difference between the outlet air temperature and the set temperature is larger. Select as the representative air outlet.

The operation control unit 104 controls the operation of the air conditioner based on the temperature difference between the outlet air temperature of the representative outlet and the set temperature. That is, the operation control unit 104 controls the operation of the air conditioner so that the temperature of the blown air at the representative air outlet becomes equal to the set temperature.

FIG. 4 shows a configuration example of the refrigerant circuit according to the present embodiment.
As shown in FIG. 4, the outdoor unit 10 includes a compressor 11, a four-way valve 12, an outdoor heat exchanger 13, and an outdoor unit fan 14. Further, the outside air processing unit 20 has an expansion valve 21 and an outside air processing heat exchanger 22.

A refrigerant circuit is configured by connecting the compressor 11, the four-way valve 12, the outdoor heat exchanger 13, the expansion valve 21, and the outside air processing heat exchanger 22 in an annular shape by the refrigerant pipe 30.

The compressor 11 compresses low-temperature and low-pressure refrigerants and converts them into high-temperature and high-pressure refrigerants. The compressor 11 is driven by, for example, an inverter, and the capacity (the amount of refrigerant discharged per unit time) is controlled.
The four-way valve 12 switches the flow of the refrigerant according to the operation mode of the air conditioner, for example, the cooling operation or the heating operation.
The outdoor heat exchanger 13 exchanges heat between the refrigerant flowing through the refrigerant circuit and the outdoor air.
An outdoor unit fan 14 is adjacent to the outdoor heat exchanger 13. The outdoor unit fan 14 blows air to the outdoor heat exchanger 13. By controlling the rotation speed of the outdoor unit fan 14, the amount of air blown can be adjusted.
The expansion valve 21 is composed of a valve whose opening degree can be variably controlled, for example, an electronic expansion valve. By controlling the opening degree of the expansion valve 21, the amount of reduced pressure of the refrigerant is controlled.
The outside air processing heat exchanger 22 exchanges heat between the refrigerant flowing through the refrigerant circuit and the air taken in from the outside.
By controlling the rotation speed of the fan of the air supply air blowing means 24 shown in FIG. 5, the amount of air blown to the outside air processing heat exchanger 22 can be adjusted.

FIG. 5 shows a configuration example of the outside air processing unit 20.
The outside air processing unit 20 includes an outside air processing heat exchanger 22, a total heat exchanger 23, an air supply blowing means 24 for supplying outdoor air to the indoor space 90, and an exhaust blowing air for discharging indoor air to the outside. It is equipped with means 25.

*** Explanation of operation ***
Hereinafter, the operation of the control device 100 when the air conditioner is performing the cooling operation will be described.
In the cooling operation, the air taken in from the outside is cooled by the outside air processing heat exchanger 22 and blown out to the indoor space 90.

At this time, if the temperature of the blown air drops too much, problems such as deterioration of comfort or dew condensation due to a feeling of cold air occur. On the other hand, when the temperature of the blown air rises, the cooling capacity and the amount of dehumidification decrease, and the comfort of the interior space 90 decreases.

The air conditioner premised on this embodiment cannot individually control the temperature of the blown air for each outlet 41. Therefore, in the present embodiment, the control device 100 selects a representative outlet from the plurality of outlets 41 and appropriately controls the outlet air temperature of the representative outlet to control the temperature of the entire interior space 90. To be appropriate.

Specifically, the blown air temperature acquisition unit 101 acquires the blown air temperature of the plurality of outlets 41 from the plurality of temperature measuring devices 50 for each control cycle.
Further, the set temperature acquisition unit 102 acquires the set temperature of the region of the outlet of each outlet 41 for each control cycle.

Next, the representative selection unit 103 calculates the difference ΔTsa (= Tsa-Tsa_set) between the outlet air temperature Tsa at each outlet 41 and the set temperature Tsa_set of the outlet.

Next, the representative selection unit 103 selects the outlet 41 having Tsa <Tsa_set and the largest ΔTsa as the representative outlet.
Then, the operation control unit 104 controls the air conditioner according to the value of the outlet air temperature Tsa_r of the representative outlet.

FIG. 6 describes a method of selecting a representative air outlet by the representative selection unit 103.
Note that FIG. 6 omits the illustration of components that are not directly related to the description.
For example, in FIG. 6, the outdoor unit 10, the temperature measuring device 50, and the control device 100 are not shown.

In the example of FIG. 6, the set temperature Tsa_set in the region of the outlet of the outlet 41A is 13 ° C. Further, the set temperature Tsa_set in the region of the outlet of the outlet 41B is 13 ° C. Further, the set temperature Tsa_set in the region of the outlet of the outlet 41C is 14 ° C.
Further, the outlet air temperature Tsa of the outlet 41A is 12 ° C. Further, the outlet air temperature Tsa of the outlet 41B is 15.5 ° C. Further, the outlet air temperature Tsa of the outlet 41C is 12 ° C.
In this case, ΔTsa of the outlet 41A is -1 ° C. Further, ΔTsa of the outlet 41B is + 2.5 ° C. Further, ΔTsa of the outlet 41C is −2 ° C.
The representative selection unit 103 selects the outlet 41C as the representative outlet.

Since the set temperature Tsa_set may be changed sequentially and the outlet air temperature Tsa also changes from moment to moment, the representative selection unit 103 sequentially updates the representative outlet.

The operation control unit 104 controls the operation of the outdoor unit 10 and the outside air processing unit 20 so as to raise the outlet air temperature Tsa_r when the outlet air temperature Tsa_r at the representative outlet is lower than the set temperature Tsa_set.

When the heating operation is performed, the representative selection unit 103 selects the outlet 41 having Tsa> Tsa_set and the largest ΔTsa as the representative outlet in order to prevent overheating.
Then, the operation control unit 104 controls the operation of the outdoor unit 10 and the outside air processing unit 20 so as to lower the outlet air temperature Tsa_r when the outlet air temperature Tsa_r of the representative outlet exceeds the set temperature Tsa_set.

It is conceivable that the operation control unit 104 controls the outdoor unit 10 and the outside air processing unit 20 by, for example, adjusting the opening degree of the expansion valve, adjusting the compressor frequency, adjusting the air volume of the fan, and the like.
For example, the operation control unit 104 can raise the opening degree of the expansion valve, raise the frequency of the compressor, lower the air volume of the fan, or combine these to lower the blown air temperature Tsa_r.
The operation control unit 104 may control the operation of the outdoor unit 10 and the outside air processing unit 20 by a method other than these.

Next, an operation example of the control device 100 according to the present embodiment will be described with reference to the flowchart shown in FIG. 7.

In step ST1, the outlet air temperature acquisition unit 101 acquires the outlet temperature Tsa of each outlet 41 from each temperature measuring device 50. Further, the set temperature acquisition unit 102 acquires the set temperature Tsa_set in the region of the outlet of each outlet 41.

Next, in step ST2, the representative selection unit 103 calculates the difference ΔTsa (= Tsa-Tsa_set) between the blown air temperature Tsa and the set temperature Tsa_set for each outlet 41.

Next, in step ST3, the representative selection unit 103 selects a representative outlet based on Δtsa.
As described above, during the cooling operation, the representative selection unit 103 selects the outlet 41 having Tsa <Tsa_set and the largest ΔTsa as the representative outlet. On the other hand, during the heating operation, the representative selection unit 103 selects the outlet 41 having Tsa> Tsa_set and the largest ΔTsa as the representative outlet.

Next, in step ST4, the operation control unit 104 compares the outlet air temperature Tsa_r of the representative outlet with the set temperature Tsa_set of the representative outlet.

When the outlet air temperature Tsa_r of the representative outlet is larger than the set temperature Tsa_set of the representative outlet (YES in step ST4), the operation control unit 104 causes the outlet air temperature Tsa_r of the representative outlet to be lowered in step ST5. , Controls the outdoor unit 10 and the outside air processing unit 20.
The operation control unit 104 controls, for example, lowering the opening degree of the expansion valve, lowering the frequency of the compressor, increasing the air volume of the fan, and the like.

On the other hand, when the outlet air temperature Tsa_r of the representative outlet is not larger than the set temperature Tsa_set of the representative outlet (NO in step ST4), the operation control unit 104 determines that the outlet air temperature Tsa_r of the representative outlet is set in step ST6. It is determined whether or not the temperature is smaller than the set temperature Tsa_set of the representative air outlet.

When the outlet air temperature Tsa_r of the representative outlet is smaller than the set temperature Tsa_set of the representative outlet (YES in step ST6), the operation control unit 104 causes the outlet air temperature Tsa_r of the representative outlet to be raised in step ST7. , Controls the outdoor unit 10 and the outside air processing unit 20.
The operation control unit 104 controls, for example, to increase the opening degree of the expansion valve, increase the frequency of the compressor, decrease the air volume of the fan, and the like.

In step ST8, the operation control unit 104 further determines whether or not to continue the processing after ST1, and when the processing after ST1 is continued (NO in step ST8), the processing after ST1 is repeated.

In step ST4, the representative selection unit 103 compares the outlet air temperature Tsa_r of the representative outlet with the set temperature Tsa_set of the representative outlet, but the allowable width ε may be arbitrarily set.
That is, the representative selection unit 103 may compare Tsa_r with (Tsa_set + ε). In this case, step ST5 is performed when Tsa_r is larger than (Tsa_set + ε).
Further, also in step ST6, the representative selection unit 103 compares the outlet air temperature Tsa_r of the representative outlet with the set temperature Tsa_set of the representative outlet, but the allowable width ε may be arbitrarily set.
That is, the representative selection unit 103 may compare Tsa_r with (Tsa_set-ε). In this case, step ST7 is performed when Tsa_r is smaller than (Tsa_set-ε).
By doing so, the hunting of control can be relaxed.

*** Explanation of the effect of the embodiment ***
As described above, the control device 100 according to the present embodiment adjusts the outlet air temperature after acquiring the outlet air temperature of all the outlets. Therefore, according to the present embodiment, it is possible to prevent problems such as a decrease in comfort and the occurrence of dew condensation due to an excessively low temperature of the blown air.

In the above, the operation during the cooling and dehumidifying operation has been mainly described, but it is also possible to control the blowing air temperature so that it does not become too high during the heating operation. That is, according to the present embodiment, it is possible to prevent a decrease in comfort due to an excessive rise in the temperature of the blown air.

Further, the control device 100 according to the present embodiment can be applied to an air conditioning system other than the air conditioning system shown in FIG. For example, in FIG. 1, the control device 100 controls the outside air processing unit 20, but the internal adjustment system may be controlled instead of the outside air processing unit 20. The internal adjustment system sucks in the air in the indoor space 90 and blows out the air after the temperature is adjusted by the heat exchanger to the indoor space 90.

Further, in the above, it is assumed that the set temperature is different for each outlet of the blown air, but a common set temperature may be set in all the regions of the blowout destination.
In this case, the set temperature acquisition unit 102 acquires the set temperature from, for example, a management device that centrally manages the set temperature of the indoor space 90.
Further, in this case, the calculation process of ΔTsa of each outlet 41 (step ST2 in FIG. 7) is omitted. That is, in the cooling operation, the representative selection unit 103 selects the outlet 41 in which the lowest outlet air temperature Tsa among the outlet air temperatures Tsa lower than the set temperature is measured as the representative outlet. Further, during the heating operation, the representative selection unit 103 selects the outlet 41 in which the highest outlet air temperature Tsa among the outlet air temperatures Tsa higher than the set temperature is measured as the representative outlet.

Embodiment 2.
In this embodiment, the difference from the first embodiment will be mainly described.
The matters not described below are the same as those in the first embodiment.

*** Explanation of configuration ***
FIG. 8 shows a configuration example of the air conditioning system according to the present embodiment.
Compared with FIG. 1, in FIG. 8, the temperature measuring device 51 is provided. That is, in FIG. 1, a temperature measuring device 50 is provided for each outlet 41, but in FIG. 8, one temperature measuring device 51 measures the temperature of the blown air of a plurality of outlets 41. The temperature measuring device 51 is, for example, an infrared sensor. The temperature measuring device 51 is arranged at a position where the outlet air temperature of all the outlets 41 can be measured.
The temperature measuring device 51 may be realized by a dedicated device for the purpose of measuring the temperature of the blown air. Further, the temperature measuring device 51 may be realized by a device provided for another purpose (measurement of temperature of other elements, counting of the number of people in the room, etc.).
Since the other configurations shown in FIG. 8 are the same as those shown in FIG. 1, the description thereof will be omitted.

*** Explanation of operation ***
The temperature measuring device 51 measures the surface temperature of each outlet 41 as the temperature of the blown air of each outlet 41.
Then, the temperature measuring device 51 notifies the control device 100 of the measured blown air temperature of each outlet 41. Since the subsequent operations of the control device 100 are the same as those shown in the first embodiment, the description thereof will be omitted.

*** Explanation of the effect of the embodiment ***
In the present embodiment, by providing the temperature measuring device 51, it is not necessary to provide the temperature measuring device for each outlet 41.
Further, in this implementation, the temperature measuring device 51 can be realized by a device provided for another purpose. Therefore, according to the present embodiment, the cost can be suppressed.

Embodiment 3.
In this embodiment, the differences between the first embodiment and the second embodiment will be mainly described.
The matters not described below are the same as those in the first and second embodiments.

*** Explanation of configuration ***
FIG. 9 shows a configuration example of the air conditioning system according to the present embodiment.
Compared with FIG. 8, in FIG. 9, the region of the outlet of the blown air of the outlet 41A is treated as the region 60A. Further, the region where the blown air of the blowout port 41B is blown out is treated as the region 60B. Further, the region where the blown air of the blowout port 41C is blown out is treated as the region 60C. The area 60A, the area 60B, and the area 60C are areas where the blown air from the corresponding outlet 41 reaches. In the following, when it is not necessary to distinguish between the area 60A, the area 60B and the area 60C, the area 60A, the area 60B and the area 60C are collectively referred to as the area 60.
Further, in FIG. 9, a user detection device 52 is provided. The user detection device 52 detects whether or not a user who uses an air-conditioned object, specifically, an indoor space 90, exists in each area 60. Then, the user detection device 52 notifies the control device 100 of the detection result for each area 60. The user detection device 52 is, for example, a motion sensor.
The user detection device 52 may be realized by a dedicated device that detects the presence or absence of a user in order to adjust the temperature of the blown air. Further, the user detection device 52 may be realized by the temperature measuring device 51. In FIG. 9, the user detection device 52 is a dedicated device.
Since the other configurations shown in FIG. 9 are the same as those shown in FIG. 8, the description thereof will be omitted.

FIG. 10 shows an example of a functional configuration of the control device 100 according to the present embodiment.
In FIG. 10, a detection result acquisition unit 105 is added as compared with FIG.

The detection result acquisition unit 105 acquires the detection result of the user detection device 52. That is, the detection result acquisition unit 105 acquires the detection result of whether or not the air-conditioned object exists in the region 60 of the outlet of the blown air for each outlet 41.
The detection result acquisition unit 105 is also realized by a program in the same manner as the blown air temperature acquisition unit 101, the set temperature acquisition unit 102, the representative selection unit 103, and the operation control unit 104. Then, the program that realizes the detection result acquisition unit 105 is executed by the processor 901.

In the present embodiment, the representative selection unit 103 selects a representative outlet from the outlet 41 in which the object is present, based on the temperature of the outlet air in which the object is present. That is, the representative selection unit 103 calculates the temperature difference between the blown air temperature of the blowout port 41 in which the object is present and the set temperature. Then, the representative selection unit 103 selects the representative outlet from the outlets 41 in which the object exists, based on the calculated temperature difference.

Since the blown air temperature acquisition unit 101, the set temperature acquisition unit 102, and the operation control unit 104 are the same as those shown in FIG. 3, the description thereof will be omitted.

*** Explanation of operation ***
In the present embodiment, the representative selection unit 103 analyzes the detection result by the user detection device 52 when selecting the representative outlet, and the outlet 41 corresponding to the region 60 where there is no object (user of the indoor space 90). Is excluded from the candidates for the representative outlet.

FIG. 11 describes a method of selecting a representative outlet according to the present embodiment.
Note that FIG. 11 omits the illustration of components that are not directly related to the description.
For example, in FIG. 11, the outdoor unit 10 and the control device 100 are not shown.

In the example of FIG. 11, the set temperature Tsa_set of the region 60A is 13 ° C. Further, the set temperature Tsa_set of the region 60B is 13 ° C. Further, the set temperature Tsa_set of the region 60C is 14 ° C.
Further, the outlet air temperature Tsa of the outlet 41A is 12 ° C. Further, the outlet air temperature Tsa of the outlet 41B is 15.5 ° C. Further, the outlet air temperature Tsa of the outlet 41C is 12 ° C.
In the example of FIG. 11, ΔTsa of the outlet 41A is -1 ° C. Further, ΔTsa of the outlet 41B is + 2.5 ° C. Further, ΔTsa of the outlet 41C is −2 ° C.
There are users in areas 60A and 60B, but there are no users in area 60C. Therefore, the representative selection unit 103 excludes the outlet 41C corresponding to the area 60C where there is no user from the candidates for the representative outlet.
As a result, the representative selection unit 103 selects the outlet 41A having a negative Δtsa as the representative outlet.

Next, an operation example of the control device 100 according to the present embodiment will be described with reference to the flowchart shown in FIG.

Since steps ST1 and ST2 are the same as those shown in FIG. 7, the description thereof will be omitted.

In step ST11, the detection result acquisition unit 105 acquires the detection result from the user detection device 52. In the example of FIG. 11, the detection result acquisition unit 105 acquires the detection result that there is a user in the area 60A and the area 60B, but there is no user in the area 60C.

Next, in step ST12, the representative selection unit 103 excludes the outlet 41 corresponding to the area 60 where there is no user from the candidates for the representative outlet. In the example of FIG. 11, the representative selection unit 103 excludes the outlet 41C corresponding to the region 60C from the candidates for the representative outlet.

Next, in step ST13, the representative selection unit 103 selects the representative outlet based on ΔTsa.
More specifically, the representative selection unit 103 selects a representative outlet from the candidates for the representative outlet after excluding the outlet 41 corresponding to the area 60 where there is no user.

Since steps ST4 to ST8 are the same as those shown in FIG. 7, the description thereof will be omitted.

*** Explanation of the effect of the embodiment ***
As described above, in the present embodiment, the outlet corresponding to the area where there is no user is excluded from the candidates for the representative outlet. Therefore, it is possible to prevent a decrease in comfort due to an excessive feeling of cold air in the area where the user is present, and on the other hand, it is possible to prevent a decrease in comfort due to a decrease in cooling capacity and a decrease in dehumidification amount in the interior space 90 as a whole. be able to.
In the above, the explanation has been given by taking a user who is a human as an object of air conditioning as an example. The object of air conditioning is not limited to humans, but may be animals or articles.

Embodiment 4.
In this embodiment, differences from the third embodiment will be mainly described.
The matters not described below are the same as those in the third embodiment.

*** Explanation of configuration ***
Also in this embodiment, the configuration example of the air conditioning system is as shown in FIG.
Further, an example of the functional configuration of the control device 100 is as shown in FIG.

*** Explanation of operation ***
In this embodiment, two set temperatures Tsa_set are prepared. More specifically, a manned set temperature Tsa_set1 when there is a user in the area 60 and an unmanned set temperature Tsa_set2 when there is no user in the area 60 are prepared.
Then, in the present embodiment, the representative selection unit 103 selects the manned set temperature Tsa_set1 in the area 60 where the user is present, based on the detection result by the user detection device 52. On the other hand, in the area 60 where there is no user, the representative selection unit 103 selects the unmanned set temperature Tsa_set2. It is conceivable to set the manned set temperature Tsa_set1 to a temperature that does not give an excessive feeling of cold air to the user. Further, it is conceivable to set the unmanned set temperature Tsa_set2 to a temperature at which dew condensation does not occur.
The manned set temperature Tsa_set1 corresponds to the first set temperature. Further, the unmanned set temperature Tsa_set2 corresponds to the second set temperature.
The representative selection unit 103 selects a representative outlet based on the selected manned set temperature Tsa_set1 or unmanned set temperature Tsa_set2.

FIG. 13 describes a method of selecting a representative outlet according to the present embodiment.
Note that FIG. 13 omits the illustration of components that are not directly related to the description.
For example, in FIG. 13, the outdoor unit 10 and the control device 100 are not shown.

In the example of FIG. 13, the manned set temperature Tsa_set1 of the region 60A is 13 ° C., and the unmanned set temperature Tsa_set2 is 11 ° C. Further, the manned set temperature Tsa_set1 in the region 60B is 13 ° C., and the unmanned set temperature Tsa_set2 is 11 ° C. Further, the manned set temperature Tsa_set1 in the region 60C is 14 ° C., and the unmanned set temperature Tsa_set2 is 11 ° C.
Further, the outlet air temperature Tsa of the outlet 41A is 12 ° C. Further, the outlet air temperature Tsa of the outlet 41B is 15.5 ° C. Further, the outlet air temperature Tsa of the outlet 41C is 12 ° C.
Since there is a user in the area 60A, the representative selection unit 103 selects 13 ° C., which is the manned set temperature Tsa_set1, for the outlet 41A. Further, since there are users in the area 60B, the representative selection unit 103 selects 13 ° C., which is the manned set temperature Tsa_set1, for the outlet 41B. On the other hand, since there is no user in the region 60C, the representative selection unit 103 selects 11 ° C., which is the unmanned set temperature Tsa_set2, for the outlet 41C.
As a result, ΔTsa of the outlet 41A is -1 ° C. Further, ΔTsa of the outlet 41B is + 2.5 ° C. Further, ΔTsa of the outlet 41C is + 1 ° C.
As a result, the representative selection unit 103 selects the outlet 41A having a negative Δtsa as the representative outlet.

Next, an operation example of the control device 100 according to the present embodiment will be described with reference to the flowchart shown in FIG.

In step ST14, the outlet air temperature acquisition unit 101 acquires the outlet temperature Tsa of each outlet 41 from each temperature measuring device 50. Further, the set temperature acquisition unit 102 acquires the manned set temperature Tsa_set1 and the unmanned set temperature Tsa_set2 in the outlet region 60 of each outlet 41.

Next, in step ST11, the detection result acquisition unit 105 acquires the detection result from the user detection device 52. In the example of FIG. 13, the detection result acquisition unit 105 acquires the detection result that there is a user in the area 60A and the area 60B, but there is no user in the area 60C.

Next, in step ST15, the representative selection unit 103 calculates ΔTsa (= Tsa-Tsa_set) for each outlet 41. More specifically, in the detection result from the user detection device 52, the representative selection unit 103 has a difference ΔTsa (= Tsa-Tsa_set1) between the blown air temperature Tsa and the manned set temperature Tsa_set1 in the region 60 where the user is present. Is calculated. On the other hand, in the region 60 where there is no user, the difference ΔTsa (= Tsa-Tsa_set2) between the blown air temperature Tsa and the unmanned set temperature Tsa_set2 is calculated.
In the example of FIG. 13, the representative selection unit 103 uses the manned set temperature Tsa_set1 for the outlet 41A and the outlet 41B. On the other hand, for the outlet 41C, the representative selection unit 103 uses the unmanned set temperature Tsa_set2.

Since steps ST3 to ST8 are the same as those shown in FIG. 7, the description thereof will be omitted.

*** Explanation of the effect of the embodiment ***
As described above, in the present embodiment, the manned set temperature Tsa_set1 and the unmanned set temperature Tsa_set2 are prepared. Then, in the present embodiment, one of the manned set temperature Tsa_set1 and the unmanned set temperature Tsa_set2 is selected for each area depending on the presence or absence of the user. By setting the unmanned set temperature Tsa_set2 to a temperature at which dew condensation does not occur, it is possible to prevent the occurrence of dew condensation in addition to the effect of the third embodiment.

Although the embodiments of the present invention have been described with reference to the drawings, the specific configuration is not limited to these embodiments and can be changed without departing from the gist of the invention.
Further, two or more of these embodiments may be combined and carried out.
Alternatively, one of these embodiments may be partially implemented.
Alternatively, two or more of these embodiments may be partially combined and carried out.

*** Explanation of hardware configuration ***
Finally, a supplementary explanation of the hardware configuration of the control device 100 will be given.
The processor 901 shown in FIG. 2 is an IC (Integrated Circuit) that performs processing.
The processor 901 is a CPU (Central Processing Unit), a DSP (Digital Signal Processor), or the like.
The main storage device 902 shown in FIG. 2 is a RAM (Random Access Memory).
The auxiliary storage device 903 shown in FIG. 2 is a ROM (Read Only Memory), a flash memory, an HDD (Hard Disk Drive), or the like.
The communication device 904 shown in FIG. 2 is an electronic circuit that executes data communication processing.
The communication device 904 is, for example, a communication chip or a NIC (Network Interface Card).

Further, the OS (Operating System) is also stored in the auxiliary storage device 903.
Then, at least a part of the OS is executed by the processor 901.
The processor 901 executes a program that realizes the functions of the blown air temperature acquisition unit 101, the set temperature acquisition unit 102, the representative selection unit 103, the operation control unit 104, and the detection result acquisition unit 105 while executing at least a part of the OS. ..
When the processor 901 executes the OS, task management, memory management, file management, communication control, and the like are performed.
Further, at least one of the information, data, signal value, and variable value indicating the processing result of the blown air temperature acquisition unit 101, the set temperature acquisition unit 102, the representative selection unit 103, the operation control unit 104, and the detection result acquisition unit 105 , Main storage device 902, auxiliary storage device 903, and stored in at least one of the registers and cache memory in the processor 901.
Further, the programs that realize the functions of the blown air temperature acquisition unit 101, the set temperature acquisition unit 102, the representative selection unit 103, the operation control unit 104, and the detection result acquisition unit 105 are magnetic disks, flexible disks, optical disks, compact disks, and Blu-ray discs. (Registered trademark) It may be stored in a portable recording medium such as a disc or a DVD. Then, a portable recording medium containing a program that realizes the functions of the blown air temperature acquisition unit 101, the set temperature acquisition unit 102, the representative selection unit 103, the operation control unit 104, and the detection result acquisition unit 105 is commercially distributed. You may.

Further, the "section" of the blown air temperature acquisition unit 101, the set temperature acquisition unit 102, the representative selection unit 103, the operation control unit 104, and the detection result acquisition unit 105 is referred to as a "circuit" or "process" or "procedure" or "process". May be read as ".
Further, the control device 100 may be realized by a processing circuit. The processing circuit is, for example, a logic IC (Integrated Circuit), a GA (Gate Array), an ASIC (Application Specific Integrated Circuit), or an FPGA (Field-Programmable Gate Array).
In this case, the blown air temperature acquisition unit 101, the set temperature acquisition unit 102, the representative selection unit 103, the operation control unit 104, and the detection result acquisition unit 105 are each realized as a part of the processing circuit.
In this specification, the superordinate concept of the processor and the processing circuit is referred to as "processing circuit Lee".
That is, the processor and the processing circuit are specific examples of the "processing circuit Lee", respectively.

10 outdoor unit, 11 compressor, 12 four-way valve, 13 outdoor heat exchanger, 14 outdoor unit fan, 20 outdoor air treatment unit, 21 expansion valve, 22 outdoor air treatment heat exchanger, 23 total heat exchanger, 24 air supply ventilation Means, 25 exhaust ventilation means, 30 refrigerant pipes, 40 ducts, 41 outlets, 42 suction ports, 43 ducts, 50 temperature measuring devices, 51 temperature measuring devices, 52 user detection devices, 60 areas, 81 ducts, 82 ducts. , 90 indoor space, 100 control device, 101 blown air temperature acquisition unit, 102 set temperature acquisition unit, 103 representative selection unit, 104 operation control unit, 105 detection result acquisition unit, 901 processor, 902 main storage device, 903 auxiliary storage device. , 904 communication device.

Claims (8)

A blowout air temperature acquisition unit that acquires the temperature of the blown air at each of the plurality of outlets from which the air from the air conditioner is blown out as the blown air temperature, and
For each outlet, a set temperature acquisition unit that acquires the set temperature at the outlet of the blown air,
A representative selection unit that calculates the temperature difference between the outlet air temperature and the set temperature for each outlet and selects a representative outlet from the plurality of outlets based on the calculated temperature difference .
A control device having an operation control unit that controls the operation of the air conditioner based on the temperature difference between the outlet air temperature of the representative outlet and the set temperature . The representative selection unit is
When the air conditioner is in cooling operation, an outlet whose outlet air temperature is lower than the set temperature and whose temperature difference between the outlet air temperature and the set temperature is larger is selected as the representative outlet.
When the air conditioner is in heating operation, the representative outlet is selected from an outlet in which the outlet air temperature is higher than the set temperature and the temperature difference between the outlet air temperature and the set temperature is larger. The control device described in. The control device further
Each outlet has a detection result acquisition unit that acquires the detection result of whether or not an air-conditioned object exists at the outlet of the blown air.
The representative selection unit is
The control device according to claim 1, wherein the representative outlet is selected from the outlets in which the object is present, based on the temperature difference between the outlet air temperature in which the object is present and the set temperature . The operation control unit
The control device according to claim 3 , which controls the operation of the air conditioner based on the temperature difference between the outlet air temperature of the representative outlet and the set temperature. A blowout air temperature acquisition unit that acquires the temperature of the blown air at each of the plurality of outlets from which the air from the air conditioner is blown out as the blown air temperature, and
For each outlet, a detection result acquisition unit that acquires the detection result of whether or not there is an air-conditioned object at the outlet of the blown air,
For each outlet, a first set temperature, which is a set temperature when the object is present at the outlet of the blown air, and a second set temperature, which is a set temperature when the object is not present at the blowout destination of the blown air. And the set temperature acquisition unit to acquire
At the outlet where the object is present, the temperature difference between the outlet air temperature and the first set temperature is calculated, and at the outlet where the object is not present, the temperature difference between the outlet air temperature and the second set temperature is calculated. Then, based on the calculated temperature difference , a representative selection unit that selects a representative outlet from the plurality of outlets, and a representative selection unit.
When the representative outlet is an outlet in which the object is present, the operation of the air conditioner is controlled based on the temperature difference between the outlet air temperature of the representative outlet and the first set temperature, and the representative outlet is used. When the outlet is an outlet in which the object does not exist, an operation control unit that controls the operation of the air conditioner is provided based on the temperature difference between the outlet air temperature of the representative outlet and the second set temperature . Control device to have. The blown air temperature acquisition unit is
The control device according to claim 1 or 5 , wherein the temperature of the blown air at each of the plurality of outlets measured by a single temperature measuring device is acquired as the blown air temperature. The computer obtains the temperature of the blown air at each of the multiple outlets from which the air from the air conditioner is blown out as the blown air temperature.
The computer acquires the set temperature at the outlet of the blown air for each outlet.
The computer calculates the temperature difference between the outlet air temperature and the set temperature for each outlet, and selects a representative outlet from the plurality of outlets based on the calculated temperature difference .
A control method in which the computer controls the operation of the air conditioner based on the temperature difference between the outlet air temperature of the representative outlet and the set temperature . The computer obtains the temperature of the blown air at each of the multiple outlets from which the air from the air conditioner is blown out as the blown air temperature.
The computer acquires the detection result of whether or not there is an air-conditioned object at the outlet of the blown air for each outlet.
For each outlet, the computer has a first set temperature which is a set temperature when the object is present at the outlet of the blown air and a set temperature when the object does not exist at the blowout destination of the blown air. Get the set temperature of 2 and
The computer calculates the temperature difference between the outlet air temperature and the first set temperature at the outlet where the object is present, and the outlet air temperature and the second set temperature at the outlet where the object is not present. The temperature difference is calculated, and based on the calculated temperature difference , a representative outlet is selected from the plurality of outlets.
When the representative outlet is an outlet in which the object is present, the computer controls the operation of the air conditioner based on the temperature difference between the outlet air temperature of the representative outlet and the first set temperature. If the representative outlet is an outlet in which the object does not exist, the control for controlling the operation of the air conditioner is based on the temperature difference between the outlet air temperature of the representative outlet and the second set temperature. Method.

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