JP2014085077A - Air-conditioning control system, air-conditioning control device, air-conditioning control method, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To keep user's comfort as much as possible in controlling air-conditioning to have a plurality of air-conditioning regions in one space.SOLUTION: An air-conditioning control device includes: a human distribution state determining unit for determining a distribution state of humans in a space on the basis of detection information output by a sensor detecting a prescribed object to be detected in the space; an air-conditioning control unit defining a plurality of air-conditioning environment regions in which different air-conditioning environments are set in the space, and controlling air-conditioning equipment to change the distribution of the air-conditioning environment regions in the space on the basis of the distribution state of humans determined by the human distribution state determining unit; and a display information creating unit for creating display information to display a situation of each of the plurality of air-conditioning environment regions in the space on a display device.

Description

  The present invention relates to an air conditioning control system, an air conditioning control device, an air conditioning control method, and a program.

  In recent years, the demand for energy saving has increased. Of the electrical facilities, the air conditioning facility is one of high power consumption, so reducing the power of the air conditioning is effective in terms of energy saving.

  Then, the following are known as an air-conditioning control apparatus. In other words, when there are few users in the air-conditioning control target space, this air-conditioning control device divides the space into a normal cooling area and a cooling stop area, performs normal operation of the air conditioning equipment in the normal cooling area, Stop operation of air conditioning equipment in the cooling stop area. In addition, when there are many users in the air conditioning control target space, this air conditioning control device sets the space separately into a normal cooling area and a weak cooling area, performs normal operation of the air conditioning equipment in the normal cooling area, This is to perform weak operation of the air conditioning equipment in the weak cooling area (for example, see Patent Document 1).

JP 2009-299933 A

If the cooling area is divided as in Patent Document 1, for example, energy can be saved as compared with the case where the entire space is uniformly air-conditioned by normal cooling.
However, when the cooling area in the space is divided as in Permitted Document 1, there is a possibility that people will concentrate on one cooling area. In such a case, for example, in a cooling area where people are concentrated, the user feels cramped due to excessive crowding, or the set temperature becomes difficult to maintain due to an increase in heat load. Thereby, the comfort of the person who exists in the air_conditioning | cooling area may be impaired.

  The present invention has been made in view of such circumstances, and in performing air-conditioning control so as to form a plurality of air-conditioning regions for one space, it is intended to keep user comfort as much as possible. Objective.

  In order to solve the problems described above, an air conditioning control system according to an aspect of the present invention includes an air conditioning facility that performs air conditioning of a space, a sensor that detects a predetermined detection target in the space, a display device, and an air conditioning control device. The air conditioning control device includes a human distribution state determination unit that determines a distribution state of people in the space based on detection information output by the sensor, and a plurality of air conditioning environments that are set differently in the space. An air conditioning control unit that forms an air conditioning environment region and controls the air conditioning equipment to change the distribution of the air conditioning environment region in the space based on the distribution state of the person determined by the human distribution state determination unit; A display information generation unit configured to generate display information for causing the display device to display a situation for each of a plurality of air-conditioning environment areas in the space.

  Further, in the air conditioning control system of the present invention, the human distribution state determination unit determines the presence or absence of an overly air-conditioned environment region where the number of people or the density of people is a certain value or more as the distribution state of the people in the space, The air conditioning control unit expands the overcrowded air conditioning environment region and reduces each air conditioning environment region other than the overcrowded air conditioning environment region when the person distribution state determination unit determines that the overcrowded air conditioning environment region exists. May be.

  Further, in the air conditioning control system of the present invention, the human distribution state determination unit determines the presence or absence of a sparsely air-conditioned environment region in which the number of people or the density of people is a certain value or less as the distribution state of the people in the space, The air-conditioning control unit expands the over-condensed air-conditioning environment region and determines the over-condensed air-conditioning environment when the human-distribution state determination unit determines that the over-air-conditioning environment region exists and the de-populated air-conditioning environment region The depopulated air conditioning environment area may be preferentially reduced from the air conditioning environment areas other than the area.

  In the air conditioning control system of the present invention, the display information generation unit may generate the display information including information indicating a distribution state for each of a plurality of air conditioning environment regions in the current space.

  Further, in the air conditioning control system of the present invention, the display information generating unit is an actual temperature for each of the plurality of air conditioning environment areas detected at present as information indicating a temperature state for each of the plurality of air conditioning environment areas in the current space. The display information including information indicating at least one of the set temperatures for each of the plurality of air-conditioning environment regions currently set as target values by the air-conditioning control unit may be generated.

  In the air conditioning control system of the present invention, the display information generating unit may generate the display information including information indicating a distribution state for each of a plurality of air conditioning environment regions in the space that is to be formed after a certain time. Good.

  Further, in the air conditioning control system of the present invention, the display information generation unit is configured such that the actual temperature for each of the plurality of air conditioning environment regions predicted after a certain time and the air conditioning control unit are constant as the temperature state for each of the plurality of air conditioning environment regions. You may produce | generate the said display information containing the information which shows at least any one of the preset temperature for every some air-conditioning environment area | region which is set as a target value after time.

  An air conditioning control device according to an aspect of the present invention includes a human distribution state determination unit that determines a human distribution state in the space based on detection information output from a sensor that detects a predetermined detection target in the space, A plurality of air-conditioning environment areas, each having a different air-conditioning environment, are formed, and air-conditioning is performed so as to change the distribution of the air-conditioning environment area in the space based on the person distribution state determined by the person distribution state determination unit An air conditioning control unit that controls equipment and a display information generation unit that generates display information for causing a display device to display a situation for each of a plurality of air conditioning environment regions in the space.

  The air conditioning control method as one aspect of the present invention includes a person distribution state determination step of determining a person distribution state in the space based on detection information output from a sensor that detects a predetermined detection target in the space, A plurality of air-conditioning environment areas in which different air-conditioning environments are set in the space are formed, and the air-conditioning environment area in the space is determined based on the person distribution state determined in the person distribution state determination step. An air conditioning control step for controlling the air conditioning equipment so as to change the distribution, and a display information generation step for generating display information for causing the display device to display the status of each of the plurality of air conditioning environment regions in the space.

  In addition, a program as one aspect of the present invention includes a human distribution state determination step of determining, on a computer, a distribution state of people in the space based on detection information output by a sensor that detects a predetermined detection target in the space. A plurality of air-conditioning environment areas in which different air-conditioning environments are set in the air-conditioning equipment for air-conditioning the space are formed, and the air-conditioning environment in the space is determined based on the person distribution state determined in the person distribution state determination step An air conditioning control step for controlling the air conditioning equipment so as to change the distribution of the region, and a display information generation step for generating display information for causing the display device to display the status of each of the plurality of air conditioning environment regions in the space are executed. Is for.

  As described above, according to the present invention, it is possible to maintain the comfort of the user when performing air conditioning control so as to form a plurality of air conditioning regions for one space. .

It is a figure which shows the structural example of the air-conditioning control system and air-conditioning control apparatus in 1st Embodiment. It is a figure which shows an example of the content of the air-conditioning condition image displayed on a display apparatus in 1st Embodiment. It is a figure which shows an example of the content of the air-conditioning condition image after the air-conditioning control change displayed on a display apparatus in 1st Embodiment. It is a figure which shows the example of a process sequence which the air-conditioning control apparatus in 1st Embodiment performs. It is a figure which shows an example of the content of the air-conditioning condition image after the air-conditioning control change displayed on a display apparatus in 2nd Embodiment. It is a figure which shows the example of a process sequence which the air-conditioning control apparatus in 2nd Embodiment performs. It is a figure which shows the example of a display mode of the temperature display area as a modification in this embodiment.

<First Embodiment>
[Configuration example of air conditioning control system]
FIG. 1 shows an example of the configuration of an air conditioning control system in the first embodiment of the present invention.
The air conditioning control system shown in this figure is a system for performing air conditioning in one space 100 as an air conditioning control target. This space 100 is a relatively large space such as a cafeteria, a resting space, a free address office, a library reading space, etc., and people enter and exit in a fluid manner. It corresponds to a place that is not defined.

In the space 100 shown in FIG. 1, an air conditioner 101, a sensor 102, a temperature sensor 103, and a display device 104 are provided.
In the space 100, a plurality of air conditioning facilities 101 are provided. The plurality of air conditioning equipment 101 performs air conditioning of the space 100. In addition, the plurality of air conditioning equipments 101 form a plurality of air conditioning environment areas in which different air conditioning environments are set in the space 100 under the control of the air conditioning control device 200, and the distribution of these air conditioning environment areas in the space 100 is also determined. It is installed so that it can be changed.

  The sensor 102 detects a predetermined detection target in the space 100 used when the human distribution state determination unit 201 makes a determination. In the following description, the sensor 102 detects a person as a detection target. In the space 100, a plurality of sensors 102 are provided. The plurality of sensors 102 are installed so as to detect persons in different areas.

In addition, as the sensor 102 for detecting a person, for example, a human sensor using infrared rays or the like can be employed. Alternatively, an IC card reader may be provided as the sensor 102 after the user of the space 100 carries an IC (Integrated Circuit) card. In this case, information on the person's entry / exit can be acquired by the IC card reader.
Alternatively, an RFID tag may be carried by a resident of the facility, and a reader / writer corresponding to an RFID (Radio Frequency IDentification) tag may be provided as the sensor 102.

  The temperature sensor 103 detects the temperature (air temperature) in the space 100. In the space 100, a plurality of temperature sensors 103 are provided. The plurality of temperature sensors 103 are installed so as to detect temperatures in different regions of the space 100, for example.

  In FIG. 1, each air conditioner 101, sensor 102, and temperature sensor 103 are shown to correspond to each other, but there is no particular relationship between them. Therefore, the numbers of the air conditioning equipment 101, the sensor 102, and the temperature sensor 103 may be different from each other.

The display device 104 displays information indicating a situation for each of a plurality of air conditioning environment areas in the space in accordance with the display control of the air conditioning control device 200.
The display device 104 is installed near the entrance of the space 100, for example. The user who has entered from the entrance looks at the information displayed on the display device 104 to determine which one of the plurality of air-conditioning environment areas is in his / her preferred condition, for example. I can know. And when this user enters the space 100, he / she can go to the air-conditioning environment area in his / her favorite situation without hesitation.
That is, the display device 104 has a role for allowing the user of the space 100 to accurately know the air-conditioning environment area in which the air-conditioning environment suitable for the user is set.

[Configuration example of air conditioning controller]
Next, with reference to the same FIG. 1, the structural example of the air-conditioning control apparatus 200 is demonstrated.
The air conditioning control device 200 performs air conditioning control in the space 100. That is, the air conditioning control device 200 controls the operation of the plurality of air conditioning facilities 101 in the space 100.

  In addition, the air conditioning control device 200 controls the air conditioning equipment 101 so as to form a plurality of air conditioning environment areas in which different air conditioning environments are set in the space 100. In addition, the air conditioning control device 200 changes the distribution of the plurality of air conditioning environment areas in the space 100 according to the distribution status of users (people) in the space 100. In addition, the air conditioning control device 200 causes the display device 104 to display information indicating a situation for each of a plurality of air conditioning environment areas in the space 100 under such air conditioning control.

For this purpose, the air conditioning control device 200 includes a person distribution state determination unit 201, an air conditioning control unit 202, a display information generation unit 203, and a display control unit 204.
The person distribution state determination unit 201 determines the distribution state of users (people) in the space 100 based on detection information output from the sensor 102. In the present embodiment, the human distribution state determination unit 201 determines whether or not a person existing in each of a plurality of air-conditioning environment areas formed in the space 100 is in an overcrowded state as a human distribution state. That is, the human distribution state determination unit 201 determines whether or not there is an air-conditioning environment region in an overcrowded state.
In determining whether it is an overcrowded state, the person distribution state determination unit 201 may determine, for example, whether the number of people in the air-conditioning environment area or the population density is equal to or greater than a certain value.

In the following description, an air conditioning environment area in which the number of people or the population density is determined to be a certain value or more is referred to as an overcrowded air conditioning environment area.
Further, hereinafter, the case where the human distribution state determination unit 201 performs the determination using the population density will be described as an example. The population density can be obtained, for example, by dividing the floor area of the air-conditioning environment area by the number of people existing in the air-conditioning environment area.

The air conditioning control unit 202 controls the air conditioning equipment 101 so as to form a plurality of air conditioning environment areas in the space 100. At this time, the air-conditioning control unit 202 controls the air-conditioning equipment 101 so as to change the distribution of the air-conditioning environment region in the space 100 based on the person distribution state determined by the person distribution state determination unit 201.
In addition, when it is determined by the human distribution state determination unit 201 that the over-air-conditioning environment area is present, the air-conditioning control apparatus 200 according to the first embodiment expands the over-air-conditioning environment area and Reduce each air conditioning environment area.

The display information generation unit 203 generates display information indicating a situation for each of a plurality of air conditioning environment areas in the space as display information to be displayed on the display device.
In the first embodiment, the display information generation unit 203 indicates, for example, information indicating a distribution state for each of a plurality of air conditioning environment areas in the current space 100 and a set temperature for each of the plurality of air conditioning environment areas in the current space 100. Display information including information is generated. Here, the set temperature is a temperature for each air conditioning environment area set as a target value when the air conditioning control unit 202 performs air conditioning control.

  The display information generation unit 203 can generate information indicating a distribution state for each of a plurality of air-conditioning environment areas in the current space 100 based on the control status of the air-conditioning equipment 101 by the air-conditioning control unit 202. Further, the display information generation unit 203 can acquire the set temperature for each of the plurality of air conditioning environment areas in the current space 100 from the air conditioning control unit 202.

The display control unit 204 executes control for causing the display device 104 to display the display information generated by the display information generation unit 203.
As a result, in the first embodiment, the display device 104 displays an air conditioning status image showing the distribution state of the air conditioning environment area in the space 100 and information on the set temperature for each air conditioning environment area.

[Example of air conditioning status]
FIG. 2 shows an example of the air conditioning status image displayed on the display screen 104 </ b> A of the display device 104.
A spatial image Pac is displayed on the display screen 104A. The space image Pac is an image of an image obtained by looking down the space 100 from the plane direction.
In the space image Pac of this figure, as shown by a broken line, an example in which the space 100 is divided into five air-conditioning environment areas Aac1 to Aac5 is shown. Thus, in the air conditioning status image, the distribution state for each of the air conditioning environment areas Aac1 to Aac5 in the space 100 is shown.
Note that the air-conditioning environment areas Aac1 to Aac5 in the spatial image Pac are preferably displayed by being color-coded, for example. By color-coding in this way, the user can easily grasp the distribution state of the air-conditioning environment areas Aac1 to Aac5. Further, when color-coding, for example, by setting the color for each of the air-conditioning environment areas Aac1 to Aac5 so as to change from a cold color system to a warm color system, for example, from a lower set temperature to a higher set temperature, the user can more sensibly. It becomes easy to grasp the distribution state of the air conditioning environment areas Aac1 to Aac5.

  Further, on the display screen 104A, on the upper side of the spatial image Pac, temperature display areas Atm1 to Atm5 are displayed corresponding to the air-conditioning environment areas Aac1 to Aac5 in the spatial image Pac, respectively. The temperature display areas Atm1 to Atm5 indicate set temperatures as temperature states for the air conditioning environment areas Aac1 to Aac5, respectively.

In the example of this figure, the air conditioning environment areas Aac1 to Aac5 have higher set temperatures in the order of the air conditioning environment areas Aac1, Aac2, Aac3, Aac4, and Aac5. In this figure, the set temperatures of the air-conditioning environment areas Aac1 to Aac5 are shown in increments of 1 ° C. as indicated by 24 ° C., 25 ° C., 26 ° C., 27 ° C. and 28 ° C. in the temperature display areas Atm 1 to Atm 5 respectively. An example of different settings is shown.
In the following description, the air conditioning environment areas Aac1 to Aac5 are described as the air conditioning environment area Aac when it is not necessary to distinguish them. Further, when it is not necessary to distinguish between the temperature display areas Atm1 to Atm5, they are described as a temperature display area Atm.

As described above, the display device 104 is installed near the entrance of the space 100 so that when the user tries to enter the space 100 in order to use the space 100, the user can easily see the user. Yes.
Then, when the user sees the air conditioning status image displayed as shown in FIG. 2, for example, in what state the plurality of air conditioning environment areas are currently distributed in the space 100, and each air conditioning environment It is possible to know what set temperature the area is.
For example, when using a space that is somewhat large and does not have a fixed position, it may be confused as to where the space should be. If the distribution of the air-conditioned space area is displayed as described above, the user can select the air-conditioned space area where his / her preferred air-conditioning environment is set as the place where he / she should be, and hesitate to be lost. Disappears.

  However, depending on the weather of the day, the arrangement of tables, chairs and other equipment in the space 100, the user may concentrate on a specific air conditioning environment area. For example, if the number of users increases to a certain level or more with respect to the volume of the air conditioning environment area, a congested situation exceeding the allowable range occurs in the air conditioning environment area, and the user is cramped. You may feel it. In addition, there is a possibility that the heat load increases as the number of users increases, making it difficult to maintain the set temperature or increasing the power used in the air conditioning control.

Therefore, the air conditioning control device 200 according to the first embodiment expands the air conditioning environment region when an air conditioning environment region in which the user is overcrowded occurs as follows.
For example, it is assumed that the number of users increases to an extent that exceeds the allowable range in the air conditioning environment area Aac1 among the air conditioning environment areas Aac1 to Aac5 illustrated in FIG.
Accordingly, the person distribution state determination unit 201 determines that the air-conditioning environment area Aac1 is an overcrowded air-conditioning environment area. This corresponds to, for example, that the human distribution state determination unit 201 determines that the user is overcrowded in the air conditioning environment area Aac1 as the human distribution state.

As described above, when it is determined that the air conditioning environment area Aac1 is an overcrowded air conditioning environment area, the air conditioning control unit 202 corresponds to the air conditioning status images of FIGS. 2 to 3 with respect to the state of the air conditioning environment area Aac. Change to state.
The air-conditioning environment area Aac1 in FIG. 3 is enlarged so as to extend toward the air-conditioning environment area Aac2 that was adjacent to the air-conditioning environment area Aac1 in FIG. 2, for example. As the air conditioning environment area Aac1 is expanded in this way, each of the other air conditioning environment areas Aac2 to Aac5 is reduced.
The air conditioning control unit 202 appropriately controls each of the air conditioning equipment 101 in the space 100 so that the air conditioning environment area Aac shown in FIG.
In the present embodiment, there is no particular limitation on how to determine the enlargement ratio when enlarging the overcrowded air conditioning environment area. For example, the enlargement ratio may be a predetermined fixed value. Further, the enlargement rate may be determined according to the population density or the number of people in the overcrowded air conditioning environment area.

  The air conditioning control unit 202 changes the control of the operation of the air conditioning equipment 101 provided in the space 100 in order to change the distribution of the air conditioning environment area Aac as described above. For example, the air conditioning control unit 202 controls the air conditioning equipment 101 installed in the space 100 within the air conditioning environment area Aac1 of FIG. In addition, the air conditioning control unit 202 sets the actual temperature for each air conditioning environment area Aac2 to Aac5 for each air conditioning facility 101 installed in each range of the air conditioning environment areas Aac2 to Aac5 in FIG. 25 ° C., 26 ° C., 27 ° C., 28 ° C.).

In addition, as the air conditioning control unit 202 switches the operation control as described above, the display information generation unit 203 displays the distribution states of the air conditioning environment areas Aac1 to Aac5 in the space 100 after the operation control is switched, and these Display information indicating the set temperatures of the air conditioning environment areas Aac1 to Aac5 is generated. The display control unit 204 causes the display device 104 to display the display information generated in this way.
As a result, the air conditioning status image displayed on the display screen 104A of the display device 104 changes from the content shown in FIG. 2 to FIG.

Thus, by changing the distribution of the air-conditioning environment area Aac, the volume of the air-conditioning environment area Aac1, which was an overcrowded air-conditioning environment area, is expanded. Thereby, the overcrowded state of the air-conditioning environment area Aac is eliminated, and the comfort of the user existing in the air-conditioning environment area Aac1 can be maintained.
On the other hand, the other air-conditioning environment areas Aac2 to Aac5 are still formed in the space 100 after the respective distributions are reduced. Since these air-conditioning environment areas Aac2 to Aac5 were not overcrowded air-conditioning environment areas, the number of users existing there was not very large. Therefore, although the other air-conditioning environment areas Aac2 to Aac5 are reduced, the comfort of the users existing there is not greatly impaired.

  Further, in accordance with the change in the distribution of the air conditioning environment area Aac as described above, the display device 104 displays the air conditioning status image of FIG. Thereby, the user can visually grasp the change of the distribution of the air-conditioning environment area Aac and the setting for each air-conditioning environment area Aac after the change.

[Example of processing procedure]
The flowchart of FIG. 4 shows an example of a processing procedure executed by the air conditioning control device 200 according to the first embodiment.
In the air conditioning control device 200, the air conditioning control unit 202 forms an initial air conditioning environment, for example, with the start of the air conditioning operation in the space 100 (step S101). At the same time, the display information generation unit 203 generates display information corresponding to the initial air conditioning environment, and the display control unit 204 causes the display device 104 to display the generated display information (step S101).
In this initial air-conditioning control, the air-conditioning control apparatus 200 determines the air-conditioning equipment according to the distribution state of the plurality of air-conditioning environment areas Aac in the space 100 indicated by the initial setting contents of the air-conditioning environment and the set temperature for each air-conditioning environment area Aac. The operation for each 101 is controlled.

The initial setting content of the air conditioning environment may be fixed in advance by, for example, an operation manager. In this case, the air conditioning control unit 202 may read the data of the initial setting content of the air conditioning environment stored in the air conditioning control device 200 and execute the air conditioning control according to the initial setting content indicated by the read data.
Or the air-conditioning control part 202 may produce | generate the initial setting content of an air-conditioning environment by the learning process using the past performance etc., for example.

Next, the person distribution state determination unit 201 inputs detection information for each sensor 102 that detects the presence of a person (step S102), and based on the input detection information, the air-conditioning environment area Aac is overcrowded. It is determined whether or not there is an environmental area (step S103).
When it determines with there being no overcrowded air-conditioning environment area | region (step S103-NO), the human distribution state determination part 201 returns a process to step S102.
On the other hand, when it is determined that there is an overcrowded air conditioning environment area (step S103—YES), the air conditioning control unit 202 executes the following air conditioning control. That is, the air conditioning control unit 202 expands the air conditioning environment area Aac in the overcrowded air conditioning environment area and reduces each air conditioning environment area Aac other than the overcrowded air conditioning environment area as illustrated as a transition from FIG. 2 to FIG. 3. Air-conditioning control is executed (step S104).

The display information generation unit 203 generates display information reflecting the air conditioning control changed by the air conditioning control unit 202 according to step S104 (step S105). Thereby, the display information is updated from the content corresponding to the air conditioning control before the change to the content corresponding to the air conditioning control after the change.
The display control unit 204 causes the display device 104 to display an air conditioning status image indicating the display information generated in step S105 (step S106). Thereby, the content of the air-conditioning status image displayed on the display device 104 is changed as illustrated as a transition from FIG. 2 to FIG. 3. The air conditioning control device 200 repeatedly executes the processes of steps S102 to S106, for example, during the operation period of the air conditioning equipment 101 in the space 100.

<Second Embodiment>
[Overview]
Next, the second embodiment will be described. In addition, about the structure of the air-conditioning control system in 2nd Embodiment, it may be the same as that of FIG.
In changing the air conditioning environment area Aac in the first embodiment, each of the air conditioning environment areas other than the overcrowded air conditioning environment area is uniformly reduced. For example, the air-conditioning environment such as the set temperature for each air-conditioning environment area Aac is determined within a range that is expected to be used by a certain number of users or more. In view of this, it is appropriate to uniformly reduce the air-conditioning environment area other than the overcrowded air-conditioning environment area because the user in any air-conditioning environment area Aac is considered.
However, for example, depending on the date and time zone, there may be a situation in which a user is absent or hardly exists in a specific air conditioning environment region. That is, there is a possibility that a sparsely air-conditioned environment area where the number of people or the density of people is below a certain value will occur.
For example, when the distribution of the air-conditioning environment area is changed in the first embodiment, such a sparse air-conditioning environment area is also uniformly reduced along with the air-conditioning environment areas other than the other over-congested air-conditioning environment areas. However, when reducing other air-conditioning environment areas other than the over-condensed air-conditioning environment area in this way, the other air-conditioning environment area where the user is present is more than necessary due to the de-populated air-conditioning environment area in the absence of or close to the user. There is a possibility of becoming narrower.

  Therefore, the air conditioning control unit 202 in the second embodiment changes the air conditioning control as follows when there is an air conditioning environment area in the space 100 and a sparse air conditioning environment area. That is, the air-conditioning control unit 202 expands the dense air-conditioning environment area, and preferentially reduces the depopulated air-conditioning environment area other than the dense air-conditioning environment area.

  In this case, when the sparse air-conditioning environment area is reduced in response to the expansion of the sparse air-conditioning environment area, only the sparse air-conditioning environment area is first reduced. The air conditioning environment area that is not the environment area is not reduced.

[Examples of changing air conditioning control]
Here, the example of a change of the air-conditioning control in 2nd Embodiment is demonstrated.
First, the air conditioning control state in the current space 100 is the same as that shown in the air conditioning status image of FIG. It is assumed that the person distribution state determination unit 201 determines that the air conditioning environment area Aac1 is an overcrowded air conditioning environment area due to an increase in the number of users in the air conditioning environment area Aac1 under this state.
In this case, the person distribution state determination unit 201 in the second embodiment further determines whether or not there is a depopulated air-conditioning environment area having a population density (or the number of persons) of a certain value or less.
Here, when it is determined that there is no excessive air-conditioning environment region, the air-conditioning control unit 202 performs the same air-conditioning control change as that in the first embodiment. That is, as shown in FIG. 3, the air conditioning control unit 202 expands the air conditioning environment area Aac1 determined to be an overcrowded air conditioning environment area, and equally reduces the other air conditioning environment areas Aac2 to Aac5.

On the other hand, when the human distribution state determination unit 201 determines that the air conditioning environment region Aac5 in FIG. 2 is a depopulated air conditioning environment region, the air conditioning control unit 202 changes the air conditioning control as follows.
That is, the air conditioning control unit 202 expands the air conditioning environment area Aac1. In addition, the air-conditioning control unit 202 preferentially reduces the air-conditioning environment area Aac5, which is a sparse air-conditioning environment area, when reducing the air-conditioning environment areas Aac2 to Aac5 other than the air-conditioning environment area Aac1 according to this expansion.

FIG. 5 shows an example when the distribution of the air-conditioning environment area Aac is changed as described above. In FIG. 5, first, an air conditioning environment area Aac1 is formed by the same distribution as the air conditioning environment area Aac1 of FIG. In addition, the portion where the air-conditioning environment area Aac5 is distributed in FIG. 2 is also replaced with the air-conditioning environment area Aac1. Accordingly, the temperature display areas Atm1-1 and Atm1-2 corresponding to the two air-conditioning environment areas Aac1 in FIG. 5 both show the same set temperature of 24 ° C.
in this way. The air-conditioning environment area Aac1 in FIG. 5 is not adjacent to the space 100, but is enlarged from the state of FIG.

  In the example of FIG. 5, the air-conditioning environment area Aac5 that existed in FIG. 2 has disappeared. That is, in the second embodiment, the air-conditioning environment area Aac determined as a sparsely air-conditioned environment area may disappear from the space 100 as a result of being reduced in accordance with the enlargement of the sparse air-conditioning environment area.

  By changing the air-conditioning environment area Aac in the space 100 in this way, the volume of the air-conditioning environment areas Aac2 to Aac2-4 that are neither overcrowded nor under-depopulated is not squeezed by the depopulated air-conditioning environment area. Thereby, the comfort of the user who exists in air-conditioning environment area | region Aac2-4, for example can be maintained.

In the second embodiment, for example, when the sparse air-conditioning environment area is larger than the expansion of the sparse air-conditioning environment area, the sparse air-conditioning environment area that is reduced along with the expansion of the dense air-conditioning environment area is The amount corresponding to the difference from the enlarged portion remains.
In addition, if the depopulated air conditioning environment area is smaller than the expansion of the overcrowded air conditioning environment area, the expansion of the overcrowded air conditioning environment area will first change the original depopulated air conditioning environment area to the same air conditioning environment area as the overcrowded air conditioning environment area. replace. In addition, as for the surplus expansion, the remaining air-conditioning environment area other than the overcrowded air-conditioning environment area may be reduced evenly as in the first embodiment.

[Example of processing procedure]
The flowchart of FIG. 6 shows an example of a processing procedure executed by the air conditioning control device 200 according to the second embodiment. In FIG. 6, steps that are the same as those in FIG. 4 are denoted by the same reference numerals, and description thereof is omitted here.
In the process shown in this figure, when it is determined in step S103 that there is a congested air-conditioning environment area, the human distribution state determination unit 201 further determines whether or not there is a depopulated air-conditioning environment area (step S103A).

When it is determined that there is no sparsely air-conditioned environment area (step S103A-NO), the air-conditioning control unit 202 executes the process of step S104 similar to FIG.
On the other hand, when it is determined that there is a sparsely air-conditioned environment area (step S103A-YES), the air-conditioning control unit 202 executes the following processing. That is, the air-conditioning control unit 202 expands the air-conditioning environment area Aac that has been determined to be a congested air-conditioning environment area in step S103, and the air-conditioning that has been determined to be a sparse air-conditioning environment area in step S103A according to the expansion. The environmental area Aac is reduced (step S104A).
After executing the process of step S104 or step S104A, the processes of steps S105 and S106 are executed as in FIG.

<Modification>
Next, various modifications of the present embodiment will be described.
In the description of the embodiments so far, the temperature display area Atm in FIGS. 2, 3, and 5 gives an example of displaying the set temperature, but as temperature information to be displayed in the temperature display area Atm, It is not limited.
As an example, the current actual temperature in the corresponding air conditioning environment area Aac may be displayed in the temperature display area Atm. In order to display the temperature display area Atm indicating the actual temperature, the display information generation unit 203 may include information indicating the actual temperature of the corresponding air conditioning environment area Aac as the temperature information in the display information. For example, the display information generation unit 203 determines the actual temperature for each of the plurality of air-conditioning environment areas Aac in the current space 100 based on the temperature detected by each temperature sensor 103 and the installation position of each temperature sensor 103 in the space 100. Can be requested.

Moreover, as the temperature display area Atm, for example, both the current set temperature and the current actual temperature may be displayed.
FIG. 7A is an example of a display mode when both the current set temperature and the current actual temperature are displayed as the temperature display area Atm. FIG. 7 shows an extracted portion of the temperature display area Atm in the air conditioning status image.

  In FIG. 7A, a temperature display area Atm1 and a temperature display area Atm11 indicate a set temperature and an actual temperature corresponding to the same air conditioning environment area Aac1, respectively. The temperature display area Atm2 and the temperature display area Atm12 respectively indicate a set temperature and an actual temperature corresponding to the same air conditioning environment area Aac2. The temperature display area Atm3 and the temperature display area Atm13 indicate a set temperature and an actual temperature corresponding to the same air conditioning environment area Aac3, respectively. The temperature display area Atm4 and the temperature display area Atm14 indicate the set temperature and the actual temperature corresponding to the same air conditioning environment area Aac4, respectively. The temperature display area Atm5 and the temperature display area Atm15 indicate the set temperature and the actual temperature corresponding to the same air conditioning environment area Aac5, respectively.

Even if the air conditioning control unit 202 switches the air conditioning control to change the distribution of the air conditioning environment area Aac, it takes some time for the target air conditioning environment area Aac distribution state to be formed. . If the target air conditioning environment area Aac distribution state, set temperature, or the like is displayed as the current air conditioning state immediately after such switching of the air conditioning control, there is a possibility that the deviation from the actual air conditioning state becomes large. There is.
Therefore, for example, as the air conditioning status image, not only the current status but also a status planned or predicted in the future after a certain time may be displayed.
For example, the distribution of the air-conditioning environment area Aac formed by the switching of the air-conditioning control is displayed as the distribution of the air-conditioning environment area Aac scheduled after a certain time from the timing when the air-conditioning control unit 202 switches the air-conditioning control. .
In addition, there may be a case where the set temperature of the air conditioning environment region is changed in accordance with the switching of the air conditioning control. Therefore, the set temperature thus changed may be displayed in the temperature display area Atm as the set temperature of the air-conditioning environment area Aac scheduled after a certain time.

  Further, in the temperature display area Atm, the actual temperature predicted after a certain time may be displayed. The actual temperature after a certain time is predicted using, for example, the current actual temperature detected by the temperature sensor 103, the content of the current air conditioning control by the air conditioning control unit 202, past performance data, learning data, and the like. Can do. For example, the air conditioning control unit 202 may predict the actual temperature, and the display information generation unit 203 may input the prediction result. Alternatively, the display information generation unit 203 itself may predict the actual temperature.

Further, for example, in the temperature display area Atm, the current set temperature and the actual temperature after a certain time may be displayed together, and the current and the situation after a certain time may be displayed simultaneously.
In addition, display information indicating the current air conditioning status and display information indicating the air conditioning status may be switched and displayed on the display device 104. In this case, the display information generation unit 203 generates display information indicating the current air conditioning status and display information indicating the air conditioning status planned or predicted after a predetermined time. Then, the display control unit 204 executes control for switching the display information indicating the current air conditioning status and the display information indicating the air conditioning status to be displayed on the display device 104. Further, the display switching may be performed automatically, for example, at regular intervals, or may be performed in response to a user operation.

In the description so far, the value as the temperature is displayed in the temperature display region Atm. However, it may be easier for the user to present a more sensual display content rather than presenting the difference in air conditioning control for each air conditioning environment area Aac as a numerical value.
As an example, as shown as a temperature display area Atm in FIG. 7B, air conditioning control for each air conditioning environment area Aac, a difference in air conditioning effect, a sentence explaining the strength of cooling, a word, or the like may be displayed. Moreover, although illustration is abbreviate | omitted, you may express the difference in the air-conditioning control and air-conditioning effect for every air-conditioning environment area | region Aac by displaying the picture as a different icon etc. in the temperature display area Atm, for example.

Further, as the air-conditioning control for each air-conditioning environment area Aac by the air-conditioning control unit 202, not only the set temperature is changed but also other elements may be combined. For example, the air conditioning control unit 202 sets the same set temperature for a plurality of air conditioning environment areas Aac, and then changes the operating intensity of the fans in each of them to change the degree of airflow. Thereby, the sensible temperature in each air-conditioning environment area Aac varies.
Note that when air conditioning control is performed in this way, for example, in the air conditioning status image, a character, a pattern, or the like for informing the difference in the airflow state for each air conditioning environment area Aac may be displayed. In this case, the sensible temperature may be displayed as temperature information to be displayed in the temperature display area Atm.

Further, in the description so far, when the human distribution state determination unit 201 determines the distribution state of people in the space 100 (the presence or absence of an over-condensed air-conditioning environment region or a depopulated air-conditioning environment region), the detection that the sensor 102 has detected a person is detected. Based on the information, the population density or the number of people was directly calculated.
However, for example, the distribution state of people in the air-conditioning environment area can be determined as follows. In this case, the sensor 102 sets the detection target as temperature. In addition, since the temperature sensor 103 is also provided in the configuration of the air conditioning control system in FIG. 1, for example, the temperature sensor 103 may be used as the sensor 102. Then, based on the temperature detected by the temperature sensor 103, the person distribution state determination unit 201 estimates the population density or the number of people in the air conditioning environment area Aac.
Taking cooling as an example, for example, under conditions where the operation rate is constant, the greater the population density or the number of people in the air-conditioning environment area Aac, the higher the heat load and the temperature of the air-conditioning environment area Aac increases. Thus, the population density or the number of people in the air conditioning environment area Aac can be estimated from the temperature of the air conditioning environment area Aac if the operation rate for the air conditioning equipment 101 is known. Based on this, the person distribution state determination unit 201 may estimate the population density or the number of people by a predetermined calculation using, for example, the operation rate for the air conditioning equipment 101 and the temperature detected by the sensor 102 as parameters. Then, the human distribution state determination unit 201 determines the distribution state of humans in the space 100 (presence / absence of over-condensed air-conditioning environment region or de-populated air-conditioning environment region) based on the estimated result.

In the above description, the display device 104 is assumed to be installed near the entrance of the space 100. However, the present invention is not limited to this. For example, the display device 104 may be installed not only in the vicinity of the entrance but also in a key place in the space 100. In addition, for example, a plurality of display devices 104 may be provided and each may be arranged on a desk in the space 100.
In addition, although it is remote from the space 100, the display device 104 may be installed in a place or space where many users go to the space 100. As an example, when the space 100 is a cafeteria or a meeting room in a company facility, the display device 104 is arranged in a certain space such as an office room. As a result, the employee can know the air-conditioning environment of the canteen or the meeting room in advance by looking at the display device 104 when moving from the office to the canteen or the meeting room.

  Further, the distribution pattern of the air-conditioning environment area Aac in the space 100 is not limited to one in which the space 100 is divided vertically as shown in FIGS. 2, 3, 5, and the like. For example, the air-conditioning environment area Aac may be distributed so as to divide the space 100 into a grid.

  Further, by recording a program for realizing the function of each unit in the air conditioning control unit 202 in FIG. 1 on a computer-readable recording medium, causing the computer system to read and execute the program recorded on the recording medium. Air conditioning control may be performed. Here, the “computer system” includes an OS and hardware such as peripheral devices.

Further, the “computer system” includes a homepage providing environment (or display environment) if a WWW system is used.
The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Further, the “computer-readable recording medium” refers to a volatile memory (RAM) in a computer system that becomes a server or a client when a program is transmitted via a network such as the Internet or a communication line such as a telephone line. In addition, those holding programs for a certain period of time are also included. The program may be a program for realizing a part of the functions described above, and may be a program capable of realizing the functions described above in combination with a program already recorded in a computer system.

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes designs and the like that do not depart from the gist of the present invention.

DESCRIPTION OF SYMBOLS 100 Space 101 Air-conditioning equipment 102 Sensor 103 Temperature sensor 104 Display apparatus 104A Display screen 200 Air-conditioning control apparatus 201 Person distribution state determination part 202 Air-conditioning control part 203 Display information generation part 204 Display control part

Claims (10)

An air conditioning facility for air conditioning a space, a sensor for detecting a predetermined detection target in the space, a display device, and an air conditioning control device,
The air conditioning control device
A human distribution state determination unit that determines a distribution state of people in the space based on detection information output by the sensor;
A plurality of air-conditioning environment areas in which different air-conditioning environments are set in the space are formed, and the distribution of the air-conditioning environment areas in the space is changed based on the person distribution state determined by the person distribution state determination unit. An air conditioning control unit for controlling the air conditioning equipment;
An air-conditioning control system comprising: a display information generating unit that generates display information for causing the display device to display a situation for each of a plurality of air-conditioning environment areas in the space. The human distribution state determination unit
As the distribution state of people in the space, determine the presence or absence of an overcrowded air conditioning environment area where the number of people or the density of people is a certain value or more,
The air conditioning controller
2. When the person distribution state determination unit determines that the overly air-conditioned environment region is present, the over-air-conditioned air environment region is expanded and each air-conditioned environment region other than the over-air-conditioned air region is reduced. The air conditioning control system described. The human distribution state determination unit
As the distribution state of people in the space, determine the presence or absence of a depopulated air conditioning environment area where the number of people or the density of people is below a certain value,
The air conditioning controller
When it is determined by the human distribution state determination unit that the overly air-conditioned environment area is present and the under-air-conditioned air environment area is present, the over-air-conditioned air environment area is expanded and an air-conditioning environment other than the over-air-conditioned air environment area The air conditioning control system according to claim 2, wherein the depopulated air conditioning environment area is preferentially reduced from among the areas. The display information generation unit
The air conditioning control system according to any one of claims 1 to 3, wherein the display information including information indicating a distribution state for each of a plurality of air conditioning environment regions in the current space is generated. The display information generation unit
As information indicating the temperature state for each of the plurality of air-conditioning environment areas, the actual temperature for each of the plurality of air-conditioning environment areas currently detected and the information for each of the plurality of air-conditioning environment areas currently set as target values by the air-conditioning control unit The air conditioning control system according to claim 4, wherein the display information including information indicating at least one of set temperatures is generated. The display information generation unit
The air conditioning control system according to any one of claims 1 to 5, wherein the display information including information indicating a distribution state for each of a plurality of air conditioning environment regions in the space scheduled to be formed after a certain time is generated. The display information generation unit
As the temperature state for each air conditioning environment area, the actual temperature for each air conditioning environment area predicted after a certain time and for each air conditioning environment area that the air conditioning control unit plans to set as the target value after a certain time The air conditioning control system according to claim 6, wherein the display information including information indicating at least one of the set temperatures is generated. A human distribution state determination unit that determines a distribution state of people in the space based on detection information output by a sensor that detects a predetermined detection target in the space;
A plurality of air conditioning environment areas in which different air conditioning environments are set in the space are formed, and the distribution of the air conditioning environment areas in the space is changed based on the person distribution state determined by the person distribution state determination unit. An air conditioning control unit for controlling the air conditioning equipment;
An air-conditioning control apparatus comprising: a display information generating unit that generates display information for causing a display device to display a situation for each of a plurality of air-conditioning environment areas in the space. A human distribution state determination step for determining a human distribution state in the space based on detection information output by a sensor that detects a predetermined detection target in the space;
A plurality of air conditioning environment areas in which different air conditioning environments are set in the space are formed, and the distribution of the air conditioning environment areas in the space is changed based on the person distribution state determined by the person distribution state determination step. An air conditioning control step for controlling the air conditioning equipment;
An air-conditioning control method comprising: a display information generation step for generating display information for causing a display device to display a situation for each of a plurality of air-conditioning environment areas in the space. On the computer,
A human distribution state determination step for determining a human distribution state in the space based on detection information output by a sensor that detects a predetermined detection target in the space;
A plurality of air conditioning environment areas in which different air conditioning environments are set in the space are formed, and the distribution of the air conditioning environment areas in the space is changed based on the person distribution state determined by the person distribution state determination step. An air conditioning control step for controlling the air conditioning equipment;
A display information generating step of generating display information for displaying a status for each of a plurality of air-conditioning environment areas in the space on a display device.

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