JP6802358B2 - Control devices, control methods and programs - Google Patents

Description

The present invention relates to control devices, control methods and programs.

Spaces to be air-conditioned are usually provided in buildings such as houses, office buildings and factories. The manager of such a building is responsible for adjusting the target temperature of the air conditioning so that the user in the room does not feel uncomfortable with the thermal environment. However, the manager may customarily set the target temperature without considering the characteristics of the building and the taste of the user. In such a case, the thermal environment is not maintained in a comfortable state for the user.

Therefore, a technique for reducing user dissatisfaction with the thermal environment has been proposed (see, for example, Patent Document 1). Patent Document 1 describes a system in which resident's declarations regarding the thermal environment are collected and aggregated through a communication network to form a resident's agreement and change the room temperature.

Japanese Unexamined Patent Publication No. 2004-205202

Air conditioning may be restricted, for example, from the viewpoint of energy saving. When such a limitation is set, it is preferable to achieve both the energy consumption due to the air conditioning and the comfortable state for the user to some extent, but this compatibility becomes difficult depending on the outside air condition and the physical condition of the user. Therefore, it is necessary to lift this restriction before the thermal environment is significantly deteriorated by the air conditioning with the restriction set.

Here, it is conceivable to apply the aggregation method described in Patent Document 1 to the report from the user to determine whether or not the thermal environment has deteriorated. The aggregation method described in Patent Document 1 is to prevent the target temperature from becoming unstable by leveling a plurality of declarations. In such a method, the restriction is lifted only when most users declare that it is unpleasant, and there is a possibility that the restriction cannot be lifted before the thermal environment is significantly deteriorated.

Further, it is necessary to set the restriction at an appropriate timing for the declaration from the user together with the release of the restriction, but even if the aggregation method described in Patent Document 1 is applied, the user can release the restriction as well as the removal of the restriction. It may not be possible to set restrictions on the declaration at an appropriate time.

The present invention has been made in view of the above circumstances, and an object of the present invention is to set or release restrictions on a report from a user at an appropriate timing.

In order to achieve the above object, the control device of the present invention is a control device that controls an air conditioner by receiving a report from two or more users, and is a first type report and a first type in which the degree of comfort of air conditioning is different. The number of first-class filings and the number of second-class filings when the restrictions on the control of air-conditioning equipment are lifted and the acquisition means for acquiring information indicating the filing selected from the two types of filing. It comprises a transmitting means for transmitting a control instruction to the air conditioner when the combination is within the first range, and the limitation is set or lifted when the combination is within a second range different from the first range. To.

According to the present invention, when the restriction on the control of the air conditioner is lifted and the combination of the number of the first type declaration and the number of the second type declaration is within the first range, the control instruction is given. Is transmitted to the air conditioner, and the restriction is set or lifted when the combination is within a second range different from the first range. For this reason, the counting method for declarations for directly controlling air conditioning equipment and the counting method for setting or canceling restrictions are different. Therefore, the restriction can be set or released at an appropriate timing for the report from the user.

Diagram showing the configuration of the air conditioning system Diagram showing the hardware configuration of terminals, control devices and air conditioners Diagram showing the functional configuration of the terminal The figure which shows an example of the declaration input screen which concerns on Embodiment 1. Diagram showing the functional configuration of the control device Diagram showing the filing database Diagram showing the functional configuration of air conditioners Flow diagram showing control processing The flow chart which shows the control process for the air-conditioning apparatus which concerns on Embodiment 1. Diagram for explaining the first range The flow chart which shows the specific example of the control processing for the air-conditioning apparatus which concerns on Embodiment 1. FIG. 5 is a flow chart showing a setting process of presence / absence of restriction according to the first embodiment. Diagram for explaining the second range A flow chart showing a specific example of the setting process of the presence / absence of restriction according to the first embodiment. The figure which shows an example of the declaration input screen which concerns on Embodiment 2. The flow chart which shows the control process for the air-conditioning apparatus which concerns on Embodiment 2. FIG. 5 is a flow chart showing a setting process for the presence / absence of restrictions according to the second embodiment. The first figure which shows the distribution example of the number of declarations The second figure which shows the distribution example of the number of declarations FIG. 5 is a flow chart showing a setting process of presence / absence of restriction according to the third embodiment. FIG. 3 showing an example of distribution of the number of declarations

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

Embodiment 1.
FIG. 1 shows the configuration of the air conditioning system 100 according to the present embodiment. The air conditioning system 100 is a system installed in an office building that harmonizes the air in the indoor space provided in the office building. The indoor space may be a work place for a plurality of users to work, or may be a warehouse for storing equipment at an appropriate room temperature. The user means a user of the air conditioning system 100. The user makes a declaration indicating the degree of comfort in the thermal environment formed by the air conditioning system 100, and the air conditioning system 100 receives the declarations of two or more users and harmonizes the air in the indoor space. If there is only one user, the air conditioning system 100 harmonizes the air according to the user's declaration.

The air-conditioning system 100 is an air-conditioning system that blows air-conditioned air into the indoor space according to terminals 11, 12, 13 for inputting a report, a control device 20 that controls the air-conditioning devices 31 and 32, and a control instruction from the control device 20. It has devices 31 and 32. In the following, the terminals 11, 12, and 13 are collectively referred to as the terminal 10, and the air conditioners 31 and 32 are collectively referred to as the air conditioner 30.

The terminal 10 and the control device 20 are connected so as to be able to communicate with each other via the local network 41. The local network 41 is, for example, a wired or wireless LAN (Local Area Network) line or a dedicated communication line provided in an office building. Further, the control device 20 and the air conditioning device 30 are connected so as to be able to communicate with each other via the air conditioning network 42. The air-conditioning network 42 is, for example, a wired or wireless communication network or a dedicated communication line in which signals are transmitted by a protocol independently defined by the manufacturer of the air-conditioning equipment 30. Although FIG. 1 shows an example in which the local network 41 and the air conditioning network 42 are different, the control device 20, the terminal 10, and the air conditioning device 30 are all connected so as to be able to communicate with the same network. May be good.

FIG. 2 shows the hardware configurations of the control device 20, the terminal 10, and the air conditioner 30. As shown in FIG. 2, these devices are configured as a computer having a processor 51, a main storage unit 52, an auxiliary storage unit 53, an input unit 54, an output unit 55, and a communication unit 56. The main storage unit 52, the auxiliary storage unit 53, the input unit 54, the output unit 55, and the communication unit 56 are all connected to the processor 51 via the internal bus 57. In FIG. 2, components other than the elements constituting the computer are omitted. For example, the fans and louvers constituting the air conditioner 30 are omitted in FIG.

The processor 51 includes a CPU (Central Processing Unit) or an MPU (Micro Processing Unit). The processor 51 executes the processing described later by executing the program 58 stored in the auxiliary storage unit 53.

The main storage unit 52 includes a RAM (Random Access Memory). The program 58 is loaded into the main storage unit 52 from the auxiliary storage unit 53. Then, the main storage unit 52 is used as a work area of the processor 51.

The auxiliary storage unit 53 includes a non-volatile memory typified by a hard disk and a flash memory. In addition to the program 58, the auxiliary storage unit 53 stores various data used in the processing of the processor 51. The auxiliary storage unit 53 supplies the data used by the processor 51 to the processor 51 according to the instruction of the processor 51, and stores the data supplied from the processor 51.

The input unit 54 includes an input key, a pointing device, and an input device typified by a microphone. The input unit 54 acquires the information input by the user and notifies the processor 51 of the acquired information.

The output unit 55 includes an LCD (Liquid Crystal Display) and an output device typified by a speaker. The output unit 55 presents various information to the user according to the instruction of the processor 51.

The communication unit 56 includes a NIC (Network Interface Controller) for communicating with an external device. The communication unit 56 receives a signal from an external device and outputs the data included in the signal to the processor 51. Further, the communication unit 56 transmits a signal indicating the data output from the processor 51 to an external device.

The terminal 10, the control device 20, and the air-conditioning device 30 constituting the air-conditioning system 100 exhibit various functions by cooperating with the above-mentioned hardware configurations. The functional configurations of the terminal 10, the control device 20, and the air conditioner 30 will be described with reference to FIGS. 3 to 7.

FIG. 3 shows the functional configuration of the terminal 10. The terminal 10 is, for example, a mobile terminal represented by a smartphone and a tablet terminal. The terminal 10 receives the declaration input by the user and transmits the declaration information indicating the contents of the accepted declaration to the control device 20. Although terminals 11, 12, and 13 are shown as examples of terminals 10 in FIG. 1, the number of terminals 10 may be one. When there is one terminal 10, two or more users may input the declaration to one terminal. As shown in FIG. 3, the terminal 10 has a UI (User Interface) unit 101 into which a declaration is input by a user, and a transmission unit 102 for transmitting declaration information.

The UI unit 101 is realized mainly by the cooperation of the input unit 54 and the output unit 55 of the terminal 10. The UI unit 101 according to the present embodiment is configured as a touch screen in which a pointing device and an LCD are integrally formed. The UI unit 101 displays a screen for the user to input the declaration to the user, and accepts the declaration input by the user using the displayed screen.

FIG. 4 shows an example of a declaration input screen displayed by the UI unit 101. The declaration input screen displays a plurality of options with different degrees of user comfort for air conditioning. As shown in FIG. 4, there are two options according to the present embodiment: "not hot (comfortable)" as the first type of declaration and "hot (unpleasant)" as the second type of declaration. Is. Then, the user selects one of the check boxes displayed next to each of the options and touches the "send" button to input the selected declaration to the terminal 10.

Returning to FIG. 3, the transmission unit 102 is mainly realized by the communication unit 56 of the terminal 10. The transmission unit 102 transmits the declaration information indicating the declaration input to the UI unit 101 to the control device 20 via the local network 41.

FIG. 5 shows the functional configuration of the control device 20. The control device 20 is, for example, a controller of a BEMS (Building Energy Management Controller) that comprehensively manages electrical equipment in an office building. As shown in FIG. 5, the control device 20 includes an acquisition unit 210 for acquiring declaration information, a control unit 220 for controlling the components of the control device 20, a declaration database 230 for storing declaration information, and a declaration. It has a transmission unit 240 that transmits a control instruction to the air conditioner 30 accordingly.

The acquisition unit 210 is mainly realized by the communication unit 56 of the control device 20. The acquisition unit 210 acquires the declaration information from the terminal 10 via the local network 41, and outputs the acquired declaration information to the control unit 220.

The control unit 220 is mainly realized by the processor 51 of the control device 20. The control unit 220 stores the declaration information in the declaration database 230 by adding the declaration information output from the acquisition unit 210 to the declaration database 230. Then, the control unit 220 refers to the declaration database 230 to generate a control instruction for the air conditioner 30 according to the declaration, and sets or releases a restriction on the control of the air conditioner 30. The control unit 220 has a first determination module 221 that determines whether or not to generate a control instruction, and a second determination module 222 that determines whether or not to set and release restrictions.

The first determination module 221 calculates and determines the tendency of the feeling of warmth and coldness from the reports of a plurality of users. That is, the first determination module 221 determines whether or not the combination of the numbers for each type of declaration selected by the user is within the first range described later. Further, the second determination module 222 is formed by an executing control method by determining whether or not the combination of numbers for each type of declaration selected by the user is within the second range described later. Determine the degree to which the thermal environment deviates from an environment that is comfortable for the user to some extent.

Here, the control method means either a method in which a restriction on the control of the air conditioner 30 is set or a method in which the restriction is released. In the method in which the limit is set, the target temperature of the air conditioner is fixed to a predetermined reference temperature, and it is not allowed to change the target temperature according to the declaration. From the viewpoint of energy saving, the reference temperature may be predetermined by the administrator of the air conditioning system 100, or may be acquired by the control device 20 from an external server via the Internet. On the other hand, in the method where the restriction is lifted, it is permitted to change the target temperature according to the declaration.

The declaration database 230 is mainly realized by the auxiliary storage unit 53 of the control device 20. FIG. 6 shows an example of the declaration database 230. As shown in FIG. 6, the filing database 230 inputs the filing information identification number, the filing content, the filing person who is the user who entered the filing, the identification number of the terminal where the user entered the filing, and the filing. This is table data in which a plurality of row data associated with the declared date and time are accumulated. One row of data in FIG. 6 is equivalent to one declaration information.

The transmission unit 240 is mainly realized by the communication unit 56 of the control device 20. When the restriction on the control of the air conditioner 30 is released, the transmission unit 240 controls according to the declaration when the combination of the number of the selected declaration types is within the first range described later. The control instruction to be executed is acquired from the control unit 220, and the control instruction is transmitted to the air conditioning device 30 via the air conditioning network 42.

Although the control device 20 has an operation management function of the air conditioning device 30 mounted on a general air conditioning system, the description of the function will be omitted.

FIG. 7 shows the functional configuration of the air conditioner 30. The air conditioner 30 is, for example, an indoor unit installed in a ceiling-embedded type, which is connected to an outdoor outdoor unit via a refrigerant pipe and cooperates with the outdoor unit to perform heat pump type air conditioning. .. The air conditioner 30 according to the present embodiment shall execute only the cooling operation and not the heating operation. As shown in FIG. 7, the air-conditioning device 30 has a receiving unit 301 that receives a control instruction from the control device 20, a control unit 302 that controls the components of the air-conditioning device 30, and a control content instructed by the control instruction. It has a setting storage unit 303 for storing, a refrigerant circuit 304 connected to the outdoor unit, a louver 305 for controlling the wind direction, and a fan 306 for blowing conditioned air into the indoor space.

The receiving unit 301 is mainly realized by the communication unit 56 of the air conditioner 30. The receiving unit 301 receives a control instruction from the control device 20 via the air conditioning network 42, and notifies the control unit 302 of the control content instructed by the control instruction. The control content includes setting the target temperature.

The control unit 302 is mainly realized by the processor 51 of the air conditioner 30. The control unit 302 stores the content of the control instruction in the setting storage unit 303. Then, the control unit 302 refers to the setting storage unit 303 and controls the refrigerant circuit 304, the louver 305, and the fan 306 according to the control instruction to generate conditioned air for setting the temperature of the indoor space as the target temperature. ..

Subsequently, a series of control processes executed by the control device 20 will be described with reference to FIGS. 8 to 14. The control process shown in FIG. 8 starts when the power of the control device 20 is turned on.

In the control process, the control device 20 acquires the declaration (step S1). Specifically, the acquisition unit 210 acquires the declaration information transmitted from the terminal 10 and stores it in the declaration database 230.

Next, the control device 20 determines whether or not the control condition is satisfied (step S2). Specifically, the control unit 220 determines whether or not a predetermined control condition is satisfied. The control condition is a condition for the control device 20 to control the air conditioner 30. For example, the current time has reached a predetermined time, or a predetermined number of declaration information has been acquired. Is. When the control condition is that the current time has reached a predetermined time, the control device 20 transmits the control instruction to the air conditioner 30 at a predetermined time of the day. Therefore, when the control is not restricted, the control instruction is transmitted only once a day. Further, when it is a control condition that a predetermined number of declaration information is acquired, the control device 20 transmits a control instruction every time the declaration from the user is accumulated to some extent.

When it is determined that the control condition is not satisfied (step S2; No), the control device 20 repeats the processes after step S1. On the other hand, when it is determined that the control condition is satisfied (step S2; Yes), the control device 20 executes the control process for the air conditioner 30 (step S3). After that, the control device 20 executes the setting process of whether or not there is a restriction (step S4). Then, the control device 20 repeats the processes after step S1.

Subsequently, each of the control process for the air conditioner 30 in step S3 and the setting process for setting whether or not there is a restriction in step S4 will be described in order.

FIG. 9 shows the details of the control process for the air conditioner 30. The control process for the air conditioner 30 is mainly executed by the first determination module 221 and the transmission unit 240 of the control unit 220.

In the control process for the air conditioner 30, the first determination module 221 refers to the declaration database 230 (step S31). For example, the first determination module 221 reads the declaration information accumulated after the previous control process (step S3) for the air conditioner 30 is completed from the declaration database 230.

Next, the first determination module 221 determines whether or not the restriction on the control of the air conditioner 30 is released (step S32). For example, the first determination module 221 determines whether or not the restriction is currently released by referring to the flag indicating the presence or absence of the restriction stored in the auxiliary storage unit 53 of the control device 20.

When it is determined that the restriction is not released (step S32; No), that is, when the restriction is set, transmission of the control instruction to the air conditioning device 30 is prohibited, so that the air conditioning device 30 is not allowed to transmit the control instruction. The control process ends. As a result, the process executed by the control device 20 returns to the control process shown in FIG.

On the other hand, when it is determined that the restriction is released (step S32; Yes), the first determination module 221 determines whether or not the combination of the number of declarations of all types is within the predetermined first range. Is determined (step S33). In the first range according to the present embodiment, the number of declarations of "not hot (comfortable)" is x1, the number of declarations of "hot (unpleasant)" is x2, and x1 is smaller than x2, that is, "x1". This is the range defined as "x2". In other words, this range is the range in which more users feel uncomfortable. FIG. 10 shows a first range 61 according to this embodiment. The first range 61 may be set by the administrator of the air conditioning system 100, or may be appropriately adjusted with the operation of the air conditioning system 100.

When it is determined that the combination of the number of declarations is not within the first range (step S33; No), that is, when there are many users who feel comfortable, the first determination module 221 has a certain degree of current thermal environment. Judge that it is comfortable. Then, the control process for the air conditioner 30 is completed without the control device 20 transmitting the control instruction to the air conditioner 30. As a result, the process executed by the control device 20 returns to the control process shown in FIG.

On the other hand, when it is determined that the combination of the number of declarations is within the first range (step S33; Yes), the first determination module 221 generates a control instruction for controlling according to the declaration, and the transmission unit. The 240 transmits the generated control instruction to the air conditioner 30 (step S34). After that, the control process for the air conditioner 30 is completed, and the process executed by the control device 20 returns to the control process shown in FIG.

Here, a specific example of the control process for the air conditioner according to the present embodiment will be described with reference to FIG. In the example shown in FIG. 11, steps S31 and S32 similar to the example shown in FIG. 9 are executed.

When the determination in step S32 is affirmed (step S32; Yes), the first determination module 221 calculates the weighted average value m1 of all the declarations (step S331). Specifically, the first determination module 221 calculates the average value m1 by the calculation represented by the following equation (1).

However, M represents the number of all declarations, x1 represents the number of declarations indicating comfort, x2 represents the number of declarations indicating discomfort, and (0,1) is for weighting. It has a zero component as a weight for x1 and a component of 1 as a weight for x2.

Next, the first determination module 221 determines whether or not the calculated average value m1 is larger than the predetermined threshold value m2 (step S332). The threshold value m2 according to this embodiment is 0.5.

When it is determined that the average value m1 is not larger than the threshold value m2 (step S332; No), the control process for the air conditioner 30 ends. On the other hand, when it is determined that the mean value m1 is larger than the threshold value m2 (step S332; Yes), the first determination module 221 targets in response to a large number of "hot (unpleasant)" declarations rather than a small number of declarations of comfort. The transmission unit 240 generates a control instruction for lowering the temperature, and transmits the generated control instruction to the air conditioner 30 (step S341). Then, the control process for the air conditioner 30 is completed.

Note that steps S331 and S332 in FIG. 11 correspond to step S33 in FIG. 9, and step S341 in FIG. 11 corresponds to step S34 in FIG.

Subsequently, the details of the setting process (step S4) for the presence / absence of restrictions will be described with reference to FIG. The process of setting whether or not there is a restriction is mainly executed by the second determination module 222 of the control unit 220.

In the process of setting whether or not there is a restriction, the second determination module 222 refers to the declaration database 230 (step S41). For example, the second determination module 222 reads the declaration information accumulated after the completion of the previous restriction setting process (step S4) from the declaration database 230.

Next, the second determination module 222 determines whether or not the combination of the number of declarations of all types is within the predetermined second range (step S42). The second range according to the present embodiment is a range defined regardless of the number of declarations indicating comfort x1 and a range in which the number of declarations indicating discomfort x2 is larger than the threshold value. In other words, this range is a range in which there are some users who feel uncomfortable. FIG. 13 shows a second range 62 when the threshold value is 5. The second range may be set by the administrator of the air conditioning system 100, or may be appropriately adjusted with the operation of the air conditioning system 100.

When it is determined that the combination of the number of declarations is within the second range (step S42; Yes), the second determination module 222 determines that the thermal environment is deteriorating and limits the control of the air conditioner 30. It is released (step S43). Specifically, the second determination module 222 rewrites the value of the flag indicating the presence / absence of the restriction stored in the auxiliary storage unit 53 of the control device 20 to zero, which is a value indicating that the restriction is released. .. However, if the restriction has already been released, the process of step S43 may be omitted.

On the other hand, when it is determined that the combination of the number of declarations is not within the second range (step S42; No), the second determination module 222 determines that the thermal environment has not deteriorated, and determines that the thermal environment has not deteriorated. A limit to control is set (step S44). For example, when the second determination module 222 has a combination of the number of declarations in the third range 63 shown in FIG. 13, the value of the flag indicating the presence / absence of the restriction is set to the value indicating that the restriction is set. Rewrite to 1. However, if the limit has already been set, the process of step S44 may be omitted. Further, the limit may be set by another determination process represented by step S45 described later without executing the step S44 for setting the limit according to the number of declarations. That is, the limit may be set only according to a parameter different from the number of declarations.

Next to steps S43 and S44, the second determination module 222 sets whether or not there is a limit according to the power consumption (step S45). For example, even if there are relatively many declarations of discomfort and it is desirable to lift the restrictions according to the declarations, the power consumption of the entire office building in which the air conditioning system 100 is installed is imminent on the breaker capacity. If so, it is necessary to set restrictions regardless of the content of the declaration. In addition, even if there are relatively many declarations indicating comfort and it is desirable to set a limit from the viewpoint of energy saving, the limit may be lifted depending on the subsequent schedule or the predicted transition of the outside air temperature. There are also suitable cases. In this way, the second determination module 222 sets whether or not there is a limit according to the power consumption of the office building measured by the measuring device (not shown). After that, the setting process of whether or not there is a restriction is completed, and the process executed by the control device 20 returns to the control process shown in FIG.

Here, a specific example of the setting process for the presence / absence of restrictions according to the present embodiment will be described with reference to FIG. In the example shown in FIG. 14, step S41 similar to the example shown in FIG. 12 is executed.

Next to step S41, the second determination module 222 extracts the declarations indicating that it is not comfortable from the declaration information read from the declaration database 230, and sets the number of extracted declarations as comfortable declarations and uncomfortable declarations. It is calculated as an index value n1 indicating a bias in the number of (step S421).

Next, the second determination module 222 determines whether or not the calculated index value n1 is larger than the predetermined threshold value n2 (step S422). The threshold value n2 is 5, for example, as shown in FIG.

When it is determined that the index value n1 is larger than the threshold value n2 (step S422; Yes), the second determination module 222 executes the process of step S43. On the other hand, when it is determined that the index value n1 is not larger than the threshold value n2 (step S422; No), the second determination module 222 executes the process of step S44. After that, when the second determination module 222 executes step S45 in the same manner as in the example shown in FIG. 12, the process of setting whether or not there is a restriction ends.

In addition, steps S421 and S422 in FIG. 14 correspond to step S42 in FIG.

As described above, the control device 20 according to the present embodiment controls the air conditioner device in response to the reports from two or more users. The control device 20 was selected by the user from a first-class declaration of "not hot (comfortable)" and a second-class declaration of "hot (unpleasant)" with different degrees of comfort of air conditioning. The acquisition unit 210 is provided as an acquisition means for acquiring the declaration information indicating the declaration. Further, when the restriction on the control of the air conditioner 30 is lifted, the control device 20 determines that the combination of the number of first-class declarations and the second-class declaration is within the first range. A transmission unit 240 is provided as a transmission means for transmitting the control instruction to the air conditioner 30. Then, the restriction on the control of the air conditioner 30 is lifted when the combination of the number of declarations is within the second range different from the first range, and the combination of the number of declarations is within the third range different from the first range. Set when at.

As a result, the counting method for declarations for directly controlling air-conditioning equipment and the counting method for setting or canceling restrictions are different. Therefore, it is possible to set or release the restriction at an appropriate timing for the report from the user.

Further, the second range is defined as a range in which the index value n1 indicating the bias in the number of the first type declaration and the second type declaration exceeds the threshold value n2, and the limitation is that the combination of the number of declarations is the second range. It was unlocked when it was inside. Therefore, when the number of declarations is biased toward the unpleasant side, the restriction will be lifted. Therefore, the restriction can be lifted at an appropriate timing according to the report from the user.

In addition, the second range was the range specified regardless of the number of first-class declarations indicating comfort. As a result, the restriction can be lifted at an appropriate timing by paying attention to the number of second-class declarations indicating that it is unpleasant.

Embodiment 2.
Subsequently, the second embodiment will be described focusing on the differences from the first embodiment described above. For the same or equivalent configuration as that of the first embodiment, the same reference numerals are used, and the description thereof will be omitted or simplified. The air-conditioning system 100 according to the present embodiment is related to the first embodiment in that the air-conditioning device 30 also executes a heating operation in addition to the cooling operation and that there are seven types of reports from the user. Is different.

FIG. 15 shows a declaration input screen of the terminal 10 according to the present embodiment. As shown in FIG. 15, the declaration input screen is 7 of "very hot", "hot", "slightly hot", "neither hot nor cold", "slightly cold", "cold" and "very cold". Includes seed choices and check boxes that appear side by side with each choice. The user selects the corresponding option by selecting one of the check boxes. Then, the user inputs the selected declaration to the terminal 10 by touching the "send" button.

Subsequently, the details of the control process (step S3) for the air conditioner 30 and the setting process (step S4) for the presence / absence of restrictions according to the present embodiment will be described in order.

In the control process for the air conditioner 30, as shown in FIG. 16, the process equivalent to steps S31, S32, S331, S332, and S341 according to the first embodiment is executed (see FIG. 11). However, in step S331 according to the present embodiment, the first determination module 221 calculates the average value m1 by the calculation represented by the following equation (2).

However, M is the number of all declarations, x1 is the number of declarations that are "very hot", x2 is the number of declarations that are "hot", and x3 is the number of declarations that are "slightly hot". x4 is the number of declarations "neither hot nor cold", x5 is the number of declarations "slightly cold", x6 is the number of declarations "cold", and x7 is the number of declarations "very cold". Represents the number of each. Further, (3,2,1,0, -1, -2, -3) is a vector for weighting, and a component having a value of 3 as a weight corresponding to x1 and a value as a weight corresponding to x2. 2 components, a component with a value of 1 as a weight corresponding to x3, a component with a value of zero as a weight corresponding to x4, a component with a value of -1 as a weight corresponding to x5, and a component having a value of -1 corresponding to x6. It has a component having a value of -2 as a weight and a component having a value of -3 as a weight corresponding to x7. The value of the component of this vector may be appropriately adjusted by the manager of the air conditioning system 100.

The average value m1 calculated in step S331 indicates the average feeling of warmth and coldness of all the users who input the declaration. For example, if the mean value m1 is a positive value and its magnitude is large, then the user feels hotter on average, and if the mean value m1 is a negative value and its magnitude is large, then On average, the user will feel colder. The closer the average value m1 is to zero, the more comfortable the user feels on average.

When it is determined in step S332 that the average value m1 is larger than the threshold value m2 (step S332; Yes), the process of step S341 is executed. The threshold value m2 according to the present embodiment is usually a positive value, for example, 2. On the other hand, when it is determined in step S332 that the average value m1 is not larger than the threshold value m2 (step S332; No), the first determination module 221 determines whether or not the average value m1 is smaller than the predetermined threshold value m3. Is determined (step S333). The threshold m3 is usually a negative value, for example -2.

When it is determined that the average value m1 is not smaller than the threshold value m3 (step S333; No), the control process for the air conditioner 30 ends. On the other hand, when it is determined that the average value m1 is smaller than the threshold value m3 (step S333; Yes), the first determination module 221 generates a control instruction for raising the target temperature, and the transmission unit 240 is generated. The control instruction is transmitted to the air conditioner 30 (step S342). Then, the control process for the air conditioner 30 is completed.

Note that step S333 in FIG. 16 corresponds to step S33 in FIG. 9, and step S342 in FIG. 16 corresponds to step S34 in FIG. Further, although not shown because it is a range in a multidimensional space, the determination in step S332 is whether or not the combination of the seven types of declared numbers is within the range defined by the above equation (2) and the threshold value m2. Is equivalent to determining. Further, the determination in step S333 is equivalent to determining whether or not the combination of the seven types of declared numbers is within the range defined by the above equation (2) and the threshold value m3.

In the setting process (step S4) of whether or not there is a restriction according to the present embodiment, as shown in FIG. 17, step S41 according to the first embodiment is executed (see FIG. 14). Next to step S41, the second determination module 222 extracts the declarations indicating that it is not comfortable from the declaration information read from the declaration database 230, and determines the size of the weighted average value of the extracted declarations as the number of declarations. It is calculated as an index value n1 indicating the bias of (step S423). Specifically, the second determination module 222 extracts six types of declarations excluding the declaration of "neither hot nor cold", and calculates the index value n1 by the calculation represented by the following equation (3).

However, N represents the number of extracted declarations, and x1 to x3 and x5 to x7 represent the number of declarations similar to the above formula (2), respectively. Further, (3,2,1, -1, -2, -3) is a vector for weighting, and a component having a value of 3 as a weight corresponding to x1 and a value having a value of 2 as a weight corresponding to x2. A component with a value of 1 as a weight corresponding to x3, a component with a value of -1 as a weight corresponding to x5, a component with a value of -2 as a weight corresponding to x6, and a weight corresponding to x7. It has a component having a value of -3. The value of the component of this vector may be appropriately adjusted by the air conditioning manager.

The index value n1 calculated in step S423 is shown in FIG. 19 rather than the case where the number of declarations for each type is generally distributed around the center corresponding to the comfortable declaration, for example, as shown in FIG. In addition, it becomes a large value when the distribution is biased toward the hot and unpleasant side. Further, the index value n1 becomes a large value even when the number of declarations is distributed unevenly toward the cold and unpleasant side. Therefore, the index value n1 can be used as an index value indicating the degree to which the number of declarations is biased toward the unpleasant side.

Returning to FIG. 17, after step S423, the second determination module 222 determines whether or not the index value n1 is larger than the predetermined threshold value n2 (step S422). This threshold value n2 is a positive value predetermined by the administrator of the air conditioning system 100 according to the number of users, and is defined as 10, for example, when there are about 10 users.

Then, when the determination in step S422 is affirmed (step S422; Yes), the processes after step S43 are executed as in the first embodiment, and the determination in step S422 is denied (step S422; No). The processes after step S44 are executed in the same manner as in the first embodiment (see FIG. 14).

Note that step S423 in FIG. 17 corresponds to step S42 in FIG. Further, although not shown because it is a range in a multidimensional space, the determination in step S422 is whether or not the combination of seven types of declared numbers is within the range defined by the above equation (3) and the threshold value n2. Is equivalent to determining. As can be seen from the fact that x4 is not included in the above formula (3), this range is defined regardless of the number of declarations x4 indicating comfort.

As described above, the control device 20 according to the present embodiment controls the air conditioner 30 in response to the seven types of declarations, and when the index value n1 exceeds the threshold value n2 as the first threshold value, the air conditioner is air-conditioned. The restriction on the control of the device 30 has been lifted. As a result, it is possible to control the air conditioner according to the user's experience as compared with the first embodiment. As a result, the comfort of the user can be improved.

In this embodiment, the declaration "neither hot nor cold" is treated as a declaration indicating comfort, and the other six types of declarations are treated as declarations indicating discomfort. Not limited to. For example, the declarations of "slightly hot", "neither hot nor cold", and "slightly cold", which are considered to require less immediate improvement in the environment, may be treated as a declaration of comfort. When these three types of declarations are treated as declarations indicating comfort, the index value n1 is calculated by the calculation represented by the following equation (4).

However, N represents the number of four types of declarations, "very hot", "hot", "cold", and "very cold", extracted from the declaration database 230.

Embodiment 3.
Subsequently, the third embodiment will be described focusing on the differences from the second embodiment described above. For the same or equivalent configuration as that of the second embodiment, the same reference numerals are used, and the description thereof will be omitted or simplified. The air conditioning system 100 according to the present embodiment is different from that according to the first embodiment in that the index value n1 is calculated as indicating a distortion of the number of declarations.

FIG. 20 shows a setting process (step S4) for the presence or absence of restrictions according to the present embodiment. In the process of setting the presence or absence of this restriction, as shown in FIG. 20, the second determination module 222 determines the magnitude of the difference between the weighted average value m1 and the mode value of all the declarations after step S41. It is calculated as an index value n1 indicating a distortion of the number of declarations (step S424). The mode is the value corresponding to the declaration with the largest number of declarations among the seven types of declarations. Here, when the number of declarations of "very hot" is the maximum, the mode is set to 3, and when the number of declarations of "hot" is the maximum, the mode is set to 2, and the declaration of "slightly hot" is set. When the number of is maximum, the mode is set to 1, and when the number of declarations "neither hot nor cold" is the maximum, the mode is set to zero, and the number of declarations "slightly cold" is the largest. In this case, the mode is -1, the mode is -2 when the number of "cold" declarations is the largest, and the mode is the maximum when the number of "very cold" declarations is the largest. Let it be -3.

The index value n1 calculated in step S424 becomes a larger value when the number of declarations is distorted and distributed as shown in FIG. 21 than in the case of the distribution shown in FIG. Therefore, the index value n1 can be used as an index value indicating the degree to which the number of declarations is distorted and distributed. When the number of declarations is distributed as shown in FIG. 21, the positive value and the negative value of the above formula (3) or the above formula (4) are canceled out, and the index value n1 indicating the bias according to the second embodiment is offset. Is not a large value.

Then, the second determination module 222 executes the processes after step S422 as in the example shown in FIG.

Note that step S424 in FIG. 20 corresponds to step S42 in FIG. Further, although not shown because it is a range in a multidimensional space, the determination in step S422 is that the combination of the seven types of declared numbers is within the range defined by the above-mentioned mode calculation method and the threshold value n2. It is equivalent to determining whether or not there is.

As described above, the index value n1 according to the present embodiment was calculated as indicating a distortion of the distribution of the number of declarations. Then, when the index value n1 exceeds the threshold value n2 as the second threshold value, the restriction on the control of the air conditioner 30 is released. As a result, even if the number of declarations is not biased, the limit can be set or released when the distribution of the number of declarations is distorted. As a result, the restriction can be lifted when the thermal environment is deteriorating to improve user comfort.

In the present embodiment, the magnitude of the difference between the average value m1 and the mode value is set to the index value n1, but the present invention is not limited to this. For example, the magnitude of the difference between the average value m1 and the median value may be set as the index value n1.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above embodiments.

For example, in the above embodiment, the user inputs the declaration even when he / she feels comfortable. However, in such a case, since it is not necessary for the user to input the declaration, there is a possibility that the declaration will not be input. Therefore, for example, the control device 20 may treat the number of unanswered numbers obtained by subtracting the number of declarations from the number of terminals 10 as the number of declarations indicating comfort. If the number of non-answers is treated as the number of declarations indicating comfort, the user only needs to input the request for air conditioning when he / she feels uncomfortable. This simplifies the user's effort.

Further, the index value n1 indicating the bias of the number of declarations according to the second embodiment and the index value n1 indicating the distortion of the distribution of the number of declarations according to the third embodiment may be used in combination. For example, the limit may be set or released by determining whether or not one or both of these two index values exceeds a predetermined threshold value. This makes it possible to accurately detect the deterioration of the thermal environment and set the presence or absence of restrictions.

Further, in the above embodiment, a declaration selected by the user from a plurality of types of declarations is input, but the present invention is not limited to this. For example, the terminal 10 recognizes the voice spoken by the user in an arbitrary wording, selects a declaration suitable for the user's experience from a plurality of types, and transmits the declaration information indicating the selected declaration to the control device 20. You may.

The functions of the terminal 10, the control device 20, and the air conditioner 30 according to the above embodiment can be realized by dedicated hardware or by a normal computer system.

For example, a device that executes the above-described processing can be configured by storing and distributing a program 58 stored in the auxiliary storage unit 53 in a computer-readable recording medium and installing the program 58 in the computer. it can.

Further, the program 58 may be stored in a disk device of a server device on a communication network represented by the Internet, superposed on a carrier wave, and downloaded to a computer, for example.

The above process can also be achieved by starting and executing the program 58 while transferring it via the communication network.

Further, the above-mentioned processing can also be achieved by executing all or a part of the program 58 on the server device and executing the program 58 while the computer sends and receives information about the processing via the communication network. ..

If the above functions are shared by the OS (Operating System) or realized by collaboration between the OS and the application, only the parts other than the OS may be stored in the medium and distributed. You can also download it to your computer.

Further, the means for realizing the function of the air conditioning system 100 is not limited to software, and a part or all of the software may be realized by dedicated hardware including a circuit.

The present invention allows for various embodiments and modifications without departing from the broad spirit and scope of the present invention. Moreover, the above-described embodiment is for explaining the present invention, and does not limit the scope of the present invention. That is, the scope of the present invention is indicated not by the embodiment but by the claims. Then, various modifications made within the scope of the claims and the equivalent meaning of the invention are considered to be within the scope of the present invention.

The present invention is suitable for controlling air conditioning equipment.

100 Air conditioning system, 10 to 13 terminals, 101 UI unit, 102 transmitter unit, 20 control device, 210 acquisition unit, 220 control unit, 221 first judgment module, 222 second judgment module, 230 declaration database, 240 transmitter, 30 ~ 32 Air conditioning equipment, 301 receiver, 302 control unit, 303 setting storage unit, 304 refrigerant circuit, 305 louver, 306 fan, 41 local network, 42 air conditioning network, 51 processor, 52 main storage unit, 53 auxiliary storage unit, 54 Input unit, 55 output unit, 56 communication unit, 57 internal bus, 58 program, 61 1st range, 62 2nd range, 63 3rd range.

Claims (6)

A control device that controls air conditioning equipment in response to reports from two or more users.
An acquisition method for acquiring information indicating a declaration selected from the first type declaration and the second type declaration having different degrees of comfort of air conditioning, and
When the restriction on the control of the air conditioner is released and the combination of the number of the first type declarations and the number of the second type declarations is within the first range, the control instruction is given to the air conditioner. Equipped with a transmission means to transmit to the device,
A control device in which the limitation is set or lifted when the combination is within a second range different from the first range. The second range is a range in which the index value indicating the bias in the number of the first type declaration and the second type declaration exceeds the first threshold value.
The limitation is lifted when the combination is within the second range.
The control device according to claim 1. The acquisition means acquires information indicating a declaration selected from the first type declaration, the second type declaration, and one or more other types of declarations having different degrees of comfort of air conditioning.
In the second range, an index value indicating a distortion of the distribution between the number of the first type of declarations, the number of the second type of declarations, and the number of the other one or more types of declarations sets the second threshold value. In the range that exceeds
The combination is a combination of the number of first-class declarations, the second-class declarations, and the other one or more types of declarations.
The limitation is lifted when the combination is within the second range.
The control device according to claim 1 or 2. The first type of declaration is a declaration indicating that the air conditioning is comfortable.
The second range is a range defined regardless of the number of the first type declarations.
The control device according to claim 1 or 2. It is a control method that controls air conditioning equipment by receiving reports from two or more users.
When the restriction on the control of the air conditioning equipment is lifted, the number of the first type declarations and the number of the second type declarations in which the degree of comfort of air conditioning differs from the first type declarations. Including the step of transmitting a control instruction to the air conditioner when the combination is within the first range.
A control method in which the limitation is set or lifted when the combination is within a second range different from the first range. For computers that control air conditioning equipment in response to reports from two or more users
When the restriction on the control of the air conditioning equipment is lifted, the number of the first type declarations and the number of the second type declarations in which the degree of comfort of air conditioning differs from the first type declarations. When the combination is within the first range, the control instruction is transmitted to the air conditioner.
A program in which the limitation is set or lifted when the combination is within a second range different from the first range.

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