JP2018162947A - Environmental management device, environmental management program and environmental management method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an environmental management device, an environmental management program and an environmental management method capable of reducing usage of electric power for managing an environment.SOLUTION: An environmental management device includes: a state acquisition section for acquiring actual measurement values of a temperature and humidity of outside air and forecast values of the temperature of the humidity after elapse of a predetermined time; a deviation degree calculation section for referring to a storage section in which a condition for defining a predetermined environment is stored and calculating a first deviation degree indicating a degree of deviation of the actual measurement values from the condition and a second deviation degree indicating a degree of deviation of the forecast values from the condition; and a control section for controlling an air-conditioning related facility in accordance with a trend of a change of the deviation degree that is determined based on the first deviation degree and the second deviation degree.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an environment management apparatus, an environment management program, and an environment management method.

  In recent years, efforts are being made in data centers, homes, and the like to maintain the indoor environment at a predetermined condition by managing the indoor temperature, humidity, and the like.

  For example, in a data center or the like, the temperature and humidity of the server room are managed so as not to deviate from the specified conditions to prevent the server from going down. In houses and the like, conditions that people feel comfortable are regulated, and air conditioners are managed to satisfy these conditions.

  Furthermore, in such an approach, in order to satisfy the conditions while suppressing the amount of power used, not only the air conditioning equipment is used but also the intake of outside air is appropriately performed.

JP2013-213345A JP 2002-5488 A JP 2013-92298 A

  In the conventional approach described above, for example, an air conditioner, which is one of air conditioning equipment, uses a lot of electric power at the time of start-up, so that the amount of electric power used increases when it is frequently operated and stopped. Further, in the conventional approach, even when the opening and closing of windows and ventilation openings are controlled to take in outside air, the power consumption increases as the number of times of control increases.

  It is an object of the disclosed technology to provide an environment management apparatus, an environment management program, and an environment management method that reduce power consumption in environment management.

  The disclosed technology refers to a state acquisition unit that acquires measured values of the temperature and humidity of the outside air and a predicted value of the temperature and humidity after a predetermined time, and a storage unit that stores conditions that define a predetermined environment A deviation degree calculating unit for calculating a first deviation degree indicating a degree of deviation of the actual measurement value from the condition and a second deviation degree indicating a degree of deviation of the forecast value from the condition; A control unit that controls air-conditioning-related equipment according to the calculation of the tendency of change in the degree of deviation determined from the first degree of deviation and the second degree of deviation. .

  Each of the above sections may be a computer-readable storage medium storing a program and a method for causing the above sections to be executed by a computer as a procedure for realizing the above sections.

  Reduce power consumption in environmental management.

It is a figure explaining the environment management apparatus of 1st embodiment. It is a figure which shows an example of the hardware constitutions of the environment management apparatus of 1st embodiment. It is a figure which shows an example of the state database of 1st embodiment. It is a figure which shows an example of the setting value database of 1st embodiment. It is a figure which shows an example of the operation history database of 1st embodiment. It is a figure explaining the function of the environment management apparatus of 1st embodiment. It is a 1st flowchart explaining operation | movement of the environment management apparatus of 1st embodiment. It is a 2nd flowchart explaining operation | movement of the environment management apparatus of 1st embodiment. It is a 3rd flowchart explaining operation | movement of the environment management apparatus of 1st embodiment. It is a 4th flowchart explaining operation | movement of the environment management apparatus of 1st embodiment. It is a flowchart explaining the process of the change of the comfort conditions in the environment management apparatus of 1st embodiment. It is a 1st figure explaining operation | movement of the environment management apparatus of 1st embodiment. It is a 1st figure explaining the procedure of operation | movement of the environment management apparatus of 1st embodiment. It is a 2nd figure explaining operation | movement of the environment management apparatus of 1st embodiment. It is a 2nd figure explaining the procedure of operation | movement of the environment management apparatus of 1st embodiment. It is a figure explaining the change of the comfort conditions by the environment management apparatus of 1st embodiment. It is a figure explaining the procedure of the comfort conditions by the environment management apparatus of 1st embodiment. It is a figure explaining the environment management apparatus of 2nd embodiment.

(First embodiment)
The first embodiment will be described below with reference to the drawings. FIG. 1 is a diagram illustrating an environment management apparatus according to the first embodiment.

  The environment management apparatus 100 shown in FIG. 1 controls the indoor air-conditioning equipment 200 such as a residence, a data center, a hospital, a nursing care facility, etc., and manages the indoor environment comfortably, and uses power in this management. Reduce the amount.

  The environment management apparatus 100 of this embodiment may be a general stationary type or notebook type computer, or may be a tablet type computer. Moreover, the environment management apparatus 100 of this embodiment may be a smartphone or the like.

  The environment management apparatus 100 according to the present embodiment is connected to a sensor group 300 for detecting the state of the air conditioning related equipment 200 via a LAN (Local Area Network) or the like, and as state information indicating the state of the air conditioning related equipment 200 The data output from the sensor group 300 is acquired.

  In addition, the environment management apparatus 100 performs infrared communication with a remote controller (hereinafter referred to as a remote controller) group 400 for operating the air conditioning related equipment 200, and acquires operation history information indicating a history of operations on the air conditioning related equipment 200. .

  Furthermore, the environment management apparatus 100 according to the present embodiment communicates with, for example, a weather information service 500 that provides weather information via the Internet or the like, and acquires measured values and predicted values of humidity and temperature indicating the outdoor environment. To do.

  The environment management apparatus 100 according to the present embodiment includes a state database 110, a setting value database 120, an operation history database 130, and an environment management processing unit 140.

  In the state database 110, data output from sensors included in the sensor group 300, actual measurement values acquired from the weather information service 500, and the like are stored as state information. The setting value database 120 stores values for setting various conditions for the outdoor environment. The operation history database 130 stores operation history information acquired from the remote control group 400. Details of each database will be described later.

  In addition, the environment management apparatus 100 according to the present embodiment refers to the state database 110 and the setting value database 120 by the environment management processing unit 140, and determines whether or not the outdoor environment deviates from preset comfort conditions. Determine. Then, when the outdoor environment deviates from the comfort condition, the environment management processing unit 140 calculates a deviation degree indicating the degree of deviation.

  Furthermore, the environment management apparatus 100 according to the present embodiment obtains a predicted value of outdoor temperature and humidity provided from the weather information service 500 by the environment management processing unit 140, and the degree of deviation from the predicted value. The tendency of the change of the deviation degree indicating whether or not to change is determined.

  And the environment management apparatus 100 of this embodiment performs control with respect to the air-conditioning related equipment 200 based on the determination result of the tendency of the deviation from the comfortable conditions of the outdoor environment and the deviation degree.

  For example, in the present embodiment, when the degree of departure is smaller than a predetermined value and the tendency of change in the degree of departure tends to decrease, the air conditioning related equipment need not be controlled.

  As described above, according to the present embodiment, by controlling the air conditioning related equipment based on the degree of deviation from the outdoor environment comfort conditions and the tendency of the deviation degree to change, control of unnecessary air conditioning related equipment is suppressed. , Power consumption can be reduced.

  In the example of FIG. 1, the air conditioning related equipment 200 is an air conditioner (hereinafter referred to as an air conditioner) 210, a window 220, etc., but is not limited thereto. The air conditioning related equipment 200 includes, for example, a ventilation fan. The air conditioning related facility 200 of the present embodiment may be a facility that can take outside air into the room. In addition, the air conditioning-related equipment 200 may include a fan, a circulator, or the like that supports the intake of outside air into the room. Moreover, the air conditioning related equipment 200 of this embodiment has a function of detecting the temperature and humidity in the room.

  The sensor group 300 of the present embodiment includes, for example, an air conditioner operating state sensor 310 that detects an operating state of the air conditioner, a window opening / closing sensor 320 that detects opening / closing of a window, and the like. Moreover, the sensor group 300 of this embodiment contains the sensor for detecting the state of the installation contained in the air-conditioning related equipment 200 besides the sensor mentioned above.

  The sensor group 300 of the present embodiment includes, for example, an air conditioner operating state sensor 310 that detects an operating state of the air conditioner, a window opening / closing sensor 320 that detects opening / closing of a window, and the like. Moreover, the sensor group 300 of this embodiment contains the sensor for detecting the state of the installation contained in the air-conditioning related equipment 200 besides the sensor mentioned above.

  In addition, the remote control group 400 of the present embodiment includes, for example, a remote control 410 for the air conditioner 210, a remote control 420 for the window 220 that opens and closes the window 220, and the like.

  In this embodiment, by managing the indoor environment in this way, for example, the interior of a house where an elderly person who does not like an air conditioner resides, the interior of a room where a newborn is staying, and a temperature change are weak. It is possible to appropriately manage the environment such as indoors of facilities where organisms live.

  Hereinafter, a hardware configuration of the environment management apparatus 100 according to the present embodiment will be described with reference to FIG. FIG. 2 is a diagram illustrating an example of a hardware configuration of the environment management apparatus according to the first embodiment.

  The environment management apparatus 100 according to the present embodiment includes an input device 11, an output device 12, a drive device 13, an auxiliary storage device 14, a memory device 15, an arithmetic processing device 16, and an interface device 17 that are connected to each other via a bus B. It is an information processing apparatus including.

  The input device 11 is for inputting various information. The output device 12 outputs (displays) various information. The interface device 17 includes a modem, a LAN card, and the like, and is used for connecting to a network.

  The environment management program is at least a part of various programs that control the environment management apparatus 100. The environment management program is provided by, for example, distribution of the storage medium 18 or downloading from the network. The storage medium 18 on which the environmental management program is recorded is information such as a CD-ROM, a flexible disk, a magneto-optical disk, etc., a storage medium for recording information optically, electrically or magnetically, a ROM, a flash memory, etc. Various types of storage media, such as a semiconductor memory that electrically records data, can be used.

  The environment management program is installed from the storage medium 18 to the auxiliary storage device 14 via the drive device 13 when the storage medium 18 storing the environment management program is set in the drive device 13. The environment management program downloaded from the network is installed in the auxiliary storage device 14 via the interface device 17.

  The auxiliary storage device 14 stores the installed environment management program and stores necessary files, data, and the like. The memory device 15 reads and stores the environment management program from the auxiliary storage device 14 when the computer is activated. The arithmetic processing unit 16 implements various processes as will be described later in accordance with the environment management program stored in the memory device 15.

  For example, when the environment management apparatus 100 according to the present embodiment is a tablet computer or a smartphone, a display operation apparatus having an input function and an output function is provided instead of the input apparatus 11 and the output apparatus 12. become.

  Next, each database included in the environment management apparatus 100 of this embodiment will be described. Each database included in the environment management apparatus 100 may be provided in the auxiliary storage device 14, for example. Moreover, in this embodiment, although each database has what the environment management apparatus 100 has, it is not limited to this. Each database to be described later may be provided in a storage device outside the environment management apparatus 100.

  FIG. 3 is a diagram illustrating an example of a state database according to the first embodiment. The state database 110 of the present embodiment includes date and time, outdoor environment, and related equipment states and states as information items. In the following description, information including the values of these items is referred to as state information. In this embodiment, the value of the item “outdoor environment” is referred to as weather information, and the values of the other items are referred to as facility state information. That is, the state information of this embodiment includes weather information and facility state information. The weather information included in the state information is actual values of temperature and humidity.

  In the state database 110 of the present embodiment, state information is stored for each facility included in the air conditioning related facility 200. In the example of FIG. 3, state information 110-1 of the air conditioner 210 included in the air conditioning related facility 200 is shown. The state information 110-1 may be associated with the air conditioner 210 by including an identifier or the like for specifying the air conditioner 210.

  Moreover, in this embodiment, the information which specifies the place where the equipment matched with the state information is installed may also be included.

  In the example of FIG. 3, the air conditioner 210 is set to the room A. Therefore, the state information 110-1 includes information for specifying the air conditioner 210 and information for specifying a space (room) in which the air conditioner 210 is set.

  The value of the item “date and time” indicates the date and time when the status information is acquired. The item “outdoor environment” includes the items “temperature” and “humidity”. The value of the item “temperature” is an actually measured value of the outdoor temperature included in the weather information acquired from the weather information service 500. The value of the item “humidity” is an actual measurement value of outdoor humidity included in the weather information acquired from the weather information service 500.

  The value of the item “related equipment state” indicates the state of the equipment related to the equipment associated with the state information in the air conditioning related equipment 200.

  The equipment associated with the equipment associated with the state information is provided in the same space (in the room) as the equipment associated with the state information, and is associated with the state information in order to control the indoor environment. It is equipment that can be controlled in combination with the installed equipment.

  In the example of FIG. 3, the value of the item “related equipment state” indicates the state of the window 220 that is equipment related to the air conditioner 210 that is equipment associated with the state information 110-1.

  The value of the item “state” indicates the state of the equipment associated with the state information. The value of the item “state” of the state information 110-1 illustrated in FIG. 3 indicates the state of the air conditioner 210 associated with the state information 110-1.

  In the example of FIG. 3, for example, the outdoor temperature acquired at 9:00 on 2/21 is 25 ° C., the humidity is 40%, and the window 220 associated with the air conditioner 210 is closed. It can be seen that the operation is stopped.

  In the state database 110 of the present embodiment, as with the state information 110-1, for the window 220 included in the air conditioning related equipment 200, information for specifying the window 220 and a space (room) in which the window 220 is provided are specified. The state information 110-1 including the information to be stored is also stored.

  FIG. 4 is a diagram illustrating an example of the setting value database according to the first embodiment. The setting value database 120 of the present embodiment includes space, comfortable environment, allowable environment, limit environment, and duration limit time as information items. Information including the values of these items is referred to as setting value information.

  The value of the item “space” indicates information for specifying a room that is a target for controlling the indoor environment. Specifically, for example, an identifier assigned to each room may be used.

  Each of the items “comfortable environment”, “allowable environment”, and “limit environment” has items “upper limit temperature”, “lower limit temperature”, “upper limit humidity”, and “lower limit humidity”.

  Each value of the items "Upper temperature", "Lower temperature", "Upper humidity", and "Lower humidity" included in the "Comfortable environment" is the upper temperature limit that defines the environment in which people are assumed to feel comfortable. And a lower limit value, and an upper limit value and a lower limit value of humidity.

  Each value of the items “Upper temperature”, “Lower temperature”, “Upper humidity” and “Lower humidity” included in the “Allowable environment” does not feel uncomfortable or is immediately healthy if within this range. The upper limit value and the lower limit value of the temperature, and the upper limit value and the lower limit value of the humidity that define the environment that is estimated to have no adverse effect are shown.

  Each value of the items "Upper limit temperature", "Lower limit temperature", "Upper limit humidity", and "Lower limit humidity" included in the item "Limited environment" defines the environment in which it is estimated that it is difficult for people to stay there The upper and lower temperature limits and the upper and lower humidity limits are shown.

  The value of the item “continuation limit time” indicates the longest time that a person can stay in the room in the limit environment.

  In the example of FIG. 4, in the room A, the temperature is 17 ° C. to 28 ° C., and the humidity is 40% to 70%. A range of temperature and humidity indicating a comfortable environment is called a comfortable condition.

  Moreover, in this embodiment, the case where the temperature does not enter the range of 17 ° C to 28 ° C among the 14 ° C to 31 ° C and the humidity does not fall within the range of 40% to 70% among the 30% to 80%. Make it an acceptable environment. Further, the temperature and humidity ranges indicating the allowable environment are referred to as allowable conditions.

  In this embodiment, the difference between the upper limit value / lower limit value of the comfort condition and the upper limit value / lower limit value of the allowable condition is referred to as an upper limit side allowable difference / lower limit side allowable difference. For example, the allowable difference with respect to the temperature is an upper limit allowable difference that is a difference between the upper limit temperature of the comfortable condition and the upper limit temperature of the allowable condition is + 3 ° C., and a lower limit that is a difference between the lower limit temperature of the comfortable condition and the lower limit temperature of the allowable condition The side tolerance is -3 ° C.

  Moreover, in this embodiment, when temperature does not enter into the range of 14 degreeC-31 degreeC among 10 degreeC-32 degreeC, and humidity does not enter into the range of 30%-80% among 20%-90%. Limit the environment. Further, the temperature and humidity range indicating the limit environment is called a limit condition. It can be seen that in this critical environment, a person is not allowed to stay for more than 0.5 hours.

  In the example of FIG. 4, each condition is associated with a space (room) to be managed. However, the present invention is not limited to this. Each condition may be associated with, for example, each air conditioning related facility 200 set in a room to be managed, or may be associated with identification information of a user of the environment management apparatus 100 or the like. .

  That is, in this embodiment, each condition may be set for each air conditioning related facility 200 or for each user of the environment management apparatus 100.

  FIG. 5 is a diagram illustrating an example of the operation history database according to the first embodiment. The operation history database 130 of this embodiment includes the operation type, date and time, and indoor environment as information items. In the following description, information including the values of these items is referred to as operation history information.

  In the operation history database 130 of the present embodiment, operation history information is stored for each facility included in the air conditioning related facility 200. In the example of FIG. 5, operation history information 130-1 of the air conditioner 210 included in the air conditioning related equipment 200 is shown.

  The value of the item “operation type” indicates the type of operation for the equipment associated with the operation history information. The value of the item “date and time” indicates the date and time when the operation was performed. The values of the items “temperature” and “humidity” included in the item “room environment” indicate the outdoor temperature and humidity at the date and time when the operation was performed.

  In the example of FIG. 5, the air conditioner 210 is operated to turn on the power to the air conditioner 210 at 10:25 of 2/21. At this time, the indoor temperature is 29 ° C. and the humidity is 50 %.

  Next, functions of the environment management apparatus 100 according to the present embodiment will be described with reference to FIG. FIG. 6 is a diagram for explaining functions of the environment management apparatus according to the first embodiment.

  The environment management apparatus 100 according to the present embodiment includes an environment management processing unit 140. The environment management processing unit 140 is realized by the arithmetic processing device 16 of the environment management device 100 reading out and executing the environment management program from the memory device 15.

  The environment management processing unit 140 of this embodiment includes a state acquisition unit 141, a deviation degree calculation unit 142, a first control notification unit 143, a second control notification unit 144, a control prediction unit 145, a prediction control notification unit 146, and a device operation unit. 147, an operation history acquisition unit 148, a setting reflection unit 149, and an output unit 150.

  The state acquisition unit 141 according to the present embodiment acquires state information, and includes an equipment state acquisition unit 151 and a weather information acquisition unit 152. The equipment state acquisition unit 151 acquires equipment state information indicating the state of each equipment of the air conditioning related equipment 200. The weather information acquisition unit 152 acquires the temperature (actual value) and humidity (actual value) of the outdoor environment as weather information from the weather information service 500. In other words, the weather information acquisition unit 152 acquires measured values of the temperature and humidity of the outside air.

  The departure degree calculation unit 142 refers to the state database 110 and the setting value database 120, and calculates the degree of departure from the comfortable environment at the outdoor temperature and humidity acquired by the state acquisition unit 141.

  The deviation degree calculation unit 142 according to the present embodiment is the actual value of the deviation degree based on the actual measurement value of the outdoor temperature and humidity acquired by the weather information acquisition unit 152 of the state acquisition unit 141, and the prediction of the outdoor temperature and humidity. A deviation value forecast value based on the value is calculated. Details of the departure degree by the departure degree calculation unit 142 will be described later.

  The first control notification unit 143 notifies the device operation unit 147 of a method of controlling the indoor environment when the outdoor environment satisfies the comfort condition. Specifically, the first control notification unit 143 notifies that control is performed to stop the air conditioner and open the window. In the following description, the notification from the first control notification unit 143 is referred to as a first control notification.

  The second control notification unit 144 notifies the device operation unit 147 of a method for controlling the indoor environment when the outdoor environment does not satisfy the allowable conditions. Specifically, the second control notification unit 144 notifies that the operation of the air conditioner is started and the window is closed. In the following description, the notification from the second control notification unit 144 is referred to as a second control notification.

  The control predicting unit 145 predicts a method of controlling the indoor environment when the outdoor environment satisfies the allowable conditions. Specifically, the control prediction unit 145 obtains a predicted value of outdoor temperature and humidity at the time when the continuation limit time has elapsed from the present time from the weather information service 500, and the deviation degree calculation unit 142 adds the predicted value to the predicted value. The forecast value of the deviation degree based on is calculated.

  Then, the control predicting unit 145 determines a tendency of a change in the deviation degree from the present time to the continuation limit time from the actual measurement value of the current deviation degree and the predicted value of the deviation degree after the continuation limit time has elapsed. Predict the control method according to the results. Details of the determination of the tendency of the deviation degree change by the control prediction unit 145 will be described later.

  The prediction control notification unit 146 selects either the control predicted by the control prediction unit 145 or the control for maintaining the current state of the air conditioning related equipment 200 based on the tendency of the deviation degree change, The device control unit 147 is notified of the selected control method. In the following description, the notification from the prediction control notification unit 146 is referred to as a prediction control notification.

  Specifically, when the tendency of change is a tendency to improve, the predictive control notification unit 146 selects control that maintains the current state of the air conditioning-related equipment 200, and the tendency of the change tends to deteriorate. If so, the predicted control is selected. The tendency to improve is a tendency that the outdoor environment approaches a comfortable environment, and the tendency to deteriorate is a tendency that the outdoor environment deviates from the comfortable environment.

  The device operation unit 147 creates operation content information indicating the content of the operation on the air conditioning related equipment 200 according to the control method notified by each notification unit.

  The operation history acquisition unit 148 acquires operation history information for the air conditioning related equipment 200 performed by the remote control group 400 and stores it in the operation history database 130. Note that the operation history acquisition unit 148 may acquire operation history information including the type of operation from the type of button operated in the remote control group 400, for example.

  The setting reflection unit 149 refers to the operation history database 130 and reflects the operation performed by the operator of the remote control group 400 in the comfort condition.

  The output unit 150 may output the operation content information created by the device operation unit 147 to the remote control group 400 as an operation instruction for the air conditioning related equipment 200, and cause the remote control group 400 to operate the air conditioning related equipment 200. Further, the output unit 150 may cause the operation content information created by the device operation unit 147 to be output to the output device 12 or the like of the environment management apparatus 100.

  As described above, in the present embodiment, the first control notification unit 143, the second control notification unit 144, the control prediction unit 145, the prediction control notification unit 146, the device operation unit 147, and the output unit 150 are connected to the air conditioning related equipment 200. It can be said that it functions as a control unit for controlling.

  Next, calculation of the deviation degree by the deviation degree calculation unit 142 of the present embodiment will be described. The deviation degree calculation unit 142 of the present embodiment calculates an actual value of the deviation degree based on the actual measured values of the temperature and humidity of the outdoor environment and a predicted value of the deviation degree based on the predicted values of the temperature and humidity.

  In the following description, the degree of deviation calculated based on the actual measured values of temperature and humidity is referred to as the actual value deviation degree, and the degree of deviation calculated based on the predicted temperature and humidity values is referred to as the predicted value deviation degree.

  Below, formula (1) for calculating the actual value deviation degree and formula (2) for calculating the forecast value deviation degree are shown.

  Expression (1) indicates how much the measured value of the weather information (temperature, humidity) at time t deviates from the comfort condition. The deviation degree calculation unit 142 according to the present embodiment calculates an actual value deviation degree for temperature and an actual value deviation degree for humidity.

  Expression (2) indicates how much the forecast value of the weather information (temperature, humidity) at the future time t deviates from the comfortable condition. The deviation degree calculation unit 142 according to the present embodiment calculates the degree of prediction value deviation for temperature and the degree of prediction value deviation for humidity.

  In the present embodiment, when the measured value deviation degree differs between temperature and humidity, the value having the larger absolute value is set as the measured value deviation degree at time t. The same applies to the predicted value deviation degree (t).

  In the present embodiment, when the absolute value of the measured value deviation degree (t) is 0, the weather information indicates that the comfortable condition is satisfied, and when the absolute value is less than 1, it indicates that the allowable condition is satisfied. When the absolute value is larger than 1, it indicates that the allowable condition is not satisfied, that is, the limit environment.

  In Expressions (1) and (2), C_upper is the upper limit temperature or upper limit humidity of the comfort condition, and C_lower is the lower limit temperature or lower limit humidity of the comfort condition. In the expressions (1) and (2), ValR (t) is an actual measured value of the outdoor environment temperature or humidity at time t, and ValF (t) is the outdoor environment temperature at time t. Or it is the predicted value of humidity.

  Next, the determination of the tendency of the deviation degree change by the control prediction unit 145 of the present embodiment will be described.

  The control predicting unit 145 of the present embodiment uses the following equation (3) to calculate the tendency of the deviation degree from the actual value deviation degree and the forecast value deviation degree at time t calculated by the deviation degree calculation unit 142. Determine. Note that Equation (3) applies to both temperature and humidity. Moreover, in Formula (3), N is a continuation limit time.

  Next, the operation of the environment management apparatus 100 of this embodiment will be described. First, the control of the air conditioning related equipment 200 by the environment management apparatus 100 will be described with reference to FIGS.

  FIG. 7 is a first flowchart illustrating the operation of the environment management apparatus according to the first embodiment. FIG. 7 shows a flow of control of the air conditioning related equipment 200 by the environment management processing unit 140 in the environment management apparatus 100. Note that the environment management apparatus 100 according to the present embodiment may execute the processing illustrated in FIG. 7 periodically or according to an instruction of a user of the environment management apparatus 100 or the like.

  The environment management processing unit 140 according to the present embodiment acquires state information using the state acquisition unit 141 and stores the state information in the state database 110 together with the time when the state information is acquired (step S701).

  More specifically, the state acquisition unit 141 uses the facility state acquisition unit 151 to acquire facility state information indicating the operating state of the air conditioner 210 that is the air conditioning related facility 200, the opening / closing state of the window 220, and the like from the sensor group 300. In addition, the state acquisition unit 141 acquires outdoor weather information (measured values of temperature and humidity) by the weather information acquisition unit 152. Then, the state acquisition unit 141 stores the equipment state information and the weather information in the state database 110 in association with the date and time.

  Subsequently, the environment management processing unit 140 refers to the setting value database 120 by using the deviation degree calculation unit 142 and acquires a comfort condition associated with the space (room) to be controlled (step S702).

  In the present embodiment, when the process by the environment management processing unit 140 is executed, the air conditioning related equipment 200 to be controlled may be specified, or the space to be managed may be specified. In the processing of FIG. 7, it is assumed that the room A is designated as the management target.

  Subsequently, the environment management processing unit 140 calculates an actual measured value deviation degree based on the comfort condition acquired in step S702 and the weather information acquired in step S701 by the deviation degree calculation unit 142 (step S703). Here, if the time associated with the weather information acquired in step S701 is t, the calculated actual value deviation degree is the actual value deviation degree (t) at time t.

  Further, the actually measured value deviation degree (t) calculated here is the actually measured value deviation degree of the larger one of the actual temperature value deviation degree and the humidity actual value deviation degree.

  Subsequently, the environment management processing unit 140 determines whether the absolute value of the measured value deviation degree (t) is 0, greater than 1, or less than 1 by using the deviation degree calculation unit 142 (step) S704).

  In step S704, when the absolute value of the actually measured value deviation degree (t) is 0, the outdoor weather information satisfies the comfort condition. Therefore, in this case, the environment management processing unit 140 causes the first control notification unit 143 to send the first control notification to the device operation unit 147 for controlling the air conditioner 210 corresponding to the room A to be managed and opening the window. Notification is made (step S705), and the process proceeds to step S709 described later.

  That is, the environment management processing unit 140 controls the air conditioning related equipment 200 so that the temperature and humidity in the room A are close to the temperature and humidity of the outside air. In other words, the environment management processing unit 140 controls the air conditioning related equipment 200 so that outside air is taken into the room A.

  In step S704, when the absolute value of the measured value deviation degree (t) is larger than 1, it indicates that the outdoor weather information does not satisfy the allowable condition and is in the limit environment. Therefore, the environment management processing unit 140 notifies the device operation unit 147 of the second control notification for starting the operation of the air conditioner 210 corresponding to the room A to be managed and closing the window by the second control notification unit 144. (Step S706), the process proceeds to Step S709 described later.

  That is, the environment management processing unit 140 controls the air conditioning related equipment 200 so that the temperature and humidity in the room A are brought close to the comfortable environment.

  In step S704, when the absolute value of the actually measured value deviation degree (t) is 1 or less, the outdoor weather information indicates that the permissible environment is satisfied and the permissible environment is present. Therefore. The environment management processing unit 140 uses the control prediction unit 145 to determine a tendency of a change in the degree of deviation of the outdoor environment with respect to the comfort condition, and predicts a control method based on the determination result (step S707).

  Subsequently, the environment management processing unit 140 notifies the device operation unit 147 of the control method predicted in step S707 by the prediction control notification unit 146 according to the change tendency determination result (step S708).

  Subsequent to steps S705, 706, and 708, the environment management processing unit 140 uses the device operation unit 147 to determine the content of the operation of the air conditioning related equipment 200 based on the notification and to control the air conditioning related equipment 200 (step S709). ), The process is terminated.

  Next, each process of step S707-step S709 is demonstrated. FIG. 8 is a second flowchart for explaining the operation of the environment management apparatus according to the first embodiment. FIG. 8 shows details of the process of the control prediction unit 145 in step S707.

  The control prediction unit 145 of the present embodiment refers to the setting value database 120 by the weather information acquisition unit 152, acquires the continuation limit time associated with the room to be managed, and the time after the continuation limit time (T + N) The (forecast value) of weather information is acquired (step S801). Subsequently, the control prediction unit 145 uses the departure degree calculation unit 142 to calculate the prediction value departure degree (t + N) using the prediction value acquired in Step S801 (Step S802). Subsequently, the control prediction unit 145 compares the absolute value of the actually measured value deviation degree (t) with the absolute value of the forecast value deviation degree (t + N) (step S803).

  In step S803, when the absolute value of the actually measured value deviation degree (t) is larger than the absolute value of the forecast value deviation degree (t + N), the control prediction unit 145 stops the air conditioner 210 and opens the window 220. The control method is predicted, this method is retained (step S804), and the process proceeds to step S806 described later.

  In this embodiment, when the absolute value of the actually measured value deviation degree (t) is larger than the absolute value of the forecast value deviation degree (t + N), the change in the deviation degree tends to be small. This indicates that the outdoor environment is approaching comfortable conditions. In other words, in this case, the tendency of the deviation degree to change indicates that the outdoor environment tends to be improved.

  Therefore, in this case, the control predicting unit 145 predicts a control method in which the air conditioner 210 is stopped and the window 220 is opened so that outside air is taken into the room.

  In step S803, when the absolute value of the actually measured value deviation degree (t) is equal to or larger than the absolute value of the forecast value deviation degree (t + N), the control predicting unit 145 operates to control the air conditioner 210 and close the window 220. This method is predicted, this method is retained (step S805), and the process proceeds to step S806 described later.

  In the present embodiment, when the absolute value of the actually measured value deviation degree (t) is equal to or larger than the absolute value of the forecast value deviation degree (t + N), the deviation degree tends to increase. In this case, the outdoor environment deviates from the comfort conditions. In other words, in this case, the tendency of the deviation degree to change indicates that the outdoor environment tends to deteriorate.

  Therefore, in this case, the control predicting unit 145 predicts a control method of operating the air conditioner 210 and closing the window 220 so as to control the temperature and humidity in the room without taking outside air into the room.

  Subsequently, the control predicting unit 145 sets the control method predicted in step S804 or step S805 and the determined change tendency as the predicted environment management method and the change tendency of the deviation degree (step S806), and performs the processing. finish.

  FIG. 9 is a third flowchart for explaining the operation of the environment management apparatus according to the first embodiment. FIG. 9 shows details of the process of the prediction control notification unit 146 in step S708.

  The prediction control notification unit 146 of this embodiment acquires the prediction environment management method set by the control prediction unit 145 and the change tendency (step S901).

  Subsequently, the prediction control notification unit 146 determines whether the acquired change tendency is a tendency to deteriorate or a tendency to improve / no change (step S902).

  In step S902, when the change tendency tends to deteriorate, the prediction control notification unit 146 notifies the device operation unit 147 of the prediction environment management method predicted by the control prediction unit 145 as a prediction control notification (step S903). ), The process is terminated.

  In step S902, when the change tendency is a tendency to improve / no change, the predictive control notification unit 146 refers to the equipment state information included in the state information acquired in step S701, and determines the air conditioning related equipment 200 to be controlled. The current state is acquired (step S904).

  Subsequently, the prediction control notification unit 146 notifies the device operation unit 147 of the control method for maintaining the current state of the air conditioning-related equipment 200 as the prediction control notification (step S905), and ends the process.

  FIG. 10 is a fourth flowchart for explaining the operation of the environment management apparatus according to the first embodiment. FIG. 10 shows details of the process of the device operation unit 147 in step S709.

  Upon receiving a notification from any of the notification units, the device operation unit 147 of the present embodiment updates the state database 110 to the latest state (step S1001).

  Subsequently, the device operation unit 147 determines whether or not a first control notification has been received (step S1002). If the first control notification is received, the device operation unit 147 acquires the first control notification (step S1003) and will be described later. The process proceeds to step S1007.

  If the first control notification is not received in step S1002, the device operation unit 147 determines whether or not the second control notification is received (step S1004). If the second control notification is received, the second control notification is received. Is acquired (step S1005), and the process proceeds to step S1007 described later.

  If the second control notification is not received in step S1004, the device operation unit 147 acquires the prediction control notification (step S1006), and proceeds to step S1007 described later.

  When the device operation unit 147 acquires any one of the first control notification, the second control notification, and the prediction control notification, the device operation unit 147 refers to the state database 110 and the state of the air conditioning related equipment 200 to be controlled is the acquired control notification. Operation content information indicating the operation content to be in the state indicated by is created (step S1007). Subsequently, the device operation unit 147 causes the output unit 150 to output the operation content information (step S1008), and ends the process.

  As described above, in the environment management apparatus 100 according to the present embodiment, even when the outdoor environment deviates from the comfort conditions, the deviation is small and the deviation tends to be small. Control of the facility 200 is not performed. In the present embodiment, when this determination is made, if the air conditioner 210 is stopped, the state where the air conditioner 210 is stopped is continued, so that the number of times of operation / stop of the air conditioner can be suppressed. Therefore, according to the present embodiment, it is possible to reduce the amount of power used in the management of the indoor environment.

  Next, with reference to FIG. 11, the change of the comfort condition according to the operation history of the remote control group 400 in the environment management apparatus 100 of the present embodiment will be described.

  FIG. 11 is a flowchart for explaining comfort condition change processing in the environment management apparatus according to the first embodiment. The processing shown in FIG. 11 is performed independently of the processing described with reference to FIGS. FIG. 11 shows a case where the comfort condition is changed using operation history information when an operation is performed on the air conditioner remote controller 410 in the remote controller group 400.

  The environment management processing unit 140 according to the present embodiment creates operation history information corresponding to the type of the operated button by the operation history acquisition unit 148 every time the remote controller 410 is operated, and stores the operation history information in the operation history database 130. (Step S1101).

  Subsequently, when the operation history information for N times is stored in the operation history database 130, the environment management processing unit 140 acquires the latest state information associated with the air conditioner 210 from the state database 110 by the setting reflection unit 149. To do. The setting reflection unit 149 acquires the outdoor temperature and humidity detected by the air conditioning-related equipment 200, and sets the temperature and humidity in the record added in step S1101 (step S1102).

  Subsequently, the environment control processing unit 140 determines whether there is a button in which operation history information for N times is stored (step S1103). Here, the operation history information for N times is the operation history information for N times for each type of operated button. Specifically, for example, N operation history information indicating an operation on the “cooling button”, N operation history information indicating an operation on the “heating button”, and an N operation history indicating an operation on the “dehumidification button”. Indicates information.

  In step S1103, when there is no button storing the operation history information for N times, the environment control processing unit 140 returns to step S1101.

  In step S1103, when the corresponding button exists, the environment management processing unit 140 refers to the setting value database 120 by the setting reflection unit 149 when the operated button type is the cooling button (step S1104), The operation history information when the cooling button is pressed is acquired from the operation history database 130, and the difference (i) between the temperature of the outdoor environment of the acquired operation history information and the upper limit temperature of the comfort condition is calculated and retained ( Step S1105). Here, the setting reflection unit 149 sets i = 1, 2,..., N, and calculates the difference for N times.

  Subsequently, the setting reflection unit 149 calculates an average value Av of N differences (i) (step S1106).

  Subsequently, the setting reflection unit 149 calculates a new comfort condition, changes the corresponding comfort condition in the setting value database 120 (step S1107), and ends the process.

  Specifically, the setting reflection unit 149 sets the temperature obtained by adding the average value Av to the upper limit temperature of the comfort condition as the new upper limit temperature of the comfort condition. If the temperature obtained by adding the average value Av to the upper limit temperature of the comfort condition exceeds the upper limit temperature of the limit condition, the setting reflection unit 149 sets the upper limit temperature of the limit condition as the new upper limit temperature of the comfort condition. To do.

  If the operated button type is the heating button in step S1104, the setting reflection unit 149 refers to the setting value database 120 and acquires operation history information when the heating button is pressed from the operation history database 130. Then, a difference (i) between the temperature of the outdoor environment in the acquired operation history information and the lower limit temperature of the comfort condition is calculated (step S1108). Here, the setting reflection unit 149 sets i = 1, 2,..., N, and calculates the difference for N times.

  Subsequently, the setting reflection unit 149 calculates and holds the average value Av of N differences (i) (step S1109).

  Subsequently, the setting reflection unit 149 calculates a new comfort condition, changes the corresponding comfort condition in the setting value database 120 (step S1110), and ends the process.

  In particular. The setting reflection unit 149 sets the temperature obtained by adding the average value Av to the lower limit temperature of the comfort condition as the new lower limit temperature of the comfort condition. If the temperature obtained by adding the average value Av to the upper limit temperature of the comfort condition exceeds the lower limit temperature of the limit condition, the setting reflection unit 149 sets the lower limit temperature of the limit condition as the new lower limit temperature of the comfort condition. To do.

  If the operated button type is the dehumidifying button in step S1104, the setting reflection unit 149 refers to the setting value database 120 and acquires operation history information when the dehumidifying button is pressed from the operation history database 130. Then, the difference (i) between the temperature of the outdoor environment of the acquired operation history information and the upper limit humidity of the comfort condition is calculated (step S1111). Here, the setting reflection unit 149 sets i = 1, 2,..., N, and calculates the difference for N times.

  Subsequently, the setting reflection unit 149 calculates and holds an average value Av of N differences (i) (step S1112).

  Subsequently, the setting reflection unit 149 calculates a new comfort condition, changes the corresponding comfort condition in the setting value database 120 (step S1113), and ends the process.

  In particular. The setting reflection unit 149 sets the humidity obtained by adding the average value Av to the upper limit humidity of the comfort condition as the upper limit humidity of the new comfort condition. If the humidity obtained by adding the average value Av to the upper limit humidity of the comfort condition exceeds the upper limit humidity of the limit condition, the setting reflection unit 149 sets the upper limit humidity of the limit condition as the upper limit humidity of the new comfort condition. To do.

  As described above, in the present embodiment, the comfort condition can be changed based on the operation history information for the remote control group 400. Therefore, according to the present embodiment, the comfort conditions can be updated according to individual cases for each room to be managed, for each user of the environment management apparatus 100, and the like. Therefore, according to this embodiment, the frequency | count of control of the air conditioning related equipment 200 can be reduced compared with the case where the air conditioning related equipment 200 is controlled according to the fixed comfort conditions.

  For this reason, according to the present embodiment, it is possible to reduce the amount of power used in the management of the indoor environment.

  Below, control of the air-conditioning related equipment 200 by the environment management apparatus 100 of the present embodiment will be described more specifically.

  FIG. 12 is a first diagram illustrating the operation of the environment management apparatus according to the first embodiment. FIG. 12 illustrates an example in which the control predicted by the control prediction unit 145 is selected by the prediction control notification unit 146.

  In the example of FIG. 12, the comfort conditions are a temperature of 17 ° C. to 28 ° C., a humidity of 40% to 70%, an upper temperature limit tolerance of + 3 ° C., and a lower temperature tolerance of −3 ° C. It is assumed that the upper limit side tolerance is + 10% and the lower limit side tolerance is -10%.

  In the example of FIG. 12, the state of the air conditioner 210 indicated by the equipment state information at time t is “stopped”, the state of the window 220 is “open”, and the temperature and humidity indicated by the weather information are 30 ° C. and 65%, The predicted value of temperature and humidity after one hour, which is the continuation limit time, is 31 ° C. and 63%.

  In this case, the environment management apparatus 100 causes the output device 12 to display an operation content (message) 121 “Let's turn on the air conditioner and close the window”. Then, the environment management apparatus 100 issues an operation instruction to the remote controller 410 and the remote controller 420 according to the operation content information indicating the operation content 121, and performs the corresponding operation to the air conditioner 210 and the window 220.

  Hereinafter, with reference to FIG. 13, the procedure of the operation performed by the environment management apparatus 100 in the state shown in FIG. 12 will be described. FIG. 13 is a first diagram illustrating an operation procedure of the environment management apparatus according to the first embodiment.

  The environment management processing unit 140 of the environment management apparatus 100 according to the present embodiment uses the state acquisition unit 141 to indicate that the state of the air conditioner 210 is “stopped”, the state of the window 220 is “open”, and the weather information. Obtains a temperature of 30 ° C. and a humidity of 65% (step S1301).

  Next, the environmental management processing unit 140 calculates the actual value deviation degree (t) for the temperature and humidity by using the deviation degree calculation unit 142 (step S1302). Here, since the actual measured value of the air temperature is higher than the upper limit temperature of the comfort condition, the actual measured value deviation degree (t) is (30−28) /3=0.666. . Moreover, since the measured value of humidity is within the range of comfort conditions, the measured value deviation degree (t) of humidity is zero. Therefore, here, the actually measured value deviation degree (t) is 0.666.

  Next, since the actual value deviation degree (t) is smaller than 1, the environment management processing unit 140 calculates the tendency of change in the deviation degree and holds the predicted control method (step S1303). ).

  The control prediction unit 145 acquires 31 ° C. and 63%, which are predicted values of temperature and humidity after one hour, which is the continuation limit time. Then, the control prediction unit 145 causes the departure degree calculation unit 142 to calculate the prediction value departure degree (t + N).

  Here, since the predicted humidity value is within the range of the comfortable environment, the predicted value deviation (t + N) of the humidity is zero. Moreover, since the predicted temperature value is higher than the upper limit temperature of the comfort condition, the predicted temperature deviation degree (t + N) is (31−28) / 3 = 1.

  Therefore, in this case, | measured value deviation degree (t) | <| forecast value deviation degree (t + N) |, which indicates that the outdoor environment tends to deteriorate.

  Therefore, the control predicting unit 145 holds the change tendency “deterioration” and the predicted control method “operate the air conditioner 210 and close the window 220”.

  Next, the environment management processing unit 140 makes a prediction control notification to the device operation unit 147 by the prediction control notification unit 146 according to the change tendency held by the control prediction unit 145 (step S1304).

  Here, the change tendency held in the control prediction unit 145 is “deterioration”. Therefore, the prediction control notification unit 146 passes the notification indicating the control method held in the control prediction unit 145 to the device operation unit 147 as the prediction control notification.

  The device operation unit 147 receives the prediction control notification, refers to the state database 110, and creates operation content information indicating the operation content for the air conditioning related equipment 200 so that the state indicated by the prediction control notification is obtained (step S1305). .

  Here, the content indicated by the prediction control notification is “operate the air conditioner 210 and close the window 220”. On the other hand, in the current facility state information, the state of the air conditioner 210 is “stopped” and the state of the window 220 is “open”.

  Therefore, the device operation unit 147 compares the content indicated by the prediction control notification with the content indicated by the equipment state information, and creates operation content information “drive the air conditioner 210 and close the window 220”.

  By such processing, the operation content 121 is displayed on the output device 12 in FIG.

  Next, with reference to FIG. 14, another example of the control of the air conditioning related equipment 200 by the environment management apparatus 100 of the present embodiment will be described.

  FIG. 14 is a second diagram illustrating the operation of the environment management apparatus according to the first embodiment. FIG. 14 illustrates an example in which the control predicted by the control predicting unit 145 is not selected by the predictive control notification unit 146 and control for maintaining the current state is selected.

  In FIG. 14, the comfort condition temperature of temperature and humidity, the upper limit side allowable difference, and the lower limit side allowable difference are the same as in the example of FIG. In FIG. 14, the state of the air conditioner 210 indicated by the equipment state information at time t, the state of the window 220, the temperature and humidity indicated by the weather information, and the duration limit time are also the same as in the example of FIG.

  Further, in FIG. 14, it is assumed that the predicted value of temperature and humidity after one hour, which is the continuation limit time, is 29 ° C. and 68%.

  In this case, the environment management apparatus 100 causes the output device 12 to display an operation content (message) 122 “Let's keep this state (let the air conditioner stop and leave the window open)”. .

  Hereinafter, with reference to FIG. 15, a procedure of operations performed by the environment management apparatus 100 in the state illustrated in FIG. 14 will be described. FIG. 15 is a second diagram illustrating the operation procedure of the environment management apparatus according to the first embodiment.

  The processing in steps S1501 and S1502 in FIG. 15 is the same as the processing in steps S1301 and S1302 in FIG.

  In step S1502, the actual value deviation degree (t) is 0.666, which is smaller than 1, so the control prediction unit 145 calculates the tendency of the deviation degree change and holds the predicted control method ( Step S1503).

  At this time, the control prediction unit 145 acquires 29 ° C. and 65%, which are predicted values of temperature and humidity after one hour, which is the continuation limit time. Then, the control prediction unit 145 causes the departure degree calculation unit 142 to calculate the prediction value departure degree (t + N).

  Here, since the predicted humidity value is within the range of the comfortable environment, the predicted value deviation (t + N) of the humidity is zero. Further, since the predicted temperature value is higher than the upper limit temperature of the comfort condition, the predicted temperature deviation degree (t + N) is (29−28) /3=0.333.

  Therefore, in this case, | measured value deviation degree (t) |> | forecast value deviation degree (t + N) |, which indicates that the outdoor environment tends to improve.

  Therefore, the control predicting unit 145 holds the change tendency “improvement” and the predicted control method “stop the air conditioner 210 and open the window 220”.

  The prediction control notification unit 146 selects control for maintaining the state of the air conditioning related equipment 200 in the current state from the change tendency “improvement” held by the control prediction unit 145 (step S1504).

  Here, the predictive control notification unit 146 acquires the latest equipment state information from the state database 110 and creates a predictive control notice indicating a control method for maintaining the equipment state information. Here, the latest equipment state information is “the state of the air conditioner 210 is“ stop ”and the state of the window 220 is“ open ””. Therefore, the prediction control notification unit 146 performs the prediction control notification with the content “stop the air conditioner” and “open the window”.

  The device operation unit 147 receives the notification that “the air conditioner is stopped and the window is opened”, and as a result of comparison with the equipment state information, it matches, so “the current state is maintained (the air conditioner is stopped, the window is opened) The operation content information of the operation content "status)" is generated (step S1505).

  Thus, in the present embodiment, even when the outdoor environment deviates from the comfort condition, the degree of departure is smaller than a predetermined value, and the tendency of change in the degree of deviation approaches the comfort condition. If it is, control of the air conditioning related equipment 200 is not performed.

  Therefore, according to this embodiment, since the frequency | count of control of the air conditioning related equipment 200 can be suppressed, the electric power consumption in management of an indoor environment can be reduced.

  Next, with reference to FIG. 16 and FIG. 17, the change of the comfort condition in the environment management apparatus 100 of this embodiment is demonstrated concretely.

  FIG. 16 is a diagram for explaining a change in comfort conditions by the environment management apparatus according to the first embodiment. In FIG. 16, the comfort conditions are a temperature of 17 ° C. to 28 ° C., a humidity of 40% to 70%, a temperature upper limit tolerance of + 3 ° C., a lower limit tolerance of −3 ° C., and a humidity upper limit of It is assumed that the allowable difference is + 10% and the lower limit side allowable difference is −10%. In the example of FIG. 16, the limiting conditions are a temperature of 10 ° C. to 32 ° C. and a humidity of 20% to 90%.

  In the example of FIG. 16, when N = 3 and the operation history information obtained by performing “cooling” operation on the air conditioner 210 is accumulated three times, the comfort condition is changed to 17 ° C. to 31.3 ° C. Yes. In FIG. 16, the indoor temperature detected by the air conditioner 210 in the first operation is 30 ° C., and the indoor temperature detected by the air conditioner 210 in the second operation is 31 ° C. In this operation, the indoor temperature detected by the air conditioner 210 is assumed to be 32 ° C.

  FIG. 17 is a diagram illustrating a change in comfort conditions by the environment management apparatus according to the first embodiment.

  When the “cooling” button is operated on the remote controller 410, the environment management processing unit 140 according to the present embodiment performs an operation in which the operation history acquisition unit 148 associates the operation type with the time when the operation was performed. History information is generated and stored in the operation history database 130 (step S1701). The operation history information acquired at this time is the first operation history information. At this time, since the room temperature detected by the air conditioner 210 is 30 ° C., the room temperature 30 ° C. is set in the operation history information.

  Next, when a “cooling” operation is performed on the air conditioner 210, the operation history acquisition unit 148 generates second operation history information (step S1702). At this time, since the room temperature detected by the air conditioner 210 is 31 ° C., the room temperature 31 ° C. is set in the operation history information.

  Next, when the “cooling” operation is performed on the air conditioner 210, the operation history acquisition unit 148 generates operation history information for the third time (step S1703). At this time, since the room temperature detected by the air conditioner 210 is 31 ° C., the room temperature 33 ° C. is set in the operation history information.

  Next, the setting reflection unit 149 calculates the difference between the room temperature included in the operation history information for three times and the upper limit value of the comfort condition (step S1704).

  In this case, since the upper limit temperature of the comfort condition is 28 ° C., the difference when the first operation history information is acquired is 30−28 = 2. The difference when the second operation history information is acquired is 31−28 = 3. The difference when the third operation history information is acquired is 33-28 = 5.

  Subsequently, the setting reflection unit 149 calculates an average value Av of three differences (step S1705). Here, the average value Av = (2 + 3 + 5) /3=3.3.

  Subsequently, the setting reflection unit 149 adds the average value Av to the upper limit temperature of the comfort condition, and if the result is lower than the upper limit temperature of the limit temperature, this temperature is set as a new upper limit temperature of the comfort condition (step S1706). .

  The temperature obtained by adding the average value Av to the upper limit temperature 28 ° C. of the comfortable condition is 31.3 ° C. This temperature is lower than the upper limit temperature 32 ° C. of the limit condition. Therefore, the setting reflection unit 149 sets 31.3 ° C. as the upper limit temperature of the new comfort condition. Therefore, the comfort condition is changed to 17 ° C to 31.3 ° C.

  As described above, according to the present embodiment, the comfort condition can be changed according to the operation history information. Therefore, it is more preferable to control the interior of the room than to control the air conditioning related equipment 200 according to the comfort condition that has been set. The environment can be made more comfortable.

(Second embodiment)
The second embodiment will be described below with reference to the drawings. The second embodiment is different from the first embodiment only in that weather information (actually measured values) is acquired not from the weather information service 500 but from, for example, a temperature / humidity sensor installed in a house, a data center, or the like. Therefore, in the following description of the second embodiment, only differences from the first embodiment will be described, and those having the same functional configuration as the first embodiment will be described for the first embodiment. The same reference numerals as those used in FIG.

  FIG. 18 is a diagram illustrating an environment management apparatus according to the second embodiment. In the present embodiment, the temperature / humidity sensor 330 is included in the sensor group 300A.

  The temperature / humidity sensor 330 may be provided indoors or outdoors, for example, but the temperature and humidity detected here are actually measured values of outdoor temperature and humidity.

  The environment management processing unit 140A of the environment management apparatus 100A of the present embodiment acquires the weather information, which is the temperature and humidity of the outdoor environment, from the temperature / humidity sensor 330 instead of the weather information service 500.

  Therefore, in this embodiment, when the process by the control prediction unit 145 using the predicted temperature and humidity of the outdoor environment is not performed, the air conditioning related equipment 200 is controlled without communicating with the weather information service 500. can do.

  The case where the process by the control prediction unit 145 using the forecast value is not performed is a case where the outdoor environment satisfies the comfort condition or the outdoor environment deviates greatly from the comfort condition.

  Therefore, according to this embodiment, the communication load for acquiring weather information can be reduced.

  In each embodiment described above, the environment management apparatus is described as managing the indoor environment, but the present invention is not limited to this. The environmental management apparatus of each embodiment is, for example, a part of the environment management facility 200, such as an athletic field or an event hall, and the air conditioning related equipment 200 is provided. Can be applied to management.

In the disclosed technology, forms such as the following supplementary notes are conceivable.
(Appendix 1)
A state acquisition unit for acquiring measured values of the temperature and humidity of the outside air and the predicted values of the temperature and humidity after a predetermined time;
Refers to a storage unit that stores a condition that defines a predetermined environment, and indicates a first deviation degree indicating a degree of deviation of the actual measurement value from the condition and a degree of deviation of the forecast value from the condition. A deviation degree calculation unit for calculating a second deviation degree;
An environment management apparatus comprising: a control unit that controls air-conditioning-related equipment according to a tendency of a change in the degree of departure determined from the first degree of departure and the second degree of departure.
(Appendix 2)
The controller is
When the tendency of the change is a tendency for the temperature and humidity to approach the range indicated by the condition, control to maintain the state of the air conditioning-related equipment,
The environment management apparatus according to appendix 1, wherein when the tendency of the change is a tendency that the temperature and humidity are away from a range indicated by the condition, the temperature and humidity are controlled to approach the range indicated by the condition.
(Appendix 3)
When the first deviation degree is a predetermined value or less,
The departure degree calculation unit calculates the second departure degree, and the control unit calculates a tendency of the change,
When the first deviation degree is larger than the predetermined value,
The environment management device according to appendix 2, wherein the control unit performs control to bring the temperature and humidity in a room where the air-conditioning-related equipment is installed closer to a range indicated by the condition.
(Appendix 4)
The controller is
When the first deviation degree satisfies the condition,
The environment management device according to any one of appendices 1 to 3, wherein the air conditioning related facility is controlled so that the outside air is taken into a room in which the air conditioning related facility is installed.
(Appendix 5)
The state acquisition unit
Having an equipment state information acquisition unit for acquiring equipment state information indicating the state of the air conditioning-related equipment;
The controller is
Based on the control content for the air conditioning related equipment and the equipment status information, an equipment operation unit that generates operation content information indicating the operation content for the air conditioning related equipment,
The environment management device according to any one of appendices 1 to 4, further comprising: an output unit that outputs the operation content information.
(Appendix 6)
The output unit is
The environment management apparatus according to appendix 5, wherein an operation instruction based on the operation content information is output to a controller that operates the air conditioning related equipment, and the controller operates the air conditioning related equipment.
(Appendix 7)
The output unit is
The environmental management apparatus according to appendix 5 or 6, wherein an operation instruction based on the operation content information is displayed on a display unit.
(Appendix 8)
An operation history acquisition unit that acquires operation history information indicating a history of operations on the controller;
Appendices 1 to 6 including a reflection unit that updates the condition to a condition reflecting the operation history based on the operation history information and the temperature and humidity of the room in which the air conditioning-related equipment is installed. The environmental management apparatus according to any one of the above.
(Appendix 9)
A process of acquiring measured values of the temperature and humidity of the outside air and a predicted value of the temperature and humidity after a predetermined time;
Refers to a storage unit that stores a condition that defines a predetermined environment, and indicates a first deviation degree indicating a degree of deviation of the actual measurement value from the condition and a degree of deviation of the forecast value from the condition. A process of calculating a second deviation degree;
A process for controlling air-conditioning-related equipment according to a tendency of a change in the degree of deviation determined from the first degree of deviation and the second degree of deviation, and an environment management program to be executed by a computer.
(Appendix 10)
A computer-aided environmental management method comprising:
Obtain the measured values of the temperature and humidity of the outside air and the predicted values of the temperature and humidity after a predetermined time,
Refers to a storage unit that stores a condition that defines a predetermined environment, and indicates a first deviation degree indicating a degree of deviation of the actual measurement value from the condition and a degree of deviation of the forecast value from the condition. A second deviation degree is calculated,
An environment management method for controlling air-conditioning-related equipment according to a tendency of a change in the degree of departure determined from the first degree of departure and the second degree of departure.

  The present invention is not limited to the specifically disclosed embodiments, and various modifications and changes can be made without departing from the scope of the claims.

100, 100A Environment management device 110 State database 120 Setting value database 130 Operation history database 140, 140A Environment management processing unit 141 State acquisition unit 142 Deviation degree calculation unit 143 First control notification unit 144 Second control notification unit 145 Control prediction unit 146 Prediction control notification unit 147 Device operation unit 148 Operation history acquisition unit 149 Setting reflection unit 150 Output unit 200 Air conditioning related equipment 300 Sensor group 400 Remote control group 400
500 Weather Information Service

Claims (7)

A state acquisition unit for acquiring measured values of the temperature and humidity of the outside air and the predicted values of the temperature and humidity after a predetermined time;
Refers to a storage unit that stores a condition that defines a predetermined environment, and indicates a first deviation degree indicating a degree of deviation of the actual measurement value from the condition and a degree of deviation of the forecast value from the condition. A deviation degree calculation unit for calculating a second deviation degree;
An environment management apparatus comprising: a control unit that controls air-conditioning-related equipment according to a tendency of a change in the degree of departure determined from the first degree of departure and the second degree of departure. The controller is
When the tendency of the change is a tendency for the temperature and humidity to approach the range indicated by the condition, control to maintain the state of the air conditioning-related equipment,
The environment management apparatus according to claim 1, wherein when the tendency of the change is a tendency that the temperature and humidity are away from a range indicated by the condition, control is performed to bring the temperature and humidity closer to the range indicated by the condition. When the first deviation degree is a predetermined value or less,
The departure degree calculation unit calculates the second departure degree, and the control unit calculates a tendency of the change,
When the first deviation degree is larger than the predetermined value,
The environment management apparatus according to claim 2, wherein the control unit performs control to bring the temperature and humidity in a room where the air-conditioning-related equipment is installed closer to a range indicated by the condition. The controller is
When the first deviation degree satisfies the condition,
The environment management apparatus according to any one of claims 1 to 3, wherein the air conditioning related equipment is controlled so that the outside air is taken into a room in which the air conditioning related equipment is installed. An operation history acquisition unit that acquires operation history information indicating an operation history for a controller that operates the air conditioning-related equipment;
The reflection part which updates the said conditions to the conditions in which the said operation | movement history was reflected based on the said operation history information and the temperature and humidity of the room | chamber interior in which the said air-conditioning related installation was installed. 5. The environmental management device according to any one of 4. A process of acquiring measured values of the temperature and humidity of the outside air and a predicted value of the temperature and humidity after a predetermined time;
Refers to a storage unit that stores a condition that defines a predetermined environment, and indicates a first deviation degree indicating a degree of deviation of the actual measurement value from the condition and a degree of deviation of the forecast value from the condition. A process of calculating a second deviation degree;
A process for controlling air-conditioning-related equipment according to a tendency of a change in the degree of deviation determined from the first degree of deviation and the second degree of deviation, and an environment management program to be executed by a computer. A computer-aided environmental management method comprising:
Obtain the measured values of the temperature and humidity of the outside air and the predicted values of the temperature and humidity after a predetermined time,
Refers to a storage unit that stores a condition that defines a predetermined environment, and indicates a first deviation degree indicating a degree of deviation of the actual measurement value from the condition and a degree of deviation of the forecast value from the condition. A second deviation degree is calculated,
An environment management method for controlling air-conditioning-related equipment according to a tendency of a change in the degree of departure determined from the first degree of departure and the second degree of departure.

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