JP2007298229A - Air conditioning control device, control program, demand control device, control program, and air conditioning control system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an air conditioning control system, and an air conditioning control device and a demand control device composing the system capable of realizing energy saving measures while maintaining a comfort level of a room on the basis of indoor and outdoor conditions of the room provided with an indoor unit, and electric energy consumption of the indoor unit. <P>SOLUTION: A means is provided for specifying a control information table corresponding to an alarm type responding to electric energy consumption of the indoor unit. A means is provided for specifying a control coefficient table corresponding to a clothing amount and indoor labor strength responding to outdoor conditions, and reading a control coefficient corresponding to indoor temperature and humidity from the control coefficient table, and a means is provided for reading control information for controlling operation of the indoor unit corresponding to the control coefficient read from the control coefficient table from the specified control information table. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to air conditioning control of an air conditioner or the like installed indoors, and in particular, enables energy saving measures while maintaining indoor comfort.

To maintain a comfortable indoor air-conditioning environment, for example, when the indoor temperature rises and you feel hot, lower the set temperature of the indoor unit. On the other hand, when the indoor temperature decreases and you feel cold, set the indoor unit. It is necessary to control the air conditioning according to the indoor temperature and humidity, such as raising the temperature.
So far, proposals have been made regarding air conditioning control that realizes a comfortable air conditioning environment (see, for example, Patent Document 1).

However, no proposal has been made regarding air-conditioning control that enables energy-saving measures while maintaining indoor comfort. That is, in order to maintain the indoor comfort level, for example, it is necessary to control the operation of the indoor unit so that the indoor temperature and humidity become a predetermined target value (change of set temperature, air volume, etc.). Keeping the comfort level in the room while ignoring the power consumption is contrary to the recent demand for energy saving. The indoor comfort level also needs to consider indoor conditions such as time of day and room use, and outdoor conditions such as the weather of the day.
Japanese Patent No. 3049266

  The present invention has been made in view of the conventional situation as described above, and maintains indoor comfort based on the indoor / outdoor conditions in which the indoor unit is installed and the power consumption of the indoor unit. An object of the present invention is to provide an air conditioning control system capable of realizing energy saving measures, and an air conditioning control device and a demand control device constituting the system.

  An air conditioning control system according to the present invention includes a means for specifying a control information table corresponding to an alarm type corresponding to the power consumption of an indoor unit, and a control coefficient corresponding to an amount of clothes according to an outdoor situation and an indoor work intensity. Control information specifying a table and means for reading out a control coefficient corresponding to the indoor temperature and humidity from the specified control coefficient table, and control information specifying control information for controlling the operation of the indoor unit corresponding to the control coefficient read from the control coefficient table Means for reading from the table and transmitting to the indoor unit.

  According to the present invention, based on the amount of clothes specified according to the current month and outside temperature, the indoor work intensity specified according to the time zone, the indoor temperature and humidity, the power consumption of the indoor unit, etc. Since the operation of the machine can be controlled, energy saving measures can be taken while maintaining the comfort level in the room.

  Hereinafter, embodiments of an air conditioning control device and a control program, a demand control device and a control program, and an air conditioning control system according to the present invention will be described with reference to the drawings.

  The embodiment described below will be described by taking as an example the case of controlling the operation of an indoor unit installed in each of the office room, examination room, and hospital room in a hospital building.

In the present embodiment, a case where electricity is used as a power source for operating the indoor unit will be described as an example. That is, in the following description, power consumption is an example of energy consumption, and demand is power demand.
However, in the present invention, gas or other energy may be used as a power source for the indoor unit.

  The air conditioning control system according to the present invention (hereinafter referred to as “the present system”) determines whether the indoor temperature / humidity is within a comfortable temperature / humidity range, and is comfortable when it is not within the comfortable range. The operation of the indoor unit is controlled so that it becomes temperature and humidity.

Here, for example, ASHRAE (American Heating / Cooling / Air Conditioning Association) Standard is used as an example of a comfortable temperature in the present system.
The ASHRAE Standard indicates a comfortable temperature range as follows.
In summer, the standard amount of clothing is 0.5 clo, the temperature is 22.8 to 26.1 ° C, the upper limit of absolute humidity is 16.7 ° C (11.8 g / kg in terms of absolute humidity) at the dew point temperature, The lower limit is a dew point temperature of 1.3 ° C. (4.2 g / kg in absolute humidity).
The winter conditions are the same as in summer when the standard clothing amount is 0.9 clo, the temperature is 20.0 to 23.6 ° C., and the humidity.
The amount of clothes is an index representing the heat insulating property of clothes represented by the unit “clo”, and is a thermal resistance value of 0.155 m ² ° C./W from the skin surface to the clothes surface. By the way, the winter three-piece suit is about 1clo.

This system controls the operation of indoor units based on ASHRAE standard SET * (Standard New Effective Temperature) so that the room has a comfortable temperature and humidity. Therefore, in this system, when the room temperature is high, it is possible to cool the air by increasing the air volume without lowering the room temperature by using the effect that it feels cool if the airflow is strong (fast airflow speed) even at the same room temperature. It is configured to maintain comfort. On the other hand, when the room temperature is low, the temperature near the ceiling in the room is high, and the temperature near the floor is low, so that the comfort level is maintained by first blowing air and stirring the air without immediately heating. It is configured.
In addition, in this system, a demand control device, which will be described later, monitors the power consumption of the indoor unit, issues a demand alarm when the predetermined power consumption is exceeded or is likely to exceed, and Air conditioning control is performed by reducing the comfort level according to the level. This achieves energy saving while maintaining the comfort level in the room.

(Configuration of this system)
The configuration of this system will be described below.
FIG. 1 is a schematic diagram showing an example of an outline of the present system.
This system controls the operation of the indoor units installed in each room so that the office room R1, the examination room R2, and the hospital room R3 have a comfortable environment. The air conditioning control device 1 and the outside air temperature sensor 2 , An indoor temperature / humidity sensor 3, an indoor unit 4, a demand control device 5, a power meter 6, a management server 7, and a management terminal 8.

The air conditioning control device 1 is an information processing device that transmits control information to the indoor unit 4. The control information will be described later. The air conditioning control device 1 can communicate with the outside air temperature sensor 2, the temperature / humidity sensor 3 installed in each room, the indoor unit 4, the demand control device 5, and the management server 7 via the communication network. So connected.
In the air conditioning control device 1, the air conditioning control program according to the present invention is operating, and information processing described later is realized by each means in the air conditioning control device 1.

The outside air temperature sensor 2 is a sensor that senses the temperature outside the hospital building.
The outside air temperature sensor 2 may be one or two or more in the system. For example, when the outside air temperature differs depending on the measurement position from the shape of the building or the sunshine state, two or more outside air temperature sensors are provided. The system may obtain the average value.

  The indoor temperature / humidity sensor 3 is a sensor that senses indoor temperature and humidity. In the present embodiment, one room is installed in each room, an indoor temperature / humidity sensor 31 is installed in the office room R1, an indoor temperature / humidity sensor 32 is installed in the examination room R2, and an indoor temperature / humidity sensor 33 is installed in the hospital room R3. Yes.

The indoor unit 4 is a device that adjusts indoor temperature and humidity. In the present embodiment, one is installed in each room, and an indoor unit 41 is installed in the office room R1, an indoor unit 42 is installed in the examination room R2, and an indoor unit 43 is installed in the hospital room R3.
The correspondence between the indoor temperature / humidity sensor 3 and the indoor unit 4 may be one-to-one or may be one-to-one. Therefore, in the case of a large room, the indoor temperature / humidity sensor 3 may be installed in the vicinity of the center, and may be provided corresponding to the plurality of indoor units 4 installed in the vicinity. In the present embodiment, the indoor unit 41 corresponds to the indoor temperature / humidity sensor 31, the indoor unit 42 corresponds to the indoor temperature / humidity sensor 32, and the indoor unit 43 corresponds to the indoor temperature / humidity sensor 33, respectively. ing.

The demand control device 5 monitors the power consumption of the indoor unit 4 (41, 42, 43), and transmits an alarm type to the air conditioning control device 1 when a predetermined power amount is exceeded or is likely to be exceeded. Information processing apparatus. The alarm type will be described later.
In the demand control device 5, the demand control program according to the present invention is running, and information processing described later is realized by each means in the demand control device 5.

The wattmeter 6 is a device that measures the power consumption of the indoor units 4 (41, 42, 43), and is installed in a power distribution board in a hospital building.
The wattmeter 6 is connected to be able to communicate with the demand control device 5 via a communication network.

  The management server 7 includes information indicating the indoor temperature and humidity, the operation history of the air conditioning control device 1 and the demand control device 5, and the operation status of the indoor unit, for example, control information transmitted from the air conditioning control device 1 to the indoor unit 4, This is an information processing device that collects and stores alarm types and the like transmitted from the demand control device 5 to the air conditioning control device 1 from the air conditioning control device 1 and the like, and transmits them to the management terminal 8.

The management server 7 and the management terminal 8 can access the management server 7 from the management terminal 8 and browse the information stored in the management server 7 by an administrator or an operator of this system. It is configured. That is, for example, the management server 7 operates as a Web server, and an administrator or the like browses using the browser of the management terminal 8.
In addition, the management server 7 and the management terminal 8 input information in various tables stored in the air-conditioning control device 1 and the demand control device 5 described later by the administrator of the system from the management terminal 8, and the management server 8 7 can be set (transmitted) to the air-conditioning control device 1 or the like.
The management server 7 and the management terminal 8 can be realized by a personal computer or the like.

This system having the above-described configuration is installed indoors based on the outside air temperature detected by the outside air temperature sensor 2 and the indoor temperature and humidity detected by the indoor temperature / humidity sensor 3 installed in each room. The operation of the indoor unit 4 is controlled.
Further, the present system is configured so that each of the indoor units 41, 42, and 43 can realize energy saving based on a demand alarm (alarm type) issued by the demand control device 5 that monitors the power consumption of the indoor unit. To control the operation.

(Network configuration of this system)
FIG. 2 is a network configuration diagram showing an example of a connection form of a group of devices constituting this system. The air conditioning control device 1, the outside air temperature sensor 2, the indoor temperature / humidity sensor 3n (31, 32, 33), the indoor unit 4n (41, 42, 43), the demand control device 5, the wattmeter 6, and the management server 7 are the first Are connected via the communication network NW1. The management server 7 and the management terminal 8 are connected via the second communication network NW2.

Here, as an example of the communication network NW1, there is LONWORKS (registered trademark) of Echelon. That is, each device connected to the communication network NW1 is embedded with an LSI called “neuron chip” having both communication and control functions, and each device is specified by identification information called “neuron ID”. It communicates with a communication protocol called Lontalk that complies with TCP / IP.
On the other hand, an example of the communication network NW2 is a computer communication network such as the Internet.

(Information used in this system)
Next, the relationship of information used in this system will be described with reference to FIG. The contents of each information will be described later.

First, the amount of clothing is determined from the current month and outside temperature. The work intensity for each room is determined from the current time (time zone). The work intensity is an index indicating the work intensity, and is represented by the unit “met”. The work intensity is not affected by gender, age, physique, and the like because the work energy consumption is expressed by the energy metabolism rate. As an example of work intensity, for example, it is 0.65met for rest and 1.0-1.2met for light work in chair position.
Next, for each room, that is, for each indoor unit, a control coefficient table corresponding to the combination of the clothing amount and the work intensity is selected from a plurality of control coefficient tables.
Next, for each indoor unit, a control coefficient corresponding to the indoor temperature and humidity is read from the selected control coefficient table.
On the other hand, a control information table corresponding to the alarm type is selected from a plurality of control information tables.
Next, for each indoor unit, control information corresponding to the control coefficient read from the control coefficient table is read from the selected control information table.
The read control information for each indoor unit is transmitted to the indoor units in each room.

(Configuration of air conditioning control device 1)
Next, the air conditioning control device 1 will be described.
FIG. 4 is a block diagram showing an embodiment of the air conditioning control device 1.
The air conditioning control device 1 includes a time data acquisition unit 101, an outside air temperature data acquisition unit 102, a month data acquisition unit 103, a clothing amount calculation unit 104, a work intensity calculation unit 105, a control coefficient table selection unit 106, and an indoor temperature and humidity data acquisition unit. 107, a control coefficient acquisition unit 108, an alarm type acquisition unit 109, a control information table selection unit 110, a control information acquisition unit 111, a control information transmission unit 112, a timer 113, a time determination unit 114, and a storage unit.
The storage unit stores a clothing amount table TBL101, work intensity table TBL102, correspondence table TBL103, control coefficient table TBL104, alarm type database DB101, demand control table TBL105, control information table TBL106, and address table TBL107.

  Although not shown, the air conditioning control device 1 includes a CPU (central processing unit) and a program storage unit. The CPU controls and controls each means of the air conditioning control device 1 according to the program stored in the program storage unit, and executes the program processing. The program storage unit includes a ROM (Read Only Memory), a RAM (Random Access Memory), and the like, and stores various programs used by the air conditioning control device 1.

In the air-conditioning control apparatus 1, an air-conditioning control program (hereinafter referred to as "this program") according to the present invention operates to control each means in the air-conditioning control apparatus 1, so that an air-conditioning control method (described below) Hereinafter, it is referred to as “the present method”.
Further, if a computer-readable recording medium (hereinafter referred to as “this recording medium”) in which the program is recorded is used, a computer (not shown) can function in the same manner as the air conditioning control device 1. That is, the method can be realized by a computer (not shown) reading and executing the program from the recording medium.

Hereinafter, each means in the air-conditioning control apparatus 1 will be described.
First, each database stored in the storage unit will be described. In the following description, the database is indicated by the symbols “TBL” and “DB”. The code “TBL” indicates a so-called master table, and information stored by the system is not updated as a result of information processing by the system except for an initial setting by an administrator of the system. On the other hand, the symbol “DB” indicates a database in which stored information is updated as a result of information processing by this system.

(Clothing amount table)
The clothing amount table TBL101 is a database that stores the clothing amount for each outside temperature for each month.
FIG. 5 is a schematic diagram showing an example of information stored in the TBL 101. For example, it is shown that the clothing amount “light” is stored in association with the outside temperature “25 ° C.” and the month “May”. ing.
Although FIG. 5 shows that the outside temperature uses information (temperature) at 8:00 am on the day of determining the amount of clothes, outside temperatures other than “8:00 am” may be used. Absent. FIG. 5 shows that the outside air temperature is set to “every 5 ° C.”, but the present invention is not limited to this, and for example, it is set to “every 1 ° C.”. Also good.

(Work intensity table)
The work intensity table TBL102 is a database that stores the work intensity of each room for each time zone. Here, in this embodiment, since one indoor unit is installed for each room, the TBL 102 associates the indoor unit ID and time zone, which is information for identifying the indoor unit by the system. The work intensity is stored.
FIG. 6 is a schematic diagram illustrating an example of information stored in the TBL 102. For example, the work intensity “strong” is stored in association with the time zone “8: 0 to 20:59” and the indoor unit ID “41”. It has been shown.
In FIG. 6, the time zones are set to “8: 0 to 20:59” and “21: 0 to 7:59”, but the time zones may be set according to the usage of the room. In FIG. 6, the time zone is set in common for each room, but a different time zone may be set for each room.

(Correspondence table)
The correspondence table TBL103 is a database that stores control coefficient table identifiers by work intensity for each clothing amount. The control coefficient table identifier is information used by the air conditioning control device 1 to identify the control coefficient table.
FIG. 7 is a schematic diagram showing an example of information stored in the TBL 103. For example, an identifier “control coefficient table 1” of the control coefficient table is stored in association with the clothing amount “normal” and the work intensity “weak”. It shows that.

(Control coefficient table)
The control coefficient table TBL104 is a database that stores control coefficients for each room temperature for each relative humidity.
FIG. 8 is a schematic diagram illustrating an example of information stored in the TBL 104. For example, the control coefficient “+3” is stored in association with the relative humidity “10%” and the room temperature “18 ° C.”. ing.
In FIG. 8, the room temperature is set to “every 2 ° C.”, but the present invention is not limited to this, and may be set to “every 1 ° C.”, for example. In FIG. 8, the relative humidity is initially set to 10% relative to “every 20%”. However, in the present invention, the relative humidity is not limited to this. For example, “every 10%” or “every 5%”. It may be set.

(Alarm type database)
The alarm type database DB101 is a database that stores the alarm types received from the demand control device 5 by the air conditioning control device 1.
FIG. 9 is a schematic diagram showing an example of information stored in the DB 101, and shows that the alarm type “2” is stored. The alarm type stored in the DB 101 is overwritten and saved (updated) every time the air conditioning control device 1 receives the alarm type from the control device 5.

(Demand control table)
The demand control table TBL105 is a database storing a control information table identifier for each room type for each alarm type. Since the indoor unit is installed for each room as in the above-described TBL 102, in this embodiment, the control information table identifier is stored in the TBL 105 in association with the combination of the alarm type and the indoor unit ID. Yes.
FIG. 10 is a schematic diagram showing an example of information stored in the TBL 105. For example, the control information table identifier “control information table 0” is stored in association with the alarm type “0” and the indoor unit ID “41”. It shows that.

(Control information table)
The control information table TBL106 is a database that stores control information corresponding to control coefficients. The control information is composed of three types of information: “air volume”, “operation mode”, and “deviation temperature”.
FIG. 11 is a schematic diagram showing an example of control information stored in the TBL 106. For example, the control information table of the control information table identifier “control information table 0” has control information associated with the control coefficient “+3”. It shows that “strong (air volume)”, “heating (operation mode)” and “+2 (deviation temperature)” are stored.
In the present embodiment, there are three TBLs 106 in the air conditioning control device 1, but FIG. 11 shows the control information stored in each control information table in association with the control coefficient for convenience of explanation. Shown in one table.

  As shown in FIG. 11, different control information is stored in the three TBLs 106 (control information table identifier = 0, 1, 2) for the same control coefficient (they may be the same). That is, for example, for the control coefficient “+3”, the three control information tables include the air volume “strong” “medium” “weak”, the operation modes “heating” “heating” “heating”, and the deviation temperature “+2” “ “+1” and “+1” are stored.

As will be described later, the present system selects a control information table according to the alarm type determined by the demand control device 5, reads out the control information, and transmits it to the indoor unit. Here, the alarm type is the relationship between the power consumption of the indoor unit and the predetermined allowable power amount, that is, the time until the power consumption has already exceeded or is expected to exceed the allowable power amount. It is determined accordingly.
That is, this system is configured to transmit control information corresponding to the relationship between the power consumption of the indoor unit and the predetermined allowable power amount to the indoor unit. That is, when the power consumption amount does not exceed the allowable power amount, the present system controls the operation of the indoor unit so as to maintain the comfort level based on the SET * theory.
On the other hand, when the time until the power consumption is expected to exceed the allowable power is long, the system maintains a comfort level slightly inferior to the comfort level based on the SET * theory (comfort level). Control the operation of the indoor unit (with some sacrifice). In addition, if the time until the power consumption is expected to exceed the allowable power is short or has already exceeded, the system consumes more power than maintaining comfort based on the SET * theory. The operation of the indoor unit is controlled so that priority is given to reducing the amount.

(Address table)
The address table TBL107 is a database that stores a combination of the address of the indoor unit 4n and the address of the indoor temperature / humidity sensor 3n in association with the indoor unit ID.
FIG. 12 is a schematic diagram showing an example of information stored in the TBL 107. For example, in association with the indoor unit ID “41”, the address “A1” of the corresponding indoor unit and the corresponding indoor temperature and humidity sensor It indicates that the address “a1” is stored.

(Control information)
FIG. 13 is a schematic diagram illustrating an example of control information transmitted from the present system to each of the indoor units 41, 42, and 43. The indoor unit 4 that has received the control information from the air conditioning control device 1 operates based on the received control information.
In the present embodiment, for example, control information “weak (air volume)” “heating (operation mode)” “+1 (deviation temperature)” is transmitted to the indoor unit with the indoor unit ID “43”. Yes. In the figure, “-” indicates that there is no update information (as it is).

  Next, the time data acquisition unit 101, the outside air temperature data acquisition unit 102, the month data acquisition unit 103, the clothing amount calculation unit 104, the work intensity calculation unit 105, the control coefficient table selection unit 106, the room temperature, which are included in the air conditioning control device 1 Each means of the humidity data acquisition unit 107, the control coefficient acquisition unit 108, the alarm type acquisition unit 109, the control information table selection unit 110, the control information acquisition unit 111, the control information transmission unit 112, the timer 113, and the time determination unit 114 will be described. .

  The time data acquisition unit 101 is a unit that acquires current time data in response to an inquiry from the time determination unit 114, or an instruction from the timer 113 or periodically, and transmits the current time data to the time determination unit 114. The current time data is acquired from a time measuring unit (not shown) provided in the air conditioning control device 1.

  The outside air temperature data acquisition unit 102 receives outdoor temperature data from the outside air temperature sensor 2 and transmits it to the clothing amount calculation unit 104, and transmits information indicating that the outdoor temperature data has been acquired to the month data acquisition unit 103. Means.

  The month data acquisition unit 103 is a unit that receives information indicating that outdoor temperature data has been acquired from the outside air temperature data acquisition unit 102, acquires current month data, and transmits the acquired month data to the clothing amount calculation unit 104. Month data is acquired from the timekeeping unit provided in the air conditioning control device 1.

  The clothing amount calculation unit 104 refers to the clothing amount table TBL101 for the clothing amount corresponding to the combination of the outdoor temperature data received from the outside air temperature data acquisition unit 102 and the month data received from the month data acquisition unit 103. It is means for reading and transmitting to the control coefficient table selection unit 106.

The work intensity calculation unit 105 reads the work intensity corresponding to the combination of the time data acquired by the time determination unit 114 from the time data acquisition unit 101 and the indoor unit ID with reference to the TBL 102, and the control coefficient table selection unit 106 It is a means to transmit to.
Here, as a method for the air conditioning control device 1 to identify the indoor unit ID, for example, when the air conditioning control device 1 receives temperature / humidity data from the indoor temperature / humidity sensor 3, the indoor temperature / humidity sensor 3 received together with the temperature / humidity data. Address is used. That is, the air conditioning control device 1 refers to the TBL 107 using the address of the indoor temperature / humidity sensor 3 and reads the indoor unit ID stored in association with this address.

  The control coefficient table selection unit 106 is a unit that reads a control coefficient table identifier corresponding to a combination of the amount of clothes and work intensity for each room, that is, for each indoor unit, and transmits the control coefficient table identifier to the control coefficient acquisition unit 108. That is, the control coefficient table selection unit 106 refers to the TBL 103 and stores the control coefficient stored in association with the combination of the clothing amount received from the clothing amount calculation unit 104 and the work strength received from the work strength calculation unit 105. The table identifier is read and transmitted to the control coefficient acquisition unit 108.

  The indoor temperature / humidity data acquisition unit 107 is means for receiving indoor temperature / humidity data from the indoor temperature / humidity sensor 3 and transmitting it to the control coefficient acquisition unit 108.

  The control coefficient acquisition unit 108 refers to the control coefficient table corresponding to the control coefficient table identifier received from the control coefficient table selection unit 106, and corresponds to the indoor temperature / humidity data received from the indoor temperature / humidity data acquisition unit 107. This is means for reading out the control coefficient and transmitting it to the control information acquisition unit 111.

  The alarm type acquisition unit 109 is a unit that receives an alarm type from the demand control device 5 and stores it in the DB 101.

  The control information table selection unit 110 is means for selecting a control information table corresponding to an alarm type for each room, that is, for each indoor unit. That is, the control information table selection unit 110 reads the alarm type from the DB 101, reads the control information table identifier stored in association with the combination of the read alarm type and the indoor unit ID with reference to the TBL 105, and obtains control information It is means for transmitting to the unit 111.

  The control information acquisition unit 111 refers to the TBL 106 corresponding to the control information table identifier received from the control information table selection unit 110, reads the control information corresponding to the control coefficient received from the control coefficient acquisition unit 108, and controls the control information. It is means for transmitting to the transmission unit 112.

The control information transmission unit 112 is a unit that transmits the control information read from the TBL 106 by the control information acquisition unit 111 to the indoor unit 4. The address of the indoor unit 4 that is the transmission destination of the control information is read and specified by referring to the TBL 107 based on the indoor unit ID.
The control information transmission unit 112 transmits information indicating that the control information has been transmitted to the timer 113.

  The timer 113 is means for measuring that a predetermined time has elapsed after the control information transmitting unit 112 receives information indicating that the control information has been transmitted. When a predetermined time has elapsed, the timer 113 transmits information to that effect to the time determination unit 114.

  In response to receiving information indicating that a predetermined time has elapsed from the timer 113, the time determination unit 114 inquires of the time data acquisition unit 101 about the current time and determines whether the time is a predetermined time. Means. The time determination unit 114 instructs the outside air temperature data acquisition unit 102 to receive outdoor temperature data from the outside air temperature sensor 2 or determines the current time to the work intensity calculation unit 105 according to the determination result. The indoor temperature / humidity data acquisition unit 107 is instructed to receive the indoor temperature / humidity data from the indoor temperature / humidity sensor 3.

(Air conditioning control processing)
Next, the air conditioning control process by the air conditioning control device 1 will be described.
FIG. 14 is an example of a flowchart of an air conditioning control process by the air conditioning control device 1. The air conditioning control device 1 implements the air conditioning control process described below using each means in the device 1 described above.

(First air conditioning control method)
First, the air-conditioning control apparatus 1 acquires current time data, outside air temperature data, and month data using the time data acquisition unit 101, the outside air temperature data acquisition unit 102, and the month data acquisition unit 103, respectively (S1, S2). , S3). The air-conditioning control device 1 stores the acquired data in a storage unit in the device 1 and reads it by a process described later.

  Next, the air conditioning control device 1 uses the clothing amount calculation unit 104 to read out the clothing amount stored in association with the outside air temperature data and the month data stored in the storage unit from the TBL 101 (S4). For example, if the outside air temperature data is “20 ° C.” and the month data is “April”, the clothing amount “normal” is read from the TBL 101.

  Next, the air-conditioning control device 1 reads the work intensity corresponding to the current time data stored in the storage unit from the TBL 102 using the work intensity calculation unit 105 (S5). For example, if the current time data is “8:00” and the room type data is “R2 (consultation room)”, the work intensity “medium” is read from the TBL 102.

  Next, the air conditioning control device 1 uses the control coefficient table selection unit 106 to read the control coefficient table identifier stored in association with the previously read clothing amount and work intensity from the TBL 103 (S6). For example, if the clothing amount information is “normal” and the work intensity information is “medium”, the control coefficient table identifier “control coefficient table 2” is read from the TBL 103.

  Next, the air conditioning control device 1 acquires room temperature / humidity data from the room temperature / humidity sensor 3 using the room temperature / humidity data acquisition unit 107 (S7).

Next, the air conditioning control device 1 uses the control coefficient acquisition unit 108 to control the control coefficient stored in association with the acquired humidity (relative humidity) and room temperature in correspondence with the read control coefficient table identifier. Obtained from the coefficient table (S8).
For example, when the TBL 104 in FIG. 8 is a control coefficient table corresponding to the read control coefficient table identifier, if the indoor humidity data is “20 ° C.” and the indoor temperature data is “30%”, the control coefficient is calculated from the TBL 104. “+1” is read out.

  Next, the air conditioning control device 1 reads the alarm type from the DB 101 using the alarm type acquisition unit 109 (S9).

Next, the air conditioning control device 1 uses the control information table selection unit 110 to read the control information table identifier stored in association with the read alarm type from the TBL 105 for each indoor unit (S10).
For example, if the alarm type read from the DB 101 is “2”, “control information table 2” for the indoor unit 41, “control information table 1” for the indoor unit 42, and “control information table 0” for the indoor unit 43. Is read out.

  Next, the air conditioning control device 1 uses the control information acquisition unit 111 to identify and refer to the control information table corresponding to the read control information table identifier, and stores the control information table in association with the previously read control coefficient. The control information is read (S11). For example, when the TBL 106 of FIG. 10 is a control information table corresponding to the read control information table identifier, if the previously read control coefficient is “+1”, the control information “− (air volume)” “stop ( Operation mode) “0 (deviation temperature)” is read.

  Next, the air-conditioning control apparatus 1 reads the address of the indoor unit 4 using the control information transmission unit 112 with reference to the TBL 107, and transmits the previously read control information to the indoor unit 4 (S12).

  The air conditioning control device 1 that has transmitted the control information uses the timer 13 to wait for 1 minute to elapse after transmission (S13).

After 1 minute has elapsed (Yes), the air conditioning control device 1 uses the time determination unit 114 to read the current time and determine whether or not the current time is “8 o'clock”. If one minute has not elapsed (No), the timer 13 is used to wait for one minute to continue (S13).
As a result of the determination, if it is determined that the time is “8 o'clock” (Yes), the air conditioning control device 1 executes each process after the outside air temperature data acquisition process (S2) described above.
On the other hand, when it is determined that it is not “8 o'clock” (No), the air conditioning control device 1 determines whether or not the current time is “21:00”.

As a result of the determination, when it is determined that it is “21 o'clock” (Yes), the air conditioning control device 1 executes each process after the work intensity calculation process (S5) described above.
When it is determined that it is not “21 o'clock” (No), the air conditioning control device 1 executes each process after the room temperature / humidity data acquisition process (S7) described above.

  According to the first air conditioning control method described above, it is possible to perform air conditioning control in which the amount of energy consumed by the indoor unit is added to the indoor situation determined based on the work intensity and the amount of clothes. That is, it is possible to take energy saving measures while maintaining indoor comfort.

(Second air conditioning control method)
In the first air conditioning control method described above, a plurality of control coefficient tables exist depending on the combination of the clothing amount and the work intensity. That is, in the first air conditioning control method, in the control coefficient table selection process (S6) of FIG. 14, the control coefficient table identifier corresponding to the combination of the work intensity and the clothing amount is read from the TBL 103 shown in FIG.
On the other hand, in the second air conditioning control method, there are a plurality of control coefficient tables corresponding to only the work intensity. That is, in the second air conditioning control method, the process corresponding to the control coefficient table selection process (S6) in the flowchart shown in FIG. 14 is replaced with the control coefficient table identifier for each work intensity instead of the correspondence table shown in FIG. The control coefficient table identifier corresponding to the read work intensity (S5) is read using the correspondence table in which is stored. In the second air conditioning control method, each process corresponding to (S2, S3, S4) in FIG. 14 is unnecessary. Other processes are the same as those in the first air conditioning control method.

  According to the second air-conditioning control method described above, air-conditioning control can be performed in consideration of the amount of energy consumed by the indoor unit in the indoor situation determined based on the work intensity. Countermeasures can be made possible.

(Third air conditioning control method)
In the first air conditioning control method described above, a plurality of control coefficient tables exist depending on the combination of the clothing amount and the work intensity. That is, in the first air conditioning control method, in the control coefficient table selection process (S6) of FIG. 14, the control coefficient table identifier corresponding to the combination of the work intensity and the clothing amount is read from the TBL 103 shown in FIG.
On the other hand, in the third air conditioning control method, there are a plurality of control coefficient tables corresponding only to the amount of clothes. That is, in the third air conditioning control method, the process corresponding to the control coefficient table selection process (S6) in the flowchart shown in FIG. 14 is replaced with the control coefficient table identifier for each clothing amount instead of the correspondence table shown in FIG. The control coefficient table identifier corresponding to the read clothing amount (S4) is read using the correspondence table in which is stored. In the third air conditioning control method, the processing corresponding to (S1, S5) in FIG. 14 is not necessary. Other processes are the same as those in the first air conditioning control method.

  According to the third air-conditioning control method described above, air-conditioning control in which the amount of energy consumed by the indoor unit is added to the indoor situation determined based on the amount of clothes can be saved. Countermeasures can be made possible.

(Fourth air conditioning control method)
In the first air conditioning control method described above, a plurality of control information tables exist for each alarm type. That is, in the first air conditioning control method, the control information table identifier corresponding to the combination of the alarm type and the indoor unit ID is read from the TBL 105 shown in FIG. 10 in the control information table selection process (S10) of FIG.
In contrast, in the fourth air conditioning control method, a plurality of control information tables exist corresponding to only the indoor unit ID. That is, in the fourth air conditioning control method, the process corresponding to the control information table selection process (S10) in the flowchart shown in FIG. 14 is replaced with the control information table for each indoor unit ID instead of the correspondence table shown in FIG. The control information table identifier corresponding to each indoor unit ID is read using the demand control table in which the identifier is stored. Note that the fourth air conditioning control method does not require the processing corresponding to (S9) in FIG. Other processes are the same as those in the first air conditioning control method.

  According to the fourth air-conditioning control method described above, air-conditioning control can be performed in consideration of the indoor conditions determined based on the amount of clothes and the work intensity, and thus energy-saving measures can be taken while maintaining the comfort level in the room. can do.

(Demand control device 5)
Next, the demand control device 5 will be described.
FIG. 15 is a block diagram showing an embodiment of the demand control device 5.
The demand control device 5 includes a power consumption amount reception unit 501, a power consumption amount prediction value calculation unit 502, an integrated power consumption amount calculation unit 503, a power amount comparison unit 504, an alarm type determination unit 505, an alarm type transmission unit 506, and a storage. It has a part.
The storage unit stores a power consumption DB 501, an integrated power consumption DB 502, a contract power consumption TBL 501, a demand first definition table TBL 502, a demand second definition table TBL 503, and a transmission alarm value DB 503.

  Although not shown, the demand control device 5 includes a CPU (Central Processing Unit) and a program storage unit. The CPU controls and controls each component of the demand control device 5 according to the program stored in the program storage unit, and executes program processing. The program storage unit includes a ROM (Read Only Memory), a RAM (Random Access Memory), and the like, and stores various programs used by the demand control device 5.

  Note that the demand control apparatus 5 implements a demand control method described below by operating a demand control program according to the present invention and controlling each means in the demand control apparatus 5.

Hereinafter, each means in the demand control apparatus 5 will be described.
First, each database stored in the storage unit will be described.

(Power consumption database)
The power consumption database DB 501 is a database that stores the power consumption (measured value) received from the wattmeter 6 and the power consumption (predicted value) predicted by the demand control device 5. Here, it is assumed that the demand control device 5 receives the total amount of power consumption of the indoor units 31, 32, 33 from the power meter 6 every minute, and every time the power consumption amount is received from the power meter 6, the prediction is performed. The value shall be calculated.

FIG. 20 is a schematic diagram showing an example of information stored in the DB 501, and shows that 10 power consumption amounts (actually measured values) and 9 power consumption amounts (predicted values) are stored. ing. FIGS. 20A to 20C show examples of information stored in the DB 501 at times “0:10”, “0:11”, and “0:12”, respectively.
That is, (a) shows that the demand control device 5 that has received each power consumption “1” of “0:01”, “0:02”,. It shows that nine power consumption amounts (predicted values) “1” from “0:11” to “0:19” are calculated by receiving the power consumption amount “1” of “10”.
In (b), the demand control device 5 receives the power consumption amount “3” of “0:11”, and nine power consumption amounts (predicted values) “3” of “0:12” to “0:20”. "Is calculated.
In (c), the demand control device 5 receives the power consumption amount “4” of “0:12”, and nine power consumption amounts (predicted values) “4” of “0:13” to “0:21”. "Is calculated.

As described above, the demand control device 5 calculates the power consumption (predicted value) and updates the information stored in the DB 501 every time the power consumption is received from the wattmeter 6. The update method is to delete one oldest actual measurement value among the ten actual measurement values stored in the DB 501, nine predicted values, one actual value received from the wattmeter 6, and This is performed by storing nine newly calculated predicted values.
The predicted value is calculated by a program having a predetermined calculation formula, for example, based on the temporal transition of the actual measurement value, or the actual measurement value (demand control device 5 in the past (for example, one year ago) at the same time in the past. Stored in a storage means (not shown).

(Integrated power consumption database)
The integrated power consumption database DB502 is a database that stores the integrated power consumption.
FIG. 16 is a schematic diagram showing an example of information stored in the DB 502, and shows that the accumulated power consumption for each accumulator ID is stored. Here, the accumulator ID is an identifier of a program for calculating the accumulated power consumption. The demand control device 5 includes ten integration programs (integration meters 1 to 10), and each integration meter calculates the integrated power consumption by summing the power consumption for 10 minutes. That is, the totalizer N (N = 1 to 10) calculates the total power consumption by summing (11−N) actual measurement values and (N−1) predicted values. That is, at the time “0:10” shown in FIG. 20, the totalizer 1 calculates the integrated power consumption by summing up the ten actually measured values from the times “0:01” to “0:10”. Then, the accumulator 2 calculates the accumulated power consumption by adding the nine actually measured values from time “0:02” to “0:10” and one predicted value “0:11”.

(Contract power amount table)
The contract power amount table TBL501 is a database that stores the contract power amount. The contract power amount is, for example, an upper limit value of power consumption determined between a hospital and a power company. That is, the hospital operates each indoor unit so that the total power consumption amount of the indoor units 41, 42, and 43 is equal to or less than the contract power amount. If the contract power amount is exceeded, the penalty fee is charged. You are contracting with a power company to pay to the company. The electric power company can make a power supply plan based on the contracted electric energy.
FIG. 17 is a schematic diagram showing an example of information stored in the TBL 501 and shows that the contract power amount “20 (kwh)” is stored.
In the present invention, the contract power amount is an example of the allowable energy amount.

(Demand 1st and 2nd definition table)
The demand first definition table TBL502 and the demand second definition table TBL503 store the alarm type corresponding to the result of comparing the accumulated power consumption stored in the DB502 and the contract power consumption stored in the TBL501. Database.
FIG. 18A is a schematic diagram showing an example of information stored in the TBL 502, and shows that the alarm type “0” is stored. FIG. 18B is a schematic diagram illustrating an example of information stored in the TBL 503. The alarm type “2” and the accumulator IDs “5” to “4” are associated with the accumulator IDs “1” to “4”. This indicates that the alarm type “1” is stored in association with “10”.
The relationship between the comparison result between the integrated power consumption and the contract power consumption and the alarm types stored in the TBLs 502 and 503 will be described later.

(Transmission alarm value database)
The transmission alarm value database DB 503 is a database that stores alarm types transmitted from the demand control device 5 to the air conditioning control device 1. The information stored in the DB 503 is updated every time the alarm type determination unit 505 determines the alarm type (including a case where the alarm type is overwritten when the alarm type is the same throughout the update).

  Next, the demand control device 5 includes a power consumption amount reception unit 501, a power consumption amount prediction value calculation unit 502, an integrated power consumption amount calculation unit 503, a power amount comparison unit 504, an alarm type determination unit 505, and an alarm type transmission unit. Each means of 506 will be described.

  The power consumption amount receiving unit 501 is means for receiving the power consumption amount consumed by the indoor unit 4 from the wattmeter 6 and storing it in the DB 501.

  The predicted power consumption value calculation unit 502 calculates a predicted value of power consumption (hereinafter referred to as “predicted power consumption”) based on the power consumption received by the power consumption receiver 501, and the DB 501. It is means to memorize.

  The integrated power consumption calculation unit 503 calculates the integrated power consumption using the power consumption received from the power consumption reception unit 501 and the predicted power consumption received from the power consumption prediction value calculation unit 502. And means for storing in the DB 502.

  The power amount comparison unit 504 is a unit that compares the accumulated power consumption stored in the DB 502 with the contract power amount stored in the TBL 501 and transmits the comparison result to the alarm type determination unit 505. . The comparison result is information indicating whether or not there is an accumulated power consumption that exceeds the contracted power amount. If there is, the accumulator ID corresponding to the excess accumulated power amount is displayed. Information. Here, when the plurality of integrated power consumption amounts exceed the contracted power amount, the minimum integrated meter ID among the corresponding integrated meter IDs is set. That is, for example, if the integrator ID corresponding to the integrated power consumption exceeding the contracted electric energy among the integrator IDs “1” to “10” is “7” to “10”, the comparison result is “7”.

  The alarm type determination unit 505 is a unit that reads an alarm type corresponding to the comparison result received from the power amount comparison unit 504 from the TBL 502 or TBL 503 and transmits the alarm type to the alarm type transmission unit 506.

The alarm type transmission unit 506 is means for transmitting the alarm type read by the alarm type determination unit 505 to the air conditioning control device 1 and storing it in the DB 503.
The alarm type transmission unit 506 refers to the DB 503 when the alarm type is received from the alarm type determination unit 505, and the alarm type received from the alarm type determination unit 505 matches the alarm type stored in the DB 503. The alarm type received from the alarm type determination unit 505 is transmitted to the air conditioning control device 1 only when it is determined whether or not to match.
However, the transmission method of the alarm type to the air-conditioning control apparatus 1 in the present invention is not limited to this, and the alarm type transmission unit 506 does not determine whether or not they match, but the alarm type transmission unit 506 receives the alarm type from the alarm type determination unit 505. You may comprise so that the received alarm classification may be transmitted to the air-conditioning control apparatus 1 whenever it receives. In this case, the DB 503 can be unnecessary.

(Warning type judgment method)
Next, an alarm type determination method (reading method) by the alarm type determination unit 505 will be described using the accumulated power consumption stored in the DB 502 illustrated in FIG. 16 as an example.

  At the time “0:10” shown in FIG. 16A, “10 (kwh)” of all the integrated power consumptions of the integrators 1 to 10 exceeds the contracted power consumption “20 (kwh)”. Absent. Therefore, as described above, the alarm type determination unit 505 receives a comparison result indicating that there is no integrated power consumption exceeding the contracted power amount from the power amount comparison unit 504. When the comparison result is received, the alarm type determination unit 505 reads the alarm type “0” with reference to the TBL 502.

  At the time “0:11” shown in FIG. 16B, the accumulated power consumption of the accumulators 6 to 10 exceeds the contracted power amount “20 (kwh)”. Therefore, as described above, the alarm type determination unit 505 receives, from the power amount comparison unit 504, the smallest totalizer ID “6” among the surplus totalizers as a comparison result. When the comparison result is received, the alarm type determination unit 505 reads the alarm type “1” corresponding to the comparison result “6” with reference to the TBL 503.

  At the time “0:12” shown in FIG. 16C, the accumulated power consumption of the integrators 3 to 10 exceeds the contracted energy “20 (kwh)”. Therefore, as described above, the alarm type determination unit 505 receives, from the power amount comparison unit 504, the smallest totalizer ID “3” among the surplus totalizers as a comparison result. When this comparison result is received, the alarm type determination unit 505 reads the alarm type “2” corresponding to the comparison result “3” with reference to the TBL 503.

  As described above, the alarm type determination unit 505 reads the alarm type corresponding to the comparison result after selecting the demand definition table to be referred to according to the comparison result received from the power amount comparison unit 504.

(Demand control processing)
Next, demand control processing by the demand control device 5 will be described.
FIG. 19 is a flowchart illustrating an example of demand control processing executed by the demand control device 5. The demand control device 5 implements the demand control processing described below using each means in the device 5 described above.

  First, the demand control device 5 receives the power consumption (actual value) from the wattmeter 6 every minute using the power consumption receiver 501 and stores it in the DB 501 (T1).

  Next, the demand control apparatus 5 calculates nine power consumption amounts (predicted values) using the predicted power consumption value calculation unit 502 and stores them in the DB 501 (T2).

  Next, the demand control device 5 uses the integrated power consumption calculation unit 503 to read the actual measurement value and the predicted value of the power consumption from the DB 501, calculate the integrated power consumption, and store it in the DB 502 (T3).

  Next, the demand control device 5 reads the integrated power consumption and the contract power consumption from the DB 502 and the TBL 501 using the power amount comparison unit 504 (T4), and each of the read ten integrated power consumptions and the contract power. The magnitude is compared with the amount (T5).

  As a result of the comparison between the integrated power consumption and the contract power consumption, when it is determined that none of the 10 integrated power consumptions exceeds the contract power consumption (No), the demand control device 5 compares the comparison results. The alarm type corresponding to is determined (T61). That is, as described above, the demand control device 5 reads the alarm type “0” from the TBL 502.

  On the other hand, as a result of the comparison between the accumulated power consumption and the contract power consumption, when it is determined that any of the 10 accumulated power consumptions exceeds the contract power consumption (Yes), the demand control device 5 The alarm type corresponding to the comparison result is determined (T62). That is, as described above, the demand control device 5 reads out from the TBL 503 the alarm type stored in association with the accumulator ID that is the comparison result.

  Next, the demand control device 5 uses the alarm type transmission unit 506 to transmit the alarm type read from the TBL 502 or TBL 503 to the air conditioning control device 1 (T7). At this time, the demand control device 5 transmits the read alarm type to the air conditioning control device 1 only when the read alarm type and the alarm type stored in the DB 503 do not match.

  As described above, the air conditioning control device 1 that has received the alarm type from the demand control device 5 selects a table corresponding to the alarm type from the plurality of control information tables, and performs air conditioning control processing.

  As described above, this system can control the operation of the indoor unit based on the power consumption (actual value and predicted value) of the indoor unit in addition to the amount of clothes, work intensity, and indoor temperature and humidity. . That is, according to the present system, it is possible to realize air conditioning control that enables energy saving measures while maintaining the comfort level in the room.

It is a mimetic diagram showing an embodiment of an air-conditioning control system concerning the present invention. It is a network block diagram which shows the example of the connection form of the apparatus group which comprises the said system. It is a schematic diagram which shows the relationship of the information used with the said system. It is a block diagram which shows the example of the air-conditioning control apparatus which comprises the said system. It is a schematic diagram which shows the example of the information memorize | stored in the clothing amount table of the said air-conditioning controller apparatus. It is a schematic diagram which shows the example of the information memorize | stored in the work intensity | strength table of the said air-conditioning controller apparatus. It is a schematic diagram which shows the example of the information memorize | stored in the correspondence table used in order for the said air-conditioning control apparatus to select a control coefficient table. It is a schematic diagram which shows the example of the information memorize | stored in the control coefficient table in the said air-conditioning control apparatus. It is a schematic diagram which shows the example of the information memorize | stored in the alarm classification database in the said air-conditioning control apparatus. It is a schematic diagram which shows the example of the information memorize | stored in the demand control table in the said air-conditioning control apparatus. It is a schematic diagram which shows the example of the information memorize | stored in the control information table in the said air-conditioning control apparatus. It is a schematic diagram which shows the example of the information memorize | stored in the address table in the said air-conditioning control apparatus. It is a schematic diagram which shows the example of the control information which the said air-conditioning control apparatus transmits. It is a flowchart which shows the example of the air-conditioning control process by the said system. It is a block diagram which shows the example of the demand control apparatus which comprises the said system. It is a schematic diagram which shows the example of the information memorize | stored in the integrated power consumption database in the said demand control apparatus. It is a schematic diagram which shows the example of the information memorize | stored in the contract electric energy table in the said demand control apparatus. It is a schematic diagram which shows the example of the information memorize | stored in the demand definition table of the said demand control apparatus. It is a flowchart which shows the example of the demand control process by the said demand control apparatus. It is a schematic diagram which shows the example of the relationship between the actual value of the power consumption amount memorize | stored in the said demand control apparatus, and a predicted value. It is a schematic diagram which shows the example of the integrated power consumption calculated by the said demand control apparatus. It is a schematic diagram which shows another example of the integrated power consumption calculated by the said demand control apparatus. It is a schematic diagram which shows another example of the integrated power consumption calculated by the said demand control apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Air-conditioning control apparatus 2 Outside temperature sensor 3 Indoor temperature / humidity sensor 4 Indoor unit 5 Demand control apparatus 6 Wattmeter TBL101 Clothes amount table TBL102 Work intensity | strength table TBL103 Correspondence table TBL104 Control coefficient table TBL105 Demand control table TBL106 Control information table TBL107 Address table DB101 Alarm type database TBL501 Contract power consumption table TBL502 Demand first definition table TBL503 Demand second definition table DB501 Power consumption database DB502 Integrated power consumption database DB503 Transmission alarm value database

Claims (9)

Connect the indoor unit installed in the room and each of the sensors that sense the temperature and humidity in the room via a communication network,
A work intensity table storing work intensity corresponding to the time, and
A control coefficient table storing control coefficients corresponding to indoor temperature and humidity, and
A control information table storing control information for controlling the operation of the indoor unit for each control coefficient;
With
There are multiple control coefficient tables corresponding to work intensity,
Means for obtaining current time data;
Means for receiving indoor temperature and humidity data from the sensor;
Means for reading the work intensity corresponding to the time data from the work intensity table;
Means for reading out the control coefficient corresponding to the received indoor temperature and humidity data from the control coefficient table corresponding to the read work intensity;
Means for reading control information corresponding to the read control coefficient from the control information table and transmitting it to the indoor unit;
The air-conditioning control apparatus characterized by having. An indoor unit installed in the room, a first sensor that senses the temperature and humidity in the room, and a second sensor that senses the temperature outside the room are connected via a communication network.
A clothing amount table storing the amount of clothing corresponding to the outdoor temperature every month;
A control coefficient table storing control coefficients corresponding to indoor temperature and humidity, and
A control information table storing control information for controlling the operation of the indoor unit for each control coefficient;
With
There are multiple control coefficient tables corresponding to the amount of clothing,
A means of obtaining current month data;
Means for receiving indoor temperature and humidity data from the first sensor;
Means for receiving outdoor temperature data from the second sensor;
Means for reading out the clothing amount corresponding to the combination of the outdoor temperature data and the month data from the clothing amount table;
Means for reading out the control coefficient corresponding to the received indoor temperature and humidity data from the control coefficient table corresponding to the read out clothing amount;
Means for reading control information corresponding to the read control coefficient from the control information table and transmitting it to the indoor unit;
The air-conditioning control apparatus characterized by having. An indoor unit installed in the room, a first sensor that senses the temperature and humidity in the room, and a second sensor that senses the temperature outside the room are connected via a communication network.
A clothing amount table storing the amount of clothing corresponding to the outdoor temperature every month;
A work intensity table storing work intensity corresponding to the time, and
A control coefficient table storing control coefficients corresponding to indoor temperature and humidity, and
A control information table storing control information for controlling the operation of the indoor unit for each control coefficient;
With
There are a plurality of the above control coefficient tables corresponding to the combination of the amount of clothes and work intensity,
Means for obtaining current month data and time data;
Means for receiving indoor temperature and humidity data from the first sensor;
Means for receiving outdoor temperature data from the second sensor;
Means for reading out the clothing amount corresponding to the combination of the outdoor temperature data and the month data from the clothing amount table;
Means for reading the work intensity corresponding to the time data from the work intensity table;
Means for reading out the control coefficient corresponding to the received indoor temperature and humidity data from the control coefficient table corresponding to the combination of the read out clothing amount and work intensity;
Means for reading control information corresponding to the read control coefficient from the control information table and transmitting it to the indoor unit;
The air-conditioning control apparatus characterized by having. Connect to a demand control device that transmits one of multiple alarm types according to the energy consumption of the indoor unit via a communication network,
There are a plurality of control information tables corresponding to each of the plurality of alarm types,
Means for receiving an alarm type from the demand control device;
Means for selecting a control information table from which control information to be transmitted to the indoor unit is read out according to the received alarm type from the plurality of control information tables;
The air conditioning control device according to any one of claims 1 to 3, further comprising:   An air conditioning control program for causing a computer to function as the air conditioning control device according to any one of claims 1 to 4. An energy meter that measures the energy consumption of the indoor unit and an air conditioning control device that controls the operation of the indoor unit are connected via a communication network.
A first storage unit storing an accumulated energy amount;
A second storage unit storing an allowable energy amount;
A third storage unit storing an alarm type corresponding to a result of comparing the amount of accumulated energy consumption and the allowable energy amount;
Means for receiving the energy consumption from the energy meter;
Means for updating the accumulated energy consumption stored in the first storage unit using the received energy consumption;
Means for comparing the amount of accumulated energy consumption stored in the first storage unit and the allowable energy amount stored in the second storage unit;
Means for reading out the alarm type corresponding to the comparison result from the third storage unit and transmitting it to the air conditioning control device;
A demand control device comprising: An energy meter that measures the energy consumption of the indoor unit and an air conditioning control device that controls the operation of the indoor unit are connected via a communication network.
A fourth storage unit storing the accumulated energy amount;
A fifth storage unit storing an allowable energy amount;
A sixth storage unit storing an alarm type corresponding to an excess predicted time based on a result of comparing the amount of accumulated energy consumption and the allowable energy amount;
Means for receiving the energy consumption from the energy meter;
Means for calculating the predicted energy consumption from the energy consumption,
Means for updating the accumulated energy consumption stored in the fourth storage unit using the estimated excess energy consumption;
Means for comparing the amount of accumulated energy consumption stored in the fourth storage unit with the allowable energy amount stored in the fifth storage unit;
Means for calculating the estimated excess time based on the comparison result;
Means for reading out the alarm type corresponding to the estimated excess time from the sixth storage part and transmitting it to the air conditioning control device;
A demand control device comprising:   A demand control program for causing a computer to function as the demand control apparatus according to claim 6 or 7. An air conditioning control device that controls the operation of the indoor unit, and a demand control device,
An air conditioning control system according to any one of claims 1 to 4, wherein the air conditioning control device is the demand control device according to claim 6 or 7.

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