JP6000181B2 - Air conditioning control system and air conditioning control method - Google Patents

Description

  The present invention relates to an air-conditioning control system and an air-conditioning control method, and more particularly, a reduction in electricity charges by automatic control of an air-conditioner by demand control at a time when it is not determined whether the air-conditioner performs cooling or heating. The present invention relates to an air conditioning control system and an air conditioning control method suitable for supporting coexistence of various indoor environments.

  Generally, a high-voltage power receiving company contracts with an electric power company and pays an electricity bill using the average power for 30 minutes using the most power in the past year as a contract power (Non-Patent Document 1, Non-Patent Document 1, (See Patent Document 2). Therefore, in order to save electricity charges, it is important to suppress the demand value (maximum demand power).

  In order to suppress this demand value, demand controllers have become widespread. This demand controller is a device that monitors the power usage of the supply and demand from time to time, and if it is predicted to exceed the set demand value, it controls the load equipment so as not to exceed a certain value. .

  For example, Patent Document 1 discloses a system that automatically changes a setting value of a demand controller.

  Further, Patent Document 2 discloses a demand control system that selects an air conditioner that stops an air conditioner based on rank data.

  Non-Patent Document 3 and Non-Patent Document 4 introduce air conditioning control controllers that can perform demand control.

JP 2007-202277 A JP 2000-333368 A

TEPCO, “Introduction of Demand Control System”, [online], [Search on March 14, 2013], Internet <URL: http://www.tepco.co.jp/setsuden/business/demand-j .html> Tohoku Electric Power Co., Ltd., “Top page-> Electricity charges-> Contract electric power-> [Corporate customers]-> Contract electric power-> Contract electric power", [online], [2013 March Search 14th of March], Internet <URL: http://www.tohoku-epco.co.jp/dbusiness/service/rule.html> Panasonic, “Air-conditioning integrated monitoring and control system P-AIMS”, [online], [March 14, 2013 search], Internet <URL: http://www2.panasonic.biz/es/air/control/paims /> Sanyo Electronics Co., Ltd., “Air-conditioning energy-saving system“ ESSOR ””, [online], [March 14, 2013 search], Internet <URL: http://www.sdk-kk.co.jp /prd/essor/ESSOR_exp.html>

The demand controller for an air conditioner according to the prior art disclosed in Non-Patent Documents 3 and 4 has a demand excess prevention function as follows in order to suppress the demand value.
(1) Energy-saving mode of air conditioner Set the device operation output and auto-off time for each time zone for each air conditioner.
(2) Peak power cut function Limits the operation of the air conditioner when it exceeds or is expected to exceed a preset power value (stopping, reducing the degree of cooling / heating, etc.).

  A general demand controller that controls an air conditioner functions to reduce cooling in the summer and to suppress heating in the winter when approaching the demand value in order to lower the demand value.

  However, in general, in spring and summer, which are the off-season of hot and cold days, it is not determined whether cooling or heating is controlled to keep the indoor environment comfortable. On the same day, air conditioning may be performed, and on a cold day, heating may be performed. In the prior art, a demand control control model at a time when the air conditioner may perform both cooling and heating has not been considered. Therefore, the user cannot perform appropriate demand control for the air conditioner in spring and summer, which are the off-season of hot and cold days.

  The present invention has been made in order to solve the above-mentioned problems, and the object of the present invention is, in particular, an electricity charge by automatic control of an air conditioner by demand control at a time when it is not determined whether the air conditioner performs cooling or heating. It is to provide an air conditioning control system that supports both a reduction in energy consumption and a comfortable indoor environment.

  In the air conditioning control system of the present invention, a power measurement monitor that measures the power consumption of the electrical equipment installed at each site, a temperature / humidity sensor that measures the temperature and humidity in the area constituting each site, and each site The air conditioner installed in the area comprising the air conditioner, the air conditioner or the outdoor unit of the air conditioner, connected to the air conditioner or the air conditioner control device for controlling the outdoor unit, the power measurement monitor and the temperature / humidity sensor. A site terminal that receives measurement data in a site and the area that constitutes the site, is connected to an air conditioning control device, and transmits an air conditioning control command. And a server for holding information.

  The air conditioning control information includes a target power value for demand control in each site, a target temperature for heating in the area constituting each site, a lower limit temperature and an upper limit temperature for the target temperature for heating, and a cooling higher than the target temperature for heating. The base terminal receives the air conditioning control information from the server, and based on the received air conditioning control information, the power consumption value at the site is the demand control target. Control that turns off the air conditioner for the air conditioning control device when the temperature measured in the area is above the lower limit temperature for the heating target temperature and below the cooling target temperature when the power value does not exceed Send a command.

In addition, the base terminal receives the air conditioning control information from the server, and based on the received air conditioning control information, when the power consumption value at the site exceeds the target power value for demand control, the temperature measured in the area is the heating temperature. When the temperature is lower than the lower limit for the target temperature and lower than the upper limit for the cooling target temperature, a control command for turning off the air conditioner is sent to the air conditioning control device. When the power value exceeds the target power value for demand control and the temperature measured in the area is between the lower limit temperature for the first target temperature and the upper limit temperature for the second target temperature, or When the power consumption value at the site does not exceed the target power value for demand control, and the first target temperature and the second target temperature When the time is between, the base terminal transmits to the air conditioning control device a control command for performing partial suppression of the air conditioner operation in the area.

  In addition, the base terminal determines that when the power consumption value at the site exceeds the target power value for demand control and the temperature measured in the area falls below the lower limit temperature for the first target temperature, or the second terminal When the temperature exceeds the upper limit temperature with respect to the target temperature, a control command for turning on the air conditioner is transmitted to the air conditioning control device.

  The air conditioning control information includes information related to date / time and time. When the air conditioning control information corresponds to the information related to date / time and time, the base terminal transmits a control command to turn off the air conditioner to the air conditioning control device.

  According to the present invention, particularly in demand control at a time when the air conditioner is likely to perform both cooling and heating, the air conditioning control that supports both the reduction of the electricity bill by the automatic control of the air conditioner and the comfortable indoor environment. A system can be provided.

It is a system configuration figure of an air-conditioning control system concerning one embodiment of the present invention. It is a block diagram which shows the structure of the base terminal which concerns on one Embodiment of this invention. It is a block diagram which shows the structure of the server which concerns on one Embodiment of this invention. It is a figure which shows the model of the air-conditioning control system which concerns on one Embodiment of this invention. It is a figure which shows a site demand management table. It is a figure which shows a site structure table. It is a figure which shows an air-conditioning control setting table. It is a figure which shows a temperature control setting table. It is a figure which shows a base terminal management table. It is a figure which shows an air-conditioning control condition table. It is a figure which shows a temperature control condition table. It is a figure which shows an air-conditioning control apparatus structure table. It is a figure which shows an air-conditioning control state management table. It is a figure which shows an air-conditioning driving | operation history table. It is a figure which shows the program structure in the server side. It is a figure which shows the program structure in the base terminal side. It is a timing chart which shows information exchanged with processing of each part of an air-conditioning control system concerning one embodiment of the present invention. It is the data flow figure which showed in detail the place regarding the air-conditioning control of the air-conditioning control system which concerns on one Embodiment of this invention. It is a figure which shows the air-conditioning control determination process in the base terminal at the time of air_conditionaing | cooling operation. It is a figure which shows the air-conditioning control determination process in the base terminal at the time of heating operation. It is a figure which shows the air-conditioning control determination process in case both cooling operation and heating operation can exist (the 1). It is a figure which shows the air-conditioning control determination process in case both cooling operation and heating operation can exist (the 2). It is a figure which shows an air-conditioning control setting screen. It is a figure which shows the air-conditioning control detailed setting screen displayed at the time of addition. It is a figure which shows the air-conditioning control detailed setting screen displayed at the time of update / deletion. This is a warning dialog that pops up when the temperature is set.

Hereinafter, an embodiment according to the present invention will be described with reference to FIGS.
First, the configuration of an air conditioning control system according to an embodiment of the present invention will be described with reference to FIGS. 1 to 3.
FIG. 1 is a system configuration diagram of an air conditioning control system according to an embodiment of the present invention.
FIG. 2 is a block diagram showing the configuration of the base terminal according to the embodiment of the present invention.
FIG. 3 is a block diagram showing a configuration of a server according to an embodiment of the present invention.

  Here, power monitoring in the air conditioning control system according to the present embodiment is managed in units of sites, and areas are defined as subdivisions thereof. This specific example will be described later in detail.

  As shown in FIG. 1, the air conditioning control system according to the present embodiment includes a base terminal 100 (master unit), a power measurement monitor 10, a temperature / humidity sensor 50 (slave unit), a signal converter 80, an air conditioning control device 90, 95, display terminal 400, pulse detector 70, router 40, client terminal 30, and server 20.

  The base terminal 100 receives and stores, as measurement data, the power consumed by the equipment from the power measurement monitor 10 for a certain period of time, the temperature and humidity from the temperature / humidity sensor 50, and measures them via the router 40 over the Internet. Upload data. In addition, the measurement data at regular intervals is transmitted to the display terminal 400. In this embodiment, the interval for receiving the measurement data from the power measurement monitor 10 and the temperature / humidity sensor 50 and the measurement interval for the electric energy are set to 1 minute. In addition, the period for uploading the measurement data to the server 20 is 12 hours in this embodiment. The detailed configuration and operation of the base terminal 100 will be described later in detail.

  Further, the site terminal 100 receives the air conditioning control condition from the server, and gives a command to the air conditioning control devices 90 and 95 according to the amount of power at the site measured by the power measurement monitor 10 and the temperature condition from the wet temperature sensor 50. The air conditioner 300 is controlled.

  The power measurement monitor 10 transmits measurement data obtained by measuring the amount of power to the base terminal 100 via the signal conversion device 80 every minute. The signal conversion device 80 is a device that converts a serial interface into a network interface. The power measurement monitor is connected to a pulse detector 70 installed in the wattmeter 60, for example, and measures the amount of power.

  The temperature / humidity sensor 50 transmits the measured temperature and humidity at the installation location to the base terminal 100 which is the master unit every minute.

  The display terminal 400 is a general-purpose tablet PC, for example, and displays information on power consumption, humidity, and temperature at each site based on measurement data sent from the base terminal 100.

  The router 40 is a device that connects the base terminal 100 to a network. The base terminal 100 is connected to the Internet by the router 40 and sends measurement data to the server 20 or receives management information and air conditioning control conditions from the server 20.

  The server 20 receives the input of the air conditioning control condition for each site from the client terminal 30, accumulates the measurement data of the site, and holds it as management information for each site. In addition, the air conditioning control conditions for each site are transmitted to the base terminal 100.

  The client terminal 30 is a device for inputting the air conditioning control conditions of each site or accessing the management information of the server 20 and viewing the status of each site. For example, a general-purpose personal computer (hereinafter, referred to as a network device) that can be connected to a network. PC)).

  The air conditioning control devices 90 and 95 are devices for controlling the air conditioning device 300 in response to a command from the base terminal 100. There are two types of air conditioning control devices of the present embodiment, and there are an air conditioning control device 90 of a type directly connected to the air conditioning device 300 and an air conditioning control device 95 of a type connected to the outdoor unit 305.

  The air conditioning control device 90 is connected to the air conditioning device 300 and controls the air conditioning device 300 in response to a command from the base terminal 100. On the other hand, the air-conditioning control device 95 is connected to the outdoor unit 305, receives the command from the base terminal 100, and controls the air-conditioning device 300 by operating the air-conditioning function of the outdoor unit 305.

  Next, the hardware configuration of the base terminal 100 will be described in detail.

  As shown in FIG. 2, the base terminal 100 includes an MPU 110, a RAM 120, a ROM 130, a network IF 140, a USB IF 150, a card slot 160, a wireless IF 170, and an antenna 180.

  An MPU (Micro Processor Unit) 110 is a control unit, executes a program, performs various calculations, and issues input / output commands to each unit.

  A RAM (Random Access Memory) 120 is a semiconductor main storage device, and holds programs executed by the MPU 110 and work data for calculation.

  A ROM (Read Only Memory) 130 is a memory that holds a program to be executed. In the ROM 130, a power / temperature / humidity management program and an air conditioning control program are written when the apparatus is manufactured. Details of the functions of the power / temperature / humidity management program and the air conditioning control program will be described later.

  The power / temperature / humidity management program and the air conditioning control program may be periodically rewritten from the server 20 and updated to the latest one.

  The network IF 140 is an interface for a wired network, and is connected to the router 40 by, for example, Ethernet (registered trademark). The base terminal 100 transmits measurement data from each site to the client terminal 30 via the network IF 140 and transmits the measurement data to the server 20 collectively. In addition, site management information and air conditioning control conditions are received from the server 20 via the network IF 140.

  The USBIF 150 is an interface for connecting a USB (Universal Serial Bus) device. The USB is a general-purpose serial interface, and is used for maintenance such as writing the address of the server 20 in the base terminal 100 of the present embodiment.

  The card slot 160 is a slot for inserting an SD / MicroSD memory card. The SD / MicroSD memory card is a standardized memory card using a flash memory as a storage medium. The base terminal 100 of the present embodiment uses the SD / MicroSD memory card inserted into the card slot 160 as auxiliary storage, and the measurement data and necessary tables from each site are held in the SD / MicroSD memory card. .

  The wireless IF 170 is an interface for transmitting and receiving radio waves from the antenna 180 and performing wireless communication. As the wireless communication, for example, communication according to standards such as IEEE802.11b and Bluetooth (registered trademark) with a frequency band of 2.4 GHz can be used. The base terminal 100 of the present embodiment collects measurement data from the slave units installed at each site via the wireless IF 170 and transmits the measurement data and necessary information to the display terminal 400.

  Next, the hardware configuration of the server 20 will be described in detail.

  As shown in FIG. 3, the server 20 is realized by a general computer, and includes a CPU (Central Processing Unit) 201, a main storage device 202, a network IF 203, a graphic IF 204, an input / output IF 205, and an auxiliary storage device IF 206. It is the form combined by.

  The CPU 201 controls each unit of the server 20 and loads and executes necessary programs in the main storage device 202.

  The main storage device 202 is usually composed of a volatile memory such as a RAM, and stores a program executed by the CPU 201 and data to be referred to.

  The network IF 203 is an interface for connecting to the external Internet.

  The graphic IF 204 is an interface for connecting a display device 220 such as an LCD (Liquid Crystal Display).

  The input / output IF 205 is an interface for connecting an input / output device.

  The auxiliary storage device IF 206 is an interface for connecting an auxiliary storage device such as an HDD (Hard Disk Drive) 241 or a DVD drive (Digital Versatile Disk) 242.

  The HDD 241 has a large storage capacity, and stores a program for executing this embodiment.

  In general, the server 20 configures a RAID according to a request for data safety and continuous operation. Although not shown, it is also possible to connect a dedicated mass storage device.

  The HDD 241 of this embodiment stores an air conditioning control condition setting program 261 and a site management program 262.

  Details of the functions of the air conditioning control condition setting program 261 and the site management program 262 will be described later.

  The DVD drive 242 is a device that writes data to or reads data from an optical disk such as a DVD or CD. For example, a program provided by a CD-ROM can be installed in the server 20.

  The server 20 according to the present embodiment installs a necessary program in the computer as described above and executes each function.

Next, the model of the air-conditioning control system of this embodiment is demonstrated using FIG.
FIG. 4 is a diagram illustrating a model of an air conditioning control system according to an embodiment of the present invention.

  As shown in FIG. 4, the model of the air-conditioning control system of the present embodiment is called a 1F department store, 1F office on a site called A department store Shinjuku store (hereinafter referred to as “A department store Shinjuku store site”). Area (hereinafter referred to as “1F sales floor area”, etc.), A department store Shibuya store site includes 2F sales floor area, 5F office area, and A department store headquarters site includes management department area Model.

  The 1F sales floor area of the A department store Shinjuku site includes a temperature / humidity sensor a50, an air conditioner a300, an air conditioner b300, an air conditioner c300, an air conditioning control device a90, an air conditioning control device b90, and an air conditioning control device c90.

  The 1F office area of the A department store Shinjuku store site includes a temperature / humidity sensor b50, an air conditioner d300, an air conditioning control device d90, and a client terminal a30.

  The A department store Shinjuku store site is provided with a base terminal a100 and a power measurement monitor a10. And it is connected to the base terminal a100 via the signal conversion device a80 in the 1F sales floor area. The base terminal a100 is connected to the network via the router a40 and can communicate with the server 20 in the management unit area 20 of the A department store headquarters site.

  The temperature / humidity sensor a50 in the 1F sales area of the A department store Shinjuku store site transmits the measured temperature / humidity data to the base terminal 100 by radio.

  In addition, power is measured by the power measurement monitor 10 and transmitted to the base terminal 100 via the signal converter 80.

  The base terminal 100 sends the transmitted temperature / humidity measurement data and power measurement data to the server 20 in the management department area 20 of the A department store headquarters site, and based on the air conditioning control conditions sent from the server 20, The air conditioner control device a90, the air conditioner control device b90, the air conditioner control device c90, and the air conditioner control device d90 in the 1F office area are controlled. Here, the unit that the base terminal 100 controls the air conditioning control device is assumed to be one area unit.

  In addition, from the client terminal a30 in the 1F office area of the A department store Shinjuku store site, the air conditioning control conditions are input and transmitted via the router 40 to the server 20 in the management department area 20 of the A department store head office site. Site management information is received from the server 20 and displayed.

  A router 40 is installed in the A department store headquarters site, and a client terminal b30 and a server 20 are installed in the management area.

  The server 20 receives the air conditioning control condition input from the client terminal 30 in each area via the router c40 and transmits it to each base terminal 100. In addition, the management information display request of the site is received from the client terminal 30 in each area, and the management information is transmitted via the router c40. The function of the client terminal b30 is the same as the function of the client terminal a30.

  On the other hand, the 2F sales floor area of the A department store Shibuya store site includes a temperature / humidity sensor c50, an outdoor unit a305, an air conditioner e315, an air conditioner f315, an air conditioner g315, and an air conditioning control device e95.

  The 5F office area of the A department store Shibuya store site includes a temperature / humidity sensor d50, an outdoor unit b, an air conditioner h300, and an air conditioning control device f95.

  The A department store Shibuya store site is provided with a base terminal b100 and a power measurement monitor b10. And it is connected to the base terminal a100 via the signal converter b80 in the 2F sales floor area. The base terminal b100 is connected to the network via the router b40, and can communicate with the server 20 in the management unit area 20 of the A department store headquarters site.

  The functions of each device at the A department store Shibuya store site are almost the same as those at the A department store Shinjuku store site. However, the air conditioning control device e95 controls the outdoor unit a305, whereby the air conditioner e315, the air conditioner f315, and the air conditioner. The function of the air conditioner h315 is indirectly controlled by controlling the function of the air conditioner h315 indirectly by controlling the function of the air conditioner g315 indirectly.

  Both the A department store Shinjuku store site and the A department store Shibuya store site are common in that each area is one air conditioning control unit. However, in the A department store Shinjuku store site, each air conditioner a300, air conditioner b300, and air conditioner c300 in one area can be individually controlled. However, in the A department store Shibuya store site, the air conditioning control device e95 is Since the outdoor unit a305 is controlled, the individual air conditioners e315, f315, and g315 are different from each other in that they cannot be individually controlled.

Next, the data structure according to the present embodiment will be described based on the system model described above with reference to FIGS.
FIG. 5 is a diagram showing a site demand management table.
FIG. 6 is a diagram showing a site configuration table.
FIG. 7 is a diagram showing an air conditioning control setting table.
FIG. 8 is a diagram showing a temperature control setting table.
FIG. 9 is a diagram showing a base terminal management table.
FIG. 10 is a diagram illustrating an air conditioning control condition table.
FIG. 11 is a diagram showing a temperature control condition table.
FIG. 12 is a diagram illustrating an air conditioning control device configuration table.
FIG. 13 is a diagram illustrating an air conditioning control state management table.
FIG. 14 is a diagram illustrating an air conditioning operation history table.

  Here, the site demand management table, the site configuration table, the air conditioning control setting table, the temperature control setting table, and the base terminal management table of FIGS. 5 to 9 are tables held in the server 20, and are shown in FIGS. An air conditioning control condition table, a temperature control condition table, an air conditioning control device configuration table, an air conditioning control state management table, and an air conditioning operation history table are tables held in the base terminal 100.

  The site demand management table is a table that holds a target demand value at each site, and includes fields of “site” and “demand value” as shown in FIG. Here, the target demand value is the maximum demand power (average power for 30 minutes) targeted by the power receiver as a management reference.

  The site configuration table is a table showing the configuration of each site, and includes fields of “site”, “area”, “air conditioning control device”, and “greenhouse temperature sensor” as shown in FIG. For example, in this example, it is shown that there are air conditioning control devices a, b, c and a greenhouse degree sensor a in the 1F sales floor area of the A department store Shinjuku store site.

  The air conditioning control setting table is a table for storing power control conditions set by the user. As shown in FIG. 7, “site”, “period”, “time”, “automatic OFF”, “non-working day” ”,“ Control setting name ”,“ control order ”, and“ operation time value ”.

  “Site” indicates a site to which this setting is applied. The “control setting name” is a name input by the user in order to uniquely distinguish the setting of this record (described later). “Period” and “Time” indicate a period and time for operating the air conditioner. “Automatic OFF” is a flag indicating whether or not the air conditioning is automatically turned off when the time expires for the designated period, and when it is “valid”, the time expires for the designated period. Sometimes, the air conditioning is automatically turned off, and “invalid” indicates that the air conditioning is not automatically turned off when the specified period of time has expired. The “non-working day” indicates the day when the air conditioning is not operated, even in the designated period and time, in units of days of the week.

  The “control order” indicates a priority order for performing the demand control operation of the air conditioning control device, and the demand control operation is performed from the air conditioning control device having a higher priority order.

  The “operation time point value” is a value indicating what percentage of the demand value shown in FIG.

  For example, in this example, the setting of the control setting name “Shinjuku store summer season” relates to the A department store Shinjuku store site, and the period from June 10 to September 14 is 9:45 to 20:00. The auto-off is set to “valid”, and the non-working day is Wednesday, and the air-conditioning control device is operated in the order of d, c, b, and a in order of demand to 90% of the demand value. This indicates that demand control operation will start when it becomes.

  The temperature control setting table is a table for storing temperature control conditions set by the user. As shown in FIG. 8, “site”, “area”, “control setting name”, “operation selection”, “lower limit” Each field includes “temperature”, “target temperature”, and “upper limit temperature”.

  “Site” and “Area” indicate sites and areas to which this setting is applied. “Operation selection” indicates whether the air conditioner is in a cooling operation or a heating operation.

  The “control setting name” is the same as that described in the air conditioning control setting table of FIG.

  "Lower limit temperature" and "Upper limit temperature" are the lower and upper limit temperatures that serve as a reference for turning ON or OFF during air-conditioning operation, and "Target temperature" approaches this temperature. This is the target temperature. The relationship between the “lower limit temperature”, “upper limit temperature”, “target temperature” and air conditioning control will be described in detail later.

In this example, for example, in the 1F sales floor area of the A department store Shinjuku store site, the target temperature is 26 ° C, the lower limit temperature is 21 ° C, the upper limit temperature is 28 ° C during cooling , and the target temperature is set during heating. 20 ° C., an example in which the lower limit temperature is 14 ° C. and the upper limit temperature is 22 ° C. is shown. Thus, the temperature controlled at the time of cooling and heating can be kept separately in one area.

  The base terminal management table is a table for storing the IP address of the base terminal 100 at each site. As shown in FIG. 9, the base terminal management table includes fields from “site”, “base terminal”, and “IP address”. Become. In this example, the IP address of the base terminal of the A department store Shinjuku store is 172.16.0.1.

  The air conditioning control condition table is a table for storing the air conditioning control conditions sent from the server 20, and as shown in FIG. 10, each of “power threshold value”, “time”, and “automatic OFF” Consists of fields. In this example, the air conditioning control condition is transmitted from the server 20 to the base terminal 100 on the previous day once a day.

  The “power threshold value” indicates a value for demand control operation of the air conditioning control device when the power consumption at the site exceeds this value. “Time” is the time of air conditioning operation, “Automatic OFF” is a flag indicating whether or not the air conditioning is automatically turned off when the time expires for the specified period, “Control order” is the air conditioning The priorities for performing the demand control operation of the control device are shown respectively.

  Note that there is a relationship of power threshold value = demand value × operation time value / 100.

  The temperature control condition table is a table for storing values related to temperature among the air-conditioning control conditions sent from the server 20, and as shown in FIG. 11, "area", "operation selection" , “Lower limit temperature”, “target temperature”, and “upper limit temperature” fields. “Area” indicates an area to which this setting is applied. The meanings of “operation selection”, “lower limit temperature”, “target temperature”, and “upper limit temperature” are the same as those in FIG. In this example, the air conditioning control condition is transmitted from the server 20 to the base terminal 100 on the previous day once a day.

  The air conditioning control device configuration table is a table showing the configuration of the air conditioning control device 300 in the area, and includes fields of “area” and “air conditioning control device” as shown in FIG.

  In this example, it is shown that the air conditioning control devices a, b, and c are installed in the 1F sales floor area.

  The air conditioning control state management table is a table showing the current air conditioning control state. As shown in FIG. 13, the air conditioning control state management table includes fields of “air conditioning control device”, “control order”, “operation state”, and “operation selection”. Become.

  In this example, the control order in the area of the air-conditioning control device a is fourth, indicating that the cooling operation is being performed.

  The air conditioning operation history table is a table showing the history of the air conditioning operation so far, and includes fields of “air conditioning control device”, “operation period”, and “operation selection” as shown in FIG.

  In this example, it is shown that the air-conditioning control device a performed a cooling operation at 11: 00 to 14:00 on August 12, 2012.

Next, software functions of the air conditioning control system according to the embodiment of the present invention will be described with reference to FIGS. 15 and 16.
FIG. 15 is a diagram showing a program configuration on the server side.
FIG. 16 is a diagram showing a program configuration on the site terminal side.

  The programs stored in the HDD 241 of the server 20 include an air conditioning control condition setting program and a site management program as shown in FIG.

  The air conditioning control condition setting program has a control condition recording function and a control condition communication function. The control condition recording function is a function for receiving and recording the air conditioning control condition from the client terminal 30. The control condition communication function is a function for communicating the air conditioning control condition to the base terminal 100.

  The site management program has a site condition setting function, a site operation history recording function, and a site measurement data recording function. The site condition setting function is a function for setting the air conditioning control condition of each site at the client terminal 30. The site operation history recording function is a function for receiving and recording the history of air conditioning operation from each site. The site measurement data recording function is a function for receiving and recording measurement data from each site. The programs stored in the ROM 130 of the base terminal 100 or the SD / MicroSD memory card include a power / temperature / humidity management program and an air conditioning control program as shown in FIG.

  The power / temperature / humidity management program has a power / temperature / humidity measurement data collection function, a measurement data storage function, and a measurement data communication function. The power / temperature / humidity measurement data collection function is a function for collecting power measurement data from the power measurement monitor 10 and temperature / humidity measurement data from the temperature / humidity sensor 50. The measurement data storage function is a function for recording the transmitted power, temperature and humidity measurement data on the SD / MicroSD card. The measurement data communication function is a function for transmitting measurement data to the server 20.

  The air conditioning control program has a demand power management function, a temperature management function, an air conditioning control device command function, and an air conditioning control device state management function.

  The demand power management function is a function that suppresses the operation of the air conditioner when the power consumption increases to a set ratio of the demand value. The temperature management function is a function for controlling the operation of the air conditioner so that the set temperature is reached. The air conditioning control device command function is a function that gives a command to the air conditioning control device. The air-conditioning control device state management function is a function for holding an operation history of the air conditioner and transmitting it to the server 20.

Next, operation | movement of the air-conditioning control system which concerns on one Embodiment of this invention, and the data flow in each part are demonstrated using FIG. 17 and FIG.
FIG. 17 is a timing chart showing information exchanged with processing of each unit of the air conditioning control system according to the embodiment of the present invention.
FIG. 18 is a data flow diagram showing in detail a place related to the air conditioning control of the air conditioning control system according to the embodiment of the present invention.

  First, the power measurement monitor 10 shown in FIG. 1 transmits measurement data related to power to the base terminal 100 (A01).

  In parallel, the temperature / humidity sensor 50 wirelessly transmits measurement data related to temperature / humidity to the base terminal 100 (A02).

  Both of these transmissions are performed periodically, for example, every minute.

  The base terminal 100 stores the measurement data received from the power measurement monitor 10 and the temperature / humidity sensor 50 in the SD / MicroSD card (S01).

  Next, the base terminal 100 periodically transmits measurement data via the network (A03).

  The server 20 records the measurement data transmitted from the base terminal 100 (S08).

  Before the measurement data is recorded, the user inputs air conditioning control conditions from the client terminal 30 (S09).

  The input air conditioning control conditions are transmitted from the client terminal 30 to the server 20 (A10).

  The server 20 stores the transmitted air conditioning control conditions in the air conditioning control setting table shown in FIG. 7 and the temperature control setting table shown in FIG. 8 (S06).

  Next, the demand value in the site demand management table shown in FIG. 5 and the operation time point value in the air conditioning control setting table shown in FIG. 7 are multiplied to calculate necessary air conditioning control conditions such as obtaining a power threshold. (S07).

  Then, the server 20 transmits the received and calculated air conditioning control conditions to the base terminal 100 (A04). This transmission is transmitted on the day before the target day, and the frequency is once a day.

  The base terminal 100 stores the transmitted air conditioning control conditions in the air conditioning control condition table shown in FIG. 10 and the temperature control condition table shown in FIG. 11 (S02).

  Next, the base terminal 100 determines the air conditioning control based on the values stored in the air conditioning control condition table and the temperature control condition table (S03). A specific determination method will be described in detail later.

  Then, the base terminal 100 refers to the air conditioning control state management table in FIG. 13, and when it is necessary to issue a control command such as a state change based on the determination result of S03, A control command is issued (A05).

  The air conditioning control device 90 receives a control command from the base terminal 100 and issues a control command to the air conditioner 300 (A06). Based on this, the air conditioner 300 performs an air conditioning operation (S04).

  Then, the air conditioner 300 reports the status such as “normal” and “abnormal” to the air conditioning control device 90 (A07), and the air conditioning control device 90 reports the status to the base terminal 100 based on the status report (A08). .

  The base terminal 100 stores the operating state in the air conditioning operation history table shown in FIG. 14 based on the status report of the air conditioning control device 90 (S05).

  Then, the history of the air-conditioning operation is transmitted from the base terminal 100 to the server 20 periodically, for example, once a day (A09).

  In addition, although the case of the A department store Shinjuku store site was shown above, in the case of the A department store Shibuya store site, the control flow is: base terminal 100 → air conditioning control device 95 → outdoor unit 305 → air conditioner 300. Is the same.

  Further, when there is a request for site management information from the client terminal 30 (A11), the server 30 transmits the site management information to the client terminal 30 (A12), and the client terminal 30 displays it (S10). .

  The site management information includes power consumption at the site, temperature / humidity history, air conditioning control conditions currently set for the site, air conditioning operation history, site configuration information, and the like.

Next, details of the air conditioning control determination process at the base terminal will be described with reference to FIGS. 19A to 20B.
FIG. 19A is a diagram illustrating an air conditioning control determination process in the base terminal during the cooling operation.
FIG. 19B is a diagram showing an air conditioning control determination process in the base terminal during the heating operation.
FIG. 20A and FIG. 20B are diagrams illustrating an air conditioning control determination process when there is a possibility of both cooling operation and heating operation.

  The feature of the air-conditioning control system according to the present embodiment is that it provides a demand control control mechanism for the air-conditioner that can perform both cooling and heating in spring and summer, which are the off-season of hot and cold days. That is.

  First, as a premise of the description, control when the air conditioner performs cooling and heating independently will be described with reference to FIGS. 19A and 19B.

In the case of the cooling operation, it is intended to be operated mainly in summer. Here, as shown in FIG. 19A, the lower limit temperature is 20 ° C., the target temperature is 26 ° C., and the upper limit temperature is 28 ° C. Suppose that it is ° C.
(1) When power consumption> power threshold (power consumption> demand value × demand target value / 100) When room temperature <lower limit temperature, cooling is not necessary. At this time, the base terminal 100 controls the air conditioning control devices 90 and 95 to turn off the cooling.

  When the lower limit temperature ≦ the room temperature ≦ the upper limit temperature, control is performed so as to reduce the number of air-conditioning units as much as possible until the upper limit temperature is reached. That is, when there are a plurality of air conditioners in the area, the base terminal 100 gives a control command to the air conditioning control devices 90 and 95 so that only a part is operated or the air conditioners are intermittently operated. When an air conditioner control order is specified, when turning it off, turn the air conditioner off from the one with the highest control order. Turn on the air conditioner from the air conditioner with a long period.

  At this time, when the air conditioner is turned on, the room temperature decreases, and when the air conditioner is turned off, the room temperature increases. However, since the number of air conditioning units is controlled as much as possible during demand control, Is gradually approaching the outside air temperature, or when the outside air temperature exceeds the upper limit temperature, it approaches the upper limit temperature of 28 ° C. from a lower temperature.

  When the upper limit temperature <room temperature, even if the demand target is exceeded, the base terminal 100 controls the air conditioning control devices 90 and 95 to turn on the cooling in consideration of the environment at the air conditioning installation location. give.

For this reason, since the air conditioner is turned on when the upper limit temperature <room temperature, the room temperature is lowered and approaches the upper limit temperature of 28 ° C. from the higher temperature.
(2) When power consumption ≦ power threshold (power consumption ≦ demand value × demand target value / 100) When room temperature <lower limit temperature, cooling is unnecessary. At this time, the base terminal 100 instructs the air conditioning control devices 90 and 95 to turn off the cooling.

When the lower limit temperature ≦ the room temperature ≦ the target temperature, control is performed to reduce the number of air-conditioning units as much as possible within a range not exceeding the target temperature. That is, when there are a plurality of air conditioners in the area, the base terminal 100 gives a control command to the air conditioning control devices 90 and 95 so that only a part is operated or the air conditioners are intermittently operated. When an air conditioner control order is specified, when turning it off, turn the air conditioner off from the one with the highest control order. Turn on the air conditioner from the air conditioner with a long period.
When room temperature> target temperature, the base terminal 100 gives an instruction to the air conditioning control devices 90 and 95 to increase the number of air conditioning units to reach the target temperature.

  When the lower limit temperature ≦ the room temperature ≦ the target temperature, the control is performed so as to reduce the number of air conditioning units as much as possible. Therefore, the room temperature increases, and the room temperature approaches the target temperature of 26 ° C. from the lower temperature.

  When room temperature> target temperature, control is performed to increase the number of air-conditioning units so as to reach the target temperature. Therefore, the room temperature decreases, and the room temperature approaches the target temperature of 26 ° C. from the higher temperature.

  That is, in any case, in the case of (2), it can be seen that the room temperature approaches the target temperature of 26 ° C.

  On the other hand, in the case of heating operation, the cooling and temperature control are dual.

In the case of heating operation, it is intended to be operated mainly in winter. Here, as shown in FIG. 19B, the lower limit temperature is 14 ° C., the target temperature is 22 ° C., and the upper limit temperature is 24 ° C. Suppose that it is ° C.
(1) When power consumption> power threshold (power consumption> demand value x demand target value / 100) When room temperature <lower limit temperature, consider the environment at the air-conditioning installation site even if the demand target is exceeded The base terminal 100 gives a control command to the air conditioning control devices 90 and 95 to turn on the heating.

  For this reason, when the room temperature is less than the lower limit temperature, the air conditioner is turned on, so that the room temperature rises and approaches the lower limit temperature of 14 ° C. from the lower temperature.

  When the lower limit temperature ≦ the room temperature ≦ the upper limit temperature, control is performed so as to reduce the number of air-conditioning units as much as possible until the lower limit temperature is reached. That is, when there are a plurality of air conditioners in the area, the base terminal 100 gives a control command to the air conditioning control devices 90 and 95 so that only a part is operated or the air conditioners are intermittently operated. When an air conditioner control order is specified, when turning it off, turn the air conditioner off from the one with the highest control order. Turn on the air conditioner from the air conditioner with a long period.

  At this time, when the air conditioner is turned on, the room temperature increases, and when the air conditioner is turned off, the room temperature decreases. However, since the number of air conditioning units is controlled as much as possible during demand control, When the outside air temperature gradually approaches or falls below the lower limit temperature, the temperature approaches the lower limit temperature of 14 ° C. from the higher temperature.

Heating is not required when the upper limit temperature is less than room temperature. At this time, the base terminal 100 gives a control command to the air conditioning control devices 90 and 95 to turn off the heating.
(2) When power consumption ≦ power threshold value (power consumption ≦ demand value × demand target value / 100) When room temperature <target temperature, the demand terminal is within the demand target. A control command is given to 95 so as to increase the number of air-conditioning units until the target temperature is reached.

  When target temperature ≦ room temperature ≦ upper limit temperature, control is performed so as to reduce the number of air-conditioning control units as much as possible until the target temperature is reached. That is, when there are a plurality of air conditioners in the area, the base terminal 100 gives a control command to the air conditioning control devices 90 and 95 so that only a part is operated or the air conditioners are intermittently operated. . When an air conditioner control order is specified, when turning it off, turn the air conditioner off from the one with the highest control order. Turn on the air conditioner from the air conditioner with a long period.

  When target temperature ≦ room temperature ≦ upper limit temperature, control is performed so as to reduce the number of air-conditioning units as much as possible. Therefore, the room temperature decreases, and the room temperature approaches the target temperature of 22 ° C. from the higher temperature.

  When the room temperature is less than the target temperature, the number of air-conditioning units is controlled to increase so that the target temperature is reached. Therefore, the room temperature increases, and the room temperature approaches the target temperature of 22 ° C. from the lower temperature.

  That is, in any case, in the case of (2), it can be seen that the room temperature approaches the target temperature of 22 ° C.

  Heating is not required when the upper limit temperature is less than room temperature. At this time, the base terminal 100 gives a control command to the air conditioning control devices 90 and 95 to turn off the heating.

  Next, regarding the control of the air conditioning control system according to the present embodiment when there is a possibility that the air conditioner performs both cooling and heating in spring and summer, which are the off-season periods on hot and cold days, using FIGS. 20A and 20B. explain.

  First, in order to be able to do this, it is necessary that the target temperature of heating <the target temperature of cooling. This condition is based on a natural request that energy is saved, cost is reduced, and the health of workers is not too cold during cooling and not too warm during heating.

As will be described later, when both the cooling and heating temperature conditions of one area are set, the user is allowed to input to satisfy this condition. When the target heating temperature is set equal to or higher than the target cooling temperature, the control for cooling and heating is performed separately, and the following control is not performed.
(1) When the lower limit temperature of the cooling operation ≦ the upper limit temperature of the heating operation For example, the lower limit temperature during the heating operation is 14 ° C., the target temperature is 20 ° C., the upper limit temperature is 22 ° C., and the lower limit temperature during the cooling operation is , 21 ° C., target temperature is 26 ° C., and upper limit temperature is 28 ° C.

At this time, as shown in FIG. 20A, the air conditioning control processing is performed by combining the left side of FIG. 19B and the right side of FIG. 19A into the heating OFF part on the right side of FIG. 19B and the cooling off part on the left side of FIG. It becomes a cut figure.
(1-1) When power consumption> power threshold value (power consumption> demand value × demand target value / 100) When the room temperature is lower than the lower limit temperature of the heating, the environment in the air-conditioning installation place even if the demand target is exceeded In consideration of the above, the base terminal 100 gives a control command to the air conditioning control devices 90 and 95 to turn on the heating.

  For this reason, when the room temperature is lower than the lower limit temperature of heating, the air conditioner is turned on, so that the room temperature rises and approaches the lower limit temperature of 14 ° C. from the lower temperature.

  When the lower limit temperature of heating ≦ the room temperature ≦ the upper limit temperature of the cooling, control is performed to reduce the number of air-conditioning units as much as possible. That is, when there are a plurality of air conditioners in the area, the base terminal 100 gives a control command to the air conditioning control devices 90 and 95 so that only a part is operated or the air conditioners are intermittently operated.

  Therefore, when the lower limit temperature of heating ≦ outside temperature ≦ the upper limit temperature of cooling, the room temperature is set to the outside temperature, and when the outside temperature <the lower limit temperature of heating, the upper limit of cooling is set to 14 ° C., which is the lower limit temperature of heating. When the temperature is less than the outside air temperature, the temperature approaches 28 ° C., which is the upper limit temperature for cooling.

  Normally, in spring and summer, which are the off-season of hot and cold days when the air conditioner may perform both cooling and heating, the outside air temperature is a comfortable temperature lower limit of heating ≤ outside temperature ≤ upper limit temperature of cooling It is expected that many will be satisfied.

  When the upper limit temperature of cooling <room temperature, even if the demand target is exceeded, the base terminal 100 turns on the cooling for the air conditioning control devices 90 and 95 in consideration of the environment at the air conditioning installation location. Give a control command.

For this reason, since the air conditioner is turned on when the upper limit temperature of the cooling is less than room temperature, the room temperature is lowered and approaches the upper limit temperature of 28 ° C. from the higher temperature.
(1-2) When power consumption ≦ power threshold value (power consumption ≦ demand value × demand target value / 100) When room temperature <target temperature for heating, the target terminal 100 is air-conditioned because it is within the demand target. A control command is given to the control devices 90 and 95 to increase the number of air-conditioning units until the heating target temperature is reached.

  At this time, since control is performed to increase the number of air-conditioning units to reach the heating target temperature, the room temperature rises, and the room temperature approaches the heating target temperature of 20 ° C. from the lower temperature side.

  When the target temperature of heating ≦ the room temperature ≦ the target temperature of cooling, control is performed so as to reduce the number of air-conditioning control units as much as possible. That is, when there are a plurality of air conditioners in the area, the base terminal 100 gives a control command to the air conditioning control devices 90 and 95 so that only a part is operated or the air conditioners are intermittently operated.

  Therefore, when the target temperature of heating is equal to or lower than the target temperature of cooling, the room temperature is equal to the target temperature of cooling. When the temperature is less than the outside air temperature, the temperature approaches the target temperature of 26 ° C., respectively.

  When the target temperature of cooling is less than room temperature, the demand terminal is within the demand target, so the base terminal 100 instructs the air-conditioning control devices 90 and 95 to increase the number of air-conditioning units until the target temperature of cooling is reached. give.

At this time, since control is performed to increase the number of air conditioning units so as to reach the cooling target temperature, the room temperature decreases, and the room temperature approaches the cooling target temperature of 26 ° C. from the higher temperature side.
(2) When the upper limit temperature of the heating operation <the lower limit temperature of the cooling operation For example, the lower limit temperature during the heating operation is 14 ° C., the target temperature is 20 ° C., the upper limit temperature is 22 ° C., and the lower limit temperature during the cooling operation is 24 ° C., the target temperature is 26 ° C., and the upper limit temperature is 28 ° C.

At this time, as shown in FIG. 20B, the air conditioning control process is a diagram in which the left side of FIG. 19B and the right side of FIG. 19A are combined as they are.
(2-1) When power consumption> power threshold (power consumption> demand value × demand target value / 100) When room temperature <lower limit temperature of heating, when upper limit temperature <room temperature, (1-1) It is the same.

  When the lower limit temperature of heating ≤ room temperature ≤ upper limit temperature of cooling and the upper limit temperature of heating ≤ room temperature ≤ lower limit temperature of cooling, both heating and cooling are OFF, and the lower limit temperature of heating ≤ room temperature ≤ upper limit temperature of cooling, And when it is other than the upper limit temperature of heating ≦ room temperature ≦ the lower limit temperature of cooling, the demand control operation is performed as in (1-1).

At this time, the room temperature is the lower limit temperature of heating ≦ the outside temperature ≦ the upper limit temperature of cooling, and the outside temperature is set to the outside temperature, and the outside temperature <the lower limit temperature of heating is set to 14 ° C. which is the lower limit temperature of heating. When the upper limit temperature is less than the outside air temperature, approaching to the cooling upper limit temperature of 28 ° C. is the same as (1-1).
(2-2) When power consumption ≦ power threshold (power consumption ≦ demand value × demand target value / 100) When room temperature <target temperature for heating, when target temperature for cooling <room temperature, (1-2 ).

  When the target temperature of heating ≦ the room temperature ≦ the target temperature of cooling, and when the upper limit temperature of heating ≦ the room temperature ≦ the lower limit temperature of cooling, both the heating and the cooling are turned off, and the target temperature of heating ≦ the room temperature ≦ the target temperature of the cooling, And when the upper limit temperature of heating ≦ room temperature ≦ the lower limit temperature of cooling, the thinning operation is performed as in (1-2).

  Also at this time, when the target temperature of heating ≦ the outside temperature ≦ the target temperature of cooling, the outside temperature is set to the outside temperature, and when the outside temperature <the target temperature of heating, the heating target temperature is set to 20 ° C. <It is the same as (1-2) that the temperature is close to the cooling target temperature of 26 ° C. when it is outside air temperature.

  As described above, in the air conditioning control system according to the present embodiment, as long as the condition of the target temperature of heating <the target temperature of cooling is satisfied, the spring corresponding to the off-season period on hot and cold days when the air conditioner may perform both cooling and heating. And summer air conditioning control can be performed centrally.

  If the air conditioner is appropriately set, unnecessary operation can be avoided by setting the temperature of the air conditioner even when the air conditioner operation mode and the control by the air conditioning control system of the present embodiment do not match. For example, in the example shown in FIG. 20A, when (1-2) power consumption ≦ power threshold value, the temperature setting of the air conditioner is 23 ° C., the air conditioner remains in the heating mode, and the room temperature is 26 Suppose that it rose to ℃. At this time, the air conditioning control system controls to turn on the cooling, but the temperature is higher than 23 ° C., which is the set temperature of the air conditioner itself, so the air conditioner does not operate.

Next, a user interface of an air conditioning control system according to an embodiment of the present invention will be described with reference to FIGS.
FIG. 21 is a diagram showing an air conditioning control setting screen.
FIG. 22A is a diagram showing an air conditioning control detail setting screen displayed at the time of addition.
FIG. 22B is a diagram showing an air conditioning control detail setting screen displayed at the time of updating / deleting.

  FIG. 23 shows a warning dialog popped up when the temperature is set.

  The air conditioning control setting screen 400 and the air conditioning control detail setting screens 500a and 500b are both displayed by the user operating the client terminal 30, and necessary values are input.

  On the air conditioning control setting screen 400, the user inputs or selects a site in the site input field 401.

  The setting list 410 displays a list of air conditioning control settings created in advance for demand control.

  When adding the air conditioning control setting, input the values of the period 421, the time 422, the automatic OFF 423, the non-working day 424, the area 425, and the control detailed setting 426 from the air conditioning control setting input field 420, and “add as a new setting” "Button 404 is clicked. With this operation, the setting ID is automatically given and added to the setting list 410.

  When deleting the air conditioning control setting, a delete button 403 is clicked.

  When updating the air conditioning control setting, the air conditioning control in the setting list 410 is selected, the value of the displayed air conditioning control setting input field 420 is changed, and the update button 405 is clicked. To clear the displayed value of the air conditioning control setting input field 420, the clear button 406 may be clicked.

  The detailed control setting 426 is a column for setting a control order of air conditioning in the site and an operation time point for demand control. To add a new control detail setting, an add button 428 is clicked.

  When the add button 428 is clicked, an air conditioning control detail setting screen 500a shown in FIG. 22A is displayed. Then, for the control detail setting name 503, the control detail setting name is input, for example, “1F sales floor summer”.

  Since the list of air conditioners in the site is displayed in the control order column 510, the target air conditioner is selected and the order change button 511 is clicked to change the control order of the selected air conditioner. . Here, the higher the priority is, the higher the priority is. In the case of demand control, the air conditioning operation is preferentially restricted.

  In the column of the operation time point setting 520, it is specified what percentage of the demand target value the power consumption at the site will perform the demand control of the air conditioner.

  Then, when adding a control detail setting based on the input value, an add button 504 is clicked. To cancel the input value, a cancel button 505 is clicked.

  In order to update / delete the control detail setting, the control detail setting is selected from the control detail setting combo box 427 and the update / delete button 429 is clicked.

  When the update / delete button 429 is clicked, an air conditioning control detail setting screen 500b shown in FIG. 22B is displayed. Since the control detail setting that has already been input is displayed in the control detail setting field 502, a new name is input to the control detail setting name 503 when it is desired to change the control detail setting name.

  When necessary, the control order and the operation time setting values are updated, and an update button 506 is clicked. Click the delete button 507 to delete the selected control detail setting, and click the cancel button 508 to cancel the input value.

  Next, the temperature setting input field 430 is used to set the temperature for each area.

  The user inputs the name of the control area, and inputs the lower limit temperature, the target temperature, and the upper limit temperature in each of the operation selection, which is cooling or heating, or both.

  In order to enable the temperature setting, the selection check box 431 is clicked.

  Then, by clicking on the operation selection check box, it is possible to specify cooling, selection, or both. When both cooling and selection are selected, input is performed so that the target temperature for heating is less than the target temperature for cooling.

  When this condition is violated, a warning dialog as shown in FIG. 23 is popped up to prompt the user to input again.

  In this example, for the setting of the 1F sales floor area in the “Shinjuku store spring setting” at the A department store Shinjuku store site, both cooling and heating are specified as the operation selection. During cooling, the lower limit temperature is 21 ° C. The target temperature is set to 26 ° C., the upper limit temperature is set to 28 ° C., and during heating, the lower limit temperature is set to 14 ° C., the target temperature is set to 20 ° C., and the upper limit temperature is set to 22 ° C.

DESCRIPTION OF SYMBOLS 10 ... Electric power measurement monitor, 50 ... Temperature / humidity sensor, 20 ... Server, 30 ... Client terminal, 40 ... Router, 80 ... Signal converter, 90, 95 ... Air-conditioning control apparatus, 100 ... Base terminal (master unit), 200 ... Display terminal, 300, 315 ... air conditioner, 305 ... outdoor unit,
110 ... MPU, 120 ... RAM, 130 ... ROM, 140 ... Network IF, 150 ... USBIF, 160 ... Card slot, 170 ... Wireless IF, 180 ... Antenna,
201 ... CPU (Central Processing Unit), 202 ... main storage device, 203 ... network IF, 204 ... graphic IF, 205 ... input / output IF, 206 ... auxiliary storage device IF, 220 ... display device, 241 ... HDD, 242 ... DVD Drive (Digital Versatile Disk).

Claims (7)

A power measurement monitor that measures the power consumption of electrical equipment installed at each site;
A temperature and humidity sensor that measures the temperature and humidity in the areas that make up each site;
Air conditioners installed in the areas that make up each site;
An air conditioning control device connected to the air conditioner or an outdoor unit of the air conditioner and controlling the air conditioner or the outdoor unit;
From the power measurement monitor and the temperature / humidity sensor, receive measurement data in each installed site and the area constituting the site, connected to the air conditioning control device, and air conditioning control command to the air conditioning control device A base terminal that sends
In the air conditioning control system connected to the base terminal by a network and having management information for each site and a server for holding air conditioning control information,
The air conditioning control information includes a target power value for demand control in each site, a first target temperature in an area constituting each site, a lower limit temperature and an upper limit temperature for the first target temperature, and the first target temperature. higher second target temperature, the lower limit temperature and the upper limit temperature and the free Mutotomoni for that the second target temperature,
In the case where the air conditioner can be used in combination with a cooling or heating operation mode,
Including one or more operation modes of the air conditioner in the same area of each site, or one or more operation modes different from each other,
The first and second target temperatures controlled by each of the different operation modes and the upper and lower temperature limits can be set separately,
The base terminal receives the air conditioning control information from the server, and based on the received air conditioning control information, when the power consumption value at the site does not exceed the target power value of the demand control, the temperature measured in the area When the air temperature is equal to or higher than the first target temperature and equal to or lower than the second target temperature, a control command for turning off the air conditioner is transmitted to the air conditioning control device. system.   The base terminal receives the air conditioning control information from the server, and when the power consumption value at the site exceeds the target power value of the demand control based on the received air conditioning control information, is measured in the area When the temperature is equal to or higher than the lower limit temperature relative to the first target temperature and equal to or lower than the upper limit temperature relative to the second target temperature, a control command for turning off the air conditioner is transmitted to the air conditioning control device. The air conditioning control system according to claim 1.   Further, the base terminal is configured such that when the power consumption value at the site exceeds the target power value for the demand control, the temperature measured in the area is a lower limit temperature with respect to the first target temperature and a second temperature. When it is between the upper limit temperatures for the target temperature, or when the power consumption value at the site does not exceed the target power value of the demand control, and when it is between the first target temperature and the second target temperature The air-conditioning control system according to claim 1, wherein the base terminal transmits a control command for performing partial suppression of air-conditioner operation in the area to the air-conditioning control device.   Furthermore, when the power consumption value at the site exceeds the target power value of the demand control, and the temperature measured in the area falls below a lower limit temperature with respect to the first target temperature, the base terminal 2. The air conditioning control system according to claim 1, wherein when the temperature exceeds an upper limit temperature for the second target temperature, a control command for turning on an air conditioner is transmitted to the air conditioning control device.   The air-conditioning control information includes information related to date / time, and when the information corresponds to the information related to date / time and time, the base terminal transmits a control command to turn off the air-conditioner to the air-conditioning control device. The air conditioning control system according to claim 1.   2. The air conditioning according to claim 1, wherein the first target temperature is a heating target temperature of the air conditioner operation, and the second target temperature is a cooling target temperature of the air conditioner operation. Control system. A power measurement monitor that measures the power consumption of electrical equipment installed at each site;
A temperature and humidity sensor that measures the temperature and humidity in the areas that make up each site;
Air conditioners installed in the areas that make up each site;
An air conditioning control device connected to the air conditioner or an outdoor unit of the air conditioner and controlling the air conditioner or the outdoor unit;
From the power measurement monitor and the temperature / humidity sensor, receive measurement data in each installed site and the area constituting the site, connected to the air conditioning control device, and send an air conditioning control command to the air conditioning control device. The base terminal to send,
A server that is connected to the base terminal by a network and that holds management information for each site, and air conditioning control information,
In an air conditioning control method of an air conditioning control system having a client terminal connected to the server and transmitting the air conditioning control information,
The air conditioning control information includes a target power value for demand control in each site, a first target temperature in an area constituting each site, a lower limit temperature and an upper limit temperature for the first target temperature, and the first target temperature. higher second target temperature, the lower limit temperature and the upper limit temperature and the free Mutotomoni for that the second target temperature,
In the case where the air conditioner can be used in combination with a cooling or heating operation mode,
Including one or more operation modes of the air conditioner in the same area of each site, or one or more operation modes different from each other,
The first and second target temperatures controlled by each of the different operation modes and the upper and lower temperature limits can be set separately,
The base terminal receiving measurement data related to power related to a site from the power measurement monitor;
The base terminal receives measurement data relating to the temperature constituting the site from the temperature and humidity sensor; and
Transmitting air conditioning control information from the client terminal to the server;
The server holds the received air conditioning control information;
The server transmitting the air conditioning control information to the base terminal;
The base terminal receives the air conditioning control information from the server, and based on the received air conditioning control information, when the power consumption value at the site does not exceed the target power value of the demand control, the temperature measured in the area Transmitting a control command to turn off the air conditioner to the air conditioning control device when the temperature is equal to or higher than the first target temperature and equal to or lower than the second target temperature. Air conditioning control method.

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