KR20230076869A - demand control system - Google Patents

Abstract

Provided is a demand control system that does not require wiring work and can be introduced at a lower cost. The demand control system 1 of the present invention calculates a predicted value of power demand with a power measuring device 5 that measures the amount of power of a load device 3, and gives a control command when it is determined that the predicted value exceeds a target value. A demand control system comprising a monitoring device (10) for transmitting and an operating device (20) for operating load equipment in response to a control command, wherein the control command is transmitted and received by wireless communication, and the operating device is a control circuit (21). ) and a power supply circuit 22 for supplying power to the control circuit, the control circuit includes a wireless communication unit 213 that receives control commands from the monitoring device by wireless communication, and data storage that stores the received control commands. The power supply circuit includes a unit 212, a control unit 211 that processes control commands, and a contact unit 214 that operates load devices according to instructions from the control unit, and includes a solar cell panel 211 and a secondary battery ( 223) and a charging unit 222 for charging a part of the power generated by the solar cell panel to the secondary battery, and the power supply circuit supplies the power generated by the solar cell panel to the control circuit and charges the secondary battery with surplus power. , When power cannot be supplied from the solar panel, power is supplied from the secondary battery to the control circuit.

Description

demand control system

The present invention relates to a demand control system, and more particularly, to a demand control system capable of adjusting demand power by monitoring the amount of power used in a building.

When contracting with an electric power company for electric power used in a factory or building, etc., a basic electric charge is usually set based on demand electric power (also called demand electric power). Demand power means the average power consumption per unit time period (usually set to 30 minutes), and the amount of power consumption is integrated from the start of the unit time period, and the accumulated amount of power at the end of the unit time period is divided by the unit time period. is calculated as

The basic electric charge for the electric power consumer is calculated based on the electric power demand at which the electric power consumption of the electric power consumer is the largest in the year. A variety of monitoring systems or control systems for monitoring the demanded power have been developed from the point where the base rate can be reduced by suppressing this maximum demanded power to a low level.

In Patent Document 1, as a demand control system, equipment related to power demand is set as a control target, power demand is calculated from the amount of power used, and operation of the equipment is stopped or consumed so as not to exceed a target value It is disclosed to reduce power.

Japanese Unexamined Patent Publication No. 2011-193639

Conventionally, when introducing such a demand control system into an existing facility, it is necessary to newly install an electric power measurement device, a monitoring device for monitoring the amount of power used, and an operating device for controlling equipment such as an air conditioner. In addition, it is necessary to supply power to such devices or to perform wiring work so that devices can communicate with each other.

In particular, since the outdoor unit of the air conditioner is installed outside the building, the cost of electrical wiring and communication wiring for installing the operating device close to the outdoor unit is high. The high cost of this wiring work has been one of the factors that have made power consumers hesitant to introduce a demand control system.

The present invention has been made in view of the above-described problems, and is intended to simplify wiring work and provide a demand control system that can be introduced at a lower cost.

According to the demand control system of the present invention, a power measuring device that measures the amount of power of a load device and transmits a measured value of the amount of power, and a predicted value of power demand based on the measured value received from the power measuring device A monitoring device that calculates and determines whether or not the predicted value exceeds a target value and transmits a control command when it is determined that the predicted value exceeds the target value, and is connected to the load device and receives the control command from the monitoring device. A demand control system having an operating device that receives and operates the load device in response to the control command, wherein the control command is transmitted and received by wireless communication, and the operating device includes a control circuit and power to the control circuit. The control circuit includes a wireless communication unit that receives the control command from the monitoring device by wireless communication, a data storage unit that stores the received control command, and a control command that processes the control command. A control unit and a contact unit for manipulating the load device according to instructions of the control unit, wherein the power supply circuit includes a solar cell panel, a secondary battery, and a charging unit for charging a part of power generated by the solar cell panel to the secondary battery. The power circuit supplies the generated power of the solar cell panel to the control circuit, charges surplus power to the secondary battery, and when the generated power cannot be supplied from the solar cell panel, the secondary It is solved by supplying power to the control circuit from a battery.

According to the configuration described above, power necessary for operating the operating device can be supplied from the solar battery or the secondary battery. In addition, the operating device may receive a monitoring device and a control command through a wireless communication device. Wiring work for supplying power to the operating device or transmitting information is simplified, and a demand control system can be introduced at a lower cost.

In addition, describing a configuration suitable for the demand control system of the present invention, the operating device has a primary battery, and the power supply circuit cannot supply power generated from the solar cell panel and the secondary battery is discharged. It is only necessary to supply power to the control circuit from the primary battery.

With the above structure, for example, even if power cannot be supplied from the solar cell due to continuous rain and the secondary battery is also discharged, it is possible to switch to the primary battery and supply power to the control circuit, so that the operation device can be operated for a longer period of time. there is.

[0030] Further, if a configuration suitable for the demand control system of the present invention is described, the operating device may have a magnet on its outer surface, and may be attached to the load device by the magnet.

With the above configuration, it is possible to attach the operating device to the load device more easily than, for example, in the case of screwing the operating device to the load device. In addition, the operating device can be disposed at a position suitable for the solar cell panel of the operating device to receive light.

In addition, a configuration suitable for the demand control system of the present invention is described, an environmental information measuring device for measuring environmental information of a room in which the load device is installed and transmitting the measured environmental information to the monitoring device, the monitoring device comprising: If it is determined that the predicted value exceeds the target value, a control command based on the environmental information received from the environmental information measuring device may be transmitted.

With the above configuration, it is possible to control the load device based on the measurement result of the environmental information.

In addition, describing a configuration suitable for the demand control system of the present invention, the environmental information measuring device has a temperature sensor for measuring temperature and a humidity sensor for measuring humidity, and the environmental information is obtained by the temperature sensor and the humidity sensor. What is necessary is just to include the acquired temperature and humidity information.

With the above configuration, the demand control system can control the load device based on the indoor temperature and humidity.

In addition, describing a configuration suitable for the demand control system of the present invention, the environmental information measuring device has an illuminance sensor for measuring illuminance or a carbon dioxide sensor for measuring the concentration of carbon dioxide, and the environmental information is the illuminance measured by the illuminance sensor. Alternatively, information on the concentration of carbon dioxide measured by the carbon dioxide sensor may be included.

With the above configuration, the monitoring device can issue a control command based on whether or not a person is present. For example, when the illuminance in the room is below a predetermined value (lights off) or when the concentration of carbon dioxide is below a predetermined value, it is determined that there is no person in the room (absence), and the operation of the load device is stopped. When it is determined that there is a person indoors, load equipment is adjusted (for example, in the case of an air conditioner, the driving capacity of the outdoor unit is lowered) to reduce power consumption.

In addition, if a configuration suitable for the demand control system of the present invention is described, the environmental information measuring device may include a beacon receiver that receives a beacon signal, and the environment information may include information of the beacon signal received by the beacon receiver. .

With the above configuration, it is possible to detect the presence of a person in the room by receiving a beacon signal, so that when the beacon signal is not received, it is determined that there is no person in the room and the operation of the load device can be stopped. In addition, when a beacon signal is received, it is determined that there is a person present, and load devices are adjusted to reduce power consumption.

ADVANTAGE OF THE INVENTION According to the demand control system of this invention, wiring work for supplying electric power to an operating device, or transmitting and receiving information, is simplified, and a demand control system can be introduced at a lower cost.

1 is a configuration diagram showing the entire demand control system of the present embodiment.
2A is a diagram showing the hardware configuration of the monitoring device.
2B is a diagram showing the hardware configuration of the operating device.
2C is a diagram showing the hardware configuration of the environmental information measuring device.
3A is an explanation showing power demand in the case where a demand control system is not introduced.
3B is an explanatory diagram showing power demand in the case of using a demand control system.
Fig. 4A is a top view of the operating device viewed from above.
4B is a side view of the operating device viewed from the side.
Fig. 5 is a flowchart showing a process of supplying electric power by the power supply circuit of the operating device.

<<Demand Control System>>

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described using drawings. 1 is a configuration diagram showing the entirety of a demand control system 1 installed in a building B.

The demand control system 1 includes an air conditioner 3 (load device) that adjusts temperature and humidity, and a power measuring device 5 that measures the amount of power of the entire building B including the air conditioner 3 and the like, It is composed of a monitoring device 10 that monitors the amount of power and an operating device 20 that operates the air conditioner 3 according to a control command from the monitoring device 10. In addition, an environmental information measuring device 30 for measuring temperature, humidity, etc. is installed in the room R of each floor.

The power measuring device 5, the operating device 20, the environmental information measuring device 30, and the monitoring device 10 are connected through a wired or wireless network, so that information can be transmitted and received. The monitoring device 10 is connected to an external network N such as the Internet, and can transmit/receive information to and from the manager terminal 50 at a remote location.

<<load device>>

The air conditioner 3 as a load device in this embodiment is composed of an indoor unit 3a and an outdoor unit 3b. The indoor unit 3a is installed inside each room R to adjust the indoor temperature or humidity. The outdoor unit 3b is connected to the indoor unit 3a via refrigerant pipes and wires, and is installed outdoors. In the air conditioner 3, by directly manipulating the indoor unit 3a, it is possible to turn ON/OFF the power, change the set temperature or humidity, and the like. In addition, the air conditioner 3 can adjust the power used by turning ON/OFF the power using the outdoor unit 3b. In addition, the amount of power used can be adjusted also by controlling the drive capability of the outdoor unit 3b. For example, by tightening the output of the compressor or the like of the outdoor unit 3b, the time required for the indoor temperature to reach the set temperature is delayed, thereby reducing power consumption. As a result, the temperature in the room may rise or fall. In this embodiment, the air conditioner 3 is used as the load device, but this is an example, and the load device may be a lighting fixture, a refrigerating device, or a refrigerating device.

<<power measuring device>>

As described above, the power measurement device 5 is capable of measuring the amount of power of the entire building B. The power measuring device 5 is a power meter capable of digitally measuring the amount of power and is called a smart meter, and is installed in the power receiving device 40 . The power measuring device 5 is connected to the monitoring device 10 through a network, and transmits the measured value of the measured power consumption (power amount) to the monitoring device 10 as digital data. A network used for transmission of measurement values may be wired or wireless.

When using a wireless network, wireless communication of a Low Power Wide Area (LPWA) method may be used. The LPWA system is an international communication technology that realizes long-distance communication by suppressing power consumption as much as possible, and is a UNB (ultra narrow band) communication network with a transmission capacity per transmission of 100 bytes or less. As the LPWA method, there is, for example, cellular LPWA, SIGFOX, or LoRaWAN. By adopting this communication method, it is possible to realize wireless communication of the order of several kilometers. Moreover, you may transmit using wireless communication by Wifi (registered trademark) or BlueTooth (registered trademark).

<<Monitoring device>>

The monitoring device 10 is a device that monitors the amount of power of the entire building B, such as the air conditioner 3. The monitoring device 10 issues a control command to the operating device 20 to operate the air conditioner 3 when the predicted value of the power demand calculated from the amount of power received from the power measuring device 5 is likely to exceed a target value. do lowering

Here, the effect of reducing electric power charges by the demand control system 1 will be described using FIGS. 3A and 3B.

The basic rate of electricity contracted with the power company is determined by the largest value in the maximum demand electricity generated in the past year.

More specifically, the power demand is an average value of power consumed for 30 minutes (refer to the graph on the left of FIG. 3A). This power demand is added up each month, and the maximum value of the power demand for one month becomes the maximum power demand (demand) for that month (refer to the graph in the middle of FIG. 3A). The contracted power is determined based on the largest value of the maximum demand power generated in the past year (see the graph on the right of FIG. 3). Therefore, when a high maximum demand power is recorded even for a month, a contract is made with the maximum demand power. That's why you pay a relatively high base rate for other months when you don't use that much power.

By using the demand control system 1, the power demand is controlled so that the maximum power demand does not increase temporarily, the peak cut is performed, and the annual maximum demand power is leveled to lower the basic rate, thereby reducing the electricity rate. are doing

Specifically, the monitoring device 10 calculates the power demand for each unit time limit (30 minutes) from the amount of power, and when the predicted value of this power demand is likely to exceed the target value, a control command is sent to the operating device 20. out, the load equipment such as the air conditioner 3 is stopped, and the peak cut is executed.

For example, the monitoring device 10 calculates the average power consumption (predicted value) when the air conditioner is used in the same way at the time point when 15 minutes have elapsed. If the integrated power already being used exceeds half of 1000 kW (target value), there is a possibility that the predicted value exceeds the target value. The monitoring device 10 compares the predicted value with the target value, and determines whether the predicted value exceeds the target value. When it is determined that the target value is exceeded, the monitoring device 10 transmits a control command for lowering the amount of power used to the operating device 20 .

The control command is a signal instructing the operating device 20 to lower the power load by the air conditioner 3, and is, for example, a command to stop the operation of the air conditioner 3. Further, the control command is not limited to simply stopping the operation, but may lower the driving capability of the outdoor unit 3b. For example, the output of the compressor or the like of the outdoor unit 3b that sends out cold air or the like is forcibly reduced. By reducing the output, it takes longer than usual for the indoor temperature to reach the set temperature of the air conditioner 3 (reach time), but the amount of power used is reduced.

In addition, as shown in Fig. 1, the monitoring device 10 monitors the amount of power used in the entire building B, and the presence of people in each room R by the environmental information measuring device 30 described later. is detecting When it is determined by the environmental information measuring device 30 that there is no person, a control command for stopping the air conditioner 3 in the room is issued. When a person is detected, the outdoor unit 3b connected to the indoor unit 3a of the room may be operated to issue a control command to lower its driving capability.

In this way, the control command is set according to the season, the outside air temperature, the temperature or humidity of the room R, and the presence or absence of people in the room.

As shown in FIG. 2A, the monitoring device 10 has a CPU 11 as a data arithmetic/control processing device, ROM/RAM 12 and HDD 12A (or SSD) as a storage device, and information with other devices. It is a computer equipped with a communication device 13 that transmits and receives data. In addition, the monitoring device 10 has an input/output device 14 such as a keyboard or a monitor. The storage device of the monitoring device 10 stores a program for calculating a predicted value of the power demand or comparing it with a target value, in addition to a main program that functions as a computer. In addition, the received power amount and environment information are recorded in the storage device. When the stored program is executed by the CPU, the function of the monitoring device 10 is exhibited.

The monitoring device 10 has a communication device 13 that communicates with other devices via a wired or wireless network. In addition, the monitoring device 10 is equipped with a radio communication device 13a in order to transmit and receive data with the operating device 20 wirelessly. The wireless communication device 13a is capable of communication in a wireless communication system of the LPWA system. In addition, the monitoring device 10 can communicate by wire through the communication device 13, and can be connected to the manager terminal 50 via the Internet. Therefore, the system manager changes the expression used when the monitoring device 10 obtains the predicted value, the content of the control command transmitted to the operating device 20, and various parameters to operate the demand control system 1 from a remote location. it is possible

<<Operating device>>

The operating device 20 is a device that controls the driving ability of the outdoor unit 3b. The operating device 20 is connected to the outdoor unit 3b of the air conditioner 3 by wire, and is connected to the monitoring device 10 by wireless. The operating device 20 operates the air conditioner 3 in response to a control command received from the monitoring device 10 . For example, when receiving a control command to stop the air conditioner 3 from the monitoring device 10, the operating device 20 turns off the power of the outdoor unit 3b to stop the air conditioner 3. When receiving a control command for lowering the driving capacity of the air conditioner 3, the operating device 20 operates the outdoor unit 3b to lower the output of the compressor in the outdoor unit 3b, for example.

The operating device 20 is a computer composed of a control circuit 21 and a power supply circuit 22 that supplies power to the control circuit 21, as shown in FIG. 2B. The control circuit 21 transmits and receives information data between a CPU 211 (control unit) as a data arithmetic and control processing device, a RAM/ROM 212 (data storage unit) as a storage device, and the monitoring device 10 and the like. A wireless communication device 213 (wireless communication unit) that performs the operation and a contact circuit 214 (contact unit) that operates the air conditioner 3 are provided.

In the storage device of the operating device 20, a program for processing control commands received from the monitoring device 10 is stored in addition to a main program that functions as a computer. When the stored program is executed by the CPU 211, the function of the operating device 20 is exerted.

The operating device 20 has a wireless communication device 213 that communicates with the monitoring device 10 or the inspector's portable terminal via a wireless network. As the wireless communication device 213, the operating device 20 is equipped with a wireless communication unit capable of communicating with the monitoring device 10 in the LPWA system to transmit and receive information data. Also, this wireless communication unit may be a wireless LAN module such as WiFi (registered trademark).

In addition, the operating device 20 is equipped with a Bluetooth (registered trademark) unit as the wireless communication device 213 apart from the LPWA system wireless communication unit. The manager of the system can connect a mobile terminal such as a smartphone and the operation device 20 via Bluetooth (registered trademark) to confirm or change the setting information of the operation device 20. By connecting the mobile terminal and the operating device 20 by wireless communication, data exchange can be performed easily without preparing a connection means such as a cable.

The contact circuit 214 of the operating device 20 is composed of four contacts, and the operating device 20 controls the relay based on a control command to operate the air conditioner 3 (more specifically, the outdoor unit 3b). It is possible to manipulate. In addition, the number of contacts of the contact circuit is not limited to four, and is increased or decreased as necessary.

As described above, the power supply circuit 22 is a device that supplies power to the control circuit 21, that is, the CPU 211, the RAM/ROM 212, the wireless communication device 213, and the contact circuit 214, It is composed of a solar cell panel 221, a charging circuit 222 (charging unit), a lithium ion secondary battery 223 (secondary battery), and a lithium primary battery 224 (primary battery).

The solar cell panel 221 is a panel for generating power with sunlight. Also, the charging circuit 222 is a device that charges the lithium ion secondary battery 223 with a part of the power generated by the solar cell panel 221 .

The lithium ion secondary battery 223 is a storage battery and is a battery that can be used repeatedly by being charged. The secondary battery to be used is not limited to the lithium ion secondary battery 223, and other secondary batteries such as a lithium ion polymer secondary battery and a nickel-hydrogen storage battery may be used.

Since the power supply circuit 22 is constituted by the solar cell panel 221 and the lithium ion secondary battery 223, it is possible to install the operating device 20 without doing electrical wiring work to supply power. has been

In addition, when there is insufficient illumination during the day, for example, when cloudy or rainy days last for several days, there is a possibility that the solar cell panel 221 cannot generate electricity and power cannot be supplied from the lithium ion secondary battery 223 either. there is For this reason, the power supply circuit 22 has the lithium primary battery 224 as a backup power supply. The power supply circuit supplies power from the lithium primary battery 224 to the control circuit 21 when the power from the lithium ion secondary battery 223 is insufficient.

The lithium primary battery 224 is a chemical battery that can only discharge DC power, and can be replaced. The primary battery may be a dry battery such as a manganese dry cell or an alkali manganese dry cell.

Even when the electric power from the lithium ion secondary battery 223 is insufficient, electric power can be supplied from the lithium primary battery 224 to the control circuit 21, and the operating device 20 can be operated continuously for a longer period of time.

The external appearance of the operating device 20 is shown to FIG. 4A and FIG. 4B. 4A is a plan view of the operating device 20 viewed from above, and FIG. 4B is a side view of the operating device 20 viewed from the side. As shown in FIG. 4B, the operating device 20 has a casing 20a formed in a quadrangular pyramid shape, and inside the casing 20a, a control circuit 21, a charging circuit 222, a lithium ion secondary battery 223, A lithium primary battery 224 is accommodated. A cable 25 for connection with the air conditioner 3 extends from the side of the casing 20a.

In addition, in the operating device 20, a solar cell panel 221 is arranged on the upper surface 20b of the casing 20a. In addition, a plate-shaped magnet 24 is provided on the bottom surface 20c of the casing 20a, and by using the magnet 24, it is possible to detachably attach to the casing of the outdoor unit 3b. As the magnet, a powerful magnet such as a neodymium magnet may be used.

The operating device 20 can be attached more easily to the outdoor unit 3b than in the case of screwing. In addition, since it can be easily detached, replacement of the operating device 20 and replacement of the lithium primary battery 224 are also easy.

Using FIG. 5, a process in which the power supply circuit 22 supplies power to the control circuit 21 will be described.

During the day, power is generated by the solar cell panel 221 (S101). At this time, it is determined whether the control circuit 21 can supply sufficient power to operate (S102). When sufficient power can be supplied (Yes in S102), the power supply circuit 22 supplies the control circuit 21 with power generated by the solar cell panel 221 to the control circuit 21 (S103). At this time, it is determined whether there is surplus power (S104). When there is surplus power, the power supply circuit 22 charges the lithium ion secondary battery 223 with surplus power through the charging circuit 222 (S105).

At night, since no electricity is generated by the solar cell panel 221, sufficient power cannot be supplied to the control circuit 21 (No in S102). Therefore, it is determined whether to supply the lithium ion secondary battery 223 (S106). If it is possible to supply (Yes in S106), the power supply circuit 22 supplies the electric power charged in the lithium ion secondary battery 223 to the control circuit 21 (S107).

When power generated by the solar cell panel 221 cannot be supplied and sufficient power cannot be supplied from the lithium ion secondary battery (No in S106), power is supplied from the lithium primary battery 224 to the control circuit 21. (S108).

<<environmental information measuring device>>

The demand control system 1 has an environmental information measuring device 30 . The environmental information measurement device 30 is a device that measures environmental information of the room R in which the air conditioner 3 is installed and transmits data of the measured environmental information to the monitoring device 10 via a network.

As shown in FIG. 2C, the environmental information measurement device 30 includes a CPU 31 as a data calculation/control processing device, a ROM/RAM 32 as a storage device, a communication device 33 for transmitting and receiving information data, It has a sensor 34 that measures environmental information and a power supply 35.

The environmental information measurement device 30 is a computer, and in addition to the main program that functions as a computer in the ROM/RAM 32 as a storage device, the measured value of the environmental information acquired by the sensor 34 is stored in the monitoring device 10. Programs for transmission and the like are stored. When the stored program is executed by the CPU 31, the function of the environmental information measuring device 30 is exhibited.

The environmental information measuring device 30 can be connected to a network through a wired or wireless communication device 33 . Moreover, when connecting to a wireless network by the wireless communication device 33a, you may use the wireless communication of the LPWA system similarly to the monitoring device 10. In addition, wireless communication may be used by Wifi (registered trademark) or BlueTooth (registered trademark). By connecting the environmental information measurement device 30 and the monitoring device 10 via a wireless network, wiring work for communication such as installing a LAN cable or the like for wired connection is not required.

In addition, by connecting a portable terminal such as a smartphone and the like according to the standard of short-distance wireless communication of BlueTooth (registered trademark), the administrator of the system can view the setting information of the environmental information measuring device 30 and the like.

The environmental information measuring device 30 may be equipped with a USB (Universal Serial Bus) terminal, and transmit/receive environmental information stored in a storage device to a PC or the like by connecting the USB terminal to a USB port of a PC or the like.

In addition, you may use this USB terminal as a power supply device 35. That is, power for operating the environmental information measuring device 30 is acquired via the USB terminal. For example, power is obtained from an outlet by using a charger having a USB port. The power supply device 35 of the environmental information measuring device 30 may be a primary battery such as an alkaline battery or a lithium battery, a secondary battery such as a NiCd battery, a NiMH battery, or a Li battery, an AC adapter, or the like.

The sensor 34 includes a temperature sensor 34a for measuring temperature, a humidity sensor 34b for measuring humidity, an illuminance sensor 34c for measuring illuminance, and a carbon dioxide sensor 34d for measuring the concentration of carbon dioxide.

The environmental information measuring device 30 measures the temperature and humidity using the temperature sensor 34a and the humidity sensor 34b and transmits the temperature and humidity information to the monitoring device 10 . The monitoring device 10 can grasp the temperature and humidity of each room R, and can issue a control command considering the temperature and humidity. For example, when the indoor temperature is significantly lower or higher than the outdoor air temperature, the power load can be reduced by issuing a control command so that the indoor temperature approaches the outdoor air temperature. In addition, by measuring the temperature and humidity after issuing the control command, it is possible to confirm whether the air conditioner 3 is normally controlled by the operating device 20 or not. In addition, the environmental information measuring device 30 may be installed outside the room R as well as inside the room to measure the outside temperature or humidity.

In addition, the environmental information measuring device 30 uses the illuminance sensor 34c and the carbon dioxide sensor 34d to measure the indoor illuminance and the carbon dioxide concentration, and transmits information on the illuminance and the carbon dioxide concentration to the monitoring device 10. . The monitoring device 10 can determine, for example, whether lighting is turned on by grasping the intensity of illumination. When the light level is low, there is a high possibility that no one is in the room because the lights are not turned on. Therefore, even if the air conditioner 3 is stopped, the influence is small, and the monitoring device 10 can reduce the amount of power used by issuing a control command to stop the air conditioner 3 in a room with low illumination.

Similar to the carbon dioxide concentration, when the measured carbon dioxide concentration is low, it can be determined that there is no person in the room. In addition, when the carbon dioxide concentration increases, it can be determined that there is a person in the room. Therefore, the monitoring device 10 turns off the power of the air conditioner 3 in the room in which the absence is determined, and issues a control command to lower the driving capability of the outdoor unit 3b in the room R in which the person is detected, thereby lowering the amount of power used. It becomes possible.

In addition, the environmental information measuring device 30 may further include a beacon receiver 36 . When the user of the building B always carries the beacon oscillator 37, it is possible to determine whether or not there is a user in the vicinity of the environmental information measuring device 30 by a beacon signal. A control command can be issued more accurately in that a person's detection can be directly determined according to the presence or absence of a beacon signal, instead of indirectly determining a person's detection, such as illuminance or carbon dioxide concentration.

In the above, the demand control system 1 of the present embodiment has been described using the drawings. The demand control system 1 has a power supply circuit 22 equipped with a solar cell panel 221 in order to operate an operating device 20 that operates an air conditioner 3 as a load device. Moreover, the operating device 20 and the monitoring device 10 are connected by a wireless network. Therefore, wiring work for power and communication is simplified, and it becomes possible to introduce the demand control system 1 at a lower cost.

In addition, the embodiment described above is only an example for facilitating understanding of the present invention, and does not limit the present invention. While this invention can be changed and improved without departing from the meaning, it goes without saying that equivalents are included in this invention.

One… Demand control system N… network
3... Air conditioner (load device) 3a... indoor unit
3b... Outdoor unit 5... power measuring device
10... monitoring device 11 . . . CPU
12... ROM/RAM 12A... HDD
13... communication device 13a... radio communication device
14... input/output device 20 . . . operating device
20a... Casing 20b... upper face
20 c... bottom surface 21 . . . control circuit
211... CPU (control unit) 212 . . . ROM/RAM (data storage unit)
213... wireless communication device (wireless communication unit) 214 . . . Contact circuit (contact part)
22... power circuit 221 . . . solar panel
222... Charging circuit (charging part)
223... Lithium ion secondary battery (secondary battery)
224... Lithium primary battery (primary battery) 24 . . . magnet
25... cable 30... Environmental information measuring device
31... CPU 32... ROM/RAM
33... communication device 33a... radio communication device
34... sensor 34a... temperature Senser
34b... Humidity sensor 34c... light sensor
34d... carbon dioxide sensor 35 . . . power unit
36... beacon receiver 37 . . . beacon oscillator
40... power receiving device 50 . . . terminal for administrator

Claims (7)

a power measuring device that measures the amount of power of a load device and transmits a measured value of the amount of power;
A monitoring device that calculates a predicted value of power demand from the measured value received from the power measuring device, determines whether or not the predicted value exceeds a target value, and transmits a control command when it is determined that the predicted value exceeds the target value. and,
an operating device connected to the load device, receiving the control command from the monitoring device, and operating the load device in response to the control command;
As a demand control system having a,
The control command is transmitted and received by wireless communication,
The operating device is
a control circuit and a power supply circuit for supplying power to the control circuit;
The control circuit,
a wireless communication unit that receives the control command from the monitoring device by wireless communication;
a data storage unit for storing the received control command;
a control unit for processing the control command;
a contact unit for operating the load device according to instructions from the control unit;
with,
The power circuit,
A solar cell panel, a secondary battery, and a charging unit for charging a part of the power generated by the solar cell panel to the secondary battery,
The power circuit supplies the generated power of the solar cell panel to the control circuit and charges surplus power to the secondary battery;
and supplying power to the control circuit from the secondary battery when the generated power cannot be supplied from the solar cell panel. 2. The method according to claim 1, wherein the operating device has a primary battery, and the power supply circuit is configured to supply electric power from the primary battery to the control circuit when power generated from the solar panel cannot be supplied and the secondary battery is discharged. Demand control system, characterized in that for supplying. The demand control system according to claim 1 or 2, wherein the operating device has a magnet on an outer surface thereof and is attached to the load device by the magnet. The method according to any one of claims 1 to 3, comprising an environmental information measuring device that measures environmental information of a room in which the load device is installed and transmits the measured environmental information to the monitoring device;
The demand control system according to claim 1 , wherein the monitoring device transmits a control command based on the environmental information received from the environmental information measurement device when determining that the predicted value exceeds the target value. The method of claim 4 , wherein the environmental information measuring device has a temperature sensor for measuring temperature and a humidity sensor for measuring humidity, and the environment information includes temperature and humidity information acquired by the temperature sensor and the humidity sensor. Demand control system characterized in that. The method of claim 4 or 5, wherein the environmental information measuring device has an illuminance sensor for measuring illuminance or a carbon dioxide sensor for measuring the concentration of carbon dioxide, and the environmental information is the illuminance measured by the illuminance sensor or the carbon dioxide sensor A demand control system comprising information on the measured concentration of carbon dioxide. The method according to any one of claims 4 to 6, wherein the environmental information measurement device has a beacon receiver for receiving a beacon signal, and the environment information includes information on the beacon signal received by the beacon receiver. Demand control system with.

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