KR102443443B1 - System for managing building energy - Google Patents

Abstract

An efficient building energy management system of the present invention includes: a server including a communication unit for transmitting and receiving data with a plurality of modules, a storage unit for storing data received from the plurality of modules, and a control unit for controlling devices connected to each module through the plurality of modules; a first module connected to a first device, controlling the first device, and communicating with the server in a first communication method; and a second module connected to a second device, controlling the second device, and communicating with the server in a second communication method different from the first communication method. The server transmits first control data for controlling the first device to the first module and transmits second control data for controlling the second device to the second module, and the first control data may include a first control command and a first delay for delaying a time at which the first device is controlled by the first control command.

Description

Building Energy Management System {SYSTEM FOR MANAGING BUILDING ENERGY}

The present invention relates to a building energy management system, and more particularly, to a building energy management system for regulating the control of devices disposed in a building.

Recently, many measures to control carbon emissions have been in the spotlight. With respect to carbon emissions, there is a growing need to efficiently consume and manage the energy of devices deployed in buildings, in particular. A building energy management system is needed to comprehensively manage the energy of a building by grafting efficient IoT technology and machine learning technology to devices deployed in buildings.

One object of the present invention relates to a building energy management system for efficiently controlling devices disposed in a building.

In the building energy management system for managing the energy of a building by collecting information of modules connected to a plurality of devices disposed in a building, the building energy management system according to an embodiment includes a communication unit for transmitting and receiving data with a plurality of modules, the plurality of a server including a storage unit for storing data received from a module of a first module connected to a first device to control the first device, and to communicate with the server in a first communication method; and a second module connected to a second device to control the second device, and to communicate with the server in a second communication method different from the first communication method, wherein the server is configured to control the first device sending first control data to the first module, and sending second control data for controlling the second device to the second module, wherein the first control data includes a first control command and the first control command and a first delay for delaying the time at which the first device is controlled by the .

Here, the server transmits a first reference signal to the first module, transmits a second reference signal to the second module, and a first response to the first reference signal from the first module at a first time Receives a first response signal, receives a second response signal that is a response to the second reference signal from the second module at a second time, and receives the first response signal based on a difference between the first time and the second time You can set the delay.

Here, the first module transmits first execution data including the first delay to the server in response to the first control data, and the second module sends a response to the second control data to the server to transmit the second performance data, and the server may simultaneously process the first performance data and the second performance data at a point in time based on the first delay included in the received first performance data.

Here, the first module may control the first device based on the first control command after a time corresponding to the first delay has elapsed from a point in time when the first control data is received.

Here, the first control command may include information for controlling at least one of power, illuminance, temperature, and humidity of the first device.

Here, the first communication method may be Wi-Fi or Bluetooth, and the second communication method may be ZigBee.

Here, the second control data includes a second control command and a second delay for delaying a time at which the second device is controlled by the second control command, and the second delay includes the first delay and the second delay. It may be set based on a first transmission time, which is a time point at which the first control data is transmitted, and a second transmission time, which is a time point at which the second control data is transmitted.

In the building energy management method according to an embodiment, in the building energy management method for managing the energy of a building by collecting information of modules connected to a plurality of devices arranged in a building, transmitting a first reference signal to a first module ; transmitting a second reference signal to a second module; receiving a first response signal that is a response to the first reference signal from the first module at a first time; receiving a second response signal that is a response to the second reference signal from the second module at a second time; setting a first delay based on a difference between the first time point and the second time point; and generating a first control command for controlling a first device and first control data including the first delay, and transmitting the first control data to the first module.

According to an embodiment of the present invention, a building energy management system for efficiently controlling devices disposed in a building may be provided.

1 is a view for explaining a device and a module disposed in a building.
2 is an environmental diagram of a building energy management system according to an embodiment.
3 is a diagram for describing pattern data according to an exemplary embodiment.
4 is a diagram illustrating an example of pattern data according to an embodiment.
5 is a diagram for explaining control data and delay measurement according to an embodiment.

The embodiments described in this specification are for clearly explaining the spirit of the present invention to those of ordinary skill in the art to which the present invention belongs, so the present invention is not limited to the embodiments described in this specification, and the The scope should be construed to include modifications or variations without departing from the spirit of the present invention.

The terms used in this specification have been selected as widely used general terms as possible in consideration of the functions in the present invention, but they may vary depending on the intention, precedent, or emergence of new technology of those of ordinary skill in the art to which the present invention belongs. can However, when a specific term is defined and used in an arbitrary sense, the meaning of the term will be separately described. Therefore, the terms used in this specification should be interpreted based on the actual meaning of the terms and the contents of the entire specification, rather than the names of simple terms.

The drawings attached to this specification are for easily explaining the present invention, and the shapes shown in the drawings may be exaggerated as necessary to help understand the present invention, so the present invention is not limited by the drawings.

In the present specification, when it is determined that a detailed description of a known configuration or function related to the present invention may obscure the gist of the present invention, a detailed description thereof will be omitted if necessary.

1 is a view for explaining a device and a module disposed in a building. Figure 1 (a) is a view for explaining a device disposed in a building, Figure 1 (b) is a view for explaining a module connected to the device.

Referring to FIG. 1A , a plurality of devices disposed in a building is illustrated. In general, a plurality of devices including an entrance device, a lighting device, a heating and cooling device, a circulation device, and a power supply device are disposed inside and outside a building.

The access device disposed in the building may include a door lock, a door lock device, an automatic door device, an automatic revolving door, or an authentication device through supplementation. The lighting device included in the building may include a device for outputting light, such as a light bulb, an LED light, an emergency light, and some of them may have illuminance adjusted.

The air conditioning unit disposed in the building may include an air conditioner, a heater, a heater, a radiator, etc. for controlling the temperature of the room, some of which may also adjust the humidity of the room. The circulation device disposed in the building may include a device capable of circulating air in the building, such as a circulator and a fan. A power supply device disposed in a building may include a power supply, an outlet, and the like.

Referring to FIG. 1( b ), a module connected to an outlet disposed in a building is illustrated. In FIG. 1(b) , an example of the device is taken as an outlet, but the device that can be connected to the module may be each device included in an access device, a lighting device, a heating/cooling device, a circulation device, and a power supply device.

The module may be connected to the device, collect information related to the device's energy, and control the device. Specifically, the module may be connected to a wire or circuit inside the device to collect data and transmit the collected data to a server. A detailed description of the module is described in FIG. 2 .

2 is an environmental diagram of a building energy management system according to an embodiment.

Referring to FIG. 2 , a building energy management system according to an embodiment may include a server 1000 , one or more modules, and one or more devices.

The modules 100 and 200 may be connected to a device as shown in FIG. 1(b) to collect device data. Specifically, the module may collect information related to the energy of the device.

According to one embodiment, the module may collect voltage, current, wattage or power factor information of the device. The module may collect the parameters in real time or periodically or aperiodically according to a control command of the server 1000 . In addition, the module can also collect information about whether the device is arcing and the arc current when arcing occurs.

According to another embodiment, the module may collect information about the control of the device. Specifically, the module may collect information about which device was controlled by whom, where, for which item, and with what content.

For example, for a lighting device in a room, the module may collect information about whether the lighting device was powered off by a person inside the room at one point in time. Also, for example, with respect to the air conditioner, the module may collect information about the fact that the power of the air conditioner is turned off by the reservation function of the air conditioner at one point in time.

Also, for example, with respect to the heater of the room, the module may collect information about the decrease in the set temperature of the heater by the user terminal outside the room at one point in time. Also, for example, for an outlet in a room, the module may collect information about whether the power of the outlet is turned off by an external device at one point in time.

The server 1000 is a central component of the building energy management system, and may serve as an overall control unit of the building energy system.

The server 1000 may be connected to the first module 100 and the second module 200 . Also, the server 1000 may be connected to the first module 100 and the second module 200 to exchange communication signals.

Alternatively, when a communication function exists in the device, the server 1000 may transmit and receive a communication signal directly to each device without passing through the module. However, since the device rarely has a communication function, an example in which the server 1000 collects device information through a module will be mainly described herein.

Although not shown in FIG. 1 , a device for relaying their communication may exist between the server 1000 and the first module 100 and the second module 200 . For example, another module exists between the server 1000 and the first module 100 , and the other module may transmit a communication signal between the server 1000 and the first module 100 .

Also, for example, a sub-server or edge computing may exist between the server 1000 and the first module 100 to transmit a communication signal between the server 1000 and the first module 100 . That is, the server 1000 and each module can communicate with each other without limiting the distance.

According to an embodiment, the server 1000 may include a control unit 1100 , a communication unit 1200 , a storage unit 1300 , and an analysis unit 1400 .

1 illustrates four components included in the server 1000, the illustrated components are not essential, and the server 1000 may have more components or fewer components. In addition, each component of the server 1000 may be physically included in one server, or may be a distributed server distributed for each function.

The controller 1100 may oversee the operation of the server 1000 . Specifically, the control unit 1100 may send a control command to the communication unit 1200 , the storage unit 1300 , and the analysis unit 1400 to execute the operations of each department.

Hereinafter, unless otherwise specified, the operation of the server 1000 may be interpreted as being performed under the control of the controller 1100 .

The communication unit 1200 may connect the server 1000 and an external device to communicate. That is, the communication unit 1200 may transmit/receive data to/from an external device. For example, the communication unit 1200 may exchange data with the first module 100 or the second module 200 .

According to an embodiment, the communication unit 1200 may receive energy information of a device connected to the module from the module. For example, the communication unit 1200 may receive energy information of the first device from the first module 100 . A detailed description thereof will be described below with reference to FIG. 3 .

The communication unit 1200 may be a communication module supporting at least one communication method among a wired communication method and a wireless communication method. For example, the communication unit may acquire data from an external device through communication methods such as WiFi, Bluetooth, Zigbee, Bluetooth Low Energy (BLE), and RFID.

The storage unit 1300 may store various data and programs required for the server 1000 to operate. The storage unit 1300 may store information obtained by the server 1000 .

For example, the storage unit 1300 may store information about the energy of the device received by the communication unit 1200 through the module. Also, the storage unit 1300 may store information on control of each device.

The storage unit 1300 may temporarily or semi-permanently store data. Examples of the storage unit 1300 include a hard disk (HDD), a solid state drive (SSD), a flash memory, a read-only memory (ROM), and a random access memory (RAM). Alternatively, there may be cloud storage or the like. However, the present invention is not limited thereto, and the storage unit 1300 may be implemented as various modules for storing data.

The storage unit 1300 may be provided in a form embedded in the wearable device 1000 or in a form detachable.

The analysis unit 1400 may analyze the data acquired by the communication unit 1200 , classify the data, and generate new data. In this case, the analysis unit 1400 may input data into the learned machine learning model and analyze data related to the device. The analysis unit 1400 may analyze the reason for controlling the device at each time point through the machine learning model. The analyzer 1400 may continuously learn the machine learning model through data input to the machine learning model.

According to an embodiment, the analysis unit 1400 may analyze or classify data about the device acquired by the communication unit 1200 . Specifically, the analyzer 1400 may analyze or classify information related to the energy of the device.

For example, the analysis unit 1400 may analyze the power status of the device by analyzing the voltage, current, amount of power, and the like of the device. In addition, the pumice unit 1400 may analyze whether an arc has occurred in the device and an arc current to analyze the arc generation status of the device.

In more detail, the analysis unit 1400 may analyze or classify information related to device control. For example, the analyzer 1400 may analyze data on which item was controlled by whom and how the device was controlled at one point in time. And the analysis unit 1400 may classify the data for the control according to the six-fold principle.

As a specific example, the analysis unit 1400 may classify the control of the device into a control subject, a control place, a control item, and a control content to generate control information according to the classification.

The analysis unit 1400 may generate pattern data including information related to energy of the device and control information according to classification. Also, the analysis unit 1400 may establish a control policy for the device thereafter based on the pattern data. The pattern data generated by the analysis unit will be described in detail below with reference to FIG. 3 .

3 is a diagram for explaining pattern data generated by a server according to an embodiment. 4 is a diagram illustrating an example of pattern data according to an embodiment.

Referring to FIG. 3 , pattern data may include energy information and control information.

The energy information included in the pattern data is information related to energy of the device, and may include power data and/or arc data.

The power data may include voltage, current, wattage and/or power factor information of the device, as shown in FIG. 4 . A device's voltage, current, wattage and power factor change over time, and the device sends time-varying information to the module. The device may transmit the corresponding information to the module in real time, periodically, only when there is a change, or aperiodically at the request of the module.

As illustrated in FIG. 4 , the arc data may include information on whether an arc is generated in the device and an arc current when an arc occurs. Arcing can be caused by external shocks and internal circuit problems in the device. The device continuously monitors for arcing and can sense arc current if an arc has occurred. The device may transmit the arc-related information to the module in real time, periodically, only when there is a change, or aperiodically at the request of the module.

The control information included in the pattern data is information related to control of the device, and may include information related to a control subject, a control location, a control item, and/or control contents.

As shown in FIG. 4 , the controlling entity that controls the device may be a person, an application, an internal device, or an external device. Specifically, the device may be controlled by a person operating a switch, by an application on the user terminal, by a reservation system inside the device, or by an external device.

Also, the place where the device is controlled may be a place where the controlling subject is located according to the controlling subject. Specifically, when the controlling subject is a person, the controlling place becomes a place where the switch is disposed, and when the controlling subject is an application, the controlling place may be determined based on GPS sensing information of the user terminal. Also, when the controlling subject is an internal device, the controlling place may be a place where the device is located, and when the controlling subject is an external device, the controlling place may be a place where the external device is located.

Also, the control items and contents for controlling the device may vary depending on the type of the device. For example, when the device is an air conditioner, the control item may be power, temperature, and humidity, and the control content may be on, off, increase, or decrease. Also, for example, when the device is a lighting device, the control items may be power and illuminance, and the control contents may be on, off, increase, or decrease.

Referring to FIG. 4 , the server 1000 may generate pattern data according to time. The pattern data of FIG. 4 is pattern data generated by the server 1000 for the lighting device.

For example, the server 1000 may generate pattern data including control information and energy information of the device according to the first time point (01:00). In this case, the control information at the first time may include information about the person in the room 1 turning on the lighting device. In addition, at this time, the energy information at the first time point may include information about that the lighting device has a voltage, b current, c wattage, and d power factor, and no arc is generated at the first time point.

Also, the pattern data may include control information and energy information of the device according to the second time point (02:00). In this case, the control information of the second time point may include information about the increase in the illuminance of the lighting device by the user terminal in the room 1. Also, at this time, the energy information at the second time point may include information about whether the lighting device has e voltage, f current, g wattage, and power factor h at the second time point, and no arc is generated.

The server 1000 may analyze the pattern data to establish a policy for building energy thereafter. Specifically, by analyzing the energy information of the device according to the control information, it is possible to establish a policy by which the device is to be controlled at a specific point in time. Also, specifically, by analyzing the energy information of the device according to the control information, it is possible to establish a policy by which the device is to be controlled according to a specific control subject.

For example, based on the information included in the pattern data, if the server 1000 determines that the lighting device is turned on by a person at 9:00 am, the server 1000 automatically turns on the lighting device every 9:00 am You can set the control for the lighting device so that it can be turned on.

Also, for example, based on the information included in the pattern data, when the server 1000 determines that the set temperature reduction control is repeatedly performed on the air conditioner after the indoor temperature becomes 25 degrees or more, the server 1000 is You can adjust the set temperature so that the temperature does not exceed 25 degrees.

Also, after establishing the policy, the server 1000 may transmit a control command to each device through the module according to the policy.

For example, the server 1000 may transmit a control command for turning off the power of the lighting device and turning off the power of the air conditioner to each module at 6 pm according to the leave policy. In this case, each module may control the power of a device connected to each module to be turned off based on the received control command.

Also, for example, the server 1000 may transmit a control command for setting the set temperature of the heater to 24 degrees Celsius for a certain period according to the winter policy to each module. In this case, each module may control the set temperature of the heater connected to each module to be 24 degrees based on the received control command.

When the server 1000 transmits control data including a control command to each module according to a policy, the time for controlling the device may vary depending on the communication method of each module. Specifically, the first module 100 communicates with the server 1000 in a first communication method, and the second module 200 communicates with the server 1000 in a second communication method that is different from the first communication method. can

The reason that the communication method of the module is different may be due to a device connected to the module. Alternatively, a communication method may be different for each location where each device is installed. For example, a module connected to an outlet may communicate with the server 1000 via Wi-Fi or Bluetooth, and a module connected to the lighting device may communicate with the server 1000 via ZigBee. In this case, the ZigBee communication method may be slower than the Wi-Fi or Bluetooth communication method.

Even if the server 1000 transmits the same control command to the module due to a difference in communication method, the control performed by the control command in the device may be differently performed for each device.

For example, the server 1000 transmits the same control data to the first module connected to the first lighting apparatus and the second module connected to the second lighting apparatus so that the power of the first lighting apparatus and the second lighting apparatus are turned on. can be transmitted

In this case, the first module communicating with the server 1000 in the first communication method may change the power of the first lighting device to an on state at a first time based on the received control data. However, the second module communicating with the server 1000 in the second communication method may change the power of the second lighting device to the on state at a second time point later than the first time point based on the received control data. have.

From the outside, even though the server 1000 transmits control data at the same time, it can be confirmed that the power of each lighting device is not turned on at the same time but separately. This may be seen as an error in the building energy management system including the server 1000 .

Also, internally, the server 1000 needs to process data related to each module with the same time stamp. If the server 1000 processes data related to each module that does not come in uniformly depending on the difference in communication speed from time to time, the server 1000 cannot process the data in batches, so there is no need to manage with one time stamp. have.

Therefore, there is a need for a building energy management system that can consider the speed difference of communication methods. The speed difference of the communication method can be resolved by including the delay in the control data.

5 is a diagram for explaining control data and delay measurement according to an embodiment. FIG. 5(a) is a diagram for explaining control data, and FIG. 5(b) is a diagram for explaining an example of measuring a delay.

Referring to FIG. 5A , the control data transmitted by the server 1000 to each module may include a delay (D, delay) and a control command (M, information). For example, when the control data is 255 bits, the server 1000 may allocate a delay to 2 bits and allocate a control command to the remaining bits.

When control data including a delay is transmitted to the module, the module may operate in a buffer state for a time corresponding to the delay. That is, the module may not process data for a time corresponding to the delay, but may process data after the time has elapsed. In this case, processing the data may mean controlling the device by transmitting a control command to the device.

Referring to FIG. 5B , an example of a method of setting a delay included in control data is illustrated. The server 1000 may transmit a signal to the first module and the second module in advance, determine a time at which the signal is received by the module, and set a delay based on a difference in the received time.

For example, the server 1000 may transmit the first reference signal R1 to the first module in the first communication method and transmit the second reference signal R2 to the second module in the second communication method. In this case, the reference signal may be a basic communication signal that does not include a control command. Also, the first reference signal R1 may be the same as the second reference signal R2 .

In this case, as shown in FIG. 5B , the server 1000 may simultaneously transmit the first reference signal R1 and the second reference signal R2 at a reference time point t0. However, the present invention is not limited thereto, and the server 1000 may determine the speed difference between the communication methods of each module in a different way without simultaneously transmitting the first reference signal R1 and the second reference signal R2 .

For example, a first reference signal R1 is transmitted at a first time point, a response to the first reference signal R1 is received at a second time point, and the first reference signal R1 is transmitted based on the first time point and the second time point. You can check the speed of the communication method. In addition, by transmitting the second reference signal R2 at the third time point and receiving a response to the second reference signal R2 at the fourth time point, the second communication method based on the third time point and the fourth time point can determine the speed of

The first module receiving the first reference signal R1 may transmit a first response signal Rp1 that is a response to the first reference signal R1 back to the server 1000 . In this case, the first response signal Rp1 may be a simple ACK signal. The server 1000 may receive the first response signal Rp1 at a first time point t1 .

The second module receiving the second reference signal R2 may transmit a second response signal Rp2 that is a response to the second reference signal R2 back to the server 1000 . In this case, the second response signal Rp2 may be a simple ACK signal. The server 1000 may receive the second response signal Rp2 at a second time point t2 .

The server 1000 may calculate a difference between the first time point t1 and the second time point t2. In this case, the difference may mean a speed difference between the first communication method and the second communication method. The server 1000 may set a delay to be included in the control data based on the difference.

In addition, when the delay is set based on the difference, not only the communication speed difference but also the data processing speed difference for each module may be reflected.

When the server 1000 transmits control data to the first module and the second module at the same time, it transmits the first control data including the delay set based on the difference to the first module, and transmits the second data that does not include the delay. It can be transmitted to the second module.

Alternatively, when the server 1000 simultaneously controls the first device and the second device but does not transmit control data to each module at the same time, the first control data including the first delay set based on the difference is transmitted to the first module and transmit second control data including a second delay set based on a time at which the first control data is transmitted, the first delay, and a time at which data is transmitted to the second module, to the second module. That is, when the server 1000 does not transmit control data to each module at the same time, the calculated delay may be included for each control data transmitted to each module and transmitted to each module.

The method according to the embodiment may be implemented in the form of program instructions that can be executed through various computer means and recorded in a computer-readable medium. The computer-readable medium may include program instructions, data files, data structures, etc. alone or in combination. The program instructions recorded on the medium may be specially designed and configured for the embodiment, or may be known and available to those skilled in the art of computer software. Examples of the computer-readable recording medium include magnetic media such as hard disks, floppy disks and magnetic tapes, optical media such as CD-ROMs and DVDs, and magnetic such as floppy disks. - includes magneto-optical media, and hardware devices specially configured to store and execute program instructions, such as ROM, RAM, flash memory, and the like. Examples of program instructions include not only machine language codes such as those generated by a compiler, but also high-level language codes that can be executed by a computer using an interpreter or the like. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the embodiments, and vice versa.

As described above, although the embodiments have been described with reference to the limited embodiments and drawings, various modifications and variations are possible by those skilled in the art from the above description. For example, the described techniques are performed in a different order than the described method, and/or the described components of the system, structure, apparatus, circuit, etc. are combined or combined in a different form than the described method, or other components Or substituted or substituted by equivalents may achieve an appropriate result.

Therefore, other implementations, other embodiments, and equivalents to the claims are also within the scope of the following claims.

Claims (8)

In the building energy management system for managing the energy of a building by collecting information of modules connected to a plurality of devices arranged in a building,
A communication unit for transmitting and receiving data with a plurality of modules, a storage unit for storing data received from the plurality of modules, an analysis unit for analyzing data received from the plurality of modules, and a device connected to each module through the plurality of modules a server comprising a control unit for controlling;
a first module connected to a first device to control the first device, and to communicate with the server in a first communication method; and
A second module connected to a second device to control the second device, and to communicate with the server in a second communication method different from the first communication method,
The server is
Receiving first pattern data including information related to energy and control of the first device from the first module through the communication unit, and receiving from the second module, information related to energy and control of the second device from the second module 2 pattern data- The first pattern data and the second pattern data are, respectively, a control time point for operation, a controlling subject, Receive - including a plurality of control information classified according to a control location, a control item, a control content, and a control reason;
By inputting energy information and control information for each time point included in the first pattern data and the second pattern data into a machine learning model through the analysis unit, the control reason for each time point of the first device and the second device is analyzed do,
Based on the results of the machine learning model including the control reason for each time point through the analysis unit, a building energy policy including information about the control of the building in which the first device and the second device are disposed,
Transmitting a first reference signal to the first module and a second reference signal to the second module through the communication unit,
Receiving a first response signal that is a response to the first reference signal from the first module at a first time through the communication unit and a second response that is a response to the second reference signal from the second module at a second time receive a signal,
The time for controlling the first device based on the difference between the first time point and the second time point to which the delay related to signal transmission of the second module and the delay related to signal reception of the second device are reflected through the analysis unit setting a first delay for delaying,
Transmitting first control data for controlling the first device to the first module through the communication unit, and transmitting second control data for controlling the second device to the second module,
The first control data includes a first control command based on the building energy policy and the first delay for delaying a time at which the first device is controlled by the first control command,
The building energy policy includes first policy information and the second device including information that the first device should be controlled at a specific point in time so that energy of the first device can be saved using the classified plurality of control information. and second policy information including information to be controlled at a specific point in time so that the energy of the second device can be saved,
The first policy information includes control items and control contents different from the control items and control contents at the first time point, which is a time point before analyzing the control reason, and the second policy information is a time point before analyzing the control reason. Containing control items and control contents different from the control items and control contents at the second time point,
The control items include power, temperature, humidity and illuminance,
The control content includes on, off, increment and decrement
Building energy management system.
delete According to claim 1,
The first module transmits first performance data including the first delay in response to the first control data to the server;
the second module transmits second performance data to the server in response to the second control data;
The server simultaneously processes the first performance data and the second performance data at a point in time based on the first delay included in the received first performance data
Building energy management system.
According to claim 1,
The first module is configured to control the first device based on the first control command after a time corresponding to the first delay has elapsed from the time of receiving the first control data.
Building energy management system.
delete According to claim 1,
The first communication method is Wi-Fi or Bluetooth,
The second communication method is ZigBee.
Building energy management system.
According to claim 1,
The second control data includes a second control command and a second delay for delaying a time at which the second device is controlled by the second control command,
The second delay is set based on the first delay, a first transmission time that is a time when the first control data is transmitted, and a second transmission time that is a time when the second control data is transmitted
Building energy management system. delete

Images