KR20140096713A - Server, system and method for controlling power based on cloud computing - Google Patents

Abstract

The present invention relates to a server for controlling power of a building through cloud computing to minimize management costs, a system including the server, and a power control method performed by the server. The server for controlling power based on cloud according to an embodiment of the present invention comprises: a communications unit to receive a command signal from at least one client and receive power data from at least one building installation device; and a control unit to control power of the building installation device according to the received power data or command signal. According to the server of the present invention, both adoption and management of a power control related program are performed in a main server of a cloud computing system, thereby reducing costs and management costs and saving resources of a client device compared to the past when the investment was made per node.

Description

TECHNICAL FIELD [0001] The present invention relates to a cloud-based power control server, a system, and a power control method,

The present invention relates to a cloud-based power control server, a system, and a power control method. More particularly, the present invention relates to a server for controlling power of a building through cloud computing so that management costs can be minimized, To a power control method to be performed.

The problem of energy environ- mental issues such as the surge in international oil prices, future resource depletion issues, and climate change-related problems are emerging as global challenges. Therefore, development of energy resources and energy conservation technologies are being actively pursued. In Korea, energy consumption of apartment buildings and high-rise buildings is increasing, so it is necessary to reduce energy consumption of buildings.

One way to reduce building energy consumption is to reduce standby power in addition to reducing energy consumption itself. In particular, 11% of the average power consumption per household per year is wasted as standby power, and since the standby power is gradually increasing due to home networking, the total energy consumption can be greatly reduced by reducing the standby power.

Nowadays, server-client-based computing environments are increasingly being replaced by client devices due to capacity shortage as applications running on clients become increasingly complicated due to rapidly changing computing environments. In this case, a new program for energy consumption control should be installed in the newly replaced client device. In addition, if an existing program needs to be upgraded, it is necessary to reinstall the program on all client devices, which leads to an increase in personnel costs due to an increase in the number of management personnel.

In addition, in the case of the standby power interruption function using the power breaker and the power control function using the occupant detector, the respective power breakers and the occupant sensors operate independently, and the integrated management is not easy.

An object of the present invention is to provide a cloud-based power control server, a system, and a power management system capable of reducing resources of client devices and minimizing management costs by installing programs and data for controlling energy consumption of buildings in a main server of a cloud computing system And to provide a control method.

It is another object of the present invention to provide an integrated management system capable of intercepting standby power and power consumption by using a power breaker and power control using a room sensor in a main server of a cloud computing system, A cloud-based power control server, a system, and a power control method.

A cloud-based power control server according to an embodiment of the present invention includes a communication unit that receives command signals from at least one client and receives power data from at least one building installation device; And a controller for controlling power of the at least one building installation device according to the received power data or command signal.

A cloud-based power control server according to another embodiment of the present invention includes a communication unit for receiving a command signal from at least one client and receiving a room detection signal from at least one room sensor installed in the building; And a controller for controlling power of at least one building installation device according to the received room detection signal or command signal.

A cloud-based power control system according to an embodiment of the present invention includes at least one electronic device installed in a building; At least one power breaker coupled to the at least one electronic device and having a wireless communication module; At least one client having a wireless communication module and transmitting a mode setting command signal and a specific electronic equipment power control command signal to a main server; And setting the power control mode to one of a manual mode and an automatic mode. When the power mode is set to the manual mode, the power of the corresponding electronic device is cut off according to a command signal received from the at least one client. And analyzes the power data received from the power breaker to interrupt the power of the corresponding electronic device when it is determined that the standby power is maintained for a predetermined time.

At least one electronic device installed in a building according to another embodiment of the present invention; At least one occupant sensor having a wireless communication module and installed in the building; At least one client having a wireless communication module and transmitting a mode setting command signal and a specific electronic equipment power control command signal to a main server; And setting the power control mode to one of a manual mode and an automatic mode. When the mode is set to the manual mode, the power of the corresponding electronic device is controlled according to a command signal received from the at least one client. And controls power of the electronic apparatus linked to the occupant sensor when the occupant detection signal is received from the occupant detector.

A power control method for a cloud-based power control server according to an exemplary embodiment of the present invention includes: setting a power control mode according to a command signal received from at least one client; Blocking the power consumption of the building-installed device when receiving the building-installed-device control command from the at least one client when the mode is set to the manual mode; And automatically powering off the building installation device when it is determined that standby power is maintained for a predetermined time by analyzing the power data received from at least one building installation device when the mode is set to the automatic mode .

According to another aspect of the present invention, there is provided a power control method for a cloud-based power control server, the method including: setting a power control mode according to a command signal received from at least one client; Controlling power of the building-installed device when receiving the building-installed-device control command from the at least one client when the mode is set to the manual mode; And controlling power of the corresponding electronic device when receiving a member detection signal from at least one occupant sensor installed in the building when the automatic mode is set.

According to the present invention, both the adoption and management of the power control related program are performed in the main server of the cloud computing system, so that the cost can be reduced and the management cost can be reduced compared to the past investment for each node, Can save resources. From the viewpoint of users and administrators, it is possible to eliminate the burden of installing a complicated program on a client terminal, and it is possible to flexibly cope with performance and platform of a client device in terms of supply and service, You will have the opportunity.

In addition, through the present invention, the power consumption and standby power cutoff using the power circuit breaker and the power control using the occupant detector are performed in the main server of the cloud computing system, thereby enabling power integration management.

In addition, through the present invention, power consumption and standby power cutoff and power control are supported in a multimode mode, so that a user or an administrator can easily control power through a client device anywhere.

1 is a configuration diagram of a cloud-based power control system 10 according to an embodiment of the present invention.
FIG. 2 is an internal configuration view of a main server 100 among components of a cloud-based power control system according to an embodiment of the present invention.
3 is an internal configuration diagram of a client 200 among components of a cloud-based power control system according to an embodiment of the present invention.
4 is a flowchart illustrating a power control method between a main server 100 and a client 200 according to an embodiment of the present invention.
5 is a flowchart illustrating a power control method of the main server 100 according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that the following description will be given only for the purpose of understanding the operation according to the embodiment of the present invention, and the description of other parts will be omitted so as not to disturb the gist of the present invention.

1 is a configuration diagram of a cloud-based power control system 10 according to an embodiment of the present invention. The power control system 10 of the present invention includes a main server 100, a client 200, a cloud wireless network 300, a gateway 400, an industrial power breaker 500, a home power breaker 600, 700, an electronic device 800, and a status database 900.

The main server 100 controls the power consumption of the electronic device 800 in the power control system 10 or controls the power consumption of the electronic device 800 through the occupant sensor 700, And the household power circuit breaker 600 to cut off power consumption and standby power. An application for power control is installed in the main server 100 and sets a power control mode according to a command signal received from the client 200. [ When the power control mode is set to the manual mode, when the command signal is received from the client 200, the power consumption of the specific electronic device 800 is controlled or the specific power circuit breaker 500 and the household power circuit breaker 600 are operated Thereby blocking power consumption.

When the power control mode is set to the automatic mode, when the main server 100 receives the absence sensing signal from the occupant sensor 700, the consumption of at least one electronic device 800 linked to the occupant sensor 700 And receives the power data from the industrial power circuit breaker 500 or the domestic power circuit breaker 600. If it is determined that the standby power state is maintained for a predetermined time or longer, the power circuit breaker is operated to cut off the power.

When the power control mode is set to the PEAK control mode, the main server 100 confirms the order of the electronic devices for power control when receiving the warning signal from the outside, Or the like.

In the present invention, the PEAK control mode can be divided into an automatic peak control mode and a semi-automatic peak control mode. In the automatic peak control mode, when the main server 100 receives the warning signal from the outside, it checks the order of the electronic devices for power control and blocks or controls the power consumption of the electronic device 800 according to the ranking And the semi-automatic peak control mode means a mode in which the client 200 can individually control the electronic device 800 by transmitting a warning notification message to the client 200 when receiving a warning signal from the outside.

The main server 100 receives data on the power consumption state of the building through the gateway 400 and stores the data in the state database 900. [ The main server 100 extracts data on the power consumption state of the building from the state database 900 and transmits the data to the client 200 upon request of the client 200. [

The internal components of the main server 100 will be described in detail with reference to FIG.

The client 200 is a device installed in or placed in a building and is connectable to the main server 100 and is a device that transmits a command signal to the main server 100 and receives data from the main server 100. The client 200 may be a personal computer (PC), a personal digital assistant (PDA), a smart phone, or the like. The client 200 accesses the main server 100 through a web browser and transmits a command to set the power control mode to one of an automatic mode, a manual mode, and a peak (PEAK) control mode. When the power control mode is the passive mode, the client 200 can transmit the control command of the specific electronic device 800 or the power breaker 500, 600 to the main server 100. The client 200 may also request the main server 100 to transmit data on the power consumption of the building.

The internal components of the client 200 will be described in detail with reference to FIG.

The cloud network 300 is an environment for transmitting and receiving signals between the main server 100, the client 200 and the gateway 400. The cloud network 300 may include a mobile switching center (MSC), a base station controller (BSC), and a base transceiver system (BTS).

The gateway 400 is connected to the cloud network 300 and an interface function for connecting the industrial power breaker 500, the household power breaker 600, the room detector 700, and the electronic device 800, . According to an embodiment of the present invention, the gateway 400 may be connected to the main server 100 through a wired / wireless network.

Industrial power breaker 500 is also referred to as ISPS (Industrial Smart Power Switch) as a power breaker connected to industrial electrical equipment. The industrial power breaker 500 has a wireless communication module and is configured to be able to communicate with the main server 100 through the gateway 400. [ The industrial power breaker 500 measures the amount of power consumption and transmits the measured power consumption to the main server 100. When the power shutoff command is received from the main server 100, The industrial power breaker 500 may be exposed to the outside rather than embedded in the wall of the building.

The household power circuit breaker 600 is also called a Household Smart Power Switch (HSPS) as a power breaker connected to a home appliance such as a computer, a TV, a washing machine, and an air conditioner. The home power circuit breaker 600 has a wireless communication module similar to the industrial power breaker 500 and is configured to be able to communicate with the main server 100 through the gateway 400. [ The home power circuit breaker 600 measures the amount of power consumption and transmits the measured power to the main server 100. When the power shutdown command is received from the main server 100, The electric power breaker 600 for home use may be exposed to the outside rather than embedded in the wall of the building.

The occupant sensor 700 is a device that detects the presence or absence of a person. The occupant sensor 700 may be composed of an illuminance sensor or an infrared sensor (PIR sensor) and may be a combination of the two sensors. The room sensor 700 includes a wireless communication module and is connectable to the main server 100 through the gateway 400. When the user sensor is detected, the room sensor 700 transmits a member detection signal to the main server 100. [ When the room sensor 700 receives a control signal from the main server 100, it controls the power of the electronic device 800 connected to the room sensor 700.

The electronic device 800 means an industrial or home electronic device installed or located in a building. The electronic device 800 may be an industrial electric equipment, a computer, a TV, a washing machine, an air conditioner, a lighting device, or the like. The electronic device 800 is connected to the electric circuit breaker 500 or 600 or the occupant detector 700 either in a wired or wireless manner and may be connected to the power interrupter 500 or 600 or the occupant detector 700, As shown in FIG.

The state database 900 is under the control of the main server 100 as a database for storing power data of a building. The state database 900 stores information on the total power consumption of the building, the power data received from the power breakers 500 and 600, and the power control mode of each building. The state database 900 also stores data related to power control priorities, which is an electronic device rank for controlling power, when receiving a warning message informing a PEAK of power consumption from the outside.

The cloud-based power control system 10 may include a watt-hour meter in accordance with an embodiment of the present invention. The watt hour meter is connected to the gateway 400 by wire or wireless, and transmits data on the power consumption of the building to the main server 100 through the gateway 400.

2 is an internal configuration diagram of the main server 100 among the cloud-based power control system 10 according to the embodiment of the present invention.

The main server 100 of the present invention includes a wireless communication unit 110 and a control unit 120. The control unit 120 includes a data processing unit 121, a mode setting unit 122, and an event determination unit 123 .

The wireless communication unit 110 performs transmission / reception of corresponding data for wireless communication of the main server 100. The wireless communication unit 110 may include an RF transmitter for up-converting and amplifying the frequency of a transmitted signal, and an RF receiver for low-noise amplifying the received signal and down-converting the frequency of the received signal. The wireless communication unit 110 may receive data through a wireless channel, output the data to the control unit 120, and transmit the data output from the control unit 120 through a wireless channel.

The data processing unit 121 determines data received from the wireless communication unit 110 and transmits the data to the mode setting unit 122 and the event determination unit 123 or stores the data in the state database 900. The data processing unit 121 receives the mode setting command from the client 200 through the wireless communication unit 110 and transmits the mode setting command to the mode setting unit 122. The data processing unit 121 receives the mode setting command from the client 200, , 600) control command to the event determination unit 123. The data processor 121 receives the power data from the occupant sensor 700 or the power breaker 500 or 600 and transmits the power data to the event determiner 123. Upon receiving the occupant sensor signal from the occupant sensor 700, (123). And stores the received data in the state database 900 when receiving the power consumption data from the power breaker 500 or 600 through the gateway 400 or receiving the entire power consumption data of the building from the watt hour meter.

The mode setting unit 122 sets a power control mode, and sets the power control mode to one of an automatic mode, a manual mode, and a peak control mode according to a command of the client 200. The mode setting unit 122 transmits information on the set mode to the event determination unit 123. [

The event determination unit 123 determines whether an event that controls power is generated through a signal received from the data processing unit 121. [ Upon receiving the control command for the electronic device 800 or the power breaker 500 or 600 generated from the client 200, the event determination unit 123 determines whether the power control mode is the manual mode, To the data processing unit 121, a power cutoff command of the circuit breakers 500 and 600 or a control command of the corresponding electronic device 800. [ Upon receiving the power data from the power breakers 500 and 600, the event determination unit 123 determines whether the power control mode is the automatic mode. If the power control mode is the automatic mode, the event determination unit 123 determines whether the standby power is maintained for a preset time, And transmits a blocking command to the data processing unit 121. The event determination unit 123 determines whether the power control mode is the automatic mode when receiving the member detection signal from the occupant sensor 700. If the power control mode is the automatic mode, To the data processing unit (121).

The event determination unit 123 determines whether the power control mode is set to the peak control mode when receiving a warning message informing the power usage peak (PEAK) from the power supply agency through the wireless communication unit 110 or other communication module including the wired line In the peak control mode, the power control priority stored in the state database 900 is checked, and the power consumption of the electronic device 800 is sequentially set in accordance with the priority order so that the power consumption amount required by the power supply agency can be adjusted And transmits a command to cut off or lower the data to the data processing unit 121.

In the present invention, the PEAK control mode can be divided into an automatic peak control mode and a semi-automatic peak control mode. When the power control mode is set to the automatic peak control mode, a warning message indicating the power usage peak (PEAK) Upon receipt, the event determination unit 123 checks the power control priority stored in the state database 900, and consecutively considers the consumption of the electronic device 800 in accordance with the priority order so as to match the power consumption demanded by the power supply agency To the data processing unit 121. When the power control mode is set to the semi-automatic peak control mode, the data processing unit 121 transmits a warning message indicating the power usage peak (PEAK).

Upon receiving the building power consumption amount monitoring request command generated from the client 200, the event determination unit 123 may extract the current power consumption amount of the building from the state database 900 and transmit the extracted current consumption amount to the data processing unit 121 have. The data processing unit 121 transmits the building power consumption amount data to the client 200 through the wireless communication unit 110. [

The user may set the power control priority through the client 200 and the data processing unit 121 of the main server 100 may store the power control priority data in the state database 900 do.

3 is an internal configuration diagram of a client 200 in a cloud-based power control system according to an embodiment of the present invention.

The client 200 of the present invention comprises a PC, a smart phone and the like and includes a wireless communication unit 210, an audio processing unit 220, a storage unit 230, a display unit 240, an input unit 250, and a control unit 260 . In accordance with an embodiment of the present invention, client 200 may include other communication modules including wired.

The wireless communication unit 210 performs a function of transmitting and receiving corresponding data for wireless communication of the client 200. The wireless communication unit 210 may include an RF module such as 3G or LTE, a Wifi module, and the like, and is connected to the cloud network 300 to transmit and receive data.

The audio processing unit 220 may include a CODEC, and the CODEC may include a data codec for processing packet data and an audio codec for processing an audio signal such as voice. The audio processing unit 220 converts a digital audio signal into an analog audio signal through an audio codec and reproduces the analog audio signal, and converts the input analog audio signal into a digital audio signal through an audio codec. In the present invention, the audio processing unit 220 may output a warning sound informing the power usage peak (PEAK) under the control of the control unit 260. [

 The storage unit 230 is a component for storing programs and data necessary for the operation of the client 200 and includes an operating system (OS) for booting the client 200, applications, and data such as images, audio, Can be stored.

The display unit 240 may be formed of a liquid crystal display (LCD), an organic light emitting diode (OLED), an active matrix organic light emitting diode (AMOLED) And visually provides the data stored in the storage unit 200 or the input data to the user. In the present invention, the display unit 240 displays a power control mode setting menu, an individual electronic device 800 power control menu, and an individual power breaker 500, 600 power cutoff menu under the control of the controller 260. Also, the display unit 240 can display a menu for displaying the power consumption of the building.

The input unit 250 receives a user's key operation signal for controlling the client 200, and transmits the received key operation signal to the controller 270. The input unit 250 may include a keypad including a numeric key, a character key, and a direction key, such as a 3 * 4 pad, a Qwerty pad, or a touch panel. In addition, the input unit 250 may include a button key, a jog key, and a wheel key.

The control unit 260 is a component that controls the overall operation of the client 200. [ The control unit 260 controls the wireless communication unit 210 to access the main server 100 through the cloud network 300 in order for the client 200 to control the electronic devices 800 in the building. The control unit 260 transmits a login request to the main server 100 and receives a login approval from the main server 100. [ When a mode setting menu entry command is input from the input unit 250, the control unit 260 receives data related to the mode setting menu from the main server 100 and displays a mode setting menu through the display unit 240. [ The controller 260 controls the wireless communication unit 210 to transmit the selected power control mode to the main server 100 when the power control mode is selected from the manual mode, the automatic mode, and the peak control mode. When the user selects the individual device power control menu in a state where the client 200 is connected to the main server 100, the control unit 260 receives data related to the individual device power control menu from the main server 100, 240 to display the power control menu. The power control menu includes a list of power breakers 500 and 600 that the client 200 can control and a list of electronic devices 800. When the user selects the specific power breaker 500 or 600 or the electronic device 800, the control unit 260 transmits a power consumption control command of the corresponding device.

In addition, the control unit 260 receives information on the power consumption of the building from the main server 100, and displays the received information on the display unit 240. The user can confirm the power consumption of the building in real time through the client 200. The controller 260 may display the energy status of the watt hour meter, the energy consumption pattern analysis, and the power usage history together with the display unit 240 when displaying the power consumption information of the building.

4 is a flowchart illustrating a power control method between the main server 100 and the client 200 according to an embodiment of the present invention. In FIG. 4, it is assumed that the user sets the power control mode to the passive mode in which the client 200 can control the power of the individual device.

In step 401, the client 200 makes a connection request to the main server 100. The service technology of the cloud-based power control system according to the present invention is characterized by setting an access level according to a user-specific authority with a paid or free membership process. The client 200 is already registered as a member in the main server 100. In step 401, the client 200 accesses the homepage of the main server 100 and requests login.

In step 402, the main server 100 performs a user authentication process for checking whether the client 200 is a member and an access level. If it is determined that the user is a member, the main server 100 transmits the connection approval to the client 200 in step 403. [ Thereafter, the client 200 and the main server 100 remain connected, and the client 200 requests the main server 100 to transmit data related to the mode setting menu. When the client 200 receives the data, Displays the setup menu. The mode setting menu includes a menu for selecting one of an automatic mode, a manual mode, and a peak (PEAK) control mode, and may include only an automatic mode and a manual mode according to an embodiment.

If any mode is selected by the user, the client 200 transmits the mode information selected by the user to the main server 100 in step 405. When the main server 100 receives the mode information from the client 200, the main server 100 completes the power control mode setting accordingly.

Thereafter, in step 407, the main server 100 is in a standby state, and the connection state between the client 200 and the main server 100 is continuously maintained. After the connection between the client 200 and the main server 100 is released according to the embodiment of the present invention, the client 200 and the main server 100 can be reconnected in steps 401 to 403.

When the user desires to control the specific device, when the user selects the individual device power control menu, the client 200 receives data related to the individual device power control menu from the main server 100 and displays the data on the screen. The individual device power control menu includes a list of power breakers 500 and 600 that can be controlled by the client 200 and a list of electronic devices 800. When the user selects the specific power breaker 500 or 600 or the electronic device 800, the client 200 transmits a power control command for the selected specific device to the main server 100.

When the power control command is received, the main server 100 determines in step 409 whether the power control mode is the manual mode, and controls the power consumption of the corresponding device in step 410 if the power control command is the manual mode. That is, the main server 100 controls the power consumption of the electronic device 800 such as the system air conditioner and the illumination by operating the specific power circuit breakers 500 and 600. If it is determined that the manual mode is not set in step 409, the process proceeds to step 407 without performing the power control operation to maintain the standby state.

5 is a flowchart illustrating a power control method of the main server 100 according to an embodiment of the present invention. 5 will be described with reference to the control unit 120 among the components of the main server 100 of FIG.

In step 501, the controller 120 determines whether the current power control mode is the manual mode. If it is determined that the mode is the manual mode, the controller 120 proceeds to step 502 and maintains the standby state. If the control unit 120 receives the specific device control command from the client 200 through the wireless communication unit 110 in step 503, the control unit 120 controls the power of the corresponding device in step 504. [ That is, when the control unit 120 receives a control command for a specific electronic device 800 or a control command for a specific power circuit breaker 500 or 600 from the client in step 503, the power control unit generates a power control command in step 504, To the occupancy sensor 700 or the electronic device 800. [

If it is determined in step 501 that the current power control mode is not the manual mode, the controller 120 proceeds to step 505 and determines whether the power control mode is the automatic mode. If it is determined that the mode is the automatic mode, the process proceeds to step 506 where the power received from the power breakers 500 and 600 is checked and the signal received from the occupant sensor 700 is checked. In step 507, the control unit 120 checks whether the standby power is maintained for a predetermined time or longer from the power received from the power interrupters 500 and 600. If it is determined that the standby power is maintained for a predetermined period of time, The standby power is cut off.

If it is determined in step 507 that the standby power is not maintained for the predetermined time or longer, the controller proceeds to step 509 and determines whether the absence detection signal is received from the occupancy detector 700. If it is determined that the absence detection signal is received, the flow proceeds to step 510 to control the power consumption of the electronic device 800 that is linked to the occupant sensor 700, that is, the electronic device 800 under the control of the occupant sensor 700. For example, if the electronic device 800 is an illumination device, the brightness of illumination may be lowered, and in the case of a system air conditioner, an air conditioner operation may be turned off.

If it is determined in step 505 that the current power control mode is not the automatic mode, the controller 120 proceeds to step 511 and determines whether the current power control mode is the PEAK control mode. If it is determined that the mode is the PEAK control mode, the controller 120 maintains the standby state in step 512, and proceeds to step 513 to receive a power peak signal through the wireless communication unit 110 or other communication module including the wired . The power peak signal corresponds to a signal indicating that power supply from the power supply source (for example, KEPCO) is not smooth. If it is determined in step 513 that the power peak signal has been received, the controller 120 proceeds to step 514 to check the power control priority of the corresponding building by searching the state database 900, So that the power consumption of the electronic device 800 is sequentially cut off or lowered according to the priority.

A large part of the power being wasted in the building is generated due to inadequate real-time response due to the use of an inappropriate power breaker (power switch). If the automatic mode and the manual mode of the present invention are selectively applied, And it is possible to reduce waste power.

It should be noted that the embodiments of the present invention disclosed in the present specification and drawings are only illustrative examples of the present invention and are not intended to limit the scope of the present invention. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

10: Cloud-based power control system
100: main server 110: wireless communication unit
200: client 120:
300: Cloud network 121: Data processing unit
400: Gateway 122: Mode setting unit
500: Industrial power breaker 123: Event judgment unit
600: Household electric circuit breaker 210: Wireless communication part
700: room detector 220: audio processor
800: Electronic device 230:
900: status database 240: display
250: input unit 260:

Claims (14)

In a cloud-based power control server,
A communication unit for receiving command signals from at least one client and receiving power data from at least one building installation device; And
And a controller for controlling power of the at least one building installation device according to the received power data or command signal.
The method according to claim 1,
The control unit
Wherein the controller is configured to set the power control mode to one of a manual mode, an automatic mode, and a peak control mode according to a command signal received from the at least one client, Based on the received power control information.
3. The method of claim 2,
The control unit
When the power control mode is set to the manual mode,
Based on the command signal received from the at least one client, the power of the building-installed device corresponding to the received command signal is shut off.
3. The method of claim 2,
The control unit
When the power control mode is set to the automatic mode,
Wherein the power management unit analyzes the power data received from the at least one building installation device and cuts off the power of the building installation device when it is determined that standby power is maintained for a predetermined time.
3. The method of claim 2,
The control unit
When the power control mode is set to the PEAK control mode,
And when the warning signal is received from the outside, the power of the building-installed device is cut off in a predetermined order.
3. The method of claim 2,
The control unit
When the power control mode is set to the PEAK control mode,
And transmits a warning message to the at least one client when receiving an alert signal from the outside.
In a cloud-based power control server,
A communication unit for receiving a command signal from at least one client and receiving a room detection signal from at least one room sensor installed in the building; And
And a control unit for controlling power of at least one building installation device according to the received room detection signal or command signal.
8. The method of claim 7,
The control unit
Wherein the controller is configured to set the power control mode to one of a manual mode, an automatic mode, and a peak control mode according to a command signal received from the at least one client, Based power control server.
9. The method of claim 8,
The control unit
When the power control mode is set to the manual mode,
Wherein the controller controls the power of a building installation device corresponding to the received command signal when receiving a command signal from the at least one client.
9. The method of claim 8,
The control unit
When the power control mode is set to the automatic mode,
Wherein the control unit controls the power of the building installation device when receiving the member detection signal from the at least one occupant sensor.
In a cloud-based power control system,
At least one electronic device installed in the building;
At least one power breaker coupled to the at least one electronic device and having a wireless communication module;
At least one client having a wireless communication module and transmitting a mode setting command signal and a specific electronic equipment power control command signal to a main server; And
The power control mode is set to one of a manual mode and an automatic mode. When the power mode is set to the manual mode, the power of the corresponding electronic device is cut off according to a command signal received from the at least one client. The power control system according to claim 1, wherein the power control unit is configured to analyze the power data received from the power cutoff unit and to interrupt the power of the corresponding electronic device when it is determined that the standby power is maintained for a predetermined time.
In a cloud-based power control system,
At least one electronic device installed in the building;
At least one occupant sensor having a wireless communication module and installed in the building;
At least one client having a wireless communication module and transmitting a mode setting command signal and a specific electronic equipment power control command signal to a main server; And
The power control mode is set to one of a manual mode and an automatic mode. When the power mode is set to the manual mode, the power of the corresponding electronic device is controlled according to a command signal received from the at least one client. Wherein the controller controls the power of the electronic device linked to the occupant sensor when receiving the absence detection signal from the detector.
A power control method for a cloud-based power control server,
Setting a power control mode according to a command signal received from at least one client;
Blocking a power of a building-installed device when receiving a building-installed-device control command from the at least one client when the mode is set to a passive mode; And
When the automatic power saving mode is set to the automatic mode, analyzing the power data received from the at least one building installation device and interrupting the power of the building installation device when it is determined that the standby power is maintained for a predetermined period of time A power control method for a cloud based power control server.
A power control method for a cloud-based power control server,
Setting a power control mode according to a command signal received from at least one client;
Controlling power of the building-installed device when receiving the building-installed-device control command from the at least one client when the mode is set to the manual mode; And
Controlling power of a corresponding electronic device when receiving a member detection signal from at least one occupant sensor installed in a building when the automatic mode is set.

Images