KR102447141B1 - Master plug having infrared transmission and receiving fuction, power managment method using the same - Google Patents

Abstract

Provided are a master plug having an infrared transmission and receiving function to drive an electronic device connected to a smart plug with one operation, and a power management method using the same. The provided master plug detects the electronic device, which is a target to be controlled, in response to an input of an IR control signal, which is an infrared signal for controlling the electronic device, detects the smart plug connected with the target to be controlled as a plug for the target to be controlled, and outputs a driving signal to the plug for the target to be controlled to convert the control signal into the IR control signal, which is an infrared signal corresponding to the target to be controlled, to be output.

Description

MASTER PLUG HAVING INFRARED TRANSMISSION AND RECEIVING FUCTION, POWER MANAGMENT METHOD USING THE SAME

The present invention relates to a master plug and a power management method using the same for controlling a smart plug installed in a consumer to cut off and control standby power, measure power usage, and the like.

Recently, as power consumption has rapidly increased, various devices and technologies for efficiently managing power in consumers have been developed. A representative device for efficiently managing power is a smart plug.

The smart plug is located between the consumer's outlet and the electronic device, and blocks power applied from the outlet to the electronic device in the off state to prevent standby power consumption of the electronic device.

A smart plug can drive an electronic device with a single control signal when an electronic device using a mechanical switch is connected.

However, the smart plug has a problem in that, when an electronic device to which an electronic switch is applied is connected, the smart plug, which is in a standby power cut off state, must first be driven and then the electronic device must be driven manually or with a remote control.

In addition, the conventional smart plug has no effect on power saving because it must always maintain the driving state when frequently used electronic devices are connected. There is a problem.

Korean Patent Registration No. 10-1257449 (Smart Plug and Power Quality Monitoring System Using It)

The present invention has been proposed to solve the conventional problems, and an object of the present invention is to provide a master plug having an infrared transmission/reception function to drive an electronic device connected to a smart plug with a single operation, and a power management method using the same.

In order to achieve the above object, the master plug according to an embodiment of the present invention receives an IR control signal for controlling an electronic device disposed in a consumer from a remote control, an IR receiver that outputs an IR control signal, and an IR control of the IR receiver In response to the signal output, one electronic device among a plurality of electronic devices disposed in the consumer is detected as a control target based on the IR control signal, and a smart plug to which the control target is connected from among a plurality of smart plugs disposed in the consumer is selected as a control target plug , and outputting a driving signal including the identifier of the control target plug, and then outputting a control signal transmission request including a control signal, and a control signal in response to the control signal transmission request output from the control unit, the infrared corresponding to the control target It includes an IR transmitter that converts and outputs an IR control signal that is a signal.

The IR transmitter may convert the driving signal into an infrared signal corresponding to the control target plug in response to the driving signal output from the controller, and transmit the converted driving signal to the control target plug.

The master plug according to an embodiment of the present invention converts the driving signal into a power line communication signal in response to the driving signal output from the control unit, transmits it to the control target plug, receives a response signal to the driving signal from the control target plug, and receives the control unit It may further include a power line communication unit for transmitting to.

The master plug according to an embodiment of the present invention may further include a communication unit for transmitting the driving signal to the control target plug through one wireless network among Wi-Fi and short-distance communication in response to the driving signal output from the control unit.

Upon receiving a response signal to the driving signal from the control target plug, the control unit may output a control signal transmission request, generate a control signal transmission request including an identifier of the control target and the control signal, and transmit it to the IR transmitter.

The master plug according to an embodiment of the present invention further includes a communication unit for transmitting power schedule information received from one of the management server and the portable terminal to the control unit, and the control unit detects the control target and the control target plug based on the power schedule information. can do.

In the master plug according to an embodiment of the present invention, the control unit outputs a schedule storage request including the power schedule information in response to the transmission of the power schedule information of the communication unit, and a memory for storing the power schedule information in response to the schedule storage request of the control unit may include more.

In order to achieve the above object, the power management method according to an embodiment of the present invention is performed by a master plug disposed in a consumer in which a plurality of smart plugs are disposed.

The power management method according to an embodiment of the present invention includes the steps of receiving an IR control signal for controlling an electronic device disposed in the consumer from a remote control, and a plurality of electronic devices disposed in the consumer based on the IR control signal input in the receiving step. Detecting one electronic device from among devices as a control target, detecting a smart plug connected to a control target from among a plurality of smart plugs disposed in the consumer as a control target plug, and a control target detected in the step of detecting as a control target plug converting the control signal into an IR control signal that is an infrared signal corresponding to the control target in response to a response signal of the control target plug to the driving signal output in the step of outputting the driving signal to the plug; and and outputting the converted IR control signal as a control target in the converting step.

Outputting the driving signal may include converting the driving signal into an infrared signal corresponding to the control target plug.

Outputting the driving signal may include converting the driving signal into a power line communication signal and outputting the driving signal converted into the power line communication signal to a power line connected to a control target plug.

The power management method according to an embodiment of the present invention may further include receiving a response signal of the control target plug to the driving signal through a power line connected to the control target plug before the outputting step.

In the step of outputting the driving signal, the driving signal may be transmitted to the control target plug through one wireless network among Wi-Fi and short-distance communication.

The power management method according to an embodiment of the present invention further comprises the step of receiving power schedule information received from one of the management server and the portable terminal, and the detecting as the control target detects the control target based on the power schedule information. can do.

According to the present invention, the master plug and the power management method using the same can drive the smart plug and the electronic device with one operation even when the smart plug is in the standby power cut-off state by controlling the home appliance through the infrared transmission/reception function in the master plug. can have an effect.

In addition, the master plug and the power management method using the same control the smart plug and electronic device with a single operation, so that the smart plug can be kept in the standby power cut-off state even in frequently used electronic devices, thereby reducing power compared to the conventional smart plug has the effect of improving

1 is a view for explaining a power management system according to an embodiment of the present invention.
Figure 2 is a view for explaining the configuration of the master plug of Figure 1;
3 to 5 are diagrams for explaining the configuration of the smart plug of FIG.
6 is a view for explaining an operation of a power management system driving an electronic device according to an embodiment of the present invention.
7 is a view for explaining an operation of collecting measurement information of an electronic device driven according to a power schedule by the power management system according to an embodiment of the present invention;
8 is a view for explaining a power management method according to an embodiment of the present invention.
9 is a view for explaining a modified example of a power management method according to an embodiment of the present invention.

Hereinafter, the most preferred embodiment of the present invention will be described with reference to the accompanying drawings in order to explain in detail enough that a person of ordinary skill in the art can easily implement the technical idea of the present invention. . First, in adding reference numerals to the components of each drawing, it should be noted that the same components are given the same reference numerals as much as possible even though they are indicated on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

Referring to FIG. 1 , the power management system according to an embodiment of the present invention is configured to include a management server 10 , a portable terminal 20 , a remote control 40 , a master plug 100 and a smart plug 200 . Hereinafter, the control signal is a signal for controlling the electronic device 30 installed in the consumer, such as driving (ON/OFF), operation mode, channel change, temperature setting, and the like.

The management server 10 collects and manages measurement information from the master plug 100 installed in the consumer. The management server 10 collects measurement information from the master plug 100 , and generates and manages power usage, maximum power usage period, charge, etc. based on this.

The management server 10 transmits power information to the portable terminal 20 upon request of the portable terminal 20 . In this case, the management server 10 transmits the power information including the power usage, the maximum power usage period, the fee, etc. generated based on the measurement information to the portable terminal 20 .

The management server 10 collects power schedule information from the portable terminal 20 . The management server 10 stores the power schedule information in association with the consumer or the user, and transmits the power schedule information to the master plug 100 installed in the consumer.

The mobile terminal 20 may receive and display power information managed by the management server 10 . That is, the mobile terminal 20 may receive and display the power usage, the maximum power usage period, the charge, and the like from the management server 10 .

The mobile terminal 20 may generate power schedule information based on the power information received from the management server 10 . The mobile terminal 20 receives a power schedule using power information through the UI, and transmits power schedule information including the received power schedule information to the management server 10 .

The remote controller 40 is a controller for controlling the electronic device 30 . The remote control 40 transmits an IR control signal that is an infrared signal. The remote control 40 transmits an IR control signal having different infrared characteristics depending on the manufacturer or the electronic device 30 . In this case, the remote controller 40 may be connected one-to-one with the electronic device 30 to control one electronic device 30 , or may be connected one-to-many to control a plurality of electronic devices 30 .

The master plug 100 collects and stores measurement information from the smart plug 200 disposed in the consumer. The master plug 100 collects and stores measurement information including the amount of power from the smart plug 200 . The master plug 100 transmits measurement information to the management server 10 at set time intervals. At this time, the master plug 100 may be deleted after transmitting the measurement information to secure the internal memory.

The master plug 100 controls the driving state of a plurality of smart plugs 200 and electronic devices disposed in the consumer. The master plug 100 receives a control signal from the remote control 40 and transmits a driving signal to the smart plug 200 corresponding to the control signal to drive the smart plug 200 and then to drive the smart plug 200 . A control signal is transmitted to the electronic device 30 to which power is applied. At this time, the master plug 100 is Wi-Fi, short-range communication, power line communication. A driving signal is transmitted to the smart plug 200 through infrared communication or the like, and a control signal is transmitted to the electronic device 30 through infrared communication.

The master plug 100 receives and stores power schedule information from the management server 10 . The master plug 100 operates the smart plug and the electronic device 30 according to the stored power schedule information. At this time, the master plug 100 transmits a driving signal to the smart plug 200 based on the power schedule information to drive the smart plug 200 , and then sends a control signal to the electronic device 30 connected to the smart plug 200 . to send

The master plug 100 may receive power schedule information from the management server 10 and transmit it to the smart plug 200 . In this case, the smart plug 200 is driven according to the power schedule information, and the master plug 100 transmits a control signal to the electronic device 30 based on the schedule information. After power is applied from the smart plug 200 , the home appliance operates by setting power on/off, driving mode, etc. according to a control signal received from the master plug 100 .

Referring to FIG. 2 , the master plug 100 includes a first power supply unit 110 , a first communication signal extraction unit 120 , a first power line communication unit 130 , a first communication unit 140 , and a first IR receiver 145 . ), a first controller 150 , a first memory 160 , and an IR transmitter 170 .

The first power supply unit 110 converts the AC power input from the outside to the first communication signal extraction unit 120 , the first power line communication unit 130 , the first communication unit 140 , the first IR receiving unit 145 , and the first control unit. 150 , the first memory 160 , and the IR transmitter 170 are applied. The first power supply unit 110 rectifies the AC power, converts it into DC power, and outputs it, and outputs the first communication signal extraction unit 120 , the first power line communication unit 130 , the first communication unit 140 , and the first IR receiving unit. 145 , the first controller 150 , the first memory 160 , and the IR transmitter 170 operate with DC power output from the first power supply 110 .

The first communication signal extraction unit 120 extracts the power line communication signal from the AC power input from the outside. At this time, the first communication signal extraction unit 120 extracts the power line communication signal, which is measurement information, from the smart plug 200 from the AC power. The first communication signal extraction unit 120 transmits the extracted power line communication signal (ie, the measurement value and/or the electronic device 30 identifier) to the first power line communication unit 130 .

The first communication signal extraction unit 120 extracts a response signal of the smart plug 200 from the input AC power. The first communication signal extraction unit 120 extracts a response signal to the driving signal transmitted from the first power line communication unit 130 and transmits it to the first power line communication unit 130 .

The first power line communication unit 130 converts the power line communication signal received from the first communication signal extraction unit 120 into digital data. That is, the first power line communication unit 130 converts a measurement value and/or an identifier of the electronic device 30 that is a power line communication signal into digital data. The first power line communication unit 130 transmits measurement information including a measurement value converted into digital data and/or an identifier of the electronic device 30 to the first control unit 150 .

When the first power line communication unit 130 receives the driving signal from the first control unit 150 , it transmits the driving signal to the smart plug 200 corresponding to the identifier included in the driving signal. In this case, the first power line communication unit 130 converts the driving signal into a power line communication signal and then transmits it to the smart plug 200 . The first power line communication unit 130 converts the response signal (ie, the response signal to the driving signal) received from the first communication signal extraction unit 120 into digital data and transmits it to the first control unit 150 .

The first IR receiver 145 receives the IR control signal transmitted from the remote controller 40 . The first IR receiver 145 transmits the received IR control signal to the first controller 150 .

When the first control unit 150 receives the measurement information from the first power line communication unit 130 , it generates a measurement information storage request including the measurement information, and transmits the measurement information storage request to the first memory 160 .

The first control unit 150 generates a measurement information transmission request at a set time interval and transmits the measurement information transmission request to the first communication unit 140 . When the first control unit 150 receives an Ack signal from the first communication unit 140 after transmitting the measurement information transmission request, it generates a measurement information deletion request and sends the measurement information deletion request to the first memory 160 . send.

When receiving the control signal from the first IR receiver 145, the first control unit 150 detects a control target based on the control signal. The first control unit 150 detects the smart plug 200 connected to the control target. In this case, the first control unit 150 detects the control target based on the infrared characteristic of the IR control signal. The first control unit 150 generates a driving signal including the detected identifier of the smart plug 200 , and transmits the driving signal to the first power line communication unit 130 .

When the first control unit 150 receives a response signal to the driving signal from the first power line communication unit 130 , it generates a control signal transmission request including an identifier of the electronic device 30 detected as a control target and a control signal, and controls The signal transmission request is transmitted to the IR transmitter 170 .

Meanwhile, when receiving the power schedule information from the first communication unit 140 , the first control unit 150 generates a schedule storage request including the power schedule information and transmits the schedule storage request to the first memory 160 .

The first controller 150 generates a driving signal and a control signal for controlling the driving state of the smart plug 200 and the electronic device 30 based on the power schedule information stored in the first memory 160 .

The first control unit 150 detects a control target based on the schedule information. The first control unit 150 detects the smart plug 200 connected to the control target. The first control unit 150 generates a driving signal including the detected identifier of the smart plug 200 , and transmits the driving signal to the first power line communication unit 130 .

When receiving a response signal to the driving signal from the first power line communication unit 130 , the first control unit 150 generates a control signal for controlling the electronic device 30 based on the schedule information. The first control unit 150 generates a control signal transmission request including an identifier of the electronic device 30 detected as a control target and a control signal, and transmits the control signal transmission request to the IR transmitter 170 .

Meanwhile, the first control unit 150 may transmit a driving signal for driving control of the smart plug 200 to the first communication unit 140 or the IR transmitter 170 . The first control unit 150 generates a driving signal transmission request including the identifier of the smart plug 200 , and transmits the driving signal transmission request to the first communication unit 140 or the IR transmitting unit 170 .

When the first memory 160 receives the measurement information storage request from the first controller 150 , the first memory 160 detects and stores measurement information from the measurement information storage request. When the first memory 160 receives a request to delete measurement information from the first control unit 150 , the first memory 160 deletes measurement information transmitted by the first communication unit 140 from among the stored measurement information.

When receiving a schedule storage request from the first control unit 150 , the first memory 160 detects and stores power schedule information from the schedule storage request. At this time, when the pre-stored power schedule information exists, the first memory 160 replaces the stored power schedule information with the detected power schedule information and stores it.

The first communication unit 140 receives a control signal from the management server 10 or the mobile terminal 20 . The first communication unit 140 transmits the received control signal to the first control unit 150 . In this case, the control signal may include an identifier of the electronic device to be controlled and a control command.

When the first communication unit 140 receives the measurement information transmission request from the first control unit 150 , the first communication unit 140 detects measurement information stored in the first memory 160 and transmits it to the management server 10 . In this case, the first communication unit 140 transmits the measurement information through a network including the Internet.

The first communication unit 140 receives power schedule information from the management server 10 . The first communication unit 140 receives power schedule information through a network including the Internet. The first communication unit 140 transmits the received power schedule information to the first control unit 150 .

When the first communication unit 140 receives the driving signal from the first control unit 150 , it transmits it to the smart plug 200 through a network such as Wi-Fi or short-distance communication. In this case, the first communication unit 140 detects the identifier and the driving signal of the smart plug 200 from the driving signal transmission request. The first communication unit 140 transmits a driving signal to the smart plug 200 corresponding to the detected identifier.

When the IR transmitter 170 receives the control signal transmission request from the first controller 150 , the IR transmitter 170 detects the identifier and the control signal of the electronic device 30 from the control signal transmission request. The IR transmitter 170 converts the control signal into an infrared signal corresponding to the identifier of the electronic device 30 and outputs the converted signal.

When the IR transmitter 170 receives the driving signal transmission request from the first control unit 150 , the IR transmitter 170 detects the identifier and the driving signal of the smart plug 200 from the driving signal transmission request. The IR transmitter 170 converts the driving signal into an infrared signal corresponding to the identifier of the smart plug 200 and outputs it.

Meanwhile, the master plug 100 may transmit power schedule information stored in the first memory 160 to the smart plug 200 .

The first control unit 150 transmits a schedule information transmission request including power schedule information to the first communication unit 140 . In this case, the first control unit 150 may detect a schedule corresponding to the smart plug 200 from among the power schedule information stored in the first memory 160 , and set it as the power schedule information.

The first communication unit 140 transmits the power schedule information to the smart plug 200 when receiving the schedule information transmission request from the first control unit 150 .

The smart plug 200 is inserted and coupled to an outlet of the consumer, and the power cord of the electronic device 30 is inserted and coupled to the smart plug 200 . The smart plug 200 in the off state blocks power applied to the electronic device 30 to prevent standby power consumption of the electronic device 30 . The smart plug 200 receiving the driving signal is driven to apply power to the electronic device 30 , and the electronic device 30 operates by the power applied through the smart plug 200 . At this time, the smart plug 200 is Wi-Fi, short-range communication, power line communication. The driving signal may be received through infrared communication or the like.

Referring to FIG. 3 , the smart plug 200 includes a second power supply unit 210 , a second communication signal extraction unit 220 , a second power line communication unit 230 , a second control unit 240 , and a second memory 250 . , a switch 260 , a measuring instrument 270 , and a measuring unit 280 .

The second power supply unit 210 converts the AC power input from the outside into the second communication signal extraction unit 220 , the second power line communication unit 230 , the second control unit 240 , the second memory 250 , and the switch 260 . , applied to the measuring instrument 270 and the measuring unit 280 . The second power supply unit 210 rectifies the AC power, converts it into DC power, and outputs the output, the second communication signal extraction unit 220, the second power line communication unit 230, the second control unit 240, the second memory ( 250 ), the switch 260 , the measuring instrument 270 , and the measuring unit 280 operate with DC power output from the second power supply unit 210 .

The second communication signal extraction unit 220 extracts the power line communication signal from the AC power input from the outside. At this time, the second communication signal extraction unit 220 extracts the power line communication signal that is the driving signal output from the master plug 100 from the AC power. The second communication signal extraction unit 220 transmits the extracted power line communication signal (ie, a driving signal) to the second power line communication unit 230 .

The second power line communication unit 230 converts the power line communication signal received from the first communication signal extraction unit 120 into digital data. That is, the second power line communication unit 230 converts a driving signal that is a power line communication signal into digital data. The second power line communication unit 230 transmits the driving signal converted into digital data to the second control unit 240 . Thereafter, the second power line communication unit 230 transmits a response signal to the driving signal to the master plug 100 when receiving the response signal transmission request from the second control unit 240 .

The second power line communication unit 230 transmits the measurement value to the master plug 100 when receiving the measurement value transmission request from the second control unit 240 . The second power line communication unit 230 converts the measured value into a power line communication signal and then transmits it to the master plug 100 .

When receiving the driving signal from the second power line communication unit 230 , the second control unit 240 transmits a response signal transmission request corresponding to the driving signal to the second power line communication unit 230 . When receiving the driving signal from the second power line communication unit 230 , the second control unit 240 transmits a driving request to the switch 260 . When receiving the response signal from the switch 260 , the second control unit 240 transmits a measurement start request to the measurement unit 280 .

The second control unit 240 transmits a measurement start request and, upon receiving the measurement value from the measurement unit 280 , generates a measurement value storage request including the measurement value, and transmits the measurement value storage request to the second memory 250 . .

When the second control unit 240 transmits the measurement start request and receives the measurement value from the measurement unit 280 , the second control unit 240 generates a measurement value transmission request including the measurement value, and transmits the measurement value transmission request to the second power line communication unit 230 . may be

The second memory 250 stores the measurement value in response to the measurement value storage request of the second control unit 240 . In this case, the second memory 250 stores the identifier given to the smart plug 200 or the electronic device 30 and the measurement time of the measurement value in association with the measurement value.

The switch 260 normally maintains an off state (ie, a standby power cut-off state) to block AC power input from the outside from being output to the electronic device 30 . The switch 260 outputs AC power input from the outside to the electronic device 30 by switching to an ON state in response to a driving request of the second control unit 240 . The switch 260 transmits a response signal (ie, a response signal to a driving request) to the second control unit 240 after being switched to the on state.

The measuring instrument 270 is disposed on a power line connected to an external AC power source and the switch 260 to sense current, voltage, and the like flowing through the power line. The measuring device 270 outputs a measurement signal corresponding to the current, voltage, etc. flowing through the power line to the measuring unit 280 .

The measurement unit 280 generates a measurement value based on the measurement signal output from the measurement device 270 . The measurement unit 280 converts the measurement signal into a digital signal to generate a measurement value. The measurement unit 280 transmits the generated measurement value to the second control unit 240 .

Referring to FIG. 4 , the smart plug 200 may further include a second communication unit 285 that communicates with the master plug 100 through a network such as Wi-Fi or short-distance communication.

The second communication unit 285 receives a driving signal from the master plug 100 . The second communication unit 285 receives a driving signal through a network such as Wi-Fi or short-distance communication. The second communication unit 285 transmits the received driving signal to the second control unit 240 .

When the second control unit 240 receives the driving signal from the second power line communication unit 230 , it transmits a response signal transmission request corresponding to the driving signal to the second communication unit 285 . When the second communication unit 285 receives a response signal transmission request from the second control unit 240 , it transmits a response signal to the driving signal to the master plug 100 .

The second communication unit 285 may receive power schedule information from the master plug 100 . When receiving power schedule information from the master plug 100 , the second communication unit 285 transmits the power schedule information to the second control unit 240 .

When receiving the power schedule information from the second communication unit 285 , the second control unit 240 generates a schedule storage request including the power schedule information and transmits the schedule storage request to the second memory 250 . The second controller 240 controls power supply to the electronic device 30 according to the power schedule information stored in the second memory 250 .

The second memory 250 stores power schedule information when receiving a schedule storage request from the second control unit 240 .

Referring to FIG. 5 , the smart plug 200 may further include a second IR receiver 290 for receiving an infrared signal (ie, an IR signal) output from the master plug 100 .

The second IR receiver 290 receives a driving signal that is an infrared signal from the master plug 100 . The second IR receiver 290 converts the driving signal into a digital signal and transmits it to the second controller 240 .

When receiving the driving signal from the second IR receiver 290 , the second control unit 240 transmits a response signal transmission request corresponding to the driving signal to the second power line communication unit 230 or the second communication unit 285 . When the second power line communication unit 230 or the second communication unit 285 receives a response signal transmission request from the second control unit 240 , it transmits a response signal to the driving signal to the master plug 100 .

An operation in which the power management system drives the electronic device 30 will be described with reference to FIG. 6 .

When a control command for driving the electronic device 30 is input, the mobile terminal 20 transmits a control signal corresponding to the control command to the management server 10 . In this case, the portable terminal 20 transmits a control signal including first identification information corresponding to the portable terminal 20 and/or the user, a control command, and second identification information corresponding to the electronic device 30 .

The management server 10 detects the master plug 100 of the consumer based on the first identification information included in the control signal, and transmits the control signal to the detected master plug 100 .

The master plug 100 receiving the control signal from the management server 10 detects the electronic device 30 as a control target based on the second identification information of the control signal. The master plug 100 detects the smart plug 200 to which the control target is connected.

The master plug 100 transmits a driving signal to the smart plug 200 . At this time, the master plug 100 is Wi-Fi, short-range communication, power line communication. The driving signal is transmitted through infrared communication or the like. The smart plug 200 supplies power to the electronic device 30 after transmitting an Ack signal to the master plug 100 in response to the driving signal of the master plug 100 .

The master plug 100 transmits an IR control signal to the electronic device 30 after receiving the response signal from the smart plug 200 . That is, the master plug 100 transmits an IR control signal that is an infrared signal corresponding to a control command included in the control signal. The electronic device 30 operates according to the IR control signal.

The master plug 100 may transmit a plurality of IR control signals in the case of a control command related to an operation after driving, such as channel setting and temperature setting. That is, after transmitting the IR control signal corresponding to the driving command of the electronic device 30 , the master plug 100 transmits the IR control signal corresponding to the control command such as channel setting and temperature setting.

An operation in which the power management system sets the consumer's power schedule and collects measurement information according to the power schedule will be described with reference to FIG. 7 .

The management server 10 transmits the power schedule information received from the portable terminal 20 to the master plug 100 of the consumer.

The master plug 100 stores power schedule information received from the management server 10 . The master plug 100 controls the smart plug 200 and the electronic device 30 according to the stored power schedule information.

At the same time, the master plug 100 collects, from the smart plug 200 , measurement information that is the power defended by the electronic device 30 driven according to the power schedule information. The master plug 100 collects and stores measurement information including the amount of power from the smart plug 200 . The master plug 100 transmits the measurement information to the management server 10 at a set time interval and then deletes it.

On the other hand, in the embodiment of the present invention, the master plug 100 transmits an IR control signal to the control target electronic device 30 to control the electronic device 30, but the smart plug 200 through power line communication A control signal may be transmitted to the electronic device 30 .

To this end, the electronic device 30 includes a power line communication module, and when power is supplied by driving the smart plug 200 , the electronic device 30 operates in a standby mode driven by the power line communication module. When a control signal is input from the smart plug 200 through the power line communication module, the electronic device 30 operates according to the control signal.

Referring to FIG. 8 , the master plug 100 controls the smart plug 200 and the electronic device 30 based on a control command input by the user through the remote controller 40 .

First, the smart plug 200 is operated in the standby power cut-off mode, and the supply of power to the electronic device 30 is completely cut off. The user operates the remote controller 40 to control the electronic device 30 . The remote controller 40 transmits an IR control signal for controlling the electronic device 30 . Upon receiving the IR control signal from the remote controller 40 (S110; Yes), the master plug 100 controls one electronic device 30 among a plurality of electronic devices 30 disposed in the consumer based on the IR control signal. A target is detected (S120).

The master plug 100 detects the smart plug 200 connected to the electronic device 30 detected as a control target in step S120 (S130). In this case, the master plug 100 manages the electronic device 30 in association with the smart plug 200 , and detects the smart plug 200 associated with the detected electronic device 30 based on the control signal.

Of course, the management server 10 manages the electronic device 30 in association with the smart plug 200 , and the master plug 100 detects the smart plug 200 based on information managed by the management server 10 . You may.

The master plug 100 transmits a driving signal to the smart plug 200 detected in step S130 (S140). The master plug 100 transmits a driving signal to the smart plug 200 detected in step S130 using one of Wi-Fi, short-distance communication, power line communication, and infrared communication.

The smart plug 200 that has received the driving signal from the master plug 100 drives the switch 260 to output AC power input from the outside to the electronic device 30, and outputs a response (Ack) signal to the driving signal. It is transmitted to the master plug 100 .

When receiving a response signal from the smart plug 200 that has received the driving signal (S150; Yes), the master plug 100 outputs an IR control signal to the electronic device 30 to be controlled (S160). The electronic device 30 uses infrared signals having different wavelengths and frequencies for each manufacturer. Accordingly, the master plug 100 outputs an IR control signal converted from the control signal into an infrared signal corresponding to the electronic device 30 detected as a control target in step S120 . The electronic device 30 that has received the IR control signal operates according to the control signal.

The smart plug 200 generates a measurement value by measuring current, voltage, etc. consumed as the electronic device 30 is driven, and transmits measurement information including the current to the master plug 100 . The master plug 100 collects measurement information from the smart plug 200 (S170). At this time, the master plug 100 collects and stores measurement information from the smart plug 200 through a communication method such as Wi-Fi, short-distance communication, and power line communication. Here, as an example, the measurement information includes an identifier of the smart plug 200 or the electronic device 30, a measurement value, and a measurement time.

The master plug 100 transmits the measurement information collected through step S170 to the management server 10 (S180). The master plug 100 transmits the measurement information collected through step S170 to the management server 10 at a set time interval (ie, periodically). The master plug 100 may be deleted after transmitting measurement information to secure the internal memory.

Referring to FIG. 9 , the master plug 100 controls the smart plug 200 and the electronic device 30 based on power schedule information.

The mobile terminal 20 receives a power schedule and transmits power schedule information including the received power schedule to the management server 10 . The management server 10 stores the power schedule information received from the portable terminal 20 in association with the consumer or user, and transmits the power schedule information to the master plug 100 installed in the consumer. Upon receiving the power schedule information (S210; Yes), the master plug 100 detects one electronic device 30 as a control target among a plurality of electronic devices 30 disposed in the consumer based on the power schedule information ( S220).

The master plug 100 detects the smart plug 200 connected to the electronic device 30 detected as a control target in step S220 (S230). In this case, the master plug 100 manages the electronic device 30 in association with the smart plug 200 , and detects the smart plug 200 associated with the detected electronic device 30 based on the control signal.

The master plug 100 transmits a driving signal to the smart plug 200 detected in step S230 (S240). The master plug 100 transmits a driving signal to the smart plug 200 detected in step S130 using one of Wi-Fi, short-distance communication, power line communication, and infrared communication.

The smart plug 200 that has received the driving signal from the master plug 100 drives the switch 260 to output AC power input from the outside to the electronic device 30, and outputs a response (Ack) signal to the driving signal. It is transmitted to the master plug 100 .

When receiving a response signal from the smart plug 200 that has received the driving signal (S250; Yes), the master plug 100 outputs an IR control signal to the electronic device 30 to be controlled (S260). The electronic device 30 uses infrared signals having different wavelengths and frequencies for each manufacturer. Accordingly, the master plug 100 outputs an IR control signal converted from the control signal into an infrared signal corresponding to the electronic device 30 detected as a control target in step S120 . The electronic device 30 that has received the IR control signal operates according to the control signal.

The smart plug 200 generates a measurement value by measuring current, voltage, etc. consumed as the electronic device 30 is driven, and transmits measurement information including the current to the master plug 100 . The master plug 100 collects measurement information from the smart plug 200 (S270). At this time, the master plug 100 collects and stores measurement information from the smart plug 200 through a communication method such as Wi-Fi, short-distance communication, and power line communication. Here, as an example, the measurement information includes an identifier of the smart plug 200 or the electronic device 30, a measurement value, and a measurement time.

When the schedule of the power schedule information is completed (S280; Yes), the master plug 100 transmits the measurement information to the management server 10 (S290). In this case, the master plug 100 may transmit the measurement information collected through step S270 to the management server 10 at a set time interval (ie, periodically) before the schedule is completed.

Although the preferred embodiment according to the present invention has been described above, it can be modified in various forms, and those of ordinary skill in the art can make various modifications and modifications without departing from the scope of the claims of the present invention. It is understood that it can be implemented.

100: master plug 110: first power unit
120: first communication signal extraction unit 130: first power line communication unit
140: first communication unit 150: first control unit
160: first memory 170: IR transmitter
200: smart plug 210: second power supply
220: second communication signal extraction unit 230: second power line communication unit
240: second control unit 250: second memory
260: switch 270: instrument
280: measurement unit 285: second communication unit
290: second IR receiver

Claims (13)

In the master plug disposed in the receiver in which a plurality of smart plugs are disposed,
an IR receiver configured to receive an IR control signal that is an infrared control command for controlling an electronic device disposed in the house through a remote control of an electronic device to be controlled, and output the IR control signal;
In response to the IR control signal output of the IR receiver, one electronic device among a plurality of electronic devices disposed in the consumer is detected as a control target based on the infrared characteristic of the IR control signal, and a plurality of smart devices disposed in the consumer are A control unit that detects a smart plug connected to the control target from among the plugs as a control target plug, outputs a driving signal including an identifier of the control target plug, and then outputs a control signal transmission request including the control target ID and the control signal ;
a power line communication unit that converts the driving signal into a power line communication signal in response to the driving signal output from the control unit and transmits it to the control target plug; and
and an IR transmitter for converting the control signal into an IR control signal that is an infrared signal corresponding to the identifier of the control target in response to the control signal transmission request output from the controller and outputting it;
The control unit outputs the control signal transmission request to the IR transmitter when receiving a response signal corresponding to the driving signal from the control target plug, which is switched from an off state in which standby power is cut off in response to the driving signal to an on state master plug. delete According to claim 1,
The power line communication unit is a master plug for receiving a response signal to the driving signal from the control target plug to transmit to the control unit. delete delete According to claim 1,
Further comprising a communication unit for transmitting the power schedule information received from one of the management server and the mobile terminal to the control unit,
The control unit is a master plug for detecting a control target and a control target plug based on the power schedule information. 7. The method of claim 6,
The control unit outputs a schedule storage request including the power schedule information in response to the transmission of the power schedule information of the communication unit,
The master plug further comprising a memory for storing the power schedule information in response to the schedule storage request of the control unit. In the power management method performed by a master plug disposed in a customer in which a plurality of smart plugs are disposed,
receiving an IR control signal, which is an infrared control command for controlling an electronic device disposed in the consumer, through a remote control operation of an electronic device to be controlled;
detecting, as a control target, one electronic device among a plurality of electronic devices disposed in the customer house based on the IR control signal input in the receiving step;
detecting, as a control target plug, a smart plug connected to the control target from among a plurality of smart plugs disposed in the consumer based on the infrared characteristic of the IR control signal;
outputting a driving signal to the control target plug detected in the detecting with the control target plug;
When a response signal corresponding to the driving signal is received from the control target plug, which is switched from an off state in which standby power is cut off to an on state in response to the driving signal output in the step of outputting the driving signal, the control signal is controlled converting an IR control signal that is an infrared signal corresponding to an identifier of an electronic device detected as a control target in the step of detecting the target; and
and outputting the IR control signal converted in the converting step to the control target,
The step of outputting the driving signal comprises:
converting the driving signal into a power line communication signal; and
and outputting a driving signal converted into the power line communication signal to a power line connected to the control target plug. delete delete 9. The method of claim 8,
The power management method further comprising the step of receiving a response signal of the control target plug to the driving signal through a power line connected to the control target plug before the outputting step. delete 9. The method of claim 8,
Further comprising the step of receiving the power schedule information received from one of the management server and the mobile terminal,
In the detecting as the control target, a power management method for detecting a control target based on the power schedule information.

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