KR20160000757A - USN based distributed smart power management device - Google Patents

Abstract

The present invention relates to a power control device and, more specifically, to a ubiquitos sensor network (USN)-based distributed smart power control device capable of individually controlling standby power and the power consumption amount at home and in an office by applying a situation recognition computing technique.

Description

USN-based distributed smart power management device (USN based distributed smart power management device)

[0001] The present invention relates to a power control apparatus, and more particularly, to a power control apparatus using a distributed intelligent power (UWB) system based on a USN (ubiquitous sensor network), which can control standby power and power consumption in a home and a workplace, And a control device.

As the industry develops, the use of lighting, air-conditioning and household appliances and various home appliances in homes and businesses is increasing, and thus more electric energy is being used. Furthermore, due to the recent excessive power consumption, power shortage phenomenon frequently occurs and systematic management of power consumption is required.

In general, household appliances consume a certain amount of standby power if they are plugged into an outlet when in use. Standby power is the power consumed by an electric appliance even when the power is off. Since the standby power is small compared to the operating power, most of the time when the electric appliance is in the standby power supply state for a long time, the power waste is serious.

The cost of standby power is estimated to be close to 10% of domestic household power consumption. Therefore, in order to systematically manage the power consumption as described above, centralized management of standby power is required.

On the other hand, it is required to increase the power production facilities to ensure stable power reserve, but it is difficult to solve problems by securing the location of the power supply, enormous investment funding, and strengthening environmental regulations. Therefore, power management is indispensable to reduce power supply stability and power waste.

 Accordingly, the present applicant has proposed Korean Patent Laid-Open Publication No. 10-2011-0136023 (December 21, 2011, precedent document). The prior art discloses a sensor network-based power control system capable of controlling the amount of power consumption by controlling the operating state of each electric device according to a preset power consumption criterion based on basic situation information.

However, since the conventional sensor network-based power control system as described above collects and analyzes the situation information of the entire workplace in the central management unit and controls the devices installed in each place, there arises a problem in operation in the central server, There is a problem in the entire system connected to the network, so that the respective sensor nodes can not be operated individually and power control can not be performed in the entire system.

Korean Patent Publication No. 10-2014-0014602 (February 6, 2014) Korean Patent Publication No. 10-2013-0099492 (September 6, 2013)

The present invention overcomes the above-described problems of the prior art. By applying the context aware computing technology, sensor nodes installed in a specific space cooperate with each other by distributed control through a distributed control, And to provide a USN-based distributed smart power control apparatus for controlling the consumption amount.

In order to achieve the above object, a distributed smart power control apparatus based on a ubiquitous sensor network (USN) according to the present invention includes: at least one electric device installed in a specific space; A remote control sensor node for generating a control signal to remotely control the electric device according to a user request; A standby power control sensor node for supplying standby power to the electric device according to the control signal and measuring power consumption;

Wherein a control signal applied from an external terminal device is the remote control sensor node; And an external situation recognition server for causing the electric device to be transmitted to the electric device via the standby power control sensor node to turn on / off the electric device or forcibly terminate the electric device.

The external circumstance recognition server may detect a beacon message or an operation start message transmitted by the terminal, and may transmit the beacon message or the operation initiation message to the remote sensor node.

The operation start message may include an application type standby power supply command message and the electric device forced termination message.

The standby power control sensor node can measure the power consumption of the electric device when a predetermined time elapses, thereby confirming the operating state of the electric device.

The standby power control sensor node can immediately shut off the standby power when the electric device is powered off.

The external circumstance recognition server may turn on the forced termination timer of the electric device upon receiving the forced termination message of the electric device from the terminal device.

The forcible termination timer may be automatically turned on after a predetermined time elapses, thereby blocking the standby power.

If the time is not set by the forced termination timer, the standby power may be cut off immediately after the forced termination message is transmitted and the electrical equipment may be turned off.

The external circumstance recognition server may transmit the standby power request message through the remote control sensor node and the standby power control sensor node to turn on the electric device when the electric power on command of the electric device is transmitted from the terminal device .

According to the USN-based distributed smart power control apparatus according to the present invention configured as described above, groups are formed in a small number of sensor nodes without a server in a workplace, and the sensor nodes are cooperated in a group, There is an effect of reducing unnecessary standby power by controlling individual power.

1 is a block diagram illustrating a USN-based smart power control apparatus according to a preferred embodiment of the present invention.
FIG. 2 is a block diagram showing the remote control sensor node of FIG. 1 in detail;
FIG. 3 is a control flowchart for explaining an operation state of the remote control sensor node of FIG. 2;
FIG. 4 is a block diagram illustrating a standby power control sensor node of FIG. 1 in detail;
FIG. 5 is a control flowchart for explaining an operation state of the standby power control sensor node of FIG. 4;
FIG. 6 is a detailed block diagram of the human body detection sensor node of FIG. 1;
7 is a control flowchart for explaining an operation state of the human body detection sensor node of FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a block diagram illustrating a wireless communication-based smart power control apparatus according to a preferred embodiment of the present invention.

As shown in the figure, in order to control power consumption of at least one or more electric devices 140 installed in a specific space, a smart-power control device based on wireless communication according to a preferred embodiment of the present invention includes a remote- A power control sensor node 120, a human body detection sensor node 130 and an external circumstance recognition server 150.

The specific space means a place where the electric device 140 operating using electric power is installed and includes all the places where the electric device 140 such as a home, an office, a lecture room, and a workplace is installed and operated. Also, in a spatial sense, it means a zone having a certain range such as one room (room), one floor, and one building, and the range of the space may vary depending on the configuration to which the system is applied.

The electric device 140 is a device operated by using electric power and is installed in the specific space such as an air conditioner, a fan, a fan, a heater, a lighting device, a computer, a refrigerator, a TV, a washing machine, Refers to all electric devices to be installed, and may be targeted to all the electric devices installed in the specific space, or may be targeted to only some electric devices having a large electric power consumption among all the electric devices.

The remote control sensor node 110 according to the present invention controls the electric device 140 in cooperation with the standby power control sensor node 120. That is, in a state where the initial standby power and the electric device 140 are off, a user's operation start signal is sensed and a standby power supply request message is transmitted to the standby power control sensor node 120. Upon receiving a standby power supply completion response from the standby power control sensor node 120, the controller 140 turns on the electric device 140 and controls the electric device 140.

In addition, the remote control sensor node 110 may transmit information such as temperature, humidity, illuminance, infrared signal, ultrasonic signal, optical signal, thermal sensed signal, infrared signal, and infrared signal through a human body sensor node or sensor nodes performing additional functions. It is possible to collect data by sensing basic condition information such as a motion detection signal, a power consumption amount, an operation state for each electric device, a use schedule for each specific space, and a number of people for each specific space. Accordingly, the collected information may be transmitted to the user's mobile terminal or the smartphone through a sensor network communication network (not shown) or the external circumstance recognition server 150 in the form of a notification message or a beacon message.

The standby power control sensor node 120 according to the present invention supplies standby power to the electrical equipment 140 when the standby power supply command is input from the remote sensor node 110, The standby power is cut off when the standby power supply time lasts for a predetermined time or when the operation of the electric appliance is turned off.

In addition, the human sensor node 130 according to the present invention periodically senses presence or absence of a human body in a specific space and transmits sensing information to the remote sensor node 110. If a human body is not detected, the time is counted. If a predetermined waiting time is exceeded, a power shutdown request signal to the remote sensor node 110 is transmitted to the remote sensor node 110, (SP_OFF_REQ).

FIG. 2 is a detailed block diagram of the remote control sensor node of FIG. 1, and FIG. 3 is a control flowchart for explaining an operation state of the remote control sensor node of FIG. 2. Referring to FIG.

Hereinafter, the symbols shown in the drawings are as shown in Table 1 below, and a preferred embodiment of the present invention will be described with reference to the following.

sign Explanation RM_SN Remote sensor node SPC_SN Standby power control sensor node HD_SN Human body detection sensor node SP_ON_REQ Standby power supply request message SP_ON_RES Standby power supply completion response message SP_OFF_REQ Standby power cut request message DEV_ON_REQ Electronic device ON request message SP_Timer Standby power interruption waiting timer SPC_RES_Timer Maximum waiting time to receive standby power completion response message HD_Timer Human body detection time timer HD_int_timer Human body detection cycle setting timer HD_OUT_timer Elapsed Time Check Timer TMP_read_timer Temperature forced regulation cycle timer TMP_adj_wait_timer Waiting time before performing temperature control PM_timer SPC_SN is a period in which the power consumption of the electronic device is measured SP_timer Check time only standby power is supplied SP_FORCED_OFF_REQ Electric device forced shutdown message SP_FORCED_OFF_timer Electric device forced shutdown timer SP Standby Power SP ON Standby power manual feed button PC Power Consumption CA_SERVER Context Aware Server DEV Electronic Device

The remote control sensor node 110 according to the present invention detects an operation start signal of the user while the initial standby power and the electric device are off. As a result, when an operation start signal is detected, a standby power supply request message (SP_ON_REQ) is transmitted to the standby power control sensor node 220.

The remote control sensor node 110 receives a standby power supply completion response SP_ON_REQ from the standby power control sensor node 220 and transmits a signal to turn on the electric device 140, .

2, the remote control sensor node 110 of the present invention includes a battery 211 for supplying power, a temperature sensor 212 installed outside the room for collecting temperature data, A microcontroller (MCU) 214 for controlling the operation state of each part and implementing the operation of the remote control sensor node 210, a communication IC for transmitting and receiving external temperature data collected through the sensor network communication network, (215).

As shown in FIG. 3, the operation state of the remote control sensor node 110 of the present invention will be described step by step.

In step S00 (SP off & DEV off), the remote control sensor node 110 detects a signal generated when the user enters the room and uses the remote controller to turn on the device while the initial standby power and the electric devices are both off .

At this time, it is assumed that the first case of turning on the electric device 140 and the second case of turning on the device by receiving a request (DEV_ON_REQ) to turn on the specific electric device 140 from the external situation aware server. The first case is generally a case where the user directly controls the electric device 140 in the room, and the second case is a case where the user remotely controls the electric device 140 from the outside and supplies electric power to the electric cooker Or by turning on the heater or the air conditioner to adjust the temperature of the room in advance.

The remote control sensor node 110 sends a standby power supply request (SP_ON_REQ) message to the standby power control sensor node 120 so as to supply standby power in both cases and waits until a response indicating that the standby power is turned on is received in step S01 I go in.

In step S01, it is not known whether the standby power (SP) is currently supplied in a transient state (SP on? & DEV off). After receiving the standby power supply completion response (SP_ON_REQ) from the standby power control sensor node 120, the standby power control unit 120 sends a signal to turn on the electric device 140 and enters the S02 step. The time to stay in step S02 will normally not exceed a few milliseconds. If the standby power supply completion response (SP_ON_RES) is not received for a predetermined time, the flow returns to step S00.

In step S02 (SP on & DEV on), the remote sensor node 110 periodically measures the room temperature and forcibly sets the room temperature when the room temperature differs from the desired temperature. The desired temperature may be set based on a temperature preset by the user or an appropriate living temperature for each season.

For example, since the desired temperature in the summer is 27 degrees and the current room temperature is 24 degrees and the temperature difference (Threhold) is 2 degrees, (27-24)> 2, the designated time (TMP_adj_wait_timer) ) And then forcedly set the temperature of the air conditioner to 27 degrees. At this time, if the user again sets 24 degrees, it is set to 27 degrees after waiting for the designated time again.

The waiting designation time can be changed by transmitting the standby designation time information to the external situation aware server by sensing the standby designation time setting message of the user's mobile terminal and the smart phone or the infrared ray of the remote control by the remote control sensor node 110.

Step S03 (SP on & DEV on & TMP_ad_wait_timer on) is a time for staying for a while until the waiting time TMP_adj_wait_timer expires before the temperature of the electric device 140 is adjusted.

FIG. 4 is a detailed block diagram of the standby power control sensor node of FIG. 1, and FIG. 5 is a control flowchart for explaining an operation state of the standby power control sensor node of FIG.

The standby power control sensor node 120 according to the present invention supplies the standby power SP to the electric device 140 when the standby power supply command SP_ON_REQ is input from the remote control sensor node 110, The power consumption of the device 140 is measured and the standby power SP is shut off if the standby power supply time lasts more than a predetermined time or when the operation of the electric device 140 is turned off.

As shown in FIG. 4, the standby power control sensor node 120 of the present invention includes an AC power source unit 221 to which power is externally applied, and an AC power source unit 220 that rectifies AC power applied to the AC power source unit 221 A power sensor 226 electrically connected to the electric device 140 to measure a power consumption of the electric device 140 in real time, A microcontroller (MCU) 224 for controlling the operation of each part and implementing the operation of the standby power control sensor node 120, and a microcontroller (MCU) And a communication IC 225 for performing communication. At this time, the power interruption unit 223 may be a relay, a triac, and an SSR.

As shown in FIG. 5, the operation state of the standby power control sensor node 120 according to the present invention will be described step by step.

First, when an instruction (SP_ON_REQ) to supply standby power from the remote control sensor node 110 is inputted in step S10 (SP off & DEV off), the standby power control sensor node 120 transmits to the electric device 140 And supplies standby power. At this time, it is necessary to consider a situation in which the person turns on the electric device 140 manually when the person enters the room and can not find the remote controller. Since the standby power SP is in the off state, Should be. Therefore, it is desirable to implement a standby power supply (SP_ON) button to the standby power control sensor node 120 to manually supply standby power.

Step S11 (SP on & DeV off) is a temporary stay state. In step S10, when the user turns on the electric device 140 using the remote controller or when the server requests the electric device 140 to turn on the electric device 140, the remote control sensor node 110 recognizes this, A standby power supply request message (SP_ON_REQ) is sent to the controller 120.

In this case, the standby power control sensor node 120 immediately supplies standby power and waits until the device is turned on. In addition, the standby power control sensor node 120 can determine the operating state of the device by measuring the power consumption. When standby power is supplied for a predetermined period of time (SP_timer) or longer, the standby power SP is automatically turned off and returned to the original state. Conversely, when the electric device 140 is turned on, the process goes to step S12.

In step S12 (SP on & DEV on), when the standby power control sensor node 120 has elapsed a predetermined time, the power consumption of the electric device 140 is continuously measured to determine the operation state of the electric device. Accordingly, immediately after detecting that the electric device 140 is turned off, the standby power is cut off.

Step S13 (SP on & DEV on SP_FORCED_OFF_timer on) is a step in which the user remotely controls the electric device from the outside. The remote control sensor node 110 can receive the forced device termination message SP_FORCED_OFF_REQ from the external situation aware server 150 in the home or office.

The electric device forced termination message (SP_FORCED_OFF_REQ) is transmitted from the user's mobile terminal or smart phone to the external situation awareness server 150. If the user desires to forcibly terminate the home or office electrical appliance 140 from the outside, the user transmits the electrical appliance forced termination message (SP_FORCED_OFF_REQ) to the external situation aware server 150 using the mobile terminal or the smart phone, , And turns on the electric device forced termination timer (SP_FORCED_OFF_timer).

The electric device forced termination timer (SP_FORCED_OFF_timer) is set by the user for a predetermined time, and the standby power SP is automatically blocked when a predetermined time passes. If the predetermined time is not set, the standby power SP is immediately blocked and the electric device 140 is turned off.

Also, if the user wants to forcibly turn on the home or office electrical appliance 140 from the outside, the user mobile terminal or the smart phone sends an instruction (SP_ON_RES) To the remote sensor node 110 through the remote control sensor node 110. Accordingly, the remote control sensor node 110 transmits a standby power request message (SP_ON_REQ) to the standby power control sensor sensor node 120 to turn on the electric device 140.

The electric device forced termination message SP_FORCED_OFF_REQ and the standby power supply command message SP_ON_RES generated in the user mobile terminal or the smart phone are transmitted to the remote control sensor node 110 in the form of a message such as a beacon message and an operation start signal.

FIG. 6 is a detailed block diagram of the human body detection sensor node of FIG. 1, and FIG. 7 is a control flowchart for explaining an operation state of the human body detection sensor node of FIG.

The human body sensor node 130 according to the present invention periodically detects the presence or absence of a human body and transmits the sensed human body to the remote sensor node 110. When a predetermined waiting time is exceeded, And transmits a standby power cutoff request signal to the remote sensor node 110 if a human body is not detected for a predetermined time or longer.

As shown in FIG. 6, the human body sensor node 130 of the present invention includes a battery 231 for supplying electric power, a person 231 for emitting ultrasound to the vicinity of the installed port, A microcontroller (MCU) 233 for implementing the operation of the human body sensor node 130, and a communication IC 234 for transmitting and receiving the collected ultrasound data.

7, the operational state of the human body sensor node 130 according to the present invention is determined in step S20 (when the person is not in the room), step S21 (when the person is in the room), step S22 (When a person is in the room and then leaves). There are the following states of each operation state.

In step S20 (HUMAN out), the presence or absence of a person is periodically checked. When a person comes in, it stops detecting people and informs the remote sensor node RM_SN that there is a person in the room. Then, the process goes to the step S21 in which the person is detected.

In step S21 (HUMAN in), the presence or absence of a person is detected as in step S20. In particular, when the person leaves the room, the human body detection time timer (HD_Out_timer) for checking the time when there is no person is activated, and the process goes to step S22.

Step S22 (Human out & H_Out_timer on) is a state in which the user waits for a certain period of time before the power is turned off after the person leaves the temporary state. When the human body detection time timer HD_Out_timer is stopped, the remote controller sensor node 110 transmits a standby power cutoff request message (SP_OFF_REQ) to shut down the electric device 140.

In addition, the user can arbitrarily set a cycle for performing the human body detection using the human body detection cycle timer (HD_int_timer) in case of returning to the room after seeing the urgent body, (SP_OFF_REQ) to reduce the hassle of the user.

Accordingly, the remote control sensor node 110, the standby power control sensor node 120, and the human body detection sensor node 130 according to the present invention configured as described above can be individually and independently And manages the power of the room. Therefore, even if there is a problem in communication with the external context aware server or the external context aware server, the power control is performed and the system can be operated stably.

The embodiments of the present invention described in the present specification and the configurations shown in the drawings relate to the most preferred embodiments of the present invention and are not intended to encompass all of the technical ideas of the present invention so that various equivalents It should be understood that water and variations may be present. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined in the appended claims. , Such changes shall be within the scope of the claims set forth in the claims.

110: Remote control sensor node
120: Standby power control sensor node
130: human body detection sensor node
140: Electronic device
150: External context aware server

Claims (9)

One or more electrical devices installed in a specific space;
A remote control sensor node for generating a control signal to remotely control the electric device according to a user request;
A standby power control sensor node for supplying standby power to the electric device according to the control signal and measuring power consumption;
And an external situation recognition server for controlling the electric device to be on / off controlled or forcibly terminated by causing a control signal applied from an external terminal device to be transmitted to the electric device through the remote control sensor node and the standby power control sensor node USN based distributed smart power control device. The method according to claim 1,
The external situation awareness server comprises:
USN based distributed smart power control apparatus for detecting a beacon message or an operation start message transmitted by the terminal apparatus and transmitting the beacon message or the operation start message to the remote sensor node. 3. The method of claim 2,
Wherein the operation start message includes:
USN based distributed smart power control apparatus comprising an application type standby power supply command message and the electrical equipment forced termination message. The method according to claim 1,
The standby power control sensor node includes:
And a USN-based distributed smart power control device for measuring an amount of power consumption of the electric device when a predetermined time elapses. 5. The method of claim 4,
The standby power control sensor node includes:
And a USN-based distributed smart power control device for immediately shutting off the standby power when the electric device is turned off. The method according to claim 1,
The external situation awareness server comprises:
And a forced termination timer of the electric device is turned on upon receiving a forced termination message of the electric device from the terminal device. The method according to claim 6,
The forced termination timer comprises:
Based distributed smart power control apparatus that automatically turns on and blocks the standby power when a predetermined time elapses. 8. The method of claim 7,
And a USN-based distributed smart power control apparatus for shutting off the standby power immediately after the forcible termination message is delivered if the time is not set by the forcible termination timer. The method according to claim 1,
The external situation awareness server comprises:
Based on a USN-based dispersion that transmits a standby power request message through the remote control sensor node and the standby power sensor node to turn on the electric device when a power on command of the electric device is transmitted from the terminal device, Type smart power control device.

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