KR20200059387A - Smart grid system for reducing standby power loss using seperately establised standby power line - Google Patents

Abstract

According to the present invention, a smart grid standby power reducing system in which a regular power line and a standby line are installed separately includes: a power supply line including a regular power line extended from a power generation unit producing power and supplying power to an electronic device requiring regular power supply, and a standby line supplying power to an electronic device not requiring regular power supply; a consuming unit connected to one end of the power supply line to consume supplied power; a remote control terminal outputting a control signal for cutting off the power from the standby line; and a cutoff unit including a communication part connected to the remote control terminal wirelessly and by wire to transceive a control signal, and a switching part cutting off the power from the standby line. The cutoff unit includes: a first cutoff unit installed on a standby socket, which is connected to the standby line, of individual sockets in the internal space of the consuming unit; and a second cutoff unit installed on an outdoor breaker of the consuming unit. Therefore, the smart grid standby power reducing system is capable of efficiently preventing the waste of standby power.

Description

Smart grid standby power reduction system {SMART GRID SYSTEM FOR REDUCING STANDBY POWER LOSS USING SEPERATELY ESTABLISED STANDBY POWER LINE}

The present invention relates to a power saving system for reducing standby power.

With the rapid industrialization and improvement in living standards, the demand for electricity has exploded. More power plants have to be built to meet the explosively increased demand for electricity. However, the construction of the power plant takes a lot of cost and time, and it is a problem that creates an issue related to environmental pollution.

In addition, fossil fuels are limited. Since the permanence of fuel supply and demand is not guaranteed, the cost of electric energy production is increasing day by day.

Therefore, recently, technologies for increasing energy consumption efficiency of various electronic devices and technologies for reducing power consumption have been spotlighted.

According to a recent report by the Korea Energy Management Corporation, the waste of electricity caused by leaving various home appliances plugged into an outlet for 24 hours reaches about KRW 3,250 billion a year.

Therefore, it is an important problem to cut off standby power that is unnecessarily consumed in order to save electric energy.

Conventionally, in order to cut off the standby power, the power of the electrical equipment connected to the outlet is directly pulled to cut off the standby power, or a switch is attached to an individual outlet to cut off the power.

However, such a conventional technique has a problem that is quite cumbersome because the plug must be directly disconnected or the switch must be directly disconnected when an electric device is not used. Most people do not unplug unused electronic devices because of the annoyance, and as a result, the prior art has a limitation in solving the conventional problems.

The inventor of the present invention has completed the present invention after a long research effort to solve this problem.

An object of the present invention is to provide a standby power saving system based on a smart grid.

Smart Grid is a next-generation power grid business that optimizes energy use by exchanging information on electricity use in real-time by supplying and receiving electricity-related information in real time. . In particular, the present invention provides a standby power saving system that zeroes out standby power that is wasted by separating a standby line and a phase line from among smart grids.

Another object of the present invention is to provide a standby power saving system capable of efficiently reducing standby power by automatically blocking standby power according to a predetermined scenario.

On the other hand, other objects not specified in the present invention will be additionally considered within a range that can be easily inferred from the following detailed description and its effects.

In order to achieve the above object, the present invention is a power generation unit for producing electric power; A power supply line which is formed by being extended to the power generation unit, and includes a phase line for supplying power to electronic devices that need to supply power at all times and a standby line for supplying power to electronic devices that do not need to supply power at all times; A consumption unit connected to one end of the power supply line to consume the supplied power; A remote control terminal outputting a control signal to cut off the power of the standby line; And a blocking unit connected to the remote control terminal through a wired or wireless communication unit for transmitting and receiving a control signal, and a switching unit for cutting off the power of the standby line, wherein the blocking unit is selected from among individual outlets in the interior space of the consumption unit. Provides a smart grid standby power reduction system that installs by separating and installing the standby line and the standby line, including a first blocking unit installed in a standby power outlet connected to a standby line and a second blocking unit installed in an outdoor circuit breaker of the consumption unit. do.

In another embodiment, the present invention is a first blocking unit installed in the standby power outlet of the interior space of the consumption unit, the first locking unit for fixing the electric cord fastened to the first blocking unit so as not to escape from the first blocking unit Further comprising, a second locking portion covering the outer surface of the phase-inverting power outlet connected to the phase-up line among the individual outlets of the interior space of the consumption unit, the second locking portion is formed by being embedded in one end of the second locking portion It is preferable that the electric wire connected to the phase power outlet includes a through hole formed to pass through the second locking portion.

In another embodiment, the first blocking unit of the present invention includes: an alarm unit for outputting an alarm as at least one of an alarm light, an alarm sound, and an alarm signal transmitted to the remote control terminal; It is preferable to further include a departure detection sensor that detects that the electric code is forcibly released from the lock unit and outputs a departure signal to the alarm unit.

In another embodiment, the first blocking unit of the present invention further includes a timer unit for controlling the switching unit according to a preset blocking schedule to cut off the power of the standby line, and the timer unit is connected to the communication unit and the remote control terminal It is good to receive the transmitted blocking schedule and control the switching unit.

In another embodiment, in the present invention, the remote control terminal is a parent's smart phone, and the smart grid application installed on the parent's smart phone includes: a first interface capable of setting whether a room in which the first blocking unit is installed is a child's room; A second interface capable of setting a blocking schedule of the first blocking unit installed in a child's room; And a third interface that recommends a child safety mode as a blocking schedule, wherein the child safety mode blocks standby power from any one of 10 pm to 12 pm to any of 6 to 8 am the next day. Mode is good.

In another embodiment, the first blocking unit of the present invention includes a main blocking unit installed in a parent room and further comprising a first interlocking unit; And a sub-blocking unit installed in the child's room and further comprising a second interlocking unit, wherein the first interlocking unit is connected to the second interlocking unit, so that when the switching unit of the main disconnecting unit is cut off, the power of the sub-blocking unit is cut off. It works as much as possible, but it is better not to do the opposite.

In another embodiment, the present invention further includes an IoT unit installed at the entrance of the consumption unit to perform non-contact short-range wireless communication, and the IoT unit detects that the remote control terminal enters and exits the entrance, and consumes it. It is preferable to cut off standby power of a plurality of first blocking units installed in the unit.

In another embodiment, the remote control terminal of the present invention is a smart phone, and the smart grid application installed on the smart phone includes an input interface that receives a layout of the interior space of the consumption unit; A layout interface for receiving the positions of a plurality of first blocking units in the layout diagram; And the smart grid application preferably includes a monitoring interface that displays whether or not power is cut off of the plurality of first blocking units displayed in the layout and displays the amount of power used by the individual first blocking units.

According to the present invention as described above, the present invention is installed to separate the phase line and the standby line. Therefore, it is possible to individually cut off the power of the standby line. Therefore, there is an effect that can reduce the waste of standby power. Particularly, since a blocking unit for blocking a standby line is installed step by step (for example, a first blocking unit to a fourth blocking unit), standby power can be collectively blocked from a wider perspective. Therefore, there is an effect of preventing waste of standby power more efficiently.

In addition, the present invention has an effect of collectively blocking standby power of a plurality of outlets located in a specific space (home or office) without having to individually switch off the individual outlets.

On the other hand, even if the effects are not explicitly mentioned herein, it is noted that the effects described in the following specification expected by the technical features of the present invention and the potential effects thereof are treated as described in the specification of the present invention.

1 is a view schematically showing an embodiment of a standby power saving system according to the present invention.
2 is a view schematically showing an embodiment of a standby line and a blocking unit multilayer structure according to the present invention.
3 is a view showing an embodiment of a blocking unit according to the present invention.
4 is a diagram briefly explaining the concept of a control signal network configuration between a plurality of blocking units.
5 is a view showing another embodiment of a blocking unit according to the present invention.
6 is a view showing an embodiment of a lock according to the present invention.
7 is a view showing an embodiment of an IoT unit according to the present invention.

In the description of the present invention, if it is determined that the subject matter of the present invention may be unnecessarily obscured by those skilled in the art with respect to known functions related thereto, the detailed description thereof will be omitted.

1 is a view schematically showing an embodiment of a standby power saving system according to the present invention.

As can be seen in Figure 1, the standby power saving system 10 of the present invention includes a power generation unit 100, a power supply line 200, a consumption unit 300, a blocking unit 400, a control terminal 500 can do.

The power generation unit 100 produces electric power. The power generation unit 100 transmits the generated power to the consumption unit 300 through the power supply line 200.

The power supply line 200 is formed by connecting the power generation unit and the consumption unit, and extending for a long time. The power supply line 200 includes a phase change line 210 that supplies power to electronic devices that need to be supplied with power at all times, and a standby line 220 that supplies power to electronic devices that do not need to be supplied with power at all times. 1 and 2, the phase transition line is indicated by a solid line, and the standby line is indicated by a dotted line. In another embodiment, the power supply line 200 including the phase change line 210 and the standby line 220 may be installed only between the first blocking unit and the second blocking unit, or between the first blocking unit and the third blocking unit. It might be. In an embodiment in which the fourth blocking unit is not installed, the standby line 220 may not be separately installed between the power generation unit and the third blocking unit.

The consumption unit 300 is connected to one end of the power supply line, and means a specific space that consumes the supplied power. For example, it may be a home, office, or factory. The consumption unit 300 is divided into a plurality of internal spaces. For example, when the consumption unit is a home, there may be a parent room and a child room. In addition, there are a plurality of outlets in the interior space of the consumption unit 300. The outlet includes an outlet connected to the phase line and an outlet connected to the standby line. The outlet connected to the standby line may be provided with a blocking unit, and the outlet connected to the phase line may be provided with a locking device.

The blocking unit 400 is combined with an outlet installed inside the consumption unit to cut off standby power supplied to the outlet. The blocking unit 400 may include a communication unit connected to a remote control terminal through a wired or wireless communication to transmit and receive the control signal, and a switching unit to cut off the power of the standby line.

The control terminal 500 outputs a control signal to cut off the power of the standby line. In a preferred embodiment, the control terminal 500 can transmit the control signal directly to the blocking unit. In this case, there is no need for a separate network server. In another embodiment, the control terminal 500 outputs a control signal to a network server. The network server that receives the control signal controls the blocking unit connected by wire or wirelessly.

In a preferred embodiment, the control terminal 500 may be a computing device installed in a fixed position in the interior space of the consumption unit 300. In addition, in another embodiment, the control terminal 500 may be a remote control terminal movable in the space inside the consumption unit 300. The remote control terminal may be the user's smartphone or remote control.

[Step-by-Step Separation Law]

2 is a view schematically showing an embodiment of a standby line and a blocking unit multilayer structure according to the present invention.

As can be seen in Figures 1 and 2, the standby line of the present invention is installed separately from the phase line. A standby unit is installed in the standby line to cut off standby power.

In a preferred embodiment, the blocking unit 400 may include first blocking units to fourth blocking units 410 to 440. The first blocking units to the fourth blocking units 410 to 440 are installed step by step at the branch point of the standby line connected from the power generation unit to the consumption unit.

In a preferred embodiment, the first blocking unit 410 is installed in a standby power outlet connected to the standby line among individual outlets in the interior space of the consumption unit 300. For example, the first blocking unit 410 (a) may be installed in the parent room 310, and the first blocking unit 410 (b) may be installed in the child room 320.

The second blocking unit 420 may be installed in the outdoor circuit breaker 330 outside the consumption unit 300. Compared with the first blocking unit blocking standby power of the individual outlets, when the second blocking unit 420 is blocked, there is an effect of blocking the power of all standby lines included in the consumption unit 300. Accordingly, the second blocking unit 420 is controlled by the control terminal 510 having the authority to control the standby power of the individual consumption unit 300.

The third blocking unit 430 may be installed in a repeater that supplies power to a group of consumption units including a plurality of consumption units 300. In a preferred embodiment, the third blocking unit 430 may be installed in the household distribution panel 340. Compared with the second blocking unit blocking the standby power of the individual consuming unit 300, when the third blocking unit 430 is blocked, the power of all standby lines included in the plurality of consuming units 300 can be blocked. have. Therefore, the control authority of the third blocking unit 430 needs to be specially managed. For example, if the third blocking unit 430 is blocked, the standby power of all households in one apartment can be blocked, and thus it is controlled by the control terminal 570 having special management authority. For example, the control terminal 570 that controls the third blocking unit 430 may block the third blocking unit 430 in an emergency situation of power supply and demand, such as when the power consumption of the summer skyrockets.

The fourth blocking unit 440 is installed in the power generation unit, and may be installed in a standby line for supplying power to a group of consumption units including a plurality of household distribution panels 340. When the fourth blocking unit 440 is cut off, power of all standby lines included in a specific area can be cut off. For example, when the fourth blocking unit 440 is blocked, standby power in a specific industrial area can be blocked. Therefore, the fourth blocking unit 440 is controlled by the control terminal 590 having special management authority. For example, the control terminal 590 that controls the fourth blocking unit 440 may be a control terminal having a security function. If the standby power of a specific research area is cut off collectively, the computer of the research area cannot be operated. Therefore, data leakage through a computer can be fundamentally blocked. As will be described in detail again, in order to cut off the power of the electronic devices connected to the standby power and perform a security function, a configuration such as a locking unit that prevents the outlet connected to the power supply line from being used arbitrarily may be additionally required.

Thus, the present invention can be installed by hierarchically structured the blocking unit. Therefore, it is possible to construct a smart grid standby power reduction system in more detail. If necessary, it is to build a foundation to cut off standby line power in a specific area as well as a specific consumption unit at a time.

 [Example of blocking unit]

3 is a view showing an embodiment of a blocking unit according to the present invention.

3, the blocking unit 400 may include a communication unit 401, an outlet 403, a timer unit 405, a departure detection sensor 407, and an alarm unit 409.

The communication unit 401 receives a control signal for controlling on / off of the blocking unit. Further, the communication unit 410 may retransmit the received control signal to another adjacent blocking unit. That is, by transmitting the control signal transmitted from the control terminal to another adjacent blocking unit, it is possible to control another blocking unit that has not received the control signal of the control terminal according to the control signal. A detailed embodiment of the blocking unit control network will be described later.

The switching unit 403 is connected to the outlet and cuts off power supply to the standby line connected to the outlet. In a preferred embodiment, the switching unit 403 may be a magnetic switch, but is not limited thereto.

Meanwhile, the outlet may be included in the blocking unit. In the case of such an embodiment, when a new building is built, a blocking unit and an outlet may be used together. The outlet and the blocking unit are not installed separately, but are integrally installed. On the other hand, in other embodiments, the outlet may be a concept separate from the blocking unit. It is a concept to improve by attaching a blocking unit to a conventionally buried outlet.

The timer unit 405 controls the switching unit according to a preset blocking schedule to cut off the power of the standby line. To this end, the timer unit 405 may include a memory unit that receives and stores the blocking schedule sent by the remote control terminal, and a calculation unit that controls the switching unit according to the stored blocking schedule.

Even if the blocking unit does not receive a control signal from the control terminal at any time as the timer unit 405 is built in, the blocking unit of the present invention can cut off standby power according to a predetermined schedule and situation by itself.

Accordingly, the efficiency of standby power reduction is greatly increased. In the case of the prior art, standby power was wasted because the standby power was not cut off when the user forgot or was troublesome. However, according to the present invention, such waste can be prevented.

There are various embodiments of predetermined schedules and situations. There may be a schedule according to the same time to cut off the standby power at midnight, and a schedule according to the same place to block the blocking unit to which the child's computer is connected. In the case of an office, there may be a schedule according to security, such as cutting off standby power of a disconnect unit connected to a computer handling corporate confidentiality on weekends and late at night.

The departure detection sensor 407 detects that the electric cord is forcibly released from the blocking unit. In another embodiment, the departure detection sensor 407 may detect that the electric code is forcibly released from the lock unit, and output a departure signal to the alarm unit.

In another embodiment, the departure detection sensor 407 may automatically cut off the standby power of the blocking unit when it detects that the electric code is forcibly released from the lock.

The departure detection sensor 407 may detect that the electronic device connected to the corresponding blocking unit is changed beyond detecting that the electric cord is deviated. For example, it is possible to detect this by comparing the hardware-specific characteristics of the electronic devices connected to the blocking unit. It can store and compare the device's own ID, such as the network name, CPU ID, or Mac address of the corresponding electronic device, and compares the amount of power consumed by the electronic device on average to detect whether the electronic device has been changed. You may.

Accordingly, the user cannot arbitrarily change the electronic device connected to the blocking unit. Therefore, there is an effect that can prevent the problem that the computer in the child's room is randomly operating at midnight.

The alarm unit 409 outputs an alarm as at least one of an alarm light, an alarm sound, and an alarm signal transmitted to a remote control terminal when a departure or change signal of an electronic device is received from the departure detection sensor 407.

In a preferred embodiment, the blocking unit may further include a first locking portion 415. The first locking unit 415 is installed in the standby power outlet of the interior space of the consumption unit, and is a means for physically fixing the electric cords fastened to the first blocking unit 415 so as not to escape from the first blocking unit. The first locking part 415 may be connected to the departure detection sensor 407.

 [Blocking unit control network]

4 is a diagram briefly explaining the concept of a control signal network configuration between a plurality of blocking units.

In a preferred embodiment, a plurality of blocking units can be connected wirelessly. That is, the blocking units in the wireless communication range of the blocking unit are connected to each other. Specifically, as can be seen in FIG. 4, the control terminal 410 (1) is connected to the control terminal 410 (2) and the control terminal 410 (3) in the wireless communication range. In addition, the control terminal 410 (2) is connected to the control terminal 410 (4) and the control terminal 410 (5) in the wireless communication range. In addition, the control terminal 410 (3) is connected to the control terminal 410 (5) in the wireless communication range. In this way, a plurality of control terminals in the wireless communication range are wirelessly connected to form one blocking unit control network.

Accordingly, even if the control terminal 510 transmits a control signal to the specific control terminal 410 (1), this control signal is propagated from the control terminal 410 (1) to the control terminal 410 (2) and the control terminal 410 (3) , It can be propagated from the control terminal 410 (2) to the control terminal 410 (4) and the control terminal 410 (5).

However, in other embodiments, the plurality of blocking units may be connected by wire. When one of the plurality of blocking units connected by a wire receives a control signal from the control terminal, the control signal may be propagated to another blocking unit.

The above-described example described that the control terminal 500 directly transmits the control signal to the blocking unit. In this case, there is no need for a separate network server. However, in another embodiment, the control terminal 500 may output a control signal to a network server. The network server that receives the control signal controls the blocking unit connected by wire or wirelessly.

[Physical connection between blocking units]

5 is a view showing another embodiment of a blocking unit according to the present invention.

In a preferred embodiment, the main blocking unit in the first space of the consuming unit may be physically connected to the sub blocking unit in the second space, which is another space. It is a different concept from the blocking unit control network described above. This is an embodiment for forcibly and physically immediately turning off the sub-blocking unit when the main blocking unit is turned off. It is a separate control configuration from the blocking unit control network, a safer control configuration from hacking or manipulation through communication, and a very simple control configuration because it is not through a complex control network.

For example, as can be seen in FIG. 5, the main blocking unit 411 is installed in the parent room and further includes a first interlocking unit 412 and a second interlocking unit 414 is installed in the child's room. Sub-blocking unit 413 may be installed. The first interlocking unit 412 is connected to the second interlocking unit 414, and operates when the switching unit of the main blocking unit 411 is cut off, so that the power of the sub blocking unit 413 is cut off. However, it does not work in reverse. That is, when the sub blocking unit is blocked, it does not block the main blocking unit.

 [lock]

6 is a view showing an embodiment of a lock according to the present invention.

The locking portion of the present invention is installed in an outlet or a blocking unit to prevent the electric cord from being detached or changed. For example, it is a configuration for preventing the electric cord from being disconnected from the disconnecting unit to which the computer of the child's room is connected to the outlet connected to the phase-in line.

As can be seen from FIG. 6, the locking part 470 of the present invention may have a configuration as shown in FIG. 6 (b), which is connected in a cover form over an outlet such as FIG. 6 (a). The locking unit 470 may be simultaneously connected to both an outlet to which the phase line is connected and an outlet to which the standby line is connected.

The locking part 470 secures the upper cover 471 covering the outer surface of the outlet and the upper cover 471 to the outlet and allows the upper cover 471 to rotate (so that the outlet can be connected or released). It may include a fixing member 473, a through-hole 475 formed by being embedded in one end of the upper cover 471, and a through-hole 477 formed to allow an electric wire connected to an outlet to pass through the upper cover 471. have.

Although not illustrated, the mechanical configuration of the locking portion 470 may have various embodiments. A rotating fastener may be built in the outlet, and the rotating fastener may be configured to connect the electric cord to the outlet by inserting the electric cord into the outlet and rotating a predetermined angle.

Although not shown, the locking unit can receive the fastening and exit signals of the electric cord from the control terminal (may also be received through the blocking unit).

[Internet of Things]

7 is a view showing an embodiment of an IoT unit according to the present invention.

The present invention may include a first Internet of Things unit and a second Internet of Things unit. The first object internet unit is installed at the entrance of the consumption unit to perform non-contact short-range wireless communication. The second Internet of Things unit is portable by the user and performs non-contact short-range wireless communication. The first Internet of Things unit detects that the second Internet of Things unit is entering and exiting the entrance, and cuts off standby power of the plurality of first blocking units installed in the consumption unit.

Specifically, as can be seen in FIG. 7, the first object internet unit 550 may be installed near the door 350 of the consumption unit 300. The second Internet of things unit 560 may be attached to the user's smartphone, or may be the user's wearable device. The first Internet of Things unit 550 detects that the second Internet of Things unit 560 is entering and exiting the door 350, and the standby power of the plurality of first blocking units 410 installed in the consumption unit 300 is detected. Can be blocked.

Specifically, only standby power of a predetermined blocking unit among a plurality of first blocking units 410 installed in the consumption unit 300 may be selectively blocked. For example, when the second object internet unit 560 passes through the door 350, only standby power of the blocking unit connected to the computer in the child room 320 may be selectively blocked.

In another embodiment, the first Internet of Things unit may be a plurality. For example, a plurality of first object Internet units may be installed at a front door, a parent visit, and a child visit. The first thing internet unit serves to detect the second thing internet unit. The first Internet of Things unit detects the second Internet of Things unit and determines whether the second Internet of Things unit is in a specific space. That is, the first object internet unit installed at the front door determines whether the second object internet unit is inside the house. The first object internet unit installed in the parent visit determines whether there is a person in the parent room.

A plurality of second object Internet units may also be provided. For example, the plurality of second object internet units may be a second object internet unit owned by a parent and a second object internet unit owned by a child. In this case, the second Internet of Things unit represents the person who owns the second Internet of Things object.

The following application is possible when a plurality of first Internet of Things units and a plurality of second Internet of Things units are combined. For example, when the parent's second object internet unit passes through the first object internet unit installed at the parent visit, the parent room light may be turned on, or the standby power blocking may be released from the first blocking unit installed in the parent room. .

That is, the first object internet unit can detect whether or not there is a second object internet unit in a specific space, and the second object internet unit predetermines an action to be performed when entering or leaving a specific space (such as on / off the first blocking unit). Can be set.

The embodiments so far have exemplified the house, but the space in which the first and second IoT units operate may be expanded.

For example, the first object internet unit may be installed at an apartment door, an elevator entrance, or the like. The second Internet of Things unit may be configured to block standby power of the second blocking unit and the third blocking unit, including the first blocking unit.

 [Application Interface]

In a preferred embodiment, the remote control terminal is a parent's smartphone, and a smart grid application may be installed on the smartphone. The smart grid application installed on the parent's smartphone includes a first interface that can set whether the room where the first blocking unit is installed is a child's room, and a second interface that can set a blocking schedule of the first blocking unit installed in the child's room. And a third interface that recommends a child safety mode as a blocking schedule.

The user can conveniently set the standby power cut-off schedule of the cut-off unit installed in the child's room through the first and second interfaces. On the other hand, the third interface may recommend the 'child relief mode' to the user. For example, the child safety mode may be a mode that cuts off standby power from any one of 10 pm to 12 pm to any one of 6 am to 8 am the next day. When using the third interface, the user does not need to input the blocking schedule in a hassle.

In another embodiment, the smart grid application installed in the smart phone, an input interface for receiving a layout of the interior space of the consumption unit, a layout interface for receiving the positions of a plurality of first blocking units in the layout, and displayed on the layout It may include a monitoring interface for displaying whether or not the power of the plurality of first blocking unit is cut off and the amount of power used by the individual first blocking unit. Through such an interface, the user can easily port the internal space layout of the consumption unit used by the user to the application, and monitor whether the first blocking unit installed in the layout is blocked and the amount of power used.

The scope of protection of the present invention is not limited to the description and expression of the embodiments explicitly described above. In addition, it is pointed out again that the scope of the present invention may not be limited by the obvious changes or substitutions in the technical field to which the present invention pertains.

Claims (5)

It is formed extending from the power generation unit that produces electric power, and supplies electric power to electronic devices that must be supplied at all times.
A power supply line including a phase line and a standby line for supplying power to electronic devices that do not always need to supply power;
A consumption unit connected to one end of the power supply line to consume the supplied power;
A remote control terminal outputting a control signal to cut off the power of the standby line; And
The remote control terminal is connected to the wired or wireless communication unit for transmitting and receiving a control signal, and a blocking unit including a switching unit for cutting off the power of the standby line,
The blocking unit includes a first blocking unit installed in a standby power outlet connected to the standby line among individual outlets in the interior space of the consumption unit, and a second blocking unit installed in an outdoor circuit breaker of the consumption unit,
Smart grid standby power reduction system that installs the phase line and standby line separately.
The method of claim 1
The first blocking unit installed in the standby power outlet of the interior space of the consumption unit further includes a first locking unit for fixing the electric cord fastened to the first blocking unit so as not to deviate from the first blocking unit,
It includes a second locking portion covering the outer surface of the phase-out power outlet connected to the phase-up line among the individual outlets in the interior space of the consumption unit, the second lock-up portion is formed by being embedded in one end of the second lock-up portion The connected wire includes a through hole formed to pass through the second locking portion,
Smart grid standby power reduction system that installs the phase line and standby line separately.
The method of claim 2
The first blocking unit,
An alarm unit for outputting an alarm as at least one of an alarm light, an alarm sound, and an alarm signal transmitted to the remote control terminal;
Further comprising a departure detection sensor for detecting that the lock is forcibly detached from the electric power, and outputs a departure signal to the alarm unit,
Smart grid standby power reduction system that installs the phase line and standby line separately.
The method of claim 1
The first blocking unit,
Further comprising a timer unit to cut off the power of the standby line by controlling the switching unit according to a preset blocking schedule,
The timer unit includes a memory unit for receiving and storing the blocking schedule sent by the remote control terminal, and a calculation unit for controlling the switching unit according to the stored blocking schedule,
Smart grid standby power reduction system that installs the phase line and standby line separately.
The method of claim 4,
The remote control terminal is a parent's smartphone, the smart grid application installed on the parent's smartphone,
A first interface capable of setting whether a room in which the first blocking unit is installed is a child's room;
A second interface capable of setting a blocking schedule of the first blocking unit installed in a child's room; And a third interface that recommends a child safety mode as a blocking schedule,
The child safety mode is a mode to cut off standby power from any one of 10 pm to 12 pm to any one of 6 am to 8 pm the next day,
Smart grid standby power reduction system that installs and separates the standby line and the standby line.

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