KR20170136816A - Power management device and method - Google Patents

Abstract

The present invention relates to a centralized power management apparatus and method. The centralized power management apparatus includes a main breaker for receiving power from the outside and supplying it to a load located in a building area divided into a plurality of separation spaces, a plurality of distribution breakers for receiving power from the main breaker and supplying independently power to load in each of the separation spaces, a plurality of breaker terminal blocks respectively connected to the distribution breaker, a plurality of system blocking parts located between the circuit breaker terminal block of each of the separation spaces and the load, and a blocking control part for controlling the plurality of system blocking parts. It is possible to prevent fire caused by overload and short circuit.

Description

[0001] POWER MANAGEMENT DEVICE AND METHOD [0002]

The present invention relates to a centralized power management apparatus and method, and more particularly, to a centralized power management apparatus and method capable of integrally managing an apartment wiring and an electric wiring apparatus in a building.

Generally, in order to save electric energy in the building, it can be achieved by efficiently controlling unused loads.

For this purpose, separate control panels must be installed to control unused lighting, receptacles, etc. In order to do this, a relay and a control controller must be installed to enable comprehensive monitoring and control.

In addition, in order to prevent standby power, there is a disadvantage that the user needs to separate the hand-held plug or operate a separate switch to disconnect the plug of the unused electric appliance from the outlet. There was a drawback that the effect was insufficient.

In order to solve this problem, power control is performed based on a separate sensing sensor. However, there is a problem that unnecessary electric energy is wasted due to continuous operation of the sensor unit.

(Patent Document 1) Patent Registration No. 10-1301755 (Patent Document 2) Published Japanese Patent Application No. 10-2011-0106263 (Patent Document 3) Published Unexamined Patent Application No. 10-2008-0068285 (Patent Document 4) Patent Registration No. 10-1306198

The present invention has been devised to solve the above-mentioned problems, and it is an object of the present invention to provide an apparatus and a method for controlling an electric power source and an outlet of a boiler or a gas valve, The present invention provides a centralized power management apparatus and method capable of diagnosing a fault such as a short circuit due to separation of wiring and performing various control through a passive type, automatic type, and standby power type.

A main breaker for supplying power to the load placed in a building area divided into a plurality of separation spaces according to the present invention and supplying the power to the load; A plurality of breaker terminal blocks respectively connected to the distribution breaker, a plurality of system breakers located between the breaker terminal blocks of each separation space and the loads, and a plurality of system breakers for controlling the plurality of system breakers And a controller for controlling power consumption of the power supply.

The system shut-off unit includes a plurality of light cut-off units for controlling on / off of each of a plurality of light loads according to a signal of a user or a cut-off control unit, A plurality of standby power control units for controlling the standby power of other loads connected to the plurality of sockets, and a system terminal unit connected to the light blocking unit and the outlet shedding unit, do.

And the light blocking part and the outlet blocking part use a two-line short-circuitable switch of a type in which both manual control and automatic control are possible.

The shutdown control unit includes an overload detection unit for detecting an overload, a current sensing unit for sensing an overcurrent, a communication unit for receiving a management signal from outside through communication, a user input unit for receiving a control signal, an overload detection unit, And an integrated controller for controlling the system breaker, the main breaker, and the distribution breaker by analyzing signals received from the user input unit or the communication unit and the separate standby power information.

The shut-off control unit includes a gas switch management unit that manages a gas switch that controls gas supply, a boiler management unit that controls boiler operation, a power supply unit that receives power, and a shutdown control unit that minimizes the sensing and communication operations of the shut- A power management unit, and an alarm unit for generating a warning sound through an alarm, and a display unit for displaying information.

In the case of the manual mode, the integrated controller turns off the operation of the overload detection unit and the current detection unit so that the user can directly control all the circuit breakers and the system shutoff unit. In case of the automatic mode, And in the case of the standby power mode, the operation of all parts including the part for standby power control is activated.

In accordance with another aspect of the present invention, there is provided a method of managing power using a centralized power management apparatus, the method comprising: selecting one of a manual mode, an automatic mode, and a standby power mode; When overload is detected and overcurrent is detected, it is determined whether or not standby power is generated, and a control signal for controlling the circuit breaker when the overload, overcurrent and standby power is generated, And automatically stops the power supply to the load by providing a control signal for controlling the circuit breaker and the system breaking unit when an overload and an overcurrent are generated in the case where the user selects the automatic mode, If the user selects manual mode, the breaker and system breaker must be manually It provides a centralized power management method characterized in that control.

And the interruption of the power supply cuts off two line modes connected to the load.

As described above, the present invention allows the operator to separately control the lamps and the outlets of each place and the boiler or the gas valve in one place, thereby preventing an overload and a fire caused by a short circuit, and reducing unnecessary power consumption. Diagnosis of faults such as short circuit due to separation of wiring can be performed, and various controls can be performed through passive type, automatic type and standby power type.

1 is a block diagram of a centralized power management apparatus in accordance with an embodiment of the present invention.
2 is a block diagram of a system blocking unit according to one embodiment.
3 is a block diagram of a block control unit according to an embodiment;
4 is a flowchart illustrating a centralized power management method according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It will be apparent to those skilled in the art that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to let you know. Wherein like reference numerals refer to like elements throughout.

It is to be clarified that the division of components in this specification is merely a division by main function which each component is responsible for. That is, two or more constituent parts to be described below may be combined into one constituent part, or one constituent part may be divided into two or more functions according to functions that are more subdivided. In addition, each of the constituent units described below may additionally perform some or all of the functions of other constituent units in addition to the main functions of the constituent units themselves, and that some of the main functions, And may be carried out in a dedicated manner. Accordingly, the presence or absence of each component described in this specification should be interpreted as a function. For this reason, it is clear that the centralized power management apparatus and method of the present invention can be varied within the scope of achieving the object of the present invention.

1 is a block diagram of a centralized power management apparatus in accordance with an embodiment of the present invention. 2 is a block diagram of a system blocking unit according to one embodiment. 3 is a block diagram of a block control unit according to an embodiment.

1 to 3, the centralized power management apparatus according to the present embodiment includes a main breaker 100 for supplying power to the load located in a building area divided into a plurality of separation spaces from outside, A plurality of distribution breakers 200 supplied with power from the main breaker 100 to independently supply power to the loads of the respective separation spaces and a plurality of breaker terminal blocks 300 connected to the distribution breaker 200, A plurality of system shutoff units 400 positioned between the circuit breaker terminal block 300 and the load in each separation space and a shutoff control unit 500 for controlling the plurality of system shutoff units 400.

The main breaker 100 receives power from an external transformer and provides it to the separation space of the building. At this time, the building may be an apartment or a space similar to an office. Of course, the present invention is not limited to this, and may be a variety of dry objects which can be separated into a plurality of spaces such as a warehouse and a factory. In the present embodiment, since various types of main breaker 100 can be used, no particular limitation is made in the present description.

A plurality of distribution circuit breakers 200 are installed for each space corresponding to the separation space of the building. Although the conventional circuit breaker is provided with the circuit breaker according to the purpose, it is effective to install the circuit breaker in each space unit in this embodiment. That is, in the past, electric lamps and outlets were grouped and each of the breakers corresponding to this group was installed. However, in the present embodiment, in the case of a space apartment, the breaker is installed in a living room, a room, a small room, a kitchen, a toilet, etc.

The breaker terminal block 300 provides the power supplied from the distribution breaker 200 to the loads of the corresponding separation space. In this embodiment, the breaker terminal block 300 having various shapes and configurations can be provided. It is effective that the circuit breaker terminal block 300 having such a number or more is provided according to the number of loads in the separation space.

The system interrupter 400 includes a plurality of light interrupters 410 for controlling on / off of each of a plurality of light loads according to a signal of the user or the interrupter controller 500, A plurality of standby power control units 430 for controlling the standby power of other loads connected to the plurality of outlets, and a plurality of standby power control units 430 for controlling on / off of other loads connected to the outlets, And a system terminal portion 440 connected to the power outlet 410 and the outlet shutoff portion 420.

It is possible to use a light switch for manually turning on and off the light switch 410 of the present embodiment. It is effective to use a touch-type light switch which can be turned on and off automatically according to the control signal of the cut-off control unit as well as the user's operation. At this time, it is preferable that the lamp shut-off unit 410 is short-circuited (opened) or connected to both of the two power lines provided as electric lamps. This can reduce power consumption compared to shorting only one power line.

A two-line short-circuitable switch of a type that can be manually controlled and automatically controlled can be used as the light blocking part 410. This makes it possible to reduce the power consumption for automatic control since the automatic control does not operate completely when the entire system is in the manual mode.

Although it is possible to use a switch that can be manually turned on / off by a user, it is preferable to use a touch-type outlet switch. It is also preferable that the outlet shutoff part 420 short-circuits or connects both of the two power supply lines provided in the outlet. It is preferable to use a two-line short-circuiting switch of the type in which manual control and automatic control are both possible, such as the light intercepting part 410 mentioned above.

The standby power control unit 430 controls the outlet shutoff unit 420 to reduce standby power due to other loads connected to the outlet. The standby power control unit 430 senses the standby power and automatically operates the outlet shutoff unit 420 according to the standby power to reduce standby power of the other loads.

Of course, the standby power control unit 430 may be located between two wirings connected to the outlet, and control the generation of standby power by controlling the wiring contact. To this end, the standby power controller 430 can use a standby power switch. At this time, it is effective to have a structure in which two wires can be disconnected in one switch because the two wires are simultaneously disconnected.

In this embodiment, the shutdown control unit 500 is provided for centralized control of the power in the building. The shutdown control unit 500 controls each of the main circuit breaker 100, the distribution circuit breaker 200, the breaker terminal block 300, and the plurality of system shutters 400.

The shutdown control unit 500 includes an overload detection unit 510 for detecting an overload, a current sensing unit 520 for sensing an overcurrent, a gas switch management unit 530 for managing a gas switch for controlling gas supply, A communication unit 550 for receiving a management signal from outside through communication, a user input unit 560 for receiving a control signal, an overload detection unit 510, a current detection unit 520, The main breaker 100 and the distribution breaker 200 by analyzing the signal received through the user input unit 560 or the communication unit 550 and the separate standby power information and controls the system interrupter 400, And an integrated controller 570 for controlling operations of the management unit 530 and the boiler management unit 540. [ A power management unit 502 for minimizing the sensing and communication operations of the cut-off control unit 500 in the manual mode, and an alarm unit 503 for generating a warning sound through an alarm, And a display unit 504 for displaying information. At this time, the integrated controller 570 may control the entire operation by separating into the manual mode, the automatic mode, and the standby power mode according to the input signals of the user input unit 560 and the communication unit 550. A detailed description thereof will be described later. The input unit 560 and the display unit 504 may be implemented as a single device using the touch display device. The standby power information may be provided through the standby power controller 430. [

The overload detection unit 510 detects whether an overload has occurred and provides the detection result to the integrated control unit 570. At this time, the integrated controller 570 can correctly inform the position of the system shutoff unit 400 in the area where the overload occurs. This is possible because each system shutoff unit 400 is given a unique number. The integrated controller 570 prevents a further load from being connected through a control signal for controlling the light blocking part 410 or the outlet blocking part 420 when an overload is generated by the overload detection part 510 . Thereafter, the alarm unit 503 can notify the user of the occurrence of an overload. Or communicating the occurrence of an overload to a user located at a remote location through the communication unit 550.

The current sensing unit 520 senses whether an overcurrent is generated and controls the corresponding distribution circuit breaker 200 to cut off the power supply when the overcurrent is generated, It is possible to shut off the power supply by controlling the outlet shielding part 420. [ In addition, the user may be informed of the overcurrent condition.

The gas switch management unit 530 and the boiler management unit 540 manage the operations of the gas switch 530 and the boiler management unit 540. The gas switch management unit 530 and the boiler management unit 540 can manage the operations of the gas switch management unit 530 and the boiler management unit 540 and can be configured separately from the user input unit 560 and the display unit 504. This allows users to control them individually via separate devices. In addition, the gas switch and the boiler may be externally managed through the communication unit 550.

The communication unit 550 may receive a management and control signal from a user through wired / wireless communication, or may notify the user when an error occurs. At this time, the communication method can use various wireless communication methods such as Wi-Fi and short-range communication, and it is possible to use various wired communication methods such as Ethernet.

The user input unit 560 receives management and control signals from a user through a separate input device. At this time, it is effective to use the touch panel as the user input unit 560.

Alternatively, the user input unit 560 may include one user input unit 560 for each system shutting unit 400. This makes it possible to control the system shut-off part separately.

The integrated controller 570 detects the overload and the overcurrent, detects the standby power, and controls the operation of each system shutoff unit 400 according to the user's control signal as well as the detection result.

The integrated controller 570 turns off the operation of the overload detection unit 510 and the current detection unit 520 when the user mode is the manual mode and sets the separate breaker for operating the breakers and the system breaker 400 No control or command signal is generated. This allows the user to manually control all circuit breakers and system breakers directly. This is a mode for minimum power usage, and it is possible to suppress power loss due to each sensing part and signal generation when it is used. In the case of the automatic mode, the integrated controller 570 turns on the whole operation but turns off only the portion for standby power control. In the case of the standby power mode, the operation of all the parts including the part for standby power control is normalized.

The power supply unit 501 is supplied with external power and the power management unit 502 is connected to the power supply unit 500 and the system shutdown unit 400 according to the above- And controls its operation.

In the following, a centralized power management method having the above-described configuration will be described. At this time, the operation of the cut-off control unit will be mainly described.

4 is a flowchart illustrating a centralized power management method according to an exemplary embodiment of the present invention.

As shown in FIG. 4, the user selects one of a manual mode, an automatic mode, and a standby power mode (S110).

When the user selects the standby power mode (S120), the overload detection and the overcurrent detection are performed, and it is determined whether standby power is generated or not. At this time, at the time of overload, overcurrent, and standby power generation, a breaker is controlled or a control signal for controlling the system breaker is provided to automatically shut off the power supplied to the load. At this time, two line modes connected to the load are controlled. It also provides control signals to control the gas switch and boiler to control their operation.

When the user selects the automatic mode (S130), it detects overload and overcurrent. In addition, when an overload and an overcurrent are generated, a control signal for controlling the circuit breaker and the system breaker is provided to automatically shut off the power supply to the load.

If the user selects the manual mode (S140), the control unit does not generate a signal other than the management signal for managing the gas switch and the boiler, and manually operates the circuit breaker and the system breaking unit.

At this time, mode selection can be directly input through the input unit, and input through wired / wireless communication is possible.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. 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 or scope of the following claims.

100: Main breaker 200: Multiple distribution breakers
300: Circuit breaker terminal block 400:
410: light blocking part 420:
430: standby power control unit 440:
500: Blocking control unit 510: Overload detection unit
520: current sensing unit 530: gas switch management unit
540: boiler management unit 550: communication unit
560: User Inputs 570: Integrated Controller

Claims (8)

A main breaker for supplying power to the load located in a building area divided into a plurality of separation spaces from outside and supplying the load;
A plurality of distribution breakers for receiving power from the main breaker and supplying power independently to loads in the respective separation spaces;
A plurality of breaker terminal blocks respectively connected to the distribution breaker;
A plurality of system shut-off portions located between the circuit breaker terminal block and the load of each separation space; And
And a shutdown control unit for controlling each of the plurality of system shutdown units.
The method according to claim 1,
The system shut-off unit includes a plurality of light cut-off units for controlling on / off of each of a plurality of light loads according to a signal of a user or a cut-off control unit, A plurality of standby power control units for controlling the standby power of other loads connected to the plurality of sockets, and a system terminal unit connected to the light blocking unit and the outlet shedding unit, A centralized power management device. 3. The method of claim 2,
Wherein the electric power cut-off unit and the outlet cut-off unit use a two-line short-circuitable switch of a type in which manual control and automatic control are both possible.
The method according to claim 1,
The shutdown control unit includes an overload sensing unit for sensing an overload, a current sensing unit for sensing an overcurrent, a communication unit for receiving a management signal from outside through communication, a user input for receiving a control signal, an overload sensing unit, And a central controller for controlling the system breaker, the main breaker, and the distribution breaker by analyzing signals received from a user, a user input unit, or a communication unit, and additional standby power information.
5. The method of claim 4,
The shut-off control unit includes a gas switch management unit that manages a gas switch that controls gas supply, a boiler management unit that controls boiler operation, a power supply unit that receives power, and a shutdown control unit that minimizes the sensing and communication operations of the shut- A power management unit, and an alarm unit for generating a warning sound through an alarm, and a display unit for displaying information.
6. The method of claim 5,
The integrated controller turns off the operation of the overload detection unit and the current detection unit in the manual mode according to the user's input so that the user can manually control all the circuit breakers and the system breakers directly,
Wherein the control unit activates an operation except a portion for standby power control in an automatic mode, and activates all portions including a standby power control portion in a standby power mode.
A power management method using a centralized power management apparatus according to claim 1,
Selecting a mode of one of a manual mode, an automatic mode, and a standby power mode by a user;
When the user selects the standby power mode, the overload detection and the overcurrent detection are performed, and the presence or absence of the standby power generation is determined, and when the overload, the overcurrent, and the standby power are generated, the control signal for controlling the circuit breaker Thereby automatically shutting off power supplied to the load,
When the user selects the automatic mode, it detects an overload and an overcurrent, and provides a control signal for controlling the circuit breaker and the system breaker when an overload and an overcurrent occur, thereby automatically shutting off the power supply to the load,
Characterized in that when the user selects the manual mode, the breaker and the system breaker are manually controlled.
8. The method of claim 7,
And the interruption of the power supply interrupts the two line modes connected to the load.

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