KR101301705B1 - Maximum power demand controller - Google Patents

Abstract

PURPOSE: A maximum power demand controller is provided to prevent a blackout by turning off a demand control object regardless of the intention of a user. CONSTITUTION: A power line connecting terminal (410) is formed with an outlet type and is detachably connected to the end of a power line which receives power. One end of a load power line connecting terminal (420) is connected to the power line connecting terminal by a controller power line and the other end thereof is detachably connected to the end of a load power line. A frequency sensor (100) senses the frequency of electricity supplied through a power line. A current sensor senses a current flow. A temperature sensor senses the inner temperature of a demand control object installation place. A control unit (200) reads a frequency and outputs on or off control signals of the demand control object according to the read frequency. A transmitting unit (300) wirelessly transmits the on or off control signals from the control unit to the demand control object. [Reference numerals] (100) Frequency sensor; (200) Control unit; (500) Current transformer; (600) Current sensor; (T) Demand control object device

Description

Maximum Power Demand Controller

The present invention relates to a maximum power demand controller that prevents energy savings and blackout.

As society develops and seeks convenience, the use of electric devices is increasing, and the use of electric energy is increasing rapidly.

Currently, the main method of producing electrical energy is to use fossil energy such as coal or oil or nuclear energy.

However, in the case of fossil energy, the limit of use is recommended due to resource depletion and environmental issues.

In the case of nuclear energy, the debate on the pros and cons of use is heating up due to the recent safety issues, which is not easy to expand.

For this reason, it is urgent to develop alternative energy to replace the fossil energy and nuclear energy, but this is also poorly supported.

As mentioned above, the use of electric energy is increasing every year, and the production of electric energy becomes more and more difficult, but people's perception of electric energy saving does not change so much that the shortage of electric energy is continuously occurring.

This lack of electrical energy causes blackouts (blackouts), and blackouts are more likely to occur in summer and winter, when the use of air conditioners is rapidly increasing.

Accordingly, KEPCO is conducting circular blackouts on a global basis to prevent blackouts when the reserve power drops below 1 million kw.

Patent 10-1081056

The present invention is to solve the above problems, to solve the problem to provide a maximum power demand controller to prevent energy saving and blackout.

The present invention for solving the above problems,
A plug-type power line connection terminal detachably connected to an end of a power line receiving power and forming an outlet type; One end is connected to the power line connecting terminal via the controller power line, the other end is a plug type, the outlet type load power line connecting terminal detachably connected to the end of the load power line drawn from the demand-controlled equipment;
A frequency detecting sensor installed in the main body and detecting a frequency of electricity supplied through the power line:
Installed in the main body, the current sensor for sensing the flow of current:
Temperature sensor installed in the main body, for detecting the indoor temperature of the installation site of the demand control target device:
It is installed in the main body, and reads the frequency detected by the frequency sensing sensor and outputs an on or off control signal of the demand control target device according to the read frequency value, and receives the current sensing signal from the current sensor to the controller power line The control unit outputs an on or off control signal of the demand control target device when the electricity is energized, and outputs an on or off control signal of the demand control target device according to the room temperature value from the temperature sensor:
A transmission unit installed in the main body and wirelessly transmitting a demand control target device on or off control signal from the control unit to the demand control target device;
And a control unit.

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According to the present invention as described above, the maximum power demand controller that prevents energy saving and blackout can be turned off in the blackout situation, irrespective of the user's intention. Therefore, it is possible to prevent the worsening of the situation caused by the user's reckless use of energy in the situation that blackout can come.

In addition, according to the present invention, the demand control target device can be turned off regardless of the user's intention according to the room temperature at which the demand control target device is installed. This has the effect of preventing the reckless use of energy that ignores government guidelines.

1 is a view for explaining a maximum power demand controller according to a first embodiment of the present invention,
2 is a view for explaining a maximum power demand controller according to a second embodiment of the present invention;
3 is a view showing that the maximum power demand controller according to the second embodiment of the present invention is applied to a cooler,
4 is a diagram for describing a maximum power demand controller according to a third embodiment of the present invention.

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

The maximum power demand controller C according to the first embodiment of the present invention will be described with reference to FIG. 1.

The maximum power demand controller C according to the present invention includes a frequency detecting sensor 100, a control unit 200, and a transmitting unit 300.

The frequency detection sensor 100 detects the frequency of the power line L1 that supplies power to the demand control target device T. In this embodiment, the frequency detection sensor 100 may be applied to the frequency counter.

The control unit 200 reads the frequency detected by the frequency detection sensor 100, and outputs a demand control target device control signal according to the read frequency.

In the present embodiment, the reference value of the frequency may be a frequency range where the blackout symptom starts, for example, 59.2 to 59.4 Hz. Accordingly, when the frequency of the power line L reaches the frequency reference value, the control unit 200 outputs a signal to turn off the power of the demand control target device T, and the frequency is a normal frequency, for example, 60 Hz. When the signal is recovered, the signal for turning on the power of the demand control target device T is output.

The transmitting unit 300 wirelessly transmits a demand control target device control signal from the control unit 200. On the other hand, the demand control target device (T) has a receiving unit (T1) for receiving the control signal transmitted from the transmitting unit (300). At this time, the demand control target device (T) is turned on or off in accordance with the control signal of the maximum power demand controller (C).

A second embodiment according to the present invention will be described with reference to FIG.

The maximum power demand controller C according to the present embodiment includes a main body 400, and the main body 400 includes the frequency detecting sensor 100, the control unit 200, and the transmitting unit (according to the first embodiment). 300) is installed.

The main body 400 has a power line connection terminal 410 connected to the power line (L1), one end is connected to the power line connection terminal 410 via a controller power line (L2), the other end is the demand control target device (T) A load power line connection terminal 420 connected to the load power line (L3) drawn from the) is provided. At this time, the controller power line (L2) is installed in the main body 400 refers to a power line for energizing the power line (L1) and the load power line (L3).

Meanwhile, in the present embodiment, an end of the power line L1 is formed of an outlet type, and the power line connection terminal 410 is made of a plug type, so that the connection between the power line L1 and the controller power line L2 is detachable. Can be done. In addition, the end of the load power line (L3) is made of a plug type, the load power line connection terminal 420 is made of an outlet type, the connection of the load power line (L3) and the controller power line (L2) can be made detachable. have.

Also, in the present embodiment, a current transformer (CT) 500 is installed in the controller power line L2, and the current transformer 500 is electrically connected to the power line connection terminal 410 and the load power line connection terminal 420. . In addition, a current sensor 600 is electrically connected to the current transformer 500, and the current sensor 600 is electrically connected to the frequency sensor 100.

At this time, the control unit 200 receives a current detection signal from the current sensor 600, when the electricity is supplied to the controller power line (L2) through the transmission unit 300 on or off of the demand control target device (T) It is driven to output a signal.

Here, the current transformer 500 and the current sensor 600 are well known technologies, and can be easily implemented by those skilled in the art.

Referring to Figure 3, when explaining the second embodiment according to the present invention applied to the air conditioner (A) as follows.

First, the structure of the air conditioner (A) will be described briefly as follows.

The air conditioner (A) includes an outdoor unit (10), an indoor unit (20), and a decompression device (30).

The outdoor unit 10 includes a compressor 11 for compressing a refrigerant and an outdoor heat exchanger 12 that performs heat exchange outdoors, and is installed outdoors.

The indoor unit 20 includes an indoor heat exchanger 21 for exchanging heat indoors, an input unit 24 for inputting a control signal, a receiving unit 22 for receiving a control signal from the input unit 24, and a receiving unit. The control unit 23 receives the control signal from the 22 and operates and controls the indoor unit 20 and the outdoor unit 10, and is installed indoors. At this time, the input unit 24 may be applied to a remote control for remote transmission and reception.

The pressure reduction device 30 is installed in the outdoor unit 10 or the indoor unit 20 and lowers the pressure.

Here will be briefly described the cooling principle of the air conditioner (A) as follows.

The refrigerant compressed by the compressor 11 moves to the outdoor heat exchanger 12 and releases heat from the outdoor heat exchanger 12. The refrigerant is moved to the decompression device 30 and then to the indoor heat exchanger 21. Then, the refrigerant is evaporated from the liquid state to the gaseous state and heat exchange is performed to absorb the surrounding heat, and then moves to the compressor 11 to circulate. At this time, because the indoor heat exchanger 21 installed in the room absorbs the surrounding heat, the room is cooled.

Meanwhile, when the maximum power demand controller C according to the second embodiment of the present invention is applied to the air conditioner A, the operation of the maximum power demand controller C is as follows.

First, in the maximum power demand controller C of the present invention, the power line L1 is connected to the power line connection terminal 410, and the load power line L3 from the air conditioner A is connected to the load power line connection terminal 420. At this time, if the demand control target device (T) is running, the current sensor 600 detects the flow of current, and accordingly the maximum power demand controller (C) is driven.

As described above, when the maximum power demand controller C is operating, when the frequency sensor 100 detects a frequency indicating a sign of blackout, the control unit 200 of the maximum power demand controller C receives the maximum power demand. The outdoor unit off signal is transmitted to the receiving unit 22 of the air conditioner A through the transmitting unit 300 of the controller C. Then, the control unit 23 of the air conditioner A receives the outdoor unit off signal through the receiving unit 22, and thus stops driving the outdoor unit 10.

Meanwhile, when the blackout indication disappears and the frequency sensor 100 detects a normal frequency, the control unit 200 of the maximum power demand controller C receives the receiving unit 22 of the air conditioner A through the transmitting unit 300. Transmit the outdoor unit signal. Then, the control unit 23 of the air conditioner A receives the outdoor unit ON signal through the receiving unit 22, and accordingly, the outdoor unit 10 of the air conditioner A is driven again.

Although the maximum power demand controller C according to the present invention has been described above by applying to the air conditioner, it may be applied to both a controller having a built-in controller and a remote controller. For example, the maximum power demand controller C according to the present invention is also applicable to a heating and cooling multifunction apparatus.

4, the maximum power demand controller C according to the third embodiment of the present invention will be described.

The maximum power demand controller C according to the present invention further includes a temperature sensor 700 for measuring an indoor temperature of a place where the demand control target device T is installed.

In particular, when the demand control target device (T) is applied to the air conditioner (A), the temperature sensor 700 is operated and controlled by the control unit 200 of the maximum power demand controller (C), the air conditioner (A) is installed Measure the room temperature of the place. At this time, the control unit 200 operates to control the outdoor unit 10 of the air conditioner (A) according to the temperature measured by the temperature sensor (700).

For example, when the government recommends the recommended indoor temperature guidelines for summer, the recommended indoor temperature is set in the control unit 200 of the maximum power demand controller C as a reference value. And when the room temperature is lower than the recommended room temperature, the control unit 200 transmits the outdoor unit off signal to the air conditioner (A) through the transmission unit 300 of the maximum power demand controller (C), the air conditioner (A) Receives this through the receiving unit 22 to turn off the outdoor unit (10). In addition, when the room temperature is higher than the recommended room temperature, the control unit 200 transmits the outdoor unit on-signal through the transmission unit 300, so that the outdoor unit 10 of the air conditioner (A) is turned on again.

As described above, the maximum power demand controller according to the present invention enables the demand control target device T to be turned off regardless of the user's intention in the blackout situation.

Thus, in situations where blackout may occur, the situation may be prevented from worsening due to users' indiscriminate use of energy.

In addition, the maximum power demand controller for preventing energy saving and blackout according to the present invention may turn off the demand control target device T regardless of the user's intention according to the room temperature at which the demand control target device T is installed. .

Thus, reckless use of energy that ignores government guidelines can be prevented.

This saving of electrical energy makes it possible to reduce the expansion of the main power plant or the reserve power plant.

Furthermore, the saving of electric energy can establish national greenhouse gas reduction targets and low carbon green growth infrastructure, achieve national energy efficiency improvement targets, and make a rapid transition to low energy consumption society, and Strong countermeasures allow for maximum cost in the shortest possible time.

C; Maximum power demand controller 100; Frequency Sensor
200; Control unit 300; Sending unit
T; Demand control target device T1; Receiving unit
400; Main body 500; deflector
600; Current sensor 700; temperature Senser
A; Air conditioner 10; Outdoor unit
20; Indoor unit

Claims (5)

A plug-type power line connection terminal detachably connected to an end of a power line receiving power and forming an outlet type; One end is connected to the power line connecting terminal via the controller power line, the other end is a plug type, and the outlet type load power line connecting terminal detachably connected to the end of the load power line drawn from the demand-controlled equipment;
A frequency detecting sensor installed in the main body and detecting a frequency of electricity supplied through the power line:
Installed in the main body, the current sensor for sensing the flow of current:
Temperature sensor installed in the main body, for detecting the indoor temperature of the installation site of the demand control target device:
It is installed in the main body, and reads the frequency detected by the frequency sensing sensor and outputs an on or off control signal of the demand control target device according to the read frequency value, and receives the current sensing signal from the current sensor to the controller power line The control unit outputs an on or off control signal of the demand control target device when the electricity is energized, and outputs an on or off control signal of the demand control target device according to the room temperature value from the temperature sensor:
A transmission unit installed in the main body and wirelessly transmitting a demand control target device on or off control signal from the control unit to the demand control target device;
Maximum power demand controller comprising a. delete delete delete delete

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