KR102444837B1 - Outlet device and operation method therefor - Google Patents

Abstract

An outlet device according to an embodiment of the present invention comprises: an input plug which connects a first input line and a second input line to a system power supply including a voltage line (L) and a neutral line (N); an output cover having a first connection port associated with the voltage line (L), a second connection port associated with the neutral line (N), and a third connection port associated with an earth line (E); a circuit breaker circuit which performs a leakage circuit breaker operation based on a first connection between the first input line and a first output line, and a second connection between the second input line and a second output line; a zero phase sequence current transformer which penetrates the first output line, the second output line, and the earth line, and measures leakage current according to the system power supply; a detection circuit which generates detected voltage information related to a first output voltage associated with the first output line and a second output voltage associated with the second output line; a control circuit which generates a first control signal for the circuit breaker circuit based on whether the size of the measured leakage current exceeds a predetermined first threshold value, determines the position of the neutral line (N) based on the detected voltage information, and generates a second control signal according to the determination; and a switching circuit which connects any one of the first output line and the second output line to the earth line according to the second control signal. Therefore, the present invention can be easily connected and used by being simply connected to an existing ungrounded outlet without requiring additional grounding work.

Description

OUTLET DEVICE AND OPERATION METHOD THEREFOR

The present specification relates to an outlet device applicable to a non-grounded outlet and an operating method therefor, and more specifically, to an outlet device for a non-grounded outlet that can be used by simply connecting to an existing non-grounded outlet without additional grounding work, and an outlet device for the same It's about how it works.

In general, since an ungrounded outlet does not have a grounding electrode (or a grounding wire), when power is supplied to an electrical product using an outlet with a grounding electrode, the grounding wire is not normally connected, so the earth leakage breaker does not work or there is a risk of electromagnetic waves. .

For example, when using a non-grounding type multi-tap mixed with a grounding type outlet, grounding is not possible. Conversely, even when a grounding type multi-tap is used in an existing non-grounded outlet, grounding is not achieved.

Since most people are not properly aware of the existence of the grounding electrode of the outlet, they are exposed to the risk of electric shock and electromagnetic wave due to short circuit. Furthermore, in order to replace with a grounding type outlet, additional grounding work is required in the existing building, and in this case, the additional grounding cost is approximately 1 to 3 million won per household.

As a conventional proposal, reference may be made to Korean Patent Registration No. 10-1801772 relating to a non-grounding type earth leakage prevention device.

An object of the present specification is to provide an outlet device for a non-grounding outlet that can be used by simply connecting to an existing non-grounding outlet without additional grounding work, and an operating method therefor.

In addition, an object of the present specification is to provide an outlet device for a non-grounded outlet that can solve the electromagnetic wave shielding problem that may occur when an electric device is connected to an ungrounded outlet without a grounding wire and a malfunction of the earth leakage breaker, and an operating method therefor is doing

The outlet device according to this embodiment includes an input plug for connecting the first input line and the second input line to a system power source including a voltage line (L) and a neutral line (N); an output cover provided with a first connector associated with a voltage line (L), a second connector associated with a neutral wire (N), and a third connector associated with a ground wire (E); a circuit breaker circuit for performing an earth leakage breaking operation based on a first connection between the first input line and the first output line and a second connection between the second input line and the second output line; a zero-phase current transformer circuit passing through the first output line, the second output line, and the ground line and measuring the leakage current according to the grid power; a detection circuit that generates detection voltage information regarding a first output voltage associated with the first output line and a second output voltage associated with the second output line; Generates a first control signal for the circuit breaker circuit based on whether the measured leakage current exceeds a first threshold value, determines the position of the neutral wire (N) based on the detected voltage information, and determines a control circuit for generating a second control signal according to and a switching circuit connecting one of the first output line and the second output line to the ground line according to a second control signal.

The method of operating an outlet according to an embodiment of the present invention includes: measuring the magnitude of leakage current through a plurality of output lines associated with system power including a voltage line (L) and a neutral line (N); determining whether the magnitude of the measured leakage current exceeds a preset first threshold value; determining whether an AC component greater than or equal to a second threshold value is detected based on a plurality of detection elements corresponding to a plurality of output lines when it is determined that the measured leakage current does not exceed a first threshold value; and performing a switching operation such that any one of the plurality of output lines is connected to the ground line of the load stage based on the determination.

According to the present embodiment, an outlet device that can be simply connected to an existing ungrounded outlet and used without additional grounding work and an operating method therefor can be provided.

In addition, there may be provided an outlet device for an ungrounded outlet capable of solving an electromagnetic wave shielding problem that may occur when an electric device is connected to an ungrounded outlet without a grounding wire and a malfunctioning problem of an earth leakage breaker, and an operating method therefor.

1 is a view for explaining the structure of a system power supplied from a conventional KEPCO facility.
Figure 2 shows an internal block diagram of the outlet device according to the present embodiment.
3 is a view for explaining an earth leakage blocking operation performed by the outlet device according to the present embodiment.
4 is a view for explaining an operation of providing a grounding wire to an ungrounded outlet by the outlet device according to the present embodiment.
5 is a view for explaining an operation of providing a grounding wire to an ungrounded outlet by the outlet device according to another embodiment of the present invention.
6 is a flowchart for explaining the operation of the outlet device according to the present embodiment.
7 is a diagram illustrating a plurality of detection elements in a detection circuit according to an exemplary embodiment.

The foregoing characteristics and the following detailed description are all exemplary matters for helping the description and understanding of the present specification. That is, the present specification is not limited to such an embodiment and may be embodied in other forms. The following embodiments are merely examples for fully disclosing the present specification, and are descriptions for conveying the present specification to those skilled in the art to which the present specification belongs. Therefore, when there are several methods for implementing the elements of the present specification, it is necessary to make it clear that the implementation of the present specification is possible in any one of these methods or the equivalent thereto.

In the present specification, when it is stated that a configuration includes specific elements, or when a process includes specific steps, it means that other elements or other steps may be further included. That is, the terms used in this specification are only for describing specific embodiments, and are not intended to limit the concepts of the present specification. Furthermore, the examples described to help the understanding of the invention also include complementary embodiments thereof.

Terms used in this specification have meanings commonly understood by those of ordinary skill in the art to which this specification belongs. Commonly used terms should be interpreted in a consistent sense according to the context of the present specification. In addition, the terms used herein should not be construed in an overly idealistic or formal meaning unless the meaning is clearly defined. Hereinafter, embodiments of the present specification will be described with reference to the accompanying drawings.

1 is a view for explaining the structure of a system power supplied from a conventional KEPCO facility.

1, as TT grounding, which is a grounding method on the consumer side, was applied in a conventional building before 2002, the grounding method is inconsistent with the TN-C grounding method, which is a common grounding method for the ground wire-neutral line on the grid power (ie, KEPCO facility) side There are problems with That is, the existing TT grounding method may be vulnerable to malfunction of the earth leakage breaker due to disturbance (eg, EPR voltage rise, etc.).

The power of 22.9Kv supplied through the transmission wiring (L_S) installed on the power pole on the side of the grid power (ie, KEPCO facility) of FIG. 1 may be selectively supplied to the transformer (TRF) through the switch (SW).

On the other hand, the TN-C grounding method applied to the grid power source (ie, KEPCO facilities) is implemented in a way that associates the neutral wire (N) with the KEPCO side ground (GND). In this case, based on the voltage line (L) and the neutral line (N), 220V AC power may be delivered to the customer equipment through the input line (L_IN).

Figure 2 shows an internal block diagram of the outlet device according to the present embodiment.

The outlet device 200 according to the present embodiment includes an input plug 210 , a circuit breaker circuit 220 , a detection circuit 230 , a switching circuit 240 , an image current transformer circuit 250 , a control circuit 260 , and an output. A cover 270 may be included.

The input plug 210 of FIG. 2 may include a first terminal P1 associated with the first input line L_I1 and a second terminal P2 associated with the second input line L_I2.

For example, the first terminal P1 of the input plug 210 may connect the voltage line L of the system power source to the first input line L_I1 inside the outlet device 200 . In addition, the second terminal P2 of the input plug 210 may connect the neutral wire N of the system power source to the second input line L_I2 inside the outlet device 200 .

The breaker circuit 220 of FIG. 2 may perform an earth leakage blocking operation based on the first connection CNT1 and the second connection CNT2 according to the first control signal CTL_1 . Here, the first control signal CTL_1 may be generated based on the magnitude of the leakage current detected from the zero-phase current transformer circuit 250 to be described later.

For example, the first connection CNT1 may mean a connection between the first input line L_I1 and the first output line L_O1 corresponding to the first input line L_I1 . Meanwhile, the second connection CNT2 may refer to a connection between the second input line L_I2 and the second output line L_O2 corresponding to the second input line L_I2 .

For example, when it is determined that the magnitude of the leakage current exceeds the first threshold value, the first control signal CTL_1 is configured such that the first connection CNT1 and the second connection CNT2 of the circuit breaker circuit 220 are cut off. can direct

As another example, as an example, when it is determined that the magnitude of the leakage current does not exceed the first threshold value, the first control signal CTL_1 is connected to the first connection CNT1 and the second connection (CNT1) of the circuit breaker circuit 220 ( CNT2) can be instructed to be maintained.

The detection circuit 230 of FIG. 2 is connected in parallel to the first output line and the second output line, and may include a plurality of detection elements (not shown) in the circuit. For reference, the internal configuration of the detection circuit 230 will be described in more detail with reference to the drawings to be described later.

For example, when the first input line L_I1 is connected to the voltage line L through the first terminal P1 , an AC voltage component exceeding a preset second threshold value is controlled through the detection circuit 230 . may be transferred to the circuit 260 .

As another example, when the second input line L_I2 is connected to the voltage line L through the second terminal P2 , an AC voltage component exceeding a preset second threshold value passes through the detection circuit 230 to the control circuit It can be forwarded towards (260).

Meanwhile, the detection circuit 230 may generate detection voltage information V_I1 and V_I2 based on an AC voltage component detected by each detection element (not shown). In this case, the detection voltage information V_I1 and V_I2 may be transmitted to the control circuit 260 .

Here, the detected voltage information V_I1 and V_I2 may be converted into digital information by an analog-to-digital converter (ADC) included in the control circuit 260 .

The switching circuit 240 of FIG. 2 may connect any one of the first output line L_O1 and the second output line L_O2 to the ground line E according to the second control signal CTR_2 .

For example, when an alternating current (AC) component exceeding the second threshold value is detected from a detection device (not shown) associated with the first output line L_O1 , the switching circuit 240 transmits the second control signal CTR_2 Accordingly, the second output line L_O2 may operate to be connected to the ground line E.

As another example, for example, when an alternating current (AC) component exceeding the second threshold value is detected from a detection device (not shown) associated with the second output line L_O2 , the switching circuit 240 transmits the second control signal According to (CTR_2), the first output line (L_O1) may operate to be connected to the ground line (E).

Here, it will be understood that the switching circuit 240 may be implemented based on a relay circuit or a field effect transistor (FET).

The image current transformer circuit 250 of FIG. 2 is configured to pass through the first output line L_O1 and the second output line L_O2, and electrically (or magnetically) the breaker circuit 220 and the output cover 270 . ) can be linked. In addition, the image current transformer circuit 250 may pass through the ground wire E and electrically (or magnetically) connect the switching circuit 240 and the output cover 270 .

Meanwhile, the zero phase current transformer circuit 250 may detect a current difference between the voltage line L and the neutral line N associated with the circuit breaker circuit 220 . For example, the zero phase current transformer circuit 250 passes through the first output line L_O1 and the second output line L_O2 of the secondary side of the breaker circuit 220 corresponding to the voltage line L and the neutral line N. can be implemented.

Further, the image current transformer circuit 250 connects the ground wire E extending from the third connection port of the output cover 270 to the second output line L_O2 of the secondary side of the circuit breaker circuit 220 in the opposite direction (eg, K , L direction) may be implemented to penetrate.

The control circuit 260 of FIG. 2 may control the overall operation of the outlet device 200 according to the present embodiment.

For example, the control circuit 260 may set a preset value in any one of the first output line L_O1 and the second output line L_O2 based on the detected voltage information V_I1' and V_I2' converted into digital information. 2 It can be determined whether an AC voltage component exceeding a threshold value is detected.

As an example, when the first input line L_I1 is connected to the voltage line L through the first terminal P1 , the control circuit 260 controls the AC voltage component that exceeds a preset second threshold value. The detection may be performed by a detection device (not shown) associated with the first output line L_O1.

As another example, when the second input line L_I2 is connected to the voltage line L through the second terminal P2 , the control circuit 260 generates an AC voltage component exceeding a preset second threshold value. may be detected by the detection device associated with the second output line L_O2.

For example, the control circuit 260 may control the leakage blocking operation of the circuit breaker circuit 220 by generating the first control signal CTL_1 based on information on the magnitude of the leakage current detected from the phase current transformer circuit 250 . have.

For example, when the magnitude of the leakage current exceeds a preset first threshold value, a signal having a high level of the first control signal CTL_1 may be generated. Accordingly, the first connection CNT1 and the second connection CNT2 of the circuit breaker circuit 220 may be disconnected.

As another example, when the magnitude of the leakage current is less than or equal to a preset first threshold, a signal having a low level of the first control signal CTL_1 may be generated. Accordingly, the first connection CNT1 and the second connection CNT2 of the circuit breaker circuit 220 may be maintained.

Also, the control circuit 260 may control the operation of the switching circuit 240 by generating the second control signal CTL_2 based on the detection voltage information V_I1 and V_I2 received from the detection circuit 230 .

For example, when it is determined that the level of the first output voltage associated with the first output line L_O1 exceeds a preset second threshold value, the switching circuit 240 operates the second output voltage according to the second control signal CTL_2. The output line L_O2 may be connected to the ground line E.

As another example, when it is determined that the level of the second output voltage associated with the second output line L_O2 exceeds a preset second threshold value, the switching circuit 240 operates the second output voltage according to the second control signal CTL_2. 1 The output line L_O1 may be connected to the ground line E.

The output cover 270 of FIG. 2 may include a first connector associated with the voltage line L, a second connector associated with the neutral wire N, and a third connector associated with the ground line E. As a result, the ground line (E) of the third connector may be connected to the common ground (GND_C in FIG. 1 ) associated with the neutral line (N) of the system power through the switching circuit 240 .

According to this embodiment, an outlet device that can be simply connected to an existing ungrounded outlet without additional grounding work can be provided, and electromagnetic wave shielding that may occur when an electric device is connected to an ungrounded outlet without a grounding wire It will be understood that the problem and malfunction of the earth leakage breaker can be solved.

3 is a view for explaining an earth leakage blocking operation performed by the outlet device according to the present embodiment.

2 and 3 , the first input line L_I1 of the outlet device 300 of FIG. 3 is connected to the voltage line L through the first terminal P1, and the second of the outlet device 300 It may be assumed that the input line L_I2 is connected to the neutral line N through the second terminal P2 .

For example, if it is determined that the information on the magnitude of the leakage current detected from the zero-phase current transformer circuit 350 exceeds a preset first threshold value, the control circuit 360 transmits the first control signal CTL_1 to the circuit breaker circuit 320 . can be forwarded to

In this case, the first control signal CTL_1 may instruct the first connection CNT1 and the second connection CNT2 of the circuit breaker circuit 320 to be disconnected.

4 is a view for explaining an operation of providing a grounding wire to an ungrounded outlet by the outlet device according to the present embodiment.

2 and 4 , the first input line L_I1 of the outlet device 400 of FIG. 4 is connected to the voltage line L through the first terminal P1, and the second of the outlet device 400 It may be assumed that the input line L_I2 is connected to the neutral line N through the second terminal P2 .

Also, in FIG. 4 , it may be assumed that information on the magnitude of the leakage current detected from the zero-phase current transformer circuit 350 does not exceed a preset first threshold value.

For example, the control circuit 460 may detect an AC voltage component exceeding a preset second threshold value from a detection device (not shown) associated with the first output line L_O1 . Next, the switching circuit 440 may operate such that the second output line L_O2 is connected to the ground line E according to the second control signal CTR_2 .

5 is a view for explaining an operation of providing a grounding wire to an ungrounded outlet by the outlet device according to another embodiment of the present invention.

This other embodiment may be understood for a situation where the user does not distinguish each time whether a specific terminal of the outlet device is connected to the neutral line (N) or connected to the voltage line (L).

2 and 5, the first input line (L_I1) of the outlet device 500 of FIG. 5 is connected to the neutral wire (N) through the first terminal (P1), the second of the outlet device (500) It may be assumed that the input line L_I2 is connected to the voltage line L through the second terminal P2 .

Also, in FIG. 5 , it may be assumed that information on the magnitude of the leakage current detected from the zero-phase current transformer circuit 550 does not exceed a preset first threshold value.

For example, the control circuit 560 may detect an AC voltage component exceeding a preset second threshold value from a detection element (not shown) associated with the second output line L_O2 . Next, the switching circuit 540 may operate such that the first output line L_O1 is connected to the ground line E according to the second control signal CTR_2 .

6 is a flowchart for explaining the operation of the outlet device according to the present embodiment.

In step S610 , the magnitude of the leakage current may be measured through a plurality of output lines (eg, L_O1 and L_O2 of FIG. 2 ) associated with the system power including the voltage line L and the neutral line N.

In step S620 , it may be determined whether the magnitude of the measured leakage current exceeds a preset first threshold value.

If the magnitude of the leakage current exceeds the first threshold value, the procedure is terminated. In this case, the first connection CNT1 and the second connection CNT2 may be cut according to the leakage blocking operation of the circuit breaker circuit 220 . If the magnitude of the leakage current does not exceed the first threshold value, the procedure proceeds to step S620.

In step S630, an alternating current (AC) component exceeding a preset second threshold is detected in any one of the output lines (eg, L_O1 in FIG. 2 ) of a plurality of output lines (eg, L_O1 and L_O2 in FIG. 2 ) whether it can be judged.

Step S630 of the present specification may be implemented such that monitoring of all of a plurality of output lines is performed or monitoring of any one output line is performed.

In step S640 , when an alternating current (AC) component is detected from any one of the plurality of output lines (eg, L_O1 and L_O2 in FIG. 2 ) (eg, L_O1 in FIG. 2 ), the second input line L_I2 The second output line L_O2 and the ground line E corresponding to may be connected through a switching operation.

In step S645, when an alternating current (AC) component is detected from any one of the plurality of output lines (eg, L_O1 and L_O2 of FIG. 2 ) (eg, L_O2 of FIG. 2 ), the first input line L_I1 The first output line L_O1 and the ground line E corresponding to may be connected through a switching operation.

7 is a diagram illustrating a plurality of detection elements in a detection circuit according to an exemplary embodiment.

1 to 7 , the detection circuit 730 of FIG. 7 may correspond to the detection circuit 230 of FIG. 2 , and the control circuit 760 of FIG. 7 may correspond to the control circuit 260 of FIG. 2 . can

Referring to FIG. 7 , the first detection element of the detection circuit 730 according to the present embodiment may include a first resistor R1 and a first capacitor C1. In addition, the second detection element of the detection circuit 730 may include a second resistor R2 and a second capacitor C2.

For example, the first detection voltage V_I1 is primarily attenuated while the AC component AC transmitted through the first output line L_O1 passes through the first resistor R1 and then the first capacitor C1 can be understood as passing through

In addition, the second detection voltage V_I2 passes through the second capacitor C2 after the AC component AC transmitted through the second output line L_O2 is primarily attenuated while passing through the second resistor R2 . can be understood as

As described above, the detection voltage information including the first detection voltage V_I1 and the second detection voltage V_I2 is transmitted to the control circuit 760 and converted into digital information through the ADC converter included in the control circuit 760 . can be converted

In the detailed description of the present specification, specific embodiments have been described, but various modifications are possible without departing from the scope of the present specification. Therefore, the scope of the present specification should not be limited to the above-described embodiments and should be defined by the claims and equivalents of the claims of the present invention as well as the claims to be described later.

200: an outlet device for an ungrounded outlet
210: input plug
220: circuit breaker circuit
230: detection circuit
240: switching circuit
250: video current transformer circuit
260: control circuit
270: output cover

Claims (10)

an input plug connecting the first input line and the second input line to a system power source including a voltage line (L) and a neutral line (N);
an output cover provided with a first connector associated with the voltage line (L), a second connector associated with the neutral wire (N), and a third connector associated with the ground wire (E);
Earth leakage blocking based on a first connection between the first input line and a first output line corresponding to the first input line and a second connection between the second input line and a second output line corresponding to the second input line circuit breaker (Circuit Breaker) circuit to perform the operation;
a zero-phase current transformer circuit passing through the first output line, the second output line, and the ground line and measuring a leakage current according to the system power;
a detection circuit that generates detection voltage information regarding a first output voltage associated with the first output line and a second output voltage associated with the second output line;
A first control signal for the circuit breaker circuit is generated based on whether the magnitude of the measured leakage current exceeds a preset first threshold value, and a magnitude comparison is performed based on the detected voltage information and a preset second threshold value. a control circuit for determining the position of the neutral wire (N) based on the determination and generating a second control signal according to the determination; and
and a switching circuit connecting one of the first output line and the second output line to the ground line according to the second control signal. The method of claim 1,
the detection circuit includes a first detection element associated with the first output line and a second detection element associated with the second output line;
One end of the first detection element is connected to the first output line, the other end is connected to the control circuit, and
One end of the second detection element is connected to the second output line, and the other end is connected to the control circuit. 3. The method of claim 2,
When the first input line is connected to the voltage line (L), an alternating voltage (AC) component exceeding the second threshold value is detected at the other end of the first detection element,
The outlet device, characterized in that the detected voltage information is generated based on the alternating voltage (AC) component. 4. The method of claim 3,
The second control signal is generated to instruct the second output line to be connected to the ground line through the switching circuit based on the detected voltage information. 3. The method of claim 2,
When the second input line is connected to the voltage line (L), an alternating voltage (AC) component exceeding the second threshold value is detected at the other end of the second detection element,
The outlet device, characterized in that the detected voltage information is generated based on the alternating voltage (AC) component. 6. The method of claim 5,
and the second control signal is generated to instruct the second output line to be connected to the ground line through the switching circuit based on the detected voltage information. The method of claim 1,
When it is determined that the magnitude of the leakage current exceeds the first threshold value, the first control signal instructs to disconnect the first connection and the second connection of the breaker circuit. The method of claim 1,
When the first input line is associated with the neutral line (N) of the grid power, the direction of penetration of the zero-phase current transformer circuit by the ground line is opposite to the direction of penetration of the zero-phase current transformer circuit by the first output line. outlet device, characterized in that. The method of claim 1,
The neutral wire (N) included in the grid power outlet device, characterized in that it is associated with an external common ground for the grid power. A method of operating an outlet device, comprising:
Measuring the magnitude of the leakage current through a plurality of output lines associated with the system power including the voltage line (L) and the neutral line (N);
determining whether the magnitude of the measured leakage current exceeds a preset first threshold value;
When it is determined that the measured leakage current does not exceed the first threshold value, whether an AC voltage component equal to or greater than a preset second threshold value is detected based on a plurality of detection elements corresponding to the plurality of output lines judging;
A switching operation is performed so that any one of the plurality of output lines is connected to the ground line of the load stage based on the determination,
The step of performing the switching operation,
connecting a second output line of the plurality of output lines to the ground line when the AC voltage component is detected from a first output line among the plurality of output lines; and
and connecting a first output line of the plurality of output lines and the ground line when the AC voltage component is detected from a second output line of the plurality of input lines.

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