KR101972304B1 - Power distribution system - Google Patents

Abstract

Provided is a power distribution system which comprises: a current detection unit detecting a current supplied in a power distribution line; a blocking switch blocking the current supplied in the power distribution line; and an intelligent electronic device (IED) determining a main detection signal in accordance with a priority set among a plurality of detection signals when the plurality of detection signals detected from the current detection unit are inputted, and checking a current state of the current in accordance with the main detection signal to control the operation of a module of the blocking switch.

Description

Power distribution system

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power distribution system, and more particularly, to a power distribution system that facilitates checking the current state of a current supplied to a power distribution line.

Generally, a current detection method of a low-voltage direct current distribution system can detect a shunt resistance directly connected to a distribution line to measure a current flowing through a distribution line.

In this case, the intelligent electronic device (IED) of the low-voltage direct current distribution system converts the voltage drop due to the shunt resistor to an analog-to-digital converter, and calculates the current using the ratio of the rated voltage and the rated current of the shunt resistor.

In general, the IED can take on various functions such as system protection, control measurement, status monitoring, and communication.

In low-voltage DC distribution systems, an isolation amplifier can be used to ensure insulation between the shunt resistor and the IED and to prevent a 1-wire ground fault that occurs when the line between the shunt resistor and the IED contacts the ground.

In a low-voltage direct current distribution system, the uncertainty of the measured current may increase due to an isolation amplifier (Isolation Amplifier) for securing insulation between the shunt resistor and the IED.

In addition, the shunt resistor sets a low resistance value to output several tens of mV to reduce heat generation and energy loss, but the noise effect can be increased due to the low output voltage.

In recent years, research has been conducted to measure the current supplied to the distribution line and increase the response speed to the measured current so that the noise of the distribution line is not included in the measured current, thereby accurately determining the current state of the current flowing through the distribution line Is underway.

It is an object of the present invention to provide a distribution system that can easily measure the current supplied to the distribution line and determine the current state of the measured current.

The power distribution system according to the first embodiment of the present invention includes a current sensing unit for outputting at least one of first and second sensing signals sensing a current supplied to a power distribution line, Wherein the control unit determines at least one of the first and second sensing signals as a main sensing signal according to a set priority order when at least one of the first switch and the first sensing signal is input, And an intelligent electronic device (IED) for controlling the operation of the blocking switch.

Wherein the current sensing unit comprises: a first hall sensor for outputting the first sensing signal to the IED when the peak value of the current falls within a first current peak range; And outputting the second sensing signal to the IED when the current is within the second current peak range.

Wherein the first current peak range is a range between a first peak value and a second peak value higher than the first peak value and the second current peak range is higher than the first peak value to the second peak value And a third peak value.

The IED includes a signal determination unit for determining the first sensing signal as the main sensing signal according to the priority when all of the first and second sensing signals are input, And a control unit for confirming that the current state of the current is in a normal state and controlling the shutoff switch to remain in a turned-on state.

Wherein the signal determining unit determines the second sensing signal as the main sensing signal when the second sensing signal is input, and the controller determines the current state of the current when the second sensing signal is determined as the main sensing signal, The overcurrent state can be controlled to be switched from the turn-on state to the turn-off state when the overcurrent state is maintained for the first time.

A power distribution system according to a second embodiment of the present invention includes a current sensing unit for outputting at least one of first to third sensing signals sensing a current supplied to a power distribution line, And at least one of the first to third sensing signals is determined as a main sensing signal according to a set priority, and when at least one of the first, second, third, And an IED (intelligent electronic device) for controlling the operation of the shut-off switch by checking the current state of the shut-off switch, wherein the current sensing unit is operable to sense the first sense signal when the peak value of the current falls within a first current peak range. A first Hall sensor for outputting the second sensing signal to the IED if the peak value of the current falls within a second current peak range wider than the first current peak range, And a third Hall sensor for outputting the third sensing signal to the IED if the peak value of the current falls within a third current peak range that is wider than the second current peak range .

Wherein the first current peak range is a range between a first peak value and a second peak value that is larger than the first peak value and the second current peak range is higher than the first peak value to the second peak value And the third current peak range may be a range between the first peak value and the fourth peak value higher than the third peak value.

The IED includes a signal determination unit for determining the first sensing signal as the main sensing signal according to the priority when all of the first to third sensing signals are input, And if it is determined that the current state of the current is in a normal state, and controls the shutoff switch to remain in a turned-on state.

Wherein the signal determining unit determines the second sensing signal as the main sensing signal according to the priority when the second and third sensing signals are inputted, and the controller determines that the second sensing signal is the main sensing signal The current state of the current is determined to be an overcurrent state, and if the overcurrent state is maintained for a second time period, the shutdown switch can be controlled to be switched from a turn-on state to a turn-off state.

Wherein the signal determining unit determines the third sensing signal as the main sensing signal when the third sensing signal is input and the controller determines the current state of the current when the third sensing signal is determined as the main sensing signal, Is in an accident occurrence state, and can be controlled so as to be immediately switched from the turn-on state to the turn-off state.

The power distribution system according to the present invention outputs a plurality of sensing signals sensing a current supplied to a power distribution line using a plurality of hall sensors having different sensing ranges to reduce noise included in a plurality of sensing signals There is an advantage.

Also, the power distribution system according to the present invention can easily confirm the current state of the current supplied to the power distribution line based on a plurality of sensing signals to which the intelligent electronic device (IED) is input, There is an advantage that it is easy to control the operation and the post-analysis is easy for the accident and the failure which are generated according to the current state of the current.

1 is a block diagram briefly showing a distribution system according to the present invention.
2 is a control block diagram showing a control configuration of the power distribution system according to the first embodiment of the present invention.
3 is a control block diagram showing a control configuration of a distribution system according to a second embodiment of the present invention.
4 is a view for explaining a control operation according to a sensing signal output from the power distribution system shown in FIG.

The above and other objects, features, and advantages of the present invention will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings, which are not intended to limit the scope of the present invention. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to denote the same or similar elements.

1 is a block diagram briefly showing a distribution system according to the present invention.

1, the power distribution system 100 may include a shutdown switch 110, a current sensing unit 120, and an intelligent electronic device 130.

First, the cutoff switch 110 can block the current i supplied to the power distribution line L

The shutdown switch 110 is turned on under the control of the IED 130 to supply the current i to the load or to the turn off state under the control of the IED 130, It is possible to block the current (i) supplied to the power source.

In an embodiment, the shutdown switch 110 is described as being turned on and off according to the control of the IED 130, but may be turned on and off by other devices than the IED 130 , But does not limit it.

The current sensing unit 120 is installed in a certain region of the power distribution line L and can sense the magnetic field of the current i to output a plurality of sensing signals i_s to the IED 130.

The current sensing unit 120 will be described later in detail with reference to FIGS. 2 and 3. FIG.

Here, the current sensing unit 120 includes a plurality of hall sensors (not shown) that output a plurality of sensing signals i_s, and the plurality of Hall sensors have a current peak range capable of sensing the current i Can be set differently.

The IED 130 checks the current state of the current i supplied to the distribution line L based on the plurality of sensing signals i_s output from the current sensing unit 120, The shutoff switch 110 may be maintained in a turned-on state or turned on in a turn-on state.

In addition, the IED 130 can store a plurality of sensing signals i_s for a post-analysis in case of an accident or a failure in a distribution line L or a load, and can transmit the sensing signal i_s to a higher-order device (not shown) .

2 is a control block diagram showing a control configuration of the power distribution system according to the first embodiment of the present invention.

2, the power distribution system 100 may include a shutdown switch 110, a current sensing unit 120, and an IED 130.

The cutoff switch 110 is switched from the turn-off state to the turn-on state to supply the current i to the distribution line L or from the turn-on state to cut off the current i supplied to the distribution line L It can be switched to the turn-off state.

The current sensing unit 120 may include first and second Hall sensors 122 and 124.

The first hall sensor 122 can output the first sensing signal i_s1 corresponding to the peak value of the current i when the peak value of the current i is detected to fall within the first current peak range.

Further, when the second Hall sensor 124 detects that the peak value of the current (i) belongs to the second current peak range wider than the first current peak range, the second hall sensor 124 detects the second detection It is possible to output the signal i_s2.

Here, the first current peak range is a range from a first peak value to a second peak value, and the second current peak range is a range from the first peak value to a third peak value higher than the second peak value Lt; / RTI >

In addition, each of the first and second current peak ranges may be determined according to the magnetic saturation of each of the first and second hall sensors 122 and 124.

The magnetic saturation of the magnetic sensors included in the first and second hall sensors 122 and 124 is lowered by the magnitude of the magnetic field of the current i so that the first and second hall sensors 122 and 124 The first and second sensing signals i_s1 and i_s2 are not output.

For example, if the first hall sensor 122 has the first current peak range in which the peak value of the current i can measure from 1 mA to 5 mA, the peak value of the current (i) It is possible to output the first sensing signal i_s1 corresponding to the peak value of the current i only when it belongs to the current peak range.

The second Hall sensor 124 also has a second current peak range in which the peak value of the current i can measure from 1 mA to 10 mA, It is possible to output the second sensing signal i_s2 corresponding to the peak value of the current i.

The first and second hall sensors 122 and 124 output the first and second sensing signals i_s1 and i_s2 according to different first and second current peak ranges to easily confirm the current state of the current i , The peak value of the current (i) can be finely adjusted according to the current state of the current (i).

The IED 130 may include a signal determination unit 132 and a control unit 136.

When at least one of the first and second sensing signals i_s1 and i_s2 output from the first and second hall sensors 122 and 124 is inputted, the signal determining unit 132 determines the current state of the current i The main sensing signal can be determined according to the set priority among the first and second sensing signals i_s1 and i_s2.

That is, when all of the first and second sensing signals i_s1 and i_s2 are inputted, the signal determining unit 132 may determine the first sensing signal i_s1 as the main sensing signal.

The signal determining unit 132 determines the state of the current i precisely by checking that the first hall sensor 122 outputting the first sensing signal i_s1 is narrower in current measurement range than the second hall sensor 124 The first sensing signal i_s1 output from the first hall sensor 122 can be determined as the main sensing signal.

Also, when only the second sensing signal i_s2 is inputted, the signal determining unit 132 can determine the second sensing signal i_s2 as the main sensing signal.

The control unit 136 may check the current state of the current i according to the main sensing signal determined by the signal determining unit 132 and switch the shutoff switch 110 to the on state or the turn off state, I do not.

That is, when the signal determining unit 132 determines that the first sensing signal i_s1 is the main sensing signal, the controller 136 determines that the current state of the current i having passed through the blocking switch 110 is in a normal state So that the cutoff switch 110 can be controlled to be maintained in the turned-on state.

When the signal determining unit 132 determines that the second sensing signal i_s2 is the main sensing signal, the control unit 136 determines that the current state of the current i having passed through the cutoff switch 110 is in the overcurrent state And when the overcurrent state is maintained for the first time, the shutoff switch 110 can be controlled to be switched from the turn-on state to the turn-off state.

The current sensing portion 120 includes two first and second Hall sensors 122 and 124 so that the first and second Hall sensors 122 and 124 sense the magnetic field changes of the current i The IED 130 is advantageous in that the current state of the current i is confirmed by outputting the detected first and second sensing signals i_s1 and i_s2 to the IED 130. [

3 is a control block diagram showing a control configuration of a distribution system according to a second embodiment of the present invention.

3, the power distribution system 200 may include a shutdown switch 210, a current sensing unit 220, and an IED 230.

Off switch 210 is turned on to turn on the power supply line L in order to supply the current i to the power supply line L or to turn off the current i to be supplied to the power distribution line L It can be switched to the turn-off state.

The current sensing unit 220 may include first through third hall sensors 222, 224, and 226.

The first Hall sensor 222 can output the first sensing signal i_s1 corresponding to the peak value of the current i when the peak value of the current i is detected to fall within the first current peak range.

Further, when the second Hall sensor 224 detects that the peak value of the current (i) belongs to the second current peak range wider than the first current peak range, the second hall sensor 224 detects the second detection It is possible to output the signal i_s2.

If the third Hall sensor 226 detects that the peak value of the current i belongs to a third current peak range wider than the second current peak range, the third Hall sensor 226 outputs a third sense signal (i) corresponding to the peak value of the current i_s3.

Here, the first current peak range is a range from a first peak value to a second peak value, and the second current peak range is a range from the first peak value to a third peak value higher than the second peak value And the third current peak range may range from the second peak value to a fourth peak value higher than the third peak value.

In addition, each of the first to third current peak ranges may be determined according to the magnetic saturation of each of the first to third hall sensors 222, 224, and 226.

Here, the magnetic saturation of the magnetic bodies included in the first through third Hall sensors 222, 224, and 226 is lowered by the magnitude of the magnetic field of the current (i) 224 and 226 are saturated and the first to third sensing signals i_s1, i_s2 and i_s3 are not outputted.

For example, if the first hall sensor 222 has the first current peak range that can measure the peak value of the current i from 1 mA to 5 mA, the peak value of the current (i) It is possible to output the first sensing signal i_s1 corresponding to the peak value of the current i only when it belongs to the current peak range.

The second hall sensor 224 also has a second current peak range in which the peak value of the current i can measure from 1 mA to 10 mA, It is possible to output the second sensing signal i_s2 corresponding to the peak value of the current i.

The third hall sensor 226 may be configured such that if the peak value of the current i has the third current peak range that can measure from 1 mA to 20 mA then the peak value of the current i is in the third current peak range , It can output the third sensing signal i_s3 corresponding to the peak value of the current (i).

The first to third hall sensors 222, 224 and 226 output the first to third sensing signals i_s1, i_s2 and i_s3 according to different first to third current peak ranges, It is easy to confirm the current state, and the peak value of the current (i) can be finely adjusted according to the current state of the current (i).

The IED 230 may include a signal determination unit 232 and a control unit 236.

When at least one of the first to third sensing signals i_s1, i_s2 and i_s3 output from the first through third hall sensors 222, 224 and 226 is inputted, the signal determining unit 232 determines the current The main sensing signal can be determined according to the set priority among the first to third sensing signals i_s1, i_s2, i_s3 in order to check the current state.

That is, when all of the first to third sensing signals i_s1, i_s2 and i_s3 are inputted, the signal determining unit 232 can determine the first sensing signal i_s1 having the narrowest current measuring range as the main sensing signal.

The signal determination unit 232 determines that the first Hall sensor 222 outputting the first sensing signal i_s1 has a current measurement range narrower than that of the second and third hall sensors 224 and 226, The first sensing signal i_s1 output from the first hall sensor 222 can be determined as the main sensing signal.

When only the second and third sensing signals i_s2 and i_s2 are inputted, the signal determining unit 232 outputs the second sensing signal i_s2 output from the second Hall sensor 224 having a narrow current measurement range to the main sensing signal i_s2, .

The signal determination unit 232 may determine the third sensing signal i_s3 output from the third hall sensor 226 as the main sensing signal when only the third sensing signal i_s3 is input.

The control unit 236 can check the current state of the current i according to the main sensing signal determined by the signal determining unit 232 and switch the shutoff switch 210 to the on state or the turn off state, I do not.

That is, when the signal determining unit 232 determines that the first sensing signal i_s1 is the main sensing signal, the control unit 236 determines that the current state of the current i having passed through the cutoff switch 210 is in a normal state So that the cutoff switch 210 can be controlled to be kept in the turned-on state.

When the signal determining unit 232 determines that the second sensing signal i_s2 is the main sensing signal, the control unit 236 determines that the current state of the current i having passed through the cutoff switch 210 is in the overcurrent state And when the overcurrent state is maintained for the second time, the shutoff switch 210 can be controlled to be switched from the turned-on state to the turned-off state.

When the signal determining unit 232 determines the third sensing signal i_s3 as the main sensing signal, the control unit 236 confirms that the current state of the current i having passed through the cutoff switch 210 is in an accident occurrence state , It is possible to control so that the cutoff switch 210 is immediately switched from the turned-on state to the turned-off state.

The first through third Hall sensors 222, 224 and 226 may include a current sensing unit 220 for sensing current i, The IED 230 checks the current state of the current i by outputting the first to third sensing signals i_s1, i_s2 and i_s3 sensed sensitively to the change of the magnetic field of the electric current i to the IED 230, And the like.

4 is a view for explaining a control operation according to a sensing signal output from the power distribution system shown in FIG.

FIG. 4 illustrates a control operation according to inputs to the first through third sensing signals i_s1, i_s2, and i_s3 shown in FIG.

4 (a) shows the first to third sensing signals i_s1, i_s2 and i_s3 measured according to the time-current.

Here, the first sensing signal i_s1 has the narrower current measurement range than the second and third sensing signals i_s2 and i_s3, and the third sensing signal i_s3 is the first, The current measurement range in which the current (i) can be measured is greater than that of the first to third detection signals i_s1 and i_s2.

FIG. 4B shows the current state of the current i supplied to the distribution line L according to at least one of the first to third sensing signals i_s1, i_s2 and i_s3.

4A and 4B, when all the first to third sensing signals i_s1, i_s2 and i_s3 are input, the IED 230 generates a current I_s1 based on the first sensing signal i_s1, (i) can be confirmed as a normal state.

Also, if only the second and third sensing signals i_s2 and i_s3 are inputted, the IED 230 can check the current state of the current i based on the second sensing signal i_s2 in the overcurrent state.

Finally, if only the third sensing signal i_s3 is inputted, the IED 230 can confirm the current state of the current i as an occurrence state of an accident.

The power distribution system 200 of the embodiment determines the main sensing signal as the sensing signal having the highest priority, that is, the highest accuracy among the sensing signals output from each of the first through third hall sensors 222, 224, and 226, There is an advantage in that it is possible to control the operation of the display device 210.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, But the present invention is not limited thereto.

100, 200: power distribution system 110, 210:
120, 220: current sensing unit 130, 230: IED

Claims (10)

An output current sensing unit for sensing at least one of first and second sensing signals for sensing a current supplied to the power distribution line;
A shutoff switch for shutting off the current supplied to the power distribution line; And
Determining at least one of the first and second sensing signals as a main sensing signal according to the set priorities when at least one of the first and second sensing signals is inputted and checking the current state of the current according to the main sensing signal, And an intelligent electronic device (IED) for controlling the operation of said disconnecting switch.
The method according to claim 1,
The current sensing unit includes:
A first hall sensor for outputting the first sensing signal to the IED if the peak value of the current falls within a first current peak range; And
And a second Hall sensor for outputting the second sensing signal to the IED if the peak value of the current falls within a second current peak range wider than the first current peak range.
3. The method of claim 2,
Wherein the first current peak range is selected from the group consisting of:
A range between a first peak value and a second peak value higher than the first peak value,
Wherein the second current peak range is selected from the group consisting of:
And a third peak value higher than the first peak value to the second peak value.
3. The method of claim 2,
The IED includes:
A signal determining unit for determining the first sensing signal as the main sensing signal according to the priority when all of the first and second sensing signals are input; And
And a control unit for confirming that the current state of the current is in a normal state when the first sensing signal is determined as the main sensing signal and controlling the blocking switch to remain in a turned-on state.
5. The method of claim 4,
Wherein the signal determination unit comprises:
Determines the second sensing signal as the main sensing signal when the second sensing signal is input,
Wherein,
If the second sensing signal is determined to be the main sensing signal, it is determined that the current state of the current is an overcurrent state, and if the overcurrent state is maintained for a first time period, the blocking switch is switched from a turned- Distribution system to control.
A current sensing unit for outputting at least one of first to third sensing signals sensing a current supplied to the power distribution line;
A shutoff switch for shutting off the current supplied to the power distribution line; And
Determining at least one of the first to third sensing signals as a main sensing signal according to a set priority order when at least one of the first to third sensing signals is inputted, And an intelligent electronic device (IED) for controlling the operation of the blocking switch,
The current sensing unit includes:
A first hall sensor for outputting the first sensing signal to the IED if the peak value of the current falls within a first current peak range;
A second Hall sensor for outputting the second sensing signal to the IED if the peak value of the current falls within a second current peak range wider than the first current peak range; And
And a third Hall sensor for outputting the third sensing signal to the IED if the peak value of the current falls within a third current peak range wider than the second current peak range.
The method according to claim 6,
Wherein the first current peak range is selected from the group consisting of:
A range between a first peak value and a second peak value larger than the first peak value,
Wherein the second current peak range is selected from the group consisting of:
A range between the first peak value and a third peak value higher than the second peak value,
Wherein the third current peak range is selected from the group consisting of:
And a fourth peak value higher than the first peak value to the third peak value.
The method according to claim 6,
The IED includes:
A signal determining unit for determining the first sensing signal as the main sensing signal according to the priority when all of the first to third sensing signals are input; And
And a control unit for confirming that the current state of the current is in a normal state when the first sensing signal is determined as the main sensing signal and controlling the blocking switch to remain in a turned-on state.
9. The method of claim 8,
Wherein the signal determination unit comprises:
When the second and third sensing signals are input, determining the second sensing signal as the main sensing signal according to the priority,
Wherein,
If the second sensing signal is determined to be the main sensing signal, it is determined that the current state of the current is an overcurrent state. If the overcurrent state is maintained for a second time period, the blocking switch is turned from a turned- Distribution system to control.
9. The method of claim 8,
Wherein the signal determination unit comprises:
Determines the third sensing signal as the main sensing signal when the third sensing signal is input,
Wherein,
Wherein the control unit determines that the current state of the current is an accident occurrence state when the third sensing signal is determined as the main sensing signal and immediately switches the shutoff switch from the on state to the turn off state.

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