KR102099079B1 - Electric power quality management system and method - Google Patents

Abstract

The present invention provides a power quality management system capable of measuring power quality in real time. According to embodiments of the present invention, the power quality management system comprises: a plurality of circuit breakers; a plurality of measurement units connected to the circuit breakers; an element information separation unit to use measurement information measured by the measurement units to separate element information including one among voltage information, power information, waveform information, temperature information, power factor information, and load factor information; an element information comparison unit to compare the element information separated by the element information separation unit with a preset condition; an element value correction unit to perform correction for abnormal element information if the abnormal element information exists wherein the abnormal element information does not match the preset condition in the element information; an information error output unit to output an information error signal to the outside to provide a user with information indicating that power quality is not good if corrected abnormal element information generated by the correction still does not match the preset condition; and an emergency stop unit to urgently shut off the circuit breakers connected to the measurement units which have measured the abnormal element information if the abnormal element information or the corrected abnormal element information matches a preset emergency situation condition.

Description

Electric power quality management system and method

The present invention relates to a power quality management system and method, and more particularly, to a system and method for monitoring and controlling the power state for power quality management.

In general, in the case where electricity is not self-sufficient using renewable energy such as solar or solar heat, electricity is supplied from an external power source such as a thermal power / nuclear power plant. In this case, KEPCO, which supplies power, supplies electricity by setting various standard values in order to supply electricity with constant quality.

Meanwhile, when electricity is supplied from the outside, electricity flows through the electric wires to the final wiring system until the final load is reached. In the final wiring system, devices with various loads are connected, and electricity is supplied to these devices to operate the devices. At this time, when the power quality is not stable, various problems may occur, such as the device malfunctioning or the circuit is broken and operation stops.

Korea Registered Patent No. 10-1769357

In order to solve the problems of the prior art as described above, an embodiment of the present invention is to provide a power quality management system and method capable of measuring power quality in real time.

In addition, an embodiment of the present invention is to provide a power quality management system and method capable of performing power quality correction to maintain a constant power quality.

In addition, an embodiment of the present invention is to provide a power quality management system and method for protecting a device when it is determined that a problem occurs in a connected device due to a change in power quality over a certain period.

According to an aspect of the present invention for solving the above problems, a power quality management system is provided. The power quality management system, a plurality of circuit breakers; A plurality of measuring units respectively connected to the breakers; An element information separating unit separating element information including any one of voltage information, power information, waveform information, temperature information, power factor information, and load factor information using the measurement information measured by the measurement unit; An element information comparison unit that compares the element information separated through the element information separation unit with preset conditions, respectively; An element value correcting unit which corrects the abnormal element information when the abnormal element information does not match the preset condition among the element information; An information error output unit that outputs an information error signal to the user to provide information that the power quality is not good when the corrected abnormal element information generated through the correction still does not match the preset condition; And when the abnormality element information or the corrected abnormality element information coincides with a preset emergency situation condition, an emergency stop to prevent an electric accident by cutting off the circuit breaker connected to the measurement unit where the abnormality element information is measured. Wealth; includes.

The plurality of breakers may be formed to include a primary breaker that controls the entire circuit and a secondary breaker that controls a portion of the circuit.

In the plurality of circuit breakers, the primary circuit breaker is formed of a VCB (vacuum circuit breaker), the secondary circuit breaker is formed of an ACB (air circuit breaker), and the third or more circuit breakers may be further formed of an MCCB (overcurrent circuit breaker). .

The voltage information is obtained using the maximum amplitude and the root mean square (RMS) value, and the power information includes real-time, time, daily, and monthly cumulative information, and the waveform information measures frequency and harmonics to measure the harmonics. It includes information on the distortion rate, which is the degree of distortion, and the temperature information includes both the temperature of the circuit breaker to which each measurement unit is connected and the outside air temperature of the region where the circuit breaker is installed, and the load ratio information is daily, monthly, and yearly load ratio information. It may include.

The preset condition is a range or a reference value that is set to maintain the power quality normally for each element, and the preset voltage element condition is within a range of about 5% based on the supplied voltage, and a preset power element condition Is the daily or monthly reference limit contracted by the user, and the preset waveform element condition is a range of about 0.2% or less or less than 5% harmonic distortion based on the supplied frequency value, and the preset temperature element condition is the temperature rise of the breaker The limit, the preset power factor element condition is 90%, and the preset load factor element condition may be 80%.

When all of the element information meets the preset condition, it may be determined that the power quality is good.

The element value correcting unit may include: a voltage correction module that corrects the voltage information to increase or decrease the voltage to meet the preset voltage element condition when the voltage information does not match the preset voltage element condition; A power supply correction module that cuts off the power to correct the amount of power used to satisfy the preset power factor condition; A waveform correction module that corrects the frequency and the harmonic distortion rate to satisfy the preset waveform element condition; A temperature correction module that performs correction of the temperature by emitting the outside air to satisfy the preset temperature condition or stopping the operation of a device connected to the circuit breaker; And a load factor correction module that performs correction of the load factor by stopping operation of a device connected to the circuit breaker so as to satisfy the preset load factor factor condition.

The preset emergency condition may be a case in which any one of the element information that the circuit can accommodate reaches 95% according to a preset value set by the user or a configuration of the circuit.

According to an aspect of the present invention, a power quality management method is provided. The power quality management method includes: measuring information of power supplied to a circuit using a plurality of measurement units connected to a plurality of circuit breakers, and generating measurement information; Separating the element information including any one of voltage information, power information, waveform information, temperature information, power factor information, and load factor information using the measurement information using the element information separation unit; Comparing each of the separated element information with a preset condition using the element information comparison unit; If there is abnormal element information that does not match the preset condition among the element information, performing correction on the abnormal element information using an element value correction unit; If the corrected anomaly information generated by performing the correction still does not match the preset condition, an information error signal is generated using the information error output unit and output to the outside to inform the user that the power quality is not good. Providing; And when the abnormality element information or the corrected abnormality element information coincides with a preset emergency situation condition, using the emergency stop unit to urgently cut off the circuit breaker connected to the measurement unit where the abnormality element information is measured. do.

The plurality of breakers may be formed to include a primary breaker that controls the entire circuit and a secondary breaker that controls a portion of the circuit.

In the plurality of circuit breakers, the primary circuit breaker is formed of a VCB (vacuum circuit breaker), the secondary circuit breaker is formed of an ACB (air circuit breaker), and a third or more circuit breaker may be further formed of an MCCB (overcurrent circuit breaker). .

The voltage information is obtained using the maximum amplitude and the root mean square (RMS) value, and the power information includes real-time, time, daily, and monthly cumulative information, and the waveform information measures frequency and harmonics to measure the harmonics. It includes information on the distortion rate, which is the degree of distortion, and the temperature information includes both the temperature of the circuit breaker to which each measurement unit is connected and the outside air temperature of the region where the circuit breaker is installed, and the load ratio information is daily, monthly, and yearly load ratio information. It may include.

The preset condition is a range or a reference value that is set to maintain the power quality normally for each element, and the preset voltage element condition is within a range of about 5% based on the supplied voltage, and a preset power element condition Is the daily or monthly reference limit contracted by the user, and the preset waveform element condition is a range of about 0.2% or less or less than 5% harmonic distortion based on the supplied frequency value, and the preset temperature element condition is the temperature rise of the breaker The limit, the preset power factor element condition is 90%, and the preset load factor element condition may be 80%.

When all of the element information meets the preset condition, it may be determined that the power quality is good.

In the step of performing correction on the abnormal element information, when the voltage information does not match the preset voltage element condition, a voltage correction module is used to increase or decrease the voltage to meet the preset voltage element condition. Correcting by; Cutting off the power using a power supply correction module to correct the amount of power used to satisfy the preset power factor condition; Correcting the frequency and the harmonic distortion rate using a waveform correction module to satisfy the preset waveform element condition; Performing the correction of the temperature by emitting the outside air or stopping the operation of the device connected to the circuit breaker using a temperature correction module to satisfy the preset temperature condition; And performing the correction of the load factor by stopping the operation of the device connected to the circuit breaker using the load factor correction module to satisfy the preset load factor factor condition.

The preset emergency condition may be a case in which any one of the element information that the circuit can accommodate reaches 95% according to a preset value set by the user or a configuration of the circuit.

Power quality management system and method according to an embodiment of the present invention, there is an effect that can measure the quality of the power supplied in real time.

In addition, the power quality management system and method according to an embodiment of the present invention has an effect of generating a plurality of measurement areas to measure power quality for each area in real time.

In addition, the power quality management system and method according to an embodiment of the present invention has the effect of maintaining a constant power quality within a valid range through power quality correction.

In addition, the power quality management system and method according to an embodiment of the present invention has an effect of preventing a problem in a device when the power quality changes more than a certain level.

1 is a view briefly showing the configuration of a power quality management system according to an embodiment of the present invention in which a plurality of sensors are connected to a final wiring system.
2 is a simplified block diagram of a power quality management system according to an embodiment of the present invention.
3 is a block diagram showing the configuration of the element value correction unit of the power quality management system according to an embodiment of the present invention.
4 is a flowchart illustrating a power quality management method according to an embodiment of the present invention.
5 is a flowchart illustrating in more detail a step of performing correction on abnormal element information in a power quality management method according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains may easily practice. The present invention can be implemented in many different forms and is not limited to the embodiments described herein. In the drawings, parts not related to the description are omitted in order to clearly describe the present invention, and the same reference numerals are attached to the same or similar elements throughout the specification.

1 is a diagram briefly showing the configuration of a power quality management system according to an embodiment of the present invention in which a plurality of sensors are connected to a final wiring system, and FIG. 2 is a simplified view of a power quality management system according to an embodiment of the present invention. 3 is a block diagram showing the configuration of an element value correction unit of a power quality management system according to an embodiment of the present invention.

Hereinafter, a power quality management system according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 to 3.

Referring to FIG. 1, the power quality management system 100 according to an embodiment of the present invention is formed in a form in which a sensor 120 is connected to one end of the breaker 110. At this time, a plurality of breakers 110 may be formed, and in one embodiment of the present invention, it will be described that three breakers are formed.

The primary breaker 110A is formed as a main breaker capable of blocking power entering the final wiring system, and the primary sensor 120A is provided to measure the quality of power passing through the primary breaker 110A. At this time, the primary circuit breaker 110A may be preferably formed of a vacuum circuit breaker (VCB).

The secondary circuit breakers 110B are provided in the transformers 130 connected in parallel with the primary sensor 120A, respectively. The secondary circuit breaker 110B is provided to cut off power by separating the final wiring system into a predetermined area, and the secondary sensor 120B may be connected to measure the quality of power passing through the secondary circuit breaker 110B. At this time, the secondary circuit breaker 110B may be preferably formed of an air circuit breaker (ACB).

The tertiary breaker 110C is provided after the secondary sensor 120B, and separates a certain area separated by the secondary breaker 110B into a more detailed area or individually cuts power entering a device connected to the final wiring system. Can be formed. In addition, the tertiary sensor 120C may be provided to measure the quality of power passing through the tertiary breaker 110C, and the tertiary breaker 110C may be preferably formed of an overcurrent breaker (MCCB).

On the other hand, referring to Figure 2, the sensor 120 according to an embodiment of the present invention is connected to the circuit breaker 110, the measurement unit 210, the element information separation unit 220, the element information comparison unit 230, It is formed by including the element value correction unit 240, the information error output unit 250 and the emergency stop unit 260.

The measurement unit 210 is connected to the circuit breaker 110 and measures information related to power passing through the circuit breaker 110 to obtain measurement information.

The element information separation unit 220 receives measurement information measured by the measurement unit 210 and separates at least one element information included in the measurement information into each element information. The element information may include at least one of voltage information, power information, waveform information, power factor information, load factor information, and temperature information of the circuit breaker 110 for power passing through the circuit breaker 110.

The voltage information is obtained using the maximum amplitude and the root mean square (RMS) value, and the power information includes real-time, time, daily, and monthly cumulative information. Waveform information includes harmonic distortion rate information, which is the degree to which the harmonics are distorted by measuring frequency and harmonics, and load rate information includes load rate information for daily, monthly, and yearly. In addition, the temperature information includes both the temperature of the circuit breaker 110 to which each measurement unit 210 is connected and the outside temperature of the area where the circuit breaker is installed.

The element information comparison unit 230 receives the element information separated from the element information separation unit 220 and compares each with a preset condition. The preset condition may be a condition for maintaining power quality constant, or a condition for reducing power consumption and electricity bill. These conditions may be a range or a limit (reference value) set according to a user's need or contract.

For example, the preset voltage element condition may be set within a range of about 5% based on the supplied voltage. In other words, when the supplied voltage is 220V, the condition of the preset voltage element may be 209V to 231V.

In addition, as an example, the preset power factor condition may be a daily or monthly standard limit set or contracted by the user. In other words, when the user sets or contracts a monthly standard limit of 200 kWh, the preset power factor condition may be 200 kWh. Furthermore, the condition of the preset power element may be set in a plurality of sections according to the user's setting.

In addition, as an example, the preset waveform condition may be set within a range of about 0.2% based on the supplied frequency value. In other words, when the supplied frequency value is 60 Hz, the condition of the preset waveform element may be 59.88 Hz to 60.12 Hz.

At this time, the preset waveform condition may include not only the frequency but also the harmonic distortion rate, and the harmonic distortion rate may be limited to 5%.

In addition, as an example, the preset power factor element condition may be set to a range in which the power factor, which is a value obtained by dividing active power by apparent power, is 90% to 100%.

In addition, as an example, the preset load factor element condition may be a load factor set by the user. In other words, when the user sets the load factor to 80%, the condition of the preset load factor element may be designated as 80%.

In addition, as an example, the preset temperature element condition is a temperature rise limit of the circuit breaker, and may be set as a difference between the maximum temperature allowed and the outdoor temperature according to the configuration of the circuit breaker. In other words, according to the configuration of the circuit breaker, the maximum allowable temperature is 90 degrees, and when the measured outdoor temperature is 30 degrees, the temperature rise limit of the circuit breaker may be set to 60 degrees.

The element information comparison unit 230 compares each element information separated by the element information separation unit 220 using the above-described respective element conditions. At this time, when all the separated element information satisfies each of the preset element conditions, the power quality management system 100 according to an embodiment of the present invention determines that the quality of power currently supplied is good.

On the other hand, if the separated element information does not satisfy the preset element condition, the element information comparison unit 230 transmits the corresponding element information to the element value correction unit 240.

The element value correction unit 240 receives element information that does not satisfy a predetermined element condition from the element information comparison unit 230 and performs correction on the element value. The element value compensator 240 includes a voltage correction module 310, a power supply correction module 320, a waveform correction module 330, a temperature correction module 340, and a temperature correction module 340 as shown in FIG. It is formed to include a load factor correction module 350.

The voltage correction module 310 is formed to correct the voltage passing through the circuit breaker 110 when the voltage information outside the preset voltage element condition is confirmed by the element information comparison unit 230. To this end, the voltage correction module 310 may be formed, for example, in the form of a transformer.

The power supply correction module 320 is formed to cut off power passing through the circuit breaker 110 when power information outside a preset power element condition is confirmed by the element information comparison unit 230. To this end, the power supply correction module 320 may be formed in the form of a switch, for example.

The waveform correction module 330 is configured to correct the frequency or harmonic distortion rate of electricity passing through the circuit breaker 110 when waveform information outside the preset waveform element condition is confirmed by the element information comparison unit 230.

The temperature correction module 340 is formed to reduce the outside temperature of the circuit breaker 110 when the temperature information outside the preset temperature element condition is confirmed in the element information comparison unit 230. To this end, the temperature correction module 340 may be formed of, for example, a cooling device for lowering the outside temperature.

The load factor correction module 350 is formed to reduce the load factor by cutting off power passing through the circuit breaker 110 when the load factor information outside the preset load factor element condition is confirmed in the element information comparison unit 230. To this end, the load factor correction module 350 may be formed in the form of a switch, for example.

On the other hand, each element information corrected by the element value correction unit 240 is again compared with the element conditions set in the element information comparison unit 230 again. At this time, when the preset element condition is satisfied through the element value correction, the power quality management system 100 according to an embodiment of the present invention determines that the power quality is good.

However, if the element information comparison unit 230 determines that at least one of the corrected element information still does not satisfy the preset element condition, the information error output unit 250 has a good quality of power currently supplied. It generates an information error signal that it does not, and outputs it to the outside, so that the user can prepare for unfavorable power quality.

At this time, the information error output unit 250 may output an information error to a device connected by wire or wirelessly, or may output a visual or audible alarm using an output device connected to a circuit breaker in which the corresponding element information is measured. .

On the other hand, when the element information or the corrected element information that is compared with the preset element condition in the element information comparison unit 230 matches the preset emergency condition, the emergency stop unit 260 breaks down the devices connected to the final wiring system. In order to prevent the breaker 110 is formed to be able to prevent the electric accident by blocking the emergency.

In this case, the emergency condition may be a preset value set by the user or a case in which any element information reaching 95% of the limit that the circuit can accommodate according to the circuit configuration among the element information exists. It is obvious that the circuit limit values are prepared to more easily understand the present invention, and the present invention may be changed according to the needs or demands of the user.

Meanwhile, FIGS. 4 and 5 illustrate a power quality management method according to an embodiment of the present invention. 4 is a flow chart showing a power quality management method according to an embodiment of the present invention, and FIG. 5 is a step of performing correction for abnormal element information in a power quality management method according to an embodiment of the present invention. It is a flow chart shown. Hereinafter, the power quality management methods of FIGS. 4 and 5 will be described using the power quality management systems of FIGS. 1 to 3 for convenience of explanation.

Referring to FIG. 4, in the power quality management method 400 according to an embodiment of the present invention, generating measurement information measuring power information (S410), and separating element-specific information using measurement information (S420), comparing the separated element-specific information with a preset condition (S430), performing a correction for the abnormal element information (S450), and urgently blocking the circuit breaker connected to the measurement unit where the abnormal element information is measured It is formed including the step (S460).

First, in order to manage the quality of power according to an embodiment of the present invention, power information of a connected circuit breaker is measured and measurement information is generated using a measurement unit included in a sensor connected to the circuit breaker (step S410).

At this time, a plurality of breakers may be formed, and in one embodiment of the present invention, it will be described that three breakers are formed.

The primary breaker is formed as a main breaker that can cut off the power entering the final wiring system, and the primary sensor is provided to measure the quality of the power passing through the primary breaker. At this time, the primary circuit breaker may be preferably formed of a vacuum circuit breaker (VCB).

Secondary circuit breakers are respectively provided in a transformer connected in parallel with the primary sensor. The secondary breaker is provided to cut off power by separating the final wiring system into a certain area, and a secondary sensor can be connected to measure the quality of power passing through the secondary breaker. At this time, the secondary circuit breaker may be preferably formed of an air circuit breaker (ACB).

The tertiary circuit breaker is provided after the secondary sensor, and may be formed to separate a certain area separated by the secondary circuit breaker into a more detailed area or to individually block power entering a device connected to the final wiring system. In addition, the tertiary sensor may be provided to measure the quality of power passing through the tertiary breaker, and the tertiary breaker may be preferably formed of an overcurrent breaker (MCCB).

That is, the measurement unit connected to the circuit breaker may obtain measurement information by measuring information related to power passing through the circuit breaker.

Next, the element-specific information is separated from the element information separation unit using the measurement information (step S420).

The element information separation unit receives the measurement information measured in step S410 and separates at least one element information included in the measurement information into respective element information. The element information may include at least one of voltage information about power passing through the circuit breaker, power information, waveform information, power factor information, load factor information, and temperature information of the circuit breaker.

The voltage information is obtained using the maximum amplitude and the root mean square (RMS) value, and the power information includes real-time, time, daily, and monthly cumulative information. Waveform information includes harmonic distortion rate information, which is the degree to which the harmonics are distorted by measuring frequency and harmonics, and load rate information includes load rate information for daily, monthly, and yearly. In addition, the temperature information includes both the temperature of the circuit breaker to which each measurement unit is connected and the outside air temperature of the region where the circuit breaker is installed.

Next, the separated element-by-element information is compared using the preset condition and the element information comparison unit, respectively (step S430).

The element information comparison unit receives the separated element information in step S420 and compares each with a preset condition. The preset condition may be a condition for maintaining power quality constant, or a condition for reducing power consumption and electricity bill. These conditions may be a range or a limit (reference value) set according to a user's need or contract.

For example, the preset voltage element condition may be set within a range of about 5% based on the supplied voltage. In other words, when the supplied voltage is 220V, the condition of the preset voltage element may be 209V to 231V.

In addition, as an example, the preset power factor condition may be a daily or monthly standard limit set or contracted by the user. In other words, when the user sets or contracts a monthly standard limit of 200 kWh, the preset power factor condition may be 200 kWh. Furthermore, the condition of the preset power element may be set in a plurality of sections according to the user's setting.

In addition, as an example, the preset waveform condition may be set within a range of about 0.2% based on the supplied frequency value. In other words, when the supplied frequency value is 60 Hz, the condition of the preset waveform element may be 59.88 Hz to 60.12 Hz.

At this time, the preset waveform condition may include not only the frequency but also the harmonic distortion rate, and the harmonic distortion rate may be limited to 5%.

In addition, as an example, the preset power factor element condition may be set to a range in which the power factor, which is a value obtained by dividing active power by apparent power, is 90% to 100%.

In addition, as an example, the preset load factor element condition may be a load factor set by the user. In other words, when the user sets the load factor to 80%, the condition of the preset load factor element may be designated as 80%.

In addition, as an example, the preset temperature element condition is a temperature rise limit of the circuit breaker, and may be set as a difference between the maximum temperature allowed and the outdoor temperature according to the configuration of the circuit breaker. In other words, according to the configuration of the circuit breaker, the maximum allowable temperature is 90 degrees, and when the measured outdoor temperature is 30 degrees, the temperature rise limit of the circuit breaker may be set to 60 degrees.

The element information comparison unit compares each element information separated in step S420 using the above-described respective element conditions. At this time, when all the separated element information satisfies each of the preset element conditions, in the power quality management method 400 according to an embodiment of the present invention, it is determined that the quality of power currently supplied is good.

On the other hand, if at least one of the element-specific information separated in step S430 does not satisfy the preset element condition, the element value correction unit is used to correct the element information (step S440).

The element value correction unit receives element information that does not satisfy the preset element condition checked in step S430 and performs correction for the element value, and a more detailed step is illustrated in FIG. 5.

Referring to Figure 5, the step of performing correction on the abnormal element information according to an embodiment of the present invention (S440), determining whether the abnormal element information is voltage information (S510), whether the abnormal element information is power information It includes a step of determining (S520), determining whether the abnormal element information is waveform information (S530) and determining whether the abnormal element information is temperature information (S540).

If the abnormal element information is determined as voltage information (step S510), the element value correcting unit corrects the voltage passing through the breaker using the voltage correction module (step S511), and if it is not determined as the voltage information, the abnormal element is next powered It is determined whether it is information (step S520).

If the abnormal element information is determined to be power information (step S520), the element value correcting unit blocks power passing through the circuit breaker using the power supply correction module (step S521). It is determined whether it is waveform information (step S530).

When the abnormal element information is determined as waveform information (step S530), the element value correcting unit corrects the frequency or harmonic distortion rate of electricity passing through the circuit breaker using the waveform correction module (step S531). It is determined whether the abnormal element is the temperature information (step S540).

If the abnormal element information is determined as temperature information (step S540), the element value correcting unit reduces the outside temperature of the circuit breaker using the temperature correction module (step S541), and if it is not determined as temperature information, the abnormal element information is load factor information It is determined to be, and load factor correction is performed using the load factor correction module (step S542).

The above-described flowchart of FIG. 5 is one flowchart created for convenience of description, and since there is no or little change in performance or effect due to a change in the order of determining which information is an abnormal element, the order may be changed according to a user's selection. .

Meanwhile, when the correction for the abnormal element information is completed (step S440), each element corrected in step S440 may return to step S430 and be compared again with a preset element condition. At this time, when the element value corrected in step S440 satisfies the preset element condition, in the power quality management method 400 according to an embodiment of the present invention, it is determined that the quality of the power currently supplied is good.

However, if at least one of the corrected element values compared again in step S430 still does not satisfy the preset element condition, an information error signal is generated and output to the outside (step S450).

The information error signal is generated using the information error output unit and is output to the outside including information that the quality of power currently being supplied is not good, so that the user can prepare for unfavorable power quality.

At this time, the information error output unit may output the information error to a device connected by wire or wirelessly, or may output a visual or audible alarm using an output device connected to a circuit breaker for which the corresponding element information is measured.

Meanwhile, when the element information to be compared in step S430 or the corrected element value to be compared again coincides with a preset emergency condition, the power quality management method according to an embodiment of the present invention uses the emergency stop unit to display the abnormal element information. The circuit breaker connected to the measured measurement unit is urgently cut off (step S460).

The emergency stop unit is formed to prevent a breakdown of devices connected to the final wiring system by emergency stopping the breaker, thereby preventing electrical accidents.

In this case, the emergency condition may be a preset value set by the user or a case where any element information reaching 95% of a limit that the circuit can accommodate according to the configuration of the circuit among element information exists. It is obvious that the circuit limit values are prepared to more easily understand the present invention, and the present invention may be changed according to the needs or demands of the user.

Although one embodiment of the present invention has been described above, the spirit of the present invention is not limited to the embodiments presented herein, and those skilled in the art to understand the spirit of the present invention may add elements within the scope of the same spirit. However, other embodiments may be easily proposed by changing, deleting, adding, or the like, but it will also be considered to be within the scope of the present invention.

100: power quality management system
110 (110A, 110B, 110C): Circuit breaker (primary, secondary, tertiary)
120 (120A, 120B, 120C): Sensor (1st, 2nd, 3rd)
130: transformer 210: measuring unit
220: element information separation unit 230: element information comparison unit
240: element value correction unit 250: information error output unit
260: emergency stop 310: voltage correction module
320: power supply correction module 330: waveform correction module
340: temperature correction module 350: load factor correction module

Claims (16)

A plurality of breakers;
A plurality of measuring units respectively connected to the breakers;
An element information separating unit separating element information including any one of voltage information, power information, waveform information, temperature information, power factor information, and load factor information using the measurement information measured by the measurement unit;
An element information comparison unit that compares the element information separated through the element information separation unit with preset conditions, respectively;
An element value correcting unit which corrects the abnormal element information when the abnormal element information does not match the preset condition among the element information;
An information error output unit that outputs an information error signal to the user to provide information that the power quality is not good when the corrected abnormal element information generated through the correction still does not match the preset condition; And
When the abnormality element information or the corrected abnormality element information coincides with a preset emergency situation condition, an emergency stop unit for urgently shutting off the circuit breaker connected to the measurement unit where the abnormality element information is measured to prevent an electric accident. Power quality management system comprising a. According to claim 1,
The plurality of circuit breakers,
A power quality management system formed by including a primary circuit breaker controlling the entire circuit and a secondary circuit breaker controlling a portion of the circuit. According to claim 2,
The plurality of circuit breakers,
The primary circuit breaker is formed of a VCB (vacuum circuit breaker), the secondary circuit breaker is formed of an ACB (air circuit breaker), the third or more circuit breakers are further formed by MCCB (overcurrent circuit breaker) power quality management system. According to claim 3,
The voltage information is obtained using the maximum amplitude and the root mean square (RMS) value, and the power information includes real-time, time, daily, and monthly cumulative information, and the waveform information measures frequency and harmonics to measure the harmonics. It includes information on the distortion rate, which is the degree of distortion, and the temperature information measures both the temperature of the circuit breaker to which each measurement unit is connected and the outside air temperature of the region where the circuit breaker is installed, and the load factor information is daily, monthly and yearly load factor information Power quality management system comprising a. The method of claim 4,
The preset condition is a range or a reference value that is set to maintain the power quality normally for each element,
The preset voltage element condition is within a range of about 5% based on the supplied voltage,
The pre-set power factor conditions are the daily or monthly standard limits contracted by the user,
The preset waveform element condition is a range of about 0.2% or less, or a harmonic distortion rate of less than 5% based on the supplied frequency value.
The preset temperature element condition is the temperature rise limit of the circuit breaker,
The preset power factor factor condition is 90%,
A power quality management system wherein the preset load factor factor condition is 80%. The method of claim 5,
A power quality management system that determines that the power quality is good when all of the element information meets the preset condition. The method of claim 6,
The element value correction unit,
A voltage correction module that corrects the voltage information to increase or decrease the voltage to meet the preset voltage element condition when the voltage information does not match the preset voltage element condition;
A power supply correction module that cuts off the power to correct the amount of power used to satisfy the preset power factor condition;
A waveform correction module that corrects the frequency and the harmonic distortion rate to satisfy the preset waveform element condition;
A temperature correction module that performs correction of the temperature by emitting the outside air to satisfy the preset temperature condition or stopping the operation of a device connected to the circuit breaker; And
And a load factor correction module that performs correction of the load factor by stopping the operation of the device connected to the circuit breaker so as to satisfy the preset load factor factor condition. The method of claim 7,
The preset emergency condition condition is a power quality management system in which any of the element information that the circuit can accommodate reaches 95% according to a preset value set by the user or a configuration of the circuit. Generating measurement information by measuring information of power supplied to the circuit using a plurality of measurement units each connected to a plurality of circuit breakers;
Separating the element information including any one of voltage information, power information, waveform information, temperature information, power factor information, and load factor information using the measurement information using the element information separation unit;
Comparing each of the separated element information with a preset condition using the element information comparison unit;
If there is abnormal element information that does not match the preset condition among the element information, performing correction on the abnormal element information using an element value correction unit;
If the corrected anomaly information generated by performing the correction still does not match the preset condition, an information error signal is generated using the information error output unit and output to the outside to inform the user that the power quality is not good. Providing; And
And when the abnormality element information or the corrected abnormality element information coincides with a predetermined emergency situation condition, urgently shutting off the circuit breaker connected to the measurement unit where the abnormality element information is measured using an emergency stop unit. How to manage power quality. The method of claim 9,
The plurality of circuit breakers,
Power quality control method formed by including a primary circuit breaker for controlling the entire circuit and a secondary circuit breaker for controlling a portion of the circuit. The method of claim 10,
The plurality of circuit breakers,
The primary circuit breaker is formed of a VCB (vacuum circuit breaker), the secondary circuit breaker is formed of an ACB (air circuit breaker), the third or more circuit breaker is further formed by MCCB (overcurrent circuit breaker) power quality management method. The method of claim 11,
The voltage information is obtained using the maximum amplitude and the root mean square (RMS) value, and the power information includes real-time, time, daily, and monthly cumulative information, and the waveform information measures frequency and harmonics to measure the harmonics. It includes information on the distortion rate, which is the degree of distortion, and the temperature information measures both the temperature of the circuit breaker to which each measurement unit is connected and the outside air temperature of the region where the circuit breaker is installed, and the load factor information is daily, monthly and yearly load factor information Power quality management method comprising a. The method of claim 12,
The preset condition is a range or a reference value that is set to maintain the power quality normally for each element,
The preset voltage element condition is within a range of about 5% based on the supplied voltage,
The pre-set power factor conditions are the daily or monthly standard limits contracted by the user,
The preset waveform element condition is a range of about 0.2% or less, or a harmonic distortion rate of less than 5% based on the supplied frequency value.
The preset temperature element condition is the temperature rise limit of the circuit breaker,
The preset power factor factor condition is 90%,
A power quality management method wherein the preset load factor factor condition is 80%. The method of claim 13,
A power quality management method for determining that the power quality is good when all of the element information meets the preset condition. The method of claim 14,
The step of performing correction on the abnormal element information may include:
Correcting the voltage information using a voltage correction module to increase or decrease the voltage to meet the preset voltage element condition when the voltage information does not match the preset voltage element condition;
Cutting off the power using a power supply correction module to correct the amount of power used to satisfy the preset power factor condition;
Correcting the frequency and the harmonic distortion rate using a waveform correction module to satisfy the preset waveform element condition;
Performing the correction of the temperature by emitting the outside air or stopping the operation of the device connected to the circuit breaker using a temperature correction module to satisfy the preset temperature condition; And
And performing the correction of the load factor by stopping the operation of the device connected to the circuit breaker using a load factor correction module to satisfy the preset load factor factor condition. The method of claim 15,
The predetermined emergency condition condition is a power quality management method in which any of the element information that the circuit can accommodate reaches 95% according to a preset value set by the user or a configuration of the circuit.

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