KR101311364B1 - The apparatus for surveillance of electronic power distribution and electronic power distribution controlling system and method using the same - Google Patents

Abstract

PURPOSE: A distributed power remote monitoring & control connecting device, a distributed power remote monitoring & control system, and a method thereof can control operations related to various power managements. CONSTITUTION: A distributed power remote monitoring & control connecting device comprises an image current transformer, a processor, and a communication unit (440). The image current transformer is connected to line R, S, and T, and measures an amount of output current of line R, line S, and line T which are outputted to a home consumer The processor determines whether leakage or electric conduction is generated based on the amount of output current of line R, line S, and line T. The communication unit transmits the amount of output current of line R, line S, and line T from the image current transformer to a power management system. [Reference numerals] (400) Current measuring unit; (420) Sensor unit; (440) Communication unit

Description

Distribution power remote monitoring and control device and a distribution power remote monitoring and control system using the same, the present invention {The apparatus for surveillance of electronic power distribution and electronic power distribution controlling system and method using the same}

The present invention solves the risk of electric safety accidents due to the deterioration of power lines due to the excessive number of circuits branched from the power lines by supplying power to a large number of consumers of the column transformer, and the excessive maintenance cost and aesthetic damage due to excessive connection parts. The present invention relates to an apparatus, a system, and a method for solving the problem, improving the efficiency of a pole transformer, and using a leakage power consumption of a conductive power line. .

Increasing power demand due to industrial development, concentration of power demand in large cities, and increasing capacity of power equipment for consumers are in progress. In addition, the rapid increase in the standard of living of the people and the rapid growth of the high precision industry place a greater demand on the quality of electricity supply. In order to effectively cope with the trends of power usage patterns and power demand caused by urban overcrowding and the rapid increase in power consumption, efficient and systematic management of distribution loads such as accurate trend analysis and reliable future power demand prediction are needed. need.

In the distribution system mainly responsible for the load portion of the power system, a stable supply of power can be smoothly performed by a power management system installed between each major substation. In addition, the end customer load is supplied with power via a column transformer. The capacity of the column transformer can be estimated based on the estimated load, by dividing the customer into several blocks at the terminal substation.

In recent years, however, there has been an increase in the number of cooling and heating loads and information processing facilities such as computers. In addition, due to the temporary use of more than the expected power consumption in the industrial area, the load concentration area expansion and load bias is intensified. This causes the load on the columnar transformer to change irregularly and sometimes the columnar transformer is heated by an overload, facilitating deterioration of the columnar transformer.

Frequent deterioration of columnar transformers can lead to accidents such as damage to insulation between the windings and increased leakage current, which can lead to accidents such as loss of transformers due to fire and, in some cases, economic loss of customers as well as loss of life. The damage is threatening the safety and reliability of the power supply. Various methods need to be studied to prevent the loss of such a transformer.

The patent document described in the following prior art document relates to a cooling fan operation monitoring device and method of a columnar transformer as KR2010-95311. Specifically, KR2010-95311 relates to a method of monitoring cooling fan operation of a column transformer by comparing and analyzing power consumption and phase current data.

Domestic Patent Publication No. 2010-95311

The present invention is to solve the above-mentioned problems of the prior art, the present invention solves the risk of electric safety accidents caused by the deterioration of the power line due to the excessive number of circuits branched from the power line by supplying power to a number of consumers of the column transformer. In addition, it can eliminate excessive maintenance cost and aesthetic damage due to excessive connection area, improve the efficiency of pole transformer and know excessive leakage of conductive power line of customer. To provide an apparatus, system and method for enabling the prediction of demand.

In the remote power distribution monitoring and control method according to an embodiment of the present invention, the output current amount of the R line, the output current amount of the S line, which is the current output from the image current transformer to the customer, based on the image current transformer connected to the R line, the S line, and the T line, respectively. The method may include measuring an output current amount of the T line, and determining whether a short circuit or a conductive current is generated based on the output current amount of the R line, the output current amount of the S line, and the output current amount of the T line. The image current transformer may further include transmitting the output current amount of the R line, the output current amount of the S line, and the output current amount of the T line to a power management system. The power management system determines whether the leakage current of the cable is generated and whether the electric conductivity is generated based on the sum of the output current amount of the R line, the output current amount of the S line and the output current amount of the T line, and the use current amount of the customer transmitted from the installed remote meter of the customer. You can judge. The output current amount of the R line, the output current amount of the S line, the output current amount of the T line to the power management system in the image current transformer, the output current amount of the R line, the output current amount of the S line, the output of the T line in the image current transformer. It may be a step of transmitting the current amount to the access point (AP) using a wireless LAN in real time or periodically and the AP transmits the output current amount of the R line, the output current amount of the S line, the output current amount of the T line to the power management system. The image current transformer periodically transmits the output current amount of the R line, the output current amount of the S line, and the output current amount of the T line to the AP based on information transmitted by the power management system or in real time. It can be determined whether to send. Measuring an input current amount of the R line, an input current amount of the S line, and an input current amount of the T line in a current transformer, and displaying an input current amount of the R line, an input current amount of the S line, and an input current amount of the T line measured in the current transformer It may further comprise a step. The method may further include detecting degradation of a cable transmitting power from the column transformer based on a temperature sensor. Determining whether an electric leakage or a conductive current has occurred based on the output current amount of the R line, the output current amount of the S line, and the output current amount of the T line includes determining an output current amount of the R line, an output current amount of the S line, and an output current amount of the T line. Determining that a short circuit occurs when a peak occurs in an output current, and when the output current is greater than a change of a predetermined threshold based on an output current amount of the R line, an output current amount of the S line, and an output current amount of the T line. The method may further include determining that a challenge occurs.

In addition, the distribution power remote monitoring and control device according to an embodiment of the present invention includes a video current transformer and a processor, the video current transformer is a customer in the video current transformer based on the video current transformer connected to the R line, S line, T line respectively The output current amount of the R line, the output current amount of the S line, and the output current amount of the T line, which are output currents, are measured, and the processor has a short circuit and a conduction based on the output current amount of the R line, the output current amount of the S line, and the output current amount of the T line. It may be implemented to determine whether it has occurred. The distribution power remote monitoring and control connection device may further include a communication unit, and the communication unit may be implemented to transmit the output current amount of the R line, the output current amount of the S line, and the output current amount of the T line in the video current transformer to a power management system. . The power management system determines whether the leakage current of the cable is generated and whether the electric conductivity is generated based on the sum of the output current amount of the R line, the output current amount of the S line and the output current amount of the T line, and the use current amount of the customer transmitted from the installed remote meter of the customer. You can judge. The communication unit may be implemented to transmit the output current amount of the R line, the output current amount of the S line, the output current amount of the T line in real time or periodically using an WLAN to the access point (AP) in the image current transformer. The output current amount of the R line, the output current amount of the S line, and the output current amount of the T line to the power management system, and the image current transformer measures the R measured in the image current transformer to the AP by information transmitted by the power management system. The output current amount of the line, the output current amount of the S line, the output current amount of the T line can be determined whether to transmit periodically or in real time. The distribution power remote monitoring and control device may further include a current transformer and a display unit, the current transformer is implemented to measure the input current amount of the R line, the input current amount of the S line, the input current amount of the T line in the current transformer, and the display unit is The input current amount of the R line, the input current amount of the S line, and the input current amount of the T line measured by a current transformer may be implemented. The distribution power remote monitoring control connection device may further include a sensor unit, and the sensor unit may be implemented to detect deterioration of a cable transmitting power from the column transformer based on a temperature sensor. The processor determines that a short circuit occurs when a peak occurs in an output current based on the output current amount of the R line, the output current amount of the S line, and the output current amount of the T line, and the output current amount of the R line and the output current amount of the S line. Based on the output current amount of the T line, the output current may be implemented to determine that a conductivity occurs when the output current is greater than a change of a predetermined threshold value.

The features and advantages of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings.

Prior to that, terms and words used in the present specification and claims should not be construed in a conventional and dictionary sense, and the inventor may properly define the concept of the term in order to best explain its invention It should be construed as meaning and concept consistent with the technical idea of the present invention.

As described above, according to the power control method and the apparatus using the method according to the embodiment of the present invention, it is possible to determine whether a single load occurs in the column transformer and whether an overload occurs. Accordingly, power management may be performed by determining whether leakage occurs in power transmitted from the column transformer. In addition, it is possible to prevent the overload of the column transformer to prevent the loss of the column transformer.

1 is a conceptual diagram illustrating a power distribution remote monitoring control connection device according to an embodiment of the present invention.
2 is a conceptual diagram illustrating a distribution power remote monitoring control connection device of a column transformer according to an embodiment of the present invention.
3 is a conceptual diagram illustrating a data transmission method generated in a distribution power remote monitoring and control access device according to an embodiment of the present invention.
4 is a block diagram showing a distribution power remote monitoring and control connection device according to an embodiment of the present invention.
5 is a flowchart illustrating a power control method of a distribution power remote monitoring and controlling device according to an embodiment of the present invention.
6 is a flowchart illustrating a power control method of a power distribution remote monitoring and controlling device according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The objectives, specific advantages and novel features of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG. It should be noted that, in the present specification, the reference numerals are added to the constituent elements of the drawings, and the same constituent elements are assigned the same number as much as possible even if they are displayed on different drawings. Also, terms such as " first ", " second ", " one side ", " other side ", etc. are used to distinguish one element from another element, . DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In the following description of the present invention, detailed description of related arts which may unnecessarily obscure the gist of the present invention will be omitted.

It is to be understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, . On the other hand, when an element is referred to as being "directly connected" or "directly connected" to another element, it should be understood that there are no other elements in between.

The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this application, the terms "comprise" or "have" are intended to indicate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, and one or more other features. It is to be understood that the present invention does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, components, or a combination thereof.

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

1 is a conceptual diagram illustrating a power distribution remote monitoring control connection device according to an embodiment of the present invention.

Referring to FIG. 1, a distribution power remote monitoring control connection device 100 may be additionally installed in a columnar transformer. The distribution power remote supervisory control connection device 100 provided in the columnar transformer (1) measures leakage power (or leakage current) or output current, (2) detects degradation of the columnar transformer, and (3) predicts the power consumption of the consumer. Can be. Hereinafter, the embodiment of the present invention specifically discloses the operation of the power distribution remote monitoring control connection device.

(1) Measure leakage power.

The distribution power remote monitoring and controlling device 100 measures the pole current of the pole transformer and the primary current output from the distribution power remote monitoring and controlling device 100 to the customer. can do. By comparing the sum of the primary currents output from the distribution power remote monitoring and control connection device 100 to the consumer and the current received from the actual consumer, it is possible to measure the amount of power leaked when transferring power from the pole transformer to the consumer. .

For example, if the difference between two currents is more than a certain threshold based on the sum of the primary currents transmitted from the pole transformer to the consumer and the current actually received at the consumer, the power at the transfer of power from the pole transformer to the consumer A leak can be detected.

To detect power leakage, the value of the current transmitted from the pole transformer to the consumer and the current value received from the consumer can be transmitted to the power management system through the wired network or the wireless network to detect the leakage of power. The power management system is a system for controlling power transmission and may perform control in various power management related operations such as determining whether a power leakage occurs or measuring an amount of power used by a customer.

Columnar transformers and consumers can use a zero current transformer (ZCT) to measure current values and perform remote short-circuit monitoring. When power leaks from a cable that transmits power, it is possible to determine whether a cable has leaked power and to cut off the challenge early. In addition, the location of the obsolete cable that generates leakage power can be easily identified, making it easy to replace the obsolete cable. Specific embodiments will be described below in the Examples of the present invention.

(2) The power consumption of the consumer can be calculated.

Accurately predicting the expected power demand is an important issue in managing power. According to the exemplary embodiment of the present invention, the distribution power remote monitoring and control connection device 100 of the columnar transformer may measure the amount of power transmitted to the customer and periodically transmit it to the power management system. The power management system can store the measured power data in a database and generate statistical data on the amount of power required by the customer for each column transformer based on the measured power data. These statistical data can be used to calculate power estimates. In this way, more accurate power prediction can lead to effective power management.

(3) Determination of column transformer deterioration

The distribution power remote supervisory control connection device 100 may include a cable degradation temperature sensor that measures a temperature for detecting degradation of a cable provided in a transformer. The distribution power remote monitoring control access device 100 may determine whether the cable is deteriorated based on the sensor. If the cable is degraded, it can send information to the power management system that the cable is degraded.

That is, by performing the above-described method based on the distribution power remote monitoring and control connection device 100 provided in the column transformer, whether or not a single load is generated in each column transformer, whether an overload occurs, and the degree of aging of the cable of the column transformer You can judge. Therefore, transformer loss can be prevented in advance, and leakage power can be reduced to increase power efficiency.

2 is a conceptual diagram illustrating a distribution power remote monitoring control connection device of a column transformer according to an embodiment of the present invention.

FIG. 2A is a conceptual diagram illustrating a method of transmitting power from a column transformer to a consumer, and FIG. 2B is a conceptual diagram illustrating a distribution power remote monitoring control connection device of a column transformer in detail.

Referring to FIG. 2B, the distribution power remote monitoring control connection device 200 connects the output side power line of the columnar transformer to the input unit 220 of the distribution power remote monitoring control connection device 200. For example, when the power line of 380V of the pole-type transformer is connected to the input unit 220 of the distribution power remote monitoring control connection device 200, the distribution power remote monitoring control using a current transformer (CT) installed in the input unit 220. The amount of current input to the connection device 200 may be determined. Current transformers are devices that measure the amount of current flowing through a wire by measuring an electromagnetic field flowing around the wire.

An R line, an S line, a T line, and an N line may be used as an input line of the distribution power remote monitoring and control connection device 200. A current transformer CT may be connected to each input line (R line, S line, T line, N line). A display unit may be provided below the current transformer connected to each input line. The display unit may display a value measured by the current transformer of the input current of each line. When the transformer is connected to the customer based on the screening current amount displayed on the display unit, the customer can be connected to the wire with the smallest amount of current and the neutral wire (N) so that the load can be evenly distributed among the three transformers. Based on the control device provided in the current transformer CT, an operation of connecting the consumer to the wire having the least amount of current and the neutral wire N may be performed.

The video current transformer can measure the output current and remotely monitor the leakage. The image current transformer may measure the current output from the current transformer to the customer. In the current transformer, it may be regarded as a short circuit when a sudden peak current occurs. The measured value measured by the image current transformer may be transmitted by the CPU to the server according to a periodic period such as real time or once a day or once a week through the communication unit.

The output current measured by the video current transformer is calculated by the CPU for one day, one week, and six months, and thus, it may be determined that a challenge has occurred only when a different output is generated. The output amount different from the previous one used to determine whether the conduction is a case where the output current of the previously used output current amount is larger than a change of a predetermined threshold (for example, when the output current amount changes more than twice) is a challenge. It can be determined that it occurred. In addition to measuring the output current, the video current transformer also has a remote short-circuit monitoring function that can detect a short circuit when a sudden peak current occurs.

The output unit 240 of the distribution power remote monitoring and control access device 200 may connect the customer load side to supply power to the customer 250.

That is, by comparing the power transmitted from the pole transformer and the power used by the consumer 250, the distribution power remote monitoring control connection device 20 may remotely monitor the load state and the consumer load state of the pole transformer. That is, the distribution power remote monitoring and control connection device 200 may determine whether there is a power leakage due to a single load. Consumer power can be collected using a remote meter installed in each home. The power of the customer read from the remote meter can be sent to the server. The server may compare the amount of current output and the amount of current transmitted from the remote meter to determine whether a leakage current has occurred in the cable and whether a challenge has occurred. The metered consumer's power may be transmitted to the distribution power remote monitoring control access device 200 to compare the amount of current output from the distribution power remote monitoring control access device with the amount of current transmitted from the remote meter reading device. The metered consumer's power may be sent directly to the power management system.

The distribution power remote supervisory control connection device 200 may include a printed circuit board (PCB) to which a current transformer and a current transformer may be attached, such as a central processor unit (CPU), to calculate the amount of current inside an insulating material enclosure. Can be. In addition, the distribution power remote monitoring and control connection device 200 may include an integrated terminal block that can connect the output line power line of the column transformer and the customer lead line.

The amount of leakage current measured by the distribution power remote monitoring and control access device 200 may be transmitted to the power management system through a wired network or a wireless network. As described above, the amount of current measured at the consumer and the amount of output current may be transmitted to the power management system (server). The power management system may determine whether a power leakage or a challenge has occurred based on the received current amount. If there is a power leakage, it may be necessary to replace the leaked cable or determine whether there is power leakage to the outside so that no additional power leakage occurs at the location where the power leakage occurs. That is, by using the distribution power remote monitoring and control connection device according to an embodiment of the present invention, it is possible to determine the exact power leakage position on the basis of the column transformer, it is possible to perform a quick and accurate action when the power leakage occurs.

In another embodiment, whether a power leakage occurs directly from the distribution power remote monitoring and control connection device 200 provided in the column transformer without directly transmitting a current value measured by the distribution power remote monitoring and control connection device 200 to the power management system. It is also possible to determine whether a power leakage has occurred through the device for determining whether or not to transmit only the result value to the power management system.

In addition, the distribution power remote monitoring and control connection device 200 may measure the amount of power transmitted to the consumer 250 and transmit it to the power management system. In today's power management systems, if the amount of power used is not accurately predicted, power supply and demand may be unbalanced, resulting in large social and economic losses due to the failure to supply power to specific areas. In order to solve this problem, an accurate power estimation method is required. The required power varies according to the time of use of seasonal home appliances and the use of industrial power. In the distribution power remote monitoring and control access device 200 according to an embodiment of the present invention, since the power consumption by time and the power consumption by region can be accurately determined, the statistical power can be used to calculate a specific and accurate power prediction value.

The current consumption measured in real time in the video current transformer provided in the distribution power remote monitoring and control connection device 200 may be transmitted to the power management system. The database provided in the power management system has current measurement information measured for each column transformer. Can be stored. In power management systems, the stored current usage can be used as statistical data to predict specific current usage.

In addition, the distribution power remote monitoring control connection device 200 may include a temperature sensor (hereinafter referred to as a temperature sensor) for detecting the degradation of the cable. The distribution power remote monitoring control access device 200 according to an embodiment of the present invention may be provided with a temperature sensor to determine whether the distribution power remote monitoring control access device 200 is deteriorated.

The temperature sensor may be implemented as a capacitively coupled sensor. The temperature sensor may be selectively detachably attached to the steel enclosure of the column transformer. The temperature sensor attached to the transformer may measure the insulation deterioration state of the column transformer by measuring the transient ground voltage of the high frequency due to the surface effect of the high frequency induced by the partial discharge generated inside the column transformer.

The distribution power remote monitoring and control access device 200 may measure whether the columnar transformer is overloaded and the current degree of deterioration of the columnar transformer based on the results sensed by the temperature sensor. For example, when the sensed result of the temperature sensor is out of the normal value, it may be determined that the column transformer is operating beyond the normal operating range because the current transformer is overloaded. In this case, the power management system can reduce the amount of power transmitted to the corresponding pole transformer so as to prevent the pole transformer from being overloaded.

In addition, the results sensed by the temperature sensor may be transmitted to the database of the power management system. If the value sensed by the temperature sensor is out of the normal range, it can be determined that the deterioration has occurred due to the overload of the column transformer. The more the number of sensed values goes outside the normal range, the more deterioration of the columnar transformer can be determined. Thus, a pole transformer with many sensed values outside the normal range can be replaced before a pole transformer operating in a relatively normal range. By using this method, it is possible to miss the replacement timing of the column transformer and to prevent the loss of the column transformer. Specific operation of the sensor may be as follows.

The value sensed by the temperature sensor is an analog value. In order to determine whether the columnar transformer is overloaded based on the value obtained from the temperature sensor, the sensing value may be changed to a digital value by performing analog / digital (A / D) conversion on the sensed analog value. The sensing values converted into digital values are compared with a predetermined reference value for determining whether the column transformer is in normal operation, and thus the load generated on the column transformer may be measured.

The values measured by the sensor can be directly analyzed by the load variation analysis unit for analyzing the load variation trend provided in the column transformer to detect whether an overload has occurred. Alternatively, the sensing value measured using the sensor is transmitted to the power management system through the wired / wireless network instead of being directly analyzed by the load variation analysis unit, thereby controlling the column transformer based on the sensing values in the power management system.

3 is a conceptual diagram illustrating a data transmission method generated in a distribution power remote monitoring and control access device according to an embodiment of the present invention.

Referring to FIG. 3, a method of transmitting information generated by the plurality of distribution power remote monitoring control access devices 320-1 to 320-8 to a power management system is illustrated.

The plurality of distributed power remote supervisory control access devices may transmit and receive control information to and from the power management system using a wireless local area network such as Institute of Electrical and Electronics Engineers (IEEE) 802.11.

IEEE 802.11ah may perform communication between a station (STA) and an access point (AP) using a frequency bandwidth of 1 GHz or less. IEEE 802.11ah can support about 8000 stations (STAs) with a radio range of about 1 km.

The distribution power remote monitoring and control access devices 320-1 to 320-8 according to an embodiment of the present invention may use WLAN-based networking based on 802.11ah. In the WLAN-based networking, the distribution power remote monitoring control access devices 320-1 to 320-8 of the columnar transformer included in a predetermined range may perform data transmission / reception based on the WLAN with the AP 300. The distribution power remote monitoring and control devices 320-1 to 320-8 have a single load occurring at the current pole transformers at a predetermined period, and whether leakage power is generated. Information on whether to deviate may be transmitted to the AP (300).

The distribution power remote monitoring control access devices 320-1 to 320-8 included in the data transmission and reception ranges of the AP 300 have a constant index number and have different periods to access the AP 300 to connect the AP 300 to the column transformer. It can transmit columnar transformer status information such as unload and overload information. For example, when eight distribution power remote monitoring control access devices 320-1 to 320-8 exist in the service range of one AP 300, the distribution power remote monitoring control access devices 320-1 to 320-are included. 8) the plurality of distribution power remote monitoring and control access devices 320-1 to 320-8 connect to the AP 300 by setting different periods of attempting combining with the AP 300 by dividing them into four groups, two by two. The collision can be prevented.

The video current transformer provided in the distribution power remote monitoring and control device periodically monitors the output current amount of the R line, the output current amount of the S line, and the output current amount of the T line measured by the image current transformer to the AP based on the period information transmitted by the power management system. You can decide whether to send it in real time or in real time.

The combined attempt period information of the distribution power remote monitoring control access devices 320-1 to 320-8 and the AP 300 may be transmitted from the power management system 350 to the column transformer through the AP 300.

In addition, the AP 300 may transmit a control command to the distribution power remote monitoring control access devices 320-1 to 320-8 for each column transformer transmitted from the power management system 350. For example, the power management system 350 may receive a value from the first distribution power remote monitoring and control access device 320-1 through the AP 300 that senses that an overload has occurred in the columnar transformer. The power management system 350 may not only reduce the power transmitted to the column transformer having the first distribution power remote monitoring and control connection device 320-1 based on the sensed value, but also reduce the power of the AP 300. It can also be ordered to temporarily cut off the power transmitted to the distribution power remote supervisory control access device. The distribution power remote monitoring control access devices 320-1 to 320-8 may block power for a short time when a power cut command is received, thereby preventing the power loss from being lost due to overload of the pole transformer.

In the embodiment of the present invention, for convenience of description, it is assumed that the AP 300 is used to collect information of the pole transformer, but the distribution power remote monitoring and controlling device 320-1 to 320- using a networking method other than WLAN. It is also possible for the information collected from 8) to be transmitted to the power management system 350 and such embodiments are also within the scope of the present invention.

In addition, in the embodiment of the present invention, it is assumed that the distribution power remote monitoring and control connection device of the column transformer determines whether or not the power leakage to transmit to the power management system. However, the current value of the customer may be transmitted to the power management system through the first AP, and the current value of the distribution power remote monitoring control access device may be transmitted to the power management system through the second AP and compared in the power remote monitoring system. Do.

4 is a block diagram showing a distribution power remote monitoring and control connection device according to an embodiment of the present invention.

Referring to FIG. 4, the apparatus for remotely controlling power distribution monitoring may include a current transformer (not shown), an image current transformer 400, a display unit (not shown), a sensor unit 420, and a communication unit 440.

FIG. 4 is a functional classification of a distribution power remote monitoring and control device for convenience of description, and one component may be implemented by being divided into a plurality of components, and the plurality of components may be integrated into one component and implemented.

In the current transformer (not shown), the input current of the R line, the input current of the S line, and the input current of the T line can be measured by the current transformer.

The display unit (not shown) may display the current measured by the current transformer (not shown) through an image output device such as a display.

The image current transformer 400 may be implemented to calculate the leakage power by measuring the current output to the customer. As described above, the image current transformer 400 may measure an input pole current transformer secondary current and a primary current output to a consumer from a distribution power remote monitoring control connection device. In addition, the current measuring unit may measure the amount of leakage current using the image current transformer (ZCT). Information about the amount of current measured by the current measuring unit may be transmitted to the power management system through the communication unit 440.

The image current transformer 400 may measure the output current amount of the R line, the output current amount of the S line, and the output current amount of the T line.

The distribution power remote monitoring and control connection device is additionally provided with a connection control device to connect the neutral wire (N) to a line having the smallest current amount among the measured R current, S current, and T current. In order to connect the line having the smallest current amount among the current amount of the R line, the current amount of the S line, and the current amount of the T line with the neutral line N, a connection control device may be additionally provided in the distribution power remote monitoring control connection device. By using this method, the load on each line can be balanced.

As described above, the image current transformer may be used for current measurement and short circuit remote monitoring, and the measurement measured by the image current transformer may be transmitted in real time or periodically through the communication unit.

The sensor unit 420 may be implemented to calculate whether the columnar transformer is overloaded. The sensor unit 420 may include a temperature sensor for detecting a deterioration of a cable of the distribution power remote monitoring control connection device. The value sensed by the sensor unit 420 may be transmitted to the power management system through the communication unit. The power management system may determine whether the column transformer is overloaded based on the sensed value. The sensor unit 420 may transmit the sensed value to the image current transformer and transmit the sensed value to the power power management system using the communication unit 440 of the image current transformer.

The communication unit 440 may be used to transmit the values measured by the current measuring unit 400 and the sensor unit 420 to the power management system. The communication unit 440 may be variously implemented according to a method for networking. For example, it may have a different configuration depending on whether the wireless LAN communicates with the power management system or the cellular network.

In addition, the distribution power remote monitoring and control device is provided with a processor may be stored in real time, once a day, once a week through the communication unit 440 measured by the video current transformer. In addition, the processor may determine when a short circuit or a challenge occurs in itself. For example, when a sudden peak occurs in the output current, it may be determined to be a short circuit, and when the output current is a constant multiple such as 2 times, it may be determined that a challenge occurs and transmitted to the power management system through the communication unit.

Such a configuration does not directly determine whether a single load or overload occurs in the distribution power remote supervisory control access device, but uses a method of transmitting related information to the communication unit 440 to determine the single load and overload in the power management system. It is assumed. In order to determine whether the single load or overload is directly determined by the distribution power remote monitoring and control access device, the single load determiner and the overload determiner may be additionally provided.

5 is a flowchart illustrating a power control method of a distribution power remote monitoring and controlling device according to an embodiment of the present invention.

5, the leakage current is measured (step S500).

In the distribution power remote supervisory control connection device, it is possible to measure whether leakage current has occurred based on the current output from the column transformer, the current transmitted to the customer, and the amount of current received at the customer. Image current transformers can be used to measure leakage currents.

It is measured whether the columnar transformer is overloaded (step S510).

On the basis of the sensor provided in the distribution power remote monitoring and control connection device, it is possible to determine whether or not an overload occurs in the columnar transformer. Sensors can measure the overload of a pole transformer based on an element attached to the cable that can measure whether it is overloaded, such as heat from a pole transformer.

The measured information is transmitted (step S520).

The distribution power remote supervisory control access device may transmit measured current information and sensing information to the power management system. The transmission of the measured current information and the sensing information may be performed periodically or only when leakage power or overload occurs.

The power management system may control the column transformer based on the received current information and the sensing information. The power management system may control the power management system through a communication network. For example, in the event of an overload of a pole transformer, the pole transformer is sent by sending a control command to carry out a mechanism to prevent over-operation, or by controlling the amount of power transferred from the power management system to the pole transformer. Can get out of overload condition.

6 is a flowchart illustrating a power control method of a power distribution remote monitoring and controlling device according to an embodiment of the present invention.

Referring to FIG. 6, the output current amount of the R line, the output current amount of the S line, and the output current amount of the T line may be measured based on an image current transformer connected to the R line, the S line, and the T line, respectively (step S600).

As described above, the input line of the distribution power remote monitoring apparatus may be an R line, an S line, or a T line, and the current transformer may measure the current output to the customer in each phase.

The video current transformer transmits the output current amount of the R line, the output current amount of the S line, and the output current amount of the T line to the power management system (step S610).

The video current transformer may transmit the measured current value of each phase to the power management system through the communication unit. In the power management system, the cable leakage current and / or the conduction can be determined based on the sum of the output current of the R line, the output current of the S line, and the output current of the T line, and the use current of the customer transmitted from the installed remote meter of the customer. Can be. For example, two current amounts may be compared to determine that leakage and / or conduction have occurred when the current exceeds a certain threshold considering natural loss.

While the present invention has been described in detail with reference to the exemplary embodiments, it is to be understood that the present invention is not limited thereto and that the present invention is not limited thereto. It is evident that it can be modified or improved. That is, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined in the following claims.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

200: distribution power remote monitoring and control connecting device
220: input unit
240: Output section
400: video current transformer
420: sensor unit
440: communication unit

Claims (14)

In the distribution power remote monitoring and control method,
Measuring an output current amount of an R line, an output current amount of an S line, and an output current amount of a T line based on an image current transformer connected to an R line, an S line, and a T line, respectively;
Determining whether a short circuit or a conduction has occurred based on an output current amount of the R line, an output current amount of the S line, and an output current amount of the T line;
Measuring an input current amount of the R line, an input current amount of the S line, and an input current amount of the T line in a current transformer; And
And displaying the input current amount of the R line, the input current amount of the S line, and the input current amount of the T line measured by the current transformer. The method of claim 1,
And transmitting the output current amount of the R line, the output current amount of the S line, and the output current amount of the T line to the power management system in the image current transformer. The method of claim 2,
The power management system determines whether the leakage current of the cable is generated and whether the electric conductivity is generated based on the sum of the output current amount of the R line, the output current amount of the S line and the output current amount of the T line, and the use current amount of the customer transmitted from the installed remote meter of the customer. Remote monitoring and control method of distribution power to judge. The method of claim 2, wherein in the image current transformer, transmitting the output current amount of the R line, the output current amount of the S line, and the output current amount of the T line to a power management system.
Transmitting the output current amount of the R line, the output current amount of the S line, and the output current amount of the T line to an access point (AP) in real time or periodically using a wireless LAN in the image current transformer,
The AP transmits an output current amount of the R line, an output current amount of the S line, and an output current amount of the T line to the power management system.
The video current transformer periodically transmits or outputs the output current amount of the R line, the output current amount of the S line, and the output current amount of the T line to the AP based on information transmitted by the power management system in real time. Remote monitoring and control method of distribution power to determine whether or not. delete The method of claim 1,
A method for remote monitoring and controlling distribution power, further comprising detecting degradation of a cable transmitting power in a column transformer based on a temperature sensor. In the distribution power remote monitoring and control method,
Measuring an output current amount of an R line, an output current amount of an S line, and an output current amount of a T line based on an image current transformer connected to an R line, an S line, and a T line, respectively;
Determining whether a short circuit or a conduction has occurred based on an output current amount of the R line, an output current amount of the S line, and an output current amount of the T line;
The step of determining whether a short circuit or a conduction has occurred based on the output current amount of the R line, the output current amount of the S line, and the output current amount of the T line,
Determining that a short circuit occurs when a peak occurs in an output current based on an output current amount of the R line, an output current amount of the S line, and an output current amount of the T line; And
And determining that conduction occurs when the output current is greater than a change of a predetermined threshold based on the output current amount of the R line, the output current amount of the S line, and the output current amount of the T line. . A distribution power remote monitoring and control connection device, wherein the distribution power remote monitoring and control connection device includes a video current transformer and a processor.
The image current transformer measures an output current amount of an R line, an output current amount of an S line, and an output current amount of a T line based on an image current transformer connected to an R line, an S line, and a T line, respectively.
The processor may be configured to determine whether a short circuit or a conduction occurs based on an output current amount of the R line, an output current amount of the S line, and an output current amount of the T line.
The distribution power remote monitoring control connection device includes a current transformer and a display unit,
The current transformer is implemented to measure the input current amount of the R line, the input current amount of the S line, the input current amount of the T line in the current transformer,
And the display unit is configured to display the input current amount of the R line, the input current amount of the S line, and the input current amount of the T line measured by the current transformer. According to claim 8, The distribution power remote monitoring and control device further comprises a communication unit,
And the communication unit is configured to transmit the output current amount of the R line, the output current amount of the S line, and the output current amount of the T line in the image current transformer to a power management system. 10. The method of claim 9,
The power management system determines whether the leakage current of the cable is generated and whether the electric conductivity is generated based on the sum of the output current amount of the R line, the output current amount of the S line and the output current amount of the T line, and the use current amount of the customer transmitted from the installed remote meter of the customer. Distribution power remote monitoring control connecting device to judge. 10. The method of claim 9,
The communication unit is implemented to transmit the output current amount of the R line, the output current amount of the S line, the output current amount of the T line to the AP (access point) in real time or periodically in the video current transformer,
The AP transmits an output current amount of the R line, an output current amount of the S line, and an output current amount of the T line to the power management system, and the image current transformer transmits the information from the image current transformer to the AP by information transmitted by the power management system. The distribution power remote monitoring and control device for determining whether to transmit the output current amount of the R line, the output current amount of the S line, the output current amount of the T line periodically or in real time. delete According to claim 8, The power distribution remote monitoring control connection device further comprises a sensor unit,
And the sensor unit is configured to detect deterioration of a cable transmitting power from a column transformer based on a temperature sensor. A distribution power remote monitoring and control connection device, wherein the distribution power remote monitoring and control connection device includes a video current transformer and a processor.
The image current transformer measures an output current amount of an R line, an output current amount of an S line, and an output current amount of a T line based on an image current transformer connected to an R line, an S line, and a T line, respectively.
The processor may be configured to determine whether a short circuit or a conduction occurs based on an output current amount of the R line, an output current amount of the S line, and an output current amount of the T line.
The processor
Based on the output current amount of the R line, the output current amount of the S line, the output current amount of the T line, it is determined that a short circuit occurs when a peak occurs in the output current, the output current amount of the R line, the output current amount of the S line, the T The distribution power remote monitoring and control connection device is implemented to determine that a challenge occurs when the output current is greater than a change in the predetermined threshold based on the output current amount of the line.

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