KR20150026243A - Apparatus and method for controlling distribution voltage using amr(automatic meter reading) data - Google Patents

Abstract

Provided are an apparatus and a method to control a distribution voltage using automatic meter reading data in order to control the transmission voltage of a substation based on the voltage of a customer. The provided distribution voltage controlling apparatus using automatic meter reading data includes: a communication unit which receives automatic meter reading data and customer information from a management server; a correction value calculating unit which obtains AVR correction data from the automatic meter reading data and the customer information transmitted from the communication unit and calculates an AVR correction value based on the obtained AVR correction data; a measurement value calculating unit which calculates an AMR measurement value based on the automatic meter reading data transmitted from the communication unit; a determination unit which determines whether an OLTC ascends or descends based on the AVR correction value calculated from the correction value calculating unit and an AMR measurement value calculated in the measurement value calculating unit; and an output unit which generates an OLTC control signal based on the determination result of the determination unit and outputs the generated OLTC control signal to the OLTC.

Description

TECHNICAL FIELD [0001] The present invention relates to an apparatus and method for controlling distribution voltage using remote meter reading data,

The present invention relates to a distribution voltage control apparatus and method using remote meter reading data, and more particularly, to a distribution voltage control apparatus and method using remote meter reading data for controlling a transmission voltage to a distribution line to supply high quality power to a customer It is about.

The power system supplies electricity generated by the power plant to the customer through the transmission system and the distribution system. That is, as shown in FIG. 1, electric power produced by the power generation plant 10 is transported to the substation 30 through the transmission line 20. And is transported to the power distribution system 40 through the voltage elevation of the electric power at the substation 30. In the power distribution system, power is supplied to the high-pressure receptacle 50 and the low-pressure receptacle 60.

Another role of the substation is to maintain the constant voltage to supply high quality power. In particular, the distribution system delivers constant voltage to the customer through a transformer and ancillary equipment at a 154kV substation.

Recently, due to the spread of high precision equipment, social interest and importance about the quality of the supply voltage have been raised, and efforts have been made to supply the electric power of the rated voltage to the customer.

Voltage fluctuations caused by load fluctuation, inrush current, accident, system change, etc. cause decrease in the torque of the induction motor, increase in load current, etc., resulting in deterioration of the life of the electric device and power loss. For example, if the load increases under normal conditions, the voltage drop due to the impedance of the line and transformer becomes large, resulting in undervoltage. If the load is small, the feed-back voltage becomes rather large due to the ferritic phenomenon in the underground cable line and the long- Overvoltage occurs.

In the power system, in order to cope with the voltage fluctuation depending on the load, the supply voltage to the distribution line is adjusted and the operation is performed by varying the holding voltage according to the load. In the transmission voltage operation method to the distribution line, the automatic voltage adjustment is performed by operating the OLTC (On Load Tap Changer) installed on the primary side of the 154 kV transformer. 2, the OLTC adjustment is performed by an AVR (Automatic Voltage Regulator) 80 and a DVM 90 (Digital Volt Meter) that receive a voltage signal of a PT (Potential Transformer) ) Are connected in parallel. When the voltage adjustment is necessary by receiving both the AVR 80 and the DVM 90 voltage signal of the bus PT secondary side 70, a signal is sent to the OLTC to adjust the voltage. The DVM 90 transmits a signal within a short time only when the voltage is only a simple voltage signal and moves outside the set value. The AVR 80 receives the current signal through the main transformer secondary CT 75 as well as the voltage, The voltage drop (Ur) and the inductive voltage drop (Ux) are calculated and used to control the voltage delivered to the distribution line.

The AVR adopts a line drop compensator (LCD) method in which the voltage drop due to the load fluctuation is compensated based on the load center point of the power distribution line. However, there is a problem that the AVR can not respond quickly to the load fluctuation. I am installing and operating.

DVM sets the upper and lower limit values of the supply voltage maintenance reference to the distribution line, and when it goes out of the maintenance reference range, it sends an operation signal to the OLTC and transmits the signal to the OLTC so as to quickly adjust the voltage. In addition, in the 154 kV substation, the 23 kV capacitor bank is operated to adjust the voltage of the power distribution system when the load fluctuates.

As mentioned above, the AVR used for controlling the transmission voltage to the distribution line operates at a proper speed and the bandwidth is set to prevent the frequent operation of the OLTC. In addition, although the data and procedures necessary for AVR correction are well known in the substation operation standard, it is difficult to acquire the data (especially, the center point of load is difficult to select) It is not used in the field at present.

The constant-voltage transmission system that keeps the voltage of the power receiver at a constant level is adopted, but the reference of the distribution voltage is operated on the basis of the voltage of the 23 kV bus line of the substation (bus line PT). This allows the worker of the substation to adjust the voltage without knowing the voltage of the faucet customer.

In addition, the transmission voltage is managed by disregarding the characteristics of the distribution line and the load characteristic, which are changing from time to time, such as a cease-fire operation and an ancillary equipment operation, and consequently, the constant voltage may not be supplied to the faucet customer.

In the field of power distribution, customer's voltage is sampled once a year to determine suitability, and if necessary, Tap (NLTC, No Load Tap Changer) of the distribution transformer is adjusted to prevent high voltage and low voltage.

However, in the prior art, since the voltage adjustment is performed according to the sampling measurement once a year, low-quality power is supplied for a certain period.

Prior Art: Korean Patent No. 10-1232556 (name: automatic voltage regulator using SCADA and method thereof)

SUMMARY OF THE INVENTION It is an object of the present invention to provide an apparatus and method for controlling distribution voltage using remote meter reading data in which a delivery voltage of a substation is controlled on the basis of a voltage of a customer.

According to an aspect of the present invention, there is provided an apparatus for controlling distribution voltage using remote meter reading data, comprising: a communication unit for receiving remote meter reading data and customer information from a management server; A correction value calculation unit for obtaining AVR correction data from the customer information and the remote meter reading data transmitted from the communication unit and calculating an AVR correction value based on the acquired AVR correction data; A measurement value calculation unit for calculating an AMR measurement value based on the remote meter reading data transmitted from the communication unit; A determining unit for determining whether the OLTC is up or down based on the AVR correction value calculated by the correction value calculating unit and the AMR measurement value calculated by the measured value calculating unit; And an output unit for generating an OLTC control signal based on the determination result of the determination unit and outputting it to the OLTC.

The communication unit receives from the management server the remote meter reading data including the voltage, the current, the validity, the reactive power and the power factor, and the customer information including the line impedance, the turner, the supply bank and the load center point.

The correction value calculation unit obtains AVR correction data including line impedance, a rotation axis, a supply bank, and a load center point based on the remote meter reading data of the load center contained in the customer information, Delay time, resistive voltage drop, inductive voltage drop, and bandwidth.

The measured value calculation unit calculates an AMR measurement value including a power factor, a phase angle, and a voltage drop based on the remote meter reading data.

If the AMR measurement value is equal to or greater than the AVR correction value, the determination section determines that the OLTC is falling. If the AMR measurement value is less than the AVR correction value, the determination section determines that the OLTC increase is present.

The output unit outputs the OLTC rising signal to the OLTC when it is determined that the OLTC is rising in the determination unit, and outputs the OLTC falling signal to the OLTC when the determination unit determines that the OLTC is falling.

In order to achieve the above-mentioned object, a distribution voltage control method using remote meter reading data according to an embodiment of the present invention is characterized in that the correction value calculation unit obtains AVR correction data from the customer information and remote meter reading data transmitted from the management server step; Calculating an AVR correction value based on the acquired AVR correction data by the correction value calculation unit; Calculating an AMR measurement value based on the remote meter reading data transmitted from the management server by the measurement value calculation unit; Determining whether the OLTC is up or down based on the AMR measurement value calculated in the step of calculating the AVR correction value and the measurement value calculated in the step of calculating the correction value by the determination unit; And outputting the OLTC control signal to the OLTC based on the determination result of the determination unit by the output unit.

Receiving the remote meter reading data including the voltage, the current, the validity, the reactive power and the power factor, and the customer information including the line impedance, the turner, the supply bank, and the load center point from the management server by the communication unit.

In the step of acquiring the AVR correction data, the correction value calculating unit acquires AVR correction data including line impedance, rotation, supply bank and load center point based on the remote meter reading data of the load center point included in the customer information .

In the step of calculating the correction value, the correction value calculating unit calculates the AVR correction value including the reference voltage, the delay time, the resistive voltage drop, the inductive voltage drop and the bandwidth using the acquired AVR correction data.

In the step of calculating the measured value, the measured value calculating unit calculates the AMR measured value including the power factor, the phase angle and the voltage drop based on the remote meter reading data.

In the step of determining whether or not the OLTC is to be ascended or descended, the determination unit determines that the OLTC falls when the measured AMR value is equal to or greater than the AVR correction value, and determines that the OLTC increases when the measured AMR value is less than the AVR correction value.

In the outputting step, the output unit outputs an OLTC rising signal to the OLTC when it is judged by the judging unit that the OLTC is rising, and outputs the OLTC falling signal to the OLTC when it is judged that the OLTC is falling by the judging unit.

According to the present invention, a distribution voltage control apparatus and method using remote meter reading data can control the delivery voltage of a substation on the basis of the voltage of a customer, thereby maintaining a distribution voltage at an optimum state, There is an effect that can supply.

In addition, the present invention can provide a high-quality constant voltage by operating the reference voltage based on the current voltage of the customer, thereby enabling real-time acquisition of not only the voltage of the customer but also various kinds of information in real time, It is possible to reduce the load through the optimum voltage control by judging the situation.

Also, the distribution voltage control apparatus and method using the remote meter reading data can control the transmission voltage of the substation by using the remote meter reading data, so that it is not necessary to install AVR and DVM for transmission voltage control, As shown in Fig.

In addition, the distribution voltage control apparatus and method using the remote meter reading data can control the transmission voltage of the substation by using the remote meter reading data, thereby minimizing the voltage fluctuation of the power supplied to the customer, Reduction in service life of the electric device, power loss, occurrence of power failure, etc.) can be prevented.

In addition, the distribution voltage control apparatus and method using the remote meter reading data can control real-time compensation under any condition of the distribution system by controlling the transmission voltage of the substation using the remote meter reading data, thereby unnecessary waste of manpower In particular, there is an effect that it is possible to automate the line voltage check once a year at the distribution center and monitor the voltage situation of the real time customer.

In addition, the distribution voltage control apparatus and method using the remote meter reading data can control the OLTC by a software by utilizing the remote meter reading data of the customer, and by using a hardware device such as AVR and DVM, It is possible to reduce the wasteful factor to be installed in the future when the transformer is added, and thus it is possible to economically control the delivery voltage to the distribution line.

In addition, the distribution voltage control apparatus and method using the remote meter reading data can be controlled in real time by optimizing the voltage in real time, such as changing the operation condition of various distribution systems such as distributed power supply installation and armistice work, The life of the main transformer can be increased through optimum operation.

Also, the distribution voltage control apparatus and method using the remote meter reading data can automatically operate the ancillary equipment, particularly the parallel capacitor bank, by utilizing the information obtained from the remote meter reading data, thereby minimizing the power loss with the reactive power optimum control.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 and FIG. 2 are diagrams for explaining a delivery voltage control method for a conventional distribution line. FIG.
3 and 4 are diagrams for explaining a distribution voltage control apparatus using remote meter reading data according to an embodiment of the present invention.
5 is a flowchart illustrating a distribution voltage control method using remote meter reading data according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings in order to facilitate a person skilled in the art to easily carry out the technical idea of the present invention. . In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

Hereinafter, a distribution voltage control apparatus using remote meter reading data according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. 3 and 4 are views for explaining a distribution voltage control apparatus using remote meter reading data according to an embodiment of the present invention.

3, a system including a distribution voltage control apparatus 700 (hereinafter referred to as a distribution voltage control apparatus) using remote meter reading data includes a high voltage AMR 120, a low voltage AMR 140, a data concentration apparatus A scouting server 500 and an OLTC 800. The OLT 800 includes a remote control unit 600 and a remote control unit 700. The remote control unit 600 includes a remote control unit 600,

The high pressure AMR 120 transmits the remote meter reading data of a high pressure customer such as a factory, a building, etc. to the management server 400 via the CMDA network. At this time, the high-pressure AMR 120 measures the remote meter reading data including the customer's voltage, current, validity, reactive power, power factor, and the like, and transmits it to the management server 400.

The low pressure AMR 140 transmits the remote meter reading data of a low pressure consumer such as a house to the data concentrator 300 connected by a power line communication (PLC). At this time, the low-pressure AMR 140 measures the remote meter reading data including the voltage, current, effective, reactive power, and power factor of the customer and transmits the data to the data concentrator 300.

The data concentrator 300 transmits the remote meter reading data received from the low pressure AMR 140 to the management server.

The management server 400 collects the remote meter reading data from the plurality of high voltage AMRs 120 and the plurality of data concentrators 300. The management server 400 provides the customer (that is, the customer) with the information such as the fee and the usage amount based on the collected remote meter reading data.

The management server 400 collects the customer information into the scada server 500. That is, the management server 400 requests the scada server 500 to transmit the customer information. The management server 400 receives the customer information including the line impedance, the turner, the supply bank, the load center point, etc. from the scada server 500.

The management server 400 transmits the remote meter reading data and the customer information to the remote slave device 600. That is, the management server 400 transmits the remote meter reading data collected through the plurality of high-pressure AMRs 120 and the plurality of data concentrators 300 to the remote slave device 600. The management server 400 transmits the customer information received from the scada server 500 to the remote slave device 600.

The scada server 500 transmits the customer information to the management server 400 at the request of the management server 400. [ That is, the scada server 500 detects and transmits to the management server 400 the customer information including the line impedance, the turner, the supply bank, the load center point, and the like.

The remote slave device 600 transmits the remote meter reading data and the customer information input from the management server 400 to the voltage doubler control device.

The distribution voltage control apparatus 700 is configured in module or software form in the remote substation 600 to control the transmission voltage to the distribution line based on the remote meter reading data and the customer information received from the remote substation 600 And outputs the OLTC 800 control signal.

The distribution voltage control apparatus 700 outputs a control signal of the OLTC 800 using a line drop compensator (LDC) scheme. That is, the distribution voltage control device 700 acquires the AVR correction data using the remote meter reading data (i.e., active power, reactive power, power factor, voltage, current, etc.) of the load center included in the customer information. At this time, the distribution voltage control device 700 acquires AVR correction data including line impedance, rotation, supply bank, load center point, and the like. The AVR correction data acquired by the distribution voltage control device 700 is shown in Table 1 below.

The distribution voltage control device 700 calculates the AVR correction value based on the AVR correction data. That is, the distribution voltage control device 700 includes reference voltage, delay time, resistive voltage drop, inductive voltage drop, bandwidth, and the like using AVR correction data including line impedance, turner, supply bank, load center point, Lt; RTI ID = 0.0 > AVR < / RTI >

The distribution voltage control device 700 calculates the AMR measurement value based on the remote meter reading data. That is, the distribution voltage control apparatus 700 calculates an AMR measurement value including a power factor, a phase angle, and a voltage drop by using AMR measurement values including voltage, current, validity, reactive power and power factor.

The distribution voltage control device 700 compares the AVR correction value with the AMR measurement value to determine whether the OLTC 800 is ascending or descending. That is, when the AMR measurement value is equal to or greater than the AVR correction value, the distribution voltage control apparatus 700 determines that the OLTC 800 has descended. If the AMR measurement value is less than the AVR correction value,

The distribution voltage control apparatus 700 generates a control signal for the OLTC 800 based on the determination result of the rising and falling of the OLTC 800 and outputs the control signal to the OLTC 800. [ That is, the distribution voltage control apparatus 700 outputs a down signal of the OLTC 800 to the OLTC 800 when the OLTC 800 falls. The distribution voltage control device 700 outputs a rising signal of the OLTC 800 to the OLTC 800 in case of the rise of the OLTC 800. [ Here, the distribution voltage control apparatus 700 outputs a control signal of the OLTC 800 using a Z-component scheme which sets and compensates for the voltage drop rate based on the lower stage voltage, irrespective of the line impedance and the line voltage It is possible.

4, the distribution voltage control apparatus 700 includes a communication unit 710, a correction value calculation unit 730, a measured value calculation unit 750, a determination unit 770, an output unit 790 ).

The communication unit 710 receives the remote meter reading data and the customer information from the management server 400. That is, the communication unit 710 receives the remote meter reading data including the voltage, the current, the validity, the reactive power, and the power factor from the management server 400. The communication unit 710 receives the customer information including the line impedance, the turner, the supply bank, and the load center point from the management server 400. Here, the communication unit 710 may receive the remote meter reading data from the management server 400 and receive the customer information from the scada server 500. [ The communication unit 710 transmits the received remote meter reading data and the customer information to the correction value calculating unit 730 and the measured value calculating unit 750.

The correction value calculation unit 730 calculates an AVR correction value based on the AVR correction data received from the communication unit 710. [ That is, the correction value calculating unit 730 acquires the AVR correction data using the remote meter reading data (i.e., active power, reactive power, power factor, voltage, current, etc.) of the load center included in the customer information. At this time, the correction value calculating unit 730 acquires AVR correction data including line impedance, turner, supply bank, load center point, and the like. The correction value calculator 730 calculates the AVR correction value including the reference voltage, the delay time, the resistive voltage drop, the inductive voltage drop, the bandwidth, and the like using the acquired AVR correction data. The correction value calculation unit 730 transmits the calculated AVR correction value to the determination unit 770. Here, the correction value calculating unit 730 calculates a resistive voltage drop and a fluidic voltage drop using the following equation (1).

Here, ln is the rated current (A) of the Tap using LDC, Uct is the CT Ratio (CT Ratio input to the AVR), Upt is the PT Ratio (PT Ratio input to the AVR), r is the resistive line resistance per phase (Km / s), where x is the inductive line resistance per phase (Ω / km), L is the positive (km) to the load center point and K is the rated current, calculated as the transformer rated current / do.

For example, ACR correction data is 5A for rated current of Tap using LDC, 400 for CT Ratio, 208 for PT Ratio, 0.359Ω / km for resistive line resistance per phase, 0.573 Ω / km for inductive line resistance per phase, When the positive current until the center is 1 km, the rated current of the transformer is 235, and the rated current of CT is 600, the correction value calculator 730 calculates the resistive voltage drop Ur as shown in the following equation (2) The voltage drop (Ux) is calculated according to the following equation (3).

The measurement value calculation unit 750 calculates the AMR measurement value based on the remote meter reading data received from the communication unit 710. [ That is, the measured value calculating unit 750 calculates an AMR measurement value including a power factor, a phase angle, and a voltage drop by using AMR measurement values including voltage, current, validity, reactive power and power factor. The measurement value calculation unit 750 transmits the calculated AMR measurement value to the determination unit 770. [

The determination unit 770 compares the AVR correction value with the AMR measurement value to determine whether the OLTC 800 is moving up or down. That is, the determining unit 770 determines that the OLTC 800 falls if the AMR measurement value is equal to or greater than the AVR correction value, and determines that the OLTC 800 rises if the AMR measurement value is less than the AVR correction value. The determination unit 770 transmits the up / down determination result of the OLTC 800 to the output unit 790.

The output unit 790 generates a control signal for the OLTC 800 based on the determination result of the rising and falling of the OLTC 800 received from the determination unit 770 and outputs the control signal to the OLTC 800. That is, the output unit 790 outputs a down signal of the OLTC 800 to the OLTC 800 when the OLTC 800 is down. The output unit 790 outputs the rising signal of the OLTC 800 to the OLTC 800 when the OLTC 800 is lifted.

The OLTC 800 controls the transmission voltage of the substation based on the control signal of the OLTC 800 from the distribution voltage control device 700. At this time, when the OLTC 800 receives the OLTC 800 control signal, the OLTC 800 counts the delay time and controls the transmission voltage of the substation.

Hereinafter, a distribution voltage control method using remote meter reading data according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings. 5 is a flowchart illustrating a distribution voltage control method using remote meter reading data according to an embodiment of the present invention.

The distribution voltage control device (700) receives the customer information and the remote meter reading data from the management server (400). At this time, the distribution voltage control device 700 receives the customer information and the remote meter reading data from the management server 400 through the remote control device 600. The distribution voltage control device 700 acquires AVR correction data from the received customer information (S100). That is, the distribution voltage control device 700 acquires the AVR correction data using the remote meter reading data (i.e., active power, reactive power, power factor, voltage, current, etc.) of the load center included in the customer information. At this time, the distribution voltage control device 700 acquires AVR correction data including line impedance, rotation, supply bank, load center point, and the like.

The distribution voltage control device 700 calculates an AVR correction value based on the acquired AVR correction data (S200). That is, the distribution voltage control device 700 includes reference voltage, delay time, resistive voltage drop, inductive voltage drop, bandwidth, and the like using AVR correction data including line impedance, turner, supply bank, load center point, Lt; RTI ID = 0.0 > AVR < / RTI >

The distribution voltage control device 700 calculates an AMR measurement value based on the received remote meter reading data (S100). That is, the distribution voltage control apparatus 700 calculates an AMR measurement value including a power factor, a phase angle, and a voltage drop by using AMR measurement values including voltage, current, validity, reactive power and power factor.

The distribution voltage control apparatus 700 determines whether the OLTC 800 is lifted or lowered based on the calculated AVR correction value and the AMR measurement value (S400). That is, when the AMR measurement value is equal to or greater than the AVR correction value, the distribution voltage control apparatus 700 determines that the OLTC 800 has descended. If the AMR measurement value is less than the AVR correction value,

The distribution voltage control apparatus 700 outputs a control signal of the OLTC 800 according to the determination result of the rising / falling of the OLTC 800 (S500). That is, the distribution voltage control apparatus 700 outputs a down signal of the OLTC 800 to the OLTC 800 when the OLTC 800 falls. The distribution voltage control device 700 outputs a rising signal of the OLTC 800 to the OLTC 800 in case of the rise of the OLTC 800. [

As described above, the distribution voltage control apparatus and method using the remote meter reading data can control the delivery voltage of the substation based on the voltage of the customer, so that the distribution voltage is maintained at the optimal state, and the high- There is an effect that can supply.

In addition, the present invention can provide a high-quality constant voltage by operating the reference voltage based on the current voltage of the customer, thereby enabling real-time acquisition of not only the voltage of the customer but also various kinds of information in real time, It is possible to reduce the load through the optimum voltage control by judging the situation.

Also, the distribution voltage control apparatus and method using the remote meter reading data can control the transmission voltage of the substation by using the remote meter reading data, so that it is not necessary to install AVR and DVM for transmission voltage control, As shown in Fig.

In addition, the distribution voltage control apparatus and method using the remote meter reading data can control the transmission voltage of the substation by using the remote meter reading data, thereby minimizing the voltage fluctuation of the power supplied to the customer, Reduction in service life of the electric device, power loss, occurrence of power failure, etc.) can be prevented.

In addition, the distribution voltage control apparatus and method using the remote meter reading data can control real-time compensation under any condition of the distribution system by controlling the transmission voltage of the substation using the remote meter reading data, thereby unnecessary waste of manpower In particular, there is an effect that it is possible to automate the line voltage check once a year at the distribution center and monitor the voltage situation of the real time customer.

In addition, the distribution voltage control apparatus and method using the remote meter reading data can control the OLTC by a software by utilizing the remote meter reading data of the customer, and by using a hardware device such as AVR and DVM, It is possible to reduce the wasteful factor to be installed in the future when the transformer is added, and thus it is possible to economically control the delivery voltage to the distribution line.

In addition, the distribution voltage control apparatus and method using the remote meter reading data can be controlled in real time by optimizing the voltage in real time, such as changing the operation condition of various distribution systems such as distributed power supply installation and armistice work, The life of the main transformer can be increased through optimum operation.

Also, the distribution voltage control apparatus and method using the remote meter reading data can automatically operate the ancillary equipment, particularly the parallel capacitor bank, by utilizing the information obtained from the remote meter reading data, thereby minimizing the power loss with the reactive power optimum control.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but many variations and modifications may be made without departing from the scope of the present invention. It will be understood that the invention may be practiced.

120: High pressure AMR 140: Low pressure AMR
200: CDMA network 300: data concentrator
400: Management server 500: Scada server
600: remote remote device 700: distribution voltage control device
710: Communication unit 730: Correction value calculation unit
750: Measured value calculating unit 770:
790: Output section 800: OLTC

Claims (13)

A communication unit for receiving the remote meter reading data and the customer information from the management server;
A correction value calculation unit for obtaining AVR correction data from the customer information and remote meter reading data transmitted from the communication unit and calculating an AVR correction value based on the acquired AVR correction data;
A measurement value calculation unit for calculating an AMR measurement value based on the remote meter reading data transmitted from the communication unit;
A determination unit for determining whether the OLTC is up and down based on the AVR correction value calculated by the correction value calculation unit and the AMR measurement value calculated by the measurement value calculation unit; And
And an output unit for generating an OLTC control signal based on a determination result of the determination unit and outputting the generated OLTC control signal to the OLTC. The method according to claim 1,
Wherein,
From the management server, the remote meter reading data including the voltage, the current, the validity, the reactive power and the power factor, and the customer information including the line impedance, the turner, the supply bank and the load center point. Distribution voltage control device. The method according to claim 1,
Wherein the correction value calculation unit
The AVR correction data including the line impedance, the turner, the supply bank, and the load center point are acquired based on the remote meter reading data of the load center included in the customer information, and the reference voltage, the delay time, the resistance Wherein the AVR correction value including the voltage drop, the inductive voltage drop, and the bandwidth is calculated. The method according to claim 1,
Wherein the measured value calculating section calculates,
And calculating an AMR measurement value including a power factor, a phase angle, and a voltage drop based on the remote meter reading data. The method according to claim 1,
Wherein,
Wherein the controller determines that the OLTC is falling if the AMR measurement value is greater than or equal to the AVR correction value, and determines that the OLTC is increased if the AMR measurement value is less than the AVR correction value. The method according to claim 1,
The output unit includes:
Wherein the determination unit outputs an OLTC rising signal to the OLTC when it is determined that the OLTC is rising, and outputs a OLTC falling signal to the OLTC when the determination unit determines that the OLTC is falling. controller. Acquiring AVR correction data from the customer information and the remote meter reading data transmitted from the management server by the correction value calculation unit;
Calculating an AVR correction value based on the acquired AVR correction data by the correction value calculation unit;
Calculating an AMR measurement value based on the remote meter reading data transmitted from the management server by the measurement value calculation unit;
Determining whether the OLTC is up or down based on the AMR measurement value calculated at the step of calculating the AVR correction value and the measurement value calculated at the step of calculating the correction value by the determination unit; And
And outputting an OLTC control signal to the OLTC based on a determination result of the determination unit by the output unit. The method of claim 7,
The method further comprises the step of receiving, from the management server, the remote meter reading data including the voltage, the current, the validity, the reactive power and the power factor, and the customer information including the line impedance, the turner, the supply bank, Wherein the remote control data is used for controlling the distribution voltage. The method of claim 7,
In the step of acquiring the AVR correction data,
Wherein the correction value calculation unit obtains AVR correction data including line impedance, a rotation axis, a supply bank, and a load center point based on the remote meter reading data of the load center point included in the customer information, A method of controlling distribution voltage using. The method of claim 7,
In the step of calculating the correction value,
Wherein the correction value calculating unit calculates the AVR correction value including the reference voltage, the delay time, the resistive voltage drop, the inductive voltage drop and the bandwidth using the acquired AVR correction data Control method of distribution voltage. The method of claim 7,
In the step of calculating the measured value,
Wherein the measured value calculating unit calculates an AMR measured value including a power factor, a phase angle, and a voltage drop based on the remote meter reading data. The method of claim 7,
In the step of determining whether or not the OLTC is up / down,
Wherein the determining unit determines that the OLTC is falling when the AMR measurement value is equal to or greater than the AVR correction value and determines that the OLTC is rising when the AMR measurement value is less than the AVR correction value. Control method. The method of claim 7,
In the outputting step,
Wherein the output unit outputs an OLTC rising signal to the OLTC when the determination unit determines that the OLTC is rising, and outputs a OLTC falling signal to the OLTC when the determination unit determines that the OLTC is falling. Control method of distribution voltage using meter reading data.

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