KR20180134665A - Method for tele-calculating mof ratio error using smartmeter based on advanced metering infrastructure and ami server using the same - Google Patents

Abstract

The present invention relates to a remote calculating method for a metering out fit (MOF) ratio error using an advanced metering infrastructure (AMI)-based smart meter and to an AMI server using the same. According to an embodiment of the present invention, the remote calculating method for an MOF ratio error using an AMI-based smart meter comprises: a step of calculating voltage and current of each phase for a fixed period through calculation information transmitted from a smart meter; a step of calculating the amount of effective power of a three-phase three-wire type and a three-phase four-wire type by each phase after the fixed period; a step of comparing the preset threshold with a difference of the amount of effective power of the calculated three-phase three-wire type and three-phase four-wire type by each phase; and a step of calculating the ratio error of MOF by calculating a calculation error rate of the relevant phase when an abnormal ratio error is determined in the relevant phase from the comparison results. The present invention is able to calculate the ratio error of MOF in real time.

Description

METHOD FOR TELE-CALCULATING MOF RATIO ERROR USING SMARTMETER BASED ON ADVANCED METERING INFRASTRUCTURE AND AMI SERVER USING THE SAME TECHNICAL FIELD The present invention relates to a method for remotely estimating a MOF ratio error using an AMI-

The present invention relates to a method for remotely estimating a MOF error using an AMI-based smart meter and an AMI server using the same, and more particularly, 3, and 3, and when the specific phase is a common reference, the difference of the effective power amount is compared with a preset threshold value to determine occurrence of a deviation error with respect to the phase, A method for remotely estimating a MOF error using an AMI-based smart meter, and an AMI server using the method.

In general, a Metering Out Fit (hereinafter referred to as "MOF") includes a potentiometric transformer (PT) that transforms a certain voltage value into a voltage proportional thereto, (Current Transformer: CT) in a single case. It is used for the purpose of measuring the amount of electric power of the customer by combining with the maximum demand adjustment watt hour meter and the maximum demand watt hour meter.

If the customer's receiver is a transformer with a delta-to-wye (ie, Δ-Y) connection, the ratio error of the MOF can be used to determine whether the MOF is normal. In the field, the MOF ratio error is calculated by comparing the primary (high-pressure side) and secondary (low-pressure side) ratios for each phase through a measuring transformer (CT).

In addition, conventionally, it is possible to determine whether MOF is normal by measuring an N-phase current (neutral current) as a sum of three-phase currents measured by MOF.

The above-described methods have not yet been developed to automatically measure and calculate the MOF bias error remotely, and to calculate an excess / shortage of the electric power due to the error error.

On the other hand, the MOF bias error is measured by the manpower using the equipment for measuring the bias error, and the check cost of several billions of won is consumed annually. In Korea, there is a limit to check all high-voltage customers measuring power using MOF due to labor and cost constraints. However, the annual average MOF error rate is 4.1% of total customers.

In particular, current transformers (CTs) and transformers (PTs), including MOF, are no longer required to comply with the obligation of validity periods as they are excluded from statutory meters. These metering facilities are on the rise due to aging and aging. This requires high power supply reliability, which can be a social problem due to increased power outage time due to MOF failure, and can be a factor that hinders fair power trading, which is the original purpose of MOF.

In addition, conventionally, it is difficult to measure the MOF ratio error in real time. There is always a case where there is a manufacturing defect before installation of the MOF, or there is always a case where a fault occurs due to a shock phenomenon such as an external surge or a burst after the installation, so that the change ratio can not be precisely modified. Therefore, there is a need for a method for measuring the MOF error in real time.

In addition, the MOF error measurement is rarely done for the weighing equipment that has been in operation since the customer first installed it.

In addition, in the past, due to the obsolescence of MOF and the external noise, it is not possible to detect that the error is out of the normal range, and the electric power company is suffering massive loss due to the weight loss due to the difference of the MOF ratio error.

Korean Patent Publication No. 10-2011-0081008 Korean Patent Laid-Open No. 10-2009-0105779

An object of the present invention is to provide an AMI server that calculates an effective power amount for a 3-phase 3-wire and a 3-phase 4-wire for each phase by using metering information input to a smart meter located at a remote location, And a predetermined threshold value to determine the occurrence of the error in the phase, and calculate a MOF error ratio in real time by calculating the error rate of the phase. The MOF ratio error using the AMI-based smart meter And an AMI server using the same.

A method for remotely estimating a MOF error using an AMI-based smart meter according to an embodiment of the present invention includes: calculating voltage and current of each phase for a predetermined period through metering information transmitted from a smart meter; Calculating an effective power amount for the three-phase three-wire type and the three-phase four-wire type for each phase after a predetermined period; Comparing the calculated difference of the effective electric power for the three-phase three-wire type and the three-phase four-wire type for each phase to a preset threshold value; And a step of calculating a metric error rate of the corresponding phase when the comparison result indicates that the error in the corresponding phase has occurred, and calculating the error rate of the MOF (Metering Out Fit).

The step of calculating the active power amount may calculate the active power amount of each of the three-phase three-wire type for each phase at the common reference of the phase when the power factor is one.

The MOF may be laid on the primary side when the transformer of the special high voltage receiving facility is connected to the delta (primary side) -wire (secondary side).

The comparison may be such that when the specific phase is a common reference, if the difference of the effective power amount for the three-phase three-wire type and the three-phase four-wire type is greater than a predetermined threshold value,

Wherein the comparison step determines that no error is generated when the difference between the effective power amount for the three-phase three-wire type and the three-phase four-wire type is less than the predetermined threshold value when the specific phase is the common reference, In the case of the common standard, it is possible to compare the difference of the effective power amount with the predetermined threshold value for the three-phase three-wire type and the three-phase four-wire type.

The metering error rate may be a value representing the difference between the three-phase three-wire type active power amount and the three-phase four-wire type active power amount as a percentage of the three-phase three-wire type active power amount when the specific phase is a common standard.

The error rate may be a value corresponding to three times the metering error rate.

Further, in the AMI server including the processor according to the embodiment of the present invention, the processor calculates the voltage and current of each phase for a predetermined period through the metering information transmitted from the smart meter, Calculating an effective power amount for the three-phase three-wire type and the three-phase four-wire type for each phase, comparing the calculated difference of the effective power amount for the three-phase three-wire type and the three- As a result of comparison, if it is judged that the error of the phase error has occurred, the error error rate of the MOF (Metering Out Fit) can be calculated by calculating the error rate of the corresponding phase.

In the present invention, an AMI server calculates an active power amount for a 3-phase 3-wire and a 3-phase 4-wire for each phase by using metering information input to a smart meter located at a remote place, And a predetermined threshold value to determine the occurrence of a deviation error of the phase, and calculate the error error rate of the corresponding phase so that the error error of the MOF can be calculated in real time.

Further, the present invention can reduce the measurement loss due to the error to the MOF and the inspection cost for the MOF. That is, since the present invention can detect and respond to all customers in real time based on AMI without directly measuring MOF abnormality and error in real time, the present invention can prevent potential loss of several tens of billions of won annually.

In addition, the present invention can be expected to have a high expected demand considering the situation similar to the electric power company in the world.

In addition, the present invention is judged to be a meaningful technology in the fourth industrial age by constructing a fair electric trading environment and checking and determining the abnormality of the MOF by using an electronic watt hour meter, IOT technology.

1 is a diagram of a method for remotely estimating MOF ratio error using an AMI-based smart meter according to an embodiment of the present invention.

For a better understanding of the present invention, a preferred embodiment of the present invention will be described with reference to the accompanying drawings. The embodiments of the present invention may be modified into various forms, and the scope of the present invention should not be construed as being limited to the embodiments described in detail below. The present embodiments are provided to enable those skilled in the art to more fully understand the present invention. Therefore, the shapes and the like of the elements in the drawings can be exaggeratedly expressed to emphasize a clearer description. It should be noted that in the drawings, the same members are denoted by the same reference numerals. Detailed descriptions of well-known functions and constructions which may be unnecessarily obscured by the gist of the present invention are omitted.

1 is a diagram of a method for remotely estimating MOF ratio error using an AMI-based smart meter according to an embodiment of the present invention.

The Advanced Metering Infrastructure (AMI) server can calculate the MOF error in real time using the metering information input to the smart meter located at the remote location. At this time, the AMI server can be operated by the processor.

In addition, the AMI server can diagnose whether the MOF is normal, detect excess error phase, and estimate the over / under amount of power usage due to the error error through the estimated MOF ratio error.

The delta-wye connection (Δ-Y connection) is applied to the transformer connection method of the high-voltage customer's receiving facility. Since the weighing point is the primary side, the following Equation 1 is established.

According to the above formula (1), the smart meter can eventually be measured within a predetermined range (constant cycle, constant interval) determined by the metering method by the three-phase four-wire type and the three-phase three-wire type.

With this characteristic in mind, the AMI server can check the difference in the amount of power by comparing the 'active power value of each phase of 3-phase 3-wire type' and '3-phase 4-wire type active power value'. This is possible even if the AMI server does not measure the MOF directly.

이고, A상 공통 기준시

이며, C상 공통 기준지

이다. 3상 4선식의 유효전력값은

이다.Here, the active power value of each phase of the three-phase three-wire type is set to a value of "1" when the power factor is "1"

, And the A-phase common reference time

, And C common reference point

to be. The effective power value of 3-phase 4-wire type is

to be.

Through this, the AMI server can calculate the error rate by checking the difference in the amount of power detected through the smart meter and checking the error over the corresponding phase, and by inverting the error of the corresponding phase.

Hereinafter, a method for remotely estimating a MOF ratio error using an AMI-based smart meter will be described with reference to FIG.

Here, it is assumed that the following conditions are assumed. The transformer connection method of the 22.9-kV receiving facility is delta (primary) -wire (secondary) connection (△ -Y connection). MOF and watt hour meter are installed on the primary side of the transformer. The MOF conversion ratio is 50/5 (10: 1) and the MOF conversion ratio is 13,200: 1. The voltage is Va = Vb = Vc = 1 and the current is Ia = Ib = Ic = 1. The power factor is 100% and the load is in equilibrium. Also, the error ratio is generated with a B-phase current ratio of 10% (10 A: 0.9 A).

First, the AMI server calculates the voltage and current of each phase for a predetermined period through the metering information transmitted from the smart meter (S101).

Thereafter, the AMI server calculates an active power amount for each of the three-phase three-wire type (3P3W) and three-phase four-wire type (3P4W) after a predetermined period (S102).

Here, the three-phase three-wire active power of each phase is 'V _ab I _a cos θ + V _cb I _c cos θ' at the B phase common reference, 'V _ba I _b cos θ + V _ca I _c cos θ' at the A phase common reference, Can be calculated as 'V _ac I _a cos θ + V _bc I _b cos θ'. The three-phase four-wire active power can be calculated as 'V _a I _a + V _b I _b + V _c I _c '.

For example, the three-phase three-wire active power at the B-phase common reference can be calculated as shown in Equation 2 below.

With reference to Equation (2) above, three-phase three-wire active power can also be calculated for the cases of A-phase common reference and C-phase common reference.

The three-phase four-wire active power can be calculated as shown in Equation 3 below.

Thereafter, the AMI server compares the difference of the effective power amount for each phase with a predetermined threshold value to determine occurrence of a rain error in the corresponding phase.

Specifically, when the AMI server is the B phase common reference, it is determined whether the difference between the active power amounts of the three-phase three-wire type and the three-phase four-wire type is equal to or greater than a threshold value (S103).

Next, the AMI server judges whether the difference in effective power between the three-phase three-wire type and the three-phase four-wire type is greater than or equal to the threshold value in the case of the A-phase common reference (S104).

Next, the AMI server judges whether the difference between the active power amounts of the three-phase three-wire type and the three-phase four-wire type is equal to or greater than the threshold value in the case of the C-phase common reference (S105).

When the AMI server is the C-phase common reference, when the difference in the effective power amount is less than the threshold value (S105), it is determined that no error error has occurred in all phases. Thereafter, the AMI server performs step S101 again.

On the other hand, when the AMI server is the B-phase common reference, if the difference in the effective power amount is equal to or greater than the threshold value (S103), it is determined that the error error has occurred in the B phase (S106). Thereafter, the AMI server calculates the B error rate using the result of the calculation of the B error rate (S109). At this time, the AMI server informs the manager of the error of the B phase error (S112).

For example, the metric error rate on phase B can be calculated as shown in Equation 4 below. That is, the B error rate of the phase B is the value of the difference between the three-phase four-wire active power and the three-phase three-wire active power as a percentage of the three-phase three-wire active power when the phase B is a common standard.

In addition, the error rate of the B phase can be calculated as shown in Equation (5) below. That is, the B error rate is three times the B error rate.

Similarly, when the AMI server is the A-phase common reference, when the difference between the effective power amounts is equal to or greater than the threshold value (S104), it is determined that the error error has occurred on the A-phase (S107). Thereafter, the AMI server calculates the error rate of the A phase using the result of calculating the metering error rate of the A phase (S110). At this time, the AMI server notifies the manager of the occurrence of the error of A phase (S112).

When the AMI server is the C-phase common reference, when the difference between the effective power amounts is equal to or larger than the threshold value (S105), it is determined that the error error has occurred on the C-phase (S108). Thereafter, the AMI server calculates the error rate of the C phase using the result of calculating the weighting error rate on the C phase (S111). At this time, the AMI server informs the manager of the error occurrence on the C phase (S112).

It will be apparent to those skilled in the art that various modifications and equivalent arrangements may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Accordingly, it is to be understood that the present invention is not limited to the above-described embodiments. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims. It is also to be understood that the invention includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims.

Claims (8)

Calculating voltage and current of each phase for a predetermined period through the metering information transmitted from the smart meter;
Calculating an effective power amount for the three-phase three-wire type and the three-phase four-wire type for each phase after a predetermined period;
Comparing the calculated difference of the effective electric power for the three-phase three-wire type and the three-phase four-wire type for each phase to a preset threshold value; And
Calculating a metric error rate of a phase error of the corresponding phase by calculating a metric error rate of the phase error value;
A method for remotely estimating MOF rain error using an AMI - based smart meter.
The method according to claim 1,
The step of calculating the active power amount includes:
A method for remotely estimating the MOF bias error using an AMI - based smart meter that computes the effective power amount of each phase - by - phase three - wire system at the common reference level when the power factor is 1.
The method according to claim 1,
The MOF is a remote method for estimating MOF ratio error using an AMI-based smart meter installed on the primary side when a transformer of a special high-voltage receiving facility is connected to a delta (primary side) -wire (secondary side) connection.
The method according to claim 1,
Wherein the comparing comprises:
When the difference between the effective power amount for the three-phase three-wire type and the three-phase four-wire type is equal to or greater than a predetermined threshold value when the specific phase is a common standard, the MOF ratio error using the AMI- .
The method according to claim 1,
Wherein the comparing comprises:
When the difference between the effective power amount for the three-phase three-wire type and the three-phase four-wire type is less than a preset threshold value, when the specific phase is a common reference, A Method for Remote Estimation of MOF Intensity Error Using AMI - based Smart Meter Comparing Difference of Active Power Amount for 3 - wire and 3 - phase 4 - wire with Preset Threshold.
The method according to claim 1,
The metering error rate
A method for remotely estimating MOF bias error using AMI-based smart meter, where the difference between 3-phase 3-wire active power and 3-phase 4-wire active power is expressed as a percentage of 3-phase 3-wire active power when a specific phase is a common standard.
The method according to claim 1,
The above-
A method for remote estimation of a MOF ratio error using an AMI-based smart meter that is three times the metering error rate.
CLAIMS What is claimed is: 1. An AMI server comprising a processor,
The processor,
The voltage and current of each phase are calculated for a certain period through the metering information transmitted from the smart meter,
After a predetermined period, the active power amount for each phase is calculated for the three-phase three-wire type and the three-phase four-wire type,
Comparing the calculated difference of the effective power amount for the three-phase three-wire type and the three-phase four-wire type for each phase with a predetermined threshold value,
The AMI server calculates the error rate of the Metering Out Fit (MOF) by calculating a metric error rate of the corresponding phase when it is determined that the error of the phase error has occurred.

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