KR100527435B1 - Determination method for equivalence impedance of power line - Google Patents

Abstract

The present invention relates to a method for determining an equivalent impedance of a distribution line using a distribution loss ratio that can replace a complex distribution system with a single equivalent impedance calculated on the basis of the distribution loss ratio in the accurate analysis of the power system. The present invention relates to distribution voltage, distribution loss ratio, effective and invalid load data, which are basically managed in distribution substations, and a method for determining a single equivalent impedance of a distribution line by simple numerical analysis using the same.

To this end, the present invention inputs the bus voltage (V _L ), the effective and invalid loads (I _P , I _Q ), the energy loss rate (q _O ) from 1 to t hours obtained at the distribution substation in charge (step 300). Assuming the distribution line single equivalent impedance initial values R _ini , X _ini (step 310), calculate the bus voltage (V _k ) at the load point k (step 320), and calculate the new loss rate from the assumed equivalent impedance initial values. (q) is calculated (step 330), and the objective function value (L) is calculated from the calculated loss rate (step 340), and if the result is within the error (ε) (step 350), the given R, X is final. Characterized by determining the distribution line equivalent impedance (step 360).

Description

DETERMINATION METHOD FOR EQUIVALENCE IMPEDANCE OF POWER LINE}

The present invention relates to a distribution line equivalent impedance determination method using a distribution loss ratio that can replace a complex distribution system with a single equivalent impedance calculated based on the distribution loss ratio in the precision analysis of a power system. The present invention relates to distribution voltage, distribution loss ratio, effective and invalid load data, which are basically managed in the relevant substation, and a method for determining the impedance of a single equivalent distribution line of a distribution line by a simple numerical method using the same.

The distribution line of the power system varies depending on the region and time, but load current flows to the extent that the effective value does not normally exceed about 250 amperes. However, when an accident occurs due to various causes such as an insulator breakdown or a power line breakage, a large fault current of hundreds to thousands of amperes flows. This is because the phase wires (A, B, C) and the phase wires or the phase wires and the neutral wire (N phase) are short-circuited and the impedance rapidly decreases. The fault current flows from the substation on the power supply side through the distribution line to the substation through the neutral point and back to the substation, so that a large current flows only at the power stage at the fault point and no fault current flows at the load end of the fault point.

Therefore, the terminal apparatus is installed in the distribution line at regular intervals, the terminal apparatus detects whether a fault current of a predetermined value or more flows, and sends the information to the central control station when a fault current of a predetermined value or more flows. The central control station may acquire fault information of the terminal device to determine and correct an accurate fault location.

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Figure 1 has shown any power distribution grid in a typical power system, reference numeral V _H of the substation high-voltage side bus bar, reference numeral V _L is substation low-voltage side bus bar, reference numeral X _T is the main transformer leakage reactance, numeral ℓ is ℓ-th distribution lines a, numeral n is the n-th load connection point of the distribution lines, reference numeral Z _n is a substation low-voltage side bus line impedance from the up-voltage distribution line (n) th the load connection point to a, the reference numeral I _Pn are the n-th effective load of the distribution lines, reference numeral I _Qn Denotes the nth invalid load of the distribution line.

That is, a leakage reactance is generated in the peripheral voltage transformer between the substation high voltage side bus bar and the low voltage side bus bar, and the 1, 2 --- th power distribution line is provided in the substation low voltage side bus bar. In the L-th distribution line, the impedance from the substation low voltage side bus line to the n-th load connection point of the distribution line is generated at the nth load connection point, and the effective load and the invalid load of the distribution line are generated.

The distribution system as described above is relatively more complicated than the transmission system according to the load distribution of general customers, etc.In order to analyze the electrical circuit, the distribution line constants (resistance, inductance, capacitance) per unit length, length (Length) And distribution system data are essential. However, the amount of such data is so large that it is difficult to manage systematically, and the acquisition is not easy.

In addition, in order to consider all the distribution systems in the general power system analysis, due to its complexity, a large amount of calculation and calculation time are required, and the electrical characteristics of the distribution system are omitted in large-scale power system analysis.

Accordingly, the present invention has been invented in view of the above-mentioned circumstances, and when analyzing a distribution system that is relatively complicated compared with the transmission system, the data collection efforts such as distribution line constant, positive and distribution system diagram, and complicated electricity Without the need for a circuit calculation process, the distribution voltage, distribution loss ratio, effective and invalid load data, which are basically managed in the distribution substation in charge, and a simple numerical method using the same numerical method are used to determine the impedance of a single equivalent distribution line. It is an object of the present invention to provide a method for determining an equivalent impedance of a distribution line using a distribution loss ratio in order to accurately consider the electrical characteristics.

The present invention for achieving the above object is to input the bus voltage (V _L ), effective and invalid load (I _P , I _Q ) results, energy loss rate (q _O ) from 1 to t hours obtained by the distribution substation in charge. Step (step 300), assuming the distribution line single equivalent impedance initial values (R _ini , X _ini ) (step 310), input bus voltage (V _L ), effective and reactive load (I _P , I _Q ) performance And calculating a bus voltage (V _K ) at the load point k by using a single equivalent impedance initial value (R _ini , X _ini ) of the distribution line (step 320), and the bus voltage at the calculated load point k ( V _K) calculating a new loss factor (q) by using (step 330), and a calculated loss rate (q) to the input energy loss rate (q ₀₎ assigned to the objective function for calculating a value (L) the objective function In step 340, if the result of the objective function value L is within the error ε (step 350), the given R and X are converted into the final distribution line equivalent impedance. And that the step consisting of determining (step 360) with its features.

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

2 shows that the complex distribution line is replaced by a single equivalent impedance centering on a substation in charge of the distribution system according to the present invention. In this process, the existing vast distribution line related information is not required. Here, reference numeral V _H are substation high-voltage side bus bar, reference numeral V _L is substation low-voltage side bus bar, reference numeral X _T is the main transformer leakage reactance, reference numeral k is an assumed load concentration points, reference numeral V _k is _the k point bus voltage, the reference numeral R is the line resistance from the substation low voltage side bus line to the k point of the distribution line, symbol X is the line reactance from the substation low voltage side bus line to the k point of the distribution line, symbol I _PK is the k point effective load of the distribution line, symbol I _QK Denotes k point reactive load of the distribution line.

The present invention is a method for determining the impedance of a single equivalent distribution line by using the distribution voltage, distribution loss ratio, effective and invalid load data, and simple numerical analysis using the same, which are basically managed in the relevant substation. Therefore, if necessary, a complex distribution system can be replaced with a single equivalent impedance calculated based on the distribution loss ratio.

The present invention assumes that all loads of a distribution line form a single equivalent load concentrated at k points, and is a method of determining the equivalent impedance of the replaced single distribution line. The basic concept of the method for determining the equivalent impedance of a distribution line includes a voltage (V _L ), an active load and an invalid load (P [MW], Q [MVar]) and distribution lines in a substation busline, which are generally known to electric utilities. When the impedance (R + jX) of the distribution line is determined from the energy loss rate (q ₀ ) data, the distribution line becomes an equivalent line for the load.

First, assuming that the k point voltage is V _k , the relation of equation (1) can be known for the given resistance R and reactance X.

Since P + jQ = V _L (I _P −jI _Q ), the effective and invalid loads can be converted into I _P and I _Q.

Since Equation (1) is generally a complex number, the relationship between Equation (2) can be seen by dividing into a real part and an imaginary part.

Then, let q be the loss rate for a certain period of time t.

here, : Supply energy.

If the loss ratio for this distribution system is known and the value is q _O

L = (q ₀ -q) ² (4)

The objective function can be defined and find the value L is minimized for R and X.

In other words,

here,

And,

Here, α has a value of about 1.1 as an acceleration factor for reducing the number of iterations, and after R and X are modified as in Equation (7), the process after Equation (1) is repeated again to obtain the final equivalent impedance. Will be decided.

3 is an algorithm flowchart for explaining a method for determining an equivalent impedance of a distribution line using the distribution loss ratio of the present invention. In step 300, the bus voltage V _L from 1 to t hours, the effective and invalid loads I _P , I _Q ) A step of inputting the performance, energy loss rate (q ₀ ), step 310 is assuming a single equivalent impedance initial value (R _ini , X _ini ), step 320 is the bus voltage (V _L) input in step 300 ), active and reactive load (I _P, I _Q) with a single equivalent impedance initial value (R _ini, X _ini) assumed in performing the step 310 calculating a bus voltage (V _k) at the load point k, and In operation 330, a new loss ratio q is calculated using the bus voltage V _K at the load point k calculated in operation 320. Step 340 is a step of calculating the objective function value (L) by substituting the energy loss rate (q ₀ ) input in step 300 and the loss rate (q) calculated in step 330 into the objective function, and step 350 is calculated in step 340. Determining the error (ε) of the objective function value (L), and step 360 is to determine the given R, X if the objective function value (L) calculated in step 350 is within the error range (│L | <ε) Determining the final distribution line equivalent impedance, and step 370 is a distribution line equivalent impedance correction amount (∂L / ∂) when the objective function value L calculated in step 350 is outside the error range (│L│> ε). R, ∂L / ∂X) is calculated, and step 380 is the equivalent impedance initial value R _ini , X _ini assumed in step 310 and the equivalent impedance correction amount ∂L / ∂R, ∂ calculated in step 370. This step is to update the equivalent impedances (R, X) by adding L / ∂X).

That is, input the bus voltage (V _L ), the effective and invalid loads (I _P , I _Q ), the energy loss rate (q ₀ ) from 1 to t hours acquired at the distribution substation in charge (step 300), and the single distribution line Assume the equivalent impedance initial values R _ini , X _ini (step 310). The bus voltage V _K at the load point k is calculated using the above-described equation (2) (step 320), and a new loss rate q is calculated by the equation (3) (step 330). Substituting the calculated loss rate into equation (4) yields the calculated objective function value (L) (step 340), and if the result is within the error (ε) (│L│ <ε) (step 350), R and X are determined to be the final distribution line equivalent impedances (step 360). If the condition given in step 350 is not satisfied, the corrections of R and X are calculated (step 370), R and X are updated (step 380), and then iteratively calculated from step 320 described above.

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By using the distribution line equivalent impedance calculated by the present invention, a complicated distribution system can be simply configured with a single equivalent impedance when the power system is accurately analyzed. Therefore, the present invention is a method for converting a complex distribution system into a single equivalent impedance of a distribution line using a distribution energy loss rate.

As described above, according to the present invention, data analysis such as distribution line parameters (resistance, inductance and capacitance per unit length), positiveness, and distribution system, which are essential when analyzing a distribution system that is relatively complicated compared to the transmission system, are essential. It is possible to determine the impedance of a single equivalent distribution line of a non-wiring line by using the distribution voltage, distribution loss ratio, effective and invalid load data basically managed in the relevant substation, and a simple numerical method using it without the need for effort and complicated electrical circuit calculation process. There is an advantage.

Although the present invention has been described based on an exemplary drawing, the technical idea of a method for determining an equivalent impedance of a distribution line using a distribution loss ratio, which is illustrative of the best embodiment of the present invention, and the scope of the claims of the present invention is limited. no. It will be apparent to those skilled in the art that various modifications and imitations can be made without departing from the scope of the technical idea of the present invention.

1 is a configuration diagram showing a conventional arbitrary power distribution system,

2 is a configuration diagram in which a distribution system is replaced with a single equivalent impedance in a distribution line equivalent impedance determination method using a distribution loss ratio according to an embodiment of the present invention;

3 is an algorithm flowchart for explaining a method for determining an equivalent impedance of a distribution line using the distribution loss ratio of the present invention.

-Explanation of symbols for the main parts of the drawings-

300: Bus voltage (V _L ) from 1 to t hours, effective and reactive load (I _P , I _Q ) results, energy loss rate (q _O ) input stage

310: assumption of the single equivalent impedance initial value (R _ini , X _ini ) of distribution line

320: step of calculating the bus voltage (V _K ) at the load point K

330: calculating loss rate (q) from initial assumed distribution line single equivalent impedance initial value

340: calculating the objective function value (L)

350: error determination step

360: determining final impedance (R, X) of distribution line

370: Computation step (∂L / ∂R, ∂L / ∂X) of equivalent distribution impedances (R, X)

380: update the equivalent impedance (R, X)

Claims (6)

Inputting bus voltage (V _L ), effective and invalid loads (I _P , I _Q ) results, energy loss rate (q ₀ ) from 1 to t hours acquired at the distribution substation in charge (step 300), Assuming a distribution line single equivalent impedance initial value R _ini , X _ini (step 310), Calculating a bus voltage V _K at the load point k using a single equivalent impedance initial value R _ini , X _ini of the distribution line assumed in step 310 (step 320), Calculating a new loss rate q using the bus voltage V _K at the load point k calculated in step 320 (step 330); Calculating an objective function value L by substituting the energy loss ratio q ₀ input in step 300 and the loss ratio q calculated in step 330 into the objective function (step 340); Determining an error ε of the objective function value L calculated in the step 340 (step 350), If the objective function value (L) calculated in step 350 is within the error range (│L│ <ε), determining the given R, X as the final distribution line equivalent impedance (step 360), characterized in that Distribution impedance determination method using distribution loss ratio. The method of claim 1, When the objective function value L calculated in the step 350 is outside the error range (│L│> ε), the correction amount (∂L / ∂R, ∂L / ∂) of the distribution line equivalent impedances (R, X) Calculating X) (step 370), Equivalent initial impedances R _ini and X _ini assumed in step 310 and correction parts ∂L / ∂R and ∂L / ∂X of distribution line equivalent impedances R and X calculated in step 370 are summed together. And updating the distribution line equivalent impedances (R and X) (step 380). Using the distribution loss ratio, after updating the distribution line equivalent impedances (R, X) in step 380, the step is repeated again from step 320 until the condition (│L│ <ε) is satisfied. Method for determining equivalent impedance of distribution line. delete The method of claim 1, Diet used in step 330 Equivalent impedance determination method of the distribution line using the distribution loss ratio. The method of claim 1, The objective function calculation formula Equivalent impedance determination method of the distribution line using the distribution loss ratio. The method according to claim 1 or 2, The final equivalent impedance calculation formula Equivalent impedance determination method of the distribution line using the distribution loss ratio.