KR20140046264A - Method for determining maximum short-circuit current of transformer - Google Patents

Abstract

The present invention relates to a method of determining a maximum short current of a transformer and, more particularly, to a method of determining a maximum short current of a transformer which automatically calculates the short currents generated by all kinds of equivalent or non-equivalent accidents to determine the maximum short current and applies the maximum short current to a transformer short strength design, so that damage to the transformer can be prevented and safety can be improved. The present invention provides a method including the following steps of: calculating a short current according to a trouble type by applying a short current calculation formula after determining a type of a transformer based on initial conditions; and determining the maximum short current by comparing the short currents calculated in the calculating step according to each trouble type with each other. [Reference numerals] (AA) Start; (BB) End; (S110) Step of providing initial conditions; (S120) Step of determining a type of a transformer; (S130) Step of calculating a short current; (S200) Step of determining the maximum short current of a transformer; (S300) Designing step

Description

Method for determining maximum short-circuit current of transformer}

The present invention relates to a method for determining the maximum short-circuit current of the transformer, and in detail, based on the data of the transformer and the power system to which the transformer is applied, automatically calculates the short-circuit current for all kinds of equilibrium and unbalance accidents, and uses the maximum short-circuit. The present invention relates to a method for determining the maximum short-circuit current of a transformer that can prevent the burnout of the transformer and improve the safety by determining the current and applying it to the transformer short-circuit strength design.

To date, transformer short-circuit strength design has typically been based on the maximum value of the three-phase short-circuit current, considered the largest.

The short-circuit strength design in this way does not reflect the development of the power system, which has recently been complicated and diversified, and many cases of transformer burnout due to short-circuit accidents are installed after installing the transformer in the field.

Although some unbalanced fault conditions, such as one-wire ground faults, have recently been considered in addition to the three-phase short circuit, which is an equilibrium fault, there have been no design applications by calculating the short-circuit current for the system conditions and types of faults in all cases.

In order to calculate the maximum short-circuit current that is the design standard for short-circuit strength considering all the conditions of the transformer and the power system to which the transformer is applied, data such as the special conditions of the target system, power short-circuit capacity, power impedance, transformer connection, transformer impedance, and neutral ground resistance Based on, the three-phase short circuit, one-line ground fault, two-line ground fault, and line-to-line short-circuit current at each fault location should be calculated.

This is a difficult point in the development of the method for determining the maximum short-circuit current, which is a standard for the design of transformer short-circuit strength, and this calculation method has not been proposed at present.

As discussed above, considering the power system reality and transformer burnout cases, which are recently complicated and diverse, the maximum short-circuit current determination method considering integrated and unbalanced accidents is necessary.

The present invention is to solve the problems of the prior art as described above, based on the data of the transformer and the power system to which the transformer is applied automatically calculates the short-circuit current for all kinds of equilibrium and unbalance accidents, using the maximum short-circuit current The purpose of the present invention is to provide a method for determining the maximum short-circuit current of a transformer that can prevent the burnout of the transformer and improve the safety by applying the same to the transformer short-circuit strength design.

The present invention for achieving the above object is a transformer short-circuit current calculation step of determining the type of the transformer on the basis of the initial conditions, calculating the short-circuit current according to the failure type by applying the short-circuit current calculation formula according to the type of the transformer; And determining a maximum short-circuit current for the transformer by comparing the short-circuit current calculated according to each fault type in the transformer short-circuit current calculating step to determine the largest short-circuit current as the maximum short-circuit current. .

On the other hand, the transformer short-circuit current calculating step, the initial condition providing step of providing an initial condition required to calculate the maximum short-circuit current; A transformer type determining step of determining a type of a transformer according to the type of the winding; And a short circuit current calculating step of calculating a short circuit current according to a failure type by applying a short circuit current formula according to the determined type of transformer.

At this time, if the type of the transformer is a two-winding transformer, the short-circuit current is calculated by applying the two-group transformer short-circuit current calculation formula. The short-circuit current is calculated by applying the winding transformer short-circuit calculation formula, and if the transformer type is a three-wound transformer, the short-circuit current is calculated by applying the three-winder transformer short-circuit current formula. do.

Here, the short-circuit current according to the fixed form is characterized in that the short-circuit current at the time of three-phase short circuit, 1 line ground fault, line short circuit and 2 line ground fault.

On the other hand, the present invention is characterized by comparing the short-circuit currents at the time of the three-phase short circuit, one-wire ground fault, line short-circuit and two-wire ground fault to determine the largest short-circuit current among these short-circuit currents as the maximum short-circuit current.

Specifically, the short-circuit current at the three-phase short circuit is compared with the short-circuit current at the three-phase short circuit, and when the short-circuit current at the three-phase short circuit is large, the short-circuit current at the three-phase short circuit is determined as the maximum short-circuit current. If the short-circuit current at the time of the first line ground is large, the short-circuit current at the time of the first line ground is compared with the short-circuit current at the time of the line short-circuit. If the short-circuit current is determined as the maximum short-circuit current, and if the short-circuit current at the line short-circuit is large, the short-circuit current at the line short-circuit is compared with the short-circuit current at the two-wire ground fault, and the larger short-circuit current is determined as the maximum short-circuit current. Characterized in that.

According to the present invention, based on the data of the transformer and the power system to which the transformer is applied, the short circuit current for the equilibrium and unbalance accidents is automatically calculated, and the maximum short circuit current of the transformer can be determined using the same.

In addition, by applying the determined maximum short-circuit current to the transformer short-circuit strength design, it is possible to prevent burnout of the transformer and to improve safety.

In addition, the present invention can be applied to all wiring systems of two winding transformers, three winding transformers, and single winding transformers.

1 is a simplified diagram showing a procedure for explaining a method for determining a maximum short-circuit current of a transformer according to the present invention.
2 is a detailed view showing a procedure for explaining a transformer short-circuit current calculation step in the method for determining the maximum short-circuit current of the transformer according to the present invention.
3 is a detailed diagram illustrating a procedure for explaining a transformer maximum short circuit current determining step in the method for determining a maximum short circuit current of a transformer according to the present invention.

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

The method for determining the maximum short-circuit current of the transformer according to the present invention described below can be widely applied in the field in which the transformer is installed for the purpose of obtaining the same effect obtained through the present invention.

1 is a simplified view showing a procedure for explaining the method for determining the maximum short-circuit current of the transformer according to the present invention, Figure 2 is a diagram for explaining the transformer short-circuit current calculation step in the method for determining the maximum short-circuit current of the transformer according to the present invention 3 is a detailed diagram showing a procedure, and FIG. 3 is a detailed diagram illustrating a procedure for explaining a transformer maximum short circuit current determining step in the method for determining a maximum short circuit current of a transformer according to the present invention.

1 to 3, the method for determining the maximum short-circuit current of the transformer according to the present invention includes a transformer short-circuit current calculating step (S100), a transformer maximum short-circuit current determining step (S200) and a design step (S300).

The transformer short-circuit current calculating step (S100) classifies the type of transformer based on the initial conditions provided for determining the maximum short-circuit current, and calculates the short-circuit current according to the failure type by applying a short-circuit current calculation formula according to the type of transformer. Step.

Specifically, the transformer short circuit current calculating step S100 may include an initial condition providing step S110, a transformer type determining step S120, and a short circuit current calculating step S130.

In detail, the initial condition providing step (S110) is a step of providing an initial condition necessary to determine the maximum short-circuit current that is the design criteria of the short-circuit strength, the special conditions of the power system to which the transformer is applied, the power short-circuit capacity, the power impedance, the transformer Provides data such as wiring, transformer impedance, and neutral ground resistance.

The initial condition is then provided by the operator's input to a system equipped with a program for determining the maximum short-circuit current of the transformer.

The transformer type determining step S120 is a step of determining the type of a transformer based on an initial condition, and the transformer type is determined based on the type of winding of the transformer.

That is, in the transformer type determining step (S120), the transformer may determine which type of transformer is a single winding transformer, a two winding transformer, or a three winding transformer according to the winding type.

First, check whether the transformer is a two-wound transformer (S121), and if it is not a two-wound transformer, check whether the transformer is a single winding transformer (S122) and determine the type of the transformer.

The short-circuit current calculation step (S130) is a step of calculating the short-circuit current according to the failure type by applying a short-circuit current calculation formula according to the type of transformer determined in the transformer type determination step (S120). At this time, the short-circuit current calculation formula is derived based on the data input in the initial condition input step (S110).

If the transformer determined in the transformer type determination step (S120) is a two-winding transformer, by applying a two-winding transformer short-circuit current calculation formula (S131), the short-circuit current at the three-phase short circuit, 1-line ground, line-line short circuit, 2-line ground fault is calculated (S132).

If the transformer determined in the transformer type determining step (S120) is a single winding transformer, after converting to a three winding transformer equivalent circuit (S133), by applying a three winding transformer short-circuit current calculation formula (S134), three-phase short circuit, one wire The short-circuit current at ground fault, line short circuit, and two-wire ground fault is calculated (S132).

On the other hand, if the transformer determined in the transformer type determination step (S120) is a three-wire transformer, by applying a three-wire transformer short-circuit current calculation formula (S134), the short-circuit current at the time of three-phase short circuit, 1 wire ground, line short circuit, 2 wire ground Calculate (S132).

The transformer short-circuit current determination step (S200) is a step of determining the largest short-circuit current as the maximum short-circuit current by comparing the short-circuit current calculated according to each failure type in the transformer short-circuit current calculation step (S100).

That is, the short-circuit current in three-phase short circuit, short-circuit current in one-line ground fault, short-circuit current in line short-circuit and short-circuit current in two-wire ground fault are compared with each other, and the largest short-circuit current among these short-circuit currents is regarded as the maximum short-circuit current. Decide

First, the short-circuit current at the three-phase short circuit is compared with the short-circuit current at the one-phase ground (S210). If the short-circuit current at the three-phase short circuit is large, the short-circuit current at the three-phase short circuit is determined as the maximum short-circuit current (S240). ).

If the short-circuit current at 1-line ground fault is large, compare the short-circuit current at 1-line ground fault with the short-circuit current at line short-circuit (S220). The current is determined as the maximum short-circuit current (S240).

However, if the short-circuit current at the line short-circuit is large, the short-circuit current at the line short-circuit is compared with the short-circuit current at the 2-wire ground fault (S230). The short-circuit current at line short-circuit is determined as the maximum short-circuit current (S240), and if the short-circuit current at 2-line ground fault is greater than the short-circuit current at line-line short circuit, the short-circuit current at 2-line ground fault is determined as the maximum short-circuit current (S240). ).

At this time, when comparing each short-circuit current in the transformer maximum short-circuit current determination step (S200), if the two short-circuit currents to be compared are the same, the corresponding short-circuit current is determined as the maximum short-circuit current.

The design step (S300) is a step of designing the short-circuit strength of the transformer winding and lead based on the maximum short-circuit current determined in the transformer short-circuit current determination step (S200).

As described above, the method of determining the maximum short-circuit current of the transformer provides a short-circuit strength design technology that can reduce the possibility of a transformer short-circuit accident in the future when power system development and diversification are expected. Will greatly contribute to ensuring this.

Although the method for determining the maximum short-circuit current of the transformer according to the present invention has been described according to a limited embodiment, the scope of the present invention is not limited to the specific embodiment, and is obvious to those skilled in the art in connection with the present invention. Various alternatives, modifications and changes can be made within the implementation.

Therefore, the embodiments described in the present invention and the accompanying drawings are intended to illustrate rather than limit the technical spirit of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments and accompanying drawings . The scope of protection of the present invention should be construed according to the claims, and all technical ideas within the scope of equivalents should be interpreted as being included in the scope of the present invention.

S100: Transformer short circuit current calculation step
S200: Transformer short circuit current determination step
S300: setting step

Claims (6)

A transformer short circuit current calculating step of determining a type of a transformer based on initial conditions and calculating a short circuit current according to a fault type by applying a short circuit current calculation formula according to a transformer type; And
And determining the maximum short-circuit current to determine the largest short-circuit current as the maximum short-circuit current by comparing the short-circuit currents calculated according to each fault type in the transformer short-circuit current calculating step. The method according to claim 1,
The transformer short circuit current calculating step may include an initial condition providing step of providing an initial condition necessary to calculate a maximum short circuit current;
A transformer type determining step of determining a type of a transformer according to the type of the winding; And
A method for determining the maximum short-circuit current of a transformer including a short-circuit current calculating step of calculating a short-circuit current according to a fault type by applying a short-circuit current calculation formula according to the determined type of transformer. The method according to claim 1,
If the type of transformer is a two-winding transformer, the short-circuit current is calculated by applying the two-group transformer short-circuit current calculation formula,
If the transformer type is single-circuit transformer, after converting into three-wire transformer equivalent circuit, apply the three-wire transformer short-circuit current calculation formula to calculate the short-circuit current according to the failure type,
If the transformer is a three-wound transformer, the method for determining the maximum short-circuit current of the transformer calculates the short-circuit current according to the type of failure by applying the three-wound transformer short-circuit current calculation formula. The method according to claim 1,
The short-circuit current according to the fixed form is the short-circuit current of the three-phase short circuit, 1-line ground, between-line short-circuit and two-wire grounding method. 5. The method of claim 4,
A method for determining the maximum short-circuit current of a transformer characterized by comparing the short-circuit currents at the time of the three-phase short circuit, one-wire ground fault, line short-circuit, and two-wire ground fault, and determining the largest short-circuit current among these short-circuit currents. . 6. The method of claim 5,
When the short-circuit current at the three-phase short circuit is compared with the short-circuit current at the three-phase short circuit, and the short-circuit current at the three-phase short circuit is large, the short-circuit current at the three-phase short circuit is determined as the maximum short-circuit current.
If the short-circuit current at the first line ground is large, the short-circuit current at the first line ground is compared with the short-circuit current at the line short-circuit. Determine the current as the short circuit current,
And if the short-circuit current at the time of the line short-circuit is large, the short-circuit current at the time of line short-circuit and the short-circuit current at the two-wire ground fault are further compared to determine a larger short-circuit current as the maximum short-circuit current.

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