KR100218382B1 - Directional overcurrent relay for transmission line protection - Google Patents

Abstract

The present invention relates to a direction overcurrent relay for quickly detecting a fault in a transmission line and removing an accident line from a health line. If the voltage disappears during breaker operation, the present invention maintains a trip that has already occurred unless the overcurrent relay returns. It is possible to operate the magnetic direction failure without time delay while giving a time delay, so that the disappearance of the reference vector voltage and the time delay during the direction reversal do not affect the operation of the direction overcurrent relay. A voltage storage capability is provided for the case where the voltage disappears when it occurs, and a time delay of one cycle is added to prevent malfunction in the direction reversal.

Description

Directional overcurrent relay for transmission line protection

1 is a block diagram of a conventional directional overcurrent relay.

2 is a view showing the process until the circuit breaker of FIG.

3 is an operation timing diagram of FIG.

4 is a diagram showing the protection algorithm and auxiliary relay operating time of the present invention.

5 is a block diagram of the directional overcurrent relay for protecting the transmission line of the present invention.

6 is a timing diagram of each part in the case where a failure occurs in a line in another direction in the apparatus of the present invention.

* Explanation of symbols for main parts of the drawings

1: direction relay 2: overcurrent relay

PT: Instrument transformer D: Directional element

IOC: Instant Element TOC: Time Element

10: direction selector 20: delay unit

30: pure sheet holding part 40: one sheet holding part

AND1 to AND5: endgate OR1 to OR4: oragate

The present invention relates to a directional overcurrent relay for quickly detecting a failure in a transmission line and removing an accident line from a healthy line.

In general, the line protection method by overcurrent relay is a protection relay that operates according to the amount of fault current. When there is power at one end of the transmission line, the direction of accident current is constant and the general operation is performed. In the case of a loop transmission line or a load side of a parallel two-wire transmission line, the direction of the current flowing through the relay is changed depending on the accident point, so that the overcurrent relay has directivity so as to operate only in a certain direction of current.

In addition, the direction relay uses a voltage as a reference vector to determine the direction of the current, and since the product of the voltage and the current is the operating torque, a wiring method in which the polarity is greatest when a failure occurs is frequently used.

1 is a configuration diagram of a conventional directional over-current relay, as shown in the current transformer CT for detecting the current installed in the transmission line, the instrument transformer (PT) for measuring the power supply voltage, and the instrument transformer ( A direction relay 1 for determining the voltage measured from PT) as a reference vector and determining the direction of the current detected from the current transformer CT, and transmitted from the direction relay 1 in connection with the direction relay 1; It consists of an overcurrent relay 2 which operates the breaker from the magnitude of the detected current, and its operation will be described with reference to FIG. 2 and FIG.

The direction relay 1 operates only in a certain direction current of the current detected through the accident generator current transformer CT and uses a voltage as a reference vector to determine the direction of this current. Therefore, if the voltage disappears during the near-end accident, the criterion is destroyed. In such a case, the direction of the fault current is determined by using the past voltage or the stored voltage. 1 cycle of Figure 2, after which the auxiliary relay (not shown) is operated and the breaker is operated to complete the opening of the breaker.

In addition, in the case of protecting the parallel two-line as shown in FIG. 1, if an accident occurs in the rear of the relay installation point, the direction relay 1 does not operate, but the overcurrent relay 2 may operate. If the fault current is reversed and the direction element operates earlier than the return of the overcurrent element, there is a possibility of malfunction. Therefore, start the overcurrent relay 2 only when the direction relay 1 operates or add a short time delay to prevent malfunction. do.

3 is a timing diagram of an operation process of a conventional directional overcurrent relay. When a fault occurs at a time point t1, the overcurrent relay 2 starts to operate, and when the fault is removed at a time point t2, the direction relay 1 The operation of the overcurrent relay 2 is stopped accordingly.

In the conventional device operating as described above, since the voltage, which is the reference vector, may disappear during the operation of the circuit breaker, the circuit breaker operating time should be properly determined in consideration of the circuit breaker operation time. There is a problem that is difficult to select.

In addition, in order to properly handle the 'lap time' in which the direction relay operates at the time t2 of FIG. 3, an overcurrent relay is started only when the direction relay 1 is operated or a short time delay is added to prevent malfunction. In the case of directional relay after starting the overcurrent relay, the malfunction of the relay can be prevented during the reversal of the direction.However, if the fault occurs in the line in the magnetic section, the overcurrent relay operates after the directional relay operates. Therefore, there is a problem that time delay occurs as much as judging the direction of the current, and also in the latter case, it operates properly when the direction is reversed, but causes a time delay of operation time for a fault occurring in the line of the magnetic section.

In order to solve this problem, the present invention maintains a trip that has already occurred unless the overcurrent relay is restored when the voltage disappears during the operation of the circuit breaker. It is designed to operate without time delay, so that the disappearance of the reference vector voltage and the time delay during direction reversal do not affect the operation of the direction overcurrent relay, and the time element of the overcurrent relay is started by the direction element. When described in detail with reference to the accompanying drawings as follows.

5 is a configuration diagram of the directional overcurrent relay for protecting the transmission line of the present invention, using the output of the direction element of the direction relay 1 and the output of the instantaneous element (IOC) of the overcurrent relay 2 of FIG. The direction selection unit 10 for determining whether the magnetic direction failure, the delay unit 20 for delaying the operation of the direction element by one cycle, the output of the delay unit 20 and the output of the direction selection unit 10 A second end gate AND2 for end combining, a third end gate AND3 for receiving an inverted input of the direction selector 10, and an end combination of the output of the directional element D, and the second end gate AND2. 2, the first o-gate which combines the output of the third end gate AND2 (AND3) and the failure output of the instrument transformer PT of FIG. 1 and the output when the momentary element is turned off in the correction. An instantaneous trip combining the output of the first OR gate and the output of the instantaneous element IOC; And a third orifice OR3 configured to hold and combine the output of the time direction element OFF in the failure output and correction of the directional element D and the instrument transformer PT. And a one-sheet holding unit 40 that combines the output of the time element of the overcurrent relay activated by the output of the third orifice OR3 and the output of the third orifice OR3.

In addition, the direction selector 10 includes a first end gate AND1 and an input terminal D that receive an inverted input of an instantaneous element IOC and an output of a direction element of the overcurrent relay 2 in the apparatus of FIG. The flip-flop FF which is always input between the state and the output of the first end gate AND1 to the clock terminal CLK, and is cleared when the output of the instantaneous element of the overcurrent relay is low. Consists of.

In addition, the forward seat holding unit 30 receives the output of the first ora gate OR1, and receives a third or gate OR3 receiving the feedback forward seat signal IOC Trip, and the third orphan. And a fourth end gate AND4 for outputting a forward-slip signal IOC Trip by combining the output of the gate OR3 and the output of the instantaneous element IOC, and the one-sheet holding part 40 is formed of the first end gate 40. The fourth OA gate OR4, which receives the output of the first OA gate OR1, and receives the feedback one sheet trip signal TOC Trip, the output of the fourth OG gate OR4, and the time element TOC. Is combined to form a fifth end gate AND5 for outputting a one-sheet trip signal TOC Trip.

The operation and effects of the directional overcurrent relay for protecting the transmission line of the present invention configured as described above will be described with reference to FIGS. 4 and 6.

First, as shown in FIG. 4, in order to extract the fundamental wave from the protection algorithm and the auxiliary relay operation time, the time for performing one period Fourier transform and the auxiliary relay operation time are added up to 1.5 cycles.

In other words, if the voltage storage capacity is held at a maximum of 1.5 cycles from the current sample value until the breaker operates, the trip is set to be maintained continuously unless the overcurrent element is returned thereafter.

After setting in this way, if a fault occurs in the line in the direction of oneself, the current direction is determined based on the past voltage before 1.5 cycles, and if the overcurrent elements (IOC, TOC) operate without time delay, the overcurrent elements (IOC, TOC) The high state is output from and the direction element (D).

Then, the time element of the overcurrent relay is started by the failure of the direction element D or the instrument transformer PT and the time direction element OFF.

The high state output of the direction element D is output from the second OA gate OR2 to the high state through the third end gate AND3 and is input to the forward seat holding unit 30 and the one seat holding unit 40. In the forward seat holding unit 30, the high state output of the second orifice OR2 and the high state output of the instantaneous element IOC are combined at the fourth end gate AND4 to generate the forward seat signal IOC. Trip) is output in the high state, and similarly, in the one-sheet holding unit 40, the output of the high state of the third orifice OR3 is passed through the fourth ordinal AND4 from the fifth end gate AND5. The trip is completed by outputting the one-sheet trip signal TOC Trip in the high state in combination with the output of the time-limiting element TOC in the high state.

Next, a case where a failure occurs in a line in another direction will be described with reference to FIG.

If a failure occurs at the time point t1 of FIG. 6, the direction is determined as in the case of a failure in its own direction, but the direction is determined as in the case of a failure in the other direction, but a failure occurs in the other direction. The direction element D does not operate.

Accordingly, the end gate AND1 of the direction selector 10 is activated, and accordingly, the flip-flop FF, which receives the high state input to the input terminal D, is enabled and the output Q is latched to the high state. .

At this time, when the fault is eliminated at the time t2, the direction element D is operated due to the direction reversal, so that the output of the direction element D is delayed by one cycle in the delay unit 20 so that the overcurrent element IOC may be delayed. Wait for the return.

If the overcurrent element IOC is not returned even after the one cycle delay time of the delay unit 20, a high state is output from the delay unit 20, and the output of the second end gate AND2 becomes a high state. As described above, the forward sheet signal IOC Trip is output through the first ora gate OR1, and it is determined that a failure occurs in the magnetic direction continuously.

On the contrary, if the overcurrent element IOC is returned before the delay time, that is, before the delay unit 20 outputs the high state, the flip-flop FF through the output of the time element IOC of the direction selector 10. As the input of the second end gate AND2 is cleared and the output is also low, the IOC Trip does not occur. Thus, the apparatus of the present invention again prevents the failure of the magnetic line. It is ready for detection without time delay.

In addition, when the instrument transformer PT of FIG. 1 fails or the momentary direction is turned OFF at the time of correction, the signal at this time is inputted to the first oar gate OR1 to correlate with the direction element D. FIG. Trip will go out without.

The TOC Trip does not start the time element of the overcurrent relay when the direction element D does not operate or is not a failure of the instrument transformer PT or when the time direction is not OFF. Do not.

The one cycle time delay is the time elapsed when one cycle Fourier transform is used to extract the fundamental wave of the overcurrent element, and the change of the current signal can be reflected in the effective value only after a maximum period of one cycle. Using transforms can reduce latency.

Therefore, the maximum time delay is 1 cycle.

As described in detail above, in the present invention, the voltage disappears when an accident occurs in the near-end so that the time delay at the time of disappearing and reversing direction of the reference vector voltage does not affect the operation of the direction overcurrent relay. In addition, it has a voltage storage capability, and adds a time delay of one cycle to prevent a malfunction in reversing direction.

Claims (6)

A direction selector for judging whether the direction reversal or magnetic direction failure is made by using the output of the direction element and the instantaneous element of the overcurrent relay, a delay unit which delays the operation of the direction element by one cycle, and an output of the delay unit; A second end gate for end combining the output of the trip holding unit; a third end gate for receiving an inverted input of the output of the trip holding unit; and an end combination of the output of the directional element and an output of the second and third end gates. A time limit that combines an output of the first ogate, an instantaneous trip holding unit that combines an output of the first ogate and an output of the instantaneous element, an output of the third ogate and an output of the activated time element. Directional over-current relay for transmission line protection, characterized in that the trip holding unit. The transmission line according to claim 1, wherein the first oA gate combines the outputs of the second and third end gates and combines the output of the instrument transformer with the output of the instantaneous element OFF. Directional overcurrent relay for furnace protection. The direction overcurrent relay for protecting a transmission line according to claim 1, wherein the maximum time delay of the delay unit is one cycle. The method of claim 1, wherein the direction selector comprises: a first end gate configured to invert the output of the instantaneous element and the output of the direction element; And a flip-flop which is configured to receive an output as a clock terminal and to be cleared when the output of the first oar gate is in a low state. 5. The apparatus of claim 4, wherein the forward-slip holding unit combines the output of the first or second gate and the output of the third oracle and the output of the instantaneous element. And a fourth end gate for outputting a forward seat signal. The method of claim 4, wherein the one-sheet lip holding unit combines an output of the fourth ogate and an output of the time element and a fourth oracle that receives the output of the third oar gate and receives the received one-sheet signal. And a fifth end gate for outputting a one-sheet lip signal.