KR100258484B1 - Protection device for distribution line - Google Patents

Abstract

A distribution system comprising a distribution busline connected to a power source, a distribution line connecting one side to the distribution busbar, the other to a load, a outlet breaker connecting the distribution line and the distribution busbar, and a plurality of circuit breakers provided at appropriate points on the distribution line. As a protective device to be applied, each breaker on the distribution line includes a current transformer for detecting the current at the installation point, and a current relay for opening the breaker when the output of the current transformer is above the set value, and the set value of each current relay is adjacent to the load side. When the accident occurs at the breaker installation point or the furthest point of the distribution line, set it based on the simulated fault current.

Description

Protection device of distribution line

1 is a view showing a distribution system hole according to the first invention.

2 is a view for explaining the relationship between the fault point and the current.

3 and 4 illustrate one embodiment of the first invention.

5 is a view showing a distribution system configuration according to the second invention.

6 is a diagram for explaining the relationship between an accident point and voltage.

7 is an embodiment of the second invention.

8 is a view showing a distribution system configuration according to the third invention.

9 to 14 show one embodiment of the third invention.

15 to 20 are characteristic diagrams in the embodiment of FIGS. 9 to 14.

* Explanation of symbols for main parts of the drawings

1: feeder line B: busbar

CB: Breaker DM: Division Switchgear

CT: Current transformer RY: Current relay

10: rectifier circuit 11: normal circuit

12: voltage setting circuit 13: comparison circuit

14: time circuit 15, 16: logical integration circuit

18, 19: switching circuit 20, 28: counting circuit

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a protection device for a distribution line, and more particularly, to a distribution line protection device when a circuit breaker is provided on a distribution line in addition to the circuit breaker of a distribution line outlet.

Conventionally, the protection of power distribution lines is such that, for example, Japanese Patent Application Laid-Open No. 63-18922 provides a breaker at the outlet of the power distribution line, and detects an accident by using a protective relay installed at the lead line at the time of the accident of the power distribution line and opens the breaker. After that, by the so-called time-sequence transfer method, it is made to inject at predetermined time intervals sequentially from the switchgear closest to the outlet.

According to the above-described prior art, since the breaker of the outlet is opened regardless of the occurrence position at the time of the accident of the distribution line, the entire section of the distribution line becomes a power failure, and the division switch is sequentially put in by the time circulating method. There is a problem.

For this reason, there is a request to minimize the power failure section at the time of an accident of a distribution line (only the load side from the accident point is a power failure). To solve this problem, a protective relay device is provided for each breaker by replacing the breaker on the distribution line with a breaker. Separation after the accident point is considered.

However, in a power system with only one load, such as a distribution line, the protection relay system for accurately opening the circuit breaker on the power supply side closest to the accident point and maintaining the circuit breaker on the power supply side more accurately than this circuit breaker is not yet known. It is not clear.

In view of the above, it is an object of the present invention to provide a protection device for a distribution line that can reliably perform division protection (minimization of the electrostatic range) of the distribution line when a circuit breaker is introduced into the distribution line.

The first invention of the present invention focuses on the current during an accident, and opens and controls each circuit breaker when the magnitude of the current detected at that position on the distribution line is greater than the current at the accident at the next circuit breaker installation point downstream of this circuit breaker installation point. .

The second invention of the present invention focuses on the voltage at the time of an accident, and when the magnitude of the voltage detected at that position on the distribution line is lower than the voltage at the time of the accident at the next breaker installation point downstream of this breaker installation point, the breaker is controlled. do.

In addition, the third invention of the present invention focuses on the current and voltage at the time of an accident, and the inverse time characteristic of the overcurrent relay which inputs the current detected at the position on the distribution line as the input voltage It is variable according to the size.

In the event of an accident, the current flowing through the power distribution line depends on the power supply and the distance to the accident point. For this reason, the electric current which flows into a distribution line at the time of an accident at each breaker installation point can be calculated | required previously, Therefore, minimization of an electrostatic section can be implement | achieved by comprised like 1st invention.

When an accident occurs, the voltage at each point of the distribution line depends on the distance between the power supply and the accident point. For this reason, the voltage detected at the breaker installation point of the magnetic pole at the time of an accident at the next breaker installation point on the load side can be obtained in advance, and therefore, the configuration as in the second invention can minimize the power failure section.

When an accident occurs, the voltage on the distribution line drops, and the degree of the drop is closer to the accident point. For this reason, the overcurrent relay at the position closest to the accident point can be operated first by the configuration as in the third invention in which the inverse time characteristic is variable according to the voltage drop.

1 is a diagram showing a power distribution system of the present invention, a bus B is fed from a feed line 1 via a transformer Tr, and a plurality of power distribution lines are connected to a breaker CB1 from another bus B. (2) is connected. The breakers CB2 and CB3 are installed at appropriate positions of the power distribution line 2. In addition, in this figure, several division switch DM is provided between breaker CB. In the first invention for protecting the distribution system, the outlet breaker CB1 is controlled by the current relay RY11 which inputs a signal from the current transformer CT or the like, and the breaker CB2, CB3) is controlled by current relays RY12 and RY13 that take in signals from current transformer CT.

Although the details of the first invention focusing on the current will be described below, the relationship between the distance to the accident point at the time of a distribution line accident (short circuit accident) and the current will be described.

Fig. 2 shows the current flowing through the power distribution line when an accident occurs at each point of the power distribution line, and the distance from the power supply on the horizontal axis and the accident current value on the vertical axis. As apparent from this figure, the current flowing in the event of an accident at the breaker CB1 and the installation point F0 is IF0, and the current flowing in the event of an accident at the breaker CB2 installation point F1 is IF1 and the breaker CB3 is installed. The current flowing at the time of the accident at the point F2 becomes IF2, and the current flowing at the time of the accident at the breaker CB4 installation point F3 becomes IF3. In addition, in case of an accident at the furthest point (F4), it becomes IF4. In addition, the electric current which flows at the time of an accident at a specific point is almost the same even if it measures in any point. Therefore, the first invention focusing on the current at the time of an accident is thus configured as shown in FIG. 3.

FIG. 3 shows any one of the current relays RY1 of FIG. 1, in which the current I from the current transformer CT is rectified in the rectifying circuit 10 and smoothed in the smoothing circuit 11. (V) is compared with the setting value VS of the setting circuit 12 in the comparison circuit 13, and when V is larger, the output is applied after the time limit T1 determined by the time limit circuit 14. The characteristic of this circuit is that IF1 in Fig. 2 is set as the set value Vs in the current relay RY11, IF2 is set in the current relay RY12, IF3 is set in the current relay RY13, In step RY14, IF4 is set. That is, in Fig. 2, when attention is paid to a specific current relay (here, for example, RY12), the accident current IF2 at the point of installation of the next breaker CB3 on the load side causes an accident current IF2 of this current relay RY12 to fail. It is set as operation setpoint VS. For this reason, when an accident occurs in the section 4 of FIG. 2, a current having a magnitude between the currents IF3 and IF4 flows, and only the breaker CB4 is opened. When an accident occurs in the section 3, a current of magnitude between the currents IF2 and IF3 flows to open the breakers CB3 and CB4. When an accident occurs in section (2), a current of magnitude between currents IF2 and IF3 flows to open the breakers CB2, CB3 and CB4. When an accident occurs in section 1, a current of magnitude between currents IF1 and IF2 flows, and all breakers are opened. According to this method, only after the accident section is cut off, and the healthy section does not become a power failure. Also, this breaker opens all breakers after the accident section, but this does not particularly affect the operation of the distribution line. That is, the restoration of the power failure section is made to be input at predetermined time intervals from the breaker or the division switch close to the outlet by the time-sequential time-sequential transfer method from the upstream side. There is no change.

Next, using only FIG. 4, the circuit breaker of an accident zone is cut | disconnected as this application. This circuit differs from FIG. 3 in that two setting circuits 12 and two comparison circuits 13 are provided, VS1 is set in the setting circuit 12-1 and VS2 is set in the setting circuit 12-2. In each comparison circuit 13, the detector V is outputted with the larger one. In the logical multiplication circuit 15, the comparison circuit 13-1 outputs the output, and the comparison circuit 13-2 does not output the final output via the time limit circuit 14. The characteristic of this circuit is that IF0 of FIG. 2 is set as VS2 in the current relay RY11, IF1 is set as VS2, IF1 is set as VS1 in the current relay RY12, and IF2 is set as VS2. In the current relay RY13, IF2 is set as VS1 and IF3 is set as VS2. In the current relay RY14, IF3 is set as VS1 and IF3 is set as VS2. That is, in Fig. 2, when attention is paid to a specific current relay (e.g., RY12), the fault current VS2 (IF2) at the installation point of the next breaker CB3 on the load side is the current relay RY12. It is set as the lower limit operation set value, and the fault current VS1 (IF1) at the time of an accident at the breaker CB2 installation point of the specific current relay RY12 is set as the upper limit operation set value of this current relay RY12. For this reason, when an accident occurs in the section 4 of FIG. 2, a current having a magnitude between the currents IF3 and IF4 flows, and only the breaker CB4 is opened. When an accident occurs in the section 3, a current of magnitude between the currents IF2 and IF3 flows, and only the breaker CB3 is opened. When an accident occurs in section (3), a current of magnitude between currents IF2 and IF3 flows, and only breaker CB2 is opened. When an accident occurs in the section 1, a current of magnitude between the currents IF1 and IF2 flows, and only (CB1) is opened.

FIG. 5 is a diagram showing a distribution system when protecting with a voltage relay, which is the second invention of the present invention, and different from FIG. 1, the protection relay R YV operates by inputting the voltage at the installation point from the voltage transformer PT. It's just that.

Next, the details of the second invention will be described. However, the relationship between the distance to the accident point at the time of the distribution line accident and the voltage is explained.

Fig. 6 shows the voltage observed at each point of the distribution line when an accident occurs at each point of the distribution line, and shows the distance from the power supply on the horizontal axis and the accident voltage value at each point on the vertical axis. In this figure, L ₀ , L ₁ , L ₂ , L ₃ , L ₄ is the voltage at each distribution line at the breaker (CB1) installation point (F0), the voltage at each distribution line at the breaker (CB2) installation point (F1), This is a characteristic line showing the voltage of each distribution line at the breaker (CB3) installation point (F2), the voltage of each distribution line at the breaker (CB4) installation point (F3), and the voltage of each distribution line at the farthest point (F4). . In this way, even at an accident at any point, the voltage at the accident point (shorting fault point) becomes zero, the power supply voltage is usually rated, and the voltage value at each point in between can be known in advance. Therefore, in the second invention which focuses on the voltage at the time of an accident from this, it is comprised as FIG.

FIG. 7 shows any one of the voltage relays RYV in FIG. 5, in which the voltage V from the voltage transformer PT is rectified in the rectifying circuit 10 and smoothed in the smoothing circuit 11. This value V is compared with the set value VS of the setting circuit 12 in the comparison circuit 13, and when V is smaller, after the time limit T ₁ determined by the time limit circuit 14, the output is output. Add. The characteristic of this circuit is that VF1 in Fig. 6 is set as the set value VS in the voltage relay RYV1, VF2 in RYV2, VF3 in RYV3, and VF4 in RYV4. That is, in FIG. 6, when the specific voltage relay (for example, RYV2) is noted, the accident voltage VF2 output by the specific voltage relay when the accident occurs at the installation point of the next breaker CB3 on the load side is the voltage relay ( RYV2). For this reason, when an accident occurs in the section (4) of Fig. 6, the voltage is below the voltage VF4, and only the breaker CB4 is opened. When an accident occurs in the section 3, the voltage is between the voltages VF3 and 2VF4, and the breakers CB3 and CB4 are opened. When an accident occurs in the section (2), the voltage breaker (CB2, CB3 and CB4) is opened between the voltage (VF2) and the voltage (VF3). When an accident occurs in section 1, the voltage is between the voltages VF1 and VF2, and all breakers are opened. According to this method, only after the accident section is cut off, and the healthy section does not become a power failure. In addition, in this method, all breakers after the accident section are opened, but for the above reasons, this does not particularly interfere with the operation of the distribution line.

Finally, the third invention will be described. In this invention, the inverse time characteristic of an overcurrent relay was corrected to the voltage value of a distribution line. Fig. 9 is a diagram showing a distribution system when protecting with an overcurrent relay of inverse time characteristic in the third invention, and differs from Fig. 1 or 5 in that the protective relay RY is the current and voltage at its installation point. Is inputted from the current transformer CT and the voltage transformer PT to operate. 9 to 14 show one embodiment of the protective relay device at this time.

VS1일 때 비교회로(13-13), 논리합회로(18)를 거쳐 차단기(CB)의 트립(tripping)신호가 발생된다. 이 회로에서 설정신호(VS1)는 과전류 계전기(RY1)의 감도전류(최소동작전류)에 상당하고, 설정신호(VS1)는 동작시간을 결정한다. 이 회로에서는 입력(V1)의 크기에 따른 속도로 적분이 행해지고, 설정치(VS1)에 달하는 시간이 결정되기 때문에, 반한시 특성(Ln)이 실현된다. 또한, 도 15에 나타낸 바와 같이 인출구 차단기(CB1)를 위한 보호계전장치(RY1)의 특성(L1)은, 감도전류가 반한시 특성(Ln)보다 크게 설정되어 있다.Among these, FIG. 9 is a method of correcting the inverse time characteristic of the overcurrent relay on the distribution line to a fixed time limit when detecting a voltage drop, and shows the characteristic in FIG. In Fig. 9, the current I and the voltage V at the installation point are input to the protective relay RY on the distribution line from the distribution line 2 through the current transformer CT and the voltage modification time PT. . The circuit constituted by the rectifier circuit 10, the smoothing circuit 11, the setting circuit 12-1, the integrating circuit 16, and the comparison circuits 13-1 and 13-3 of the protective relay device RY. When the portion corresponds to the so-called overcurrent relay RY1 and the output V1 of the smoothing circuit 11 is larger than the output VS1 of the setting circuit 12, the comparison circuit 13-1 outputs (13- On the condition that the output of 1) is obtained, the integrating circuit 16 starts the integration of the input V1. The integral output V12 is compared with the set voltage VS1 and V12

In the case of VS1, a tripping signal of the breaker CB is generated through the comparison circuit 13-13 and the logic sum circuit 18. In this circuit, the setting signal VS1 corresponds to the sensitivity current (minimum operating current) of the overcurrent relay RY1, and the setting signal VS1 determines the operation time. In this circuit, integration is performed at a speed corresponding to the magnitude of the input V1, and the time to reach the set value VS1 is determined, so that the inverse time characteristic Ln is realized. As shown in Fig. 15, the characteristic L1 of the protective relay RY1 for the inlet breaker CB1 is set larger than the inverse time characteristic Ln.

VS2일때 비교회로(13-2)가 출력한다. 비교회로(13-2)의 출력은 한시회로(14)에 입력되어 여기서 설정된 시간(T1)후에 출력한다. 논리곱회로 (17)는 배전선에 전압강하가 생긴 것을 한시회로(14)의 출력에서 확인하고, 또한 감도 전류이상의 전류가 흐르고 있음을 비교회로(13-1)의 출력에서 확인하여 논리합회로 (18)를 거쳐 차단기(CB)의 트립 신호를 출력한다. 또한, 도 15에 나타낸 바와 같이 시간(T1)은 예상되는 최대 사고전류(I_max)일때의 과전류 계전기(RY1)의 동작시간(t1)보다도 짧게 설정되어 있다.On the other hand, circuit portions other than the overcurrent relay RY1 (time circuit 14, logical multiplication circuit 17, logical sum circuit 18, rectifier circuit 10, smoothing circuit 11, comparison circuit 13-2, and setting circuit 12-2) Is the adjusting unit of the inverse time characteristic, and the distribution line voltage V2 which is the output of the smoothing circuit 11 is compared with the setting voltage VS2 which is the output of the setting circuit 12-2 in the comparison circuit 13-2. V2

When it is VS2, the comparison circuit 13-2 outputs. The output of the comparison circuit 13-2 is input to the time limit circuit 14 and output after the time T1 set here. The AND circuit 17 checks at the output of the temporary circuit 14 that a voltage drop has occurred in the distribution line, and also checks at the output of the comparison circuit 13-1 that a current higher than the sensitivity current is flowing. The trip signal of the breaker CB is output through As shown in Fig. 15, the time T1 is set shorter than the operation time t1 of the overcurrent relay RY1 at the expected maximum fault current I _max .

In this invention, since it is comprised like FIG. 9, the sum total characteristic becomes as FIG. That is, the overcurrent relay RY1 alone has the same inverse time characteristic as that of the characteristic Ln of FIG. 15, but when the adjusting part outputs by voltage, the output is forcibly output by the time limit T1. However, in the large current region, the characteristic is the characteristic of the dynamic Ln 'outputted at a constant time T1. Moreover, the characteristic of this circuit is that VF1 in Fig. 6 is set as the set value VS2 in the protective relay device RY1, VF2 in RY2, VF3 in RY3, and VF4 in RY4. This voltage setting method is the same as that described in Fig. 7, which is an embodiment of the second invention. According to this system, for example, when an accident occurs in the section 3 of Fig. 6, the protection circuit RY4 does not output the accident current so that the comparison circuit 13-3 in the overcurrent relay RY1 does not output. Therefore, the trip signal is not output. The protective relay RY3 detects a fault current above the sensitivity current and operates according to the inverse time characteristic. However, in the adjusting unit which inputs the voltage, it detects that the voltage drops below VF3. Since the current is greater than or equal to the sensitivity current, the logical AND circuit 17 is output, and a trip signal is applied without waiting for the output of the overcurrent relay RY1. The total operation characteristic of the protective relay device RY3 at this time is as shown by Ln 'in FIG. The protective relays RY1 and RY2 detect fault currents higher than the sensitivity current, and the overcurrent relay RY1 starts to operate according to the inverse time characteristic. On the other hand, in the control unit that inputs the voltage, the voltage does not drop below VF1 and VF2. Therefore, no output is applied, and accordingly, the output is applied according to the inverse time characteristic. However, since the protection relay RY3 blocks the accident section before reaching the final output, no trip signal is applied. The total operating characteristics of the protective relay devices RY1 and 2 at this time are as shown in Ln in FIG. Therefore, only the accident section is blocked, and the health section does not become a power failure. Further, in the protective relay device RY3, a trip is performed by the output of the overcurrent relay RY1 even if the voltage adjusting part is not operated. Thus, the backup relay is in a certain sense. Similarly, even if the protective relay device RY3 does not operate, the protective relay devices RY1 and RY2 trip by the output of the respective overcurrent relays RY1.

The embodiment of FIG. 10 is a modification of the third invention, and the part of the overcurrent relay RY1 has the same configuration as that of FIG. Among the adjustment units of the inverse time characteristic, 10, 11, 12-3, and 13-2 also have the same configuration as in Fig. 9, and the integral circuit 16-2 is started by detecting the voltage drop. When the integrating circuit 16-2 is started by the comparing circuit 13-2, the integral circuit 16-2 starts to integrate the constant voltage V _c of the setting circuit 12-3. Increase at speed. The voltage V2 of the single distribution line is input to the comparison circuit 13-4 via the counting circuit 28 and compared with the output of the integrating circuit 16-2. And when the output of the integration circuit 16-2 becomes larger than the output of the counter circuit 28, it outputs. As is apparent from this configuration, the output of the comparison circuit 13-4 is output at an earlier point in time as the degree of drop in the distribution line voltage V2 increases. In other words, the closer to the accident point, the faster the output. The sum total characteristic as the whole protective relay system of the Example of FIG. 10 becomes a variable characteristic like FIG. That is, if an accident occurs in the accident section 2 of Fig. 6, the protective relay device RY2 is as Ln'2 in Fig. 16, the protective relay device RY1 is as Ln'1 in Fig.

In the above embodiment, the time limit is fixed at the time of voltage drop. Next, an embodiment in which the time characteristic is inverse to the voltage drop will be described with reference to FIG.

VS2라고 판단되었을 때는 설정회로(12-1)의 출력(VS1)을 비교회로(13-3)에 가하고, V2

VS2로 판단되었을 때는 설정회로(12-3)의 출력 (VS3)를 비교회로(13-3)에 가한다. 단, VS1

VS3로 되어 있다. 따라서 배전선의 전압이 크게 강하했을 때(V2

VS2), 더 작은 설정전압(VS1)이 비교회로(13-3)에 입력되어 적분전압(V12)과 비교되고, 배전선의 전압이 그다지 강하하지 않을 때 (V2

VS2), 더 큰 설정전압(VS3)이 비교회로(13-3)에 입력되어 적분전압(V12)과 비교된다. 어떤 설정전압을 선택한 경우이더라도, 과전류 계전기(RY1)는 반한시 특성을 나타내나, 그 복합 특성은 도 17와 같은 반한시 특성이 된다. 즉, 전압강하를 검출하지 않을 때는 특성 Ln과 같은 반한시 특성이나, 전압강하를 검출했을 때는 더빠른 시간으로 동작하는 동도 Ln'의 반한시 특성이 된다. 또한, 이 회로에 있어서 전압설정치 (VS2)의 설정방식 및 사고 발생시의 동작은 도 9의 경우와 동일하므로 그 설명은 생략한다.The circuit configuration of FIG. 11 is essentially different from FIGS. 6 and 7 in that the integral value V12 of the overcurrent relay RY1 is compared with either of the set voltage VS1 or VS3 selected by the switching circuit 19. The set voltages VS1 and VS3 are set to V2 in the comparison circuit 13-2 of the inverse time characteristic adjusting unit.

When it is determined that it is VS2, the output VS1 of the setting circuit 12-1 is added to the comparison circuit 13-3, and V2 is applied.

When judged as VS2, the output VS3 of the setting circuit 12-3 is applied to the comparison circuit 13-3. However, VS1

It is VS3. Therefore, when the voltage of the distribution line drops greatly (V2

VS2), when the smaller set voltage VS1 is input to the comparison circuit 13-3 and compared with the integral voltage V12, and the voltage of the distribution line does not drop much (V2).

VS2), a larger set voltage VS3 is input to the comparison circuit 13-3 and compared with the integral voltage V12. Even if any set voltage is selected, the overcurrent relay RY1 exhibits an inverse time characteristic, but the composite characteristic becomes an inverse time characteristic as shown in FIG. In other words, when the voltage drop is not detected, it becomes the inverse time characteristic such as the characteristic Ln, or when the voltage drop is detected, the inverse time characteristic of the same degree of operation Ln 'which operates at a faster time. In this circuit, the setting method of the voltage set value VS2 and the operation at the time of an accident are the same as in the case of Fig. 9, and the description thereof is omitted.

The embodiment of FIG. 12 is a modification of FIG. 11, and in FIG. 11, the correction is made to the inverse time characteristic according to the degree of voltage drop in the present invention, while the correction is made to the predetermined inverse time characteristic when the voltage falls below a predetermined voltage value. . The portion of the double overcurrent relay RY1 has an inverse time characteristic in which the output VS1 'of the counting circuit 28 is compared with the output 12 of the integrating circuit 16, so that the smaller the VS1', the faster it operates. And VS1 'is proportional to the detected voltage V2 of the distribution line 2. The adjusting unit for determining the output of the counting circuit 28 applies the detection voltage V2 as the output of the switching circuit 19 only when the comparison circuit 13-2 detects the voltage drop, and corresponds to the rated voltage of the distribution line. Injecting output. As apparent from this configuration, when no voltage drop is detected, the overcurrent relay RY1 becomes the inverse time characteristic (Fig. 18 LN) determined by the set voltage VS1, and the voltage V2 of the distribution line is set voltage VS2. ), The lower the degree of descent, the faster the output. In other words, the voltage drop is corrected as LN1, LN2 depending on the degree of the drop.

Although the above embodiment corrects the inverse time characteristic of the overcurrent relay during voltage drop, an embodiment of correcting the sensitivity current of the overcurrent relay during voltage drop will be described with reference to FIG.

VS2로 판단되었을 때는 설정회로(12-1)의 출력(VS1)을 비교회로(13-3)에 가하고, V2

VS2라고 판단되었을 때는 설정회로(12-3)의 출력(VS3)을 비교회로(13-3)에 가한다. 단, VS1

VS3으로 되어 있다. 따라서 배전선의 전압이 크게 강하했을 때(V2

VS2), 보다 작은 설정전압(VS1)이 비교회로(13-1, 13-3)에 입력되어 전압 V1, V12와 비교되고, 배전선의 전압이 그다지 강하하지 않을 때(V2

VS2), 보다큰 설정전압(VS3)이 비교회로(13-1, 13-3)에 입력되어 전압(V1, V12)와 비교된다. 어떤 설정 전압을 선택한 경우이더라도 과전류 계전기(RY1)은 반한시 특성을 나타내나, 그 복합특성은 도 19와 같은 반한시 특성이 된다. 즉, 전압강하를 검출하지 않을 때는 특성 Ln과 같은 반한시 특성이나, 전압 강하를 검출했을 때는 더 감도 전류가 낮은 동도 Ln'의 특성이 된다. 또한, 이 회로에 있어서 전압설정치(VS2)의 설정방식 및 사고 발생시의 동작은 도 9의 경우와 동일하고 설명은 생략한다.The circuit configuration of FIG. 13 is substantially different from that of FIG. 11 in that the detected current V1 of the overcurrent relay RY1 is compared with either of the set voltage VS1 or VS3 selected by the switching circuit 19. In this circuit, The set voltage VS1 or VS3 corresponds to the so-called sensitivity current. These set voltages VS1 and VS3 are set to V2 in the comparison circuit 13-2 of the adjustment unit.

When it is determined as VS2, the output VS1 of the setting circuit 12-1 is added to the comparison circuit 13-3, and V2 is applied.

When determined to be VS2, the output VS3 of the setting circuit 12-3 is applied to the comparison circuit 13-3. However, VS1

It is VS3. Therefore, when the voltage of the distribution line drops greatly (V2

VS2) When a smaller set voltage VS1 is input to the comparison circuits 13-1 and 13-3 and compared with the voltages V1 and V12, and the voltage of the distribution line does not drop very much (V2).

VS2), a larger set voltage VS3 is input to the comparison circuits 13-1 and 13-3 and compared with the voltages V1 and V12. Even if any set voltage is selected, the overcurrent relay RY1 exhibits an inverse time characteristic, but the composite characteristic becomes an inverse time characteristic as shown in FIG. That is, when the voltage drop is not detected, it becomes the inverse time characteristic similar to that of the characteristic Ln, and when the voltage drop is detected, the characteristics of the dynamic Ln 'with lower sensitivity current are further reduced. In this circuit, the setting method of the voltage set value VS2 and the operation at the time of an accident are the same as in the case of Fig. 9, and the description is omitted.

The embodiment of FIG. 14 is a modification of FIG. 13, and in FIG. 13, a correction is made to a sensitivity current corresponding to the degree of voltage resistance in the present embodiment, while the correction is made to a predetermined sensitivity current when the voltage is below a predetermined voltage value. In part of the overcurrent relay RY1, the output VS1 ′ of the counter circuit 20 is compared with the detection voltage V1, and thus VS1 ′ is proportional to the detection voltage V2 of the power distribution line 2. The adjusting unit which determines the output of the counting circuit 20 applies the detection voltage V2 as the output of the switching circuit 19 only when the comparison circuit 13-2 detects the voltage drop, and corresponds to the rated voltage of the normal distribution line. Is adding output. As apparent from this configuration, when no voltage drop is detected, the overcurrent relay RY1 becomes the inverse time characteristic (Fig. 20 LN) determined by the set voltage VS1, and the voltage V2 of the distribution line is set voltage VS2. When it is less than), the greater the degree of the drop, the lower the sensitivity current. In other words, the voltage drop is corrected as LN1, LN2 depending on the degree of the drop.

In addition, in Fig. 1, Fig. 5 and Fig. 8, the protective relay device for protecting the outlet breaker is described as having the same configuration as the protective relay device for the distribution line. good.

According to the power distribution line protection device of the present invention, when the breaker is introduced into the power distribution line, it is possible to reliably divide the protection of the power distribution line (minimize the power failure range).

Claims (16)

Distribution line consisting of a distribution bus line connected to a power source, a distribution line connecting one side to the distribution busbar and the other to a load, a outlet breaker connecting the distribution line and the distribution bus line, and a plurality of circuit breakers provided at appropriate points on the distribution line. A protective device for a circuit comprising: a current transformer for detecting a current at an installation point of each breaker on the distribution line; and a current relay for opening the breaker at the installation point when the current output of the current transformer detects a current value equal to or greater than an operating set current value. The operation set current value of each of the current relays is set according to an accident current value assumed when an accident occurs at an adjacent load side breaker installation point, or an accident current value assumed when an accident occurs at the furthest point of the distribution line. Protective device for power distribution lines. A distribution bus line connected to the power source, a distribution line for connecting one side to the distribution busbar and the other to a load, a outlet breaker for connecting the distribution line and the distribution busbar, and a plurality of circuit breakers provided at appropriate points on the distribution line. A protection device for a distribution line, comprising: a current transformer for detecting a current at the installation point for each breaker on the distribution line, and a current relay for opening the breaker at the installation point when the current output of the current transformer detects a current value equal to or greater than an operating set current value. And the operation setting current value of each of the current relays is set as lower as possible from the power distribution bus. A distribution line protection device comprising a distribution bus line connected to a power supply, a distribution line connecting one side to the distribution bus line and the other to a load, and a circuit breaker provided on the distribution line, for controlling the circuit breaker on the distribution line. A current transformer for detecting a current of the current relay; and a current relay for opening the circuit breaker at the installation point when the current output of the current transformer detects a current value within an upper and lower set current value. A protection device for a distribution line, characterized in that it is set larger than the assumed accident current value when an accident occurs at the furthest point and smaller than the assumed accident current value when an accident occurs at the closest point. A distribution bus line connected to the power source, a distribution line connecting one side to the distribution busbar and the other to a load, a outlet breaker connecting the distribution line and the distribution busbar, and a plurality of circuit breakers provided at appropriate points on the distribution line. A protective device for a power distribution line, comprising: a voltage transformer for detecting a voltage at an installation point for controlling a circuit breaker on the power distribution line, and a circuit breaker for the installation point when the voltage transformer output detects a voltage below an operation setting voltage value. An open voltage relay is provided, and the operation set voltage value of each voltage relay is an assumed accident voltage value detected by the voltage transformer when an accident occurs at an adjacent load side breaker installation point, or an accident occurs at the furthest point of the distribution line. When the voltage is generated, it is set according to the assumed accident voltage value detected by the voltage transformer. Line protection device. A distribution bus line connected to the power source, a distribution line connecting one side to the distribution busbar and the other to a load, a outlet breaker connecting the distribution line and the distribution busbar, and a plurality of circuit breakers provided at appropriate locations on the distribution line. A protection device for a distribution line, comprising: a voltage transformer for detecting a voltage at an installation point for each circuit breaker on the distribution line, and a circuit breaker for the installation point when the voltage transformer output detects a voltage below an operation setting voltage value. And a voltage relay, and the operation set voltage value of each voltage relay is set as the distance from the power distribution bus is lower. A circuit breaker provided on a distribution line connecting one side to a distribution busbar and the other side to a load, and a current relay that opens the breaker, wherein the current relay has an inverse time characteristic for opening the breaker. Characteristic, characterized in that the current relay is modified according to the drop in the distribution line voltage of the installation point is installed. 7. The current relay according to claim 6, wherein the modification of the inverse time characteristic of the current relay reduces a sensitivity current. 7. The current relay according to claim 6, wherein the modification of the inverse time characteristic of the current relay shortens the operation time. A circuit protection device for a distribution line comprising a distribution bus line connected to a power source, a distribution line connecting one side to the distribution bus line and the other side to a load, and a circuit breaker provided at a suitable location on the distribution line. And a current transformer for detecting a current at the installation point, a voltage transformer for detecting a voltage, and a current relay for opening the circuit breaker after a time limit according to the inverse time characteristic when the current of the current transformer detects a current exceeding a set value. The inverse time characteristic of the relay is modified according to a drop in the distribution line voltage of the installation point detected by the voltage transformer. The protection device for a distribution line according to claim 9, wherein the modification of the inverse time characteristic of said current relay reduces a sensitivity current. 10. The protection apparatus for a distribution line according to claim 9, wherein the modification of the inverse time characteristic of said current relay shortens the operation time. A distribution line protection device comprising a distribution bus line connected to a power source, a distribution line connecting one side to the distribution bus line and the other side to a load, and a circuit breaker provided at a suitable place on the distribution line, in order to control the circuit breaker on the distribution line. And a current transformer for detecting a current at the installation point, a voltage transformer for detecting a voltage, and a current relay for opening the circuit breaker at the installation point after a time limit according to the inverse time characteristic when the current of the current transformer is greater than or equal to a set value. And when the voltage transformer detects a drop in the distribution line voltage, an opening command is applied to the circuit breaker at the installation point before the time limit determined by the inverse time characteristic of the current relay is exceeded. The forced circuit breaker opening command before the time limit, which is determined by the inverse time characteristic of the current relay, is set when the distribution line voltage detected by the voltage transformer decreases and the output of the current transformer is equal to or higher than a set value. Protective device for power distribution lines. A distribution line protection device comprising a distribution bus line connected to a power source, a distribution line connecting one side to the distribution bus line and the other side to a load, and a circuit breaker provided at a suitable location on the distribution line, in order to control the circuit breaker on the distribution line. A current transformer for detecting a current at the installation point, a voltage transformer for detecting a voltage, and a current relay for opening the circuit breaker at the installation point after a time limit according to the inverse time characteristic when the current of the current transformer is greater than or equal to a set value. When the voltage transformer detects a drop in the distribution line voltage, the opening command of the breaker at the installation point is applied before the time limit determined by the inverse time characteristic of the current relay, and until the opening command of the breaker is applied. The protection device for a distribution line, wherein the time becomes shorter as the drop in the distribution line voltage increases. A circuit protection device for a distribution line comprising a distribution bus line connected to a power source, a distribution line connecting one side to the distribution bus line and the other side to a load, and a circuit breaker provided at a suitable location on the distribution line, in order to control the circuit breaker on the distribution line. And a current transformer for detecting a current at the installation point, a voltage transformer for detecting a voltage, and a current relay for opening the circuit breaker at the installation point after a time limit according to the inverse time characteristic when the current of the current transformer is greater than or equal to a set value. When the voltage transformer detects a drop in the distribution line voltage, the sensitivity current of the inverse time characteristic of the current relay is reduced, and the magnitude of the sensitivity current is smaller as the drop in the distribution line voltage increases. Protection. A protective relay comprising a circuit breaker installed on a distribution line connecting one side to a distribution busbar and the other to a load, and a current relay to open the breaker, wherein the current relay is determined by the magnitude of the current at the breaker installation point. And an inverse time characteristic, wherein the inverse time characteristic of the current relay is corrected when the installation point voltage is lowered.

Images