JPS623655B2 - - Google Patents

Description

[Detailed Description of the Invention] The present invention makes it possible to selectively activate the fault display section on the power transmission side (or the opposite side) of the fault point in either case of forward power transmission or reverse power transmission. Regarding a distribution line ground fault detection device.

As a distribution line ground fault detection device, for example,
There is something like the one shown in the figure. Figure 1 shows the power transmission section 10.
a, 10b (power is transmitted from either one), and multi-circuit switches 11a, 1 located on the side of the power transmission section 10a.
1b, 11c, 11d, 11e, and power transmission section 10b
Multi-circuit switches 12a, 12b, 1 located on the side of
2c, 12d, 12e, and cabinet parts 13a, 13b...13n provided at each part of the distribution line and having switches for main lines, branch lines, and consumer lines,
Ground fault display sections 14a, 14b... provided adjacent to the cabinet sections 13a, 13b...13n.
...14n, and ground fault display parts 14a, 14b...
Zero-sequence voltage detector 15 that outputs zero-sequence voltage to 14n
a, 15b...15n and phase current detectors 16a, 16b...16n that supply ground fault current.

In the above configuration, when a ground fault occurs at point p of the distribution line, a ground fault current Io flows in the direction of the arrow, and the connection direction kl of the zero-sequence current detectors 16a, 16b...16n is in the direction of the ground fault current Io. Accident display part 1 that matches
Only 4a, 14b, . . . are activated, and their lamps (not shown) are lit. On the other hand, the fault display section 14 (n-
1), 14n does not operate, so the lamp does not light up. This allows the accident point P to be confirmed and the accident section to be isolated.

However, according to the conventional device, the power transmission section 10a
In the case of forward power transmission in which power is transmitted from the power transmission section 10b, the fault display sections 14a, 14b, . 14b... will operate on the side opposite to the power transmission section when viewed from the fault point P, so when confirming the fault point P, check the connection direction of the zero-sequence current detectors 16a, 16b...16n and the fault. Therefore, the fault point P could not be confirmed quickly.

In view of the above, the present invention enables confirmation of the fault point by selectively operating the fault display section on the power transmission side (or the opposite side) of the fault point in either case of forward power transmission or reverse power transmission. To provide a distribution line ground fault detection device that changes the connection direction of a zero-sequence current detector (the phase of the zero-sequence current or the phase of the zero-sequence voltage) according to the power transmission direction of the distribution line, in order to quickly perform the It is something.

The distribution line ground fault detection device of the present invention will be described in detail below.

FIG. 2 shows an embodiment of the present invention, in which a three-phase distribution line
Zero-sequence current detectors 1 each coupled to RST
6. Current transformers 17R, 17S, 17T, phase voltage detection unit 18, zero-sequence voltage detection unit 19, and a ground that is connected to the zero-sequence current detector 16 and zero-sequence voltage detection unit 19 to detect a ground fault. a fault detection circuit 20;
A power transmission direction detection circuit 21 is connected to the current transformer 17T and the phase voltage detection unit 18 and determines whether the power transmission direction is forward or reverse.It is connected to the phase voltage detection unit 18 and inputs the phase voltage of the RST phase to detect the three phases. A phase voltage detection circuit 22 that detects the presence or absence of voltage, and a short circuit current detection circuit 2 that is connected to the current transformers 17R and 17S and detects a short circuit accident.
3, a power supply circuit 24 that is connected to the current transformer 17T and provides power to each part, and each of the above-mentioned circuits 20 to 24.
The display circuit 25 is connected to a display circuit 25 for displaying a ground fault or short circuit accident.

The ground fault detection circuit 20 includes a zero-phase current detector 16
a transformer Tr ₁ connected to the transformer Tr 1, an amplifier 31 that amplifies the output of the transformer Tr ₁ , a rectangular wave converter circuit 32 that converts the output of the amplifier 31 into a rectangular wave, and a flip-flop which will be described later. A NAND circuit 33 receives the output of the reverse terminal RT of FF ₁ , an inverter 34 when the rectangular wave of the rectangular wave conversion circuit 32 is inverted, and a NAND circuit that receives the output of the inverter 34 and the output of the forward terminal FT of the flip-flop FF ₁ . 35, a NAND circuit 36 that receives the outputs of the NAND circuits 33 and 35, a level detection circuit 37 that outputs "1" when the output of the amplifier 31 reaches a predetermined value, and a NAND circuit 36 and a level detection circuit 37. a NAND circuit 38 receiving the output of
A phase delay circuit 39 that delays the output of the NAND circuit 38 by 90°, a transformer Tr ₂ connected to the zero-sequence voltage detection section 19, an amplifier 40 that amplifies the output of the transformer Tr ₂ , and a rectangular shape that outputs the output of the amplifier 40. A rectangular wave conversion circuit 41 that converts into a wave, a level detection circuit 42 that outputs "1" when the output of the amplifier 40 reaches a predetermined value, and receives the outputs of the rectangular wave conversion circuit 41 and the level detection circuit 42. NAND circuit 43 and NAND
A differentiator circuit 44 that differentiates the output of the circuit 43, a phase delay circuit 39, and a NAND circuit that receives the output of the differentiator circuit 44.
a circuit 45, a determination circuit 46 that determines the output of the NAND circuit 45 and outputs a determination signal, and a determination circuit 46.
It has a time limit circuit 47 that outputs a ground fault signal when the determination signal continues for, for example, 1.5 seconds.

Next, the power transmission direction detection circuit 21 includes a transformer Tr ₃ connected to the current transformer 17T, amplifiers 48 and 49 that amplify the output of the transformer Tr ₃ , and a rectangular wave conversion circuit that converts the output of the amplifier 48 into a rectangular wave. 50, a level detection circuit 51 that outputs "1" when the output of the amplifier 49 reaches a predetermined value, a NAND circuit 52 that receives the outputs of the rectangular wave conversion circuit 50 and the level detection circuit 51, and the NAND circuit 52. a differentiating circuit 53 that differentiates the output of the transformer Tr ₄ connected to the phase voltage detection section 18, amplifiers 54 and 55 that amplifies the output of the transformer Tr ₄ , and a rectangular wave that converts the output of the amplifier 54 into a rectangular wave. a conversion circuit 56 and an inverter 57 that inverts the output of the rectangular wave conversion circuit 56
and a level detection circuit 58 that outputs "1" when the output of the amplifier 55 reaches a predetermined value, and receives the outputs of the inverter 57 and the level detection circuit 58.
A NAND circuit 59, a phase delay circuit 60 that delays the output of the NAND circuit 59 by 90 degrees, a NAND circuit 61 that receives the outputs of the differentiating circuit 53 and the phase delay circuit 60, and
It has a determination circuit 62 that determines the output of the circuit 61 and outputs a determination signal, and a time limit circuit 63 that outputs "1" as a forward power transmission signal when the determination signal of the determination circuit 62 continues for 6 seconds, for example. are doing.

Further, the phase voltage detection circuit 22 includes the phase voltage detection section 1
Transformers Tr _{5 and} Tr 6 connected to 8 and Tr ₅ and Tr ₆
amplifiers 64 and 65 respectively amplifying the outputs of the
Level detection circuits 66, 67 that output "1" when the outputs of the amplifiers 64, 65 reach a predetermined value.
and a NOR circuit 68 that receives the outputs of the level detection circuit 58 and level detection circuits 66 and 67 described above.
It has an oscillation circuit 69 that outputs "1" at a constant frequency when the output of the NOR circuit 68 is "0".

Furthermore, the short circuit current detection circuit 23 is connected to the current transformer 17
Transformers Tr ₇ and Tr ₈ connected to R and 17S,
Amplifier 7 that amplifies the output of transformers Tr ₇ and Tr ₈
0, 71, level detection circuits 72, 73 that output "1" when the outputs of amplifiers 70, 71 reach predetermined levels, respectively, and level detection circuit 7.
NOR circuit 74 receiving the outputs of 2 and 73;
74 outputs "0" for a predetermined time, a time limit circuit 75 outputs "1".

The display circuit 25 which displays an accident in response to the signals from each of the circuits 20 to 23 described above includes a flip-flop FF ₁ (the above-mentioned forward feed terminal FT, reverse feed terminal RT ), NAND circuits 76 and 77 receiving the outputs of the ground fault detection circuit 20, flip-flop FF ₁ and phase voltage detection circuit 22, and phase voltage detection circuit 2
2 and a NAND that receives the output of the short circuit current detection circuit 23
circuit 78, an oscillation circuit 80 (90 minutes) that operates when switch 79 is turned on, and an oscillation circuit 82 (30 minutes) that operates when switch 81 (for testing) is turned on.
seconds) and receive the outputs of the oscillation circuits 80 and 82.
A NOR circuit 83, a counter circuit 85 that receives the output of the NOR circuit 83 and the output of an AND circuit 84 (described later), and a NOR circuit 86 that receives the inverted outputs of the NAND circuits 76 and 77 and the output of the counter circuit 85.
, a NAND circuit 87 receiving the output of the NOR circuit 86 and the output of the NAND circuit 78;
87, NAND circuits 77, 87, and three flip-flops FF ₂ , FF ₃ , FF ₄ receiving the outputs of NAND circuits 78, 87;
NAND circuit 8 receiving Q output of FF ₂ , FF ₃ , FF ₄
8, the inverted output of NAND circuit 87, and NAND circuit 8
8 _, and indicator lamps 89 (ground fault during forward power transmission), _{90 (} ground fault during reverse power transmission), and 91 (short circuit), and a switch 92 and a return circuit 93 for manually returning flip-flops FF ₂ , FF ₃ , and FF ₄ .

Power supply circuit 2 that provides power to each circuit described above
4 is an amplifier 94 that amplifies the output of the current transformer 17T.
, a charging circuit 96 that charges a battery 95 based on the output of the amplifier 94, and a constant voltage circuit 97 that causes the battery 95 to output a constant voltage.

In the configuration of the above ground fault detection circuit 20,
When a ground fault occurs and the zero-sequence current detector 16 detects a zero-sequence current, the amplifier circuit 31 amplifies it, and then the rectangular wave conversion circuit 32 converts it into a rectangular wave and outputs it. When the level of the zero-sequence current amplified by the amplifier circuit 31 exceeds the set level, the level detection circuit 37 outputs "1". During forward transmission, "1" is input to the FT terminal of the NAND circuit 35, and during reverse transmission,
Since "1" is input to the RT terminal of the NAND circuit 33, the NAND circuit 38 has a
Square waves with a 180° phase difference are output. This rectangular wave is delayed by 90 degrees by a phase delay circuit 39.

On the other hand, the zero-phase voltage detected by the zero-phase voltage detection section 19 is amplified by the amplifier circuit 40, and then converted into a rectangular wave by the rectangular wave conversion circuit 41 and converted to a set level. If it exceeds the value, the differentiating circuit 42 outputs "1".

When the differentiating circuit 42 outputs "1", the rectangular wave of the conversion circuit 41 is phase-shifted by 180 degrees by the NAND circuit 43. Since the differentiating circuit 44 differentiates this, a pulse is output at the rise of the phase-shifted rectangular wave, in other words, at the fall of the rectangular wave of the conversion circuit 41. The NAND circuit 45 receives this pulse from the phase delay circuit 3.
9 when the phase relationship is consistent with "1" of the rectangular wave in forward and reverse phase, it outputs "1" with "0" synchronized with the pulse output, and it does not match (that is, it matches "0" of the rectangular wave) ) Always outputs “1” when there is a phase relationship.

The determination circuit 46 outputs a determination signal "1" when a "1" having a "0" synchronized with the pulse of the differentiating circuit 44 is output based on the output of the NAND circuit 45. The determination signal "1" is output for 1.5 seconds, for example. When this continues, the timer circuit 47 outputs a ground fault signal.

Further, in the power transmission direction detection circuit 21, the current transformer 17T detects the load or charging current, and the phase voltage detection section 18 detects the phase voltage. If the level exceeds the set level after being amplified (by the amplifier circuits 48, 49, 54, 55)
The NAND circuits 52 and 59 output rectangular waves having a 180° phase difference. The rectangular wave of the NAND circuit 52 is differentiated by a differentiating circuit 53, and the rectangular wave of the NAND circuit 59 is delayed by 90 degrees by a phase delay circuit 60. When the pulse of the differentiating circuit 53 (detecting the rising edge of the rectangular wave) and the rectangular wave of the delay circuit 60 are input to the NAND circuit 61, and the NAND circuit 61 outputs "1" with "0" synchronized with the pulse. The determination circuit 62 outputs a determination signal "1". When the judgment signal "1" continues for 6 seconds, for example, the timer circuit 6
3 outputs a forward power transmission signal "1" representing the forward power transmission method (when the time limit circuit 63 is "0", it is the time of reverse power transmission).

Next, in the phase voltage detection circuit 22, each of the phase voltages detected by the phase voltage detection section 18 is detected by the amplifier circuit 5.
5, 64, 65, and if the level exceeds the set level, level detection circuits 58, 66, 6
7 outputs "1". Therefore, phase voltage detection section 1
8 detects a no-voltage state, the NOR circuit 68 inputs "0", "0", "0" and outputs "1". When the NOR circuit 68 outputs "1", the oscillation circuit 69 does not oscillate, and when it outputs "0", it oscillates at a constant frequency.

Further, in the short circuit current detection circuit 23, when the current transformer 17R or 17S detects an overcurrent, the amplifier circuits 70 and 71 amplify it. When the amplified level reaches the set level, the level detection circuit 7
2 or 73 outputs "1". When at least one of the level detection circuits 72 and 73 outputs "1", the NOR circuit 74 outputs "O", and after a certain period of time, the time limit circuit 75 operates and outputs "1".

In the above operation, when the time limit circuit 47 of the ground fault detection circuit 20, the time limit circuit 63 of the power transmission direction detection circuit 21, and the NOR circuit 68 of the phase power direction detection circuit 22 each output "1" (therefore, the oscillation circuit 69 does not oscillate), time limit circuit 63 “1”
In order to cause the flip-flop FF ₁ to output "1", "1", "1", "1" are input to the NAND circuit 76, and "0" is output from the NAND circuit 76.
This "0" and the "1" of the NAND circuit 87 that inputs the "0" of the NOR circuit 86 cause the Q terminal of flip-flop FF ₂ to become "0" and the terminal to "1", so that the potential of the negative terminal becomes When the value becomes "0", the display lamp 89 lights up (indicating a ground fault during forward power transmission). When the Q terminal of flip-flop FF ₂ becomes "0", the NAND circuit 88 outputs "1", and when the NOR circuit 86 outputs "1" due to accident recovery, the NAND circuit 87 outputs "0".
At this time, the AND circuit 84 outputs "1" and causes the counter circuit 85 to start counting time (the switch 79 is always on). The counter circuit 85 is
Counts the pulses of the oscillation circuit 80 via the NOR circuit 83, and outputs "1" when 90 minutes have elapsed.
The NAND circuit 87 is made to output "1". Due to this "1", the Q terminal of flip-flop FF ₂ returns to "1", the terminal returns to "0", and the display lamp 89
is turned off and the AND circuit 84 outputs "0", so that the counting operation of the counter circuit 85 is stopped. The operation of turning on and off the indicator lamp 90 during reverse power transmission is also carried out in the same way via the flip-flop FF ₃ , and the operation of turning on and turning off the indicator lamp 91 for a short circuit accident is also carried out in the same way via the flip-flop FF ₄ . Note that 94 is a switch for preparing the oscillation circuit 69 for testing.

As explained above, according to the distribution line ground fault detection device according to the present invention, since the connection direction of the zero-sequence current detector (the phase of the zero-sequence current) is changed depending on the power transmission direction of the distribution line, the forward power transmission In either case of power transmission or reverse power transmission, the fault point can be quickly confirmed by selectively operating the fault display section on the power transmission side (or the opposite side) of the fault point.

[Brief explanation of the drawing]

FIG. 1 is an explanatory diagram showing a conventional distribution line ground fault detection device. FIG. 2 is an explanatory diagram showing one embodiment of the present invention. Explanation of symbols, 16... Zero-phase current detector, 17
R, 17S, 17T...Current transformer, 18...Phase voltage detection unit, 19...Zero-sequence voltage detection unit, 20...Ground fault detection circuit, 21...Power transmission direction detection circuit, 22
... Phase voltage detection circuit, 23 ... Short circuit current detection circuit, 24 ... Power supply circuit, 25 ... Display circuit.

Claims (1)

[Claims] 1. A circuit for detecting a zero-sequence current; a circuit for detecting a zero-sequence voltage; a power transmission direction detection circuit for inputting line current and phase voltage to detect a power transmission direction; a circuit that outputs a phase-shifted zero-phase current or a phase-shifted zero-phase voltage obtained by shifting the phase of the zero-phase current or the zero-phase voltage by 180 degrees when the direction differs from a predetermined reference direction; and the zero-phase current or the phase-shifted zero-phase voltage. a circuit that outputs a ground fault signal based on a phase comparison between the current and the zero-sequence voltage, or a phase comparison between the zero-sequence voltage or the phase-shifted zero-sequence voltage and the zero-sequence current; and the ground fault signal. and a display circuit having a forward power transmission display section and a reverse power transmission display section that operate when the power transmission direction is in a predetermined reference direction and when it is different from the reference direction, respectively. Features: Distribution line ground fault detection device.