JP6419492B2 - Disconnection detection device, disconnection detection method, and disconnection section identification system - Google Patents

Description

  The present invention relates to a disconnection detection device, a disconnection detection method, and a disconnection section specifying system that detect disconnection of a distribution line.

  A disconnection detection device for detecting disconnection of a distribution line in a distribution network has been developed. For example, there is a method of detecting disconnection on the upstream side (power supply side) from the voltage detection point by detecting the voltage of each phase of the distribution line (for example, Patent Document 1). Further, there is a method of detecting a line current of each phase of the distribution line and detecting a disconnection on the downstream side (load side) based on the phase difference of each line current (for example, Patent Document 2).

JP 2007-282451 A JP 2009-81905 A

  For example, in order to divide the distribution line into three sections and detect the disconnection for each section, in the case of the disconnection detection device that detects the disconnection on the upstream side, the disconnection detection that detects the disconnection in each section respectively. Since a device is required, it is necessary to arrange three disconnection detection devices. That is, as shown in FIG. 16A, a disconnection detection device A101 for detecting disconnection in the first section of the distribution line, a disconnection detection device A102 for detecting disconnection in the second section, and the first It is necessary to arrange a disconnection detecting device A103 for detecting disconnection in three sections.

  The same applies to the disconnection detection device that detects the disconnection on the downstream side. That is, as shown in FIG. 16B, a disconnection detection device A201 for detecting a disconnection in the first section of the distribution line, a disconnection detection device A202 for detecting a disconnection in the second section, and the first It is necessary to arrange a disconnection detector A203 for detecting disconnection in the three sections.

  That is, in the case of the conventional disconnection detection device, it is necessary to arrange the disconnection detection devices by the number of sections to be detected.

  The present invention has been conceived under the circumstances described above, and an object of the present invention is to provide a disconnection detection device capable of reducing the number of lines arranged on a distribution line as compared with the prior art.

  In order to solve the above problems, the present invention takes the following technical means.

  The disconnection detection device provided by the first aspect of the present invention is a disconnection detection device for detecting disconnection of a distribution line, based on an electrical signal detected by an electrical signal detector disposed on the distribution line, Based on an electrical signal detected by the electrical signal detector and an upstream disconnection detecting means for detecting an upstream disconnection from a position where the electrical signal detector is disposed, and from a position where the electrical signal detector is disposed. And a downstream disconnection detecting means for detecting a downstream disconnection.

  In a preferred embodiment of the present invention, the downstream disconnection detecting means is a current that is a change vector of a line current vector based on a reference voltage for each phase based on the electrical signal detected by the electrical signal detector. A current change vector generating means for generating a change vector; and a downstream disconnection for determining whether or not a disconnection has occurred on the downstream side of the distribution line based on each current change vector generated by the current change vector generating means Determination means.

  In a preferred embodiment of the present invention, the current change vector generation means generates a line current vector for each phase based on the current signal detected by the electrical signal detector, and the voltage detected by the electrical signal detector. A vector generating means for generating a voltage vector for each phase based on the signal, and using the voltage vector for each phase, the line current vector for each phase is converted into a vector based on a reference voltage for each phase; And an arithmetic means for calculating a change vector of the line current vector of each phase after conversion.

  In a preferred embodiment of the present invention, the current change vector generation means generates a line current vector for each phase based on the current signal detected by the electrical signal detector, and the voltage detected by the electrical signal detector. A vector generation unit that generates a voltage vector of each phase based on the signal, a change vector of a line current vector of each phase generated by the vector generation unit, and a voltage vector of each phase generated by the vector generation unit And calculating means for converting the change vector into a vector based on a reference voltage for each phase.

  In a preferred embodiment of the present invention, the reference voltage for each phase is a phase voltage of each phase.

  In a preferred embodiment of the present invention, the reference voltage for each phase is a line voltage of each phase.

In a preferred embodiment of the present invention, the downstream disconnection judging means is configured such that each current change vector generated by the current change vector generating means is
(1) A phase difference of a current change vector of a phase whose phase advances with respect to a current change vector of a certain phase, and a current change vector of the certain phase with respect to a current change vector of a phase whose phase is later than the certain phase Of the first threshold value θ ₁ or more and the second threshold value θ ₂ or less, respectively.
(2) the magnitudes of all current change vectors are greater than or equal to a predetermined threshold I ₀ ;
(3) Not applicable when all of the following (3-1) to (3-2) are satisfied,
(3-1) The phase difference between the current change vector having the maximum size among the current change vectors and the other current change vectors is about 60 °, respectively.
(3-2) The magnitude of the maximum current change vector is about twice the magnitude of the other current change vectors.
If all the conditions are satisfied, it is determined that a disconnection has occurred.

In a preferred embodiment of the present invention, the first threshold value θ ₁ is 5 ° to 30 °.

In a preferred embodiment of the present invention, the second threshold value θ ₂ is 150 ° to 180 °.

In a preferred embodiment of the present invention, the predetermined threshold value I ₀ is several amperes.

In a preferred embodiment of the present invention, further comprising a zero-phase voltage detecting means for detecting a zero-phase voltage, the downstream disconnection judging means, in addition to the conditions (1) to (3)
(4) The zero-phase voltage is not less than a predetermined threshold value V ₀ .
If all the conditions are satisfied, it is determined that a disconnection has occurred.

  In a preferred embodiment of the present invention, the upstream disconnection detecting means includes an effective value calculating means for calculating an effective value of each line voltage based on the electric signal detected by the electric signal detector, and the effective value. Upstream disconnection determination means for determining whether a disconnection has occurred on the upstream side of the distribution line based on the effective value of each line voltage calculated by the calculation means.

  The disconnection section specifying system provided by the second aspect of the present invention includes a plurality of disconnection detection devices provided by the first aspect of the present invention disposed on a distribution line, and the disconnection detection device detects disconnection. And a management device that transmits information about the disconnection by communication from the disconnection detection device when detected, and the management device generates a disconnection of the distribution line based on the received information about the disconnection It is characterized by specifying the section which was performed.

  The disconnection detection method provided by the third aspect of the present invention is a disconnection detection method for detecting disconnection of a distribution line, wherein the electrical signal detector disposed on the distribution line detects an electrical signal. A second step of detecting a disconnection downstream of a position where the electric signal detector is disposed based on the electric signal detected in the first step, and a step detected in the first step. And a third step of detecting a disconnection upstream of the position where the electrical signal detector is disposed based on the electrical signal.

  According to the present invention, the upstream disconnection detecting means can detect the disconnection on the upstream side of the distribution line, and the downstream disconnection detecting means can detect the disconnection on the downstream side of the distribution line. That is, the disconnection detection apparatus according to the present invention can detect a disconnection on the upstream side of the arrangement location, and can also detect a disconnection on the downstream side of the arrangement location. Therefore, the number arranged in the distribution line can be reduced from the disconnection detection device that detects only the upstream or downstream disconnection.

  Other features and advantages of the present invention will become more apparent from the detailed description given below with reference to the accompanying drawings.

It is a figure for demonstrating the disconnection detection apparatus which concerns on 1st Embodiment. It is a figure for demonstrating the case where the connection of a transformer is (DELTA) delta connection. It is a figure for demonstrating the state which a disconnection generate | occur | produced. It is a figure for demonstrating the state which the single phase load fluctuation | variation generate | occur | produced. It is a figure for demonstrating the state which the three-phase load fluctuation | variation generate | occur | produced. It is a figure for demonstrating the case where the connection of a transformer is (DELTA) Y connection. It is a figure which shows the vector at the time of load fluctuation. It is a figure for demonstrating the case where the connection of a transformer is a Ydelta connection. It is a figure which shows the vector at the time of load fluctuation. It is a figure for demonstrating arrangement | positioning to the distribution line of the disconnection detection apparatus which concerns on 1st Embodiment. It is a figure for demonstrating arrangement | positioning to the distribution line of the disconnection detection apparatus which concerns on 1st Embodiment, and the conventional disconnection detection apparatus. It is a figure for demonstrating the state which the two-phase load fluctuation | variation generate | occur | produced. It is a figure which shows the vector at the time of two-phase load fluctuation | variation. It is a figure for demonstrating the disconnection detection apparatus which concerns on 2nd Embodiment. It is a figure for demonstrating a disconnection area identification system. It is a figure for demonstrating arrangement | positioning to the distribution line of the conventional disconnection detection apparatus.

  Embodiments of the present invention will be specifically described below with reference to the drawings.

  FIG. 1 is a diagram for explaining the disconnection detection apparatus A according to the first embodiment, and shows a state where the disconnection detection apparatus A is arranged on a three-phase distribution line. The three phases consist of an a phase, a b phase, and a c phase. The b phase current is delayed in phase from the a phase current, and the c phase current is advanced in phase from the a phase current.

  The disconnection detection device A detects disconnection of the distribution line. This embodiment demonstrates the case where the disconnection detection apparatus A detects the disconnection of the three-phase distribution line which consists of the a-phase distribution line a, the b-phase distribution line b, and the c-phase distribution line c.

Loads are connected between the distribution lines a, b, and c via the transformer B, respectively. A load Lab is connected between the distribution line a and the distribution line b, a load Lbc is connected between the distribution line b and the distribution line c, and a load Lca is connected between the distribution line c and the distribution line a. Is connected. An instrumental current transformer CT1 is disposed on the distribution line a, an instrumental current transformer CT2 is disposed on the distribution line b, and an instrumental current transformer CT3 is disposed on the distribution line c. . The instrument current transformers CT1, CT2 and CT3 detect currents flowing through the respective distribution lines. Current signals i _a , i _b , and _ic detected by the instrument current transformers CT1, CT2, and CT3, respectively, are input to the disconnection detection device A. Instead of the instrument current transformers CT1, CT2, CT3, other current detection devices (for example, photocurrent measurement) may be used. An instrument transformer PT1 is arranged between the distribution line a and the distribution line b, and an instrument transformer PT2 is arranged between the distribution line b and the distribution line c. An instrument transformer PT3 is disposed between c and the distribution line a. The instrument transformers PT1, PT2, PT3 detect line voltages between the distribution lines, respectively. The voltage signals v _ab , v _bc and v _ca detected by the instrument transformers PT1, PT2 and PT3 are input to the disconnection detection device A. Instead of the instrument transformers PT1, PT2, PT3, other voltage detection devices (for example, capacitor partial pressure) may be used.

  Circuit breakers CB1, CB2, CB3 are provided downstream of the instrument current transformers CT1, CT2, CT3 and the instrument transformers PT1, PT2, PT3. The circuit breakers CB1, CB2, and CB3 block currents flowing through the distribution lines a, b, and c, respectively, in response to the disconnection command input from the disconnection detection device A. The circuit breakers CB1, CB2, and CB3 may be provided upstream of the instrument current transformers CT1, CT2, and CT3 and the instrument transformers PT1, PT2, and PT3.

Breaking detection device A, the current transformer CT1, CT2, the current signal is input from each _{CT3 i a, i b, i} c, and a voltage signal are input from the potential transformer PT1, PT2, PT3 A disconnection is detected based on v _ab , v _{bc, and} v _ca, and a disconnection command for opening the circuit breakers CB1, CB2, and CB3 that are normally closed is output. The disconnection detection device A includes a current change vector generation unit 1, a downstream disconnection determination unit 2, an effective value calculation unit 3, an upstream disconnection determination unit 4, an interruption command unit 5, and a communication unit 6.

The current change vector generation unit 1 generates a line current vector change vector for each phase voltage reference based on the input voltage signals v _ab , v _bc, v _ca and the current signals i _a , i _{b, ic.} Output. The current change vector generation unit 1 includes a vector generation unit 11, a calculation unit 12, and a storage unit 13.

The vector generation unit 11 generates a line current vector and a line voltage vector for each phase. The a-phase line current vector is Ia, the b-phase line current vector is Ib, the c-phase line current vector is Ic, the a-phase line voltage vector for the b-phase is Vab, and the b-phase line-to-c phase The voltage vector is represented as Vbc, and the line voltage vector of the c phase with respect to the a phase is represented as Vca. The vector generation unit 11 converts the current signals i _a , i _b , and _ic input from the instrument current transformers CT1, CT2, and CT3, respectively, into digital signals, removes harmonic components with a low-pass filter, and amplitudes respectively. And the phase are detected, and line current vectors Ia, Ib, and Ic are generated based on these. The vector generation unit 11 converts the voltage signals v _ab , v _bc , and v _ca input from the instrument transformers PT1, PT2, and PT3, respectively, into digital signals, removes harmonic components with a low-pass filter, The amplitude and phase are detected, and line voltage vectors Vab, Vbc, Vca are generated based on these. The vector generation unit 11 outputs the generated line current vectors Ia, Ib, Ic and the line voltage vectors Vab, Vbc, Vca to the calculation unit 12.

  The calculation unit 12 converts the line current vectors Ia, Ib, and Ic input from the vector generation unit 11 into vectors based on each phase voltage, and generates and outputs a change vector. The calculation unit 12 converts the line current vectors Ia, Ib, and Ic input from the vector generation unit 11 into vectors for each line voltage reference using the line voltage vectors Vab, Vbc, and Vca, and the phase is 30 °. By delaying, it is converted to a vector based on each phase voltage. Then, the line current vectors Ia, Ib, and Ic converted into the respective phase voltage reference vectors are stored in the storage unit 13, and the line current vector before a predetermined time (for example, several tens of milliseconds) is read from the storage unit 13. . The calculation unit 12 inputs the line current vectors Ia, Ib, Ic input from the vector generation unit 11 and converted into vectors based on the respective phase voltages to the line current vectors Ia ′, Ib ′, Current change vectors ΔIa (= Ia′−Ia), ΔIb (= Ib′−Ib), and ΔIc (= Ic′−Ic) are calculated by subtracting from Ic ′ and output to downstream disconnection determination unit 2. .

  Note that when the line current vectors Ia, Ib, and Ic are converted into vectors based on the respective line voltages, for example, the line current vector Ib is converted with reference to the line voltage vector Vab. The phase of the current vector Ic may be delayed by 120 °. In addition, first, change vectors of the line current vectors Ia, Ib, and Ic may be generated, converted into vectors for each phase voltage reference, and output.

  Note that the configuration of the current change vector generation unit 1 is not limited to that described above, and any configuration that generates the current change vectors ΔIa, ΔIb, ΔIc based on each phase voltage may be used. Further, an analog filter may be provided before the vector generation unit 11. The vector generation unit 11 generates line current vectors Ia, Ib, Ic and line voltage vectors Vab, Vbc, Vca every predetermined time, and the calculation unit 12 inputs the line current vectors Ia ′, Ib ′, The current change vectors ΔIa, ΔIb, ΔIc may be calculated from Ic ′ and the line current vectors Ia, Ib, Ic input this time.

  The downstream disconnection determination unit 2 determines the occurrence of disconnection on the downstream side (load side) from the position where the instrument current transformers CT1, CT2, CT3 and the instrument transformers PT1, PT2, PT3 are arranged, and the disconnection occurs. The distribution line is identified, and is realized by, for example, a microcomputer. The downstream disconnection determination unit 2 makes a determination based on the current change vectors ΔIa, ΔIb, ΔIc of each phase voltage reference input from the current change vector generation unit 1. The downstream disconnection determination unit 2 determines that a disconnection has occurred on the downstream side when the current change vectors ΔIa, ΔIb, and ΔIc of each phase voltage reference satisfy a predetermined condition. When the downstream disconnection determination unit 2 determines that the disconnection has occurred on the downstream side, the disconnection command unit 5 and the communication unit 6 inform the disconnection command unit 5 and the communication unit 6 that the disconnection has occurred on the downstream side and the information on the distribution line in which the disconnection has occurred. Output.

  Below, the conditions for the downstream disconnection judgment part 2 to judge a downstream disconnection are demonstrated.

  If no disconnection occurs on the downstream side and the load connected to the distribution line does not change, the line current vectors Ia, Ib, and Ic do not change. Therefore, the current change vectors ΔIa, ΔIb, and ΔIc (reference values for each phase voltage) Hereinafter, “vectors ΔIa, ΔIb, ΔIc” are all zero vectors. When the disconnection occurs on the downstream side, the line current vectors Ia, Ib, and Ic change, so the vectors ΔIa, ΔIb, and ΔIc also change. However, the vectors ΔIa, ΔIb, ΔIc also change when the load connected between the distribution lines of each phase varies. The downstream disconnection determination unit 2 determines that a disconnection has occurred on the downstream side from the characteristics of the vectors ΔIa, ΔIb, and ΔIc. Specifically, the downstream disconnection determination unit 2 conditionally stores the characteristics of the vectors ΔIa, ΔIb, ΔIc when the disconnection occurs on the downstream side, and the vectors ΔIa, ΔIb, ΔIc match the conditions. By determining whether or not to do so, the occurrence of a disconnection on the downstream side is determined.

  The connection of the transformer B (see FIG. 1) interposed between the distribution line and the load includes a ΔΔ connection, a YY connection, a ΔY connection, a YΔ connection, and the like. In this embodiment, the disconnection can be determined regardless of the connection of the transformer B.

FIG. 2 shows a case where the connection of the transformer B is a ΔΔ connection, and FIG. 2A shows the transformer B and the load connected to the distribution lines a, b, and c shown in FIG. Yes. In FIG. 2A, the current vector flowing through the load Lab is Iab, the current vector flowing through the load Lbc is Ibc, and the current vector flowing through the load Lca is Ica. As shown in FIG. 2A, the line current vector Ia of the a-phase distribution line a, the line current vector Ib of the b-phase distribution line b, and the line current vector Ic of the c-phase distribution line c are respectively
Ia = Iab-Ica
Ib = Ibc-Iab
Ic = Ica-Ibc
It becomes. For convenience of calculation, the transformation ratio of the transformer B is “1”. When the transformation ratio is not “1”, the vectors ΔIa, ΔIb, and ΔIc are obtained by dividing the magnitude by the transformation ratio, but the conditions are the same regardless of whether the line is disconnected or the load is changed. , ΔIb, ΔIc are respectively divided by the transformation ratio. Therefore, there is no problem even if the transformation ratio is calculated as “1”.

FIG. 2 (b) shows current and voltage vectors in a three-phase equilibrium state. The phase voltage vector Va of the a phase, the phase voltage vector Vb of the b phase, and the phase voltage vector Vc of the c phase are 120 degrees apart from each other (indicated by a thick arrow in FIG. 2B). . The a-phase line voltage vector Vab for the b-phase, the b-phase line voltage vector Vbc for the c-phase, and the c-phase line voltage vector Vca for the a-phase are respectively
Vab = Va−Vb
Vbc = Vb−Vc
Vca = Vc−Va
(Indicated by broken-line arrows in FIG. 2 (b)). Assuming that the current is advanced in phase θ from the voltage, current vectors Iab, Ibc, and Ica are indicated by thin line arrows in FIG.

となり、ｂ相の相電圧ベクトルＶｂを基準にして、電流ベクトルＩａｂ，Ｉｂｃ，Ｉｃａを表すと、

となり、ｃ相の相電圧ベクトルＶｃを基準にして、電流ベクトルＩａｂ，Ｉｂｃ，Ｉｃａを表すと、

となる。 When current vectors Iab, Ibc, and Ica are expressed with reference to phase voltage vector Va of a phase,

When current vectors Iab, Ibc, and Ica are expressed with reference to phase voltage vector Vb of b phase,

When current vectors Iab, Ibc, and Ica are expressed with reference to phase voltage vector Vc of c phase,

It becomes.

FIG. 3A shows a state in which a disconnection occurs in the a-phase distribution line a. When disconnection occurs in the distribution line a, no current flows through the distribution line a, so the line current vector Ia becomes a zero vector. The same current flows through the loads Lab and Lca, and this current vector is a vector having the same phase and different magnitude as the current vector Ibc, and can be expressed as αIbc. Therefore,
Ia = 0
Ib = Ibc + αIbc
Ic = −Ibc−αIbc
It becomes.

となる。 Therefore, the current change vectors ΔIa, ΔIb, ΔIc before and after the disconnection are
ΔIa = (Iab−Ica) − (0) = Iab−Ica
ΔIb = (Ibc−Iab) − (Ibc + αIbc) = − Iab−αIbc
ΔIc = (Ica−Ibc) − (− Ibc−αIbc) = Ica + αIbc
And expressed with reference to the phase voltage vector of each phase,

It becomes.

となる。実際の電力系統では、断線時に電圧不足による停電のため、αは「０」に近い値になる。図３（ｂ）は、断線時のベクトルΔＩａ，ΔＩｂ，ΔＩｃを示したものである。 When the line current vector based on each phase voltage is set to I and the vectors βVa, βVb, βVc are replaced with the vector I, respectively,

It becomes. In an actual power system, α becomes a value close to “0” due to a power failure due to insufficient voltage at the time of disconnection. FIG. 3B shows vectors ΔIa, ΔIb, ΔIc at the time of disconnection.

  Next, vectors ΔIa, ΔIb, ΔIc at the time of single-phase load fluctuation will be described.

FIG. 4A represents a single-phase load fluctuation and shows a state where the load Lab is disconnected. In this case, as is apparent from FIG.
Ia = -Ica
Ib = Ibc
Ic = Ica-Ibc
It becomes.

となる。 Therefore, the current change vectors ΔIa, ΔIb, ΔIc before and after the load change are
ΔIa = (Iab−Ica) − (− Ica) = Iab
ΔIb = (Ibc−Iab) − (Ibc) = − Iab
ΔIc = (Ica−Ibc) − (Ica−Ibc) = 0
And expressed with reference to the phase voltage vector of each phase,

It becomes.

となる。図４（ｂ）は、単相負荷変動時のベクトルΔＩａ，ΔＩｂ，ΔＩｃを示したものである。 When the line current vector based on each phase voltage is set to I and the vectors βVa, βVb, βVc are replaced with the vector I, respectively,

It becomes. FIG. 4B shows the vectors ΔIa, ΔIb, ΔIc when the single-phase load fluctuates.

  Next, vectors ΔIa, ΔIb, ΔIc at the time of three-phase load fluctuation will be described.

FIG. 5A shows a three-phase load fluctuation, and shows a state where the loads Lab, Lbc, and Lca are disconnected. In this case, as is apparent from FIG.
Ia = 0
Ib = 0
Ic = 0
It becomes.

となる。 Therefore, the current change vectors ΔIa, ΔIb, ΔIc before and after the load change are
ΔIa = (Iab−Ica) − (0) = Iab−Ica
ΔIb = (Ibc−Iab) − (0) = Ibc−Iab
ΔIc = (Ica−Ibc) − (0) = Ica−Ibc
And expressed with reference to the phase voltage vector of each phase,

It becomes.

となる。図５（ｂ）は、三相負荷変動時のベクトルΔＩａ，ΔＩｂ，ΔＩｃを示したものである。 When the line current vector based on each phase voltage is set to I and the vectors βVa, βVb, βVc are replaced with the vector I, respectively,

It becomes. FIG. 5B shows the vectors ΔIa, ΔIb, ΔIc when the three-phase load fluctuates.

  Next, the case where the connection of the transformer B is a ΔY connection will be described.

FIG. 6 shows a case where the connection of the transformer B is a ΔY connection, and FIG. 6A shows the transformer B and the load connected to the distribution lines a, b, and c shown in FIG. Yes. Similarly to FIG. 2A, in FIG. 6A, the vector of current flowing through the load Lab is Iab, the vector of current flowing through the load Lbc is Ibc, and the vector of current flowing through the load Lca is Ica. As shown in FIG. 6A, the line current vector Ia of the a-phase distribution line a, the line current vector Ib of the b-phase distribution line b, and the line current vector Ic of the c-phase distribution line c are respectively
Ia = Iab + Ibc-2Ica
Ib = Ibc + Ica-2Iab
Ic = Ica + Iab-2Ibc
It becomes.

FIG. 6B shows current and voltage vectors in a three-phase equilibrium state. The phase voltage vector Va of the a phase, the phase voltage vector Vb of the b phase, and the phase voltage vector Vc of the c phase are 120 degrees apart from each other (indicated by a thick arrow in FIG. 6B). . The a-phase line voltage vector Vab for the b-phase, the b-phase line voltage vector Vbc for the c-phase, and the c-phase line voltage vector Vca for the a-phase are respectively
Vab = Va−Vb
Vbc = Vb−Vc
Vca = Vc−Va
(Indicated by broken-line bold arrows in FIG. 6B). The voltage vector applied to the load Lab is Vab ′, the voltage vector applied to the load Lbc is Vbc ′, the voltage vector applied to the load Lca is Vca ′, and the phase is 30 with respect to the line voltage vectors Vab, Vbc, Vca, respectively. Go forward. Assuming that the current is advanced in phase θ from the voltage, current vectors Iab, Ibc, and Ica are indicated by thin line arrows in FIG.

となり、ｂ相の相電圧ベクトルＶｂを基準にして、電流ベクトルＩａｂ，Ｉｂｃ，Ｉｃａを表すと、

となり、ｃ相の相電圧ベクトルＶｃを基準にして、電流ベクトルＩａｂ，Ｉｂｃ，Ｉｃａを表すと、

となる。 When current vectors Iab, Ibc, and Ica are expressed with reference to phase voltage vector Va of a phase,

When current vectors Iab, Ibc, and Ica are expressed with reference to phase voltage vector Vb of b phase,

When current vectors Iab, Ibc, and Ica are expressed with reference to phase voltage vector Vc of c phase,

It becomes.

  When the connection of the transformer B is the ΔY connection, the vectors ΔIa, ΔIb, ΔIc at the time of the disconnection are the same as those in FIG.

  Next, vectors ΔIa, ΔIb, ΔIc at the time of single-phase load fluctuation will be described.

When the load Lab is disconnected and Iab = 0,
Ia = Ibc-2Ica
Ib = Ibc + Ica
Ic = Ica-2Ibc
It becomes.

となる。 Therefore, the current change vectors ΔIa, ΔIb, ΔIc before and after the load change are
ΔIa = (Iab + Ibc-2Ica) − (Ibc-2Ica) = Iab
ΔIb = (Ibc + Ica−2Iab) − (Ibc + Ica) = − 2Iab
ΔIc = (Ica + Iab−2Ibc) − (Ica−2Ibc) = Iab
And expressed with reference to the phase voltage vector of each phase,

It becomes.

となる。図７（ａ）は、単相負荷変動時のベクトルΔＩａ，ΔＩｂ，ΔＩｃを示したものである。 When the line current vector based on each phase voltage is set as I and the vectors γVa, γVb, and γVc are replaced with the vector I, respectively,

It becomes. FIG. 7A shows the vectors ΔIa, ΔIb, ΔIc when the single-phase load fluctuates.

  Next, vectors ΔIa, ΔIb, ΔIc at the time of three-phase load fluctuation will be described.

When the loads Lab, Lbc, and Lca are disconnected,
Ia = 0
Ib = 0
Ic = 0
It becomes.

となる。 Therefore, the current change vectors ΔIa, ΔIb, ΔIc before and after the load change are
ΔIa = (Iab + Ibc−2Ica) − (0) = − 3Ica
ΔIb = (Ibc + Ica−2Iab) − (0) = − 3Iab
ΔIc = (Ica + Iab−2Ibc) − (0) = − 3Ibc
And expressed with reference to the phase voltage vector of each phase,

It becomes.

となる。図７（ｂ）は、三相負荷変動時のベクトルΔＩａ，ΔＩｂ，ΔＩｃを示したものである。 When the line current vector based on each phase voltage is set as I and the vectors γVa, γVb, and γVc are replaced with the vector I, respectively,

It becomes. FIG. 7B shows the vectors ΔIa, ΔIb, ΔIc when the three-phase load fluctuates.

  Next, a case where the connection of the transformer B is a YΔ connection will be described.

FIG. 8 shows a case where the connection of the transformer B is a YΔ connection, and FIG. 8A shows the transformer B and the load connected to the distribution lines a, b, and c shown in FIG. Yes. Similarly to FIG. 2A, in FIG. 8A, the current vector flowing through the load Lab is Iab, the current vector flowing through the load Lbc is Ibc, and the current vector flowing through the load Lca is Ica. As shown in FIG. 8A, the line current vector Ia of the a-phase distribution line a, the line current vector Ib of the b-phase distribution line b, and the line current vector Ic of the c-phase distribution line c are respectively
Ia = (2/3) Iab- (1/3) Ibc- (1/3) Ica
Ib = (2/3) Ibc- (1/3) Ica- (1/3) Iab
Ic = (2/3) Ica- (1/3) Iab- (1/3) Ibc
It becomes.

  FIG. 8B shows vectors of currents and voltages in a three-phase equilibrium state. The phase voltage vector Va of the a phase, the phase voltage vector Vb of the b phase, and the phase voltage vector Vc of the c phase are 120 degrees apart from each other (indicated by a thick line arrow in FIG. 8B). . The a-phase line voltage vector Vab for the b-phase, the b-phase line voltage vector Vbc for the c-phase, and the c-phase line voltage vector Vca for the a-phase are equal to the phase voltage vectors Va, Vb, and Vc, respectively. . Assuming that the current is advanced in phase θ from the voltage, current vectors Iab, Ibc, Ica are indicated by thin line arrows in FIG.

となり、ｂ相の相電圧ベクトルＶｂを基準にして、電流ベクトルＩａｂ，Ｉｂｃ，Ｉｃａを表すと、

となり、ｃ相の相電圧ベクトルＶｃを基準にして、電流ベクトルＩａｂ，Ｉｂｃ，Ｉｃａを表すと、

となる。 When current vectors Iab, Ibc, and Ica are expressed with reference to phase voltage vector Va of a phase,

When current vectors Iab, Ibc, and Ica are expressed with reference to phase voltage vector Vb of b phase,

When current vectors Iab, Ibc, and Ica are expressed with reference to phase voltage vector Vc of c phase,

It becomes.

  Even when the connection of the transformer B is the YΔ connection, the vectors ΔIa, ΔIb, ΔIc at the time of the disconnection are the same as those in FIG.

  Next, vectors ΔIa, ΔIb, ΔIc at the time of single-phase load fluctuation will be described.

When the load Lab is disconnected and Iab = 0,
Ia =-(1/3) Ibc- (1/3) Ica
Ib = (2/3) Ibc- (1/3) Ica
Ic = (2/3) Ica- (1/3) Ibc
It becomes.

となる。 Therefore, the current change vectors ΔIa, ΔIb, ΔIc before and after the load change are
ΔIa = (2/3) Iab− (1/3) Ibc− (1/3) Ica) − (− (1/3) Ibc− (1/3) Ica) = (2/3) Iab
ΔIb = ((2/3) Ibc− (1/3) Ica− (1/3) Iab) − ((2/3) Ibc − ((1/3)) Ica) = − (1/3) Iab
ΔIc = ((2/3) Ica− (1/3) Iab− (1/3) Ibc) − ((2/3) Ica− (1/3) Ibc) = − (1/3) Iab
And expressed with reference to the phase voltage vector of each phase,

It becomes.

となる。図９（ａ）は、単相負荷変動時のベクトルΔＩａ，ΔＩｂ，ΔＩｃを示したものである。 When the line current vector based on each phase voltage is set to I and the vectors εVa, εVb, and εVc are replaced with the vector I, respectively,

It becomes. FIG. 9A shows the vectors ΔIa, ΔIb, ΔIc when the single-phase load fluctuates.

  Next, vectors ΔIa, ΔIb, ΔIc at the time of three-phase load fluctuation will be described.

When the loads Lab, Lbc, and Lca are disconnected,
Ia = 0
Ib = 0
Ic = 0
It becomes.

となる。 Therefore, the current change vectors ΔIa, ΔIb, ΔIc before and after the load change are
ΔIa = ((2/3) Iab− (1/3) Ibc− (1/3) Ica) − (0) = Iab
ΔIb = ((2/3) Ibc− (1/3) Ica− (1/3) Iab) − (0) = Ibc
ΔIc = ((2/3) Ica− (1/3) Iab− (1/3) Ibc) − (0) = Ica
And expressed with reference to the phase voltage vector of each phase,

It becomes.

となる。図９（ｂ）は、三相負荷変動時のベクトルΔＩａ，ΔＩｂ，ΔＩｃを示したものである。 When the line current vector based on each phase voltage is set to I and the vectors εVa, εVb, and εVc are replaced with the vector I, respectively,

It becomes. FIG. 9B shows the vectors ΔIa, ΔIb, ΔIc when the three-phase load fluctuates.

  When the connection of the transformer B is the YY connection, it is the same as the case of the ΔΔ connection. It should be noted that the two-phase load fluctuation occurs only in a very special state and hardly occurs in practice, and therefore, this embodiment does not assume a case where the two-phase load fluctuation occurs.

  As described above, the vectors ΔIa, ΔIb, and ΔIc have a case where a disconnection occurs on the downstream side (see FIG. 3B) and a case where a load change occurs (see FIGS. 4B and 5B). 7 (a), 7 (b), 9 (a), and 9 (b)), the vectors are different. When the vectors ΔIa, ΔIb, ΔIc become the vectors shown in FIG. 3B, it can be determined that a disconnection has occurred on the downstream side. However, when the load fluctuates, there is no problem considering that the load is approximately balanced. However, when the downstream disconnection occurs, the load on the load side from the disconnection point is not always balanced, as shown in FIG. Deviations from the vector diagram may occur. It is also necessary to take into account that measurement errors occur in the instrument current transformers CT1, CT2, CT3 or the instrument transformers PT1, PT2, PT3. That is, even if these errors are included, the vectors ΔIa, ΔIb, ΔIc are the vectors shown in FIG. 3B, and FIG. 4B, FIG. 5B, FIG. It is necessary to set conditions that can be determined not to be the vectors shown in (b) and FIGS. 9 (a) and 9 (b).

In the present embodiment, the following conditions are set as conditions for determining the occurrence of downstream disconnection.
(1) Phase difference of a phase voltage reference current change vector of a phase whose phase is advanced from a phase with respect to a current change vector of a phase voltage reference of a phase, and a phase voltage reference current change of a phase lagging a phase The phase difference of the current change vector based on the phase voltage of a certain phase with respect to the vector is not less than the first threshold θ _{1 and not} more than the second threshold θ ₂ .
(2) The magnitude of the current change vector based on the phase voltage of all phases is equal to or greater than a predetermined threshold value I ₀ .
(3) Not applicable if all of the following conditions are met.
(3-1) The phase difference between the vector having the largest magnitude among the current change vectors based on the phase voltage of each phase and the other vectors is about 60 °.
(3-2) The size of the maximum vector is about twice the size of the other vectors.

In the present embodiment, a value of 5 ° to 30 ° is set as the first threshold θ ₁ , a value of 150 ° to 180 ° is set as the second threshold θ ₂ , and a value of several amperes is set as the predetermined threshold I _0. Is set.

The above condition (1) is, for example, "certain phase" when the a-phase, with respect to the current change vector of the phase voltage reference a phase, the phase difference is theta ₁ through? ₂ of the current change vector of the phase voltage reference c phase And the phase difference of the current change vector of the a-phase phase voltage reference to the current change vector of the b-phase phase voltage reference is in the range of θ ₁ to θ ₂ .

  The condition (3) is that the condition does not correspond to the vectors shown in FIGS. 7 (a) and 9 (a). When no power failure occurs due to disconnection, that is, when α is (1/2), the vector shown in FIG. 3B and the vectors shown in FIGS. 7A and 9A can be discriminated. difficult. However, it is unlikely that no power outage will occur in the actual system. Therefore, if the vectors ΔIa, ΔIb, ΔIc correspond to the vectors shown in FIG. 7A or FIG. 9A, there is no problem even if it is determined that the load is not a disconnection but a load change. In the present embodiment, the condition (3-1) is determined based on whether each phase difference is within a range of 60 ° ± 5 °. Further, it is determined whether or not the condition (3-2) is within a range of 1.9 to 2 times.

  The conditions (1) to (3) described above are examples of conditions for determining the occurrence of downstream disconnection, and the conditions set in the downstream disconnection determination unit 2 are not limited thereto. The conditions for determining the occurrence of the downstream disconnection are based on the case where the disconnection occurs on the downstream side (see FIG. 3B) based on the vectors ΔIa, ΔIb, ΔIc, and the case where a load change occurs (see FIG. 3). 4 (b), Fig. 5 (b), Fig. 7 (a), (b), Fig. 9 (a), (b)) may be used.

  The downstream disconnection determination unit 2 generates a disconnection on the downstream side of the distribution line when the vectors ΔIa, ΔIb, ΔIc input from the current change vector generation unit 1 satisfy all the above conditions (1) to (3). Judge.

  In the above description, the vector diagrams of the vectors ΔIa, ΔIb, and ΔIc when the loads are disconnected as the load fluctuation occurs (FIGS. 4B, 5B, 7A, and 7) ( b) and FIGS. 9A and 9B). When the load decreases, only the lengths of the vectors ΔIa, ΔIb, and ΔIc in each diagram are different. When the load increases, the directions of the vectors ΔIa, ΔIb, and ΔIc in each diagram are simply reversed by 180 °. is there. Therefore, these cases can also be distinguished from those at the time of occurrence of downstream disconnection using the above conditions (1) to (3).

Returning to FIG. 1, the effective value calculation unit 3 calculates effective values Vrmsab, Vrmsbc, and Vrmsca of the line voltages based on the input voltage signals v _ab , v _bc , and v _ca. The effective value calculation unit 3 outputs the calculated effective values Vrmsab, Vrmsbc, and Vrmsca to the upstream disconnection determination unit 4.

  The upstream disconnection determination unit 4 determines the occurrence of disconnection on the upstream side (power supply side) from the position where the instrument current transformers CT1, CT2, CT3 and the instrument transformers PT1, PT2, PT3 are disposed. The distribution line is identified, and is realized by, for example, a microcomputer. The upstream disconnection determination unit 4 makes a determination based on the effective values Vrmsab, Vrmsbc, and Vrmsca of each line voltage input from the effective value calculation unit 3. In normal times, the effective values Vrmsab, Vrmsbc, and Vrmsca are substantially similar values. However, when a disconnection occurs on the upstream side, the line voltage related to the disconnected distribution line decreases. For example, when disconnection occurs in the a-phase distribution line a, the effective values Vrmsab and Vrmsca are lowered. The upstream disconnection determination unit 4 determines that a disconnection has occurred on the upstream side when any two of the effective values Vrmsab, Vrmsbc, and Vrmsca are lower than the remaining one by a predetermined value or more. Further, the upstream-side disconnection determination unit 4 determines the disconnected distribution line according to which two values have decreased. When the upstream disconnection determination unit 4 determines that the disconnection has occurred on the upstream side, the disconnection command unit 5 and the communication unit 6 inform the disconnection command unit 5 and the communication unit 6 that the disconnection has occurred on the upstream side and the information on the distribution line in which the disconnection has occurred. Output.

  The interruption command unit 5 outputs an interruption command to the circuit breakers CB1, CB2, and CB3 based on information input from the downstream disconnection determination unit 2 or the upstream disconnection determination unit 4. When the information indicating that the disconnection has occurred is input, the breaker command unit 5 outputs a breaker command to the breakers CB1 to CB3 and opens the breakers CB1 to CB3.

  The communication unit 6 transmits information input from the downstream disconnection determination unit 2 or the upstream disconnection determination unit 4 to a management device (not shown). The management device manages the state of the distribution line. When information indicating that a disconnection has occurred is input from the communication unit 6, the management device warns the occurrence of the disconnection with a buzzer and displays it on the monitor screen. . The information input from the downstream disconnection determination unit 2 to the communication unit 6 includes information indicating that a disconnection has occurred downstream, and is input from the upstream disconnection determination unit 4 to the communication unit 6. This information includes information indicating that a disconnection has occurred on the upstream side. Therefore, the information transmitted from the communication unit 6 to the management device includes information indicating whether the disconnection is downstream or upstream. Therefore, the management device determines which section of which distribution line the disconnection has occurred according to what information is input from which disconnection detection device A, and displays the determined content on the monitor screen. indicate.

  The processing performed by each part of the disconnection detection device A may be designed by a program, and the computer may function as the disconnection detection device A by executing the program. The program may be recorded on a recording medium and read by a computer.

  In the present embodiment, the upstream disconnection detection unit 4 can detect a disconnection on the upstream side of the distribution line, and the downstream disconnection detection unit 2 can detect a disconnection on the downstream side of the distribution line. That is, the disconnection detection device A can detect a disconnection on the upstream side of the arrangement location, and can also detect a disconnection on the downstream side of the arrangement location. Therefore, the number arranged in the distribution line can be reduced as compared with the disconnection detection device that detects only the upstream or downstream disconnection.

  For example, as shown in FIG. 10, when the distribution line is divided into three sections so that the disconnection can be detected for each section, the disconnection in the first section of the distribution line can be detected by the disconnection detection device A1. The disconnection in the second section can be detected by the disconnection detection device A1 and the disconnection detection device A2, and the disconnection in the third section can be detected by the disconnection detection device A2. Accordingly, since only two disconnection detecting devices A1 and A2 need be arranged, the arrangement is compared with the case of the disconnection detecting device that detects only the upstream disconnection (or the downstream disconnection) (see FIG. 16). The number of disconnection detection devices can be reduced.

  Moreover, when arrange | positioning the same number to a distribution line, one area can be shortened rather than using the disconnection detection apparatus which detects only the upstream or downstream disconnection. That is, the disconnection position can be specified in a narrower section than before.

  For example, as shown in FIG. 11, when three disconnection detection devices are arranged on the distribution line, the disconnection detection device A1 can detect disconnections in the first section and the second section, and the disconnection detection apparatus A2 Since the disconnection in the 2nd section and the 3rd section can be detected, and the disconnection detecting device A3 can detect the disconnection in the 3rd section and the 4th section, the distribution line can be divided into 4 sections. . On the other hand, in the case of the disconnection detection devices A101 to A103 that detect only the upstream disconnection, the disconnection detection device A101 detects the disconnection in the first section, the disconnection detection device A102 detects the disconnection in the second section, and the disconnection Since the detection device A3 detects the disconnection in the third section, it is necessary to divide the distribution line into three sections. Therefore, the disconnection detection apparatus A can specify the disconnection position in a narrow section.

  Further, in the present embodiment, the downstream disconnection determination unit 2 determines that the current change vectors ΔIa, ΔIb, ΔIc of each phase voltage input from the current change vector generation unit 1 satisfy the above conditions (1) to (3). If all conditions are satisfied, it is determined that a disconnection has occurred on the downstream side. Although it is difficult to distinguish between load fluctuations and downstream disconnections based on line current vectors, they can be distinguished by differences in current change vectors of each phase voltage reference. Therefore, erroneous detection due to load fluctuation can be suppressed in downstream disconnection detection.

  In this embodiment, the case where the instrument transformers PT1, PT2, and PT3 each detect the line voltage between the distribution lines has been described. However, the instrument transformers PT1, PT2, and PT3 each detect the phase voltage of the distribution line. You may make it do.

  In the present embodiment, the current change vectors ΔIa, ΔIb, ΔIc of each phase voltage reference are used to determine the occurrence of the disconnection on the downstream side, but the present invention is not limited to this. For example, each line voltage reference current change vector may be used. Alternatively, a current change vector based on a voltage obtained by adding a predetermined phase to each phase voltage (for example, a voltage obtained by shifting each phase voltage by 10 °) may be used. That is, a current change vector based on the reference voltage for each phase may be used.

  In the said 1st Embodiment, the case where the case where a two-phase load fluctuation | variation arises was not assumed was demonstrated. Below, the case where the case where a two-phase load fluctuation | variation arises is assumed is demonstrated as 2nd Embodiment.

  First, vectors ΔIa, ΔIb, ΔIc at the time of two-phase load fluctuation when the connection of transformer B is a ΔΔ connection will be described.

FIG. 12A shows a two-phase load fluctuation and shows a state where the load Lab and the load Lca are disconnected. In this case, as is apparent from FIG.
Ia = 0
Ib = Ibc
Ic = −Ibc
It becomes.

となる。 Therefore, the current change vectors ΔIa, ΔIb, ΔIc before and after the load change are
ΔIa = (Iab−Ica) − (0) = Iab−Ica
ΔIb = (Ibc−Iab) − (Ibc) = − Iab
ΔIc = (Ica−Ibc) − (− Ibc) = Ica
And expressed with reference to the phase voltage vector of each phase,

It becomes.

となる。図１２（ｂ）は、二相負荷変動時のベクトルΔＩａ，ΔＩｂ，ΔＩｃを示したものである。図３（ｂ）に示す断線時のベクトル図において、αが「０」の場合、図１２（ｂ）と同じベクトル図になってしまう。 When the line current vector based on each phase voltage is set to I and the vectors βVa, βVb, βVc are replaced with the vector I, respectively,

It becomes. FIG. 12B shows the vectors ΔIa, ΔIb, ΔIc when the two-phase load fluctuates. In the vector diagram at the time of disconnection shown in FIG. 3B, when α is “0”, the vector diagram is the same as FIG.

  Next, vectors ΔIa, ΔIb, ΔIc at the time of two-phase load fluctuation when the connection of transformer B is a ΔY connection will be described.

When the load Lab and the load Lca are disconnected and Iab = Ica = 0,
Ia = Ibc
Ib = Ibc
Ic = -2Ibc
It becomes.

となる。 Therefore, the current change vectors ΔIa, ΔIb, ΔIc before and after the load change are
ΔIa = (Iab + Ibc−2Ica) − (Ibc) = Iab−2Ica
ΔIb = (Ibc + Ica−2Iab) − (Ibc) = Ica−2Iab
ΔIc = (Ica + Iab−2Ibc) − (− 2Ibc) = Ica + Iab
And expressed with reference to the phase voltage vector of each phase,

It becomes.

となる。図１３（ａ）は、二相負荷変動時のベクトルΔＩａ，ΔＩｂ，ΔＩｃを示したものである。図１３（ａ）に示すベクトルであっても、上記条件（１）〜（３）をすべて満たしてしまう場合がある。 When the line current vector based on each phase voltage is set as I and the vectors γVa, γVb, and γVc are replaced with the vector I, respectively,

It becomes. FIG. 13A shows the vectors ΔIa, ΔIb, ΔIc when the two-phase load fluctuates. Even the vector shown in FIG. 13A may satisfy all of the above conditions (1) to (3).

  Next, vectors ΔIa, ΔIb, ΔIc at the time of two-phase load fluctuation when the connection of transformer B is a YΔ connection will be described.

When the load Lab and the load Lca are disconnected and Iab = Ica = 0,
Ia =-(1/3) Ibc
Ib = (2/3) Ibc
Ic =-(1/3) Ibc
It becomes.

となる。 Therefore, the current change vectors ΔIa, ΔIb, ΔIc before and after the load change are
ΔIa = ((2/3) Iab− (1/3) Ibc− (1/3) Ica) − (− (1/3) Ibc)
= (2/3) Iab- (1/3) Ica
ΔIb = ((2/3) Ibc− (1/3) Ica− (1/3) Iab) − (2/3) Ibc
=-(1/3) Ica- (1/3) Iab
ΔIc = ((2/3) Ica− (1/3) Iab− (1/3) Ibc) − (− (1/3) Ibc)
= (2/3) Ica- (1/3) Iab
And expressed with reference to the phase voltage vector of each phase,

It becomes.

となる。図１３（ｂ）は、二相負荷変動時のベクトルΔＩａ，ΔＩｂ，ΔＩｃを示したものである。図１３（ｂ）に示すベクトルであっても、上記条件（１）〜（３）をすべて満たしてしまう場合がある。 When the line current vector based on each phase voltage is set to I and the vectors εVa, εVb, and εVc are replaced with the vector I, respectively,

It becomes. FIG. 13B shows the vectors ΔIa, ΔIb, ΔIc when the two-phase load fluctuates. Even the vector shown in FIG. 13B may satisfy all of the above conditions (1) to (3).

  As described above, if occurrence of disconnection is determined under the above conditions (1) to (3), it is erroneously determined as disconnection when the two-phase load fluctuates. In the second embodiment, no erroneous determination is made in the case of a two-phase load fluctuation.

  FIG. 14 is a diagram for explaining the disconnection detection device A ′ according to the second embodiment. In the same figure, the same code | symbol is attached | subjected to the same or similar element as the disconnection detection apparatus A (refer FIG. 1) which concerns on 1st Embodiment.

  The disconnection detection device A ′ shown in FIG. 14 is the same as the first embodiment in that the downstream disconnection determination unit 2 ′ uses the input from the zero-phase voltage sensor 7 to determine whether the downstream disconnection has occurred. It differs from the disconnection detection apparatus A which concerns.

  The zero phase voltage sensor 7 is disposed on the distribution lines a, b, and c, and detects the zero phase voltage. The zero-phase voltage sensor 7 outputs the detected zero-phase voltage to the downstream disconnection determination unit 2 '.

The downstream disconnection determination unit 2 ′ also determines the occurrence of disconnection using the zero phase voltage input from the zero phase voltage sensor 7. Specifically, the downstream disconnection determination unit 2 ′ sets the following condition (4) in addition to the above conditions (1) to (3).
(4) The zero-phase voltage is equal to or higher than a predetermined threshold value V ₀ .

The zero-phase voltage is “0” in the three-phase equilibrium state, and is not affected by the load fluctuation. However, when a disconnection occurs, an unbalanced state occurs and the zero-phase voltage is not “0”. When the zero-phase voltage is equal to or higher than a predetermined threshold value V ₀ based on detection errors, a disconnection may have occurred. In the present embodiment, for example, a value of several volts is set as the predetermined threshold value V ₀ . Since the zero phase voltage may not be “0” due to the unbalance due to the fluctuation of the power system, the condition (1) to (3) is not determined based on the condition (4) alone. Judgment is also made. The downstream disconnection determination unit 2 ′ determines that a disconnection has occurred in the distribution line when all of the above conditions (1) to (4) are satisfied.

  When the two-phase load fluctuates, the above conditions (1) to (3) may be satisfied, but the above condition (4) is not satisfied. Therefore, in the second embodiment, it is possible to suppress erroneous determination that disconnection occurs when the two-phase load fluctuates.

  In the first and second embodiments, the case where the downstream disconnection is detected based on the current change vector has been described. However, the method for detecting the downstream disconnection is not limited to this. For example, the downstream disconnection may be detected based on the current vector. Further, a disconnection on the downstream side may be detected based on a change in impedance.

  In the first and second embodiments, the case where the upstream disconnection is detected based on the effective value of the line voltage has been described, but the method of detecting the upstream disconnection is not limited to this. For example, the upstream disconnection may be detected based on the instantaneous value of the line voltage. Further, a phase voltage may be used instead of the line voltage. Further, the disconnection on the upstream side may be detected using current, power, zero-phase voltage, or the like instead of voltage.

  Next, a disconnection section specifying system using the disconnection detection device A (A ′) will be described.

  FIG. 15 is a diagram for explaining the disconnection section identification system. The disconnection section specifying system includes disconnection detection devices A1, A2, A3,...

  The management device C manages the state of the distribution line, and receives information transmitted from each of the disconnection detection devices A1, A2, A3,. When each disconnection detecting device A1, A2, A3,... Detects a disconnection, it manages that the disconnection has occurred, whether the disconnection is on the upstream side or the downstream side, and information on the distribution line in which the disconnection has occurred. Transmit to device C. The management device C identifies the section where the disconnection has occurred based on the information about the disconnection received from each of the disconnection detection devices A1, A2, A3,. Then, the occurrence of the disconnection and the section where the disconnection has occurred are displayed on the monitor screen and notified.

  For example, the management device C receives information indicating that a disconnection has occurred downstream from the disconnection detection devices A1 and A2, and has received information indicating that a disconnection has occurred upstream from the disconnection detection device A3. In this case, it is determined that a disconnection has occurred in the third section.

  The disconnection detection device, disconnection detection method, and disconnection section identification system according to the present invention are not limited to the above-described embodiments. The specific configuration of each part of the disconnection detection device, disconnection detection method, and disconnection section identification system according to the present invention can be varied in design in various ways.

A, A ′, A1, A2 Disconnection detection device 1 Current change vector generation unit (downstream disconnection detection means, current change vector generation means)
DESCRIPTION OF SYMBOLS 11 Vector production | generation part 12 Calculation part 13 Storage part 2,2 'Downstream side disconnection judgment part (downstream side disconnection detection means, downstream side disconnection judgment means)
3 RMS value calculation unit (upstream disconnection detection means, RMS value calculation means)
4 upstream disconnection determination unit (upstream disconnection detection means, upstream disconnection determination means)
5 Shut-off command section 6 Communication section 7 Zero phase voltage sensor a, b, c Distribution line CT1, CT2, CT3 Current transformer (electric signal detector)
PT1, PT2, PT3 Instrument transformer (electric signal detector)
B Transformer C Management device

Claims (12)

A disconnection detection device for detecting disconnection of a distribution line,
Based on the electrical signal detected by the electrical signal detector disposed on the distribution line, upstream disconnection detection means for detecting a disconnection upstream from the position where the electrical signal detector is disposed;
Based on the electrical signal detected by the electrical signal detector, downstream disconnection detecting means for detecting a disconnection downstream from the position where the electrical signal detector is disposed;
Equipped with a,
The downstream disconnection detecting means includes:
A current change vector generating means for generating a current change vector that is a change vector of a line current vector based on the phase of the reference voltage for each phase based on the electric signal detected by the electric signal detector;
Based on each current change vector generated by the current change vector generation means, downstream disconnection determination means for determining whether a disconnection has occurred on the downstream side of the distribution line;
With
The disconnection detection apparatus characterized by the above-mentioned. The current change vector generation means includes
Vector generating means for generating a line current vector for each phase based on the current signal detected by the electrical signal detector, and generating a voltage vector for each phase based on the voltage signal detected by the electrical signal detector;
Calculation means for converting the line current vector of each phase into a vector based on a reference voltage for each phase using the voltage vector of each phase and calculating a change vector of the line current vector of each phase after the conversion When,
With
The disconnection detection apparatus according to claim 1 . The current change vector generation means includes
Vector generating means for generating a line current vector for each phase based on the current signal detected by the electrical signal detector, and generating a voltage vector for each phase based on the voltage signal detected by the electrical signal detector;
A change vector of the line current vector of each phase generated by the vector generation unit is calculated, and a voltage vector of each phase generated by the vector generation unit is used as a reference with respect to the reference voltage for each phase. Computing means for converting to
With
The disconnection detection apparatus according to claim 1 . The reference voltage for each phase is a phase voltage of each phase.
The disconnection detection apparatus according to any one of claims 1 to 3 . The reference voltage for each phase is a line voltage of each phase.
The disconnection detection apparatus according to any one of claims 1 to 3 . The downstream disconnection judging means has each current change vector generated by the current change vector generating means,
(1) A phase difference of a current change vector of a phase whose phase advances with respect to a current change vector of a certain phase, and a current change vector of the certain phase with respect to a current change vector of a phase whose phase is later than the certain phase Phase differences of the first threshold value θ1 and the second threshold value θ2 respectively.
(2) the magnitudes of all current change vectors are greater than or equal to a predetermined threshold I0;
(3) Not applicable when all of the following (3-1) to (3-2) are satisfied,
(3-1) The phase difference between the current change vector having the maximum size among the current change vectors and the other current change vectors is about 60 °, respectively.
(3-2) The magnitude of the maximum current change vector is about twice the magnitude of the other current change vectors.
If all the conditions are satisfied, it is determined that a disconnection has occurred.
The disconnection detection apparatus according to any one of claims 1 to 5 . The first threshold θ1 is 5 ° to 30 °.
The disconnection detection apparatus according to claim 6 . The second threshold θ2 is 150 ° to 180 °.
The disconnection detection apparatus according to claim 6 or 7 . It further comprises a zero phase voltage detecting means for detecting a zero phase voltage,
In addition to the conditions (1) to (3), the downstream disconnection judging means
(4) The zero-phase voltage is not less than a predetermined threshold value V0.
If all the conditions are satisfied, it is determined that a disconnection has occurred.
Breaking detection apparatus according to any one of claims 6 to 8. The upstream disconnection detecting means includes:
An effective value calculating means for calculating an effective value of each line voltage based on the electric signal detected by the electric signal detector;
Based on the effective value of each line voltage calculated by the effective value calculating means, upstream disconnection determining means for determining whether a disconnection has occurred on the upstream side of the distribution line,
With
The disconnection detection apparatus according to any one of claims 1 to 9 . A plurality of disconnection detection devices according to any one of claims 1 to 10 , arranged on a distribution line,
When the disconnection detection device detects a disconnection, a management device that transmits information about disconnection by communication from the disconnection detection device,
With
The management device identifies a section where the disconnection of the distribution line has occurred based on the received information about the disconnection,
Disconnection section identification system. A disconnection detection method for detecting disconnection of a distribution line,
A first step in which an electric signal detector disposed on the distribution line detects an electric signal;
Based on the electrical signal detected in the first step, a second step of detecting disconnection downstream of the position where the electrical signal detector is disposed;
A third step of detecting a disconnection upstream of the position where the electric signal detector is disposed based on the electric signal detected in the first step;
Equipped with a,
The second step includes
A fourth step of generating a current change vector which is a change vector of a line current vector based on the phase of the reference voltage for each phase based on the electric signal detected by the electric signal detector;
A fifth step of determining whether or not a disconnection has occurred on the downstream side of the distribution line based on each current change vector generated by the fourth step;
With
A disconnection detection method characterized by comprising:

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