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JP4636360B2 - Power distribution facilities - Google Patents
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JP4636360B2 - Power distribution facilities - Google Patents

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JP4636360B2
JP4636360B2 JP2004132043A JP2004132043A JP4636360B2 JP 4636360 B2 JP4636360 B2 JP 4636360B2 JP 2004132043 A JP2004132043 A JP 2004132043A JP 2004132043 A JP2004132043 A JP 2004132043A JP 4636360 B2 JP4636360 B2 JP 4636360B2
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current transformer
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iron core
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多喜雄 國分
雪雄 大澤
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Fuji Electric FA Components and Systems Co Ltd
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Description

本発明は、過電流に対する保護を行うために1次側に入力された電流を変流して2次側から出力する貫通形変流器具備する受配電設備に関し、特には、大電流に対する保護を行いつつ、小電流領域で高精度の2次側電流を出力することができる貫通形変流器具備する受配電設備に関する。 The present invention relates to a power distribution equipment having a through-type current transformer that outputs a current that is input to the primary side in order to protect against excessive current from the variable flow in the secondary side, in particular, protection against a large current while it is performing, regarding power distribution equipment having a through-type current transformer capable of outputting a secondary current of high accuracy with a small current region.

従来から、過電流に対する保護を行うために1次側端子に入力された電流を変流して2次側端子から出力する導体形変流器が知られている。図7は従来の導体形変流器を示した図である。詳細には、図7(A)は従来の導体形変流器の正面図、図7(B)は従来の導体形変流器の右側面図である。図7において、5−1は導体形変流器のハウジングを構成する樹脂、5−2は1次側端子、5−3は2次側端子である。5−4は1種類の材料により形成された鉄心、5−5は巻線である。図7に示す従来の導体形変流器では、過電流に対する保護を行うことができるように大きい鉄心5−4が設けられていた。そのため、1次側の入力電流が小さい時には、2次側の出力電流値の精度が低くなってしまっていた。それゆえ、従来の受配電設備では、1次側の入力電流が小さい時に電流計測または電力計測を行うことができるように設定された変流器が、図7に示した導体形変流器とは別個に設けられていた。そのため、従来の受配電設備では、2個以上の変流器を受配電設備本体に取付けるための取付けスペースが必要とされていた。   2. Description of the Related Art Conventionally, a conductor type current transformer is known in which a current input to a primary side terminal is converted and output from a secondary side terminal in order to protect against overcurrent. FIG. 7 shows a conventional conductor type current transformer. Specifically, FIG. 7A is a front view of a conventional conductor-type current transformer, and FIG. 7B is a right side view of the conventional conductor-type current transformer. In FIG. 7, 5-1 is resin which comprises the housing of a conductor type current transformer, 5-2 is a primary side terminal, 5-2 is a secondary side terminal. 5-4 is an iron core formed of one kind of material, and 5-5 is a winding. In the conventional conductor type current transformer shown in FIG. 7, a large iron core 5-4 is provided so as to protect against overcurrent. Therefore, when the input current on the primary side is small, the accuracy of the output current value on the secondary side is low. Therefore, in the conventional power distribution facility, the current transformer set so that current measurement or power measurement can be performed when the input current on the primary side is small is the conductor-type current transformer shown in FIG. Were provided separately. Therefore, in the conventional power distribution facility, a mounting space for mounting two or more current transformers on the power distribution facility main body is required.

また、従来から、過電流に対する保護を行うために1次側端子に入力された電流を変流して2次側端子から出力する貫通形変流器が知られている。図8は従来の貫通形変流器を示した図である。詳細には、図8(A)は従来の貫通形変流器の平面図、図8(B)は従来の貫通形変流器の右側面図である。図9は図8(A)のC−C線に沿って切断した従来の貫通形変流器の断面図である。図8および図9において、1’は過電流に対する保護を行うために1次側に入力された電流を変流して2次側から出力する貫通形変流器、1−1’は貫通形変流器1’のハウジングを構成する樹脂、1−2’は口出し線、1−3’は貫通形変流器1’を例えば遮断器に取付けるための取付け用インサートである。1−4’は鉄心、1−8’は巻線、1−9’は絶縁テープである。図8および図9に示す従来の貫通形変流器では、過電流に対する保護を行うことができるように大きい鉄心1−4’が設けられていた。そのため、1次側の入力電流が小さい時には、2次側の出力電流値の精度が低くなってしまっていた。それゆえ、従来の受配電設備では、1次側の入力電流が小さい時に電流計測または電力計測を行うことができるように設定された変流器が、図8および図9に示した貫通形変流器とは別個に設けられていた。そのため、従来の受配電設備では、2個以上の変流器を受配電設備本体に取付けるための取付けスペースが必要とされていた。   Conventionally, a feedthrough current transformer is known in which a current input to a primary side terminal is current-transformed and output from a secondary side terminal in order to protect against overcurrent. FIG. 8 shows a conventional through-type current transformer. Specifically, FIG. 8A is a plan view of a conventional through-type current transformer, and FIG. 8B is a right side view of the conventional through-type current transformer. FIG. 9 is a cross-sectional view of a conventional through-type current transformer cut along line CC in FIG. 8 and 9, 1 ′ is a through-type current transformer that converts the current input to the primary side and outputs it from the secondary side in order to protect against overcurrent, and 1-1 ′ is a through-type current transformer. Resin constituting the housing of the flow device 1 ′, 1-2 ′ is a lead wire, and 1-3 ′ is an insert for mounting the through-type current transformer 1 ′ to, for example, a circuit breaker. 1-4 'is an iron core, 1-8' is a winding, and 1-9 'is an insulating tape. In the conventional through-type current transformer shown in FIGS. 8 and 9, a large iron core 1-4 'is provided so as to protect against overcurrent. Therefore, when the input current on the primary side is small, the accuracy of the output current value on the secondary side is low. Therefore, in the conventional power distribution equipment, the current transformer set so that current measurement or power measurement can be performed when the input current on the primary side is small is the feedthrough type transformer shown in FIGS. It was provided separately from the flow device. Therefore, in the conventional power distribution facility, a mounting space for mounting two or more current transformers on the power distribution facility main body is required.

従来の一般的な方式では、高圧遮断器、変流器、および、保護継電器の組み合わせの構成が、個々に選定され、それぞれ別々に受配電設備に取付けられて固定されていた。特に、変流器は、受配電設備の保護する回路の通電電流毎に選定しなければならず、変流器の種類が多くなっていた。そのため、機器の選定、取付けに多大な労力がかかってしまう。特に、変流器は受配電設備の保護する回路の通電電流毎に選定しなければならず、変流器の種類が多くなっていたため、選定間違いのおそれがあり、取付け後の仕様変更に伴う変流器の交換が大変であるという問題があった。   In the conventional general system, the configuration of a combination of a high voltage circuit breaker, a current transformer, and a protective relay is individually selected, and is separately attached to a power receiving and distribution facility and fixed. In particular, current transformers have to be selected for each energization current of a circuit to be protected by the power receiving and distribution equipment, and the types of current transformers have increased. Therefore, a great deal of labor is required for the selection and installation of equipment. In particular, current transformers must be selected for each energizing current of the circuit to be protected by the power receiving and distribution equipment, and there are many types of current transformers. There was a problem that it was difficult to replace the current transformer.

従来の貫通形変流器の例として、例えば特開昭58−220322号公報に記載されたものがあるが、特開昭58−220322号公報に記載された受配電設備では変流器が1個しか設けられていない。そのため、特開昭58−220322号公報に記載された貫通形変流器によっては、大電流に対する保護を行いつつ、小電流領域で高精度の2次側電流を出力することができない。つまり、大電流に対する保護を行うことができるように貫通形変流器が設定されている場合には、小電流領域で高精度の2次側電流を出力することができず、小電流領域で高精度の2次側電流を出力することができるように貫通形変流器が設定されている場合には、大電流に対する保護を行うことができない。   An example of a conventional through-type current transformer is described in, for example, Japanese Patent Application Laid-Open No. 58-220322. However, in the power distribution facility described in Japanese Patent Application Laid-Open No. 58-220322, there is one current transformer. Only one is provided. For this reason, the through-type current transformer described in Japanese Patent Application Laid-Open No. 58-220322 cannot output a high-precision secondary current in a small current region while protecting against a large current. In other words, when a through-type current transformer is set so that protection against a large current can be performed, a highly accurate secondary current cannot be output in a small current region. When the feedthrough current transformer is set so that a highly accurate secondary current can be output, protection against a large current cannot be performed.

特開昭58−220322号公報JP 58-220322 A

前記問題点に鑑み、本発明は、大電流に対する保護を行いつつ、小電流領域で高精度の2次側電流を出力することができる貫通形変流器具備する受配電設備を提供することを目的とする。 In view of the above problems, the present invention is to provide a power distribution facility comprising while performing protection against large currents, a through-type current transformer capable of outputting a secondary current of high accuracy with a small current region With the goal.

請求項1に記載の発明によれば、過電流に対する保護を行うために1次側に入力された電流を変流して2次側から出力する貫通形変流器であって、1次側の入力電流が大きい時に用いられる第1鉄心と、1次側の入力電流が小さい時に用いられる第2鉄心とを具備し、1次側の入力電流が大きい時に2次側の出力電流特性が直線性を有するような第1材料により前記第1鉄心を形成し、1次側の入力電流が小さい時における2次側の出力電流値の精度が前記第1材料を用いた場合よりも高くなるような第2材料により前記第2鉄心を形成し、貫通形変流器のハウジングを構成する樹脂および巻線の内側に、前記第1鉄心および前記第2鉄心を包囲する樹脂ケースを配置し、変流比の異なる複数の巻線を内蔵した貫通形変流器と、
複数のタップと、
タップ切換えスイッチとを具備し、
前記貫通形変流器が遮断器に取付けられて一体化せしめられた状態で受配電設備本体に取付けられ、
前記貫通形変流器が前記遮断器の主回路端子部に取付けられることを特徴とする受配電設備が提供される。
According to the invention described in claim 1, a through-type current transformer that outputs a current that is input to the primary side in order to protect against excessive current from the variable flow in the secondary side, the primary side The first iron core used when the input current is large and the second iron core used when the input current on the primary side is small, and the output current characteristic on the secondary side is linear when the input current on the primary side is large The first iron core is formed of the first material having the above, and the accuracy of the output current value on the secondary side when the input current on the primary side is small is higher than that when the first material is used. The second iron core is formed of a second material, and a resin case surrounding the first iron core and the second iron core is disposed inside the resin and windings constituting the housing of the through-type current transformer. A through-type current transformer with a plurality of windings with different ratios;
Multiple taps,
A tap changeover switch,
The through-type current transformer is attached to the circuit breaker and attached to the power receiving and distribution equipment body in an integrated state,
A power distribution facility is provided in which the through-type current transformer is attached to a main circuit terminal portion of the circuit breaker .

請求項1に記載の受配電設備の貫通形変流器では、1次側の入力電流が大きい時に用いられる第1鉄心と、1次側の入力電流が小さい時に用いられる第2鉄心とが設けられている。詳細には、1次側の入力電流が大きい時に2次側の出力電流特性が直線性を有するような第1材料により形成された第1鉄心と、1次側の入力電流が小さい時における2次側の出力電流値の精度が第1材料を用いた場合よりも高くなるような第2材料により形成された第2鉄心とが設けられている。そのため、1次側の入力電流が大きい時、つまり、大電流領域においては、第1鉄心により過電流に対する保護を行うことができる。更に、1次側の入力電流が小さい時、つまり、小電流領域においては、第2鉄心により高精度の2次側電流を出力することができる。つまり、大電流に対する保護を行いつつ、小電流領域で高精度の2次側電流を出力することができる。その結果、小電流領域において電流計測用あるいは電力計測用として使用することができる。 The feedthrough transformer of the power distribution facility according to claim 1, wherein a first iron core used when the primary side input current is large and a second iron core used when the primary side input current is small are provided. It has been. Specifically, the first iron core formed of the first material whose output current characteristic on the secondary side has linearity when the input current on the primary side is large, and 2 when the input current on the primary side is small. There is provided a second iron core formed of a second material such that the accuracy of the output current value on the secondary side is higher than that when the first material is used. Therefore, when the primary side input current is large, that is, in the large current region, the first iron core can protect against overcurrent. Furthermore, when the input current on the primary side is small, that is, in a small current region, a highly accurate secondary current can be output by the second iron core. That is, it is possible to output a highly accurate secondary current in a small current region while protecting against a large current. As a result, it can be used for current measurement or power measurement in a small current region.

変流器内に硬度の異なる2個の鉄心が配置されると、少しの外力によってもそれらの鉄心が変形したり、それらの鉄心の位置ずれが生じたりするおそれがある点に鑑み、請求項1に記載の受配電設備の貫通形変流器では、第1鉄心および第2鉄心が樹脂ケースにより包囲されている。そのため、例えば第1鉄心および第2鉄心の周りに巻線が巻かれる時、巻線の周りに樹脂が注型される時など、第1鉄心および第2鉄心に対して外力が加わる時に第1鉄心または第2鉄心が変形してしまうこと、あるいは、第1鉄心と第2鉄心との位置ずれが生じてしまうことを抑制することができる。 In view of the point that when two iron cores having different hardnesses are arranged in the current transformer, the iron cores may be deformed by a slight external force or the iron cores may be displaced. In the through-type current transformer of the power receiving and distribution facility according to 1, the first iron core and the second iron core are surrounded by a resin case. Therefore, for example, when an external force is applied to the first iron core and the second iron core, such as when a winding is wound around the first iron core and the second iron core, or when resin is cast around the winding, the first iron core is applied. It can suppress that an iron core or a 2nd iron core deform | transforms, or the position shift of a 1st iron core and a 2nd iron core arises.

請求項に記載の受配電設備では、変流比の異なる複数の巻線が貫通形変流器に内蔵され、複数のタップが設けられている。そのため、単一の貫通形変流器によって広範囲にわたって異常電流を検出することができる。更に、タップ切換えスイッチが設けられている。そのため、変流比を容易に変更することができ、変流比の仕様変更に簡単に対応することができる。つまり、仕様の異なる複数の変流器の中から最適な仕様の変流器を選定する煩わしさを排除することができる。好ましくは、異常電流の検出範囲が異なる複数の巻線が貫通形変流器に内蔵され、単一の貫通形変流器によって広範囲にわたって異常電流を検出することができるように複数のタップが設けられている。 In the power distribution facility according to claim 1 , a plurality of windings having different current transformation ratios are built in the through-type current transformer, and a plurality of taps are provided. Therefore, an abnormal current can be detected over a wide range by a single through-type current transformer. Furthermore, a tap changeover switch is provided. Therefore, the current transformation ratio can be easily changed, and a change in the specifications of the current transformation ratio can be easily handled. That is, it is possible to eliminate the troublesomeness of selecting a current transformer having an optimum specification from among a plurality of current transformers having different specifications. Preferably, a plurality of windings having different detection ranges of abnormal current are built in the feedthrough current transformer, and a plurality of taps are provided so that the abnormal current can be detected over a wide range by a single feedthrough current transformer. It has been.

請求項に記載の受配電設備では、貫通形変流器が遮断器に取付けられて一体化せしめられた状態で受配電設備本体に取付けられる。そのため、貫通形変流器と遮断器とがそれぞれ別々に受配電設備本体に取付けて固定されるのに伴って機器の選定および取付けに多大な労力がかかってしまうのを回避することができる。つまり、機器の選定間違いを低減することができる。また、遮断器と一体化せしめられることなく貫通形変流器が単体で受配電設備本体に取付けられるのに伴って受配電設備の周りに貫通形変流器取付け用のスペースを確保する必要性を排除することができ、受配電設備を小型化することができる。更に、受配電設備本体に対して遮断器が取付けられるのとは別個に受配電設備本体に対して貫通形変流器が取付けられるのに伴って取付け工数が増加してしまうのを回避することができ、受配電設備の組立コストを低減することができる。 In the power distribution facility according to claim 1 , the through-type current transformer is attached to the power distribution facility main body in a state of being integrated with the circuit breaker. Therefore, it can be avoided that much effort is required for selection and installation of devices as the through-type current transformer and the circuit breaker are separately attached and fixed to the power receiving and distribution equipment main body. That is, it is possible to reduce device selection errors. In addition, it is necessary to secure a space for installing the through-type current transformer around the power receiving / distribution facility as the through-type current transformer is attached to the main body of the power receiving / distributing facility without being integrated with the circuit breaker. Can be eliminated, and the power distribution facility can be reduced in size. Furthermore, avoiding an increase in the number of mounting steps as a through-type current transformer is attached to the power receiving / distributing equipment main body separately from the circuit breaker being attached to the power receiving / distributing equipment main body. As a result, the assembly cost of the power distribution facility can be reduced.

請求項に記載の受配電設備では、貫通形変流器が遮断器の主回路端子部に取付けられる。好ましくは、貫通形変流器が取付けられた遮断器の外形寸法が、貫通形変流器が取付けられていない遮断器の外形寸法よりも大きくならないように、貫通形変流器が遮断器の主回路端子部に取付けられる。そのため、貫通形変流器が取付けられていない遮断器が取付けられていた受配電設備を変更することなく、貫通形変流器が取付けられた遮断器をその受配電設備に対して取付けることができる。 The power distribution installation according to claim 1, the through type current transformer is attached to the main circuit terminals of the circuit breaker. Preferably, the through-type current transformer is installed in the circuit breaker so that the outer dimension of the circuit breaker with the through-type current transformer is not larger than the outer dimension of the circuit breaker without the through-type current transformer. Mounted on the main circuit terminal. Therefore, it is possible to install a circuit breaker with a through-type current transformer attached to the power distribution equipment without changing the power distribution equipment to which a circuit breaker without a through-type current transformer is attached. it can.

図1は本発明の貫通形変流器の第1の実施形態を示した図である。詳細には、図1(A)は第1の実施形態の貫通形変流器の平面図、図1(B)は第1の実施形態の貫通形変流器の右側面図である。図2は図1(A)のA−A線に沿って切断した第1の実施形態の貫通形変流器の断面図である。図1および図2において、1は過電流に対する保護を行うために1次側に入力された電流を変流して2次側から出力する貫通形変流器である。1−1は貫通形変流器1のハウジングを構成する樹脂、1−2は口出し線、1−3は貫通形変流器1を例えば高圧遮断器に取付けるための取付け用インサートである。1−4は1次側の入力電流が大きい時に2次側の出力電流特性が直線性を有するような第1材料により形成された第1鉄心である。1−5は1次側の入力電流が小さい時における2次側の出力電流値の精度が第1材料を用いた場合よりも高くなるような第2材料により形成された第2鉄心である。1−6は第1鉄心1−4を包囲するための上側樹脂ケース、1−7は第1鉄心1−4および第2鉄心1−5を包囲するための下側樹脂ケースである。1−8は巻線、1−9は絶縁テープである。   FIG. 1 is a view showing a first embodiment of the through-type current transformer of the present invention. Specifically, FIG. 1A is a plan view of the through-type current transformer of the first embodiment, and FIG. 1B is a right side view of the through-type current transformer of the first embodiment. FIG. 2 is a cross-sectional view of the through-type current transformer of the first embodiment taken along the line AA in FIG. In FIG. 1 and FIG. 2, reference numeral 1 denotes a through-type current transformer that converts current input to the primary side and outputs it from the secondary side in order to protect against overcurrent. 1-1 is a resin constituting the housing of the through-type current transformer 1, 1-2 is a lead wire, and 1-3 is a mounting insert for attaching the through-type current transformer 1 to, for example, a high-voltage circuit breaker. 1-4 is a first iron core formed of a first material whose secondary output current characteristics have linearity when the primary input current is large. Reference numeral 1-5 denotes a second iron core formed of a second material such that the accuracy of the output current value on the secondary side when the input current on the primary side is small is higher than when the first material is used. 1-6 is an upper resin case for enclosing the first iron core 1-4, and 1-7 is a lower resin case for enclosing the first iron core 1-4 and the second iron core 1-5. 1-8 is a winding, and 1-9 is an insulating tape.

図1および図2に示すように、第1の実施形態の貫通形変流器では、1次側の入力電流が大きい時に用いられる第1鉄心1−4と、1次側の入力電流が小さい時に用いられる第2鉄心1−5とが設けられている。詳細には、1次側の入力電流が大きい時に2次側の出力電流特性が直線性を有するような第1材料により形成された第1鉄心1−4と、1次側の入力電流が小さい時における2次側の出力電流値の精度が第1材料を用いた場合よりも高くなるような第2材料により形成された第2鉄心1−5とが設けられている。そのため、1次側の入力電流が大きい時、つまり、大電流領域においては、第1鉄心1−4により過電流に対する保護を行うことができる。更に、1次側の入力電流が小さい時、つまり、小電流領域においては、第2鉄心1−5により高精度の2次側電流を出力することができる。つまり、大電流に対する保護を行いつつ、小電流領域で高精度の2次側電流を出力することができる。その結果、小電流領域において電流計測用あるいは電力計測用として使用することができる。   As shown in FIGS. 1 and 2, in the feedthrough current transformer of the first embodiment, the first iron core 1-4 used when the primary side input current is large and the primary side input current are small. A second iron core 1-5 that is sometimes used is provided. Specifically, when the primary side input current is large, the first iron core 1-4 formed of the first material whose secondary side output current characteristic has linearity, and the primary side input current is small. There is provided a second iron core 1-5 formed of a second material so that the accuracy of the output current value on the secondary side at that time is higher than that when the first material is used. Therefore, when the input current on the primary side is large, that is, in a large current region, the first iron core 1-4 can protect against overcurrent. Further, when the input current on the primary side is small, that is, in a small current region, the secondary core 1-5 can output a highly accurate secondary current. That is, it is possible to output a highly accurate secondary current in a small current region while protecting against a large current. As a result, it can be used for current measurement or power measurement in a small current region.

更に、第1の実施形態の貫通形変流器では、図2に示すように、第1鉄心1−4および第2鉄心1−5が樹脂ケースにより包囲されている。詳細には、第2鉄心1−5の厚みより大きい深さを有する下側樹脂ケース1−7内に第1鉄心1−4および第2鉄心1−5が挿入され、それにより、第1鉄心1−4および第2鉄心1−5が同心となるように位置決めされ、次いで、蓋をするように第1鉄心1−4上に上側樹脂ケース1−6が配置される。そのため、例えば第1鉄心1−4および第2鉄心1−5の周りに巻線1−8が巻かれる時、巻線1−8の周りに樹脂1−1が注型される時など、第1鉄心1−4および第2鉄心1−5に対して外力が加わる時に第1鉄心1−4または第2鉄心1−5が変形してしまうこと、あるいは、第1鉄心1−4と第2鉄心1−5との位置ずれが生じてしまうことを抑制することができる。   Furthermore, in the penetration type current transformer of 1st Embodiment, as shown in FIG. 2, the 1st iron core 1-4 and the 2nd iron core 1-5 are surrounded by the resin case. Specifically, the first iron core 1-4 and the second iron core 1-5 are inserted into the lower resin case 1-7 having a depth larger than the thickness of the second iron core 1-5, and thereby the first iron core. 1-4 and the 2nd iron core 1-5 are positioned so that it may become concentric, and upper resin case 1-6 is arrange | positioned on the 1st iron core 1-4 next so that it may cover. Therefore, for example, when the winding 1-8 is wound around the first iron core 1-4 and the second iron core 1-5, when the resin 1-1 is cast around the winding 1-8, etc. The first iron core 1-4 or the second iron core 1-5 is deformed when an external force is applied to the first iron core 1-4 and the second iron core 1-5, or the first iron core 1-4 and the second iron core 1-5. It can suppress that position shift with iron core 1-5 will arise.

図3は図1に示した貫通形変流器が2個取付けられた高圧遮断器を示した図である。詳細には、図3(A)は2個の貫通形変流器が取付けられた高圧遮断器の右側面図、図3(B)は図3(A)のB−B線に沿って切断した高圧遮断器の断面図である。図3において、2は高圧遮断器、3は貫通形変流器1を取付けるための取付けねじである。   FIG. 3 is a view showing a high-voltage circuit breaker to which two through-type current transformers shown in FIG. 1 are attached. Specifically, FIG. 3 (A) is a right side view of a high-voltage circuit breaker to which two through-type current transformers are attached, and FIG. 3 (B) is cut along line BB in FIG. 3 (A). It is sectional drawing of the high voltage circuit breaker which was made. In FIG. 3, 2 is a high voltage circuit breaker, and 3 is a mounting screw for mounting the through-type current transformer 1.

図4は図3に示した貫通形変流器1および高圧遮断器2が固定枠に入れられた状態を示した図である。図4において、4は図3に示した貫通形変流器1および高圧遮断器2を受配電設備(図示せず)に取付けるための専用の固定枠である。   FIG. 4 is a view showing a state in which the through-type current transformer 1 and the high-voltage circuit breaker 2 shown in FIG. 3 are placed in a fixed frame. In FIG. 4, reference numeral 4 denotes a dedicated fixing frame for attaching the through-type current transformer 1 and the high-voltage circuit breaker 2 shown in FIG. 3 to a power receiving / distributing facility (not shown).

第1の実施形態では、図3(B)に示すように、例えば2個の貫通形変流器1が高圧遮断器2の主回路端子側の下側の両端の端子に取付けられて一体化せしめられる。次いで、図4に示すように、貫通形変流器1が高圧遮断器2に取付けられて一体化せしめられた状態で固定枠4に入れられ、受配電設備本体(図示せず)に取付けられる。そのため、貫通形変流器1と高圧遮断器2とがそれぞれ別々に受配電設備本体に取付けて固定されるのに伴って機器の選定および取付けに多大な労力がかかってしまうのを回避することができる。つまり、機器の選定間違いを低減することができる。また、高圧遮断器2と一体化せしめられることなく貫通形変流器1が単体で受配電設備本体に取付けられるのに伴って受配電設備(図示せず)の周りに貫通形変流器取付け用のスペースを確保する必要性を排除することができ、受配電設備を小型化することができる。更に、受配電設備本体に対して高圧遮断器2が取付けられるのとは別個に受配電設備本体に対して貫通形変流器1が取付けられるのに伴って取付け工数が増加してしまうのを回避することができ、受配電設備の組立コストを低減することができる。   In the first embodiment, as shown in FIG. 3B, for example, two through-type current transformers 1 are attached to the terminals at both lower ends of the main circuit terminal side of the high-voltage circuit breaker 2 and integrated. I'm damned. Next, as shown in FIG. 4, the through-type current transformer 1 is attached to the high-voltage circuit breaker 2 and integrated into the fixed frame 4 and attached to the power receiving and distribution equipment main body (not shown). . Therefore, it is possible to avoid a great deal of effort in selecting and installing the equipment as the through-type current transformer 1 and the high-voltage circuit breaker 2 are separately attached and fixed to the main body of the power receiving and distributing equipment. Can do. That is, it is possible to reduce device selection errors. In addition, when the through-type current transformer 1 is attached to the main body of the power receiving / distributing equipment without being integrated with the high-voltage circuit breaker 2, the through-type current transformer is attached around the power receiving / distributing equipment (not shown). Therefore, it is possible to eliminate the necessity of securing a space for the power transmission and to reduce the size of the power receiving and distribution equipment. In addition to the fact that the high-voltage circuit breaker 2 is attached to the power receiving and distributing equipment body, the mounting man-hour is increased as the through-type current transformer 1 is attached to the power receiving and distributing equipment body. This can be avoided, and the assembly cost of the power receiving / distributing equipment can be reduced.

更に、第1の実施形態では、図3(A)および図3(B)に示したように、貫通形変流器1が取付けられた高圧遮断器2の外形寸法が、貫通形変流器1が取付けられていない高圧遮断器2の外形寸法、つまり、貫通形変流器1が取付けられる前の高圧遮断器2の外形寸法よりも大きくならないように、貫通形変流器1が高圧遮断器2の主回路端子側の端子に取付けられる。そのため、貫通形変流器1が取付けられていない高圧遮断器2が取付けられていた受配電設備を変更することなく、貫通形変流器1が取付けられた高圧遮断器2をその受配電設備に対して取付けることができる。   Furthermore, in the first embodiment, as shown in FIGS. 3 (A) and 3 (B), the external dimensions of the high-voltage circuit breaker 2 to which the through-type current transformer 1 is attached are the through-type current transformer. The through-type current transformer 1 has a high-voltage circuit breaker so that it does not become larger than the external dimensions of the high-voltage circuit breaker 2 to which no 1 is attached, that is, the external dimensions of the high-voltage circuit breaker 2 before the through-type current transformer 1 is installed. It is attached to the terminal on the main circuit terminal side of the device 2. Therefore, without changing the power receiving / distributing facility to which the high voltage circuit breaker 2 to which the through-type current transformer 1 is not attached is attached, the high-voltage circuit breaker 2 to which the through-type current transformer 1 is attached is the power receiving / distributing facility. Can be installed against.

また、第1の実施形態では、図2に示した巻線1−8の他に、変流比の異なる巻線(図示せず)が貫通形変流器1に内蔵され、受配電設備に複数のタップ(図示せず)が設けられている。そのため、単一の貫通形変流器1によって広範囲にわたって異常電流を検出することができる。更に、タップ切換えスイッチ(図示せず)が、例えば図3に示した高圧遮断器2に設けられている。そのため、変流比を容易に変更することができ、変流比の仕様変更に簡単に対応することができる。つまり、仕様の異なる複数の変流器の中から最適な仕様の変流器を選定する煩わしさを排除することができる。好ましくは、図2に示した巻線1−8とは異常電流の検出範囲が異なる巻線(図示せず)が巻線1−8とは別個に貫通形変流器1に内蔵され、単一の貫通形変流器1によって広範囲にわたって異常電流を検出することができるように複数のタップ(図示せず)が設けられている。   In the first embodiment, in addition to the windings 1-8 shown in FIG. 2, windings (not shown) having different current transformation ratios are built in the through-type current transformer 1, and are installed in the power distribution facility. A plurality of taps (not shown) are provided. Therefore, the abnormal current can be detected over a wide range by the single through-type current transformer 1. Further, a tap changeover switch (not shown) is provided in the high voltage circuit breaker 2 shown in FIG. 3, for example. Therefore, the current transformation ratio can be easily changed, and a change in the specifications of the current transformation ratio can be easily handled. That is, it is possible to eliminate the troublesomeness of selecting a current transformer having an optimum specification from among a plurality of current transformers having different specifications. Preferably, a winding (not shown) having a detection range of an abnormal current different from that of the winding 1-8 shown in FIG. 2 is built in the through-type current transformer 1 separately from the winding 1-8. A plurality of taps (not shown) are provided so that an abnormal current can be detected over a wide range by one through-type current transformer 1.

以下、本発明に関連する発明の貫通形変流器ついて説明する。本発明に関連する発明の貫通形変流器は、図1および図2に示した第1の実施形態の貫通形変流器1と同様に構成されている。そのため、本発明に関連する発明の貫通形変流器では、図1および図2に示した第1の実施形態の貫通形変流器と同様の効果を奏することができる。 Hereinafter, it will be explained in the through-type current transformer of the invention relating to the present invention. The through-type current transformer of the invention related to the present invention is configured similarly to the through-type current transformer 1 of the first embodiment shown in FIGS. 1 and 2. Therefore, the through-type current transformer of the invention related to the present invention can achieve the same effects as the through-type current transformer of the first embodiment shown in FIGS. 1 and 2.

図5は図1に示した貫通形変流器1が2個取付けられた固定枠4および高圧遮断器2を示した図である。詳細には、図5(A)は2個の貫通形変流器1が取付けられた固定枠4および高圧遮断器2の正面図、図5(B)は図5(A)に示した貫通形変流器1、固定枠4および高圧遮断器2の右側面図である。   FIG. 5 is a view showing the fixed frame 4 and the high-voltage circuit breaker 2 to which two through-type current transformers 1 shown in FIG. 1 are attached. Specifically, FIG. 5 (A) is a front view of the fixed frame 4 and the high-voltage circuit breaker 2 to which two through-type current transformers 1 are attached, and FIG. 5 (B) is the through shown in FIG. 5 (A). 3 is a right side view of the current transformer 1, the fixed frame 4, and the high-voltage circuit breaker 2. FIG.

図5に示すように、本発明に関連する発明では、例えば2個の貫通形変流器1が固定枠4の主回路端子側の下側の両端の端子に取付けられて一体化せしめられ、高圧遮断器2が固定枠4に入れられ、受配電設備本体(図示せず)に取付けられる。そのため、貫通形変流器1と固定枠4とがそれぞれ別々に受配電設備本体に取付けて固定されるのに伴って機器の選定および取付けに多大な労力がかかってしまうのを回避することができる。つまり、機器の選定間違いを低減することができる。また、固定枠4と一体化せしめられることなく貫通形変流器1が単体で受配電設備本体に取付けられるのに伴って受配電設備(図示せず)の周りに貫通形変流器取付け用のスペースを確保する必要性を排除することができ、受配電設備を小型化することができる。更に、受配電設備本体に対して固定枠4が取付けられるのとは別個に受配電設備本体に対して貫通形変流器1が取付けられるのに伴って取付け工数が増加してしまうのを回避することができ、受配電設備の組立コストを低減することができる。 As shown in FIG. 5, in the invention related to the present invention , for example, two through-type current transformers 1 are attached to the terminals on the lower side of the main circuit terminal side of the fixed frame 4 and integrated, The high-voltage circuit breaker 2 is placed in the fixed frame 4 and attached to the power receiving and distribution equipment main body (not shown). Therefore, it can be avoided that a great deal of labor is required for selection and installation of equipment as the through-type current transformer 1 and the fixed frame 4 are separately attached and fixed to the main body of the power receiving and distributing equipment. it can. That is, it is possible to reduce device selection errors. Further, as the through-type current transformer 1 is attached to the main body of the power receiving / distributing equipment without being integrated with the fixed frame 4, the through-type current transformer is attached around the power receiving / distributing equipment (not shown). Therefore, it is possible to eliminate the necessity of securing the space, and to reduce the size of the power receiving and distribution equipment. Further, it is possible to avoid an increase in the number of mounting steps as the through-type current transformer 1 is attached to the power receiving / distributing equipment body separately from the fixing frame 4 being attached to the power receiving / distributing equipment body. As a result, the assembly cost of the power receiving / distributing equipment can be reduced.

更に、本発明に関連する発明では、図5に示したように、貫通形変流器1が取付けられた固定枠4の外形寸法が、貫通形変流器1が取付けられていない固定枠4の外形寸法、つまり、貫通形変流器1が取付けられる前の固定枠4の外形寸法よりも大きくならないように、貫通形変流器1が固定枠4の主回路端子側の端子に取付けられる。そのため、貫通形変流器1が取付けられていない固定枠4が取付けられていた受配電設備を変更することなく、貫通形変流器1が取付けられた固定枠4をその受配電設備に対して取付けることができる。 Furthermore, in the invention related to the present invention , as shown in FIG. 5, the outer dimensions of the fixed frame 4 to which the through-type current transformer 1 is attached are the same as the fixed frame 4 to which the through-type current transformer 1 is not attached. The through current transformer 1 is attached to the terminal on the main circuit terminal side of the fixed frame 4 so as not to be larger than the outer dimensions of the fixed frame 4 before the through current transformer 1 is attached. . Therefore, without changing the power receiving / distributing facility to which the fixed frame 4 to which the through-type current transformer 1 is not attached is attached, the fixed frame 4 to which the through-type current transformer 1 is attached to the power receiving / distributing facility. Can be installed.

図6は図1に示した貫通形変流器1が図5に示した位置とは異なる位置に2個取付けられた固定枠4および高圧遮断器2を示した図である。詳細には、図6(A)は2個の貫通形変流器1が取付けられた固定枠4および高圧遮断器2の正面図、図6(B)は図6(A)に示した貫通形変流器1、固定枠4および高圧遮断器2の右側面図である。図6に示す例では、2個の貫通形変流器1が固定枠4の主回路端子側の上側の両端の端子に取付けられて一体化せしめられている。   FIG. 6 is a view showing the fixed frame 4 and the high-voltage circuit breaker 2 in which two through-type current transformers 1 shown in FIG. 1 are attached at positions different from the positions shown in FIG. Specifically, FIG. 6 (A) is a front view of the fixed frame 4 and the high-voltage circuit breaker 2 to which two through-type current transformers 1 are attached, and FIG. 6 (B) is the through shown in FIG. 6 (A). 3 is a right side view of the current transformer 1, the fixed frame 4, and the high-voltage circuit breaker 2. FIG. In the example shown in FIG. 6, two through-type current transformers 1 are attached to and integrated with the terminals on both ends of the fixed frame 4 on the main circuit terminal side.

本発明の貫通形変流器の第1の実施形態を示した図である。It is the figure which showed 1st Embodiment of the penetration type current transformer of this invention. 図1(A)のA−A線に沿って切断した第1の実施形態の貫通形変流器の断面図である。It is sectional drawing of the penetration type current transformer of 1st Embodiment cut | disconnected along the AA line of FIG. 1 (A). 図1に示した貫通形変流器が2個取付けられた高圧遮断器を示した図である。It is the figure which showed the high voltage circuit breaker to which two penetration type current transformers shown in FIG. 1 were attached. 図3に示した貫通形変流器1および高圧遮断器2が固定枠に入れられた状態を示した図である。It is the figure which showed the state in which the penetration type current transformer 1 and the high voltage circuit breaker 2 which were shown in FIG. 3 were put in the fixed frame. 図1に示した貫通形変流器1が2個取付けられた固定枠4および高圧遮断器2を示した図である。It is the figure which showed the fixed frame 4 and the high voltage circuit breaker 2 to which two penetration type current transformers 1 shown in FIG. 1 were attached. 図1に示した貫通形変流器1が図5に示した位置とは異なる位置に2個取付けられた固定枠4および高圧遮断器2を示した図である。FIG. 6 is a view showing a fixed frame 4 and a high-voltage circuit breaker 2 in which two through-type current transformers 1 shown in FIG. 1 are attached at positions different from the positions shown in FIG. 5. 従来の導体形変流器を示した図である。It is the figure which showed the conventional conductor type current transformer. 従来の貫通形変流器を示した図である。It is the figure which showed the conventional penetration type current transformer. 図8(A)のC−C線に沿って切断した従来の貫通形変流器の断面図である。It is sectional drawing of the conventional penetration type current transformer cut | disconnected along CC line of FIG. 8 (A).

符号の説明Explanation of symbols

1 貫通形変流器
1−1 樹脂
1−2 口出し線
1−3 取付け用インサート
1−4 第1鉄心
1−5 第2鉄心
1−6 上側樹脂ケース
1−7 下側樹脂ケース
1−8 巻線
1−9 絶縁テープ
2 高圧遮断器
3 取付けねじ
4 固定枠
DESCRIPTION OF SYMBOLS 1 Through-type current transformer 1-1 Resin 1-2 Lead wire 1-3 Installation insert 1-4 1st iron core 1-5 2nd iron core 1-6 Upper resin case 1-7 Lower resin case 1-8 Winding Wire 1-9 Insulating tape 2 High voltage circuit breaker 3 Mounting screw 4 Fixed frame

Claims (1)

過電流に対する保護を行うために1次側に入力された電流を変流して2次側から出力する貫通形変流器であって、1次側の入力電流が大きい時に用いられる第1鉄心と、1次側の入力電流が小さい時に用いられる第2鉄心とを具備し、1次側の入力電流が大きい時に2次側の出力電流特性が直線性を有するような第1材料により前記第1鉄心を形成し、1次側の入力電流が小さい時における2次側の出力電流値の精度が前記第1材料を用いた場合よりも高くなるような第2材料により前記第2鉄心を形成し、貫通形変流器のハウジングを構成する樹脂および巻線の内側に、前記第1鉄心および前記第2鉄心を包囲する樹脂ケースを配置し、変流比の異なる複数の巻線を内蔵した貫通形変流器と、
複数のタップと、
タップ切換えスイッチとを具備し、
前記貫通形変流器が遮断器に取付けられて一体化せしめられた状態で受配電設備本体に取付けられ、
前記貫通形変流器が前記遮断器の主回路端子部に取付けられることを特徴とする受配電設備。
A through type current transformer that outputs a current that is input to the primary side in order to protect against excessive current from the variable flow in the secondary side, a first core that is used when the input current in the primary is greater A second iron core used when the input current on the primary side is small, and the first material such that the output current characteristic on the secondary side has linearity when the input current on the primary side is large. An iron core is formed, and the second iron core is formed of a second material such that the accuracy of the output current value on the secondary side when the input current on the primary side is small is higher than when the first material is used. A resin case surrounding the first iron core and the second iron core is disposed inside the resin and windings constituting the housing of the through-type current transformer, and a plurality of windings having different current transformation ratios are built in. A current transformer,
Multiple taps,
A tap changeover switch,
The through-type current transformer is attached to the circuit breaker and attached to the power receiving and distribution equipment body in an integrated state,
The power distribution facility, wherein the through-type current transformer is attached to a main circuit terminal portion of the circuit breaker.
JP2004132043A 2004-04-27 2004-04-27 Power distribution facilities Expired - Lifetime JP4636360B2 (en)

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CN102064015A (en) * 2010-12-06 2011-05-18 保定天威集团有限公司 Built-in current transformer without field drying
CN103559995B (en) * 2013-10-22 2016-06-08 江苏靖江互感器厂有限公司 A kind of current transformer magnetism-free stainless steel protection unit

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JPS5667915A (en) * 1979-11-06 1981-06-08 Fuji Electric Co Ltd Current sensor for electronic circuit
JPS59176306U (en) * 1983-05-11 1984-11-26 富士電機株式会社 Fixing structure of insulated pipe in circuit breaker
JPS61135106A (en) * 1984-12-06 1986-06-23 Toshiba Corp Manufacture of saturable reactor
JPH0528747Y2 (en) * 1986-04-18 1993-07-23
JP2763844B2 (en) * 1992-06-16 1998-06-11 三菱電機株式会社 Core case
JP3121248B2 (en) * 1995-09-21 2000-12-25 東光電気株式会社 Current transformer
JP2001015365A (en) * 1999-07-02 2001-01-19 Toko Electric Corp Current transformer
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