JP2006014515A - Dc ground fault detector - Google Patents

Dc ground fault detector Download PDF

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JP2006014515A
JP2006014515A JP2004189052A JP2004189052A JP2006014515A JP 2006014515 A JP2006014515 A JP 2006014515A JP 2004189052 A JP2004189052 A JP 2004189052A JP 2004189052 A JP2004189052 A JP 2004189052A JP 2006014515 A JP2006014515 A JP 2006014515A
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ground fault
current
power
current transformer
circuit
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JP4118259B2 (en
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Koji Aoyama
浩二 青山
Hidenari Kato
英成 加藤
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Aichi Electric Co Ltd
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Abstract

<P>PROBLEM TO BE SOLVED: To provide a DC ground fault detector which is applied to a power converter constituting an interconnected system or the like, keeps the detection level of DC ground fault constant, and prevents an erroneous detection of a ground fault detection circuit. <P>SOLUTION: The DC ground fault detector is attached to a non-isolated type power converter 102 which converts the DC power of a DC power source 101 to AC power to be interconnected to an AC power system 103 having grounding, and detects the grounding current flowing from the DC power source 101 via the grounding point of the AC power system 103 to detect a ground fault. The secondary winding of a current transformer 109 inserted into a DC line or an AC line is applied with AC voltage, and the absolute average value of the excitation current of the current transformer 109 during operation of the power converter 102 is compared with a set value by each cycle to perform the DC ground fault detection. In addition, the DC ground fault detector is provided with a degaussing function of the current transformer 109. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

本発明は、直流電源の直流電力を交流電力に変換して、接地を有する交流電力系統に連系する非絶縁の電力変換装置に備えられ、かつ、直流電源から電力系統の接地点を介して流れる直流地絡電流を検出することにより地絡事故を検出することのできる直流地絡検出装置に関する。   The present invention is provided in a non-insulated power conversion device that converts DC power of a DC power source into AC power and is linked to an AC power system having a ground, and from the DC power source through a ground point of the power system. The present invention relates to a DC ground fault detection device capable of detecting a ground fault by detecting a flowing DC ground fault current.

従来から、太陽電池等の直流電源の直流電力をインバータ回路によって交流電力に変換して、接地を有する交流電力系統に変圧器を設置することなく非絶縁にて連係し、かつ、直流電路に地絡事故が発生した場合は、これを検出して、前記インバータ回路の動作を停止させる直流地絡検出装置を具備した電力変換装置は種々提案されている(特許文献1参照)。
特開2000−23368号公報 Conventionally, DC power from a DC power source such as a solar cell is converted into AC power by an inverter circuit, and is linked to a grounded AC power system without installation of a transformer, and is connected to the DC power circuit. Various power converters equipped with a DC ground fault detection device that detects the occurrence of a fault and stops the operation of the inverter circuit have been proposed (see Patent Document 1).
JP 2000-23368 A

前記[特許文献1]記載の電力変換装置(太陽光発電システム)は、図3に示すように、例えば、単相3線の商用電源3に漏電ブレーカよりなる主幹ブレーカ20を介して接続した幹線と分散電源との間に解列開閉器10を介在させている。   As shown in FIG. 3, the power conversion device (solar power generation system) described in [Patent Document 1] is, for example, a main line connected to a single-phase three-wire commercial power supply 3 via a main breaker 20 made of a leakage breaker. A disconnect switch 10 is interposed between the power supply and the distributed power supply.

負荷4には前記幹線を通して電力が供給され、商用電源3と分散電源2とのどちらからも負荷4に対して電力が供給可能となっている。前記分散電源2は太陽電池1を具備しており、太陽電池1から出力される直流電圧を昇圧回路5によって昇圧し、昇圧回路5の出力電圧をインバータ回路6により交流電圧に電力変換する。   Electric power is supplied to the load 4 through the trunk line, and electric power can be supplied to the load 4 from either the commercial power source 3 or the distributed power source 2. The distributed power source 2 includes a solar cell 1, which boosts a DC voltage output from the solar cell 1 by a booster circuit 5 and converts the output voltage of the booster circuit 5 into an AC voltage by an inverter circuit 6.

インバータ回路6の出力はフィルタ回路7を通して解列開閉器10に接続され、このフィルタ回路7によりインバータ回路6から出力されるパルス列が正弦波状に波形整形される。前記昇圧回路5とインバータ回路6は、それぞれスイッチング素子(図示せず)を備え、これらスイッチング素子は制御部8によって制御される。   The output of the inverter circuit 6 is connected to the disconnection switch 10 through the filter circuit 7, and the filter circuit 7 shapes the pulse train output from the inverter circuit 6 into a sine wave. Each of the booster circuit 5 and the inverter circuit 6 includes a switching element (not shown), and these switching elements are controlled by the control unit 8.

前記制御部8は、各種の異常(地絡等)が検出されたときに、前記スイッチング素子をオフしてインバータ回路6の動作を停止させるとともに解列開閉器10を解列させる機能を有している。前記分散電源2には、トロイダル状のコアを備える変流器からなる地絡検出用の電流センサ11が設けられており、該電流センサ11の出力は、判断回路9に与えられ、判断回路9は電流センサ11の出力に基づいて地絡を検出すると、前記インバータ回路6の動作を停止させ、かつ解列開閉器10を解列させるように制御部8を制御する。   The control unit 8 has a function of turning off the switching element to stop the operation of the inverter circuit 6 and disconnecting the disconnecting switch 10 when various abnormalities (such as a ground fault) are detected. ing. The distributed power source 2 is provided with a ground fault detection current sensor 11 including a current transformer having a toroidal core, and an output of the current sensor 11 is given to a determination circuit 9. When detecting a ground fault based on the output of the current sensor 11, the control unit 8 is controlled to stop the operation of the inverter circuit 6 and to disconnect the disconnect switch 10.

すなわち、太陽電池1の負側で地絡が生じて抵抗Rgで示す経路が形成されると、太陽電池1→昇圧回路5→インバータ回路6→フィルタ回路7→解列開閉器10→主幹ブレーカ20→商用電源3→抵抗Rg→太陽電池1という経路を通して地絡電流が流れる。   That is, when a ground fault occurs on the negative side of the solar cell 1 and a path indicated by the resistance Rg is formed, the solar cell 1 → the booster circuit 5 → the inverter circuit 6 → the filter circuit 7 → the disconnecting switch 10 → the main breaker 20 → Ground fault current flows through the path of commercial power source 3 → resistance Rg → solar cell 1.

このように地絡電流が流れると、電流センサ11に流れる電流に不平衡が生じるので、電流センサ11の出力に基づいて判断回路9が地絡と判断し、制御部8を通して解列開閉器10を解列させた後、インバータ回路6の動作を停止させる。   When the ground fault current flows in this way, an imbalance occurs in the current flowing through the current sensor 11, so that the determination circuit 9 determines that there is a ground fault based on the output of the current sensor 11, and the disconnect switch 10 Is disconnected, the operation of the inverter circuit 6 is stopped.

然るに、この種の電流センサ11においては、変流器のヒステリシス特性に製作上のバラツキがあるので、直流地絡電流の検出誤差が大きくなる問題があった。また、比較的大きな電流値の地絡電流が流れると、電流センサ11を構成する変流器のコア(図示せず)が地絡電流によって磁化され、地絡が回復した後も当該コアに磁気が残留してしまう。   However, this type of current sensor 11 has a problem in that the detection error of the DC ground fault current becomes large because the hysteresis characteristics of the current transformers vary in manufacturing. Further, when a ground fault current having a relatively large current value flows, the core (not shown) of the current transformer that constitutes the current sensor 11 is magnetized by the ground fault current, and even after the ground fault is recovered, the core is magnetized. Will remain.

これにより、前記判断回路9が地絡を検出するときの検出レベルが変動してしまい、判断回路9による地絡の誤検出を生じさせる可能性があった。   As a result, the detection level when the determination circuit 9 detects a ground fault changes, and there is a possibility that an erroneous detection of the ground fault by the determination circuit 9 may occur.

本発明は、上記問題点を解決するためになされたもので、その目的とするところは、直流地絡電流の検出レベルが一定であり、速やかで、かつ誤検出のない地絡検出を実現することのできる直流地絡検出装置を提供することにある。   The present invention has been made to solve the above-described problems, and the object of the present invention is to realize a ground fault detection that has a constant detection level of a DC ground fault current and that is quick and free from erroneous detection. An object of the present invention is to provide a DC ground fault detection device capable of performing the above.

請求項1記載の発明は、直流電源の直流電力を交流電力に変換して、接地を有する交流電力系統に連系する非絶縁の電力変換装置に適用され、かつ直流電源から交流電力系統の接地点を介して流れる地絡電流を検出する直流地絡検出装置であって、直流ライン、若しくは、交流ラインに挿入された変流器の2次巻線に交流電圧を印加し、前記電力変換装置が運転する前に、交流励磁された前記変流器の励磁電流の絶対値を平均して初期値として記憶し、前記電力変換装置が運転を開始した後、前記変流器の励磁電流の絶対値を平均した値から前記初期値を差し引いた後、これを規定値と比較して直流地絡電流を検出するように構成した。   The invention according to claim 1 is applied to a non-insulated power conversion device that converts DC power of a DC power source into AC power and is linked to an AC power system having a ground, and is connected to the AC power system from the DC power source. A DC ground fault detecting device for detecting a ground fault current flowing through a point, wherein an AC voltage is applied to a secondary winding of a current transformer inserted in a DC line or an AC line, and the power converter Before the operation, the absolute value of the excitation current of the current transformer that is AC-excited is averaged and stored as an initial value, and after the power converter starts operation, the absolute value of the excitation current of the current transformer After the initial value was subtracted from the averaged value, this was compared with a specified value to detect a DC ground fault current.

請求項2記載の発明は、請求項1記載の発明において、前記変流器の励磁電流の絶対値を前記変流器の2次巻線に印加する電圧の1周期毎に平均する地絡検出回路を具備して構成した。   The invention according to claim 2 is the ground fault detection according to claim 1, wherein the absolute value of the excitation current of the current transformer is averaged for each cycle of the voltage applied to the secondary winding of the current transformer. A circuit was provided.

請求項3記載の発明は、請求項1記載の発明において、前記地絡検出回路が前記初期値を記憶する前に、前記変流器に減衰交流電流を流して、前記変流器の残留磁気を消磁する励磁回路を具備して構成した。   According to a third aspect of the present invention, in the first aspect of the present invention, before the ground fault detection circuit stores the initial value, a damped alternating current is passed through the current transformer, and the residual magnetism of the current transformer is changed. And an excitation circuit for demagnetizing.

請求項1記載の発明によれば、直流地絡電流が流れていない状態、つまり前記電力変換装置が運転を開始する前に、交流励磁された変流器の励磁電流の絶対値を平均して初期値として記憶し、前記電力変換装置が運転を開始した後、前記変流器の励磁電流の絶対値を平均した値から前記初期値を差し引いて、これを規定値と比較するように構成したので、前記変流器のヒステリシス特性に製作上のバラツキがあっても、電力変換装置を運転する度にこれをオフセット補正することができ、直流地絡電流の検出誤差を小さくすることができる。   According to the first aspect of the present invention, the DC ground fault current is not flowing, that is, before the power converter starts operation, the absolute values of the excitation currents of the AC current transformers are averaged. After storing the initial value and starting the operation of the power converter, the initial value is subtracted from the average value of the absolute value of the exciting current of the current transformer, and this is compared with a specified value. Therefore, even if there is a manufacturing variation in the hysteresis characteristics of the current transformer, the offset can be corrected every time the power converter is operated, and the detection error of the DC ground fault current can be reduced.

請求項2記載の発明によれば、地絡検出回路において、前記変流器の2次巻線に印加する電圧の1周期毎に、励磁電流の絶対値を平均化するように構成したので、励磁電流の絶対値をフィルタを使用し、平滑して平均化する必要は一切なく、当該平滑フィルタに起因して発生する地絡電流の検出遅延を確実に回避することができる。   According to the second aspect of the present invention, in the ground fault detection circuit, the absolute value of the excitation current is averaged for each cycle of the voltage applied to the secondary winding of the current transformer. There is no need to smooth and average the absolute value of the excitation current by using a filter, and it is possible to reliably avoid the detection delay of the ground fault current caused by the smoothing filter.

請求項3記載の発明によれば、前記直流地絡検出装置が前記初期値を記憶する前に、励磁回路によって前記変流器に次第に減衰する交流電流を流すように構成したので、電力変換装置が運転する前に、前記変流器の残留磁気を確実に取り除くことができる。この結果、前記直流地絡検出装置が直流地絡を検出する際の検出レベルを一定にすることができ、以って、地絡の誤検出を良好に防止することが可能となる。   According to a third aspect of the present invention, since the DC ground fault detection device is configured to flow an alternating current gradually attenuated to the current transformer by the excitation circuit before storing the initial value, the power conversion device Before the operation, the residual magnetism of the current transformer can be surely removed. As a result, it is possible to make the detection level when the DC ground fault detection device detects a DC ground fault constant, and thus it is possible to prevent erroneous ground faults well.

以下、本発明の実施の形態を図1により説明する。図1は本発明の直流地絡検出装置を備えた電力変換装置の構成を示すブロック図である。図1において、101は太陽電池や燃料電池等の直流電源であり、102は、直流電源101から供給される直流電力を交流に変換する非絶縁型の電力変換装置であり、また、103は中性点が接地された単相3線式の交流電力系統を示している。   Hereinafter, an embodiment of the present invention will be described with reference to FIG. FIG. 1 is a block diagram showing a configuration of a power conversion device provided with a DC ground fault detection device of the present invention. In FIG. 1, 101 is a DC power source such as a solar cell or a fuel cell, 102 is a non-insulated power conversion device that converts DC power supplied from the DC power source 101 into AC, and 103 is a medium power source. A single-phase, three-wire AC power system with a sex point grounded is shown.

前記電力変換装置102は、直流電源101の直流電力を所定の直流電圧に昇圧させる昇圧回路104と、該昇圧回路104で昇圧された直流電圧を交流電圧に変換するインバータ回路105と、前記交流電圧から高周波成分を除去するフィルタ回路106、および、当該電力変換装置102を前記交流電力系統103に連系、または、解列する解列開閉器107から構成されている。   The power converter 102 includes a booster circuit 104 that boosts the DC power of the DC power supply 101 to a predetermined DC voltage, an inverter circuit 105 that converts the DC voltage boosted by the booster circuit 104 into an AC voltage, and the AC voltage. Filter circuit 106 that removes high-frequency components from the power source, and disconnection switch 107 that interconnects or disconnects the power converter 102 from the AC power system 103.

また、図1において、108は直流電源101から交流電力系統103の接地点を介して地絡電流が流れること(地絡事故)を検出する本発明に係る直流地絡検出装置を示しており、直流電源101と昇圧回路104間の直流電路(直流ライン)に設置された変流器109と、該変流器109の図示しない2次巻線に交流電流を印加する励磁回路110、および、地絡事故の有無を判定する地絡検出回路111と、地絡検出回路111からの信号の内容に応じて、前記昇圧回路104やインバータ回路105を運転/停止させたり、解列開閉器107を入/切する制御回路112から概略構成されている。   In FIG. 1, reference numeral 108 denotes a DC ground fault detection apparatus according to the present invention that detects that a ground fault current flows from the DC power source 101 through the ground point of the AC power system 103 (ground fault). A current transformer 109 installed in a DC circuit (DC line) between the DC power supply 101 and the booster circuit 104; an excitation circuit 110 for applying an AC current to a secondary winding (not shown) of the current transformer 109; A ground fault detection circuit 111 that determines whether or not a fault has occurred. The booster circuit 104 and the inverter circuit 105 are operated / stopped according to the content of the signal from the ground fault detection circuit 111, and the disconnect switch 107 is turned on. The control circuit 112 is configured roughly from the control circuit 112 for turning off / on.

また、前記励磁回路110は、交流信号発生器113と、該交流信号発生器113の出力電圧を増幅させる増幅回路114から構成されている。   The excitation circuit 110 includes an AC signal generator 113 and an amplifier circuit 114 that amplifies the output voltage of the AC signal generator 113.

さらに、前記地絡検出回路111は、前記変流器109の2次巻線(図示せず)と直列に接続された抵抗115と、抵抗115によって電圧変換された前記励磁電流の絶対値を計算する絶対値計算回路116、前記励磁電流の絶対値を平均化する平均化回路117、この平均値を記憶する第1の記憶部118、第1の記憶部118に記憶した平均値に基づく計算結果を、第2の記憶部119に予め設定して記憶させた規定値と比較することにより、地絡事故の発生の有無を判別する判別回路120を備えて構成されている。   Further, the ground fault detection circuit 111 calculates a resistance 115 connected in series with a secondary winding (not shown) of the current transformer 109, and an absolute value of the excitation current voltage-converted by the resistance 115. An absolute value calculation circuit 116 for averaging, an averaging circuit 117 for averaging the absolute value of the excitation current, a first storage unit 118 for storing the average value, and a calculation result based on the average value stored in the first storage unit 118 Is compared with a specified value that is preset and stored in the second storage unit 119, thereby including a determination circuit 120 that determines whether or not a ground fault has occurred.

つづいて、前記直流地絡検出装置108の動作について説明する。本発明の直流地絡検出装置108は、電力変換装置102が運転を開始する前に、まず、励磁回路110の交流信号発生器113から増幅回路114を介して所定の電圧値の交流電圧を、変流器109の2次巻線(図示せず)と、該2次巻線に直列接続された抵抗115に印加することにより、励磁電流を流す。   Next, the operation of the DC ground fault detection device 108 will be described. The DC ground fault detection device 108 of the present invention first converts an AC voltage having a predetermined voltage value from the AC signal generator 113 of the excitation circuit 110 via the amplifier circuit 114 before the power conversion device 102 starts operation. An excitation current is caused to flow by applying to a secondary winding (not shown) of the current transformer 109 and a resistor 115 connected in series to the secondary winding.

地絡検出回路111は、絶対値計算回路116により抵抗115で電圧変換された前記励磁電流の絶対値を計算して、平均化回路117に出力する。平均化回路117では、変流器109の2次巻線(図示せず)に印加する電圧の1周期毎に前記励磁電流の絶対値を平均化して、これを初期値として第1の記憶部118に記憶する。   The ground fault detection circuit 111 calculates the absolute value of the excitation current voltage-converted by the resistor 115 by the absolute value calculation circuit 116 and outputs the absolute value to the averaging circuit 117. In the averaging circuit 117, the absolute value of the exciting current is averaged for each cycle of the voltage applied to the secondary winding (not shown) of the current transformer 109, and this is used as an initial value for the first storage unit. 118.

次に、電力変換装置102が運転を開始した後、前述と同様に、抵抗115にて電圧変換した前記励磁電流の絶対値を計算して、平均化回路117で変流器109の図示しない2次巻線に印加する電圧の1周期毎に前記励磁電流の絶対値を平均化して判別回路120に出力する。   Next, after the power converter 102 starts operation, the absolute value of the excitation current converted into voltage by the resistor 115 is calculated in the same manner as described above, and the current transformer 109 (not shown) is calculated by the averaging circuit 117. The absolute value of the excitation current is averaged for each cycle of the voltage applied to the next winding and output to the discrimination circuit 120.

判別回路120では、電力変換装置102が運転を開始した後に平均化回路117で処理した絶対値の平均値から、先に第1の記憶部118に記憶させた初期値を差し引いた値を第2の記憶部119に予め設定した規定値と比較する。そして、この比較結果が規定値を上回るものである場合は、直流地絡が発生したものと判別し、一方、規定値を下回る結果であれば、直流地絡は発生していないと判別する。   In the determination circuit 120, a value obtained by subtracting the initial value previously stored in the first storage unit 118 from the average value of the absolute values processed by the averaging circuit 117 after the power conversion apparatus 102 starts operation is the second value. Are compared with a predetermined value preset in the storage unit 119. If the comparison result exceeds the specified value, it is determined that a DC ground fault has occurred. On the other hand, if the result is less than the specified value, it is determined that no DC ground fault has occurred.

この比較結果は、前記判別回路120から制御回路112に直流地絡検出信号として送出され、前記制御回路112において直流地絡の発生が確認された場合は、昇圧回路104とインバータ回路105の動作を停止させ、解列開閉器107をオフすることにより、電力変換装置102を交流電力系統103から解列させて、直流電源101から交流電力系統103の接地点を介して地絡電流が流れることを即座に解消し、地絡電流によって火災等が発生することを未然に防止することができる。   The comparison result is sent from the discrimination circuit 120 to the control circuit 112 as a DC ground fault detection signal. When the generation of a DC ground fault is confirmed in the control circuit 112, the operations of the booster circuit 104 and the inverter circuit 105 are performed. By stopping and turning off the disconnect switch 107, the power converter 102 is disconnected from the AC power system 103, and a ground fault current flows from the DC power source 101 through the ground point of the AC power system 103. It can be resolved immediately and a fire or the like can be prevented from occurring due to a ground fault current.

つまり、本発明の直流地絡検出装置108によれば、変流器109のヒステリシス特性に製作上のバラツキがあっても、電力変換装置102が運転を開始する前に算出した絶対値の平均値を初期値として記憶し、電力変換装置102が運転を開始した後に算出した絶対値の平均値を前記初期値から差し引いた値を予め設定した規定値と比較することにより直流地絡の有無を判別する構成であるので、電力変換装置102を運転する度に変流器109のヒステリシス特性のバラツキをオフセット補正することができ、直流地絡電流の検出誤差を極力小さくすることができる。   That is, according to the DC ground fault detection device 108 of the present invention, even if the hysteresis characteristics of the current transformer 109 vary in manufacturing, the average value of absolute values calculated before the power conversion device 102 starts operation. Is stored as an initial value, and the presence or absence of a DC ground fault is determined by comparing a value obtained by subtracting an average value of absolute values calculated after the power conversion device 102 starts operation from the initial value with a preset specified value. Thus, every time the power conversion device 102 is operated, the variation in the hysteresis characteristic of the current transformer 109 can be offset-corrected, and the detection error of the DC ground fault current can be minimized.

また、変流器109の2次巻線(図示せず)に印加する電圧の1周期毎に励磁電流の絶対値を平均する構成であるので、フィルタを使用し、電流波形を平滑して平均値を求める場合と異なり、前記フィルタの時定数が大きいことに起因する地絡検出の遅延が生じることはない。   In addition, since the absolute value of the excitation current is averaged every cycle of the voltage applied to the secondary winding (not shown) of the current transformer 109, a filter is used to smooth the current waveform and average it. Unlike the case of obtaining the value, there is no delay in ground fault detection due to the large time constant of the filter.

なお、図1に示す直流地絡検出装置108も、従来技術に示す装置(太陽光発電システム)と同様に、コア(図示せず)を備える変流器109の出力から直流電路の地絡を検出するように構成しているが、本発明の直流地絡検出装置108は、変流器109の2次巻線(図示せず)に印加する電圧を増幅回路114にて次第に減少させることにより、前記コア(図示せず)を確実に消磁させることができる。   The DC ground fault detection device 108 shown in FIG. 1 also detects the ground fault of the DC electric circuit from the output of the current transformer 109 having a core (not shown), similarly to the device (solar power generation system) shown in the prior art. Although it is configured to detect, the DC ground fault detection device 108 of the present invention gradually reduces the voltage applied to the secondary winding (not shown) of the current transformer 109 by the amplifier circuit 114. The core (not shown) can be reliably demagnetized.

すなわち、直流電路が地絡すると、比較的大きな直流地絡電流が流れ、この直流電流によって変流器109のコア(図示せず)に磁気が残留してしまう。残留磁気があると、地絡検出精度に誤差が生じてしまうので、この残留磁気を持ったまま地絡検出動作を行うのには問題があった。   That is, when the DC circuit is grounded, a relatively large DC ground current flows, and this DC current causes magnetism to remain in the core (not shown) of the current transformer 109. If there is residual magnetism, an error occurs in the ground fault detection accuracy, so there is a problem in performing the ground fault detection operation with this residual magnetism.

そこで、第1の記憶部118に初期値を記憶させる前に、磁化してしまった変流器109のコア(図示せず)を元の残留磁気の無い状態に戻すことを目的として、励磁回路110の増幅回路114によってその増幅率を変化させることにより、変流器109の2次巻線(図示せず)に印加される電圧を除々に減衰させて前記コア(図示せず)を消磁させる。   In order to return the core (not shown) of the current transformer 109 that has been magnetized before the initial value is stored in the first storage unit 118 to an original state without residual magnetism, an excitation circuit is provided. By changing the amplification factor by the amplification circuit 114 of 110, the voltage applied to the secondary winding (not shown) of the current transformer 109 is gradually attenuated to demagnetize the core (not shown). .

これにより、変流器のコア(図示せず)の残留磁気を確実に取り除いて、検出レベルを常に一定に維持することができ、地絡の誤検出を確実に防止することが可能となる。   Thereby, it is possible to reliably remove the residual magnetism of the core (not shown) of the current transformer and to keep the detection level constant, and to reliably prevent erroneous detection of ground faults.

なお、前述した実施例においては、直流ラインに流れる直流地絡電流を検出する位置に変流器109を挿入した例について説明したが、本発明の直流地絡検出装置108はこの構成に限定されることなく、例えば、図2に示すように、フィルタ回路106と解列開閉器107間に変流器109を挿入して、交流ラインに流れる直流地絡電流を検出するように構成しても良い。   In the above-described embodiment, the example in which the current transformer 109 is inserted at the position where the DC ground fault current flowing in the DC line is detected has been described. However, the DC ground fault detector 108 of the present invention is limited to this configuration. For example, as shown in FIG. 2, a current transformer 109 may be inserted between the filter circuit 106 and the disconnecting switch 107 to detect a DC ground fault current flowing in the AC line. good.

また、本発明の直流地絡検出装置108が適用される電力変換装置102は、図1に示す構成に限定されるものではなく、非絶縁型の電力変換装置であれば適用可能であることは当然である。   In addition, the power converter 102 to which the DC ground fault detector 108 of the present invention is applied is not limited to the configuration shown in FIG. 1 and can be applied to any non-insulated power converter. Of course.

さらに、前記電力変換装置102と連系する交流電力系統103も図1に示す単相3線式の電気方式に限らず、単相2線式や3相3線式、3相4線式など接地されている系統であれば本発明の適用が可能である。   Furthermore, the AC power system 103 connected to the power converter 102 is not limited to the single-phase three-wire electric system shown in FIG. 1, but a single-phase two-wire system, a three-phase three-wire system, a three-phase four-wire system, or the like. The present invention can be applied to any system that is grounded.

系統連系システムなどの電力変換装置に適用可能であり、直流地絡の検出レベルを一定にして地絡の誤検出を防止できるとともに、変流器が有する製作上のヒステリシス特性のバラツキを前記電力変換装置の運転の度にオフセット補正して直流地絡電流の検出誤差を小さくできる。   It can be applied to power converters such as grid interconnection systems, and it can prevent the detection of ground faults by making the DC ground fault detection level constant, and it can also be used to reduce the manufacturing hysteresis characteristics of the current transformer. It is possible to reduce the detection error of the DC ground fault current by correcting the offset every time the converter is operated.

本発明の直流地絡検出装置の構成を示すブロック図である。It is a block diagram which shows the structure of the direct-current ground fault detection apparatus of this invention. 本発明を適用可能な系統連系システムの回路図である。It is a circuit diagram of the grid connection system which can apply this invention. 従来の直流地絡検出装置の構成を示すブロック図である。It is a block diagram which shows the structure of the conventional DC ground fault detection apparatus.

符号の説明Explanation of symbols

101 直流電源
102 電力変換装置
103 交流電力系統
104 昇圧回路
105 インバータ回路
106 フィルタ回路
107 解列開閉器
108 直流地絡検出装置
109 変流器
110 励磁回路
111 地絡検出回路
112 制御回路
113 交流信号発生器
114 増幅回路
115 抵抗
116 絶対値計算回路
117 平均化回路
118 第1の記憶部
119 第2の記憶部
120 判別回路 DESCRIPTION OF SYMBOLS 101 DC power supply 102 Power converter 103 AC power system 104 Booster circuit 105 Inverter circuit 106 Filter circuit 107 Disconnection switch 108 DC ground fault detector 109 Current transformer 110 Excitation circuit 111 Ground fault detection circuit 112 Control circuit 113 AC signal generation 114 Amplifier circuit 115 Resistance 116 Absolute value calculation circuit 117 Averaging circuit 118 First storage unit 119 Second storage unit 120 Discrimination circuit

Claims (3)

直流電源の直流電力を交流電力に変換して、接地を有する交流電力系統に連系する非絶縁の電力変換装置に適用され、かつ直流電源から交流電力系統の接地点を介して流れる地絡電流を検出する直流地絡検出装置であって、直流ライン、若しくは、交流ラインに挿入された変流器の2次巻線に交流電圧を印加し、前記電力変換装置が運転する前に、交流励磁された前記変流器の励磁電流の絶対値を平均して初期値として記憶し、前記電力変換装置が運転を開始した後、前記変流器の励磁電流の絶対値を平均した値から前記初期値を差し引いた後、設定値と比較して直流地絡電流を検出するように構成したことを特徴とする直流地絡検出装置。   A ground fault current that is applied to a non-insulated power conversion device that converts DC power from a DC power source into AC power and is linked to an AC power system having a ground, and that flows from the DC power source through the ground point of the AC power system A DC ground fault detection device for detecting an AC voltage applied to a secondary winding of a current transformer inserted in a DC line or an AC line, and before the power converter operates, AC excitation The absolute value of the excitation current of the current transformer is averaged and stored as an initial value, and after the power converter starts operation, the initial value is calculated from the average value of the absolute value of the excitation current of the current transformer. A direct-current ground fault detection device configured to detect a direct-current ground fault current by subtracting a value and comparing with a set value. 請求項1記載の直流地絡検出装置であって、前記変流器の励磁電流の絶対値を前記変流器の2次巻線に印加する電圧の1周期毎に平均する地絡検出回路を具備して構成したことを特徴とする直流地絡検出装置。   2. The DC ground fault detection device according to claim 1, further comprising: a ground fault detection circuit that averages the absolute value of the excitation current of the current transformer every cycle of the voltage applied to the secondary winding of the current transformer. A direct-current ground fault detection device comprising: 請求項1記載の直流地絡検出装置であって、前記地絡検出回路が前記初期値を記憶する前に、前記変流器に減衰交流電流を流して、前記変流器の残留磁気を消磁する励磁回路を具備して構成したことを特徴とする直流地絡検出装置。   2. The DC ground fault detection device according to claim 1, wherein before the ground fault detection circuit stores the initial value, a damped alternating current is supplied to the current transformer to demagnetize the residual magnetism of the current transformer. A DC ground fault detection device comprising an excitation circuit that performs the configuration.
JP2004189052A 2004-06-28 2004-06-28 DC ground fault detector Expired - Fee Related JP4118259B2 (en)

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JP2011196729A (en) * 2010-03-18 2011-10-06 Kansai Electric Power Co Inc:The Leak detection device and method for dc circuit
JP2011214963A (en) * 2010-03-31 2011-10-27 Takaoka Electric Mfg Co Ltd Failure determiner for transformer
CN106483349A (en) * 2016-11-23 2017-03-08 国网重庆市电力公司江津供电分公司 A kind of transformer secondary side earthing detection protection system
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Publication number Priority date Publication date Assignee Title
JP2011038924A (en) * 2009-08-12 2011-02-24 Takaoka Electric Mfg Co Ltd Transformer failure determination device
JP2011196729A (en) * 2010-03-18 2011-10-06 Kansai Electric Power Co Inc:The Leak detection device and method for dc circuit
JP2011214963A (en) * 2010-03-31 2011-10-27 Takaoka Electric Mfg Co Ltd Failure determiner for transformer
US10396544B2 (en) 2015-04-22 2019-08-27 Panasonic Intellectual Property Management Co., Ltd. Shutoff device
JP2018074623A (en) * 2016-10-24 2018-05-10 富士電機株式会社 Uninterruptible power supply device
CN106483349A (en) * 2016-11-23 2017-03-08 国网重庆市电力公司江津供电分公司 A kind of transformer secondary side earthing detection protection system

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