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JP4096668B2 - Circuit breaker - Google Patents
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JP4096668B2 - Circuit breaker - Google Patents

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Publication number
JP4096668B2
JP4096668B2 JP2002260879A JP2002260879A JP4096668B2 JP 4096668 B2 JP4096668 B2 JP 4096668B2 JP 2002260879 A JP2002260879 A JP 2002260879A JP 2002260879 A JP2002260879 A JP 2002260879A JP 4096668 B2 JP4096668 B2 JP 4096668B2
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Japan
Prior art keywords
signal
circuit
circuit breaker
electric circuit
current
Prior art date
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JP2002260879A
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Japanese (ja)
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JP2004103308A (en
Inventor
貢一 西村
剛史 黒崎
弘二 広常
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Mitsubishi Electric Corp
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Mitsubishi Electric Corp
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Priority to JP2002260879A priority Critical patent/JP4096668B2/en
Priority to CNB031070213A priority patent/CN1309135C/en
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Description

【0001】
【発明の属する技術分野】
この発明は、電路に流れる負荷電流に応じて引外し動作を行う回路遮断器に関し、特に遮断器接点の開閉状態、負荷電流の通電状態に応じて限時引外し動作(長限時引外し動作、短限時引外し動作、及び瞬時引外し動作)の設定を変更可能にした回路遮断器に関するものである。
【0002】
【従来の技術】
図6は、例えば特開平6−245362号公報に示されたような従来の回路遮断器の構成を示すブロック図である。
図において、1は電路、2は回路遮断器、3は電路1に流れる電流を開閉する遮断器接点、4は電路1に流れる電流を検出する電流検出手段である電流センサ、5は電流センサ4で検出した信号を所定の信号に変換する信号変換部、6は信号変換部5から出力された信号を演算処理し、この信号に応じた引外し信号を後述のトリップコイル7に出力する演算部で、電路1に過電流が流れたときに電流センサから信号変換部5を介して入力された信号に応じた引外し信号をトリップコイル7に出力する。
【0003】
7は周知のごとく電磁石からなる機構部を有し、演算部6から出力された限時動作信号を受けてプランジャー(可動部分)の動きによって遮断器接点3を引外し動作させるトリップコイル、8は電路1を流れる電流によって電源回路9に電流を供給する変流器で、電源回路9は変流器8から入力された電流により信号変換部5及び演算部6に供給する電力を生成する。
【0004】
以上のように構成された回路遮断器2は、電路1に流れる負荷電流の大きさに応じ、回路遮断器の周知の限時引外し動作である長限時引外し動作、短限時引外し動作、及び瞬時引外し動作の3つの動作を行う。
【0005】
【発明が解決しようとする課題】
従来の回路遮断器は以上のように構成されており、電路に流れる負荷電流の大きさに応じて長限時引外し動作、短限引外し動作、及び瞬時引外し動作の3つの動作を行うように設定されているが、例えば、電路に接続された負荷がトランスなどの突入電流といった比較的大きなものが接続された場合、突入電流による誤動作を防ぐために回路遮断器を投入した時には、瞬時引外し動作をさせなくする必要がある。
【0006】
しかし、ただ単に瞬時引外しの動作をさせなくするようにした場合、回路遮断器投入後、負荷側において短絡事故などが起きた場合には回路遮断器本来の機能である電路を保護することができないため、回路遮断器を投入した時のみ瞬時引外し機能を動作させるようにする必要がある。この対応として回路遮断器の投入動作を機械的に検出し、検出結果に基づいて瞬時引外し動作をさせなくするという方式のものがあったが、この方式のものは、レバー、スプリング、分銅、スイッチなどの機構部品を組み合わせた構成であり、構造が複雑でコストが高くなると共に、機構部品で構成しているため、耐久性が劣るという問題があった。
【0007】
この発明は上記のような問題を解決するためになされたもので、構造が簡素で且つ信頼性の高い構成で、遮断器接点の開閉状態、負荷電流の通電状態に応じた限時引外し動作の設定を自動的に行うことができる回路遮断器を提供することを目的としている。
【0008】
【課題を解決するための手段】
この発明に係わる回路遮断器は、電路に流れる電流を開閉する遮断器接点と、この遮断器接点を引外し動作させるトリップコイルと、前記電路に流れる電流を検出する電流検出手段と、この電流検出手段で検出した信号を所定の信号に変換する信号変換部と、この信号変換部から出力された信号を演算処理しこの信号に応じた、長限時引外し動作、短限時引外し動作、及び瞬時引外し動作の各引外し信号を前記トリップコイルに出力する演算部とを備えた回路遮断器において、前記電路の前記遮断器接点より負荷側に配設され前記電路から入力された電圧に基づいて所定の時間遅らせた信号を出力する第1の遅延手段と、この第1の遅延手段から入力された信号と前記信号変換部から入力された信号に基づいて前記遮断器接点の開閉状態、負荷電流の通電状態を判定し、この判定結果を前記演算部に出力する判定部とを備え、前記第1の遅延手段は、電路の電圧を整流する整流回路と、この整流回路から入力された信号を遅延させて出力する遅延回路とにより構成されるとともに、前記電路が負荷電流通電状態で前記遮断器接点をONにしたときのみ、前記ON状態から所定の時間の間だけ、前記負荷電流の大きさに応じて前記瞬時引外し動作が行われるように構成したものである。
【0009】
また、第1の遅延手段に加え、電路の遮断器接点より電源側に配設され前記電路から入力された電圧に基づいて所定の時間遅らせた信号を出力する第2の遅延手段を備えたものである。
【0011】
また、遅延回路は電圧制限手段を備えたものである。
【0014】
【発明の実施の形態】
実施の形態1.
図1はこの発明の実施の形態1における回路遮断器の構成を示すブロック図である。
図において、1は電路、2aは回路遮断器、3は電路1に流れる電流を開閉する遮断器接点、4は電路1に流れる電流を検出する電流検出手段である電流センサ、5は電流センサ4で検出した信号を所定の信号に変換する信号変換部である。
【0015】
6は後述の判定部11の判定結果に基づいて、長限時引外し動作、短限時引外し動作、及び瞬時引外し動作の3つの限時引外し動作の中から所定の限時引外し動作を選択し設定を行うと共に、電路1に過電流が流れたときに電流センサから信号変換部5を介して入力された信号に応じた引外し信号を後述のトリップコイル7に出力する演算部である。
【0016】
7は周知のごとく電磁石からなる機構部を有し、演算部6から出力された限時動作信号を受けてプランジャー(可動部分)の動きによって遮断器接点3を引外し動作させるトリップコイル、8は電路1を流れる電流によって電源回路9に電流を供給する変流器で、電源回路9は変流器8から入力された電流により信号変換部5、演算部6、及び後述の判定部11に供給する電力を生成する。
【0017】
10は第1の遅延手段で、整流回路10a及び遅延回路10bにより構成され、電路1の負荷側から入力された電圧を整流した後平滑する整流回路10a、整流回路10aから入力された電圧を所定の時間、例えば100ms程度遅らせる機能を有する遅延回路10bから構成されている。11は第1の遅延手段10から入力された信号と信号変換部5から入力された信号に基づいて、遮断器接点3の開閉状態、負荷電流の通電状態を判定し、判定結果を演算部6に送る判定部である。
【0018】
図2は第1の遅延手段10の回路構成を示すもので、整流回路10aはブリッジダイオード10a1及び平滑コンデンサ10a2、遅延回路10bは抵抗10b1、電解コンデンサ10b2及び電圧制限手段である定電圧ダイオード10b3により構成され、抵抗10b1及び電解コンデンサ10b2の夫々の値は、信号変換部5が出力を開始する時間(例えば10ms)よりも第1の遅延手段10の出力が所定の時間、例えば100ms遅延するように設定されている。
【0019】
なお、定電圧ダイオード10b3の定電圧特性は、第1の遅延手段10から出力される電圧が所定の値(例えば10V)以上にならないと出力されないように設定されており、この定電圧ダイオード10b3を配設することにより、電路1から入力されたノイズ信号による判定部11の誤動作を防止することができる。
【0020】
図3は、この発明の実施の形態1における回路遮断器の動作を示すタイムチャートである。
次に以上のように構成されたこの発明の実施の形態1における回路遮断器の動作について説明する。
【0021】
最初に、電路1に負荷を接続状態(負荷電流通電状態)で回路遮断器2aを投入した場合について図3(a)を用いて説明する。
(1)遮断器接点3がON(S1)になる。
(2)変流器8が電路1を流れる負荷電流を検出し、電源回路9に電流を供給する。
【0022】
(3)電源回路9が電圧を発生(S2)し、信号変換部5、演算部6及び判定部11に電力を供給する。
(4)電路1に流れる負荷電流を電流センサ4が検出し、負荷電流に応じた信号を信号変換部5へ送出する。
【0023】
(5)信号変換部5は入力された信号を所定の信号に変換し、演算部6に出力すると共に、電路1に負荷電流が流れているという信号を判定部11に送出(S3)する。
(6)判定部11は第1の遅延手段10から入力された信号(出力信号なし)と信号変換部5から入力された信号(出力信号あり)により、遮断器接点3が投入されたことを検知し、結果を演算部6に送る(S4)。
【0024】
(7)演算部6に判定部11からの信号に基づいて、所定の時間(T1)、例えば100ms、長限時引外し動作、短限時引外し動作及び瞬時引外し動作を行う設定(S5)がされる。このとき、瞬時引外し動作を行うレベルの電流が電路1に流れていれば、トリップコイル7を駆動させ、遮断器接点3をOFFにする。
(8)所定の時間(T1)後、演算部6に長限時引外し動作及び短限時引外し動作を行う設定(S6)がされる。
【0025】
(9)第1の遅延手段10は入力された電路1の電圧を整流回路10aのダイオードブリッジ10a1で整流した後、平滑コンデンサ10a2で平滑し、遅延回路10bに入力され、抵抗10b1を介して電解コンデンサ10b2に充電される。電解コンデンサ10b2の電圧は抵抗10b1及び電解コンデンサ10b2で決定される時定数で徐々に増加し、電圧が定電圧ダイオード10b3の定電圧値に達する(T2)と、判定部11へ信号を出力(S7)する。
なお、この時点においては演算部6での設定処理を完了しており、出力信号(S7)は無視される。
【0026】
次に、回路遮断器2aが投入状態で無負荷から負荷状態になった場合について図3(b)を用いて説明する。
(1)無負荷(電路1に電圧が印加された状態で負荷電流が流れていない状態)においては、第1の遅延手段10が電圧を出力(S11)する。
(2)電路1に負荷電流が通電(S12)される。
【0027】
(3)電源回路9が電圧を発生(S13)し、信号変換部5、演算部6及び判定部11に電力を供給する。
(4)電路1に流れる負荷電流を電流センサ4が検出し、負荷電流に応じた信号を信号変換部5へ送出する。
【0028】
(5)信号変換部5は入力された信号を所定の信号に変換し、演算部6に出力すると共に、電路1に負荷電流が流れているという信号を判定部11に送出(S14)する。
(6)判定部11は第1の遅延手段10から入力された信号(出力信号あり)と信号変換部5から入力された信号(出力信号あり)により、遮断器接点3が投入状態の時に電路1に負荷電流が流れたことを検知し、結果を演算部6に送る(S15)。
【0029】
(7)演算部6に長限時引外し動作及び短限時引外し動作を行う設定(S16)がされる。
以上のように、この発明の実施の形態1における回路遮断器は、構造が簡素で且つ、信頼性の高い構成で、遮断器接点の開閉状態、負荷電流の通電状態に応じた限時引外し動作の設定を自動的に行うことができる。
【0030】
実施の形態2
図4はこの発明の実施の形態2における回路遮断器の構成を示すブロック図、図5は、この発明の実施の形態2における回路遮断器の動作を示すタイムチャートである。
【0031】
図において、2bは回路遮断器、12は整流回路12a、及び遅延回路12bにより構成された第2の遅延手段で、この第2の遅延手段12の回路構成は上述した実施の形態1における第1の遅延手段10と同様である。
なお、1、3〜11については上述した実施の形態1と同様であり、同一の番号を付し説明を省略する。
【0032】
次に以上のように構成されたこの発明の実施の形態2おける回路遮断器の動作について説明する。
最初に、電路1に負荷を接続状態(負荷電流通電状態)で回路遮断器2b投入した場合について図5(a)を用いて説明する。
【0033】
(1)遮断器接点3がON(S21)になる。
(2)第2の遅延手段12は電路1に電圧が印加された状態であり、電圧を出力(S22)中である。
(3)変流器8が電路1を流れる負荷電流を検出し、電源回路9に電流を供給する。
【0034】
(4)電源回路9が電圧を発生(S23)し、信号変換部5、演算部6及び判定部11に電力を供給する。
(5)電路1に流れる負荷電流を電流センサ4が検出し、負荷電流に応じた信号を信号変換部5へ送出する。
【0035】
(6)信号変換部5は入力された信号を所定の信号に変換し、演算部6に出力すると共に、電路1に負荷電流が流れているという信号を判定部11に送出(S24)する。
(7)判定部11は第1の遅延手段10から入力された信号(出力信号なし)、第2の遅延手段12から入力された信号(出力信号あり)、及び信号変換部5から入力された信号(出力信号あり)により、遮断器接点3が投入されたことを検知し、結果を演算部6に送る(S25)。
【0036】
(8)演算部6に判定部11からの信号に基づいて、所定の時間(T3)、例えば100ms、長限時引外し動作、短限時引外し動作及び瞬時引外し動作を行う設定(S26)がされる。このとき、瞬時引外し動作を行うレベルの電流が電路1に流れていれば、トリップコイル7を駆動させ、遮断器接点3をOFFにする。
(8)所定の時間(T3)後、演算部6に長限時引外し動作及び短限時引外し動作を行う設定(S27)がされる。
【0037】
(9)第1の遅延手段10は入力された電路1の電圧を整流回路10aのダイオードブリッジ10a1で整流した後、平滑コンデンサ10a2で平滑し、遅延回路10bに入力され、抵抗10b1を介して電解コンデンサ10b2に充電される。電解コンデンサ10b2の電圧は抵抗10b1及び電解コンデンサ10b2で決定される時定数で徐々に増加し、電圧が定電圧ダイオード10b3の定電圧値に達する(T4)と、判定部11へ信号を出力(S28)する。
なお、この時点においては演算部6での設定処理を完了しており、出力信号(S28)は無視される。
【0038】
次に、回路遮断器2bが投入状態で無負荷から負荷状態になった場合について図5(b)を用いて説明する。
(1)無負荷(電路1に電圧が印加された状態で負荷電流が流れていない状態)においては、第1の遅延手段10及び第2の遅延手段12が電圧を出力(S31,32)する。
(2)電路1に負荷電流が通電(S33)される。
【0039】
(3)電源回路9が電圧を発生(S34)し、信号変換部5、演算部6及び判定部11に電力を供給する。
(4)電路1に流れる負荷電流を電流センサ4が検出し、負荷電流に応じた信号を信号変換部5へ送出する。
【0040】
(5)信号変換部5は入力された信号を所定の信号に変換し、演算部6に出力すると共に、電路1に負荷電流が流れているという信号を判定部11に送出(S35)する。
(6)判定部11は第1の遅延手段10から入力された信号(出力信号あり)、第2の遅延手段12から入力された信号(出力信号あり)、及び信号変換部5から入力された信号(出力信号あり)により、遮断器接点3が投入状態の時に電路1に負荷電流が流れたことを検知し、結果を演算部6に送る(S36)。
(7)演算部6に長限時引外し動作及び短限時引外し動作を行う設定(S37)がされる。
【0041】
なお、この発明の実施の形態2における回路遮断器は、図4に示すように電源側、負荷側の両方に遅延手段である第1の遅延手段10、第2の遅延手段12が配設されており、回路遮断器2bを電路1に対して逆接続した場合においても、上述と同様の動作を行う。
【0042】
以上のように、この発明の実施の形態2における回路遮断器は、発明の実施の形態1における回路遮断器が負荷側にのみ遅延手段を配設していたものに対して、電源側、負荷側の両方に遅延手段が配設されているので、回路遮断器2bを電路1に対して逆接続した場合においても、構造が簡素で且つ、信頼性の高い構成で、遮断器接点の開閉状態、負荷電流の通電状態に応じ限時引外し動作の設定を自動的に行うことができる。
【0043】
【発明の効果】
この発明によれば、電路に流れる電流を開閉する遮断器接点と、この遮断器接点を引外し動作させるトリップコイルと、電路に流れる電流を検出する電流検出手段と、この電流検出手段で検出した信号を所定の信号に変換する信号変換部と、この信号変換部から出力された信号を演算処理しこの信号に応じた、長限時引外し動作、短限時引外し動作、及び瞬時引外し動作の各引外し信号をトリップコイルに出力する演算部とを備えた回路遮断器において、電路の断器接点より負荷側に配設され電路から入力された電圧に基づいて所定の時間遅らせた信号を出力する第1の遅延手段と、この第1の遅延手段から入力された信号と号変換部から入力された信号に基づいて遮断器接点の開閉状態、負荷電流の通電状態を判定し、この判定結果を演算部に出力する判定部とを備え、第1の遅延手段は、電路の電圧を整流する整流回路と、この整流回路から入力された信号を遅延させて出力する遅延回路とにより構成されるとともに、電路が負荷電流通電状態で遮断器接点をONにしたときのみ、ON状態から所定の時間の間だけ、負荷電流の大きさに応じて瞬時引外し動作が行われるように構成したので、構造が簡素で且つ、信頼性の高い構成で、遮断器接点の開閉状態、負荷電流の通電状態に応じた引外し動作の設定を自動的に行うことができるとともに、電路に接続された負荷がトランスなどの突入電流といった比較的大きなものが接続された場合に突入電流による誤動作がなく、また、簡素な構成で遅延信号を生成できる。
【0044】
また、第1の遅延手段に加え、電路の遮断器接点より電源側に配設され電路から入力された電圧に基づいて所定の時間遅らせた信号を出力する第2の遅延手段を備えたので、回路遮断器を電路に対して逆接続した場合においても、構造が簡素で且つ、信頼性の高い構成で、遮断器接点の開閉状態、負荷電流の通電状態に応じ限時引外し動作の設定を自動的に行うことができる。
【0046】
また、遅延回路は電圧制限手段を備えたので、電路から入力されたノイズ信号による判定部の誤動作を防止することができる。
【図面の簡単な説明】
【図1】 この発明の実施の形態1における回路遮断器の構成を示すブロック図である。
【図2】 図1の回路遮断器を構成する第1の遅延手段の回路構成である。
【図3】 この発明の実施の形態1における回路遮断器の動作を示すタイムチャートである。
【図4】 この発明の実施の形態2における回路遮断器の構成を示すブロック図である。
【図5】 この発明の実施の形態2における回路遮断器の動作を示すタイムチャートである。
【図6】 従来の回路遮断器の構成を示すブロック図である。
【符号の説明】
1 電路、2a,2b 回路遮断器、3 遮断器接点、
4 電流センサ(電流検出手段)、5 信号変換部、6 演算部、
7 トリップコイル、10 第1の遅延手段、10a 整流回路、
10b 遅延回路、10b3 電圧制限手段、11 判定部、
12 第2の遅延手段。
[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a circuit breaker that performs a tripping operation according to a load current flowing in an electric circuit, and in particular, a time-delaying operation (a long-time tripping operation, a short-time tripping operation according to a switching state of a circuit breaker contact and an energization state of a load current The present invention relates to a circuit breaker that can change the setting of a time-delay trip operation and an instantaneous trip operation.
[0002]
[Prior art]
FIG. 6 is a block diagram showing a configuration of a conventional circuit breaker as disclosed in, for example, JP-A-6-245362.
In the figure, 1 is an electric circuit, 2 is a circuit breaker, 3 is a circuit breaker contact for opening and closing a current flowing in the electric circuit 1, 4 is a current sensor which is a current detecting means for detecting a current flowing in the electric circuit 1, and 5 is a current sensor 4. A signal conversion unit that converts the signal detected in step 1 into a predetermined signal, and 6 is a calculation unit that processes the signal output from the signal conversion unit 5 and outputs a trip signal corresponding to this signal to a trip coil 7 described later. Thus, when an overcurrent flows in the electric circuit 1, a trip signal corresponding to the signal input from the current sensor 4 via the signal converter 5 is output to the trip coil 7.
[0003]
7 is a trip coil having an electromagnet mechanism as is well known, which receives a time limit operation signal output from the calculation unit 6 and trips the circuit breaker contact 3 by the movement of the plunger (movable part). A current transformer that supplies a current to the power supply circuit 9 by a current flowing through the electric circuit 1, and the power supply circuit 9 generates power to be supplied to the signal conversion unit 5 and the calculation unit 6 by the current input from the current transformer 8.
[0004]
The circuit breaker 2 configured as described above has a long-time tripping operation, a short-time tripping operation that is a well-known time-tripping operation of the circuit breaker, and a short-time tripping operation according to the magnitude of the load current flowing in the electric circuit 1. Three operations are performed: instantaneous trip operation.
[0005]
[Problems to be solved by the invention]
The conventional circuit breaker is configured as described above, and performs three operations, a long-time trip operation, a short-time trip operation, and an instantaneous trip operation according to the magnitude of the load current flowing in the electric circuit. For example, when a relatively large load such as an inrush current such as a transformer is connected to a load connected to the electric circuit, when a circuit breaker is turned on to prevent malfunction due to the inrush current, instantaneous tripping is performed. It is necessary to prevent operation.
[0006]
However, if the operation of the momentary trip is simply disabled, the circuit that is the original function of the circuit breaker may be protected if a short circuit accident occurs on the load side after the circuit breaker is turned on. It is not possible to operate the instantaneous trip function only when the circuit breaker is turned on. As a response to this, there was a method of mechanically detecting the closing operation of the circuit breaker and stopping the instantaneous trip operation based on the detection result, but this method has a lever, spring, weight, The structure is a combination of mechanical parts such as a switch. The structure is complicated and the cost is high, and the structure is composed of mechanical parts.
[0007]
The present invention has been made to solve the above-described problems, and has a simple structure and high reliability, and is capable of performing a time-delay operation according to the open / close state of the circuit breaker contact and the energization state of the load current. An object of the present invention is to provide a circuit breaker that can be automatically set.
[0008]
[Means for Solving the Problems]
A circuit breaker according to the present invention comprises a circuit breaker contact for opening and closing a current flowing in an electric circuit, a trip coil for tripping the circuit breaker contact, a current detecting means for detecting a current flowing in the electric circuit, and the current detection A signal conversion unit for converting the signal detected by the means into a predetermined signal , a long time trip operation, a short time trip operation, and a momentary operation according to the signal processed from the signal conversion unit. A circuit breaker including a calculation unit that outputs each trip signal of the trip operation to the trip coil, based on a voltage that is disposed on the load side of the circuit breaker contact and that is input from the circuit. A first delay means for outputting a signal delayed by a predetermined time; a signal input from the first delay means and a signal input from the signal converter; Determine the conductive state of the current, and a determination unit that outputs a judgment result to the calculation unit, said first delay means includes a rectifier circuit and a signal input from the rectifier circuit for rectifying the circuit of voltage And a delay circuit for delaying and outputting the load current, and only when the circuit breaker contact is turned ON while the current path is in the load current energized state, the load current is increased only for a predetermined time from the ON state. Accordingly, the instantaneous tripping operation is performed accordingly .
[0009]
Further, in addition to the first delay means, there is provided second delay means arranged on the power supply side from the circuit breaker contact of the electric circuit and outputting a signal delayed for a predetermined time based on the voltage inputted from the electric circuit. It is.
[0011]
The delay circuit includes voltage limiting means.
[0014]
DETAILED DESCRIPTION OF THE INVENTION
Embodiment 1 FIG.
1 is a block diagram showing a configuration of a circuit breaker according to Embodiment 1 of the present invention.
In the figure, 1 is an electric circuit, 2a is a circuit breaker, 3 is a circuit breaker contact that opens and closes a current flowing through the electric circuit 1, 4 is a current sensor that is a current detecting means for detecting a current flowing through the electric circuit 1, and 5 is a current sensor 4. It is a signal conversion part which converts the signal detected by (1) into a predetermined signal.
[0015]
6 selects a predetermined time-delay operation from three time-delay operations: a long-time trip operation, a short-time trip operation, and an instantaneous trip operation based on the determination result of the determination unit 11 described later. A calculation unit that performs setting and outputs a trip signal corresponding to a signal input from the current sensor 4 via the signal conversion unit 5 to an after-mentioned trip coil 7 when an overcurrent flows in the electric circuit 1.
[0016]
7 is a trip coil having an electromagnet mechanism as is well known, which receives a time limit operation signal output from the calculation unit 6 and trips the circuit breaker contact 3 by the movement of the plunger (movable part). A current transformer that supplies current to the power supply circuit 9 by the current flowing through the electric circuit 1, and the power supply circuit 9 is supplied to the signal conversion unit 5, the calculation unit 6, and a later-described determination unit 11 by the current input from the current transformer 8. Power to generate.
[0017]
Reference numeral 10 denotes a first delay unit, which includes a rectifier circuit 10a and a delay circuit 10b. The rectifier circuit 10a rectifies the voltage input from the load side of the electric circuit 1 and then smoothes the voltage. The voltage input from the rectifier circuit 10a is predetermined. For example, a delay circuit 10b having a function of delaying about 100 ms . 11 determines the open / close state of the circuit breaker contact 3 and the energization state of the load current based on the signal input from the first delay means 10 and the signal input from the signal conversion unit 5, and the determination result is calculated by the calculation unit 6. It is the determination part sent to.
[0018]
FIG. 2 shows the circuit configuration of the first delay means 10. The rectifier circuit 10a is composed of a bridge diode 10a1 and a smoothing capacitor 10a2, the delay circuit 10b is composed of a resistor 10b1, an electrolytic capacitor 10b2, and a constant voltage diode 10b3 which is a voltage limiting means. The values of the resistor 10b1 and the electrolytic capacitor 10b2 are set so that the output of the first delay means 10 is delayed by a predetermined time, for example, 100 ms, from the time (for example, 10 ms) when the signal converter 5 starts output. Is set.
[0019]
The constant voltage characteristic of the constant voltage diode 10b3 is set so that the voltage is not output unless the voltage output from the first delay means 10 exceeds a predetermined value (for example, 10V). By disposing, the malfunction of the determination unit 11 due to the noise signal input from the electric circuit 1 can be prevented.
[0020]
FIG. 3 is a time chart showing the operation of the circuit breaker according to Embodiment 1 of the present invention.
Next, the operation of the circuit breaker configured as described above in Embodiment 1 of the present invention will be described.
[0021]
First, the case where the circuit breaker 2a is turned on with a load connected to the electric circuit 1 (load current energized state) will be described with reference to FIG.
(1) The circuit breaker contact 3 is turned on (S1).
(2) The current transformer 8 detects the load current flowing through the electric circuit 1 and supplies the current to the power supply circuit 9.
[0022]
(3) The power supply circuit 9 generates a voltage (S2) and supplies power to the signal conversion unit 5, the calculation unit 6, and the determination unit 11 .
(4) The current sensor 4 detects the load current flowing in the electric circuit 1 and sends a signal corresponding to the load current to the signal converter 5.
[0023]
(5) The signal conversion unit 5 converts the input signal into a predetermined signal, outputs the signal to the calculation unit 6, and sends a signal that a load current is flowing in the electric circuit 1 to the determination unit 11 (S3).
(6) The determination unit 11 confirms that the circuit breaker contact 3 has been turned on based on the signal input from the first delay means 10 (no output signal) and the signal input from the signal conversion unit 5 (with output signal). It detects and sends a result to the calculating part 6 (S4).
[0024]
(7) Based on the signal from the determination unit 11, the calculation unit 6 is set to perform a predetermined time ( T1 ), for example, 100 ms, a long time trip operation, a short time trip operation, and an instantaneous trip operation (S5). Is done. At this time, if a current of a level for performing an instantaneous trip operation is flowing in the electric circuit 1, the trip coil 7 is driven and the circuit breaker contact 3 is turned off.
(8) After a predetermined time ( T1 ), the operation unit 6 is set to perform the long time trip operation and the short time trip operation (S6).
[0025]
(9) The first delay means 10 rectifies the input voltage of the electric circuit 1 by the diode bridge 10a1 of the rectifier circuit 10a, smoothes it by the smoothing capacitor 10a2, is input to the delay circuit 10b, and is electrolyzed through the resistor 10b1. The capacitor 10b2 is charged. The voltage of the electrolytic capacitor 10b2 gradually increases with a time constant determined by the resistor 10b1 and the electrolytic capacitor 10b2, and when the voltage reaches the constant voltage value of the constant voltage diode 10b3 (T2), a signal is output to the determination unit 11 (S7). )
At this time, the setting process in the calculation unit 6 is completed, and the output signal (S7) is ignored.
[0026]
Next, a case where the circuit breaker 2a is switched from no load to a load state when the circuit breaker 2a is turned on will be described with reference to FIG.
(1) In a no-load state (a state where a voltage is applied to the electric circuit 1 and no load current flows), the first delay means 10 outputs a voltage (S11).
(2) A load current is applied to the electric circuit 1 (S12).
[0027]
(3) The power supply circuit 9 generates a voltage (S13) and supplies power to the signal conversion unit 5, the calculation unit 6, and the determination unit 11.
(4) The current sensor 4 detects the load current flowing in the electric circuit 1 and sends a signal corresponding to the load current to the signal converter 5.
[0028]
(5) The signal conversion unit 5 converts the input signal into a predetermined signal, outputs the signal to the calculation unit 6, and sends a signal that a load current is flowing in the electric circuit 1 to the determination unit 11 (S14).
(6) The determination unit 11 uses the signal input from the first delay means 10 (with an output signal) and the signal input from the signal conversion unit 5 (with an output signal) when the circuit breaker contact 3 is in the on state. 1 detects that a load current has flowed to 1 and sends the result to the calculation unit 6 (S15).
[0029]
(7) The operation unit 6 is set to perform the long time trip operation and the short time trip operation (S16).
As described above, the circuit breaker according to the first embodiment of the present invention has a simple structure and a highly reliable configuration, and a time-release trip operation according to the open / close state of the breaker contact and the energization state of the load current. Can be set automatically.
[0030]
Embodiment 2
FIG. 4 is a block diagram showing the configuration of the circuit breaker according to Embodiment 2 of the present invention, and FIG. 5 is a time chart showing the operation of the circuit breaker according to Embodiment 2 of the present invention.
[0031]
In the figure, 2b is a circuit breaker, 12 is a second delay means constituted by a rectifier circuit 12a and a delay circuit 12b, and the circuit configuration of the second delay means 12 is the first in the first embodiment described above. This is the same as the delay means 10.
In addition, about 1 and 3-11, it is the same as that of Embodiment 1 mentioned above, attaches | subjects the same number and abbreviate | omits description.
[0032]
Next description is given of operations performed by the circuit breaker definitive to the second embodiment of the present invention as described above will be described.
First, a case where the circuit breaker 2b is turned on with a load connected to the electric circuit 1 (load current energized state) will be described with reference to FIG.
[0033]
(1) The circuit breaker contact 3 is turned ON (S21).
(2) The second delay means 12 is in a state where a voltage is applied to the electric circuit 1 and is outputting a voltage (S22).
(3) The current transformer 8 detects the load current flowing through the electric circuit 1 and supplies the current to the power supply circuit 9.
[0034]
(4) The power supply circuit 9 generates a voltage (S23) and supplies power to the signal conversion unit 5, the calculation unit 6, and the determination unit 11 .
(5) The current sensor 4 detects the load current flowing through the electric circuit 1 and sends a signal corresponding to the load current to the signal converter 5.
[0035]
(6) The signal conversion unit 5 converts the input signal into a predetermined signal, outputs the signal to the calculation unit 6, and sends a signal that a load current is flowing through the electric circuit 1 to the determination unit 11 (S24).
(7) The determination unit 11 receives the signal input from the first delay unit 10 (no output signal), the signal input from the second delay unit 12 (with an output signal), and the signal conversion unit 5 A signal (with an output signal) detects that the circuit breaker contact 3 has been turned on, and sends the result to the arithmetic unit 6 (S25).
[0036]
(8) Based on the signal from the determination unit 11, the setting of the predetermined time (T3), for example, 100 ms, the long time trip operation, the short time trip operation, and the instantaneous trip operation is set in the calculation unit 6 (S26). Is done. At this time, if a current of a level for performing an instantaneous trip operation is flowing in the electric circuit 1, the trip coil 7 is driven and the circuit breaker contact 3 is turned off.
(8) After a predetermined time (T3), the operation unit 6 is set to perform the long time trip operation and the short time trip operation (S27).
[0037]
(9) The first delay means 10 rectifies the input voltage of the electric circuit 1 by the diode bridge 10a1 of the rectifier circuit 10a, smoothes it by the smoothing capacitor 10a2, is input to the delay circuit 10b, and is electrolyzed through the resistor 10b1. The capacitor 10b2 is charged. The voltage of the electrolytic capacitor 10b2 gradually increases with a time constant determined by the resistor 10b1 and the electrolytic capacitor 10b2, and when the voltage reaches the constant voltage value of the constant voltage diode 10b3 (T4), a signal is output to the determination unit 11 (S28). )
At this time, the setting process in the calculation unit 6 is completed, and the output signal (S28) is ignored.
[0038]
Next, the case where the circuit breaker 2b changes from the no load to the loaded state in the on state will be described with reference to FIG.
(1) When there is no load (a state where a voltage is applied to the electric circuit 1 and no load current flows), the first delay means 10 and the second delay means 12 output voltages (S31, 32). .
(2) A load current is supplied to the electric circuit 1 (S33).
[0039]
(3) The power supply circuit 9 generates a voltage (S34) and supplies power to the signal conversion unit 5, the calculation unit 6, and the determination unit 11.
(4) The current sensor 4 detects the load current flowing in the electric circuit 1 and sends a signal corresponding to the load current to the signal converter 5.
[0040]
(5) The signal conversion unit 5 converts the input signal into a predetermined signal, outputs the signal to the calculation unit 6, and sends a signal that a load current is flowing through the electric circuit 1 to the determination unit 11 (S35).
(6) The determination unit 11 receives the signal input from the first delay unit 10 (with an output signal), the signal input from the second delay unit 12 (with an output signal), and the signal conversion unit 5 A signal (with an output signal) detects that a load current has flowed through the electric circuit 1 when the circuit breaker contact 3 is in the on state, and sends the result to the calculation unit 6 (S36).
(7) The operation unit 6 is set to perform the long time trip operation and the short time trip operation (S37).
[0041]
In the circuit breaker according to the second embodiment of the present invention, as shown in FIG. 4, the first delay means 10 and the second delay means 12 which are delay means are arranged on both the power supply side and the load side. Even when the circuit breaker 2b is reversely connected to the electric circuit 1, the same operation as described above is performed.
[0042]
As described above, the circuit breaker according to the second embodiment of the present invention is different from the circuit breaker according to the first embodiment in which the delay unit is provided only on the load side, Since the delay means are arranged on both sides, even when the circuit breaker 2b is reversely connected to the electric circuit 1, the circuit breaker contact is opened and closed with a simple structure and high reliability. The time-delay trip operation can be automatically set according to the energization state of the load current.
[0043]
【The invention's effect】
According to the present invention, the circuit breaker contact for opening and closing the current flowing in the electric circuit, the trip coil for tripping the circuit breaker contact, the current detecting means for detecting the current flowing in the electric circuit, and the current detecting means A signal conversion unit that converts a signal into a predetermined signal, and a signal that is output from the signal conversion unit is subjected to arithmetic processing, and a long-time trip operation, a short-time trip operation, and an instantaneous trip operation according to the signal in the circuit breaker and an arithmetic unit for outputting to each trip the trip coil of the signal, a signal obtained by delaying a predetermined time based on the voltage input from the path disposed from the breakers contacts path on the load side determining a first delay means for outputting opening and closing state of the first signal input from the delay unit and the circuit breaker contacts on the basis of a signal input from the signal conversion unit, the current state of the load current, the Judgment result And a determination section for outputting a calculation unit, a first delay means, a rectifying circuit for rectifying the circuit of the voltage, while being constituted by a delay circuit for delaying and outputting an input signal from the rectifier circuit The structure is such that only when the circuit breaker contact is turned on with the load circuit energized, the instantaneous trip operation is performed according to the magnitude of the load current for a predetermined time from the on state. With a simple and reliable configuration, it is possible to automatically set the tripping operation according to the open / close state of the circuit breaker contact and the energization state of the load current, and the load connected to the electric circuit can When a relatively large current such as an inrush current is connected, there is no malfunction due to the inrush current, and a delay signal can be generated with a simple configuration.
[0044]
Further, in addition to the first delay means, since the second delay means for outputting a signal delayed for a predetermined time based on the voltage input from the electric circuit is provided on the power supply side from the circuit breaker contact of the electric circuit, Even when the circuit breaker is reversely connected to the circuit, the structure is simple and reliable, and the time-lapse trip operation is automatically set according to the circuit breaker contact open / close state and load current energization state. Can be done automatically.
[0046]
In addition, since the delay circuit includes the voltage limiting unit, it is possible to prevent the determination unit from malfunctioning due to a noise signal input from the electric circuit.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a circuit breaker according to Embodiment 1 of the present invention.
FIG. 2 is a circuit configuration of first delay means constituting the circuit breaker of FIG.
FIG. 3 is a time chart showing the operation of the circuit breaker according to Embodiment 1 of the present invention.
FIG. 4 is a block diagram showing a configuration of a circuit breaker according to Embodiment 2 of the present invention.
FIG. 5 is a time chart showing the operation of the circuit breaker according to Embodiment 2 of the present invention.
FIG. 6 is a block diagram showing a configuration of a conventional circuit breaker.
[Explanation of symbols]
1 circuit, 2a, 2b circuit breaker, 3 circuit breaker contact,
4 current sensor (current detection means), 5 signal conversion unit, 6 calculation unit,
7 trip coil, 10 first delay means, 10a rectifier circuit,
10b delay circuit, 10b3 voltage limiting means, 11 determination unit,
12 Second delay means.

Claims (3)

電路に流れる電流を開閉する遮断器接点と、
この遮断器接点を引外し動作させるトリップコイルと、
前記電路に流れる電流を検出する電流検出手段と、
この電流検出手段で検出した信号を所定の信号に変換する信号変換部と、
この信号変換部から出力された信号を演算処理しこの信号に応じた、長限時引外し動作、短限時引外し動作、及び瞬時引外し動作の各引外し信号を前記トリップコイルに出力する演算部とを備えた回路遮断器において、
前記電路の前記遮断器接点より負荷側に配設され前記電路から入力された電圧に基づいて所定の時間遅らせた信号を出力する第1の遅延手段と、
この第1の遅延手段から入力された信号と前記信号変換部から入力された信号に基づいて前記遮断器接点の開閉状態、負荷電流の通電状態を判定し、この判定結果を前記演算部に出力する判定部とを備え、
前記第1の遅延手段は、電路の電圧を整流する整流回路と、この整流回路から入力された信号を遅延させて出力する遅延回路とにより構成されるとともに、
前記電路が負荷電流通電状態で前記遮断器接点をONにしたときのみ、前記ON状態から所定の時間の間だけ、前記負荷電流の大きさに応じて前記瞬時引外し動作が行われるように構成したことを特徴とする回路遮断器。
A circuit breaker contact that opens and closes the current flowing in the circuit;
A trip coil for tripping the circuit breaker contact;
Current detecting means for detecting a current flowing in the electric circuit;
A signal converter that converts the signal detected by the current detection means into a predetermined signal;
An arithmetic unit that performs arithmetic processing on the signal output from the signal conversion unit and outputs each trip signal of the long-time trip operation, short-time trip operation, and instantaneous trip operation to the trip coil according to the signal. In a circuit breaker with
First delay means disposed on a load side of the circuit breaker contact of the electric circuit and outputting a signal delayed by a predetermined time based on a voltage input from the electric circuit;
Based on the signal inputted from the first delay means and the signal inputted from the signal conversion unit, the switching state of the circuit breaker contact and the energization state of the load current are determined, and the determination result is output to the calculation unit. And a determination unit for
The first delay means includes a rectifier circuit that rectifies the voltage of the electric circuit, and a delay circuit that delays and outputs a signal input from the rectifier circuit.
Only when the circuit breaker contact is turned ON while the electric circuit is in a load current energization state, the instantaneous trip operation is performed according to the magnitude of the load current only for a predetermined time from the ON state. A circuit breaker characterized by that.
電路に流れる電流を開閉する遮断器接点と、A circuit breaker contact that opens and closes the current flowing in the circuit;
この遮断器接点を引外し動作させるトリップコイルと、A trip coil for tripping the circuit breaker contact;
前記電路に流れる電流を検出する電流検出手段と、Current detecting means for detecting a current flowing in the electric circuit;
この電流検出手段で検出した信号を所定の信号に変換する信号変換部と、A signal converter that converts the signal detected by the current detection means into a predetermined signal;
この信号変換部から出力された信号を演算処理しこの信号に応じた、長限時引外し動作、短限時引外し動作、及び瞬時引外し動作の各引外し信号を前記トリップコイルに出力する演算部とを備えた回路遮断器において、An arithmetic unit that performs arithmetic processing on the signal output from the signal conversion unit and outputs each trip signal of the long-time trip operation, short-time trip operation, and instantaneous trip operation to the trip coil according to the signal. In a circuit breaker with
前記電路の前記遮断器接点より負荷側に配設され前記電路から入力された電圧に基づいて所定の時間遅らせた信号を出力する第1の遅延手段と、First delay means disposed on a load side of the circuit breaker contact of the electric circuit and outputting a signal delayed by a predetermined time based on a voltage input from the electric circuit;
前記電路の前記遮断器接点より電源側に配設され前記電路から入力された電圧に基づいて所定の時間遅らせた信号を出力する第2の遅延手段と、Second delay means arranged on the power supply side of the circuit breaker contact of the electric circuit and outputting a signal delayed for a predetermined time based on the voltage input from the electric circuit;
これら第1及び第2の遅延手段から入力された信号と前記信号変換部から入力された信号に基づいて前記遮断器接点の開閉状態、負荷電流の通電状態を判定し、この判定結果を前記演算部に出力する判定部とを備え、Based on the signals input from the first and second delay means and the signal input from the signal converter, the circuit breaker contact open / close state and load current energization state are determined, and the determination result is calculated as the calculation result. A determination unit that outputs to the unit,
前記第1及び第2の遅延手段は、電路の電圧を整流する整流回路と、この整流回路から入力された信号を遅延させて出力する遅延回路とにより構成されるとともに、The first and second delay means include a rectifier circuit that rectifies the voltage of the electric circuit, and a delay circuit that delays and outputs a signal input from the rectifier circuit, and
前記電路が負荷電流通電状態で前記遮断器接点をONにしたときのみ、前記ON状態から所定の時間の間だけ、前記負荷電流の大きさに応じて前記瞬時引外し動作が行われるように構成したことを特徴とする回路遮断器。Only when the circuit breaker contact is turned ON while the electric circuit is in a load current energization state, the instantaneous trip operation is performed according to the magnitude of the load current only for a predetermined time from the ON state. A circuit breaker characterized by that.
遅延回路は電圧制限手段を備えたことを特徴とする請求項1または2記載の回路遮断器。3. The circuit breaker according to claim 1, wherein the delay circuit includes voltage limiting means.
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