EP3506330B1 - Treiberschaltung für elektromagnetischen betriebsmechanismus - Google Patents

Treiberschaltung für elektromagnetischen betriebsmechanismus Download PDF

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Publication number
EP3506330B1
EP3506330B1 EP16914221.3A EP16914221A EP3506330B1 EP 3506330 B1 EP3506330 B1 EP 3506330B1 EP 16914221 A EP16914221 A EP 16914221A EP 3506330 B1 EP3506330 B1 EP 3506330B1
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EP
European Patent Office
Prior art keywords
contact
switch element
closing
contact closing
opening
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Active
Application number
EP16914221.3A
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English (en)
French (fr)
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EP3506330A1 (de
EP3506330A4 (de
Inventor
Yuto Kikuchi
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Mitsubishi Electric Corp
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Mitsubishi Electric Corp
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Publication of EP3506330A1 publication Critical patent/EP3506330A1/de
Publication of EP3506330A4 publication Critical patent/EP3506330A4/de
Application granted granted Critical
Publication of EP3506330B1 publication Critical patent/EP3506330B1/de
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    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01HELECTRIC SWITCHES; RELAYS; SELECTORS; EMERGENCY PROTECTIVE DEVICES
    • H01H33/00High-tension or heavy-current switches with arc-extinguishing or arc-preventing means
    • H01H33/02Details
    • H01H33/28Power arrangements internal to the switch for operating the driving mechanism
    • H01H33/38Power arrangements internal to the switch for operating the driving mechanism using electromagnet
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01HELECTRIC SWITCHES; RELAYS; SELECTORS; EMERGENCY PROTECTIVE DEVICES
    • H01H33/00High-tension or heavy-current switches with arc-extinguishing or arc-preventing means
    • H01H33/60Switches wherein the means for extinguishing or preventing the arc do not include separate means for obtaining or increasing flow of arc-extinguishing fluid
    • H01H33/66Vacuum switches
    • H01H33/666Operating arrangements
    • H01H33/6662Operating arrangements using bistable electromagnetic actuators, e.g. linear polarised electromagnetic actuators
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01HELECTRIC SWITCHES; RELAYS; SELECTORS; EMERGENCY PROTECTIVE DEVICES
    • H01H47/00Circuit arrangements not adapted to a particular application of the relay and designed to obtain desired operating characteristics or to provide energising current
    • H01H47/22Circuit arrangements not adapted to a particular application of the relay and designed to obtain desired operating characteristics or to provide energising current for supplying energising current for relay coil
    • H01H47/226Circuit arrangements not adapted to a particular application of the relay and designed to obtain desired operating characteristics or to provide energising current for supplying energising current for relay coil for bistable relays

Definitions

  • the present invention relates to an electromagnetic operation mechanism drive circuit having a protection circuit in, for example, electromagnetic operation mechanism drive circuits that perform opening/closing operation of electric power apparatuses.
  • a known electromagnetic operation mechanism drive circuit that performs opening/closing operation of an electric power apparatus, for example, a vacuum valve of a vacuum circuit breaker, in the case of having two driving coils for contact closing and contact opening with respect to one movable core, when current is made to flow to one driving coil, voltage is generated by induced electromotive force at both ends of other driving coil to which current is not made to flow.
  • the generated voltage is proportional to the ratio of winding turns of both driving coils; and thus, for example, when the number of winding turns of the driving coil for contact opening is 100 turns and the number of winding turns of the driving coil for contact closing is 500 turns, if a voltage of 100 v is applied to the driving coil for contact opening, a voltage of 500 v proportional to the ratio of winding turns is generated at both ends of the driving coil for contact closing. Accordingly, when the ratio of winding turns of both driving coils is large, there is some possibility that the voltage generated in the driving coil to which the current is not made to flow exceeds a breakdown voltage of a switch element for drive control and protective measures of the switch element for drive control are needed.
  • an electromagnetic operation mechanism drive circuit of Patent Document 1 includes: a drive circuit for contact closing in which a driving coil for contact closing is connected to a capacitor for contact closing, which serves as a direct current (DC) power source, via a driving switch element for contact closing, an overvoltage suppression unit on the contact closing side, in which a resistor and a switch element are connected in series, is connected in parallel to the driving coil for contact closing, and a protection switch element is provided between the driving coil for contact closing and the driving switch element for contact closing; a drive circuit for contact opening in which a driving coil for contact opening is connected to a capacitor for contact opening, which serves as a DC power source, via a driving switch element for contact opening and an overvoltage suppression unit on the contact opening side, in which a resistor and a switch element are connected in series, is connected in parallel to the
  • contact closing operation first, the protection switch element is closed. Next, the driving switch element for contact closing is closed and thus current flows from the capacitor for contact closing to the driving coil for contact closing. Just after the driving switch element for contact closing is closed, the switch element of the overvoltage suppression unit on the contact closing side is closed. After completion of the contact closing operation, the driving switch element for contact closing is opened. Voltage of the voltage detection circuit becomes a value near voltage of the capacitor for contact closing at the timing when the driving switch element for contact closing is opened. However, when the driving switch element for contact closing cannot be opened and is kept in a closed state, the voltage of the voltage detection circuit becomes a value near zero.
  • the voltage detection circuit determines a short circuit fault state of the driving switch element for contact closing and thus the protection switch element can control so as not to interrupt the current during driving.
  • the contact closing operation there generates no difference in voltage detected by the voltage detection circuit between when the switch element of an overvoltage suppression circuit on the contact closing side has an open circuit fault and when it does not have the open circuit fault; and accordingly, the fault of the switch element of the overvoltage suppression circuit on the contact closing side cannot be detected.
  • the protection switch element interrupts current in a state where an excessive voltage is applied and accordingly there is some possibility that a failure that damages the protection switch element or the like is generated. Accordingly, a problem exists in that it is necessary to detect in advance that the switch element of the overvoltage suppression circuit on the contact closing side has a fault and to protect by stopping interrupting operation of the protection switch element.
  • the present invention has been made to solve the above described problem, and an object of the present invention is to provide an electromagnetic operation mechanism drive circuit in which interrupting operation of a protection switch element is made to stop and contact closing operation can be safely terminated even when a switch element of an overvoltage suppression circuit on the contact closing side of the electromagnetic operation mechanism drive circuit that performs opening/closing operation of an electric power apparatus has an open circuit fault.
  • an electromagnetic operation mechanism drive circuit that performs opening/closing operation of an electric power apparatus
  • the electromagnetic operation mechanism drive circuit including: a movable core coupled to the electric power apparatus that is made to perform opening/closing operation; a driving coil for contact closing and a driving coil for contact opening, which drive the movable core; a capacitor for contact closing which is connected to the driving coil for contact closing, and supplies electric power; a driving switch element for contact closing which controls the supply of electric power from the capacitor for contact closing to the driving coil for contact closing; a protection switch element which is provided between the driving switch element for contact closing and the driving coil for contact closing, and is opened when the driving coil for contact opening is excited to generate induced electromotive force in the driving coil for contact closing; an overvoltage suppression circuit on the contact closing side in which a loop circuit on the contact closing side, in which a current attenuation capacitor and a current attenuation resistor are connected in series and a discharge resistor is connected in
  • a configuration is made such that voltage applied to the switch element of the overvoltage suppression circuit on the contact closing side is detected; and therefore, an effect exists in that an open circuit fault of the switch element of the overvoltage suppression circuit on the contact closing side can be detected and interrupting operation of the protection switch element can be stopped even if the open circuit fault occurs in the switch element of the overvoltage suppression circuit on the contact closing side when the driving coil for contact opening is excited to generate induced electromotive force on the driving coil for contact closing side.
  • the electromagnetic operation mechanism drive circuit performs opening/closing operation of, for example, a vacuum valve of a vacuum circuit breaker serving as an electric power apparatus; and a movable core is made to reciprocate and to perform opening/closing operation of opening/closing contacts of the vacuum valve coupled to the movable core by energizing driving coils for contact closing and contact opening, which are arranged on both sides of the movable core.
  • FIG. 1 is a circuit diagram showing the configuration of an electromagnetic operation mechanism drive circuit according to Embodiment 1;
  • FIG. 2 is a time chart for explaining contact closing operation; and
  • FIG. 3 is a time chart for explaining contact opening operation.
  • the electromagnetic operation mechanism drive circuit includes: a movable core 1 that opens/closes opening/closing contacts of the vacuum valve; a driving coil for contact closing 2 which excites and drives (moves) the movable core 1; a capacitor for contact closing 4 which supplies electric power to the driving coil for contact closing 2; a driving switch element for contact closing 5 which controls the supply of electric power from the capacitor for contact closing 4 to the driving coil for contact closing 2; a protection relay 7 serving as a protection switch element which is provided between the driving switch element for contact closing 5 and the driving coil for contact closing 2; an overvoltage suppression circuit on the contact closing side in which a loop circuit on the contact closing side 10, in which a current attenuation capacitor 10a and a current attenuation resistor 10b are connected in series and a discharge resistor 10c is connected
  • the overvoltage suppression circuit on the contact closing side is connected in parallel to the driving switch element for contact closing 5. Furthermore, in order to protect current from flowing back, a diode 8 is provided between the driving coil for contact closing 2 and the protection relay 7 and a diode 9 is provided between the protection relay 7 and the loop circuit on the contact closing side 10.
  • the electromagnetic operation mechanism drive circuit includes: a driving coil for contact opening 3 which excites and drives the movable core 1; a capacitor for contact opening 14 which supplies electric power to the driving coil for contact opening 3; a driving switch element for contact opening 15 which controls the supply of electric power from the capacitor for contact opening 14 to electric power to the driving coil for contact opening 3; and an overvoltage suppression circuit on the contact opening side in which a loop circuit on the contact opening side 20, in which a current attenuation capacitor 20a and a current attenuation resistor 20b are connected in series and a discharge resistor 20c is connected in parallel to these, is connected in series to a loop circuit switch element on the contact opening side 16.
  • the overvoltage suppression circuit on the contact opening side is connected in parallel to the driving switch element for contact opening 15. Furthermore, in order to protect current from flowing back, a diode 18 is provided between the driving coil for contact opening 3 and the driving switch element for contact opening 15 and a diode 19 is provided between the driving switch element for contact opening 15 and the loop circuit on the contact opening side 20.
  • the contact closing operation first, the protection relay 7 is closed at Time t1.
  • the loop circuit switch element on the contact closing side 6 of the loop circuit on the contact closing side 10 is closed at Time t2 and the driving switch element for contact closing 5 which drives and controls the driving coil for contact closing 2 is further closed at Time t3; and thus, current flows through a path from the capacitor for contact closing 4 to the driving coil for contact closing 2, the diode 8, the protection relay 7, and the driving switch element for contact closing 5.
  • the contact closing operation is executed by this series of operation.
  • the driving switch element for contact closing 5 is opened at Time t4; and thus, energy stored in the driving coil for contact closing 2 passes through the diode 8, the diode 9, and the current attenuation resistor 10b and the energy is stored in the current attenuation capacitor 10a. Then, after the energy stored in the driving coil for contact closing 2 moves to the current attenuation capacitor 10a, the loop circuit switch element on the contact closing side 6 is opened at Time t5. With this operation, the energy stored in the current attenuation capacitor 10a is discharged by the loop circuit on the contact closing side 10 which is composed of the discharge resistor 10c and the current attenuation resistor 10b and the energy is gradually attenuated.
  • the protection relay 7 is opened at Time t6 after completion of the discharge and thus the contact closing operation is completed.
  • the loop circuit switch element on the contact closing side 6 does not have the open circuit fault, the loop circuit switch element on the contact closing side 6 is closed and thus the voltage V detected by the voltage detection circuit on the contact closing side 13 becomes nearly zero. More specifically, when the loop circuit switch element on the contact closing side 6 has the open circuit fault at the time of Time t3, the voltage V of the voltage detection circuit on the contact closing side 13 does not become zero, but it becomes the same as the voltage Vc of the capacitor for contact closing 4.
  • the driving switch element for contact closing 5 has a short circuit fault while the driving switch element for contact closing 5 is closed (a period of time from Time t3 to t4)
  • the voltage V of the voltage detection circuit on the contact closing side 13 becomes nearly zero for a period of time after the loop circuit switch element on the contact closing side 6 is opened and until the protection relay 7 is opened (a period of time from Time t5 to t6).
  • the driving switch element for contact closing 5 does not have the short circuit fault, the voltage V of the voltage detection circuit on the contact closing side 13 becomes a value near the voltage Vc of the capacitor for contact closing 4.
  • the driving switch element for contact closing 5 has the short circuit fault at the time of Time t5
  • the voltage V of the voltage detection circuit on the contact closing side 13 becomes nearly zero. This generates a difference in detected voltage V between the short circuit fault and normal time of the driving switch element for contact closing 5 and therefore a determination can be made that the driving switch element for contact closing 5 has the short circuit fault.
  • the protection relay 7 is kept in a closed state, whereby current that flows through the driving coil for contact closing 2 also becomes near zero and interruption can be performed can be performed by even the protection relay 7 that does not have a capacity for interrupting the current when the driving coil for contact closing 2 is driven.
  • the contact opening operation first, the loop circuit switch element on the contact opening side 16 is closed at Time t7 and the driving switch element for contact opening 15 which drives and controls the driving coil for contact opening 3 is further closed at Time t8; and thus, current flows through a path from the capacitor for contact opening 14 to the driving coil for contact opening 3, the diode 18, and the driving switch element for contact opening 15.
  • the contact opening operation is executed by this series of operation.
  • the driving switch element for contact opening 15 is opened at Time t9; and thus, energy stored in the driving coil for contact opening 3 passes through the diode 18, the diode 19, and the current attenuation resistor 20b and the energy is stored in the current attenuation capacitor 20a. Then, after the energy stored in the driving coil for contact opening 3 moves to the current attenuation capacitor 20a, the loop circuit switch element on the contact opening side 16 is opened at Time t10. With this operation, the energy stored in the current attenuation capacitor 20a is discharged by the loop circuit on the contact opening side 20 which is composed of the discharge resistor 20c and the current attenuation resistor 20b and the energy is gradually attenuated. This completes the contact closing operation.
  • the voltage of the loop circuit switch element on the contact closing side of the overvoltage suppression circuit on the contact closing side is detected, whereby opening/closing states of the loop circuit switch element on the contact closing side and the driving switch element for contact closing are determined; and when the loop circuit switch element on the contact closing side has the open circuit fault or when the driving switch element for contact closing has the short circuit fault, the protection relay is kept in the closed state during the contact closing operation and a control is made so as not to interrupt the current. Therefore, an effect exists in that the protection relay is protected from a large current and the contact closing operation can be safely completed.
  • FIG. 4 is a circuit diagram showing the configuration of an electromagnetic operation mechanism drive circuit according to Embodiment 2.
  • a difference from the circuit diagram showing the configuration of the electromagnetic operation mechanism drive circuit according to Embodiment 1 shown in FIG. 1 is that a resistor 11 is provided in parallel to a series circuit of a protection relay 7 and a diode 8.
  • Other configuration is the same as that of Embodiment 1 and therefore a description thereof will be omitted.
  • a connection is made through a path from a capacitor for contact closing 4 to a driving coil for contact closing 2, a resistor 11, a diode 9, a discharge resistor 10c, and a voltage detection circuit on the contact closing side 13; and voltage detected by the voltage detection circuit on the contact closing side 13 is determined by the driving coil for contact closing 2, the resistor 11, the diode 9, and the discharge resistor 10c.
  • the voltage detected by the voltage detection circuit on the contact closing side 13 becomes zero; and therefore the presence or absence of the short circuit fault of the driving switch element for contact closing 5 or the loop circuit switch element on the contact closing side 6 can be determined and the protection relay 7 can be protected before the start of the contact closing operation.
  • the driving switch element for contact closing 5 has an open circuit fault or the loop circuit switch element on the contact closing side 6 has an open circuit fault
  • the driving switch element for contact closing 5 and the loop circuit switch element on the contact closing side 6 are each made to close for a constant time before the start of the contact closing operation, whereby the voltage of the voltage detection circuit on the contact closing side 13 does not become zero, the presence or absence of the open circuit fault of the driving switch element for contact closing 5 or the loop circuit switch element on the contact closing side 6 can be determined, and the protection relay 7 can be protected before the start of the contact closing operation.
  • the resistor is provided in parallel to the protection relay, whereby the presence or absence of a fault of the driving switch element for contact closing or the loop circuit switch element on the contact closing side is determined before the start of the contact closing operation and thus an effect exists in that the protection relay can be protected.
  • FIG. 5 is a circuit diagram showing the configuration of an electromagnetic operation mechanism drive circuit according to Embodiment 3.
  • a difference from the circuit diagram showing the configuration of the electromagnetic operation mechanism drive circuit according to Embodiment 1 shown in FIG. 1 is that a voltage detection circuit on the contact opening side 23 is provided in parallel to a loop circuit switch element on the contact opening side 16 and a driving switch element voltage detection circuit for contact opening 24 is provided in parallel to a driving switch element for contact opening 15.
  • Other configuration is the same as that of Embodiment 1 and therefore a description thereof will be omitted.
  • Embodiment 1 normal operation in contact opening operation is described in Embodiment 1 and therefore a description thereof will be omitted.
  • the voltage V of the voltage detection circuit on the contact opening side 23 does not become zero, but it becomes the same as the voltage Vo of the capacitor for contact opening 14. This generates a difference in detected voltage V between the open circuit fault and normal operation of the loop circuit switch element on the contact opening side 16; and therefore, the presence or absence of the open circuit fault of the loop circuit switch element on the contact opening side 16 can be determined and the open circuit fault of the loop circuit switch element on the contact opening side 16 can be detected until the driving switch element for contact opening 15 is closed (until Time t9) .
  • the loop circuit switch element on the contact opening side 16 has a short circuit fault while the loop circuit switch element on the contact opening side 16 is closed (a period of time from Time t7 to t10), the voltage V of the voltage detection circuit on the contact opening side 23 becomes nearly zero even if the loop circuit switch element on the contact opening side 16 is opened (after Time t10); and therefore, a determination can be made that the loop circuit switch element on the contact opening side 16 has the short circuit fault.
  • the driving switch element for contact opening 15 has a short circuit fault while the driving switch element for contact opening 15 is closed (a period of time from Time t8 to t9)
  • the voltage V of the driving switch element voltage detection circuit for contact opening 24 becomes nearly zero even if the driving switch element for contact opening 15 is opened (after Time t9) . This can determine that the driving switch element for contact opening 15 has the short circuit fault.
  • the voltage detection circuit on the contact opening side is provided in parallel to the loop circuit switch element on the contact opening side to detect voltage and the driving switch element voltage detection circuit for contact opening is provided in parallel to the driving switch element for contact opening to detect voltage, whereby an effect exists in that a fault of the driving switch element for contact opening or the loop circuit switch element on the contact opening side can be determined in the contact opening operation. Furthermore, in contact closing operation, an effect exists in that the same effect as that of Embodiment 1 can be obtained.
  • the present invention can freely combine the respective embodiments and appropriately modify and/or omit the respective embodiments, within the scope of the present invention.

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  • Physics & Mathematics (AREA)
  • Electromagnetism (AREA)
  • Relay Circuits (AREA)
  • Driving Mechanisms And Operating Circuits Of Arc-Extinguishing High-Tension Switches (AREA)

Claims (4)

  1. Treiberschaltung für einen elektromagnetischen Betriebsmechanismus, die einen Öffnungs-/Schließ-Betrieb einer elektrischen Leistungsvorrichtung durchführt, wobei die Treiberschaltung für einen elektromagnetischen Betriebsmechanismus aufweist:
    einen bewegbaren Kern (1), der mit der elektrischen Leistungsvorrichtung gekoppelt ist, die dazu vorgesehen ist, den Öffnungs-/Schließ-Betrieb durchzuführen;
    eine Treiberspule zum Schließkontakt-Schließen (2) und eine Treiberspule zum Kontakt-Öffnen (3), die den bewegbaren Kern (1) antreiben;
    einen Kondensator zum Kontakt-Schließen (4), der mit der Treiberspule zum Schließkontakt-Schließen (2) verbunden ist und elektrische Leistung zuführt;
    ein Treiberschaltelement zum Kontakt-Schließen (5), das die Zufuhr von elektrischer Leistung von dem Kondensator zum Kontakt-Schließen (4) zu der Treiberspule zum Schließkontakt-Schließen (2) steuert;
    ein Schutzschaltelement (7), das zwischen dem Treiberschaltelement zum Kontakt-Schließen (5) und der Treiberspule zum Schließkontakt-Schließen (2) bereitgestellt ist, und geöffnet wird, wenn die Treiberspule zum Kontakt-Öffnen (3) dazu angeregt ist, eine induzierte elektromotorische Kraft in der Treiberspule zum Schließkontakt-Schließen (2) zu erzeugen;
    eine Überspannungsüberbrückungsschaltung auf der Kontakt-Schließen-Seite, in der eine Kreisschaltung auf der Kontakt-Schließen-Seite (10), in der ein Stromdämpfungskondensator (10a) und ein Stromdämpfungswiderstand (10b) in Reihe verbunden sind und ein Entladungswiderstand (10c) parallel zu diesem verbunden ist, in Reihe mit einem Kreisschaltungsschaltelement auf der Kontakt-Schließen-Seite (6) verbunden ist; und
    eine Spannungsdetektionsschaltung auf der Kontakt-Schließen-Seite (13), in der die Überspannungsüberbrückungsschaltung auf der Kontakt-Schließen-Seite parallel zu dem Treiberschaltelement zum Kontakt-Schließen (5) verbunden ist, und das eine Spannung des Kreisschaltungsschaltelements auf der Kontakt-Schließen-Seite (6) detektiert,
    wobei Öffnungs-/Schließ-Zustände des Kreisschaltungsschaltelements auf der Kontakt-Schließen-Seite (6) und dem Treiberschaltelement zum Kontakt-Schließen (5) bestimmt werden durch die Spannung, die durch die Spannungsdetektionsschaltung auf der Kontakt-Schließen-Seite (13) detektiert ist; und
    wobei das Schutzschaltelement (7) nicht dazu vorgesehen ist, sich zu öffnen, wenn das Kreisschaltungsschaltelement auf der Kontakt-Schließen-Seite (6) und das Treiberschaltelement zum Kontakt-Schließen (5) nicht geschlossen werden kann.
  2. Treiberschaltung für einen elektromagnetischen Betriebsmechanismus nach Anspruch 1,
    des Weiteren mit einem Widerstand (11), der parallel zu dem Schutzschaltelement (7) verbunden ist.
  3. Treiberschaltung für einen elektromagnetischen Betriebsmechanismus nach Anspruch 1 oder Anspruch 2,
    des Weiteren mit: einem Kondensator zum Kontakt-Öffnen (14), der mit der Treiberspule zum Kontakt-Öffnen (3) verbunden ist, und elektrische Leistung zuführt;
    einem Treiberschaltelement zum Kontakt-Öffnen (15), das die Zufuhr von elektrischer Leistung von dem Kondensator zum Kontakt-Öffnen (14) an die Treiberspule zum Kontakt-Öffnen (3) steuert;
    einer Überspannungsüberbrückungsschaltung auf der Kontakt-Öffnen-Seite, in der eine Kreisschaltung auf der Kontakt-Öffnen-Seite (20), in der ein Stromdämpfungskondensator (20a) und ein Stromdämpfungswiderstand (20b) in Reihe verbunden sind, und ein Entladungswiderstand (20c) parallel zu diesem verbunden ist, in Reihe mit einem Kreisschaltungsschaltelement auf der Kontakt-Öffnen-Seite (16) verbunden ist; und
    eine Spannungsdetektionsschaltung auf der Kontakt-Öffnen-Seite (23), in der die Überspannungsüberbrückungsschaltung auf der Kontakt-Öffnen-Seite parallel zu dem Treiberschaltelement zum Kontakt-Öffnen (15) verbunden ist, und die eine Spannung des Kreisschaltungsschaltelements auf der Kontakt-Öffnen-Seite (16) detektiert,
    wobei ein Öffnungs-/Schließ-Zustand des Kreisschaltungsschaltelements auf der Kontakt-Öffnen-Seite (16) bestimmt ist durch die Spannung, die durch die Spannungsdetektionsschaltung auf der Kontakt-Öffnen-Seite (23) gerichtet ist.
  4. Treiberschaltung für einen elektromagnetischen Betriebsmechanismus nach Anspruch 3,
    des Weiteren mit einer Treiberschaltelement-Spannungsdetektionsschaltung (24) zum Kontakt-Öffnen, die eine Spannung des Treiberschaltelements zum Kontakt-Öffnen (15) detektiert, und
    wobei ein Öffnungs-/Schließ-Zustand des Treiberschaltelements zum Kontakt-Öffnen (15) bestimmt ist durch die Spannung, die durch die Treiberschaltelement-Spannungsdetektionsschaltung zum Kontakt-Öffnen (24) detektiert ist.
EP16914221.3A 2016-08-26 2016-08-26 Treiberschaltung für elektromagnetischen betriebsmechanismus Active EP3506330B1 (de)

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Application Number Priority Date Filing Date Title
PCT/JP2016/074906 WO2018037547A1 (ja) 2016-08-26 2016-08-26 電磁操作機構の駆動回路

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EP3506330A1 EP3506330A1 (de) 2019-07-03
EP3506330A4 EP3506330A4 (de) 2019-08-14
EP3506330B1 true EP3506330B1 (de) 2020-09-23

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CN113841213B (zh) * 2019-05-22 2024-03-08 三菱电机株式会社 电磁操作装置

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MX9304342A (es) * 1992-07-20 1994-04-29 Gec Alsthom Ltd Reconectores automaticos.
JP2850277B2 (ja) * 1992-11-25 1999-01-27 富士通電装株式会社 スイッチングモジュール
JPH08149809A (ja) * 1994-09-19 1996-06-07 Fuji Electric Co Ltd スイッチング電源回路
JP4192645B2 (ja) * 2003-03-24 2008-12-10 三菱電機株式会社 操作回路およびこれを用いた電力用開閉装置
JP2004357429A (ja) * 2003-05-29 2004-12-16 Mitsubishi Electric Corp エレベーターの制御装置
FR2943170B1 (fr) * 2009-03-10 2013-03-22 Areva T & D Sa Circuit actionneur magnetique
CN102834888B (zh) * 2010-04-02 2015-02-18 三菱电机株式会社 电磁操作机构的驱动电路
JP5901245B2 (ja) 2011-11-22 2016-04-06 三菱電機株式会社 電磁操作機構の駆動回路
DE102012217583A1 (de) * 2012-09-27 2014-03-27 Siemens Aktiengesellschaft Stellvorrichtung für eine Vakuumschaltröhre und Trennanordnung

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CN109690718A (zh) 2019-04-26
EP3506330A1 (de) 2019-07-03
EP3506330A4 (de) 2019-08-14
WO2018037547A1 (ja) 2018-03-01
CN109690718B (zh) 2020-04-24

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