EP4343806A1 - Appareil d'actionnement - Google Patents

Appareil d'actionnement Download PDF

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Publication number
EP4343806A1
EP4343806A1 EP21940709.5A EP21940709A EP4343806A1 EP 4343806 A1 EP4343806 A1 EP 4343806A1 EP 21940709 A EP21940709 A EP 21940709A EP 4343806 A1 EP4343806 A1 EP 4343806A1
Authority
EP
European Patent Office
Prior art keywords
moveable
side electrode
iron core
operation apparatus
bearing
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Pending
Application number
EP21940709.5A
Other languages
German (de)
English (en)
Inventor
Kozo Tamura
Masato Kobayashi
Shinichi Shibayama
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Hitachi Industrial Equipment Systems Co Ltd
Original Assignee
Hitachi Industrial Equipment Systems Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Hitachi Industrial Equipment Systems Co Ltd filed Critical Hitachi Industrial Equipment Systems Co Ltd
Publication of EP4343806A1 publication Critical patent/EP4343806A1/fr
Pending legal-status Critical Current

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Classifications

    • 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
    • H01H3/00Mechanisms for operating contacts
    • H01H3/60Mechanical arrangements for preventing or damping vibration or shock
    • 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

Definitions

  • the present invention relates to an operation apparatus, more specifically, to the operation apparatus suitable for operating a moveable side of opposingly arranged electrodes of a breaker via an insulation operation rod as a drive shaft.
  • Patent literature 1 discloses a vacuum circuit breaker as an example of the breaker which allows the operation apparatus to operate the electrode at the moveable side.
  • the vacuum circuit breaker as disclosed in the patent literature 1 includes the vacuum valve, the operation apparatus, and the fixing member for reducing deflection of a casing of the operation apparatus by suppressing the impact resulting from opening/closing operations of the vacuum circuit breaker, or stress caused by vibration without increasing weight and size of the vacuum circuit breaker so that reliability in the opening/closing operations is, improved.
  • the vacuum valve stores at least the fixed-side electrode and the moveable-side electrode, and has its periphery covered with a molding part.
  • the operation apparatus drives the moveable-side electrode via the insulation operation rod as the drive shaft.
  • the fixing member fixes the vacuum valve and the operation apparatus which are linearly arranged across the molding part of the vacuum valve and the operation apparatus.
  • the above-described operation apparatus includes the moveable iron core to be operated integrally with the insulation operation rod, the stator iron core (which may be omitted) disposed opposingly to the moveable iron core in the axial direction, the coil disposed around the moveable iron core and the stator iron core, and wound around the bobbin which forms the magnetic field for driving the moveable iron core, the cylindrical first yoke which is provided on an outer circumferential side of the coil, and second and third yokes which are disposed at both sides of the coil in the axial direction.
  • the insulation operation rod which is integrally operated with the moveable iron core is supported by the bearing held by the second and the third yokes.
  • the operation apparatus when the moveable-side electrode and the fixed-side electrode are in a disconnected state, an end of the insulation operation rod at the side opposite the moveable-side electrode protrudes from the third yoke in the axial direction. Accordingly, the operation apparatus has to be designed in consideration with such protrusion of the insulation operation rod, resulting in the problem of increase in the apparatus size.
  • the operation apparatus is provided with the damper (shock mitigating functional component) which serves to mitigate the shock resulting from collision of the axially protruding end of the insulation operation rod from the third yoke against the wall of the container when the moveable-side electrode and the fixed-side electrode are in the disconnected state.
  • the damper shock mitigating functional component
  • Preparation of the damper as described above may increase the number of components as well as take much labor, which causes the problem of increase in the apparatus size.
  • the first object of the present invention is to provide the operation apparatus having a moveable iron core which drives a drive shaft for operating a moveable-side electrode opposingly disposed to a fixed-side electrode to bring: the moveable-side electrode and the fixed-side electrode into an electrical contact state, and a coil disposed around the moveable iron core.
  • the drive shaft and the moveable iron core are integrally operated in association with a switching operation into an open/close state between the moveable-side electrode and the fixed-side electrode.
  • the operation apparatus has the drive shaft supported by a first bearing at a side of the moveable-side electrode, and has the moveable iron core supported by a second bearing at a side opposite the moveable-side electrode.
  • the second object of the present invention is to provide the operation apparatus having a moveable iron core which drives a drive shaft for operating a moveable-side electrode opposingly disposed to a fixed-side electrode to bring the moveable-side electrode and the fixed-side electrode into an electrical contact state, and a coil disposed around the moveable iron core.
  • the drive shaft and the moveable iron core are integrally operated in association with a switching operation into an open/close state between the moveable-side electrode and the fixed-side electrode.
  • the operation apparatus has the drive shaft supported by a first bearing at a side of the moveable-side electrode, the moveable iron core supported by a second bearing at a side opposite the moveable-side electrode, and a stopper plate for stopping an axial movement of an end of the moveable iron core at a side opposite the moveable-side electrode.
  • the present invention does not require the shock mitigating functional component (damper) for labor reduction without increasing the apparatus size. It is further possible to reduce the number of components, preventing increase in the apparatus size.
  • a vacuum circuit breaker 100A is provided with a vacuum valve 1 (having its circumference covered with a molding part 1A), which is integrally molded (mold) using such solid insulator as an epoxy resin, a fixed-side cable bushing 2 having a periphery of a fixed-side cable bushing conductor 15 molded, a moveable-side cable bushing 3 having an outer periphery of a moveable-side cable bushing conductor 16 molded, and an operation apparatus 4 for operating a moveable-side electrode 13 to be described later.
  • a vacuum valve 1 having its circumference covered with a molding part 1A
  • a fixed-side cable bushing 2 having a periphery of a fixed-side cable bushing conductor 15 molded
  • a moveable-side cable bushing 3 having an outer periphery of a moveable-side cable bushing conductor 16 molded
  • an operation apparatus 4 for operating a moveable-side electrode 13 to be described later.
  • the vacuum valve 1 integrally molded using the solid insulator such as the epoxy resin is usually called a mold vacuum valve.
  • the surface part of the mold is grounded, and kept electrically insulated with the solid insulator such as the epoxy resin.
  • the vacuum valve 1 as described above includes a fixed-side end plate 6 bonded to one end of a cylindrical insulator 5, a fixed-side conductor 7 which penetrates through the fixed-side end plate 6 air-tightly, a moveable-side end plate 8 bonded to the other end of the cylindrical insulator 5, a bellows portion 9 having one end bonded to the moveable-side end plate 8 to allow the moveable section to be driven, and a moveable-side conductor 10 which penetrates through the bellows portion 9 air-tightly for driving in the axial direction while maintaining vacuum.
  • the internal pressure is kept to the vacuum degree of approximately 10 -2 Pa or lower.
  • a floating potential metal 11 supported by the cylindrical insulator 5 Inside of the vacuum valve 1, a floating potential metal 11 supported by the cylindrical insulator 5, a fixed-side electrode 12 connected to an end of a fixed-side conductor 7, and the moveable-side electrode 13 connected to an end of the moveable-side conductor 10 are arranged.
  • the moveable-side conductor 10 is connected to an insulation operation rod 14.
  • the insulation operation rod 14 is connected to the operation apparatus 4 linked with a wipe mechanism for applying the contact load to an electrode pair.
  • the space around the insulation operation rod 14 is filled with insulation gas 18 such as air and sulfur hexafluoride.
  • the moveable-side electrode 13 is driven via the insulation operation rod 14 associated with driving of the operation apparatus 4. This makes the contact/separation state between the fixed-side electrode 12 and the moveable-side electrode 13 switchable, in other words, makes the open/close state of the vacuum valve 1 switchable.
  • Figure 1 illustrates the vacuum valve 1 in the open state between the fixed-side electrode 12 and the moveable-side electrode 13.
  • the fixed-side cable bushing 2 electrically connects the fixed-side cable bushing conductor 15 to the fixed-side conductor 7 of the vacuum valve 1.
  • the moveable-side cable bushing conductor 16 disposed at the moveable side of the vacuum valve 1 is integrally molded with the vacuum valve 1 using the solid insulator such as the epoxy resin.
  • the moveable-side conductor 10 of the vacuum valve 1 and the moveable-side cable bushing conductor 16 are electrically connected via a sliding current carriable contact 17.
  • the fixed-side cable bushing 2 and the moveable-side cable bushing 3 are connected to a not shown power supply side cable, and a not shown load-side cable to make the operation ready.
  • the vacuum valve 1 and the operation apparatus 4 are substantially linearly arranged.
  • a fixing member 19 across the molding part 1A around the vacuum valve 1 and the operation apparatus 4 serves to integrally fix the vacuum valve 1 and the operation apparatus 4.
  • the vacuum valve 1 and the operation apparatus 4 are fixed using the fixing member 19.
  • the section of the fixing member 19 at the side of the vacuum valve 1 is fixed via a plurality of mold projection parts (integrally molded with the molding part 1A) 20a, 20b each embedding an insert nut outwardly protruded to the side surface of the molding part 1A of the vacuum valve 1.
  • the section of the fixing member 19 at the side of the operation apparatus 4 is directly fixed to the casing of the operation apparatus 4 using bolts 21c, 21d as fastening members.
  • the generally employed operation apparatus 4A includes a moveable iron core 22 to be operated integrally with a drive shaft 14a connected to the insulation operation rod 14, a stator iron core 25 (if the stator iron core 25 is not adopted, a first bearing 27a to be described later has to be kept from contact with the moveable iron core 22), which faces the moveable iron core 22 in the axial direction, a coil 23 which is disposed around the moveable iron core 22 and the stator iron core 25, and wound around a bobbin 24 which forms a magnetic field for driving the moveable iron core 22, a cylindrical first yoke 26a provided on an outer circumferential side of the coil 23, a disc-like second yoke 26b provided around the coil 23 at the side of the moveable-side electrode 13, and a disc-like stopper (non-magnetic body such as aluminum and SUS) which is provided around the coil 23 at the side opposite the moveable-side electrode 13 for stopping the axial movement of the moveable iron core 22.
  • a stator iron core 25 if the stat
  • the drive shaft 14a integrally operated with the moveable iron core 22 has the side of the moveable-side electrode 13 slidably supported by the first bearing (slide bearing, for example) 27a which is force-fitted and held with the disc-like second yoke 26b and the stator iron core 25, and has the side opposite the moveable-side electrode 13 slidably supported by a second bearing (slide bearing, for example) 27b which is force-fitted and held with the disc-like stopper 26c.
  • the generally employed operation apparatus 4A when the moveable-side electrode 13 and the fixed-side electrode 12 are in a disconnected (open) state, an end 14b of the drive shaft 14a at the side opposite the moveable-side electrode 13 protrudes axially from the stopper 26c. Accordingly, the generally employed operation apparatus 4A has to be designed taking the protrusion of the drive shaft 14a into consideration. This may cause the problem of increase in the apparatus size.
  • the operation apparatus according to the present invention has been made to solve the problem as described above, which will be described in detail hereinafter.
  • FIG. 3 illustrates an operation apparatus as an example 1 according to the present invention.
  • An operation apparatus 4B as illustrated in Figure 3 is similarly configured to the generally employed operation apparatus 4A as illustrated in Figure 2 .
  • the drive shaft 14a operated integrally with the moveable iron core 22 has its section at the side of the moveable-side electrode 13 slidably supported by the first bearing (slide bearing, for example) 27a which is force-fitted and held with the disc-like second yoke 26b and the stator iron core 25 (if the stator iron core 25 is not adopted, the first bearing 27a has to be kept from contact with the moveable iron core 22).
  • the moveable iron core 22 operated integrally with the drive shaft 14a is slidably supported by the second bearing (slide bearing, for example) 27c which is force-fitted and held with the resin bobbin 24.
  • the second bearing segment bearing, for example
  • the second bearing 27c is force-fitted and held with the bobbin 24.
  • a flanged bearing can be used for the second bearing 27c to be held between the bobbin 24 and the stopper (non-magnetic body such as aluminum and SUS) 26c.
  • the stopper non-magnetic body such as aluminum and SUS
  • the operation apparatus 4B of the example includes the moveable iron core 22 which is operated integrally with the drive shaft 14a, the coil 23 which is disposed around the moveable iron core 22, and wound around the resin bobbin 24 which forms the magnetic field for operating the moveable iron core 22, the cylindrical first yoke 26a provided on the outer circumferential side of the coil 23, the disc-like second yoke 26b provided around the coil 23 at the side of the moveable-side electrode13, and the disc-like stopper 26c which is formed of the non-magnetic body such as aluminum and SUS, and provided around the coil 23 at the side opposite the moveable-side electrode 13 for stopping the axial movement of the moveable iron core 22.
  • the first bearing 27a is force-fitted and held with the second yoke 26b and the stator iron core 25 (the first bearing 27a does not have to be force-fitted and held with the stator iron core 25 so long as it is force-fitted with the second yoke 26b), and the second bearing 27c is force-fitted and held with the bobbin 24.
  • a notch 22a is formed in the moveable iron core 22 at an inner diameter side, at which the end 14b of the drive shaft 14a at the side opposite the moveable-side electrode 13 is positioned so that a nut 28 is fitted with the end 14b of the drive shaft 14a at the side opposite the moveable-sideelectrode 13 in the notch 22a.
  • the bottom of the nut 28 can be held with a part of the surface of the notch 22a. This makes it possible to prevent fall-off of the drive shaft 14a.
  • Figure 4 represents a comparison of the axial length between the generally employed apparatus 4A and the operation apparatus 4B of the example.
  • Figure 4(a) illustrates the generally employed operation apparatus 4A
  • Figure 4(b) illustrates the operation apparatus 4B of the example.
  • the operation apparatus 4B of the example has its size reduced by the amount (indicated by a code L) corresponding to the axially un-protruded portion of the end 14b of the drive shaft 14a at the side opposite the moveable-side electrode 13 from the stopper 26c. This makes it possible to prevent increase in the apparatus size (operation apparatus 4B and the vacuum circuit breaker 100A provided therewith).
  • FIGS 5(a) and 5(b) illustrate an operation apparatus as an example 2 according to the present invention.
  • An operation apparatus 4C of the example as illustrated in Figures 5(a) and 5(b) is similarly configured to the operation apparatus as the example 1 as illustrated in Figure 3 .
  • the drive shaft 14a operated integrally with the moveable iron core 22 has its section at the side of the moveable-side electrode 13 slidably supported by the first bearing (slide bearing, for example) 27a which is force-fitted and held with the disc-like second yoke 26b and the stator iron core 25 (if the stator iron core 25 is not adopted, the first bearing 27a has to be kept from contact with the moveable iron core 22).
  • the moveable iron core 22 operated integrally with the drive shaft 14a is slidably supported by the second bearing (slide bearing, for example) 27c which is force-fitted and held with the resin bobbin 24.
  • the operation apparatus is further provided with a stopper plate 30 for stopping the axial movement of an end of the moveable iron core 22 at the side opposite the moveable-side electrode 13.
  • the operation apparatus 4C of the example includes the moveable iron core 22 which is operated integrally with the drive shaft 14a, the coil 23 which is disposed around the moveable iron core 22, and wound around the resin bobbin 24 which forms the magnetic field for operating the moveable iron core 22, the cylindrical first yoke 26a provided on the outer circumferential side of the coil 23, and disc-like second and third yokes 26b, 26d, which are provided at both sides of the coil 23 in the axial direction.
  • the first bearing (slide bearing, for example) 27a is force-fitted and held with the second yoke 26b and the stator iron core 25 (if the stator iron core 25 is not adopted, the first bearing 27a has to be kept from contact with the moveable iron core 22).
  • the second bearing (slide bearing, for example) 27c is force-fitted and held with the bobbin 24 while partially protruding from the third yoke 26d in the axial direction.
  • the stopper plate 30 is fixed to an axially outer side of the third yoke 26d via a bearing holding member 29 which is formed of the non-magnetic body such as aluminum and SUS, and provided on the outer circumferential side of the second bearing 27c at eight positions on the whole circumference using third fixing bolts 32c.
  • the first yoke 26a and the second yoke 26b are fixed using the first fixing bolt 32a, and the first yoke 26a and the third yoke 26d are fixed using the second fixing bolt 32b at eight positions on the whole circumference.
  • the notch 22a is formed in the moveable iron core 22 at the inner diameter side, at which the end 14b of the drive shaft 14a at the side opposite the moveable-side electrode 13 is positioned so that the nut 28 is fitted with the end 14b of the drive shaft 14a at the side opposite the moveable-side electrode 13 in the notch 22a.
  • the bottom of the nut 28 can be held by a part of the surface of the notch 22a to prevent fall-off of the drive shaft 14a.
  • Figure 6 illustrates operation states of the operation apparatus 4C of the example.
  • Figure 6(a) illustrates the operation state when the moveable-side electrode 13 and the fixed-side electrode 12 are in the connected (closed) state.
  • Figure 6(b) illustrates the operation state when the moveable-side electrode 13 and the fixed-side electrode 12 are in an intermediate (transitional) state.
  • Figure 6(c) illustrates the operation state when the moveable-side electrode 13 and the fixed-side electrode 12 are in the disconnected (open) state.
  • Figure 6 indicates that the volume of the space 33 defined by the axial end of the moveable iron core 22, the axially protruded section of the second bearing 27c, and the stopper plate 30 changes as the state of connection between the moveable-side electrode 13 and the fixed-side electrode 12 makes the transition from the connected (closed) state as illustrated in Figure 6(a) to the disconnected state as illustrated in Figure 6(c) through the intermediate state as illustrated in Figure 6(b) .
  • the operation apparatus 4C of the example is provided with a shock mitigating functional component (damper) which controls an air clearance amount in the space 33 defined by the axial end of the moveable iron core 22, the axially protruded section of the second bearing 27c, and the stopper plate 30, and mitigates shock to the stopper plate 30 when stopping the axial movement of the end 14b at the side opposite the moveable-side electrode 13 of the moveable iron core 22 when the moveable-side electrode 13 and the fixed-side electrode 12 are in the disconnected (open) state.
  • a shock mitigating functional component (damper) which controls an air clearance amount in the space 33 defined by the axial end of the moveable iron core 22, the axially protruded section of the second bearing 27c, and the stopper plate 30, and mitigates shock to the stopper plate 30 when stopping the axial movement of the end 14b at the side opposite the moveable-side electrode 13 of the moveable iron core 22 when the moveable-side electrode 13 and the fixed-side electrode 12 are in the disconnected (open) state.
  • the space 33 defined by the axial end of the moveable iron core 22, the axially protruded section of the second bearing 27c, and the stopper plate 30 has a small gap between the moveable iron core 22 and the second bearing 27c. Accordingly, air inside the space is unlikely to flow out (air passes through not in an instant but by degrees).
  • the moveable-side electrode 13 and the fixed-side electrode 12 are in the disconnected (open) state, the moveable iron core 22 moves while reducing the space 33 (reducing the volume of the space 33).
  • the counterforce caused by the small air escape route in the space 33 can be controlled by adding air clearance holes in the space 33 each serving as the shock mitigating functional component (damper).
  • the air clearance amount in the space 33 defined by the axial end of the moveable iron core 22, the axially protruded section of the second bearing 27c, and the stopper plate 30 is controlled to impart the air damper function (buffer function). This makes it possible to mitigate the shock resulting from collision of the moveable iron core 22 against the stopper plate 30 when the moveable-side electrode 13 and the fixed-side electrode 12 are in the disconnected (open) state. Mitigation of such shock eliminates or alleviates rebounding of the moveable iron core 22, which may suppress the movement of the moveable-side electrode 13 in the direction to the connected (closed) state.
  • shock mitigating functional component (damper) will be described.
  • FIG. 7 illustrates an example of the shock mitigating functional component (damper) to be adopted by the operation apparatus 4C of the example.
  • the shock mitigating functional component (damper) for mitigating the shock to the stopper plate 30 is constituted by a hole 30a formed in the center of the disc-like stopper plate 30, or a plurality of holes including the hole 30a formed in the center of the stopper plate 30, and holes 30b formed symmetrically with respect to the center axis of the stopper plate 30 (example as illustrated in Figure 7 shows the hole 30a formed in the center of the stopper plate 30, and the holes 30b formed symmetrically with respect to the center axis of the stopper plate 30).
  • the air clearance amount in the space 33 from those holes 30a, 30b is controlled to mitigate the shock to the stopper plate 30 when stopping the axial movement of the end of the moveable iron core 22 at the side opposite the moveable-side electrode 13.
  • the hole 30a formed in the center of the stopper plate 30 is threaded as illustrated in Figure 8 , with which a through-holed bolt 34 is fitted.
  • the air clearance amount in the space 33 is controlled by gradually releasing the fitted state between the through-holed bolt 34 and the hole 30a formed in the stopper plate 30.
  • each size of the through hole of the through-holed bolt 34 becomes different. This makes it possible to adjust the braking force of the shock mitigating functional component (damper).
  • the structure of the example may be provided with the shock mitigating functional component (damper) without making the axial length of the operation apparatus 4C largely different from the axial length of the generally employed operation apparatus 4A as illustrated in Figure 2 .
  • This eliminates the need for providing an additional shock mitigating functional component (damper) to attain the labor reduction.
  • the number.of components may also be reduced to attain reduction in the apparatus size.
  • the braking force of the shock mitigating functional component may be adjusted by controlling the air clearance amount in the space 33 defined by the axial end of the moveable iron core 22, the axially protruded section of the second bearing 27c, and the stopper plate 30.
  • Figure 9 illustrates an operation apparatus as an example 3 according to the present invention.
  • An operation apparatus 4D of the example as illustrated in Figure 9 uses an air-permeable filter 35 formed of a waterproof moisture permeable material which covers a hole 30c formed in the center of the stopper plate 30 as the shock mitigating functional component (damper) for mitigating the shock to the stopper plate 30.
  • Other structures of the operator apparatus of the example are the same as those of the operation apparatus 4C as the example 2 as illustrated in Figure 5(a) .
  • the air-permeable filter 35 is attached to the stopper plate 30 using the adhesive.
  • the air-permeable filter 35 is clamped by a clamping member 36 having axial through holes 36a, and fixed to the stopper plate 30.
  • the air-permeable filter 35 adopted by the operation apparatus 4D of the example may be arbitrarily formed into, for example, a sheet-like film or of bolt type (to be applied using the bolt).
  • the use of the filter makes the apparatus less subject to the lower interface environment (no entrance of water nor dust makes characteristics unlikely to be influenced by the ambient environment).
  • the air permeable filter 35 of bolt type facilitates each attachment/detachment.
  • the threaded hole 30a is formed in the center of the stopper plate 30.
  • a fixing bolt 37 is fitted with the hole 30a to hold the end 14b of the drive shaft 14a at the side opposite the moveable-side electrode 13.
  • the moveable iron core 22 can be pushed by the fixing bolt 37 through the hole 30a which is threaded in the similar way to the operation apparatus 4C as illustrated in Figure 8 .
  • the moveable iron core 22 can be pushed and fixed by the fixing bolt 37 to easily hold the connected (closed) state between the moveable-side electrode 13 and the fixed-side electrode 12.
  • the connected (closed) state between the moveable-side electrode 13 and the fixed-side electrode 12 can be held without a power source such as utility power. This facilitates measurement of control dimensions of the contact pressure spring during inspection.
  • an air piping joint 38 is fitted with the threaded hole 30a.
  • compressed air is introduced into the space 33 via the air piping joint 38 to hold the end 14b at the side opposite the moveable-side electrode 13 of the moveable iron core 22.
  • the present invention is not limited to the examples as described above, but includes various modifications.
  • the examples are described in detail for readily understanding of the present invention which is not necessarily limited to the one equipped with all structures as described above. It is possible to replace a part of the structure of one example with the structure of another example. The one example may be provided with an additional structure of another example. It is further possible to add, remove, and replace the other structure to, from and with a part of the structure of the respective examples.

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  • Physics & Mathematics (AREA)
  • Electromagnetism (AREA)
  • Driving Mechanisms And Operating Circuits Of Arc-Extinguishing High-Tension Switches (AREA)
  • Electromagnets (AREA)
EP21940709.5A 2021-05-18 2021-05-18 Appareil d'actionnement Pending EP4343806A1 (fr)

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
PCT/JP2021/018761 WO2022244092A1 (fr) 2021-05-18 2021-05-18 Appareil d'actionnement

Publications (1)

Publication Number Publication Date
EP4343806A1 true EP4343806A1 (fr) 2024-03-27

Family

ID=84141343

Family Applications (1)

Application Number Title Priority Date Filing Date
EP21940709.5A Pending EP4343806A1 (fr) 2021-05-18 2021-05-18 Appareil d'actionnement

Country Status (4)

Country Link
EP (1) EP4343806A1 (fr)
JP (1) JP7422947B2 (fr)
CN (1) CN116261766A (fr)
WO (1) WO2022244092A1 (fr)

Family Cites Families (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS3513270B1 (fr) * 1959-05-27 1960-09-13
JP2011216245A (ja) 2010-03-31 2011-10-27 Mitsubishi Electric Corp 電磁操作機構および電磁操作機構の手動開閉装置
JP2012199276A (ja) 2011-03-18 2012-10-18 Mitsubishi Electric Corp 電磁アクチュエータおよび開閉装置
JP5734513B2 (ja) 2012-05-21 2015-06-17 三菱電機株式会社 電磁石装置及びその電磁石装置を用いた開閉装置
JP6776156B2 (ja) 2017-03-03 2020-10-28 株式会社日立産機システム 真空遮断器

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Publication number Publication date
WO2022244092A1 (fr) 2022-11-24
JPWO2022244092A1 (fr) 2022-11-24
JP7422947B2 (ja) 2024-01-26
CN116261766A (zh) 2023-06-13

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