JP2018037355A - Vacuum valve - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a vacuum valve capable of suppressing degradation of withstand voltage performance.SOLUTION: A vacuum valve includes two electrodes, a contact piece, an electrode, a connection, and a connection metal. The two electrodes are movable relatively in a first direction approaching or separating each other. The contact piece is provided in the two electrodes, respectively, and has an outer edge in a second direction orthogonal to the first direction. Each of the electrodes is provided at the two electrodes, respectively, and is provided with multiple slits and a recess, and has an inner peripheral surface, an outer peripheral surface, and multiple coils, thereby forming a gap between the contact piece. The connection is provided in one of the contact piece and the electrode. The connection metal connects the connection and the other of the contact piece and the electrode. In the second direction, the connection and the connection metal are located on the inside of the outer edge of the contact piece and on the inside of the outer peripheral surface of the electrode.SELECTED DRAWING: Figure 3

Description

  Embodiments of the present invention relate to a vacuum valve.

  The vacuum valve has two electrodes that can be close to and separated from each other. Contacts are connected to the two electrodes, and the contacts of the two electrodes can contact each other. The contact is connected to the electrode by brazing, for example.

JP 2008-262772 A

  The scissors are interposed between the contact and the electrode, but may be partially exposed outside the outer peripheral portion of the electrode. When the soot is exposed to a high electric field outside the electrode, the withstand voltage performance of the vacuum valve may be reduced.

  The vacuum valve which concerns on one Embodiment is provided with two electrode parts, a contactor, an electrode, a connection part, and a connection metal. The two electrode portions are relatively movable in a first direction approaching or separating from each other, and can contact each other. The contact is provided in each of the two electrode portions, and is configured to contact the other electrode portion when the two electrode portions contact each other, and a second direction orthogonal to the first direction With an outer edge. The electrodes are provided in the two electrode portions, respectively, and are provided with a plurality of slits and a recess opening toward the contact, an inner peripheral surface facing the recess, and opposite to the inner peripheral surface And a plurality of coil portions separated from each other by the plurality of slits and configured to generate a magnetic field when electricity flows through the two electrode portions, and the contactor A gap is formed between them. The connecting portion is provided on one of the contact and the electrode, protrudes toward the other of the contact and the electrode, and in the second direction, than the outer edge portion of the contact. It is located inside and located inside the outer peripheral surface of the electrode. The connection metal connects the connection portion and the other of the contact and the electrode, and is located inside the outer edge portion of the contact in the second direction, and the electrode It is located inside the outer peripheral surface.

FIG. 1 is a cross-sectional view showing a vacuum valve according to the first embodiment. FIG. 2 is a side view showing the first electrode portion and the second electrode portion of the first embodiment. FIG. 3 is a cross-sectional view showing a part of the first electrode portion or the second electrode portion of the first embodiment. FIG. 4 is a plan view showing the first electrode portion or the second electrode portion of the first embodiment except for the contact. FIG. 5 is a cross-sectional view showing a part of the first electrode portion or the second electrode portion according to the second embodiment. FIG. 6 is a side view showing a first electrode part and a second electrode part according to the third embodiment. FIG. 7 is a plan view showing the first electrode portion or the second electrode portion of the third embodiment except for the contacts. FIG. 8 is a bottom view showing the contact according to the third embodiment. FIG. 9 is a cross-sectional view showing a part of the first electrode portion or the second electrode portion according to the fourth embodiment.

  The first embodiment will be described below with reference to FIGS. 1 to 4. In the present specification, a plurality of expressions may be described for the constituent elements according to the embodiment and the description of the elements. The constituent elements and descriptions in which a plurality of expressions are made may be other expressions that are not described. Further, the constituent elements and descriptions that are not expressed in a plurality may be expressed in other ways that are not described.

  FIG. 1 is a cross-sectional view showing a vacuum valve 10 according to the first embodiment. The vacuum valve 10 may be referred to as a vacuum circuit breaker, for example. For example, as shown in FIG. 1, the vacuum valve 10 includes a first electrode part 11, a second electrode part 12, a vacuum container 13, a shield 14, and a cover 15. The first electrode portion 11 and the second electrode portion 12 are an example of two electrode portions.

  As shown in each drawing, in this specification, an X axis, a Y axis, and a Z axis are defined. The X axis, the Y axis, and the Z axis are orthogonal to each other. The Z-axis extends along the central axis of the vacuum valve 10 indicated by a dashed line.

  The first electrode portion 11 is positioned in the positive direction along the Z axis (the direction in which the arrow of the Z axis faces, the upward direction in FIG. 1) than the second electrode portion 12. In the present embodiment, the first electrode portion 11 is a so-called fixed side electrode, and the second electrode portion 12 is a so-called movable side electrode. In addition, the 1st electrode part 11 and the 2nd electrode part 12 are not restricted to this.

  The 1st electrode part 11 and the 2nd electrode part 12 can move relatively, and can contact and space mutually. For example, the first electrode portion 11 and the second electrode portion 12 are relatively movable in the direction along the Z axis. The direction along the Z axis is an example of a first direction, and includes a positive direction along the Z axis and a negative direction along the Z axis (the direction opposite to the arrow of the Z axis, the downward direction in FIG. 1). The direction along the Z axis may also be referred to as the axial direction.

  The second electrode unit 12 is movable relative to the first electrode unit 11 in a positive direction along the Z axis and a negative direction along the Z axis. For this reason, the direction along the Z-axis can also be referred to as the moving direction of the first electrode portion 11 and the second electrode portion 12.

  The second electrode portion 12 approaches the first electrode portion 11 by moving in the positive direction along the Z axis. In other words, the first electrode part 11 and the second electrode part 12 are relatively movable in the direction in which they approach each other.

  The second electrode unit 12 moves away from the first electrode unit 11 by moving in the negative direction along the Z axis. In other words, the first electrode part 11 and the second electrode part 12 are relatively movable in directions away from each other.

  The second electrode unit 12 is movable between a position in contact with the first electrode unit 11 and a position separated from the first electrode unit 11. FIG. 1 shows a second electrode portion 12 disposed at a position spaced from the first electrode portion 11.

  FIG. 2 is a side view showing the first electrode portion 11 and the second electrode portion 12 of the first embodiment. As shown in FIG. 2, the first electrode portion 11 and the second electrode portion 12 have substantially the same shape. The shape of the first electrode portion 11 and the shape of the second electrode portion 12 may be different.

  Each of the first electrode portion 11 and the second electrode portion 12 includes a current-carrying shaft 21, an electrode 22, a contactor 23, a magnetic body 24, and a reinforcing member 25. In other words, the current-carrying shaft 21, the electrode 22, the contactor 23, the magnetic body 24, and the reinforcing member 25 are provided on the first electrode portion 11 and the second electrode portion 12, respectively. The contact 23 can also be referred to as a contact, for example. The electrode 22 may be referred to as a magnetic field generation mechanism, for example.

  The energizing shaft 21 extends in a direction along the Z axis and serves as an electric path of the vacuum valve 10. The electrode 22 is formed in a cup shape, for example, and is provided at the end of the energizing shaft 21. The electrode 22 of the first electrode unit 11 is provided at the end of the energizing shaft 21 facing the second electrode unit 12. The electrode 22 of the second electrode portion 12 is provided at the end of the energizing shaft 21 facing the first electrode portion 11. The energizing shaft 21 and the electrode 22 are made of a conductor such as oxygen-free copper, for example.

  The contactor 23 is fixed to the end of the electrode 22 by, for example, brazing. The contact 23 of the first electrode unit 11 is provided at the end of the electrode 22 facing the second electrode unit 12. The contact 23 of the second electrode unit 12 is provided at the end of the electrode 22 facing the first electrode unit 11. The contact 23 is made of a conductor such as copper chrome, for example. The contact 23 is electrically connected to the electrode 22.

  When the first electrode unit 11 and the second electrode unit 12 are in contact, the contact 23 of the first electrode unit 11 is in contact with the contact 23 of the second electrode unit 12. Thereby, the 1st electrode part 11 and the 2nd electrode part 12 are electrically connected, and the vacuum valve 10 will be in a closed state.

  As shown in FIG. 1, a part of the first electrode portion 11 and the second electrode portion 12 is accommodated in the vacuum vessel 13. For example, a part of the current-carrying shaft 21, the electrode 22, and the contact 23 of the first electrode unit 11 and the second electrode unit 12 are accommodated in the vacuum vessel 13. The first electrode part 11 and the second electrode part 12 can be contacted and separated inside the vacuum vessel 13. The vacuum container 13 includes an insulating container 41, two sealing portions 42 and 43, and a bellows 44.

  The insulating container 41 is made of an insulator such as alumina. The insulating container 41 is formed in, for example, a cylindrical shape extending in the direction along the Z axis. The insulating container 41 may be formed in other shapes. The insulating container 41 has two end portions 41a and 41b. The end 41a is an end of the insulating container 41 in the positive direction along the Z axis. The end 41b is an end of the insulating container 41 in the negative direction along the Z axis.

  One sealing portion 42 is attached to the end portion 41 a of the insulating container 41. A hole 42 a is provided in the sealing portion 42. The energizing shaft 21 of the first electrode part 11 is passed through the hole 42 a of the sealing part 42. The energization shaft 21 of the first electrode part 11 is fixed to the sealing part 42.

  The other sealing portion 43 is attached to the end portion 41 b of the insulating container 41. A hole 43 a is provided in the sealing portion 43. The energizing shaft 21 of the second electrode portion 12 is movably passed through the hole 43 a of the sealing portion 43.

  The bellows 44 extends in a direction along the Z axis so as to be stretchable. One end 44 a of the bellows 44 is fixed to the sealing portion 43. The other end 44 b of the bellows 44 is fixed to the energizing shaft 21 of the second electrode portion 12. For this reason, the bellows 44 expands or contracts in accordance with the movement of the second electrode portion 12.

The two sealing portions 42 and 43 and the bellows 44 hermetically seal the end portions 41 a and 41 b of the insulating container 41. The pressure inside the vacuum vessel 13 is maintained at, for example, 1 × 10 ⁻² Pa or less.

  The shield 14 and the cover 15 are disposed inside the vacuum vessel 13. The shield 14 is formed in a substantially cylindrical shape and surrounds the contact 23 of the first electrode part 11 and the second electrode part 12. The cover 15 is located between the electrode 22 of the second electrode portion 12 and the bellows 44 and covers the bellows 44.

  When the first electrode portion 11 and the second electrode portion 12 come into contact with each other, a rated current flows through the first electrode portion 11 and the second electrode portion 12. When the first electrode portion 11 and the second electrode portion 12 are in contact with and separated from each other, an arc may be generated between the first electrode portion 11 and the second electrode portion 12.

  There is a possibility that evaporated or molten metal is generated from the first electrode portion 11 and the second electrode portion 12 by the arc. The shield 14 prevents evaporation or molten metal from adhering to the insulating container 41 and reducing the insulation resistance of the insulating container 41. The cover 15 prevents the evaporated or molten metal from adhering to the bellows 44.

  Hereinafter, the first electrode unit 11 and the second electrode unit 12 will be described in detail. FIG. 3 is a cross-sectional view showing a part of the first electrode portion 11 or the second electrode portion 12 of the first embodiment. FIG. 3 representatively shows the second electrode portion 12. However, since the first electrode portion 11 and the second electrode portion 12 have the same shape, FIG. 3 also shows the first electrode portion 11 substantially.

  As shown in FIG. 3, the contactor 23 is formed in a substantially disk shape spreading on the XY plane. The contactor 23 may be formed in other shapes. The contact 23 has a contact surface 51, a back surface 52, a concave surface 53, and an outer edge portion 54. The back surface 52 is an example of a plane.

  The contact surface 51 is a substantially flat circular surface. The contact surface 51 may be formed in another shape such as an annular shape. The contact surface 51 of the contact 23 of the first electrode unit 11 and the contact surface 51 of the contact 23 of the second electrode unit 12 face each other. When the first electrode portion 11 and the second electrode portion 12 are in contact with each other, the contact surface 51 of the first electrode portion 11 and the contact surface 51 of the second electrode portion 12 are in contact with each other.

  The back surface 52 is located on the opposite side of the contact surface 51 and is formed to be substantially flat. The back surface 52 faces the electrode 22. The concave surface 53 is a substantially cylindrical recess that is recessed from the back surface 52. The concave surface 53 has a bottom surface 53a and an inner edge portion 53b.

  The bottom surface 53 a of the concave surface 53 is a substantially flat circular surface and faces the electrode 22. The inner edge portion 53 b is an inner edge portion of the concave surface 53 in the radial direction of the vacuum valve 10. The radial direction of the vacuum valve 10 is an example of a second direction and is a direction orthogonal to the central axis of the vacuum valve 10. In other words, the radial direction of the vacuum valve 10 is a direction orthogonal to the Z axis.

  The inner edge portion 53 b connects the back surface 52 and the bottom surface 53 a and extends in the circumferential direction of the vacuum valve 10. The circumferential direction of the vacuum valve 10 is a direction that rotates around the central axis of the vacuum valve 10. The circumferential direction of the vacuum valve 10 includes a clockwise direction and a counterclockwise direction.

  The inner edge portion 53 b faces inward in the radial direction of the vacuum valve 10. In other words, the inner edge portion 53 b faces the central axis of the vacuum valve 10. The inner edge portion 53b may include a portion facing in another direction.

  The outer edge portion 54 is an outer edge portion of the contact 23 in the radial direction of the vacuum valve 10. In other words, the outer edge portion 54 is a portion located on the outermost side of the contact 23 in the radial direction of the vacuum valve 10. The outer edge portion 54 may be, for example, a sharp edge, a round edge, or a substantially cylindrical outer peripheral surface.

  The electrode 22 is formed in a cup shape as described above. The electrode 22 is provided with a recess 60 and has a first wall portion 61 and a second wall portion 62. The recess 60 is a substantially cylindrical recess that opens toward the contactor 23. The recess 60 of the first electrode part 11 opens toward the second electrode part 12. The recess 60 of the second electrode portion 12 opens toward the first electrode portion 11.

  The first wall portion 61 is formed in a substantially disc shape that spreads on the XY plane and is separated from the contactor 23. In the first electrode part 11, the first wall part 61 is separated from the contactor 23 in the positive direction along the Z axis. In the second electrode portion 12, the first wall portion 61 is separated from the contactor 23 in the negative direction along the Z axis. In other words, the first wall portion 61 is separated from the contactor 23 in a direction away from the first electrode portion 11 or the second electrode portion 12.

  The energizing shaft 21 is connected to the first wall portion 61. The first wall portion 61 has a bottom surface 61a. The bottom surface 61 a is located on the opposite side of the surface of the first wall portion 61 to which the energizing shaft 21 is connected, and forms the bottom of the recess 60.

  The second wall portion 62 is formed in a substantially cylindrical shape extending in the direction along the Z axis. The second wall portion 62 protrudes from the outer edge of the first wall portion 61 toward the contact 23, for example. The second wall portion 62 of the first electrode portion 11 protrudes toward the second electrode portion 12. The second wall portion 62 of the second electrode portion 12 protrudes toward the first electrode portion 11.

  According to another expression, the second wall portion 62 is a cylindrical wall that protrudes from the first wall portion 61 in the direction along the Z axis and extends in the circumferential direction of the vacuum valve 10. The second wall portion 62 has an inner peripheral surface 62a, an outer peripheral surface 62b, and an end surface 62c.

  The inner peripheral surface 62 a is a substantially cylindrical surface that forms the inner peripheral surface of the recess 60. In other words, the inner peripheral surface 62 a faces the recess 60. The inner peripheral surface 62 a faces the central axis of the vacuum valve 10 and extends in the circumferential direction of the vacuum valve 10. The diameter of the inner peripheral surface 62a (the inner diameter of the electrode 22) is substantially equal to the diameter of the inner edge portion 53b of the concave surface 53 (the inner diameter of the contactor 23).

  The outer peripheral surface 62b is a substantially cylindrical surface located on the opposite side of the inner peripheral surface 62a. The outer circumferential surface 62 b faces the outside of the electrode 22 and extends in the circumferential direction of the vacuum valve 10. The diameter of the outer peripheral surface 62b (the outer diameter of the electrode 22) is substantially equal to the diameter of the outer edge portion 54 of the contactor 23 (the outer diameter of the contactor 23). The outer peripheral surface 62 b is an outer peripheral surface of the second wall portion 62 and an outer peripheral surface of the electrode 22.

  The end surface 62c is an end portion of the second wall portion 62 in the direction along the Z axis. The end surface 62 c is located on the opposite side of the first wall portion 61. The end face 62c is a substantially annular surface formed substantially flat. The end surface 62 c faces the back surface 52 at a position spaced from the back surface 52 of the contactor 23. In other words, a gap is formed between the end surface 62 c of the electrode 22 and the back surface 52 of the contactor 23.

  As shown in FIG. 2, the electrode 22 is provided with a plurality of slits 65. The plurality of slits 65 are provided in the second wall portion 62 and extend in a spiral shape. A part of the plurality of slits 65 may be provided in the first wall portion 61.

  FIG. 4 is a plan view showing the first electrode portion 11 or the second electrode portion 12 of the first embodiment except for the contact 23. As shown in FIG. 4, the slit 65 penetrates the second wall portion 62 in the thickness direction of the second wall portion 62. The thickness direction of the second wall portion 62 is a direction from the inner peripheral surface 62 a toward the outer peripheral surface 62 b and is equal to the radial direction of the vacuum valve 10. The slit 65 may be a recess (groove, dent) that opens to either the inner peripheral surface 62a or the outer peripheral surface 62b.

  As shown in FIG. 2, a plurality of coil portions 66 are formed on the electrode 22 by the plurality of slits 65. In other words, the electrode 22 has a plurality of coil portions 66, and the plurality of coil portions 66 are separated from each other by a plurality of slits 65.

  Each of the plurality of coil portions 66 extends spirally from the first wall portion 61. That is, the coil portion 66 extends in the circumferential direction of the vacuum valve 10 while shifting in a direction along the Z axis. When the slit 65 is also provided in the first wall portion 61, the coil portion 66 includes a part of the first wall portion 61.

  The plurality of coil portions 66 have end surfaces 66a. An end surface 62 c of the second wall portion 62 is formed by the end surfaces 66 a of the plurality of coil portions 66. The end surface 66 a of the coil portion 66 faces the back surface 52 of the contactor 23 by forming a gap with the back surface 52 of the contactor 23, similarly to the end surface 62 c of the second wall portion 62. In other words, the end surface 66 a of the coil portion 66 faces the contact 23 and is separated from the contact 23.

  When electricity flows through the first electrode unit 11 and the second electrode unit 12 each having the coil unit 66, electricity flows through the coil unit 66. The coil unit 66 generates a magnetic field according to the direction in which electricity flows.

  For example, the coil portion 66 generates a magnetic field in which magnetic lines of force extend in a direction along the Z axis. That is, the first electrode portion 11 and the second electrode portion 12 are so-called longitudinal magnetic field electrodes. For example, the coil section 66 may generate a magnetic field in which magnetic lines of force extend in a direction intersecting (orthogonal) with the Z axis. That is, the first electrode portion 11 and the second electrode portion 12 may be so-called magnetic drive electrodes. The magnetic drive electrode may also be referred to as a spiral electrode or a control electrode.

  In the present embodiment, a connection portion 81 is provided on the electrode 22. The connection portion 81 is formed in a substantially cylindrical shape, and protrudes from the end surface 62 c of the second wall portion 62 toward the back surface 52 of the contactor 23. The connection part 81 is formed integrally with the electrode 22. As shown in FIG. 3, the connection part 81 has the inner peripheral surface 81a, the outer peripheral surface 81b, and the connection surface 81c.

  The inner peripheral surface 81 a is a substantially cylindrical surface that extends in the circumferential direction of the vacuum valve 10 while facing the central axis of the vacuum valve 10. The diameter of the inner peripheral surface 81a (the inner diameter of the connection portion 81) is substantially equal to the diameter of the inner peripheral surface 62a of the second wall portion 62 (the inner diameter of the electrode 22). For this reason, the inner peripheral surface 81 a of the connection portion 81 is continuous with the inner peripheral surface 62 a of the second wall portion 62. The inner peripheral surface 81 a forms the inner peripheral surface of the recess 60 and faces the recess 60.

  The outer peripheral surface 81b is a substantially cylindrical surface located on the opposite side of the inner peripheral surface 81a. The outer peripheral surface 81 b faces the outside of the electrode 22 and extends in the circumferential direction of the vacuum valve 10.

  The diameter of the outer peripheral surface 81 b (the outer diameter of the connection portion 81) is smaller than the diameter of the outer peripheral surface 62 b of the second wall portion 62 (the outer diameter of the electrode 22). Furthermore, the diameter of the outer peripheral surface 81b (the outer diameter of the connecting portion 81) is smaller than the diameter of the outer edge portion 54 of the contactor 23 (the outer diameter of the contactor 23). For this reason, the connection part 81 is located inside the outer edge part 54 of the contactor 23 and inside the outer peripheral surface 62 b of the electrode 22 in the radial direction of the vacuum valve 10.

  The connection surface 81c is an end portion of the connection portion 81 in the direction along the Z axis. The connection surface 81 c is located on the opposite side of the second wall portion 62. The connection surface 81c is a substantially annular surface formed substantially flat. The connection surface 81 c faces the back surface 52 of the contactor 23.

  As shown in FIG. 2, the slit 65 is also provided in the connection portion 81. The slit 65 penetrates the connecting portion 81 in the thickness direction of the connecting portion 81. A plurality of protrusions 83 are formed in the connection portion 81 by the plurality of slits 65. In other words, the connecting portion 81 has a plurality of protrusions 83 that are separated from each other by the slit 65. The protrusion 83 can also be referred to as a protrusion or a pillar, for example.

  As shown in FIG. 4, in the first embodiment, the protrusion 83 is a substantially arc-shaped wall. The protrusion 83 extends in a direction along the Z axis from the end surface 66 a of the coil portion 66 toward the contact 23. In other words, the protrusion 83 protrudes from the end surface 62 c of the second wall portion 62 of the electrode 22 toward the contactor 23. The protrusion 83 may extend spirally together with the coil portion 66.

  Each protrusion 83 protrudes from the end surface 66a of the corresponding one coil part 66. Two or more protrusions 83 may protrude from the end surface 66a of one corresponding coil part 66.

  As shown in FIG. 3, the flange 85 connects the connection surface 81 c of the connection portion 81 and the back surface 52 of the contactor 23. The flange 85 is an example of a connection metal. In the present embodiment, the ridge 85 is a silver casket. The hook 85 may be another hard iron such as a copper iron, a soft iron such as solder, or another metal.

  The flange 85 connects the plurality of protrusions 83 and the contactor 23. The flange 85 that connects one protrusion 83 and the contact 23 is separated from the flange 85 that connects the other protrusion 83 and the contact 23.

  The flange 85 fixes the connecting portion 81 and the contactor 23 to each other. For this reason, the contactor 23 is fixed to the electrode 22 via the flange 85. Furthermore, the contactor 23 is electrically connected to the electrode 22 via the flange 85.

  When the connecting portion 81 and the contact 23 are fixed to each other, a groove 87 is formed in the first electrode portion 11 and the second electrode portion 12. The groove 87 can also be referred to as a recess or a recess, for example. The groove 87 is a portion that is recessed from the outer peripheral surface 62 b of the electrode 22 and the outer edge portion 54 of the contactor 23, and extends in the circumferential direction of the vacuum valve 10. For example, the back surface 52 of the contact 23, the outer peripheral surface 81 b of the connecting portion 81, and the end surface 62 c of the electrode 22 form a groove 87.

  When the connecting portion 81 and the contact 23 are fixed to each other, the contact 23 closes the concave portion 60 of the electrode 22. The concave portion 60 of the electrode 22 is connected to the concave surface 53 of the contactor 23 to form a hollow portion H. The hollow portion H is a room provided inside the first electrode portion 11 and the second electrode portion 12.

  The flange 85 has an interposition part 85a. Furthermore, the collar 85 may have at least one of the first exposed portion 85b and the second exposed portion 85c. The interposition part 85 a is interposed between the connection surface 81 c of the connection part 81 and the back surface 52 of the contactor 23.

  The first exposed portion 85 b is a portion that protrudes into the groove 87 from the gap between the connection surface 81 c of the connection portion 81 and the back surface 52 of the contactor 23. For this reason, the first exposed portion 85 b is located between the back surface 52 of the contactor 23 and the end surface 62 c of the second wall portion 62. The second exposed portion 85 c is a portion that protrudes into the recess 60 from the gap between the connection surface 81 c of the connection portion 81 and the back surface 52 of the contactor 23.

  The first exposed portion 85 b of the flange 85 is accommodated in the groove 87 and does not protrude beyond the outer peripheral surface 62 b of the electrode 22 and the outer edge portion 54 of the contactor 23. That is, the flange 85 is located inside the outer edge portion 54 of the contactor 23 and inside the outer peripheral surface 62 b of the electrode 22 in the radial direction of the vacuum valve 10.

  The magnetic body 24 is made of a magnetic material such as iron. The magnetic body 24 is formed in a hollow substantially cylindrical shape (ring shape) and is accommodated in the cavity H. In other words, the magnetic body 24 is accommodated inside the first electrode portion 11 and the second electrode portion 12. The magnetic body 24 may be formed in other shapes. The magnetic body 24 has an inner peripheral surface 24a, an outer peripheral surface 24b, and two end portions 24c and 24d.

  The inner peripheral surface 24 a is a substantially cylindrical surface that extends in the circumferential direction of the vacuum valve 10 while facing the central axis of the vacuum valve 10. The outer peripheral surface 24b is a substantially cylindrical surface located on the opposite side of the inner peripheral surface 24a. The outer peripheral surface 24 b faces the inner peripheral surface 62 a of the second wall 62 via a gap and extends in the circumferential direction of the vacuum valve 10. In other words, the magnetic body 24 is separated from the second wall portion 62. The diameter of the outer peripheral surface 24 b (the outer diameter of the magnetic body 24) is smaller than the diameter of the inner peripheral surface 62 a of the second wall portion 62 (the inner diameter of the electrode 22).

  The end portion 24c is an end portion of the magnetic body 24 in the negative direction along the Z axis, and is a substantially flat surface formed in a substantially annular shape. The end portion 24 c is supported by the bottom surface 61 a of the first wall portion 61. The end 24c of the magnetic body 24 is fixed to the first wall 61 by, for example, brazing. The magnetic body 24 may be movable with respect to the first wall portion 61.

  The end portion 24d is an end portion of the magnetic body 24 in the positive direction along the Z axis, and is a surface that is formed in a substantially annular shape and is inclined. The end 24d is located on the opposite side of the end 24c. For example, the end 24d is inclined in a concave shape. The end 24d is in line contact with the bottom surface 53a of the concave surface 53 of the contactor 23, for example. The end 24d may be separated from the contactor 23.

  The reinforcing member 25 is made of stainless steel, for example. The reinforcing member 25 may be made of other materials. The strength of the reinforcing member 25 is higher than that of the electrode 22 and higher than that of the contactor 23. The strength is, for example, yield strength. Furthermore, the electrical resistance of the reinforcing member 25 is higher than that of the electrode 22 and higher than that of the contactor 23.

  The reinforcing member 25 is formed in a substantially cylindrical shape and is accommodated in the cavity H. In other words, the reinforcing member 25 is housed inside the first electrode portion 11 and the second electrode portion 12. The reinforcing member 25 may be formed in other shapes. The reinforcing member 25 has an outer peripheral surface 25a and two end portions 25b and 25c.

  The outer peripheral surface 25a is a substantially cylindrical surface. The outer peripheral surface 25 a faces the inner peripheral surface 24 a of the magnetic body 24 via a gap and extends in the circumferential direction of the vacuum valve 10. The diameter of the outer peripheral surface 25a (the outer diameter of the reinforcing member 25) is smaller than the diameter of the inner peripheral surface 24a of the magnetic body 24 (the inner diameter of the magnetic body 24).

  The end portion 25b is an end portion of the reinforcing member 25 in the negative direction along the Z axis, and is a substantially flat surface formed in a substantially circular shape. The end portion 25 b is supported on the bottom surface 61 a of the first wall portion 61. The end portion 25b of the reinforcing member 25 is fixed to the first wall portion 61, for example, by brazing.

  The end portion 25c is an end portion of the reinforcing member 25 in the positive direction along the Z axis, and is a substantially flat surface formed in a substantially circular shape. The end portion 25c is located on the opposite side of the end portion 25b. The end portion 25c of the reinforcing member 25 is fixed to the bottom surface 53a of the concave surface 53 of the contactor 23, for example, by brazing.

  The reinforcing member 25 is interposed between the electrode 22 and the contact 23 at a position that overlaps the energizing shaft 21 in the direction along the Z axis. The reinforcing member 25 supports the contactor 23 and fixes the contactor 23 to the electrode 22.

  As described above, when the vacuum valve 10 is closed, the second electrode unit 12 moves in a direction approaching the first electrode unit 11, and the contact 23 of the first electrode unit 11 and the second electrode unit are moved. 12 contactors 23 come into contact. As a result, the vacuum valve 10 is closed, and electricity flows through the first electrode portion 11 and the second electrode portion 12.

  When the contact 23 of the first electrode part 11 comes into contact with the contact 23 of the second electrode part 12, an impact is applied to the first electrode part 11 and the second electrode part 12. The reinforcing member 25 supports the contact 23 and suppresses deformation of the first electrode portion 11 and the second electrode portion 12.

  In the first electrode portion 11 and the second electrode portion 12, the current passes through the electrode 22 and the contact 23. The reinforcing member 25 is brazed to the electrode 22 and the contactor 23. For this reason, an electric current may pass through the reinforcing member 25. However, the electrical resistance of the reinforcing member 25 is higher than that of the electrode 22 and higher than that of the contactor 23. For this reason, a large amount of current passes through the electrode 22 and the current flowing through the reinforcing member 25 is reduced.

  When the vacuum valve 10 is opened, the second electrode portion 12 moves in a direction away from the first electrode portion 11. At this time, an arc may be generated between the first electrode portion 11 and the second electrode portion 12. The charged particles constituting the arc are captured by the magnetic field lines in the magnetic field generated by the coil unit 66, and spirally move around the magnetic field lines. As a result, the arc is diffused and spreads over the entire contact 23, and the vacuum valve 10 more reliably cuts off the current. The magnetic body 24 further strengthens the magnetic field of the coil portion 66 and improves the current interruption performance of the vacuum valve 10.

  When the coil portion 66 generates a magnetic field in which the magnetic lines of force extend in a direction intersecting the Z axis, the arc is driven in the circumferential direction without being stagnated by the Lorentz force. For this reason, it is suppressed that an arc overheats the contactor 23 locally.

  Generally, when the flange 85 is positioned outside the outer edge portion 54 of the contactor 23 and the outer peripheral surface 62b of the electrode 22, the flange 85 is exposed to a high electric field. The electron emission coefficient of the silver cocoon which is the cocoon 85 is larger than the electron emission coefficient of oxygen-free copper, copper chrome, and stainless steel, which are the materials of the first and second electrode portions 11 and 12. For this reason, when the rod 85 is exposed to a high electric field, the withstand voltage performance of the vacuum valve 10 may deteriorate.

  On the other hand, in the vacuum valve 10 according to the first embodiment described above, the connection portion 81 and the flange 85 are located on the inner side of the outer edge portion 54 of the contactor 23 in the radial direction of the vacuum valve 10 and are electrodes. 22 is located inside the outer peripheral surface 62b. In a space (groove 87) located inside the outer edge portion 54 of the contactor 23 and inside the outer peripheral surface 65b of the electrode 22, the electric field strength is lower than that of the outer space. For this reason, it is suppressed that the collar 85 is exposed to a high electric field, and it is suppressed that the withstand voltage performance of the vacuum valve 10 falls. Furthermore, since the rod 85 is prevented from being exposed to a high electric field without adding another part or performing a surface treatment, the design restriction of the vacuum valve 10 is generated, and the manufacturing cost of the vacuum valve 10 is increased. Is suppressed from increasing.

  The reinforcing member 25 is accommodated in the first electrode portion 11 and the second electrode portion 12. The reinforcing member 25 is fixed to the electrode 22 and supports the contactor 23. Thereby, the impact at the time of opening and closing of the 1st electrode part 11 and the 2nd electrode part 12, and the deformation | transformation by the electromagnetic force when a big electric current flows into the 1st electrode part 11 and the 2nd electrode part 12 are suppressed. Is done. Furthermore, the electrical resistance of the reinforcing member 25 is higher than that of the electrode 22 and higher than that of the contactor 23. For this reason, an electric current flows into the electrode 22, and the fall of the performance of the vacuum valve 10 is suppressed.

  Hereinafter, the second embodiment will be described with reference to FIG. In the following description of the plurality of embodiments, components having the same functions as the components already described are denoted by the same reference numerals as those described above, and further description may be omitted. . In addition, a plurality of components to which the same reference numerals are attached do not necessarily have the same functions and properties, and may have different functions and properties according to each embodiment.

  FIG. 5 is a cross-sectional view showing a part of the first electrode portion 11 or the second electrode portion 12 according to the second embodiment. FIG. 5 representatively shows the second electrode portion 12. As shown in FIG. 5, in the second embodiment, the diameter of the inner edge portion 53 b of the concave surface 53 (the inner diameter of the contactor 23) is the diameter of the inner peripheral surface 62 a of the second wall portion 62 (the inner diameter of the electrode 22). Bigger than.

  The diameter of the inner edge portion 53b of the concave surface 53 (the inner diameter of the contactor 23) is substantially equal to the diameter of the outer peripheral surface 81b of the connection portion 81 (the outer diameter of the connection portion 81). For this reason, the connecting portion 81 is fitted into the concave surface 53, and the bottom surface 53 a of the concave surface 53 of the contactor 23 faces the connecting surface 81 c of the connecting portion 81.

  The inner edge portion 53 b of the concave surface 53 is in contact with the outer peripheral surface 81 b of the connection portion 81. For this reason, the concave surface 53 restricts the relative movement of the electrode 22 provided with the connecting portion 81 and the contact 23 in the radial direction of the vacuum valve 10. The inner edge portion 53 b of the concave surface 53 may be at least partially in contact with the outer peripheral surface 81 b of the connection portion 81. For example, a flange 85 may be partially interposed between the inner edge portion 53b and the outer peripheral surface 81b.

  In the second embodiment, the flange 85 connects the connection surface 81 c of the connection portion 81 and the concave surface 53 of the contactor 23. A part of the flange 85 may connect a part of the outer peripheral surface 81 b of the connection part 81 and a part of the inner edge part 53 b of the concave surface 53 of the contactor 23.

  As described above, the inner edge portion 53 b of the concave surface 53 is in contact with the outer peripheral surface 81 b of the connection portion 81. For this reason, it is suppressed that the collar 85 jumps out into the groove | channel 87 from the clearance gap between the connection part 81 and the contactor 23. FIG.

  The first exposed portion 85 b of the flange 85 may protrude into the groove 87 from the gap between the outer peripheral surface 81 b of the connecting portion 81 and the inner edge portion 53 b of the concave surface 53 of the contactor 23. However, the flange 85 is located inside the outer edge portion 54 of the contactor 23 and inside the outer peripheral surface 62 b of the electrode 22 in the radial direction of the vacuum valve 10.

  In the vacuum valve 10 of the second embodiment described above, the flange 85 connects the connecting portion 81 and the concave surface 53. The connection surface 81 c of the connection portion 81 connected by the flange 85 and the bottom surface 53 a of the concave surface 53 are covered by the inner edge portion 53 b of the concave surface 53. Thereby, it is suppressed that the collar 85 flows out from the outer edge part 54 of the contactor 23 and the outer peripheral surface 62b of the electrode 22 outside. Therefore, the withstand voltage performance of the vacuum valve 10 is more reliably suppressed.

  The inner edge portion 53 b of the concave surface 53 contacts the connection portion 81. Thereby, the contactor 23 and the electrode 22 can be easily positioned without using a high-precision jig, for example. Therefore, the vacuum valve 10 can be easily manufactured.

  The third embodiment will be described below with reference to FIGS. 6 to 8. FIG. 6 is a side view showing the first electrode portion 11 and the second electrode portion 12 according to the third embodiment. FIG. 7 is a plan view showing the first electrode portion 11 or the second electrode portion 12 of the third embodiment, excluding the contact 23. 6 and 7 representatively show the second electrode portion 12.

  As shown in FIG. 7, each of the plurality of protrusions 83 of the third embodiment is formed in a substantially cylindrical shape. Note that the protrusion 83 may be formed in other shapes. The protrusion 83 extends in a direction along the Z axis from the end surface 66 a of the coil portion 66 toward the contact 23. In other words, the protrusion 83 protrudes from the end surface 62 c of the second wall portion 62 of the electrode 22 toward the contactor 23. The columnar protrusion 83 has an outer peripheral surface 83a and an end surface 83b.

  The outer peripheral surface 83a is a substantially cylindrical surface. In the radial direction of the vacuum valve 10, the outermost portion of the outer peripheral surface 83 a of the protrusion 83 forms the outer peripheral surface 81 b of the connection portion 81 and defines the outer diameter of the connection portion 81. In the radial direction of the vacuum valve 10, the innermost portion of the outer peripheral surface 83 a of the protrusion 83 forms the inner peripheral surface 81 a of the connection portion 81 and defines the inner diameter of the connection portion 81.

  The end surface 83b is an end portion of the protrusion 83 in the direction along the Z axis. The end surface 83 b is located on the opposite side of the second wall portion 62. The end surface 83b is a substantially circular surface formed substantially flat. End surfaces 83 b of the plurality of protrusions 83 form a connection surface 81 c of the connection portion 81.

  The plurality of protrusions 83 are arranged at substantially equal intervals in the circumferential direction of the vacuum valve 10. In the circumferential direction of the vacuum valve 10, the distance between the plurality of protrusions 83 is longer than the distance between the plurality of coil portions 66 (the width of the slit 65).

  The plurality of substantially cylindrical protrusions 83 are located inside the outer edge portion 54 of the contactor 23 and inside the outer peripheral surface 62 b of the electrode 22 in the radial direction of the vacuum valve 10. More specifically, in the radial direction of the vacuum valve 10, the outermost portion of the outer peripheral surface 83 a of the protrusion 83 is located on the inner side of the outer edge portion 54 of the contactor 23 and on the inner side of the outer peripheral surface 62 b of the electrode 22. Located in.

  The plurality of protrusions 83 are provided on the end surfaces 66 a of the plurality of coil portions 66. The end face 66a of the coil part 66 has one end part 66aa and the other end part 66ab in the circumferential direction of the vacuum valve 10.

  The end portion 66aa is an end portion of the end face 66a in the direction opposite to the direction in which the coil portion 66 extends (counterclockwise direction in FIG. 7) in the circumferential direction of the vacuum valve 10. The end portion 66ab is an end portion of the end surface 66a in the circumferential direction of the vacuum valve 10 in the direction in which the coil portion 66 extends (clockwise direction in FIG. 7). The protrusion 83 is disposed at a position closer to the end portion 66ab of the end surface 66a than the center of the end surface 66a.

  A part of the protrusion 83 is located inside the inner peripheral surface 62 a of the second wall portion 62 in the radial direction of the vacuum valve 10. In other words, the protrusion 83 protrudes inside the inner peripheral surface 62 a of the second wall portion 62 in the radial direction of the vacuum bulb 10. Therefore, the plurality of protrusions 83 can be easily disposed inside the outer edge portion 54 of the contactor 23 and inside the outer peripheral surface 62 b of the electrode 22 in the radial direction of the vacuum valve 10.

  The protrusion 83 is formed, for example, in a substantially semicircular shape, so that it is disposed inside the outer edge portion 54 of the contactor 23 and inside the outer peripheral surface 62 b of the electrode 22 in the radial direction of the vacuum bulb 10. You may come to be.

  FIG. 8 is a bottom view showing the contact 23 according to the third embodiment. As shown in FIG. 8, the concave surface 53 of the third embodiment has a central portion 91 and a plurality of overhang portions 92. The central portion 91 and the plurality of overhang portions 92 each include a bottom surface 53a and an inner edge portion 53b of the concave surface 53.

  The central portion 91 is a substantially circular portion. The diameter of the inner edge portion 53 b in the central portion 91 (inner diameter of the central portion 91) is substantially equal to the diameter of the inner peripheral surface 62 a of the second wall portion 62 (inner diameter of the electrode 22). The central portion 91 is connected to the concave portion 60 of the electrode 22 to form a hollow portion H.

  The overhang portion 92 is a portion that protrudes (extends) from the central portion 91 to the outside in the radial direction of the vacuum bulb 10. The overhang portion 92 is formed in a substantially semicircular shape, for example. The diameter (inner diameter) of the inner edge portion 53 b in the overhang portion 92 is substantially equal to the diameter (outer diameter) of the columnar protrusion 83.

  When the connecting portion 81 and the contact 23 are fixed to each other, the protrusion 83 of the connecting portion 81 is accommodated in the protruding portion 92 of the concave surface 53. FIG. 8 shows the protrusion 83 with a two-dot chain line. An end surface 83 b of the protrusion 83 is connected to the bottom surface 53 a of the concave surface 53 in the overhang portion 92 by a flange 85.

  The inner edge 53 b of the concave surface 53 in the overhanging portion 92 is in contact with the outer peripheral surface 83 a of the protrusion 83. For this reason, the concave surface 53 restricts the relative movement of the electrode 22 provided with the connecting portion 81 and the contact 23 in the radial direction of the vacuum valve 10. The inner edge 53 b of the concave surface 53 may be at least partially in contact with the outer peripheral surface 83 a of the protrusion 83. For example, a flange 85 may be partially interposed between the inner edge portion 53b and the outer peripheral surface 83a.

  The inner edge portion 53 b of the substantially semicircular protruding portion 92 contacts the outer peripheral surface 83 a of the protrusion 83 in the circumferential direction of the vacuum valve 10. For this reason, the concave surface 53 restricts relative movement of the electrode 22 provided with the connecting portion 81 and the contact 23 in the circumferential direction of the vacuum valve 10.

  In the vacuum valve 10 of the third embodiment described above, the flange 85 connects the plurality of protrusions 83 and the contactor 23. By providing the plurality of cylindrical protrusions 83, the cross-sectional area of the current path through which electricity passes is reduced. Thereby, the coil part 66 of an electrode can generate | occur | produce a magnetic field stably.

  The plurality of protrusions 83 are disposed closer to the end portion 66ab of the end surface 66a in the direction in which the plurality of coil portions 66 extend than the center of the end surface 66a. Thereby, the inclination of the current path in the coil part 66 is easily set large, and the coil part 66 of the electrode can generate a stronger magnetic field.

  The fourth embodiment will be described below with reference to FIG. FIG. 9 is a cross-sectional view showing a part of the first electrode portion 11 or the second electrode portion 12 according to the fourth embodiment. FIG. 9 representatively shows the second electrode portion 12.

  As shown in FIG. 9, in the fourth embodiment, a connection portion 81 is provided on the contactor 23. The connection part 81 has a plurality of substantially cylindrical protrusions 83, for example, as in the third embodiment. In addition, the connection part 81 may be formed in a substantially annular shape as in the first embodiment.

  The connection portion 81 and the protrusion 83 included in the connection portion 81 protrude from the back surface 52 of the contactor 23 toward the end surface 62 c of the second wall portion 62 of the electrode 22. The connection part 81 is formed integrally with the contactor 23.

  The connection surface 81 c of the connection part 81 and the end surface 83 b of the protrusion 83 included in the connection surface 81 c are located on the opposite side of the contactor 23. The connection surface 81 c and the end surface 83 b face the second wall portion 62 of the electrode 22.

  In the fourth embodiment, a concave surface 95 is provided on the end surface 62 c of the second wall portion 62 of the electrode 22. The end surface 62c is an example of a plane. The concave surface 95 is a substantially annular recess, for example, recessed from the end surface 62c. The concave surface 95 may be formed in other shapes. The connecting portion 81 is fitted into the concave surface 95. The concave surface 95 has a bottom surface 95a and an inner edge portion 95b.

  A bottom surface 95 a of the concave surface 95 is a substantially flat annular surface and faces the contactor 23. The bottom surface 95 a of the concave surface 95 faces the connection surface 81 c of the connection portion 81. In other words, the bottom surface 95 a faces the end surface 83 b of the protrusion 83.

  The inner edge portion 95 b is an inner edge portion of the concave surface 95 in the radial direction of the vacuum bulb 10 and extends in the circumferential direction of the vacuum bulb 10. The inner edge portion 95b connects the end surface 62c of the second wall portion 62 and the bottom surface 95a.

  The inner edge portion 95 b faces inward in the radial direction of the vacuum valve 10. In other words, the inner edge portion 95 b faces the central axis of the vacuum valve 10. Note that the inner edge portion 95b may include a portion facing in another direction.

  The diameter of the inner edge portion 95b (the inner diameter of the concave surface 95) is substantially equal to the diameter of the outer peripheral surface 81b of the connection portion 81 (the outer diameter of the connection portion 81). For this reason, the inner edge portion 95 b of the concave surface 95 is in contact with the outer peripheral surface 81 b of the connection portion 81. That is, the inner edge portion 95 b of the concave surface 95 is in contact with the outer peripheral surface 83 a of the protrusion 83. The concave surface 95 restricts the relative movement of the electrode 22 and the contact 23 provided with the connecting portion 81 in the radial direction of the vacuum valve 10.

  The flange 85 connects the connection surface 81 c of the connection portion 81 and the concave surface 95 of the electrode 22. In other words, the flange 85 connects the end surface 83 b of the protrusion 83 and the concave surface 95 of the electrode 22. The flange 85 fixes the connection portion 81, the protrusion 83 included in the connection portion 81, and the electrode 22 to each other. The flange 85 is located inside the outer edge portion 54 of the contactor 23 and inside the outer peripheral surface 62 b of the electrode 22 in the radial direction of the vacuum valve 10.

  As in the vacuum valve 10 of the fourth embodiment described above, the connection portion 81 may be provided on the contactor 23. That is, the connection portion 81 is provided on one of the electrode 22 and the contactor 23.

  According to at least one embodiment described above, the connection part provided on one of the contactor and the electrode, and the connection metal connecting the other of the connection part, the contactor and the electrode are the second. In this direction, it is located inside the outer edge portion of the contact and located inside the outer peripheral surface of the electrode. Thereby, it is suppressed that a connection metal is exposed to a high electric field, and it is suppressed that the withstand voltage performance of a vacuum valve falls.

  Although several embodiments of the present invention have been described, these embodiments are presented by way of example and are not intended to limit the scope of the invention. These novel embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  DESCRIPTION OF SYMBOLS 10 ... Vacuum valve, 11 ... 1st electrode part, 12 ... 2nd electrode part, 22 ... Electrode, 23 ... Contact, 52 ... Back surface, 53 ... Concave surface, 53a ... Bottom surface, 53b ... Inner edge part, 54 ... Outer edge Part, 60 ... concave part, 61 ... first wall part, 62 ... second wall part, 62a ... inner peripheral face, 62b ... outer peripheral face, 62c ... end face, 65 ... slit, 66 ... coil part, 66a ... end face, 66aa, 66ab ... end, 81 ... connecting portion, 81a ... inner peripheral surface, 81b ... outer peripheral surface, 81c ... connecting surface, 83 ... projection, 83a ... outer peripheral surface, 83b ... end surface, 85 ... collar, 95 ... concave surface, 95a ... bottom surface, 95b ... inner edge.

Claims (5)

Two electrode portions that are movable relative to each other in a first direction approaching or separating from each other and in contact with each other;
Each of the two electrode portions is configured to contact the other electrode portion when the two electrode portions are in contact with each other, and has an outer edge portion in a second direction orthogonal to the first direction. With contacts,
Each of the two electrode portions is provided with a plurality of slits and a recess opening toward the contact, and is located on the inner peripheral surface facing the recess and on the opposite side of the inner peripheral surface. An outer peripheral surface, and a plurality of coil portions that are separated from each other by the plurality of slits and configured to generate a magnetic field when electricity flows through the two electrode portions, and between the contacts An electrode that forms a gap;
Provided in one of the contactor and the electrode, projecting toward the other of the contactor and the electrode, and located inward of the outer edge portion of the contactor in the second direction; And a connecting portion located inside the outer peripheral surface of the electrode;
Connecting the connecting portion and the other of the contact and the electrode, and located inward of the outer edge portion of the contact in the second direction, and from the outer peripheral surface of the electrode Is also located inside, with connecting metal,
A vacuum valve comprising: The other of the contactor and the electrode is provided with a flat surface facing one of the contactor and the electrode, and a concave surface that is recessed from the flat surface and faces the connection portion,
The connecting metal connects the connecting portion and the concave surface;
The vacuum valve according to claim 1.   The vacuum valve according to claim 2, wherein an inner edge portion of the concave surface in the second direction is in contact with the connection portion. The connecting portion has a plurality of protrusions protruding from one of the contact and the electrode toward the other of the contact and the electrode,
The connection metal connects the plurality of protrusions, the other of the contacts and the electrode,
The vacuum valve according to any one of claims 1 to 3. Each of the plurality of coil portions has an end surface facing the contact and spaced from the contact,
The plurality of protrusions protrude from the end surfaces of the plurality of coil portions, and are disposed at positions closer to the end portions of the end surfaces in the direction in which the plurality of coil portions extend than the center of the end surfaces.
The vacuum valve according to claim 4.

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