Vacuum interrupter

Abstract

A vacuum interrupter includes: an insulation cylinder; a fixed-side flange; a movable-side flange; a fixed-side electrode rod fixed to the fixed-side flange at one end and having a fixed-side electrode fitting shaft on a fixed-side end surface at another end; a movable-side electrode rod connected to the movable-side flange via a bellows at one end and having a movable-side electrode fitting shaft on a movable-side end surface at another end; a fixed-side windmill-shaped electrode fixed to the fixed-side electrode fitting shaft; and a movable-side windmill-shaped electrode fixed to the movable-side electrode fitting shaft. A fixed-side support member having a fixed-side spacer portion and a fixed-side planar portion is provided between the fixed-side end surface and the fixed-side windmill-shaped electrode, and a movable-side support member having a movable-side spacer portion and a movable-side planar portion is provided between the movable-side end surface and the movable-side windmill-shaped electrode.

Claims

1. A vacuum interrupter comprising: an insulation cylinder; a fixed-side flange sealing one end of the insulation cylinder; a movable-side flange sealing another end of the insulation cylinder; a fixed-side electrode rod which is fixed to the fixed-side flange at one end, and has a fixed-side electrode fitting shaft protruding from a fixed-side end surface at another end and having a smaller outer diameter than the fixed-side end surface; a movable-side electrode rod which is, at one end, connected to the movable-side flange via a bellows on an inner side of the insulation cylinder, and has a movable-side electrode fitting shaft protruding from a movable-side end surface at another end and having a smaller outer diameter than the movable-side end surface, the movable-side electrode rod being slidable in an axial direction of the insulation cylinder; a fixed-side windmill-shaped electrode fixed to the fixed-side electrode fitting shaft and having a plurality of grooves formed in a swirl shape from a center part toward a peripheral part; and a movable-side windmill-shaped electrode fixed to the movable-side electrode fitting shaft so as to be opposed to the fixed-side windmill-shaped electrode, and having a plurality of grooves formed in a swirl shape from a center part toward a peripheral part, wherein a fixed-side support member is held between the fixed-side end surface and the fixed-side windmill-shaped electrode, the fixed-side support member including a fixed-side spacer portion which has a cylindrical shape and surrounds the fixed-side electrode fitting shaft while being distant from the fixed-side electrode fitting shaft, and a fixed-side planar portion which has a disk shape and which spreads outward from an outer circumferential side surface of the fixed-side spacer portion and is opposed to the fixed-side windmill-shaped electrode, and a movable-side support member is held between the movable-side end surface and the movable-side windmill-shaped electrode, the movable-side support member including a movable-side spacer portion which has a cylindrical shape and surrounds the movable-side electrode fitting shaft while being distant from the movable-side electrode fitting shaft, and a movable-side planar portion which has a disk shape and which spreads outward from an outer circumferential side surface of the movable-side spacer portion and is opposed to the movable-side windmill-shaped electrode.

2. The vacuum interrupter according to claim 1, wherein the fixed-side planar portion is provided at an end of the fixed-side spacer portion on a side in contact with the fixed-side windmill-shaped electrode, or the movable-side planar portion is provided at an end of the movable-side spacer portion on a side in contact with the movable-side windmill-shaped electrode.

3. The vacuum interrupter according to claim 1, wherein the fixed-side planar portion is provided at an end of the fixed-side spacer portion on a side in contact with the fixed-side windmill-shaped electrode, and a cutout is formed around a circumference of an end surface of the fixed-side windmill-shaped electrode on a side in contact with the fixed-side planar portion, or the movable-side planar portion is provided at an end of the movable-side spacer portion on a side in contact with the movable-side windmill-shaped electrode, and a cutout is formed around a circumference of an end surface of the movable-side windmill-shaped electrode on a side in contact with the movable-side planar portion.

4. The vacuum interrupter according to claim 1, wherein the fixed-side planar portion is provided between one end and another end of the fixed-side spacer portion, or the movable-side planar portion is provided between one end and another end of the movable-side spacer portion.

5. The vacuum interrupter according to claim 1, wherein the fixed-side planar portion is provided by being fitted to a fitting portion formed by cutting out one end of the fixed-side spacer portion from an outer circumferential side toward an inner circumferential side, or the movable-side planar portion is provided by being fitted to a fitting portion formed by cutting out one end of the movable-side spacer portion from an outer circumferential side toward an inner circumferential side.

6. The vacuum interrupter according to claim 1, wherein the fixed-side planar portion is provided at an end of the fixed-side spacer portion on a side in contact with the fixed-side end surface, or the movable-side planar portion is provided at an end of the movable-side spacer portion on a side in contact with the movable-side end surface.

7. The vacuum interrupter according to claim 1, wherein a groove portion formed at an end surface of the fixed-side windmill-shaped electrode on a side opposed to the fixed-side end surface, and the fixed-side spacer portion, are fitted to each other, or a groove portion formed at an end surface of the movable-side windmill-shaped electrode on a side opposed to the movable-side end surface, and the movable-side spacer portion, are fitted to each other.

8. The vacuum interrupter according to claim 1, wherein the fixed-side planar portion and the fixed-side spacer portion are connected via a rounded portion or a tapered portion, or the movable-side planar portion and the movable-side spacer portion are connected via a rounded portion or a tapered portion.

9. The vacuum interrupter according to claim 1, wherein a cutout formed along a circumference of the fixed-side end surface, and the fixed-side spacer portion, are fitted to each other, or a cutout formed along a circumference of the movable-side end surface, and the movable-side spacer portion, are fitted to each other.

10. The vacuum interrupter according to claim 1, wherein a groove portion formed at the fixed-side end surface, and the fixed-side spacer portion, are fitted to each other, or a groove portion formed at the movable-side end surface, and the movable-side spacer portion, are fitted to each other.

11. The vacuum interrupter according to claim 1, wherein the fixed-side end surface is fitted to a step portion formed by cutting out another end of the fixed-side spacer portion from an inner circumferential side toward an outer circumferential side, or the movable-side end surface is fitted to a step portion formed by cutting out another end of the movable-side spacer portion from an inner circumferential side toward an outer circumferential side.

12. The vacuum interrupter according to claim 1, wherein the fixed-side support member is made of metal whose electric resistance is higher than an electric resistance of the fixed-side electrode rod, and the movable-side support member is made of metal whose electric resistance is higher than an electric resistance of the movable-side electrode rod.

13. The vacuum interrupter according to claim 1, wherein the fixed-side support member and the fixed-side windmill-shaped electrode are fixed to each other, or the movable-side support member and the movable-side windmill-shaped electrode are fixed to each other.

14. The vacuum interrupter according to claim 1, wherein the fixed-side support member and the fixed-side electrode rod are fixed to each other, or the movable-side support member and the movable-side electrode rod are fixed to each other.

15. The vacuum interrupter according to claim 1, wherein the fixed-side support member and the fixed-side windmill-shaped electrode are fixed to each other, and the fixed-side support member and the fixed-side electrode are fixed to each other, or the movable-side support member and the movable-side windmill-shaped electrode are fixed to each other, and the movable-side support member and the movable-side electrode rod are fixed to each other.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a sectional view showing a schematic structure of a vacuum interrupter according to embodiment 1.

(2) FIG. 2 is a sectional view showing a schematic structure around a windmill-shaped electrode of the vacuum interrupter according to embodiment 1.

(3) FIG. 3 is a plan view showing the windmill-shaped electrode of the vacuum interrupter according to embodiment 1.

(4) FIG. 4A and FIG. 4B are views showing a schematic structure of a support member of the vacuum interrupter according to embodiment 1.

(5) FIG. 5A and FIG. 5B are views showing a schematic structure of another support member of the vacuum interrupter according to embodiment 1.

(6) FIG. 6A and FIG. 6B are views showing a schematic structure of another support member of the vacuum interrupter according to embodiment 1.

(7) FIG. 7 is a sectional view showing a schematic structure of a vacuum interrupter according to embodiment 2.

(8) FIG. 8 is a sectional view showing a schematic structure around a windmill-shaped electrode of the vacuum interrupter according to embodiment 2.

(9) FIG. 9 is a sectional view showing a schematic structure around a windmill-shaped electrode of a vacuum interrupter according to embodiment 3.

(10) FIG. 10 is a sectional view showing a schematic structure around the windmill-shaped electrode of the vacuum interrupter according to embodiment 3.

(11) FIG. 11 is a sectional view showing a schematic structure around the windmill-shaped electrode of the vacuum interrupter according to embodiment 3.

(12) FIG. 12 is a sectional view showing a schematic structure around a windmill-shaped electrode of a vacuum interrupter according to embodiment 4.

(13) FIG. 13 is a sectional view showing a schematic structure around the windmill-shaped electrode of the vacuum interrupter according to embodiment 4.

(14) FIG. 14 is a sectional view showing a schematic structure of a vacuum interrupter according to embodiment 5.

(15) FIG. 15A and FIG. 15B are views showing a schematic structure around a windmill-shaped electrode of the vacuum interrupter according to embodiment 5.

(16) FIG. 16A and FIG. 16B are views showing a schematic structure around the windmill-shaped electrode of the vacuum interrupter according to embodiment 5.

(17) FIG. 17 is a sectional view showing a schematic structure around the windmill-shaped electrode of the vacuum interrupter according to embodiment 5.

DESCRIPTION OF EMBODIMENTS

(18) Hereinafter, vacuum interrupters according to embodiments of the present disclosure will be described with reference to the drawings. In the drawings, the same or corresponding members and parts are denoted by the same reference characters, to give description.

Embodiment 1

(19) FIG. 1 is a sectional view showing a schematic structure of a vacuum interrupter 1, and FIG. 2 is a sectional view showing a schematic structure around a movable-side windmill-shaped electrode 13 of the vacuum interrupter 1. The vacuum interrupter 1 is configured such that a fixed-side windmill-shaped electrode 12 and the movable-side windmill-shaped electrode 13 which are opened at the time of current interruption are provided inside an airtight container formed by an insulation cylinder 2, a fixed-side flange 3, and a movable-side flange 4.

(20) The structure of the vacuum interrupter 1 will be described. The vacuum interrupter 1 includes the insulation cylinder 2 having a cylindrical shape and made of an insulating material such as alumina ceramic, the fixed-side flange 3 sealing one end of the insulation cylinder 2 and made of metal such as stainless steel, and the movable-side flange 4 sealing the other end of the insulation cylinder 2 and made of metal such as stainless steel. The inside of the vacuum interrupter 1 is kept airtight in a high vacuum state. The fixed-side flange 3 and the movable-side flange 4 are fixed by vacuum brazing to metallization layers 5 formed at both ends of the insulation cylinder 2.

(21) The vacuum interrupter 1 includes a fixed-side electrode rod 6 and a movable-side electrode rod 7. The fixed-side electrode rod 6 is, at one end, fixed to the fixed-side flange 3 on the inner side of the insulation cylinder 2, and has a fixed-side electrode fitting shaft 6b protruding from a fixed-side end surface 6a at another end and having a smaller outer diameter than the fixed-side end surface 6a. The movable-side electrode rod 7 is, at one end, connected to the movable-side flange 4 via a bellows 8 on the inner side of the insulation cylinder 2, and has a movable-side electrode fitting shaft 7b protruding from a movable-side end surface 7a at another end and having a smaller outer diameter than the movable-side end surface 7a. The movable-side electrode rod 7 is slidable in the axial direction of the insulation cylinder 2. One end of the bellows 8 and the movable-side electrode rod 7 are fixed to each other via a bellows cover 9. The bellows cover 9 is provided for preventing the bellows 8 from being contaminated by arc occurring at the time of current interruption, and is made of stainless steel, for example. A guide 10 made of thermoplastic synthetic resin or the like is attached to the movable-side flange 4 after the vacuum interrupter 1 is sealed in a vacuum state. The movable-side electrode rod 7 and the guide 10 are sliding portions, and the guide 10 has a bearing function. For the purpose of preventing the inner circumferential surface of the insulation cylinder 2 from being contaminated by arc occurring between the fixed-side windmill-shaped electrode 12 and the movable-side windmill-shaped electrode 13 at the time of current interruption, an arc shield 11 is provided so as to surround the fixed-side windmill-shaped electrode 12 and the movable-side windmill-shaped electrode 13.

(22) As shown in FIG. 2, the movable-side windmill-shaped electrode 13 is fitted to the movable-side electrode fitting shaft 7b, and fixed thereto by brazing or the like. While FIG. 2 shows the schematic structure around the movable-side windmill-shaped electrode 13, the schematic structure around the fixed-side windmill-shaped electrode 12 is also the same structure. Since the movable-side electrode rod 7 to which the movable-side windmill-shaped electrode 13 is fixed is attached to the movable-side flange 4 via the bellows 8, the movable-side windmill-shaped electrode 13 is allowed to contact with and be separated from the fixed-side windmill-shaped electrode 12 on the axis of the insulation cylinder 2 while the airtight state is kept. FIG. 3 is a plan view showing the movable-side windmill-shaped electrode 13 of the vacuum interrupter 1 according to embodiment 1. The movable-side windmill-shaped electrode 13 has a plurality of grooves 13c formed in a swirl shape from the center part toward the peripheral part and thus an arc portion 13d is formed between two grooves 13c. The fixed-side windmill-shaped electrode 12 also has the same structure, and arc portions of the fixed-side windmill-shaped electrode 12 are provided at positions opposed to the arc portion 13d so that the respective arc portions come into contact with each other. When the fixed-side windmill-shaped electrode 12 and the movable-side windmill-shaped electrode 13 are opened at the time of current interruption, arc 100 occurs at any point on the arc portions 13d. Current I.sub.X applied to the movable-side windmill-shaped electrode 13 flows from the center along the shape of the arc portions 13d and then flows to the arc portions of the opposed fixed-side windmill-shaped electrode 12 via the arc 100. At this time, a magnetic flux density B.sub.X (not shown) occurs by the current I.sub.X. The arc 100 is subjected to a drive force F.sub.X proportional to the magnetic flux density B.sub.X, and thus rotationally moves at high speed counterclockwise on the arc portions 13d.

(23) As shown in FIG. 2, a movable-side support member 15 is held between the movable-side end surface 7a and the movable-side windmill-shaped electrode 13. Similarly, a fixed-side support member 14 is held between the fixed-side end surface 6a and the fixed-side windmill-shaped electrode 12. FIG. 4A and FIG. 4B are views showing a schematic structure of the movable-side support member 15 of the vacuum interrupter 1. FIG. 4A is a sectional view and FIG. 4B is a perspective view. The fixed-side support member 14 also has the same structure as the movable-side support member 15. Hereinafter, the fixed-side support member 14 and the movable-side support member 15 have the same shape and the same function in the same embodiment, and therefore description will be give using only one movable-side support member 15. The movable-side support member 15 includes a movable-side spacer portion 15a which has a cylindrical shape and surrounds the movable-side electrode fitting shaft 7b while being distant from the movable-side electrode fitting shaft 7b, and a movable-side planar portion 15b which has a disk shape and which spreads outward from an outer circumferential side surface of the movable-side spacer portion 15a and is opposed to the movable-side windmill-shaped electrode 13. The movable-side planar portion 15b is provided at an end of the movable-side spacer portion 15a on the side in contact with the movable-side windmill-shaped electrode 13. A space 16 is formed between the movable-side spacer portion 15a and the movable-side electrode fitting shaft 7b.

(24) The movable-side support member 15 is made of metal whose electric resistance is higher than those of the movable-side windmill-shaped electrode 13 and the movable-side electrode rod 7. For example, the movable-side support member 15 is made of stainless steel, and manufactured through cutting work from a round bar or a pipe material, press work from a pipe material or a plate material, or the like. Since the sectional area of the movable-side spacer portion 15a is small, the electric resistance of the movable-side spacer portion 15a is high. In addition, since the contact area between the movable-side spacer portion 15a and the movable-side electrode rod 7 is small, the resistance therebetween is high. Thus, leakage current flowing from the movable-side windmill-shaped electrode 13 or the movable-side electrode rod 7 to the movable-side spacer portion 15a is inhibited. It is noted that the movable-side support member 15 is not limited to such an integrally formed structure, and may be formed by combining a plurality of parts.

(25) The movable-side support member 15 has a function of reinforcing the movable-side windmill-shaped electrode 13. Specifically, the movable-side support member 15 has a function of preventing the movable-side windmill-shaped electrode 13 from being deformed by a load when the movable-side windmill-shaped electrode 13 and the fixed-side windmill-shaped electrode 12 are closed, and preventing the movable-side windmill-shaped electrode 13 from being deformed by an external pressing force applied to the vacuum interrupter 1 for increasing the contact area and reducing contact resistance between the movable-side windmill-shaped electrode 13 and the fixed-side windmill-shaped electrode 12. In addition, the movable-side planar portion 15b has a function of preventing scattering of metal spatter occurring at the time of current interruption.

(26) Since the movable-side spacer portion 15a is provided and the movable-side electrode fitting shaft 7b is formed with a length equivalent to the movable-side spacer portion 15a, the movable-side electrode fitting shaft 7b is provided with a sufficient distance so that current flowing from the movable-side electrode rod 7 to the movable-side electrode fitting shaft 7b is collected in the movable-side electrode fitting shaft 7b.

(27) Since the space 16 is provided, a path of current flowing from a part other than the movable-side electrode fitting shaft 7b into the movable-side windmill-shaped electrode 13 is restricted. While interruption is repeated, a phenomenon in which the arc-shaped grooves of the windmill-shaped electrode are gradually filled up due to wear of the electrode surface may occur. Even in this case, owing to provision of the space 16, the grooves are prevented from being closed over the entire surfaces. Thus, reduction in interruption performance is inhibited and the life for short-circuit interruption is also improved.

(28) Fixation of the movable-side support member 15 will be described. The movable-side support member 15 may be held by only contact without being fixed by the movable-side windmill-shaped electrode 13 and the movable-side electrode rod 7 which are contact parts with the movable-side support member 15. Alternatively, the movable-side support member 15 may be fixed only at the contact part between the movable-side support member 15 and the movable-side windmill-shaped electrode 13. The fixation in this case may be performed by brazing with a brazing material put between the movable-side support member 15 and the movable-side windmill-shaped electrode 13, for example. By this fixation, position displacement of the movable-side support member 15 is inhibited. The movable-side support member 15 and the movable-side electrode rod 7 are merely in contact with each other and the resistance therebetween is high. Thus, leakage current flowing therebetween can be inhibited. Accordingly, current flowing through the movable-side windmill-shaped electrode 13 is increased and the arc drive force is increased, whereby interruption performance can be improved.

(29) The movable-side support member 15 may be fixed only at the contact part between the movable-side support member 15 and the movable-side electrode rod 7. The fixation in this case may be performed by brazing with a brazing material put between the movable-side support member 15 and the movable-side electrode rod 7, for example. By this fixation, position displacement of the movable-side support member 15 is inhibited. The movable-side support member 15 and the movable-side windmill-shaped electrode 13 are merely in contact with each other and the resistance therebetween is high. Thus, leakage current flowing therebetween can be inhibited. Accordingly, current flowing through the movable-side windmill-shaped electrode 13 is increased and the arc drive force is increased, whereby interruption performance can be improved.

(30) The movable-side support member 15 may be fixed at the contact part between the movable-side support member 15 and the movable-side windmill-shaped electrode 13 and at the contact part between the movable-side support member 15 and the movable-side electrode rod 7. The fixation in this case may be performed by brazing, for example. By this fixation, position displacement of the movable-side support member 15 is inhibited. Even if an electromagnetic force is applied to the movable-side electrode fitting shaft 7b from the outside when short-circuit current flows, since the movable-side support member 15 made of a material having a great strength is fixed at two parts of the movable-side windmill-shaped electrode 13 and the movable-side electrode rod 7, deformation of the movable-side electrode fitting shaft 7b which is comparatively thin and has a small strength can be prevented.

(31) Another structure example of the movable-side support member 15 will be described. FIG. 5A and FIG. 5B are views showing a schematic structure of another movable-side support member 15 of the vacuum interrupter 1 according to embodiment 1. FIG. 5A is a sectional view and FIG. 5B is a perspective view. The fixed-side support member 14 also has the same structure as the movable-side support member 15. The movable-side planar portion 15b and the movable-side spacer portion 15a are connected via a rounded portion 17. In a case where the movable-side support member 15 is manufactured by cutting work or press work, the rounded portion 17 which is a connection portion between the movable-side planar portion 15b and the movable-side spacer portion 15a can be easily formed into a rounded shape, and thus workability is improved. In addition, forming the rounded shape can relax stress concentration on the connection portion due to a load from an external pressing force and impact at the time of electrode closing. In order to obtain the above effects, it is desirable that the rounding size of the rounded portion 17 is equal to or greater than the thickness of the movable-side support member 15. FIG. 6A and FIG. 6B are views showing a schematic structure of still another movable-side support member 15 of the vacuum interrupter 1 according to embodiment 1. FIG. 6A is a sectional view and FIG. 6B is a perspective view. The movable-side planar portion 15b and the movable-side spacer portion 15a of the movable-side support member 15 are connected via a tapered portion 18. Providing the tapered portion 18 exhibits the same effects as in the case of the rounded portion 17.

(32) As described above, the vacuum interrupter 1 has the fixed-side support member 14 between the fixed-side end surface 6a and the fixed-side windmill-shaped electrode 12, and the movable-side support member 15 between the movable-side end surface 7a and the movable-side windmill-shaped electrode 13. Thus, the vacuum interrupter 1 has a function of reinforcing the fixed-side windmill-shaped electrode 12 and the movable-side windmill-shaped electrode 13, and can inhibit leakage current flowing through parts other than the fixed-side windmill-shaped electrode 12 and the movable-side windmill-shaped electrode 13, and the fixed-side electrode rod 6 and the movable-side electrode rod 7. In addition, the fixed-side support member 14 and the movable-side support member 15 respectively have the fixed-side planar portion 14b and the movable-side planar portion 15b, thus having a function of preventing scattering of metal spatter occurring at the time of current interruption. In addition, since the leakage current is inhibited, current supplied to the fixed-side windmill-shaped electrode 12 and the movable-side windmill-shaped electrode 13 is increased. Thus, the magnetic flux density of a magnetic field occurring at the time of electrode opening is increased and the arc drive force is increased, whereby the arc rotation speed increases. As a result, the interruption performance can be improved without size increase in the fixed-side windmill-shaped electrode 12 and the movable-side windmill-shaped electrode 13.

Embodiment 2

(33) A vacuum interrupter 1 according to embodiment 2 will be described. FIG. 7 is a sectional view showing a schematic structure of the vacuum interrupter 1. FIG. 8 is a sectional view showing a schematic structure around the movable-side windmill-shaped electrode 13 of the vacuum interrupter 1. The vacuum interrupter 1 according to embodiment 2 is configured such that cutouts 12a, 13a are respectively provided in the fixed-side windmill-shaped electrode 12 and the movable-side windmill-shaped electrode 13 of the vacuum interrupter 1 shown in embodiment 1. While FIG. 8 shows the schematic structure around the movable-side windmill-shaped electrode 13, the schematic structure around the fixed-side windmill-shaped electrode 12 is also the same structure.

(34) The cutout 13a is provided around the circumference of an end surface of the movable-side windmill-shaped electrode 13 on the side in contact with the movable-side planar portion 15b. The cutout 12a is provided in the fixed-side windmill-shaped electrode 12. The cutouts 12a, 13a are formed through cutting work after the fixed-side windmill-shaped electrode 12 and the movable-side windmill-shaped electrode 13 are manufactured, for example.

(35) As described above, the vacuum interrupter 1 has the cutouts 12a, 13a, so that the contact areas between the fixed-side planar portion 14b and the fixed-side windmill-shaped electrode 12 and between the movable-side planar portion 15b and the movable-side windmill-shaped electrode 13, are reduced. Thus, the resistances therebetween are increased, whereby leakage current flowing from the fixed-side windmill-shaped electrode 12 and the movable-side windmill-shaped electrode 13 to the fixed-side planar portion 14b and the movable-side planar portion 15b is inhibited. In addition, since the leakage current is inhibited, current supplied to the fixed-side windmill-shaped electrode 12 and the movable-side windmill-shaped electrode 13 is increased. Thus, the magnetic flux density of a magnetic field occurring at the time of electrode opening is increased and the arc drive force is increased, whereby the arc rotation speed increases. As a result, the interruption performance can be improved without size increase in the fixed-side windmill-shaped electrode 12 and the movable-side windmill-shaped electrode 13.

Embodiment 3

(36) A vacuum interrupter 1 according to embodiment 3 will be described. FIG. 9 is a sectional view showing a schematic structure around the movable-side windmill-shaped electrode 13 of the vacuum interrupter 1. The vacuum interrupter 1 according to embodiment 3 is configured such that the fixed-side support member 14 and the movable-side support member 15 are provided so as to be fitted to the fixed-side electrode rod 6 and the movable-side electrode rod 7, respectively. While FIG. 9 shows the schematic structure around the movable-side windmill-shaped electrode 13, the schematic structure around the fixed-side windmill-shaped electrode 12 is also the same structure. Therefore, reference characters for parts around the fixed-side windmill-shaped electrode 12 are also shown together in FIG. 9, and description of the schematic structure around the fixed-side windmill-shaped electrode 12 is omitted.

(37) An end surface cutout 7c formed along the circumference of the movable-side end surface 7a and the movable-side spacer portion 15a of the movable-side support member 15 are fitted to each other. The end surface cutout 7c is formed through cutting work after the movable-side electrode rod 7 is manufactured, for example.

(38) The structure for fitting the movable-side support member 15 to the movable-side electrode rod 7 may be a structure shown in a sectional view in FIG. 10. A groove portion 7d formed at the movable-side end surface 7a and the movable-side spacer portion 15a of the movable-side support member 15 are fitted to each other. Alternatively, the structure for fitting the movable-side support member 15 to the movable-side electrode rod 7 may be a structure shown in a sectional view in FIG. 11. An outer circumference of the movable-side end surface 7a is fitted to a step portion 15c formed by cutting out another end of the movable-side spacer portion 15a of the movable-side support member 15 from the inner circumferential side toward the outer circumferential side.

(39) As described above, the vacuum interrupter 1 is configured such that the fixed-side support member 14 and the movable-side support member 15 are fitted to the fixed-side electrode rod 6 and the movable-side electrode rod 7 with use of the end surface cutouts 6c, 7c, the groove portions 6d, 7d, or the step portions 14c, 15c, respectively. Thus, the fixed-side support member 14 and the movable-side support member 15 can be easily positioned, whereby assemblability of the vacuum interrupter 1 can be easily improved. In addition, since the fixed-side support member 14 and the movable-side support member 15 are respectively fixed by being fitted to the fixed-side electrode rod 6 and the movable-side electrode rod 7, position displacement of the movable-side support member 15 and the fixed-side support member 14 can be inhibited. In addition, since the movable-side support member 15 and the fixed-side support member 14 are each fixed by fitting, even if an electromagnetic force is applied to the fixed-side electrode fitting shaft 6b and the movable-side electrode fitting shaft 7b from the outside when short-circuit current flows, deformation of the fixed-side electrode fitting shaft 6b and the movable-side electrode fitting shaft 7b which are comparatively thin and have small strengths can be prevented. In the case where the movable-side support member 15 and the fixed-side support member 14 are respectively fixed by being fitted to the groove portions 6d, 7d, it is possible to design the movable-side support member 15 and the fixed-side support member 14 without depending on the outer diameter sizes of the fixed-side electrode rod 6 and the movable-side electrode rod 7. In the case where the movable-side support member 15 and the fixed-side support member 14 are respectively fixed by being fitted to the step portions 14c, 15c, parts of the side surfaces of the fixed-side electrode rod 6 and the movable-side electrode rod 7 are covered by the side surfaces of the step portions 14c, 15c, whereby electric fields around the fixed-side electrode rod 6 and the movable-side electrode rod 7 can be relaxed and voltage withstanding property therearound can be improved.

Embodiment 4

(40) A vacuum interrupter 1 according to embodiment 4 will be described. FIG. 12 is a sectional view showing a schematic structure around the movable-side windmill-shaped electrode 13 of the vacuum interrupter 1. The vacuum interrupter 1 according to embodiment 4 is configured such that the fixed-side planar portion 14b and the movable-side planar portion 15b are in contact with the fixed-side electrode rod 6 and the movable-side electrode rod 7, respectively. While FIG. 12 shows the schematic structure around the movable-side windmill-shaped electrode 13, the schematic structure around the fixed-side windmill-shaped electrode 12 is also the same structure. Therefore, reference characters for parts around the fixed-side windmill-shaped electrode 12 are also shown together in FIG. 12, and description of the schematic structure around the fixed-side windmill-shaped electrode 12 is omitted.

(41) The movable-side planar portion 15b is provided at an end of the movable-side spacer portion 15a on the side in contact with the movable-side end surface 7a. The movable-side support member 15 is made of metal having a high electric resistance, such as stainless steel, and is manufactured through cutting work from a round bar or a pipe material, press work from a pipe material or a plate material, or the like. It is noted that the movable-side support member 15 is not limited to such an integrally formed structure, and may be formed by combining a plurality of parts.

(42) Another structure example of the vacuum interrupter 1 having the movable-side support member 15 shown in the present embodiment will be described. FIG. 13 is a sectional view showing a schematic structure around the movable-side windmill-shaped electrode 13 of the vacuum interrupter 1 according to embodiment 4. A groove portion 13b formed at an end surface of the movable-side windmill-shaped electrode 13 on the side opposed to the movable-side end surface 7a, and the movable-side spacer portion 15a of the movable-side support member 15, are fitted to each other. The groove portion 13b is formed by cutting work after the movable-side windmill-shaped electrode 13 is manufactured, for example.

(43) As described above, the vacuum interrupter 1 is configured such that the fixed-side planar portion 14b and the movable-side planar portion 15b are in contact with the fixed-side electrode rod 6 and the movable-side electrode rod 7, respectively. Thus, the contact areas between the fixed-side support member 14 and the fixed-side windmill-shaped electrode 12 and between the movable-side support member 15 and the movable-side windmill-shaped electrode 13, are reduced, whereby leakage current flowing from the fixed-side windmill-shaped electrode 12 and the movable-side windmill-shaped electrode 13 to the fixed-side support member 14 and the movable-side support member 15 can be inhibited. In addition, the contact is made in a state in which the outer circumferences of the fixed-side windmill-shaped electrode 12 and the movable-side windmill-shaped electrode 13 are distant from the fixed-side support member 14 and the movable-side support member 15. Thus, currents flowing at the outer circumferences of the fixed-side windmill-shaped electrode 12 and the movable-side windmill-shaped electrode 13 mainly when arc is driven, can be inhibited from divisionally flowing to the fixed-side support member 14 and the movable-side support member 15. In addition, since the leakage current is inhibited, current supplied to the fixed-side windmill-shaped electrode 12 and the movable-side windmill-shaped electrode 13 is increased. Thus, the magnetic flux density of a magnetic field occurring at the time of electrode opening is increased and the arc drive force is increased, whereby the arc rotation speed increases. As a result, the interruption performance can be improved without size increase in the fixed-side windmill-shaped electrode 12 and the movable-side windmill-shaped electrode 13. In the case where the groove portion 12b and the groove portion 13b are provided, the fixed-side support member 14 and the movable-side support member 15 can be easily positioned, whereby assemblability of the vacuum interrupter 1 can be easily improved and position displacement of the fixed-side support member 14 and the movable-side support member 15 is inhibited. In addition, in the case where the groove portion 12b and the groove portion 13b are provided, currents in the parts of the fixed-side windmill-shaped electrode 12 and the movable-side windmill-shaped electrode 13 where the groove portion 12b and the groove portion 13b are respectively formed flow at positions closer to the electrode surfaces opposed to each other, so that the current densities are increased. Thus, the magnetic flux density of a magnetic field occurring at the time of electrode opening is increased, whereby interruption performance can be further improved.

(44) Embodiment 4 has shown the case of providing the fixed-side planar portion 14b and the movable-side planar portion 15b at positions different from those in embodiment 1. However, the fixed-side support member 14 or the movable-side support member 15 shown in embodiment 1, and the fixed-side support member 14 or the movable-side support member 15 shown in embodiment 4, may be provided in combination.

Embodiment 5

(45) A vacuum interrupter 1 according to embodiment 5 will be described. FIG. 14 is a sectional view showing a schematic structure of the vacuum interrupter 1, and FIG. 15A and FIG. 15B are views showing a schematic structure around the movable-side windmill-shaped electrode 13 of the vacuum interrupter 1. FIG. 15A is a sectional view and FIG. 15B is a perspective view. The fixed-side support member 14 and the movable-side support member 15 of the vacuum interrupter 1 according to embodiment 5 are formed such that the fixed-side planar portion 14b and the movable-side planar portion 15b are respectively provided between one end and another end of each of the fixed-side spacer portion 14a and the movable-side spacer portion 15a. While FIG. 15A shows the schematic structure around the movable-side windmill-shaped electrode 13, the schematic structure around the fixed-side windmill-shaped electrode 12 is also the same structure.

(46) The movable-side planar portion 15b is provided by being fitted to a fitting portion 15d formed by cutting out one end of the movable-side spacer portion 15a at the end in contact with the movable-side windmill-shaped electrode 13 from the outer circumferential side toward the inner circumferential side. Similarly, the fixed-side planar portion 14b is provided by being fitted to a fitting portion 14d formed by cutting out one end of the fixed-side spacer portion 14a at the end in contact with the fixed-side windmill-shaped electrode 12 from the outer circumferential side toward the inner circumferential side. The movable-side spacer portion 15a is made of metal having a high electric resistance, such as stainless steel, and is manufactured by forming the fitting portion 15d through cutting work from a pipe material, for example. The movable-side planar portion 15b is made of metal having a high electric resistance, such as stainless steel, and is manufactured through press work from a plate material, for example.

(47) Another structure example of the movable-side support member 15 will be described. FIG. 16A and FIG. 16B are views showing a schematic structure around the movable-side windmill-shaped electrode 13 of the vacuum interrupter 1 according to embodiment 5. FIG. 16A is a sectional view and FIG. 16B is a perspective view. The movable-side planar portion 15b is provided by being fitted to the fitting portion 15d formed by cutting out another end of the movable-side spacer portion 15a at the end in contact with the movable-side end surface 7a from the outer circumferential side toward the inner circumferential side. In both of the structures shown in FIG. 15A and FIG. 16A, the position where the movable-side planar portion 15b is provided to the movable-side spacer portion 15a can be easily changed by changing the length of the fitting portion 15d in the movable direction of the movable-side windmill-shaped electrode 13. In a case of reducing the contact area between the movable-side support member 15 and the movable-side windmill-shaped electrode 13, the structure shown in FIG. 15 is desirable. In a case of reducing the contact area between the movable-side support member 15 and the movable-side electrode rod 7, the structure shown in FIG. 16A is desirable.

(48) In the above description, the case of forming the movable-side support member 15 from the movable-side spacer portion 15a and the movable-side planar portion 15b which are separate bodies, has been shown. However, as shown in a sectional view in FIG. 17, the movable-side support member 15 may be formed as an integrated body. The movable-side support member 15 is made of metal having a high electric resistance, such as stainless steel, and is manufactured through cutting work from a round bar or a pipe material, for example.

(49) As described above, the fixed-side support member 14 and the movable-side support member 15 of the vacuum interrupter 1 are configured such that the fixed-side planar portion 14b and the movable-side planar portion 15b are respectively provided between one end and another end of each of the fixed-side spacer portion 14a and the movable-side spacer portion 15a. Thus, the contact areas between the fixed-side support member 14 and the fixed-side windmill-shaped electrode 12 and between the movable-side support member 15 and the movable-side windmill-shaped electrode 13, and the contact areas between the fixed-side support member 14 and the fixed-side electrode rod 6 and between the movable-side support member 15 and the movable-side electrode rod 7, are both reduced, whereby leakage current flowing to the fixed-side support member 14 and the movable-side support member 15 can be inhibited. In addition, since the leakage current is inhibited, current supplied to the fixed-side windmill-shaped electrode 12 and the movable-side windmill-shaped electrode 13 is increased. Thus, the magnetic flux density of a magnetic field occurring at the time of electrode opening is increased and the arc drive force is increased, whereby the arc rotation speed increases. As a result, the interruption performance can be improved without size increase in the fixed-side windmill-shaped electrode 12 and the movable-side windmill-shaped electrode 13. In addition, in the case of providing the fixed-side planar portion 14b and the movable-side planar portion 15b by forming the fitting portions 14d, 15d, it is possible to provide the fixed-side planar portion 14b and the movable-side planar portion 15b at desired positions. Therefore, the fixed-side planar portion 14b and the movable-side planar portion 15b can be provided at positions where the function of preventing scattering of metal spatter occurring at the time of current interruption is required.

(50) Although the disclosure is described above in terms of various exemplary embodiments and implementations, it should be understood that the various features, aspects, and functionality described in one or more of the individual embodiments are not limited in their applicability to the particular embodiment with which they are described, but instead can be applied, alone or in various combinations to one or more of the embodiments of the disclosure.

(51) It is therefore understood that numerous modifications which have not been exemplified can be devised without departing from the scope of the present disclosure. For example, at least one of the constituent components may be modified, added, or eliminated. At least one of the constituent components mentioned in at least one of the preferred embodiments may be selected and combined with the constituent components mentioned in another preferred embodiment.

DESCRIPTION OF THE REFERENCE CHARACTERS

(52) 1 vacuum interrupter 2 insulation cylinder 3 fixed-side flange 4 movable-side flange 5 metallization layer 6 fixed-side electrode rod 6a fixed-side end surface 6b fixed-side electrode fitting shaft 6c end surface cutout 6d groove portion 7 movable-side electrode rod 7a movable-side end surface 7b movable-side electrode fitting shaft 7c end surface cutout 7d groove portion 8 bellows 9 bellows cover 10 guide 11 arc shield 12 fixed-side windmill-shaped electrode 12a cutout 12b groove portion 13 movable-side windmill-shaped electrode 13a cutout 13b groove portion 13c groove 13d arc portion 14 fixed-side support member 14a fixed-side spacer portion 14b fixed-side planar portion 14c step portion 14d fitting portion 15 movable-side support member 15a movable-side spacer portion 15b movable-side planar portion 15c step portion 15d fitting portion 16 space 17 rounded portion 18 tapered portion 100 arc