Abstract
An interrupter unit includes a vacuum switch tube and an insulating housing. The insulating housing has an inner surface. The vacuum switch tube is bordered at least partially by an electrically insulating structure material having an outer surface. The insulating housing at least partially surrounds the vacuum switch tube. In operation, inner surface of the insulating housing and outer surface of the vacuum switch tube are separated by an adhesion layer. The inner surface and the outer surface are provided at least partially with an electrically conductive layer such that, in a boundary region between vacuum switch tube and insulating housing, the following layer sequence is directed radially outwards from a switch axis: structure material of vacuum switch tube; outer surface of structure material; conductive layer on outer surface of structure material; adhesion layer; conductive layer on insulating housing; inner surface of insulating housing; volume material of insulating housing.
Claims
1-8. (canceled)
9. An interrupter unit, comprising: a vacuum switch tube; an insulating housing at least partially surrounding said vacuum switch tube, said insulating housing having an inner surface provided at least partially with an electrically conductive layer and said insulating housing having a volume material; an electrically insulating structure material at least partially bordering said vacuum switch tube, said electrically insulating structure material having an outer surface provided at least partially with an electrically conductive layer; an adhesion layer separating said inner surface of said insulating housing and said outer surface of said vacuum switch tube in an operational state of the interrupter unit; and a boundary region between said vacuum switch tube and said insulating housing having a layer sequence as follows in a radially outward direction from a switch axis: said structure material of said vacuum switch tube, said outer surface of said structure material, said conductive layer at said outer surface of said structure material, said adhesion layer, said conductive layer at said insulating housing, said inner surface of said insulating housing, and said volume material of said insulating housing.
10. The interrupter unit according to claim 9, wherein said conductive layers include a semiconducting material.
11. The interrupter unit according to claim 9, wherein said conductive layers each have a conductivity providing an electric resistance of said conductive layer in an axial direction in a range between 108 and 1015 ohms.
12. The interrupter unit according to claim 9, wherein said conductive layers contain silicon carbide.
13. The interrupter unit according to claim 9, wherein said insulating housing has a decreasing permittivity in the radially outward direction starting from the switch axis.
14. The interrupter unit according to claim 13, wherein the permittivity of said insulating housing decreases radially outwards in stages.
15. The interrupter unit according to claim 9, wherein said insulating housing includes a radially outer edge having a permittivity of between 1 and 2.
16. The interrupter unit according to claim 9, wherein said insulating housing includes a radially outer edge having a permittivity of between 1.2 and 1.5.
17. The interrupter unit according to claim 9, wherein said insulating housing is formed substantially of a plastic material.
18. The interrupter unit according to claim 9, wherein said insulating housing is formed of an epoxy resin.
Description
[0011] In the drawings:
[0012] FIG. 1 shows an illustration of the manufacture of an interrupter unit with an insulating housing;
[0013] FIG. 2 shows an enlarged illustration of the boundary region between the insulating housing and the vacuum switch tube according to the detail II of FIG. 1;
[0014] FIG. 3 shows a dependence of the electric field along the radial extent r according to III of FIG. 1.
[0015] FIG. 1 shows the design and production of an interrupter unit 2 with a vacuum switch tube 4 and an insulating housing 6. In the illustration according to a on the far left, a vacuum switch tube 4 is shown, which has a structure material 22 which surrounds a vacuum space 28. Two switch contacts 26 are illustrated schematically in the vacuum space 28, wherein at least one of these can be moved in a translatory manner along a switch axis 20. In this case, the outer form of the vacuum switch tube 4 should be understood as being purely schematic; the structure material 22, which generally consists of or comprises an insulating ceramic material, generally represents merely part of a housing of a vacuum switch tube 4. In particular, in a region in which the switch contacts 26 move along the switch axis 20, the vacuum switch tube 4 is bordered externally by a metal outer material.
[0016] According to the partial figure b in FIG. 1, a conductive or semiconducting layer 16 is furthermore applied to an outer surface 10 of the vacuum tube 4 or the structure material 22. This refers for example to a silicon carbide material in powder form, which is integrated in an epoxy matrix and has an SiC fill level which is between 50 and 70 percent of the total volume. The resultant layer 16 has a conductivity which is calculated such that the electric resistance of the layer in the axial direction is in range between 108 and 1015 ohm. In this case, the conductivity of the layer 16 is determined according to the rated voltage and the specified geometrical parameters of the vacuum switch tube and the resultant electric field.
[0017] According to the partial figure c, an insulating housing 6 is furthermore pushed over the vacuum switch tube 4. In this case, as seen schematically here, the insulating housing 6 has a cylindrical configuration, wherein a form-locking mounting of the insulating housing 6 is shown in this case. It is essentially also possible or expedient to cast the insulating housing 6 onto the vacuum switch tube 4, in particular onto the structure material 22. In this case, however, a further conductive layer 14 is expedient, which is applied to an inner surface 8 of the insulating housing 6. The same conditions as those already explained with regard to the layer 14 apply for the layer 16; essentially, the layers 14 and 16 should be similar. However, they can also be different in terms of their material and their conductivity if this is required due to different adhesive conditions and consequently different coating methods. This is expedient when achieving the field-free state or field reduction (to be described in more detail) between the layers 14, 16.
[0018] The interrupter unit is illustrated schematically in a finished state in the partial figure d. In FIG. 1, the boundary region 18 between the structure material 22 of the vacuum switch tube 4 and a volume material 24 of the insulating housing 6 is illustrated by a circle, which is denoted by the reference sign II and whereof an enlarged illustration is shown in FIG. 2. FIG. 2 thus shows this detail, the boundary region 18 between the vacuum switch tube 4 and the insulating housing 6, wherein the structure material 22 (for example aluminum oxide) is shown on the left side of FIG. 2 as an outer border of the vacuum switch tube 4. This structure material 22 has an outer surface 10 to which a conductive layer 16 is applied. The composition of the conductive layer 16 has already been described in the previous paragraph. This is followed by an adhesion layer 12, which is preferably and substantially formed by an organic bonding agent. This is furthermore followed by a further electrically conducting layer 14 which, in terms of its composition, is very similar to the layer 16 or even consists of the same material. The further electrically conductive layer 14 is applied to an inner surface 8 of the insulating housing 6. This inner surface 8 is furthermore followed by the volume material 24 of the insulating housing 6. This material is preferably an epoxy resin.
[0019] According to FIG. 2, bubbles 32 are shown in the adhesion layer 12 between the layers 16 and 14. The formation of these bubbles 32 is unwelcome, but difficult to avoid when applying the insulating housing to the vacuum switch tube 4 or to the structure material 22 of the vacuum switch tube 4. It should be noted here that the sequence of the layers in the boundary region 18 is described along the arrow r, which describes a radial sequence outwards starting from the switch axis 20.
[0020] FIG. 3 likewise shows the electric field as seen along the radial extent of the arrow r from the switch axis 20; it can be seen how the electric field weakens continuously in the vacuum space 28, starting from the switch axis 20. The offset of the field strength in FIG. 3, which is separated by two dashed lines in the region 28 in FIG. 3, merely shows that this refers to a section which implies that this region 28 in FIG. 3 would have a greater extent in an illustration which is true to scale. A real jump in the strength of the electric field occurs upon the presence of the structure material 22; in this case, the field penetrates from the vacuum into the structure material 22, which has a higher permittivity than the vacuum in the vacuum space 28, and the electric field is therefore greatly reduced. In this case, the electric field E also gradually decreases radially outwards.
[0021] The layers 12, 14 and 16 furthermore proceed along the arrow r in the radial direction. It can be seen in FIG. 3 that an electric field is not present in this region. This is followed by the volume material 24 of the insulating housing 6, in which the electric field E furthermore decreases until the air space 30, which likewise has an insulating effect, begins at the outer surface of the insulating housing 6. Cleaned air, but also normal air, i.e. an external atmosphere, but also a mixture similar to air, which comprises nitrogen and carbon dioxide, can be located in this air space 30. This refers to a further insulation stage for the interrupter unit 2, in which the electric field furthermore decreases.
[0022] With regard to the electric field, a jump can in turn be seen between the material 24 of the insulating housing 6 in FIG. 3. This is because the permittivity of the air or the gas which is applied outside the insulating housing 6 is close to 1. The material 24 of the insulating housing 6 generally has a higher permittivity, wherein it would be desirable for the permittivity of the material 24 to decrease along the radius so that the jump, which can be seen here between the transition from 24 to the region 30, is reduced and is as small as possible. To this end, it can be expedient for the volume material 24 of the insulating housing 6 to have different permittivities along the arrow 4. The permittivity of the material in the outer region should essentially be as low as possible, i.e. as close to 1 as possible. The permittivity can be higher in the interior. This can be achieved by a layered construction of the volume material 24 so that two or more layers of different materials with different permittivities can be placed concentrically around one another. However, it is also expedient to configure the material such that a gradient behavior of the permittivity in the direction of the arrow r is realized.
[0023] The electrically conductive layers 14 and 16, which include the adhesion layer 12, are arranged as described in the regions 12, 14 and 16, in which, according to FIG. 3, the electric field is zero or close to zero. As illustrated in FIG. 2, in the adhesion layer 12, bubbles 32 can form in which a partial discharge may occur when an electric field is applied, whereby the material of the adhesion layer or the surrounding material, or the volume material 24 of the insulating housing 6 is eroded and ultimately aged. This aging process can reduce the disruptive strength and therefore also the useful life of the combination of the insulating housing 6 and the interrupter unit 2 and therefore necessitate earlier replacement. As a result of the described layers 14 and 16, the adhesion layer 12 is, however, integrated such that the same potential is applied at its inner and outer side in each case and the electric field therefore drops to zero there and, as a result, a partial discharge also does not take place in the critical region of the adhesion layer 12, in which bubbles 32 can form. The risk of erosion in this transition or boundary region 18 is reduced to virtually zero as a result of the described layers 14 and 16.
[0024] It should be noted here that the adhesion layer 12 is generally a bonding layer, which is suitable for bonding the material 24 of the insulating housing 6 to the structure material 22 of the vacuum switch tube 4. It can essentially also be expedient to apply the layers 14 and 16 directly to one another and to subject them to an appropriate treatment so that an adhesion layer forms between them, or the adhesion layer 12 is formed directly by the layers 14 and 16. This can refer to diffusion processes, for example, or chemical conversion in a further boundary region between these two layers 14 and 16. This measure also contributes to suppressing bubbles 32 and, should they occur, to rendering them harmless in terms of a partial discharge as a result of the integration in materials with the same potential.
LIST OF REFERENCE SIGNS
[0025] 2 Interrupter unit [0026] 4 Vacuum switch tube [0027] 6 Insulating housing [0028] 8 Inner surface of the insulating housing [0029] 10 Outer surface of the vacuum tube [0030] 12 Adhesion layer [0031] 14 Conductive layer of the inner surface [0032] 16 Conductive layer of the outer surface [0033] 18 Boundary region [0034] 20 Switch axis [0035] 22 Structure material [0036] 24 Vacuum material of the insulating housing [0037] 26 Switch contacts [0038] 28 Vacuum space [0039] 30 Air space/gas space [0040] 32 Bubbles
