The invention relates to an electrical switching device having a first switching point, which is arranged within an evacuated area, and having a second switching point, which is arranged outside the evacuated area, and to a method for operation of an electrical switching device such as this.
An electrical switching device of the type mentioned above is known, for example, from U.S. Pat. No. 4,538,039. In the known arrangement, a first switching point of the electrical switching device is arranged in an evacuated area. A second switching point of the electrical switching device is arranged outside the evacuated area. The switching points are in the form of so-called vacuum interrupters and compressed-gas-isolated switching points. The two switching points are arranged alongside one another, and are formed independently of one another. This results in an arrangement which requires a comparatively large amount of space.
One object of the invention is therefore to specify an electrical switching device of the type mentioned initially which occupies less space.
The object is achieved in the case of an electrical switching device of the type mentioned initially, according to the invention, in that the first switching point is surrounded by the second switching point.
By avoiding the use of conventional switching points and the physical linking of the first switching point and the second switching point, it is possible to form a compact electrical switching device.
A dielectrically advantageous design for an electrical switching device can also be produced by surrounding the first switching point by the second switching point.
Furthermore, the second switching point may surround the first switching point in such manner that the first switching point is protected against external mechanical influences. There is no need for additional barriers for protection of the evacuated area.
A further object of the invention is to specify a suitable method for operation of switching device according to the invention.
An advantageous method for operation of an electrical switching device having a first switching point, which is arranged within an evacuated area, and having a second switching point, which is arranged outside the evacuated area, in which during a connection process, the first switching point is connected at a time before the second switching point and, during a disconnection process, the first switching point is disconnected at a time after the second switching point, has the advantage that any switching arcs which may occur preferably occur adjacent to the first switching point. The second switching point is protected against increased contact erosion by the first switching point. Appropriate encapsulation can be provided in order to bound the evacuated area. This encapsulation is designed to maintain the vacuum in an appropriately gas-tight form. If switching arcs, for example pre-arcing during connection processes or disconnection arcs, are deliberately kept within the encapsulation, then it is virtually impossible for the arc to emerge from encapsulation. Components arranged adjacent, such as the second switching point, drive apparatuses or other components, are thus well protected against the thermal effects of the arcs. By way of example, this makes it possible to use open switching contacts for the second switching point since the encapsulation prevents the arc from jumping over to the contacts of the second switching point.
In one advantageous refinement, it is also possible for the first switching point and the second switching point to be connected electrically in parallel with one another.
Connection of the two switching points electrically in parallel makes it possible to deliberately initiate commutation of a current to be disconnected onto one of the two switching points. For this purpose, during a disconnection process, it is advantageously possible for the current to be disconnected to be deliberately quenched adjacent to the first switching point. This can be done, for example, by a time offset between the switching times of the two switching points.
A further advantageous refinement makes it possible for the first switching point to have a first and a second switching piece which can move relative to one another and are arranged axially opposite one another, and for the second switching point to have a first and a second switching piece, which can move relative to one another, are rotationally symmetrical and are arranged co-axially with respect to the switching pieces of the first switching point.
The axially opposite switching pieces are moved relative to one another in the axial direction. If the switching pieces of the first and of the second switching point are arranged co-axially in a rotationally symmetrical form, this results in a body with dielectrically advantageous design. Particularly when the electrical switching device is used in the medium-voltage and high-voltage field, it is therefore possible to also cope with increased electrical field strengths. The two switching points should in each case advantageously be cylindrical, and are arranged interleaved in one another.
A further advantageous refinement makes it possible, in one projection, for an interrupter path of the disconnected second switching point to be covered by encapsulation which bounds the evacuated area.
Switching pieces which can move relative to one another are used, and when the respective switching contact is in the disconnected state, an interrupter path is created between the switching pieces involved and is used for potential isolation between the switching pieces. The encapsulation which bounds the evacuated area must be formed at least in places from an electrically insulating material in order to allow the switching pieces of the first switching point to be kept isolated from one another. This avoids shunt paths which could have a negative influence on the switching capability of the switching points. In one projection, for example radially with respect to the axis on which the switching pieces of the first switching point are arranged, and with respect to which, for example, the switching pieces of the second switching point are also arranged co-axially, the encapsulation may cover the isolation point of the second switching point. This makes it possible to inspect the encapsulation through the open second switching point. With a rotationally symmetrical design, this can be done from a large number of positions, thus allowing quick inspection.
Furthermore, it is advantageously possible for the electrical switching device to have an essentially rotationally symmetrical housing with a first housing section and a second housing section which are arranged at a distance from one another, leaving a gap free.
Use to of rotationally symmetrical housing sections assists the dielectric strength of the electrical switching device. The electrical insulation makes it possible to apply different electrical potentials to the two housing sections, as well, without producing short circuits or the like.
It is also advantageous for the gap to be covered by at least one electrically insulated holding element, which connects the first and the second housing section.
Electrically insulated holding elements can be used in order to connect the two housing sections such that the angle between them is stiff.
By way of example, the holding element may be in the form of a plate. A plurality of these holding elements may be arranged distributed on the circumference of the two housing sections. However, it is also possible to manufacture the holding element, for example, from an insulating tube and for this tube to be connected to the housing sections over its entire circumference. This results in a stiff joint between the individual housing sections. If the use of holding elements in the form of plates is preferred, then the encapsulation of the evacuated area can also be inspected through the intermediate spaces between the individual holding elements. In order to ensure this when using a tubular holding element as well, this holding element may, for example, be manufactured from a material through which light can pass.
A further advantageous refinement provides for the gap to an annular gap.
The annular shape avoids sharp edges. The housing sections are formed in a dielectrically advantageous manner. Furthermore, the gap can be used in order, for example, to hold a switching piece of a switching point.
A further advantageous refinement makes it possible for the gap to be electrically bridged by means of a movable switching piece of the second switching point.
The use of the gap as an interrupter path for an electrical switching point makes it possible to make better use of the available physical space adjacent to the electrical switching device.
One advantageous refinement also makes it possible for the evacuated area to be surrounded by an electrically insulating fluid.
By way of example, an electrically insulating fluid may be an electrically negative gas, such as sulfur hexafluoride, nitrogen or mixtures of such gases. However, it is also possible to use a suitable insulating oil to surround the evacuated area. In one simple case, the electric insulating fluid may, for example, be atmospheric air. The use of fluids to which an increased pressure is applied makes it possible to design the electrical switching device to be compact. This makes it possible to reduce the gap or else the separations between the individual switching points, since the breakdown strength is increased by compression of the electrically insulating fluid.
Furthermore, it is advantageously possible for the housing sections to be part of a current path which can be interrupted by means of the electrical switching device.
A suitable electrically insulating holder allows the housing sections to be part of a current path which can be switched by the switching device. The housing sections have an appropriate wall thickness in order to ensure adequate mechanical strength. Use of suitable electrically conductive materials, such as aluminum or copper, allows an electric current to be carried with low losses via the housing sections as well.
A further advantageous refinement makes it possible for the annular gap to surround the evacuated area.
By arrangement of the annular gap in the region of the evacuated area results in the electrical switching device having a shell-like structure. This results in a switching device which is shorter in axial direction and in which there is no offset between the individual switching points.
A further refinement makes it possible for at least one of the housing sections to surround a transmission device which drives the movable switching pieces of the switching points.
By way of example, a transmission device may be used to distribute a drive movement between the movable switching pieces and to force there to be a time offset between the movements of the switching pieces of the two switching points. The arrangement within at least one housing section allows the transmission device to be protected by the housing sections themselves against mechanical forces acting on them. Furthermore, the housing sections can hold the transmission device within an area in which there is no field. This prevents the formation of parallel current paths on the transmission device as a result of which, for example, smaller discharges could also occur.
The invention will be described in more detail in the following text and illustrated schematically in a drawing on the basis of one exemplary embodiment.
In the figures:
The design of an electrical switching device according to the invention will be described in the following text with reference to
The first switching point 2 has a rotationally symmetrical design and is arranged co-axially with respect to a first axis 4,along this axis 4. The second switching point 3 surrounds the first switching point 2. The second switching point 3 is rotationally symmetrical and is arranged co-axially with respect to the first axis 4. The second switching point 3 has a first switching piece 5 and a second switching piece 6. The second switching piece 6 can be moved by means of a drive along the first axis 4. The first switching piece 5 of the second switching point 3 is mounted in a fixed position. The switching pieces 5, 6 of the second switching point 3 are hollow-cylindrical and are each arranged co-axially with respect to the first axis 4. On the inside, the first switching piece 5 has a multiplicity of moving contact elements. The second switching piece 6 can be moved with an outer casing area into these moving contact elements so that electrical contact can be made between the first switching piece 5 and the second switching piece 6 of the second switching point 3.
The first switching piece 5 is mounted on a first housing section 7. The second switching piece 6 is mounted on a second housing section 8. The housing sections 7, 8 are each essentially rotationally symmetrical and are arranged co-axially with respect to the first axis 4. An annular gap 9 is formed between the axially opposite ends of the two housing sections 7, 8. The annular gap 9 is used as interrupter path for the second switching point 3. For robustness, the two housing sections 7, 8 are connected to one another by means of a plurality of electrically insulating holding elements 10, 11. The holding elements 10, 11 are arranged distributed uniformly around the circumference of the two housing sections 7, 8. In a projection at right angles to the first axis 4, the annular gap 9 when the second switching point 3 is in the open state is covered by encapsulation 23 which bounds the evacuated area of the first switching point 2. The zones which are left free between the individual holding elements 10, 11 make it possible to look in through the outer wall of the encapsulation 23 at the first switching point 2. The two switching points 2, 3 are connected electrically in parallel with one another.
A transmission device 12 is arranged within the second housing section 8. The transmission device 12 has a drive lever 13 for transmitting a drive movement, via which a connection or disconnection movement is initiated. On the output drive side, output drive levers are provided for the movable switching pieces 6, 21 of the first and second switching points 2, 3. In this case, the transmission device 12 is designed to produce a time offset between the start and the end of the movement of the movable switching pieces 6, 21. For example, during a connection process, it is possible for the moveable switching piece 21 of the first switching point 2 to be moved first of all, followed by the moveable second switching piece 6 of the second switching point 3. A corresponding situation can be provided for a disconnection process, with the movable second switching piece 6 of the second switching point 3 being moved first of all, and with the movable switching piece 21 of the first switching point 2 being moved at a later time.
Connecting pieces 14, 15 are arranged at the mutually remote ends of the rotationally symmetrical housing sections 7, 8 and are used for connection of an electrical supply line. Via the connecting pieces 14, 15, the housing sections 7, 8 can be used as part of a current path to be switched within an electrical power transmission system. The first switching piece 5 of the second switching point 3 is electrically conductively connected to the first housing section 7 via a rigid joint. The second switching piece 6 of the second switching point 3 is electrically conductively connected to the second housing section 8 via a corresponding sliding contact arrangement. The second switching piece 6 of the second switching point 3 can be moved telescopically with respect to this within a cylindrical section of the second housing section 8. By way of example, sprung contact fingers, helical springs or the like can be arranged as contact elements in the boundary layer between the second switching piece 6 of the second switching point 3 and the cylindrical section of the second housing section 8.
Supporting insulators 16, 17, 18, 19 in the form of pillars are used to hold the electrical switching device 1 such that it is isolated. The electrical switching device 1 may be surrounded by an electrically insulating fluid, for example an insulating liquid or an insulating gas. By way of example, this may also be done at a pressure that is higher than that of the rest of the surrounding area. The insulating medium can also flow into the interior of the electrical switching device through appropriate openings, and can surround the first switching point 2 there.
The design of the first switching point 2 will be explained in more detail in the following text with reference to the section illustrated in
The switching pieces 20, 21 of the first switching point 2 are surrounded by encapsulation 23. In its interior, the encapsulation 23 has an evacuated area. This evacuated area is also referred to as a vacuum. The encapsulation 23 has a first and a second tubular insulating piece 24, 25, with the tubular insulating pieces 24, 25 being arranged co-axially with respect to the first axis 4. The tubular insulating pieces 23, 24 are connected to one another by means of a metallic central body 26 at their mutually facing ends. The interrupter path of the first switching point 2 is arranged in the region of the central body 26. In order to hold erosion products, an electrode 27 is arranged in the interior of the encapsulation 23 in the region of the central body 26. The switching pieces 20, 21 of the first switching point 2 are passed through a wall section, in a gas-tight form, at the mutually remote ends of the tubular insulating pieces 24, 25. The encapsulation 23 may be surrounded by a mechanical-shock-absorbent casing as protection against mechanical shock.
Number | Date | Country | Kind |
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DE102005032709.5 | Jul 2005 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2006/063844 | 7/4/2006 | WO | 00 | 1/15/2008 |