The invention relates to a gas-insulated switch as specified in the independent gas-insulated switch claim and a high voltage switching arrangement as specified in the independent high voltage switching arrangement claim.
In the area of high and medium voltage switchgears sulfur hexafluoride SF6 is currently used as an insulating gas and an extinguishing gas. This gas is excellently suited for the applications mentioned, but its disadvantage is that it has a very high greenhouse potential. The alternative currently being discussed in this respect consists in various compounds as insulating media, in particular fluorinated compounds. On the other hand it is also convenient to integrate vacuum switching tubes in power switches. However an increase in rated voltage leads to a disproportionate increase in technical expenditure, which is necessary for providing vacuum switching tubes in order to ensure sufficient voltage stability of the switching path after a power failure. In order to reduce this expenditure it might be convenient to provide a circuit breaker designed in particular in the form of a gas-insulated switch, which can be opened under electrical load, i.e. in particular in case of a short-circuit, and which dielectrically discharges the vacuum switching tube.
It is an objective of the invention to provide a circuit breaker in form of a gas-insulated switch, which compared to conventional gas-insulated switches has a higher opening speed of the contacts in case of a short-circuit. Further the objective consists in providing a high voltage switching arrangement with a vacuum switching tube, which compared to the state of the art is able to carry a higher voltage per installation space.
The solution to the objective consists in a gas-insulated switch as specified in the independent gas-insulated switch patent claim and a high voltage switching arrangement as specified in the independent high voltage switching arrangement patent claim.
The gas-insulated switch has a first contact and a second contact each of which are a component of a contact unit. At least one contact unit is connected to the first contact as a movement contact unit having a drive unit. The movement contact unit is movably mounted along a switch axis. Further the gas-insulated switch includes a multi-part insulation nozzle system, which has a primary nozzle and an auxiliary nozzle, wherein a heating channel is formed between the primary nozzle and the auxiliary nozzle, said heating channel originating from an electric arc chamber and opening in a gas reservoir. This gas reservoir is delimited on one side by a ram. The invention is characterized in that the gas reservoir in respect of the switch axis is radially delimited by a wall, as least in part, wherein the movement contact unit, in respect of this wall, is movably mounted along the switch axis and in that the ram is part of the movement contact unit and together with the same is movably mounted in respect of the second contact such that the ram during an opening process of the two contact units for enlarging the gas reservoir moves along the switch axis away from the second contact.
As regards its construction the gas-insulated switch of the invention is similar to a so-called self-blowing switch, but it is different in that the conventional self-blowing switch has a self-blowing volume which is reduced in its volume during opening of the two contact systems by a ram such that an extinguishing gas is pressed back through the heating channel into the electric arc chamber, thereby extinguishing the electric arc. In this conventional self-blowing switch of the state of the art, the wall, which radially delimits the self-blowing volume, is however part of the movement contact system and remains unmoved during opening of the switch in respect of the self-blowing volume/the gas reservoir. In the present invention the wall is movably mounted in respect of the first contact unit and as such is not a component of this first contact unit. In the present invention the gas reservoir enlarging during the opening process moves along the described wall of the reservoir.
It remains to be noted that the insulation nozzle system represents a functionally interacting system in that the individual components, taken on their own, may each be part of the contact units. That means that the components, i.e. the primary nozzle and the auxiliary nozzle, do not have to be rigidly arranged in relation to each other, but can move towards and away from each other during the opening and closing processes.
Due to the movable mounting of the contact of the movement contact unit, normally a tulip contact, and the auxiliary nozzle surrounding it in the switching chamber, the invention makes it possible, in contrast to the self-blowing power switches used nowadays, to enlarge the gas reservoir, which in the present invention does not serve as a self-blowing volume. Rather due to the hot gas flowing in through the heating channel a force is exerted upon the ram, which causes an acceleration of the movement contact system in pulling direction of the drive thereby supporting the drive movement/increasing the drive speed. This makes it possible for the same drive energy to effect an increase in the contact opening speed or for a constant contact opening speed to effect a reduction in drive energy.
In a further embodiment of the invention the wall delimiting the gas reservoir, at least in part, is a component of the contact unit of the second contact. This means that parts of the second contact system, i.e. at least the described wall, preferably radially surround parts of the first contact system and contribute to form a cavity, namely the gas reservoir, which is being enlarged during opening of the switch caused by the flowing-in hot gas. Conveniently said wall is constructively fixed to the second contact system, which is realizable at little expense. In principle it may also be convenient to fix the wall to the housing of the vacuum switching tube.
In a further embodiment of the invention the ram is arranged in the first contact system such that it is designed substantially vertically in respect of a switch axis. In essence this means that an angular position relative to the switch axis is no more than 15°.
With this arrangement the ram is rotation-symmetrically designed in respect of the switch axis. This leads to a rotation-symmetric, substantially cylinder-wall-shaped gas reservoir around the switching contact. In an advantageous embodiment the ram is attached to a mounting of the auxiliary nozzle and firmly fixed to the movement contact system.
With a gas-insulated switch constructed according to the self-blowing principle the two contacts have different shapes, one contact is a tulip contact, which is preferably the first contact, and the other is a pin contact which is preferably designed as a second contact. The pin contact is preferably part of a fixed contact unit. The tulip contact is preferably part of the movement contact unit, wherein in principle both contact units may also be movably designed via an appropriate coupled drive.
In a further embodiment of the invention the described wall of the gas reservoir is part of the primary nozzle. This would facilitate a low-cost constructional conversion.
A further embodiment of the invention is a high voltage switching arrangement which encompasses a gas-insulated switch as well as a vacuum switching tube. The gas-insulated switch and the vacuum switching tube, which again may be a component of a power switch, are connected in series. Due to the fact that the described gas-insulated switch can be switched under load, the series-connected vacuum switching tube will function at a lower electrical strength in respect of the rated voltage. This requires less technical expenditure during construction of the vacuum switching tube, and it is possible in principle to achieve higher rated voltages by using a specified type of construction.
It may be convenient for the gas-insulated switch and the vacuum switching tube/a power switch in which the vacuum switching tube is integrated to be operated by a joint drive. This facilitates a simple technical construction and, on the other hand, a secure time sequence of the switching processes.
In a further embodiment of the invention the high voltage switching arrangement is configured such that the voltage division across the gas-insulated switch and the vacuum switching tube is controlled by a control device. A control device may for example be a capacitor or a resistance or a coupling of a capacitor and a resistance.
Further embodiments and further characteristics of the invention will be described in more detail by way of the drawings below. Characteristics in different designs but with identical labelling are provided with the same reference symbols. In principle these are schematic embodiments which are of a purely exemplary nature and do not represent a restriction of the scope of protection.
Further the gas-insulated switch 2 has an insulation nozzle system 12, which in particular comprises a primary nozzle 14 and an auxiliary nozzle 16 as well as a heating channel 18 formed thereby. The heating channel 18 extends from an electric arc chamber 20 to a gas reservoir 22. The electric arc chamber 20 is the chamber, which forms during opening of the contacts 30, 32 and in which a switching arc 21 occurs during the opening process.
Here the gas reservoir 22 is delimited, on the one hand, by the auxiliary nozzle 16 on a radial inside in this embodiment and radially by a wall 26 from the switch axis 10 towards the outside. These two delimitations by the auxiliary nozzle 16 and the wall 26 extend radially circumferentially, but parallel to the switch axis 10. Furthermore a ram 24 is provided, which axially delimits the gas reservoir 22. This means that the ram 24 extends substantially vertically, but rotation-symmetrically to the switch axis 10 and is movably mounted at least in respect of the wall 26. This means that the ram 24 is a fixed component of the movement contact unit 8, whereas the wall 26 is not part of this movement contact unit 8. In a preferred embodiment depicted in
During an opening movement of the switch 2 the tulip contact 30 and the pin contact 32, driven by a drive device 11, move along the switch axis 10 away from each other. During opening of the contacts 30, 32 a switching arc 21 is created. Due to the switching arc 21 the insulating medium, substantially in gas form, present in the electric arc chamber is heated and pressed via the heating channel 18 into the gas reservoir 22. The movement of the gas along the heating channel 18 occurs, in particular, due to the rise in temperature and the resulting volume expansion. This volume expansion in turn leads to the insulating medium 23 being pressed against the ram 24 at such a high energy that the translational movement of the first contact unit 8, which essentially comprises the tulip contact 30, the auxiliary nozzle 16 and the ram 24, takes place so quickly that the speed of the movement caused by the drive is exceeded. This is therefore an additional acceleration of the movement contact unit 8 away from the fixed contact 32. As a result the gas reservoir 22 is enlarged and the ram 24 moves in direction of the arrow 25.
Thus, with the described opening mechanism of switch 2, the energy of the electric arc 21 is utilized in order to speed up the opening of the switch 2 and thereby also increase the separating distance between the two contacts 30, 32. In this way the electric arc 21 is also extinguished. This may be relevant in particular then, when the switch 2 is connected in series with a vacuum switching tube 48, as depicted in
With the arrangement described in
In
In
Number | Date | Country | Kind |
---|---|---|---|
102018211621.0 | Jul 2018 | DE | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2019/068211 | 7/8/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2020/011695 | 1/16/2020 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4434332 | Yanabu | Feb 1984 | A |
4445020 | Ueda et al. | Apr 1984 | A |
4458119 | Hashimoto | Jul 1984 | A |
4486632 | Niemeyer et al. | Dec 1984 | A |
5739495 | Marin | Apr 1998 | A |
5898149 | Berger et al. | Apr 1999 | A |
6207917 | Lehmann | Mar 2001 | B1 |
6624371 | Dufournet | Sep 2003 | B2 |
6744000 | Bergmann | Jun 2004 | B1 |
9029726 | Cernat | May 2015 | B2 |
9240680 | Hartmann et al. | Jan 2016 | B2 |
Number | Date | Country |
---|---|---|
607658 | Sep 1978 | CH |
102011005905 | Sep 2012 | DE |
0067460 | Dec 1982 | EP |
0741399 | Nov 1996 | EP |
0766278 | Apr 1997 | EP |
1079404 | Feb 2001 | EP |
1548780 | Jun 2005 | EP |
20150000664 | Jan 2015 | KR |
Entry |
---|
Translation of EP1079404 (Original doc. published Feb. 28, 2001) (Year: 2001). |
Translation of KR20150000664 (Original document published Jan. 5, 2015) (Year: 2015). |
Number | Date | Country | |
---|---|---|---|
20210319966 A1 | Oct 2021 | US |