DE102017206290A1 - Gas-insulated electrical device with carbon-containing insulating gas component - Google Patents

Abstract

A gas-insulated electrical device (2, 32) is indicated. The device (2, 32) comprises a dielectric insulating gas (6) with a carbon-containing first insulating gas component and an oxidizing agent (23, 23a, 23b, 23c, 23d) which is in condensed phase and whose surface is at least partially in contact with the insulating gas ( 6) stands.

Description

The present invention relates to a gas-insulated electrical device comprising a dielectric insulating gas comprising at least one carbon-containing first insulating gas component.

In the prior art, conventional gas-insulated electrical devices are typically operated with sulfur hexafluoride (SF ₆ ) as a significant dielectric active component of the insulating gas, since SF _{6 has} a particularly good insulating effect and above all a high dielectric strength. For this reason, many gas-insulated electric devices, such as gas-insulated switching devices, gas-insulated conductors and gas-insulated transformers are operated with SF ₆ as an insulating gas. The insulating gas serves to insulate at least one active electrical component mounted within the electrical device. In particular, in switching devices, it also serves to delete a resulting during the switching operation switching arc.

Since SF _{6 is} a highly effective greenhouse gas and contributes significantly to global warming even in comparatively low concentrations, the search for alternatives to this substance has been increasing in recent years. Thus, various other fluorinated compounds have been proposed as a major component or additive component in gas-isolated devices and have been successfully tested in part. These fluorinated compounds may be, for example, fluoroketones, as in EP 2652752A1 and EP 2652753A1 is described. However, other fluorinated compounds have also been described as substitutes for SF6, for example, tetrafluoromethane, trifluoroiodomethane and other fluorinated and partially functionalized hydrocarbons. These substitutes are therefore often carbon-containing dielectric insulating gas components, which may preferably be at least partially fluorinated.

Such a carbonaceous first insulating gas component can in principle be used either in pure form or in combination with an optional further insulating gas component. The carbon-containing insulating gas component does not have to be the main component. It can also be used in a lower concentration together with an excess of carrier gas.

A fundamental problem of the carbon-containing insulating gas components is that during operation of the gas-insulated device, for example due to switching operations, partial discharges and / or elevated temperature, at least partial decomposition of the insulating gas can occur. Contains at least one of the dielectric insulating gas components carbon, then unwanted carbonaceous decomposition products can arise, which can be reflected especially in the form of solids within the device. In particular, such a solid may be dusts, for example soot or soot-like dusts. These decomposition products of the carbonaceous insulating gas component can be very toxic and / or corrosive, which can lead to risks for the personnel and / or the device. Particles in gas-insulated devices can also lead to undesirable breakdowns.

A disadvantage of the known gas-insulated devices according to the prior art is therefore that it can come through the carbon-containing substitutes for SF ₆ to form undesirable carbonaceous solids within the device.

The object of the invention is therefore to provide a gas-insulated electrical device with a carbon-containing first insulating gas component, which overcomes the disadvantages mentioned. In particular, such a device is to be made available in which the formation of soot or the formation of soot-like or soot-containing dusts is avoided.

This object is achieved by the gas-insulated electrical device described in claim 1.

The gas-insulated electrical device according to the invention comprises a dielectric insulating gas with at least one carbon-containing first insulating gas component and further comprises an oxidizing agent which is in condensed phase and whose surface is at least partially in contact with the insulating gas.

In other words, the oxidant should be present in solid or liquid form and not in the gaseous form. However, it should be arranged within the device so that it can come into contact with the insulating gas on its surface and react chemically with it. In particular, the condensed oxidant can lead to oxidation of the insulating gas and thus avoid or at least reduce soot formation within the device.

A significant advantage of the embodiment according to the invention with a solid or liquid oxidizing agent is that an admixture of an oxidizing agent to the insulating gas is not required in order to reduce soot formation. Thus, the insulating gas composition may be selected to have good dielectric properties and / or Resistance to breakdown can be achieved without having to add a gaseous oxidizing agent for reasons of soot avoidance, which could possibly adversely affect other properties of the insulating gas. In particular, gaseous oxidants such as O ₂ and / or CO _{2 can} largely be dispensed with, or such a fraction can be kept small in the insulating gas, at least advantageously. As a result, in particular the formation of poisonous CO (carbon monoxide) within the device can be avoided or at least reduced. CO arises in particular as a by-product in the case of oxidation by means of CO ₂ , so that oxidation by means of gaseous CO _{2 as} a whole is rather disadvantageous. The addition of significant amounts of oxygen (O ₂ ) in the insulating gas should be avoided as much as possible, since the oxygen also significantly increases the corrosion of the components of the device (for example of metals, metallic alloys and / or elastomers). The risk of the formation of combustible gas mixtures of the alternative insulating gases and / or their decomposition products with the oxygen increases with the oxygen concentration. At high oxygen concentrations, there is even the danger of the formation of an explosive gas mixture, which could be ignited, for example, by a switching spark or a switching arc. All of these disadvantages can be advantageously avoided by the use according to the invention of a solid and / or liquid oxidizing agent.

Advantageous embodiments and further developments of the invention will become apparent from the dependent claims of claim 1 and the following description.

Thus, the oxidizing agent may preferably have a standard potential E ⁰ of at least 0V, where E ^{0 is to be} considered as the reference value 0 relative to the normal hydrogen electrode. Such a strong oxidant is particularly suitable for reducing the formation of soot within the device through its interaction with the insulating gas.

Particularly preferably, the oxidizing agent even has a standard potential E ⁰ of at least 0.3 V and in particular even of at least 0.5 V. Even more preferably, the standard potential E ^{0 can} even be at least 0.7 V, in particular at least 1 V or even at least 1.3 V. In these areas of the stronger oxidizers, soot formation can be more effectively prevented without the need for a strong oxidant within the gas phase.

The oxidizing agent may generally be preferably an inorganic oxidizing agent. This implies the advantage that soot formation from decomposition products of the oxidizing agent can be largely avoided. In particular, the oxidizing agent may advantageously itself be free of carbon.

• - Diiodpentoxid I₂O₅,
• - Kaliumpermanganat KMnO₄ oder einem anderen Permanganat
• - Kaliumdichromat K₂Cr₂O₇ oder einem anderen Dichromat,
• - Calciumiodat Ca(IO₃)₂ oder einem anderen Iodat,
• - Kaliumnitrat KNO₃, Ammoniumcer(IV)-nitrat (NH₄)₂[Ce(NO₃)₆] oder einem anderen Nitrat,
• - Ammoniumpersulfat (NH₄)₂S₂O₈ oder einem anderen Persulfat
• - Kaliumhexacyanoferrat(III) K₃[Fe(CN)₆] oder einem anderen Hexacyanoferrat(III)
• - PbO₂,
• - einem Cu²⁺-haltigen Salz,
• - einem Ag⁺-haltigen Salz,
• - einem Ce(IV) haltigen Salz.

The oxidizing agent may generally be more preferably selected from the group consisting of:

• Diiodopentoxide I ₂ O ₅ ,
• - potassium permanganate KMnO ₄ or another permanganate
• Potassium dichromate K ₂ Cr ₂ O ₇ or another dichromate,
• Calcium iodate Ca (IO ₃ ) ₂ or another iodate,
• Potassium nitrate KNO ₃ , ammonium cerium (IV) nitrate (NH ₄ ) ₂ [Ce (NO ₃ ) ₆ ] or another nitrate,
• Ammonium persulfate (NH ₄ ) ₂ S ₂ O ₈ or another persulfate
• Potassium hexacyanoferrate (III) K ₃ [Fe (CN) ₆ ] or another hexacyanoferrate (III)
• - PbO ₂ ,
• a Cu ²⁺ -containing salt,
• an Ag ⁺ -containing salt,
• - a Ce (IV) containing salt.

These compounds mentioned are particularly suitable to avoid soot formation by this insulating gas by oxidative interaction with a carbon-containing insulating gas or at least curb.

Alternatively, however, it may in principle also be an organic oxidizing agent. In particular, in the case of a solid organic oxidizing agent, it can be converted in its oxidative interaction with the insulating gas at its previous location into another solid which remains there and does not penetrate into the remaining regions of the device.

For example, an organic oxidizing agent may advantageously be either tris (4-bromophenyl) ammoniumyl hexachloroanti-month or tetracyanoquinodimethane. Alternatively, the organic oxidizing agent may also be 2,3,5,6-tetrafluoro-7,7,8,8-quinodimethane (F4-TCNQ) or dipyrazino [2,3-f: 2 ', 3'-h] quinoxaline-2 , 3,6,7,10,11-hexacarbonitrile (HAT-CN). In general, the organic compound may advantageously be a fluorinated organic compound, an organic compound having one or more cyano groups, an organic compound having a quinoidal structure, and / or generally a Lewis acid organic compound. It should be noted that in connection with the present Invention under organic compound also coordination compounds with organic ligands and oxidizing agents in addition to the classical oxidizing agents (which act by complete absorption of at least one electron) are also generally lewisazide compounds to be understood, which also by (at least partially) receiving an electron or by receiving an electron pair or by forming a Lewis acid-base pair, the reduction of another substance and thus the formation of soot from the insulating gas can prevent. Such a Lewis acidic organic compound may be, for example, copper perfluorobenzoate [Cu (pbb)] 4 or bismuth perfluorobenzoate [Bi (pbb) 3].

Advantageously, the oxidizing agent (whether it is an inorganic and / or an organic oxidizing agent) is a non-toxic oxidizing agent. More specifically, according to the CLP Regulation, it is preferably not classified as "acute toxic" (GHS06) or hazardous to health "(GHS08). Thus it can be avoided that there is an additional danger from the oxidizing agent.

• - Kaliumpermanganat KMnO₄,
• - Calciumiodat Ca(IO₃)₂,
• - Kaliumnitrat KNO₃,
• - Ammoniumcer(IV)-nitrat (NH₄)₂[Ce(NO₃)₆],
• - Ammoniumpersulfat (NH₄)₂S₂O₈
• - Kaliumhexacyanoferrat(III) K₃[Fe(CN)₆]
• - PbO₂,
• - einem Cu²⁺-haltigen Salz,
• - einem Ag⁺-haltigen Salz.

From the above list of inorganic oxidizing agents, in particular the following substances are to be regarded as advantageous from the aspect of avoiding an additional hazard:

• Potassium permanganate KMnO ₄ ,
• Calcium iodate Ca (IO ₃ ) ₂ ,
• Potassium nitrate KNO ₃ ,
• Ammonium cerium (IV) nitrate (NH ₄ ) ₂ [Ce (NO ₃ ) ₆ ],
• - ammonium persulfate (NH ₄ ) ₂ S ₂ O ₈
• Potassium hexacyanoferrate (III) K ₃ [Fe (CN) ₆ ]
• - PbO ₂ ,
• a Cu ²⁺ -containing salt,
• - an Ag ⁺ -containing salt.

The amount of substance of the oxidant is advantageously chosen so large that at the given pressure and the given temperature of the insulating gas at least equal to the amount of substance of a hypothetical 0.25prozentigen oxygen addition to the insulating gas. Since an oxygen molecule can absorb four electrons in a redox reaction, that is, has a redox equivalent of 4, this corresponds to a hypothetical 1 percent concentration of a 1-electron acceptor in the insulating gas. In other words, at least so much oxidant should be present that the number of electrons to be absorbed by the oxidant corresponds to a 0.25 percent oxygen addition. From an oxidizing agent which only absorbs one electron (eg ammonium cyanogen nitrate by reduction of Ce ⁴⁺ to Ce ³⁺ or Ag ⁺ containing salts by reduction of Ag ⁺ to Ag (0) or potassium hexacyanoferrate (III) by reduction of Fe ³⁺ to Fe ²⁺ ) should therefore be used advantageously at least four times the amount of substance of a hypothetical 0.25prozentigen oxygen addition. By contrast, it is possible, for example, to use at least the equimolar amount of a hypothetical 0.25% oxygen admixture of an oxidizing agent which can take up four electrons. The preferred amounts of oxidizing agents that can accommodate three (potassium permanganate by reduction of Mn ⁷⁺ to Mn ⁴⁺ ), six (calcium iodate by reduction of I ⁵⁺ to I ^- ), or generally x electrons should thus be at least one hypothetical 1/3 , 1/6 or 1 / x percent oxygen addition to the insulating gas.

Particularly advantageously, the amount of substance of the oxidizing agent is even chosen so large that the number of electrons to be absorbed by the oxidizing agent corresponds to a 0.5 percent oxygen addition. It should be emphasized here that the insulating gas should not necessarily actually contain oxygen and that it is even more preferable if it does not. It should only be indicated here, which molar fraction of the insulating gas can potentially be oxidized by the oxidizing agent - in other words, what proportion of oxygen can be replaced by the condensed oxidant present.

Preferably, the surface of the oxidizing agent in contact with the insulating gas is at least 10 cm ^{2 in} total. This statement refers to the effective surface in contact with the gas space, which may be increased in size as compared to a smooth surface, for example by pores and / or channels or other structures. Such a surface enlarging structure may be advantageous in the context of this invention to improve the chemical interaction between oxidant and insulating gas. If several separate amounts of oxidizing agent are present, the specified minimum value should be understood as the sum of the surfaces of the individual portions.

Advantageously, the insulating gas has an oxygen content of at most 5%, preferably even only at most 1% and particularly preferably substantially 0%. The advantage of such a low oxygen content is that corrosion of the components of the device in contact with the insulating gas space can be avoided or at least reduced. Furthermore, the formation of combustible and / or explosive mixtures can be avoided by the described limitation of the oxygen content.

The gas-insulated electrical device may have an insulating space with at least one electrical component disposed therein. This insulating space can advantageously be closed by a housing against the external environment substantially gas-tight. With such a structure, the at least one electrical component can be effectively electrically isolated by the insulating gas and / or protected against voltage flashovers. Due to the gas-tight design, escape of insulating gas as well as penetration of other substances can be largely prevented.

The oxidizing agent may conveniently be present within the insulating space and / or be atmospherically connected to the insulating space. In other words, the oxidizing agent is arranged so that it can come into contact with the insulating gas and thus prevent formation of soot (or precursors of soot) from the insulating gas by oxidation.

Most preferably, the oxidizing agent is generally present as a solid. This facilitates the handling of the device and the confinement of the oxidizing agent to a predetermined and designated area (or more areas) of the device.

The oxidizing agent may generally be advantageously present as a constituent of a powder. It may be the main ingredient or even the sole constituent of such a powder. Alternatively, it may also be present in a mixture with another substance, for example a carrier substance, in such a powder.

The oxidizing agent may also be present as part of a compact. Again, it may be present as a sole ingredient, as a main ingredient or as a minor ingredient. The formation of a compact can be advantageous in order to avoid too fine a distribution of the solid oxidizing agent in the insulating space of the device. Such a compact may be arranged, for example, in the region of a wall and / or a side chamber of the insulating space. Within the device may also be a plurality of such compacts, especially if the spatial extent of the device is large. This is the case, for example, with a gas-insulated pipe. When multiple such compacts or other solid oxidant reservoirs are distributed along the length of the device, soot formation can be prevented or at least mitigated over the entire dimension of the device.

Alternatively, the oxidizing agent may also be present as part of a tablet or granules. Again, these are simple solid shapes that can be securely held to a separate area of the device.

Alternatively, the oxidizing agent may also be present as part of a coating. For example, it may be a coating on a wall of the insulating space. Such an embodiment has the advantage that there is no freely mobile solid in the interior of the device.

Regardless of the exact form of the oxidizing agent - that is, for example, as a powder, as a bead, as a compact or as a coating - the oxidizing agent may be present in an area separated from the insulating space. Such a separated area should be separated so far that the oxidant can not distribute unhindered in the insulating space. However, it should be atmospherically connected to the gas space to allow oxidation of gaseous components or decomposition products of the gas. In order to achieve both, the separated region can be defined, for example, by a gas- and / or liquid-permeable bag, by a separating grid and / or a separating net. Alternatively, the separated region can for example also be defined by a cartridge which can be screwed onto the main part of the gas space, wherein such a cartridge can in particular also be coupled to the main part of the gas space via an automatically gas-tight sealable connection. Such closable connections are offered for example by the company DILO under the name DN20 for the connection types M48 and M45. In general, the separated region can advantageously be separated in a gas-tight manner from the main part of the gas space.

As an alternative to the embodiment as a solid, the oxidizing agent can generally also be present as a liquid and be present, for example, in a container provided for this purpose. This may be, for example, a trough, a gutter and / or a package of a gas-permeable, but liquid-tight membrane. The liquid may be, for example, a liquid substance, a liquid mixture or a solution of a solid in a liquid solvent. The solvent used may preferably be a fluorinated solvent.

The first insulating gas component may advantageously be tetrafluoromethane (CF ₄ ) or trifluoroiodomethane (CF ₃ I) or an at least partially fluorinated ketone or an at least partially fluorinated nitrile or an at least partially fluorinated hydrocarbon or an at least partially fluorinated ether or thioether. Of the above substitutes for SF ₆ , fluoroketones and fluoronitriles have proven particularly promising. they seem Therefore, in the context of the present invention as particularly preferred. Further preferred classes of substances are hydrofluoroolefins or perfluoroolefins, ie unsaturated hydrocarbons.

More generally, the first insulating gas component may be an at least partially fluorinated carbon compound. The at least partial fluorination of such a compound has the advantage that the dielectric properties are generally improved compared to the analogous non-fluorinated material.

Particularly advantageously, the first insulating gas component may be a fluoroketone having between 3 and 12 carbon atoms, in particular between 4 and 6 carbon atoms. In general, these may be straight-chain or branched, saturated or unsaturated, partially or completely fluorinated ketones. Fluoroketones in said chain length range are particularly preferred because they have a boiling point range which is particularly suitable for operation in a gas-insulated device. C5 and C6 fluoroketones, ie compounds with 5 or 6 carbon atoms, are particularly preferred from this group. In particular, the C5 fluoroketone, which is available from 3M under the name Novec5110, proves to be a promising insulating gas component. Another particularly promising alternative is the C4 fluoronitrile, which is available from 3M under the name Novec4710.

The dielectric insulating gas may advantageously comprise at least one second insulating gas component. In this case, the first, carbon-containing insulating gas component can basically be present either as a main or as a minor constituent. Which embodiment is more favorable depends on the dielectric properties of the two or more gas components as well as their boiling points and their global warming potential.

The second insulating gas component may in particular be selected from the group consisting of nitrogen (N ₂ ), carbon dioxide (CO ₂ ), oxygen (O ₂ ), nitrogen dioxide (NO ₂ ), nitrogen monoxide (NO), nitrous oxide (N ₂ O), helium, Neon, argon, krypton and xenon. Alternatively or additionally, however, the second or further insulating gas component can also be a further fluorinated compound, analogously as described in connection with the first insulating gas component. In general, more than two such insulating gas components can be present. For example, a mixture of nitrogen and oxygen known as "clean air" may also be present in admixture with one or more fluorinated compounds. However, it is particularly preferred if, as already described above, oxygen is present at most in one of the maximum proportions of volume specified therein.

For example, if a fluoroketone or other fluorinated SF ₆ replacer is in admixture with a non-fluorinated gas, then the molar concentration of the fluorinated insulating gas component (s) may advantageously be between 1% and 40%, more preferably between 2% and 20% of the total dielectric Insulating gas amount. Percentages should be understood as volume percentages.

The electrical device may comprise, in addition to the constituents mentioned, another solid for the adsorption of water. This may in particular be a zeolite and / or a silica gel. Such a moisture adsorber can largely prevent the formation of HF within the device.

Alternatively or additionally, the electrical device may further comprise a calcium salt - in particular a carboxylate and / or an alkoxide. Such a calcium salt may advantageously serve to render harmless hydrogen fluoride formed during operation of the device.

The electrical device may in particular be a gas-insulated switching device. This may in particular be a metal-encapsulated switching device.

Alternatively, the electrical device may be a gas-insulated conduit.

Alternatively, the electrical device may be a gas-insulated transformer.

• 1 eine schematische Darstellung einer gasisolierten Schaltvorrichtung in einer weitgehend geschlossenen Phase des Schaltens,
• 2 eine schematische Darstellung einer gasisolierten Schaltvorrichtung in einer weitgehend geöffneten Phase des Schaltens,
• 3 eine schematische Darstellung einer gasisolierten Leitung zeigt und
• 4 eine schematische Darstellung eines Teilabschnitts einer solchen gasisolierten Leitung zeigt.

In the following, the invention will be described with reference to two preferred embodiments with reference to the appended drawings, in which:

• 1 a schematic representation of a gas-insulated switching device in a largely closed phase of switching,
• 2 a schematic representation of a gas-insulated switching device in a largely open phase of switching,
• 3 a schematic representation of a gas-insulated line shows and
• 4 a schematic representation of a portion of such a gas-insulated pipe shows.

In 1 is a schematic sectional view of a gas-insulated switching device 2 to a first example of the invention. This switching device 2 works on the principle of a blow piston switch, which in the following with reference to the 1 and 2 is explained. The invention is not limited to switching devices and certainly not limited to such after the blow piston principle.

In 1 is a switching device 2 Be it a medium or high voltage switching device shown, the insulating space 4 having. The isolation room 4 is through a housing 5 limited, which is schematically dashed around the switching contacts 8th and 10 is shown around. At the switch contacts 8th and 10 These are essentially rotationally symmetrical components that are arranged around the axis of rotation 13 are arranged around rotationally symmetrical. The switching contact 8th has a central spike 7 on, the annular of an outer switching contact 14 is surrounded. These two parts 7 and 14 of the switching contact 8th are here to an integrated component, the switching contact 8th united. Likewise, a second switching contact 10 also a central thorn 9 on, in turn, by an external switching contact 16 is surrounded rotationally symmetric, these components also represent an integrated component, which in this case as a switching contact 10 referred to as. The central thorn 7 fits in, as in 1 shown, in the closed state in a bore 11 one, along the axis of rotation 13 in the central spine 9 of the switching contact 10 is introduced. Furthermore, the outer switching contacts touch 14 and 16 These represent the main current path. There is also a nozzle 12 provided, which consists for example of a plastic, and also rotationally symmetrical with respect. The axis of rotation 13 around the central spine 7 of the switching contact 8th is arranged.

When opening the switchgear 2 First, the outer contacts 14 and 16 separated from each other, including at least one switching contact by a drive, illustrated by the arrow 22 in 2 along the axis of rotation 13 is deducted. The separation process takes place in total within a few milliseconds, but after separating the outer contacts 14 and 16 the contact between the central spines 7 and 9 initially persists. Here, first, the thorn 7 out of the hole 11 of the thorn 9 drawn. At the same time is insulating gas 6 that is in a compression chamber 18 is located, compressed. Further, on the switching contact 10 the nozzle 12 appropriate in the way that they relate to the thorn 7 along the axis 13 emotional.

After the separation of the two contacts 8th and 10 so far advanced is that also the inner thorns 7 and 9 Do not touch, forms in the area of the nozzle 12 roughly along the axis of rotation 13 an arc 20 out. This is due to the insulating gas 6 cleared out of the compression chamber 18 that are part of the contact 10 is, flows out.

This insulating gas, which in this example is a mixture of a fluoroketone as the first insulating gas component with nitrogen as the second insulating gas component, flows along the arrows 6 in 2 around the arc 20 and clears it out. In this case, the carbon-containing fluoroketone can be decomposed in principle with the formation of soot particles by the local heating in the arc. To prevent this, is in the lower part of the switching device in this example 2 a gas-permeable bag 24a arranged, which is a powder 23a containing an oxidizing agent. This oxidizing agent oxidizes the decomposition products formed in the decomposition of the fluoroketone and thus prevents (or reduces) the formation of soot within the device. For example, the oxidizing agent is an inorganic oxidizing agent in the form of a solid powder. The resulting from the oxidant reaction product can then also as a solid within the bag 24a remain and therefore does not lead to the entry of unwanted solid particles in the area of the switching contacts 8th and 10 , Thus, the operating time of the device is advantageously extended. The bag 24a with the powder 23a is in a first separate area 25a the device 2 arranged so that he the function of the switching contacts 8th and 10 not impaired.

The powder 23a in the bag 24a within the first separate area 25a the device 2 is intended to be exemplary of a first embodiment of the oxidizing agent. Further examples of the presence of such an oxidizing agent are, for the sake of clarity, also alternatives in the 1 and 2 located. In a real device, however, it is sufficient and expedient if, for example, only one of these different embodiments is realized-possibly also as a type of dosage form in multiple execution within a device.

Thus, the oxidizing agent may alternatively be used as a solid compact 23b in a second separate area 25b the device 2 be arranged. In this embodiment, the compact is self-supporting and no further wrapping is required.

Alternatively, the oxidizing agent may also be a liquid 23c in a liquid container 24c in a third separate area 25c be provided of the device. This liquid container 24c may for example be upwardly open or have an opening to another side, so that the liquid can come into contact with the insulating gas.

Alternatively, the oxidizing agent may also be a liquid 23d inside a closed container 24d be present, this container having a liquid-tight, but gas-permeable outer wall, so that the insulating gas in turn can come into contact with the oxidizing agent.

3 shows a schematic perspective view of a gas-insulated pipe 32 according to a second embodiment of the invention. An enlarged view of a section of this line 32 is in 4 shown. The gas-insulated pipe 32 has an inner conductor 33 on, passing through an isolation room 4 from an electrically conductive shell 34 is disconnected. The isolation room 4 is with insulating gas 6 filled, which is the inner conductor 33 electrically from the conductive shell 34 separates. This insulating gas 6 For example, it may comprise a fluoronitrile in admixture with nitrogen as a carrier gas. In the left part of the 3 is a head piece 37 shown, via which the line section shown can be flanged to other such sections. In the right part is a disc insulator 36 shown. Such disc insulators 36 may be arranged in regular or irregular sections to the inner conductor against a surrounding outer electrode 35 to center and thereby isolate. Furthermore, there are post insulators in regular or irregular sections 38 provided to support the inner conductor between the disc insulators, especially downwards against the action of gravity. In addition to the isolated disc insulators 36 and post insulators 38 becomes the inner conductor 33 in the intermediate areas only by the insulating gas 6 against the shell 34 isolated.

In the in 4 As can be seen, in this exemplary embodiment, too, a solid oxidizing agent is arranged inside the device, which serves to oxidize any decomposition products of the fluonitrile that may have formed, thus avoiding the formation of soot within the device. The oxidizing agent is here as part of a compact 43 in front of which is in a separate area 25 near the shell 34 is arranged. The compact 43 will be in this area 25 through a divider grid 44 held. This grid is gas and liquid permeable, but is suitable for holding the compact. In the example shown, the oxidizing agent can be present together with a moisture-binding zeolite in a common compact. Eventually in the gas-insulated pipe 32 existing moisture can thus be adsorbed so first in the zeolite. The residual moisture inside the pipe 32 This is very low. To the gas-insulated pipe 32 To protect against their entire length from harmful soot formation, several such reservoirs of oxidizing agent can be provided over this length. These reservoirs can be arranged in each case in particular in the region of the flanges, by which individual line sections are coupled to one another. The reservoirs may be arranged at regular or irregular intervals with or without the addition of moisture adsorbers. As an alternative to the described common compact, the moisture adsorber can also be present in a solid separated from the oxidizing agent. When used in a gas-insulated line, it is advantageous if the separate area for the reservoir is comparatively flat and close to the wall, since otherwise the distance from the inner conductor to the reservoir and / or a boundary of the separate area falls below a critical distance for a flashover could.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• EP 2652752 A1 [0003]
• EP 2652753 A1 [0003]

Claims (15)

Gas-insulated electrical device (2,32) comprising a dielectric insulating gas (6) which comprises at least one carbon-containing first insulating gas component, - And an oxidizing agent (23,23a, 23b, 23c, 23d), which is in a condensed phase and whose surface is at least partially in contact with the insulating gas (6). Device (2,32) after Claim 1 in which the oxidizing agent (23, 23a, 23b, 23c, 23d) has a standard potential E ⁰ of at least 0 V. Device (2,32) after Claim 2 in which the oxidizing agent (23, 23a, 23b, 23c, 23d) has a standard potential E ⁰ of at least 0.5 V, in particular at least 1.3 V. Apparatus (2,32) according to any one of the preceding claims, wherein the oxidizing agent (23,23a, 23b, 23c, 23d) is an inorganic oxidizing agent and in particular is selected from the group consisting of: - diiodopentoxide I ₂ O ₅ , - potassium permanganate KMnO ₄ , - potassium dichromate K ₂ Cr ₂ O ₇ - calcium iodate Ca (IO ₃ ) ₂ , - potassium nitrate KNO ₃ , - ammonium cerium (IV) nitrate (NH ₄ ) ₂ [Ce (NO ₃ ) ₆ ], - ammonium persulfate (NH _{4) 2} S ₂ O ₈ - potassium hexacyanoferrate (III) K ₃ [Fe (CN) _6] - PbO _2, - a Cu ²⁺ -containing salt, - an Ag ⁺ -containing salt. Device (2,32) according to one of Claims 1 to 3 in which the oxidizing agent (23, 23a, 23b, 23c, 23d) is an organic oxidizing agent and in particular is selected from the group consisting of: - tris (4-bromophenyl) ammonium ethyl hexachloroantimonate - tetracyanoquinodimethane (TCNQ) - 2,3,5, 6-Tetrafluoro-7,7,8,8-quinodimethane (F4-TCNQ) - Dipyrazino [2,3-f: 2 ', 3'-h] quinoxaline-2,3,6,7,10,11-hexacarbonitrile (HAT-CN), - fluorinated organic compounds - organic compounds with one or more cyano groups, - organic compounds with quinoidal structure and / or - generally lewisaziden organic compounds. Device (2,32) according to one of Claims 4 or 5 in which the oxidizing agent (23, 23a, 23b, 23c, 23d) is classified neither as "acute toxic" (GHS06) nor as "hazardous to health" (GHS08) under the CLP Regulation. Apparatus (2,32) according to any one of the preceding claims, wherein the molar amount of the oxidizing agent (23,23a, 23b, 23c, 23d) is such as to be at least that at the given pressure and temperature of the insulating gas (6) Substance of a hypothetical 0.25prozentigen oxygen additive corresponds to the insulating gas. Device (2, 32) according to one of the preceding claims, in which the surface of the oxidizing agent (23, 23a, 23b, 23c, 23d) in contact with the insulating gas (6) is at least 10 cm ^{2 in} total. Device (2,32) according to one of the preceding claims, in which the insulating gas (6) has an oxygen content of at most 5%. Device (2, 32) according to one of the preceding claims, which has at least one insulating space (4) with at least one electrical component (8, 10, 33) arranged therein. Device (2,32) after Claim 10 in which the oxidizing agent (23, 23a, 23b, 23c, 23d) is present within the insulating space (4) and / or is atmospherically connected to the insulating space (4). Device (2, 32) according to one of the preceding claims, in which the oxidizing agent (23, 23a, 23b, 23c, 23d) is incorporated as part of a powder (23a) and / or at least one compact (43) and / or tablet and / or or a granulate and / or a coating. A device (2,32) according to any one of the preceding claims, wherein the first insulating gas component is tetrafluoromethane (CF ₄ ) or trifluoroiodomethane (CF ₃ I) or an at least partially fluorinated ketone or an at least partially fluorinated nitrile or an at least partially fluorinated hydrocarbon or at least one partially fluorinated ether or thioether. Apparatus (2,32) according to any one of the preceding claims, wherein the first insulating gas component is a fluoroketone or fluoronitrile or hydrofluoroolefin or perfluoroolefin having between 3 and 6 carbon atoms. Device (2, 32) according to one of the preceding claims, which is designed as a gas-insulated switching device (2), as a gas-insulated line (32) and / or as a gas-insulated transformer.

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