DE730187C - Arc converter with electrodes in a flowing extinguishing agent - Google Patents

Description

Arc converters with electrodes in flowing extinguishing agent The previously known arc converters with flowing extinguishing agent are designed in such a way that either the gas enters the chamber interior radially and is discharged axially to both sides through nozzle-like openings, or that a gas flow axially through a nozzle or through a nozzle and additional openings (annular gaps and holes) enter the arc chamber and flow out axially through one or more openings. These known arrangements shown in Figs. I and 2 have the following disadvantages: In the arrangement shown in Fig Blocked route a bend around goJ. This creates a double-conical area c of turbulent gas, the tips of which lie in the direction of the two main electrodes i and 2. In the eddies of this double cone c, especially at high flow velocities, a pressure can prevail which is essentially different from the pressure at the measuring point on the chamber wall. There is also the possibility that gas plasma heated by the arc will be present in this cone for a long time after the extinction (a few hundred microseconds). Another disadvantage of the arrangement -d.Fig. R is the unavoidable damming effect that occurs at the outflow screens 3 and: I and nozzles 5 and G: The deficiencies listed make an according to -AM. The built-in arc valve is heavily questioned, as the blocking strength (deionization and static strength) cannot correspond to the values expected according to Paschen.

The arrangement shown in Fig. 2 has similar disadvantages. That flowing through the nozzle 5 and or holes 7 and or annular gaps into the chamber space High velocity gas forms separation vortices d. Further form :I turbulent currents and eddies E in front of and behind the opening b of the Abströnischirmes 4 .. This allows hot gases and 1I .. metal vapors from the 'central axis to the outside driven ”- earth and cause the breakthrough of the gas line here.

In the arrangements shown in Figs. I and 2 is thus itself in the case of nozzles that are precisely designed in terms of flow technology, a faultless one Do not achieve gas flow and thus a dielectric strength proportional to the chamber pressure of the arc valve cannot be reached.

The invention avoids these disadvantages of the known arrangements for arc converters with electrodes in flowing extinguishing agent and several arranged between the electrodes, consisting of conductors, semiconductors or light conductors Plates in that these plates provide openings that are finitely different in size are, "-which for the passage of gas and / or passage of arcs serve, and that the size of the passage openings, in particular the gas passage openings, the step plates increases in the direction of the gas outflow side or gas outflow sides.

The invention will be explained in more detail below Plate or ball electrodes, between which any gas acts as a dielectric higher density is provided, disturbed at one point, then forms with sufficient high field strength at this point, a field distortion. A discharge channel follows von, one of the electrodes that usually leads to the breakdown of the path. These Disturbance can occur in the axis of the arrangement. However, it can also be a different one have spatial location, e.g. B. lie at some distance from the 'central axis. Even dan: i will initiate the breakthrough. The disruption can be from particulate matter (cf. analogy of Üldurchschla @ gs); LTlow pressure core, ionized gas parts, excited gas molecules or liquid mist. This causes malfunction cannot be completely avoided during the technical operation of the converter. Furthermore, since such disturbances are much more pronounced at higher gas pressures, is with the current converter arrangements even with a considerable increase in pressure no immigration operation possible.

The invention has the effect .This disorders substantially reduced, since the arranged between the main electrodes stepping plates. -ib - e see the good guidance of the gas flow as a result of the gas passage openings that are becoming larger on the downstream side, nor the. Have the advantage of releasing only a small part of the two main poles. Disturbances that lie outside the circumference of the gas passage openings of the step plates could not, as a result, cause a breakdown of the airlten gas path, since the discharge channel formed along the field line can only grow up to the next step plate. This ensures that only a fraction of the previously existing disturbance possibilities, which is equal to the area ratio of the effective electrode surfaces to the total frontal electrode surfaces, can occur, with this fraction of disturbance possibilities also being eliminated by further inventive means listed later can be. I> he step plates can be made from insulating stubs. such as B. mica, or from. Conductor material consist of semiconductors, or in a mixed series, such as. B. conductor, insulating material, conductor ..... be arranged, with (the potential of the individual plates by ohmic, inductive or capacitive division can be st ° aert. The number, thickness and other design of the plates and the number. And diameter The holes provided in the step plates are to be selected according to the respective conditions.

Uni perfect dielectric conditions between the individual screens zti, gas flows into the annular spaces delimited by the plates from the outside eii: -guided (gradual gas flow). These gas flows serve simultaneously for perfect guidance of the main and pilot arcs, f (-rner for good dissipation the Vtrlustwä rine. They also prevent the splitting off of hot gas plasma from the edge areas of the arc gas column. This creates a major potential for disruption eliminated. The quantitative distribution of the gas entering the arc chamber is to be selected according to the prevailing operating conditions. Accordingly Equal quantities can be fed into the arc chamber from each ring or it can be grounded a certain graduation of the gas quantities can take place. It is also possible to have a Fresh gas supply to be provided only in some annular spaces. Due to the inflow of the Fresh gas perpendicular to the arc along the entire arc path becomes the quality deionization, significantly increased, since it is cold after the arc has been extinguished insulating gas parts divide the conductive hot gas column and thus the dielectric strength of the arc valve ilt significantly increase extremely small times. This is at the arrangements known up to now are often not possible, since this usually involves an upward flow of fresh gas takes place along the arc, so the fresh gas is continually -I is heated and insulated. -It is also possible with the help of the gradual gas flow possible, the length of the arc and thus the blocking distance without significant increase of losses to increase. with higher locking loads an increased Achieve security level. In doing so, the step management according to the invention the arc good, held axially. To further stabilize the arc, you can possibly the electrode system in whole or in part with a specific one Speed rotate around its central axis, creating a mechanical guide of the arc is reached.

The above-mentioned advantages of the invention not only occur at a certain direction of the gas flowing through the arc converter on, but with each arc converter designed according to the invention, regardless of the type of flow (axial-axial, radial-axial, axial-radial) the arc converter is working. This is based on several exemplary embodiments the invention explained in more detail.

The Ab @ b. 3 shows an arc converter according to the invention .One-sided gas flow. i is the one plate-shaped main electrode, which is from which is also plate-shaped ignition electrode 3 is covered. The ignition electrode 3 is provided with ignition horns 8 on which the auxiliary arc is ignited. the The shape and number of the ignition horns depend on the gas quantities and other operating conditions accordingly to. Select. The use of ignition horns is: therefore advisable, because then the ignition takes place at a point where the gas velocity is low is. The use of a plate-shaped ignition electrode has the advantage that radial directional components of the gas flow when leaving the gas passage opening the ignition electrode 3 in the arc chamber avoided «-earth. Furthermore, with plate-shaped, with ignition horns provided ignition electrode 3 a .gürstigen, namely completely centric crater-shaped burn-off of the main electrode i, so that a disruption of the gas supply and thus the deionization and ignition reliability due to the burn-off do not occur can. 9 to i i are those provided according to the invention with central holes provided step plates. The diameter of the holes of the step plates will be according to of the invention against the. Outflow pole larger. Through all (or only certain) annular spaces The stage gas is fed in between the plates, as indicated by the arrows demonstrate. q. is the discharge plate and 2 is the main discharge electrode. The discharge arrangement corresponds to that on the inflow side, and the advantages listed above apply, such as favorable combustion form, freedom from eddies of the gas, etc., also here. The potential the outflow plate .I and possibly also the potential of the plates 9, io and i i can be determined by ohmic, inductive, capacitive or mixed control "earth.

In Fig. Q. is another embodiment of the invention, shown. i is the main inflow electrode, 3 is the ignition electrode, 9, io and i i are the step plates, d, is the discharge screen and 2, for example, with holes 12 provided outflow main electrode.

Of course, the invention does not apply to one-sided gas flow limited to the two embodiments described above, but can can be used with any desired shape of the electrodes and plates.

The Fig.5 shows an application example of the invention with both sides Outflow. i and 2 are the main electrodes, which are assumed to be plate-shaped, for example are.

But they could also be designed as spherical caps or flow bodies be. 13 and 1q. are the middle plates between which the main gas is fed will. - 9, io and i i are the step plates used in this embodiment are .developed, but can also be .shaped differently. The step @ nplatten9, 1o and ii can also be made of insulating material in the embodiment of Fig. 5, Conductors or semiconductors are made, and their potentials can be in the already at can be controlled in the manner described in the other embodiments. The plate spacing can be the same or continuously decreasing or increasing in one direction. the Step plates located directly in front of the main poles can depending on the shape the main poles can also be designed as nozzle screens or screen electrodes. the Ignition of the main arcs can be carried out in a known manner with the arrangement in FIG by high frequency sparks or twin auxiliary arcs. In the latter In this case, the plates 13 and 14 then serve as ignition electrodes.

Nbb.6 shows an application example of the invention with double-sided axially inflowing and radially outflowing gas. i and 2 are again the main electrodes, : those from the ignition plates 3 and q. are covered. There are on the ignition plates Die Zündbörner B. The ignition is carried out by auxiliary arcs; driven against each other will. 9, io and ii are the step umbrellas. Between the middle step plates i i the total gas is discharged radially. The formation of the umbrellas is natural also different possible, furthermore a distance change and a Shifting the position of the screens to one another is conceivable.

Claims (1)

PATENT CLAIMS: r. Arc converter with electrodes in flowing extinguishing agent and several plates consisting of conductors, semiconductors or non-conductors arranged between the electrodes, characterized in that these plates are provided with finite openings of different sizes, which are used for the passage of gas and / or passage of arcs , and that the size of the passage openings, in particular the gas passage openings, of the step plates increases in the direction of the gas outlet side or the gas flow side. a. Arc current converter according to Claim i, characterized in that the potential of the step plates is controlled by voltage division. 3. Arc straightener according to claim i or 2, characterized by the same spacing of the steps.hlatten from each other and from the associated l) cnachbarteri electrode. .1. Arc converter according to Claim 1 or 2, characterized by the step plates being spaced differently from one another and from the associated neighboring electrical unit. j. Arc converter according to claim 1 or the following, characterized in that all or one of the spaces formed by the step plates for supplying the gas is irr. "-. Use extinguishing agent to roughen the arc. (>. Lichtlx> genstramrichter according to claim i or the following, ausgenoinmcii claim>, characterized in that all or some of the spaces formed by the step plates are used to discharge the gas or extinguishing agent from the arc chamber. 7. Arc converter according to claim i or the following, characterized in that the step plates and the step gas guide are designed and arranged in such a way that the arc is guided axially that the blocking distance can be increased without significantly increasing the arc losses. y. Arc converter according to claim 1 or the following, characterized in that the entire arc control valve or one part of the arc valve rotates so that the arc is stabilized. to. Arc converter according to claim h i or the following, characterized by the fact that the step plates - the step gas guide are designed and arranged in such a way that the gas flows impinge perpendicularly on the arc, so that the deionization is improved. r r. Arc converter according to claim 1 or the following, characterized by a plate-shaped design <fier auxiliary electrodes (ignition or shield electrodes) and / or the Haul> telel: trodeii. 12. Arc current straightener according to claim i or the following, characterized in that the step plates are designed and arranged such that the fresh gas is supplied on both sides radially through the annular spaces and discharged radially. 13. Arc converter according to claim r or the following, except: -inen claim r.2, characterized rc1cetinzeiclinet that the step plates are designed and arranged such that <las fresh gas is supplied axially on both sides and discharged radially through the annular spaces. 14. Arc enstroinrichter according to claim i or the following. characterized. Let the auxiliary arcs ignited at the two 1-main electrodes be blown against each other and held axially by the stepped plates.