DE1247493B - Process for the controlled extinguishing of the discharge of gas or vapor discharge vessels using a short-term auxiliary discharge and application of the process - Google Patents

Description

Process for the controlled deletion of the discharge. of gas, or. Vapor discharge vessels = using a temporary auxiliary discharge and application of the method The invention relates to a method for controlled deletion of the * - discharge = of gas or r Vapor discharge vessels `under-.; Use _ a temporary auxiliary discharge = Feed the control of discharge vessels in their Brenfdäüer = it is relatively easy to set the ignition point de s-vessel-arbitrary. in the course of a period of ' food d en = W: e_chselstro @ res to define: .It is hunting much more difficult to find a or targeted: gesteüenen Löschyörgäng a m a Discharge, if there is a burning 'discharge, - in particular dere = äucli'bei. Feeding such a discharge total vessel with one _voltage = half-wave of the alternating current, d, .- h. in front of the natural the zero crossing of the alternating current to educate lung_ -a partial modulation when present- one Converter to achieve: - -Es sirid @ already arrangements vöxgeschlagen_ wor = the, to 'the, - extinction: the discharge in' a gas or vapor discharge vessel, especially in. S_träm- Richter vessels5 before the normal Nülldürchgapg des Anode current due to an immediate effect on -the Tlaüptentladungsabschnitt- to bring about .., From such- arrangements becomes = multifaceted_. B_. at 'Wech = self made use. = With these the Deletion of the - discharge, -which - between-. anode and cathode of the discharge vessel burns, `means of a charged capacitor-induced, which for the. Time of deletion. with such a polar did to the anode and cathode dexerite charge path is placed -thereby: the = anode negatively is beat. - For _ -such-establishments where in the direction of the Käthöden-Arioderi route - against-the-actual marriage stream, run- the rush current used = is ;, = but is always a relax tiv - large electrical = power requirement - required, to-the deletion process. -at in effective way to carry out. It is, furthermore, a circuit-v_örgeschschlag- the one for which to bring about the deletion a discharge in a DC voltage the gas =: or: Metalldämgfentlädüngsgefäß ein.-zw Scheu- anode and cathode of the discharge vessel switched on condenser_ operationally - charged = the .and for the erasure of the discharge vessel by means of a universal switch to an auxiliary electrode is switched, which - _ designed like an umbrella - and just above a focal point in is arranged in the discharge vessel. At a- sol- This arrangement is intended to cause the deletion be led, -ass with your Aüfschälten the con- densatörs on the route auxiliary electrode-cathode the Main discharge initially on the auxiliary elec- trode-cathode and then to -this -Ent- charge path auxiliary electrode-cathode is extinguished. In doing so, the deletion process should be added be that an oscillatory discharge, which in the circuit takes place, which the auxiliary terminal contains the condenser and the first reloading of the capacitor a quenching at the auxiliary discharge path .. In -this known request was, as stated, as. emergency agile condition, - the cathode burner spot on-the cathode mercury mirror after-l.Vlög-. opportunity through a special one. Fix body and "the named auxiliary electrodes" in the manner of - one Umbrella like this over the stain fixation body. at- assign, that within - the desired deletion time the existing-cathode-spot - not from.-that Detach or remove flecked bodies. far from-this can remove: In such an arrangement, - as indicated; invoiced according to plan; that_ a Umlädüng of the condenser takes place. But this can result Ion impact from the plasma on the negatively beat auxiliary lectures to lead to-; that in the vessel a- re-ignition to the main anode- under image- formation of a cathode spot. on the auxiliary electrode takes place. This can of course be too. one _Destroy- run rüng 'the auxiliary electrode; because. it takes me- desteris so long -an; until the capacitor has been restored: -_. .. ". . -fully- charged In 'another known arrangement, -ein' Firing pin used, _- which in the Kathodenqüecksil = immersed in this - forms his. Version same- early -a umbrella-like, auxiliary electrode, -what one covers certain area around the firing pin. In this vessel, which was fed with alternating current, the ignition pin was fed rhythmically in the course of each voltage half-wave of the alternating current via a contact device each from a charged capacitor for igniting the discharge and for extinguishing the discharge. The dimensioning of the said screen is done in such a way that, within the burning time of the discharge, the cathode spot cannot move so far away from the ignition pin that it comes to lie outside the area of influence of the screen electrode forming its socket.

With this arrangement, the same disadvantageous phenomenon as they are already known in the case of the other in their essence discussed above Arrangement described wgrdel. is.

In these known arrangements, the auxiliary discharge path is effective over the entire period from the time the extinction is initiated to the time the main discharge is completed. As stated, there is in particular the deficiency that, despite a targeted, controlled extinction of the discharge, a new ignition can take place in the vessel in an undesirable manner. The invention revives the deficiencies. It relates to a method for the controlled extinguishing of the discharge of gas or vapor discharge vessels, which are re-ignited by an ignition pin in every period when operating alternating current, using a brief auxiliary discharge of high amperage between an auxiliary electrode acting as an anode and the operational cathode of the vessel, and is characterized by the use of an auxiliary discharge, the current amplitude of which exceeds the current strength of the main discharge by an order of magnitude or more, and furthermore by the fact that the auxiliary discharge is switched on before the desired point in time for the main discharge to be quickly extinguished and its circuit is blocked at the same time is switched off again. The auxiliary discharge provides a high density of negative charge carriers (electrons) in the plasma of the discharge vessel, which is sufficient to conduct the current of the main discharge to be extinguished until the cathode spot or spots of the main discharge have been broken down. Because the circuit of the auxiliary discharge is blocked at the same time as it is switched off, an energetic influx of charge = onto the anode of the auxiliary discharge is prevented, on the one hand it could lead to the formation of a cathode spot on the auxiliary anode and thus to reignition of the discharge: To initiate the Auxiliary discharge and to block the auxiliary discharge path as a generator of charge carriers and the blocking of the anode of the auxiliary discharge path against the influx of positive ions - according to the invention, according to one solution, a specially controlled electrical gas discharge valve can be connected in series with the anode of the auxiliary discharge path. This is switched on or ignited to activate the auxiliary discharge and blocks the auxiliary discharge via the auxiliary discharge path by going out. When it is blocked, however, it simultaneously forms a single isolating path in the line from the anode of the auxiliary discharge path, so that an influx of positive charge carriers can no longer take place because he at the meanwhile extinguished relief discharge line finds a lock. With such a Structure of a device according to the invention is therefore except for the main discharge vessel. such additional auxiliary discharge vessel for the control the auxiliary discharge path provided. According to another embodiment of the invention But the construction of the system can also be used in this way be taken so that no 'special relief is required to prevent the auxiliary discharge track to control. This function of switching on and the blocking of the auxiliary discharge can be Lich directly at the anode of the auxiliary discharge route if this feeds a control grid is drawn, which in an appropriate manner is applied and the impact of positive ions on the anode derilfse.tladungsstreeke prevented. The essence of an arrangement according to the invention consists in that the solution of the head nt- loading route is carried out by placing a operation with your rntladu # ag provided help charge path is switched off after the Function # 9- - the] 3ergitstQllung the increased charge carrier density n u fu Plasraa - r the deletion fulfilled has, The downstream ixahanegesclnwixrdigkeit an der H u fs Iufs- The charging path must be determined for this Live minimum amount so you want lukewarm. Lö5cha- The entire load carrier density is at a glance Plasma taking into account the carrier life duration of the burning, discharge within the method of construction time for the provisional further management of the interrupted. Current required has real value. Furthermore, the negative charge carrier density, which by applying the auxiliary Ladungsstreck_e provided for the extinguishing moment is to be dimensioned so large that it is given the sense above is # able to even the biggest .. Currents of the charge path between the anode and Tathode of the Strm_richtex vessel from your plasma to deliver out which, depending on the proper arrangement to be controlled operating cases come into question, Such operating cases can. both be arbitrary controls, such as the targeted extinction of the discharge of a current 0 for its partial modulation, as well as un- ordinary company rails for the converter Plant, such as B. a te_rgefäß bzwr fü_ r the electrical Kurzschlussatrgm, even such a can pass the application of the invention, in this case after Kind of a protective device, quite effective delete if the validation of the deletion A domestic direction corresponding bhängigkelt of the Takes place occurrence of such ü berstrQmes. That can z. B. can be achieved by a rate of change of the anode current Conducted impulse for the control or the input the protective device is used. For the Purposes of the effect as a protective device would with preferably providing the necessary negative charge carrier density with the help of a correspondingly larger energy duels for the aid charge route made. Feeding the Hip discharge route raun by means of different types i = gei power sources take place within the scope of the invention. So the supply of the auxiliary discharge path z. B. from an ele @ triselieu storage element, preferably in Farm of a capacitor. So with the Discharge of this capacitor via .the auxiliary discharge charge path the desired current gradient is guaranteed in the reduction of the auxiliary discharge path, it is expedient to build the discharge circuit over the auxiliary discharge path with as little inductance as possible. For this purpose, the line loop which forms the discharge circuit is preferably made as small as possible by arranging the capacitor close to the discharge vessel.

The capacitor is powered by a suitable source of electrical energy continuously charged, e.g. B. from an electrical AC voltage source via rectifier and, if necessary, via resistors. For supplying the auxiliary discharge path When the capacitor is discharged, it becomes the same as for the controller the supply of the auxiliary discharge specified, either by means of one with her integrating or an independent valve 'device in the form of a second controlled auxiliary gas discharge path to the auxiliary discharge path of the converter vessel for the provision of the negative charge carrier density for the extinction of the main discharge switched. This auxiliary discharge path, which is used for switching, can either be a grid controlled or also a. - be an auxiliary vessel controlled by a firing pin. Becomes a Ignition-pin-controlled vessel for initial ignition in every period of the alternating current chosen; so it is advisable to use a so-called capacitive igniter, d. H. a firing pin, which has a dielectric, flushed by the cathode mercury Owns coating. This is useful because in the present case ignitions of discharges with short-term, very high current peaks, what pure resistance detonators are for not as suitable because of certain physical phenomena in continuous operation have proven. As part of the above-mentioned expedient shortening of the conductor loop the auxiliary discharge path, it can prove to be advantageous, the discharge vessel for the control of the auxiliary discharge path directly in the construction of the converter vessel to be controlled in its deletion. to adapt its current path to this to a large extent. The switching auxiliary discharge path z. B. be used directly in the implementation, through which otherwise the lead to the anode of the auxiliary discharge path would be laid, The Capacitor for supplying the auxiliary discharge path can be constructed with the switching auxiliary discharge vessel are united by being directly with its coverings is built up around this vessel. However, the capacitor can instead z. B. be arranged around the cathode of the main discharge vessel. Uin in the circuit of the auxiliary discharge line with the smallest possible driving force Voltage to get along to achieve the most effective auxiliary discharge possible, the current path of this circuit is preferred for the formation of only small resistances measured. Several capacitors can also be used as electrical energy storage devices that are charged in parallel and connected in series for discharge will. In this way, it is only a charging source of small voltage required, however, a high driving voltage for the discharge, gained and at the same time the capacitance value which determines the time constant of the discharge circuit degraded. The auxiliary discharge path can also be fed instead of from one electrical energy storage, such. B. in forums of a capacitor, directly take place from an electrical energy source, which is continuously capable of electrical To deliver energy. Thus, in a simple way, a desired intermittent supply the auxiliary discharge takes place, the z. B. again about a special switching Auxiliary discharge vessel can be made, it is for its proper effect required that this vessel is fed by an AC voltage source, the accordingly then -for the purposes of the invention at a higher frequency than that Frequency of the main discharge line feeding current must work. Their minimum height is determined by the fact that there is a current supply of the necessary charge carrier density for the brief guidance of the discharge current in the main discharge path guaranteed from the plasma.

For the formation of the auxiliary discharge path from a special auxiliary electrode as an anode to the cathode to provide the increased negative charge carrier density of the vessel can either have a special independent auxiliary anode as an additional Component are provided. or it can be used as such an auxiliary anode if appropriate also a part that is present in the current enrichment vessel, such as, for. B. an isolated arranged anode protection tube, a control grid or directly the vacuum vessel of the converter vessel, can be used if its cathode is against. the rest of the vessel wall is electrically isolated. The control grid z. B. is then according to its control function in the gas discharge vessel continues for the purpose of the auxiliary discharge path as Auxiliary anode used during main discharge burning. Will be a special one If an independent auxiliary anode is used, it may be advisable to use it with consideration with a low anode drop over a large area and as close as possible above to arrange the cathode mercury. It will still be recommended for one rapid reduction of the residual concentration of charge carriers in the vicinity of the cathode surface Provide special deionization surfaces to avoid the risk of flashback exclude the deletion. The role of these deionization surfaces can also be immediate the anode of the auxiliary discharge path, if this electrode is transferred accordingly is formed and is accordingly arranged just above the level of the cathode.

For the supply of the auxiliary discharge path, which increases the causes negative charge carrier density, was either the use of a special one Auxiliary discharge vessel has been specified, which the energy source on this auxiliary discharge path switches, or the use of one integrating with the auxiliary discharge path Control device. In the latter case, it is also possible without a special discharge vessel to control the supply of the auxiliary discharge path can be worked by the- Anode of the auxiliary discharge path in the converter vessel with a corresponding control grid is equipped, which experiences a corresponding electrical control. This In this case, the control grid is preferably the anode of the auxiliary discharge path as close as possible to its effect as a barrier against the inflow from to make positive ions in the auxiliary anode as perfect as possible. _ _ For the purposes a partial control of the converter vessels in the course of each period of the feeding According to the invention, only single-anodic discharge vessels can be used with the alternating current. For the purpose of protection against overcurrents or short circuits, the invention but can also be used in multi-anode discharge vessels.

The application of the invention is furthermore not limited to arrangements in which the main discharge current path in the discharge vessel is fed with alternating current, but it can also be used with the same success. Apply when - the main discharge path. of the vessel is fed with direct current. The method according to the invention can therefore also be used advantageously in order to interrupt high-voltage direct currents with the aid of a -.- discharge vessel ..as .switch. The figures in the drawing illustrate some, for example, circuit arrangements for the application of the invention. In: the exemplary embodiment according to FIG. 1, 1 denotes 1-the hemp discharge vessel. to the anode 1a, -the control grid 1 b and c with a diaphragm 1, which demand the rising metal vapor in the vessel or the vessel walls deflects by condensation surfaces out. 2 designates the immersion ignition pin of the vessel - for its initial ignition in the course of each period of the alternating voltage which is applied to the anode 1a and the mercury cathode 3 of the vessel 1. An auxiliary discharge vessel is denoted by 4: This is used to control the discharge of the condenser 5 via the auxiliary anode 6 at a predetermined time, in order to generate the additional auxiliary discharge in the vessel for the operational cathode, by means of which a measure compared to the one required for the main discharge - created increased negative charge carrier density and is provided for the extinction of the main discharge path during the degradation time of the cathode spots. An alternating current source is used to charge the capacitor 5, which feeds the transformer 9, from the secondary winding of which via a limiting resistor 7 and the valve 8 the capacitor 5 is charged with electrical energy and charged with a certain polarity. If an arc existing between the anode 1a and the cathode 3 is to be extinguished, the discharge vessel 4, which according to the example is designed as a vessel with ignition ignition, is ignited by means of the ignition pin 4a. The capacitor 5 can now discharge over the path formed by the auxiliary anode 6 and the cathode 3. After the discharge of the capacitor 5 has dropped to a certain lower value with the formation of a discharge or a current from the auxiliary anode 6 to the cathode 3 with a correspondingly high rate of current change, this discharge in the vessel 4 is automatically interrupted and the capacitor 5, which in the meantime has been reloaded in the circuit fed by it, is electrically separated from the anode 6 of the auxiliary discharge path, so that an ion current that could initiate a reignition at this does not take place via the anode 6. Now, before the main discharge path is extinguished, a charge carrier density is provided in the plasma of the vessel 1 which exceeds the amount that would be required to maintain the arc between the anode 1a and the cathode 3. Because of this excess of negative charge carrier density, the arc from this high-current plasma is briefly supplied with charge carriers over the main discharge path in such a way that no electron emission from the cathode spot or cathode spots is required to maintain this current. This non-stressing of the cathode spot .bzw. the cathode spot for the delivery of electrons makes the previous existence of the cathode spot superfluous, so that it goes out automatically. In each subsequent period of the alternating current feeding the main discharge path (la to 3), this vessel is re-ignited via the ignition pin 2 at the desired moment in time, so that the main discharge between the anode la and the cathode 3 is re-established.

The embodiment -according to Fig: 2 shows an arrangement, - with the capacitance used for supplying the auxiliary discharge path in its structural design - adapted to the rest of the discharge vessel and: also consists of several condensers: these are connected in parallel for the -Auffädung and are for the discharge connected in series. In this figure, 1 again denotes the converter vessel and 4 denotes the auxiliary discharge vessel for controlling the supply of the auxiliary discharge path in the converter vessel. The capacitance 5 in this case consists of two capacitors 5 a and 5 b in the form of circular ring disks. The inner diameter of these circular ring disks is dimensioned such that it is larger than the diameter of the cathode part of the vessel enclosed by them. The anode of the auxiliary discharge path is again labeled finite 6. In this case it has a large area with corresponding through openings through which the main discharge between the anode 1 a and the cathode 3 can pass. As a result of this large-area design, this electrode 6 can be used directly as a body for accelerating the deionization process both after the main discharge has been extinguished and after the auxiliary discharge has been interrupted. An AC voltage source is used for charging the capacitors 5a and 5b , which supplies its energy via a transformer 9 and two valve sections 8a and 8b as well as limiting resistors 7a and 7b . As a result of the special activation of the valves, both half-waves of the alternating current supplied via the transformer 9 are used one after the other to charge one of the capacitors 5a or 5b. These. The circuit arrangement does not require any further explanation beyond this description, since it otherwise acts in the same way as the arrangement according to the exemplary embodiment according to FIG. 1 with appropriate control of the switching vessel 4 and the detonator 2.

It has already been pointed out above that the negative Charge carrier density that is created in the vessel, corresponding to that to be controlled Operating cases must be measured. So should an arrangement both for a partial level control the converter as well as z. B. effective for the control of short circuits should be, if only one auxiliary discharge path is used, and only an electrical energy store or a voltage source for their supply the energy of this voltage source, e.g. B. the capacitor, are dimensioned so that that it has the increased negative through the auxiliary discharge path fed by it Carrier density is able to provide the short-circuit current in the To clear main discharge path. In terms of operation, this would require a continuously high energy consumption mean for the supply of the auxiliary discharge path. This effort can, however thereby reduce that for the supply of the auxiliary discharge path two electrical Energy storage can be used. Of these, one can only know the electrical conditions master for the partial control of the vessel, i.e. the normal targeted extinguishing in the course of a period during the proper operation of the discharge vessel, and the other those electrical conditions that exist in the event of a short circuit. Instead of this, the second one can also be used to control the short circuit = extinction Capacitor can be interconnected with the first to form a battery, preferably in the form of a series circuit, which is then switched to the auxiliary discharge path will. The electrical energy storage or additional energy storage for short circuit extinguishing is only activated when such a short circuit occurs, what - how has already been stated above - can be done, e.g. B. depending on the Current change in the cathode feed line of the converter by adding a corresponding Pulse is derived to control the switching device through which the charged Capacitor for short-circuit extinction either on the same auxiliary discharge path or a special auxiliary discharge path is switched on the converter vessel for generating the increase in the negative charge carrier density. So you can for example in the embodiment according to FIG. 1 of the auxiliary discharge path, which is formed by the anode 6 and the cathode 3, a second feed system a corresponding capacitor of the type shown in FIG. 5 and a corresponding discharge vessel assign according to type of 4. For the charge of the other capacitor must then analogously a correspondingly differently dimensioned voltage or voltage source can be used.

The F i g. 3 illustrates an embodiment for an arrangement, at which for switching the electrical energy source to the auxiliary discharge path a special discharge vessel is not used, but for controlling it The auxiliary discharge path is fed directly with a corresponding control grid Is provided. As far as the same parts are present again in this figure As in the other figures, the same reference numerals are used immediately for the individual parts have been retained. As can be seen from the figure, the Auxiliary anode in this case assigned to the special control grid 6a, which over a tax rate 12 corresponding to the reverse voltage and to a control voltage for the release of the supply of the auxiliary discharge path between auxiliary anode 6 and Cathode 3 is placed. The discharge via the auxiliary discharge path 6 to. 3 goes out, as soon as the capacitor has been reloaded in the circuit it has fed and, this creates a negative potential at the auxiliary anode 6. The flowing towards the anode 6 positive ions are through the meanwhile negatively charged control grid 6a intercepted.

To provide an indication of the value of the charge carrier density in a converter vessel to give, it is pointed out that in these in the usual constructions a negative charge carrier density for carrying a current of about 1000 amperes of about 101s per cm3 is required. For extinguishing such an arc is then, according to the invention, a negative charge carrier density of at least overall to provide about 1014 per cm3 in the plasma in front of the anode to be extinguished.

Claims (13)

Claims: 1. Process for the controlled deletion of the discharge of gas or vapor discharge vessels that operate in alternating current in every period be re-ignited by a firing pin, using a temporary auxiliary discharge high amperage between an auxiliary electrode acting as an anode and the operational one Cathode of the vessel, characterized by the use of an auxiliary discharge, whose Current amplitude the amperage of the main discharge by an order of magnitude or more exceeds, and further in that the auxiliary discharge before the desired time of extinction of the main discharge both switched on and under simultaneous Blocking their circuit is switched off again. 2. The method according to claim 1, characterized in that the anode of the auxiliary discharge path is a per se part already present in the converter vessel, insulated anode protection tube, Control grid, vessel wall of the vessel insulated from the cathode, is used. 3. The method according to claim 1, characterized in that the hip discharge path fed by an alternating current source in series with a control device whose frequency is high compared to the frequency of the main discharge path flowing alternating current. 4. The method according to claim 1, characterized in that that a charged electrical storage device at the desired time of deletion is switched to the auxiliary discharge path. 5. The method according to claim 4, characterized by using several capacitors, which are either connected in parallel simultaneously or successively charged from the same voltage source and for their discharge can be connected in series to the auxiliary discharge path. 6. Establishment with a deletion of the discharge controlled according to the method according to claim 1, characterized in that a in the discharge vessel above the cathode mirror or several large-area bodies are provided that deionize the discharge path after the cathode spots have gone out. 7. Device according to claim 6, characterized in that the deionization body formed over a large area The anode (6) is used for the auxiliary discharge path (FIG. 2). B. Device with extinguishing of the discharge controlled according to the method according to Claim 1, characterized in that a controllable auxiliary discharge vessel (4) is located in series with the auxiliary discharge path (F i g.'1, 2). 9. Device according to claim 8, characterized in that the auxiliary discharge vessel is a trigger pin-controlled The vessel is whose firing pin (4a) has a dielectric coating (FIG. 1). 10. Device according to claim 8, characterized in that the auxiliary discharge vessel is inserted directly into a bushing of the discharge vessel. 11. Establishment with a deletion of the discharge controlled according to the method according to claim 1, characterized in that a control grid (6a) for control purposes in the discharge vessel the auxiliary discharge path is provided (Fig. 3). 12. Device for carrying out the method according to claim 4, characterized in that a capacitance used as an electrical storage device and consisting of one or more capacitors (5 a, 5 b) is structurally adapted to the shape of the discharge vessel (FIG. 2). 13. Application of the method according to claim 1, for switching a DC circuit. In. Publications considered: German patents No. 624 093, 638 337, 656 986, 670 281; German Patent No. 160 864 / Vienna; . British Patent No: 494 652.