DE1087273B - Glow discharge switch for lighting electric discharge lamps - Google Patents

Description

The invention relates to a glow discharge switch for starting or igniting electrical low-voltage gas discharge lamps.

It is known that glow discharge switches contain a tightly sealed bulb with an ionizable one Gas filling, leads reaching into the piston of the switch, two main electrodes, and at least one Auxiliary electrode, the leads are each connected to one of the electrodes. At least one of the The main electrode is designed as a bimetallic electrode and closes or interrupts when heated electrical contact with the other as a result of a gas discharge or cooling Main electrode.

In earlier known glow discharge switches of this type, the actuation of the bimetallic electrode is used formed main electrode required heat by a glow discharge in a gas or Gas mixture generated. The bimetal electrode exposed to the heat of the glow discharge is heated, "bent" and comes at a predetermined temperature with the other acting as a counter electrode Main electrode in contact. This contact interrupts the glow discharge, which then the heat generation is also canceled. The bimetallic electrode now cools down quickly, so that a Separation of the main electrodes takes place.

When using such switches as igniters for fluorescent lamps, the main electrodes are in contact the switch closes the heating circuit of the glow cathodes of the fluorescent lamp Episode. The closure of the cathode heating circuit releases a current for a certain period of time through which the cathodes are brought to the temperature required to ignite the fluorescent lamp should be preheated. After this period of time has elapsed, the main electrodes of the Igniter from each other, whereby the heating circuit of the cathodes is interrupted and as a result of the upstream Impedance a voltage surge is triggered, which then · the discharge in the fluorescent lamp itself ignites.

The contact time with the previously known glow discharge igniters was, however, much shorter, than it is for heating the hot cathodes +5 of the fluorescent lamp to the required temperature is necessary, so that the switching-on process described above was repeated several times until the lamp burned. This meant a corresponding number of voltage surges on the cathodes of the fluorescent lamp, causing unnecessary stress on the cathodes and shortening the life of the lamp Had a consequence.

It is already a glow discharge switch for the glow discharge dialer to ignite
electric discharge lamps

Applicant:

Egyesält Izzolämpa es Villamossägi
Reszvenytärsasäg, Budapest

Representative: Dipl.-Ing. W. Meissner,

Berlin-Grunewald, Herbertstr. 22

and Dipl.-Ing. H. Tischer, Munich 2, patent attorneys

Claimed priority:
Hungary from. November 11, 1953

György Lakatos, Janos Szabo, György Szigeti
and Janos Weiszbuxg, Budapest,
have been named as inventors

make known electrical low-voltage gas discharge lamps, in which, in addition to two main electrodes, at least one of which is designed as a bimetal electrode, at least one of the main bimetal electrode associated auxiliary electrode is provided and in which furthermore the power supply lines each are connected to one of the main electrodes in such a way that the flowing from the main electrode to the supply line Current does not flow or only partially through the auxiliary electrode, which with the bimetallic main electrode in such a way is thermally and electrically directly connected that their cooling by the in the auxiliary electrode developed heat is delayed and thereby the duration of the contact of the main electrodes increases will.

In another switch, which is disclosed in Austrian patent specification 165 822, between the electrodes of the ignition switch generates an arc discharge of such amperage that the It is sufficient to heat the electrodes of the fluorescent lamp. Of course, there is a voltage drop here between the main electrodes of the ignition switch, and they have no metallic contact with each other. These circumstances are related to heating; H. Preheating of the electrodes of the fluorescent lamp is known to be disadvantageous, which is why such constructions have not proven themselves and therefore have completely disappeared from the market.

009 587/171

3 4

The invention is based on the object of electrode. The detonator according to the invention thus has starting from this acquaintance, create a glow igniter to the essentials compared to the known construction, in the case of the first, a faster heating lent advantage that the contact is made ahead of each other Bimetal electrode and thus a faster closing time compared to the known arrangement. of contact is effected and secondly, 5 voltages are shortened. Furthermore, at the same time as the invention by the heat dissipation of the on high proper arrangement the duration of the closing of the Temperature located auxiliary electrode to the with her circuit after making contact without influencing Bimetal electrode the contact duration of the solution of the duration preceding the contact Main electrodes is extended. can be set as desired, while the loading

These two intended effects have, in a well-known arrangement, the closing period only by

the importance of switches for starting or shortening the preceding period of time is increased

that of gas discharge lamps with preheatable elec- can.,

troden, in which by the extended contact- In another known construction is with the duration of the preheating of the lamp electrodes of the bimetallic main electrode is also extended by an auxiliary electrode and thus a premature cold start of the 15 trode, which on its surface with a Lamp is prevented, which is responsible for the ignition of emitting and in operation in a sense iso-low voltage - Gas discharge lamps are provided with a particularly gleaming coating and with which is equally important. if provided with an emitting layer

The invention consists in such a main metal main electrode being connected in series. With condensation the auxiliary electrode that before the contact closes ao clocking on the main electrodes, the current flows of the main electrodes the glow discharge also passes through the auxiliary electrode and is generated there an arc discharge between the auxiliary electrode and heat, which has a certain delaying effect from the main electrode not connected to it, which exercises up. However, this construction does not secure either for the contact closure of the main electrodes as an arc against the flickering of the lamp, because after the discharge continues and through which the auxiliary elec- trodes hear the gas discharge, the generation of heat begins trode is heated to a temperature which is higher in the conductor lying in series with the bimetal is than the temperature of each of the main electrodes, where- not immediately, but it must first be the low one by increasing the contact time of the temperature of this conductor in the auxiliary electrode. In this Main electrodes increasing the amount of heat up-period, the igniter is repeated an ignition is saved. 30 try, making the cathodes of the to be ignited

In the glow discharge switch according to the invention, gas discharge lamps are detrimentally stressed,
thus sets in contrast to the known switch By the invention, the disadvantages of the above-mentioned Austrian patent known glow switch are eliminated and also the discharge as a glow discharge, then the life of the gas discharge lamps is reduced by reducing in an arc discharge, the current strength 35 reduction of the number unsuccessful switch-on processes are not sufficient to raise the electrodes. Accordingly, the flickering of the gas lamp is also heated up, but only to reduce the amount of heat in the auxiliary discharge lamp when it is started or to store such an amount of heat in the electrode that eliminates the harmful stress on the contact duration of the main electrodes after the methods have been carried out, because the ignition attempts by the contact closure of the same prolonged and to this end, the arc discharge or thermal delay is sufficient, the period of time from switching on to the igniter according to the invention without the contact closure of the main electrodes of the ignition switch being lengthened by the ignition process, because the time passes to shorten significantly. Delay required heat in the auxiliary electrode

It is already known to provide a bimetal in the igniter by means of an arc discharge in front of the con-electrode and a rod electrode, with 45 clocking of the main electrodes being generated,
The bimetallic electrode is shielded from the discharge by a plate-shaped auxiliary electrode that prevents the bimetallic electrode from cooling down. Delaying effect of the auxiliary electrode can be advantageous. Such an igniter works in such a way that between the at least one of its characteristics: Ab rod electrode and the auxiliary electrode, a glow measurements, material properties and emission discharge set in, which heats the auxiliary electrode, determines or supports the ability of the surface but this glow discharge is not - as it will be. In this way, the temperature of the construction according to the invention - ■ passes over into an arc auxiliary electrode and thereby also the time delay discharge. Then the auxiliary electrode of the switch gives the required values according to a substantial part of its heat to the bimetal to be set. The temperature of the auxiliary electrode from the electrode, which then produces the contact in the usual manner, is hereby produced in accordance with a preferred embodiment cycle with the counter-electrode. The contact form of the invention is chosen so that its maximum temperature duration is at least 600 ° C due to the temperature at the auxiliary electrode,
Stored amount of heat extended. When glowing- Further details of the invention are explained in the drawings, in which some of the glow discharge, for example embodiments of the inventive switch according to the bimetallic electrode and the counter-electrode, are schematically illustrated.
and is only shown later on the auxiliary electrode. The drawing shows

stores, or the discharge takes place between the Bi- Fig. 1 an embodiment of the invention

metal electrode and the counter electrode as well as an extraordinary switch with a time delay that turns into a

the circuit for fluorescent lamps that is known per se between the auxiliary electrode and the counter-electrode

trode. This glow discharge then goes into an arc, with the piston of the igniter in the

discharge between the auxiliary electrode and the counter-cut is shown;

electrode over, the discharge between Bi- Fig. 2 to 5 show sections of further execution

metal electrode and counter electrode stops. According to the approximately examples, with the same reference numerals being similar

Making contact heats the auxiliary electrode, which is denoted by bimetallic 70 details.

The igniter shown in Fig. 1 has a tight electrode 14, whereby an electrical contact is closed Piston 10 with an ionizable see the two main electrodes 14 and 15 to-gas filling, z. B. Argon, which comes through a base 11 and their potentials are equal to each other werend closed is. In the base 11 are two leads. The possibly remaining glow discharge 12 and 13, which reach into the piston 10 5 between the two main electrodes 14 and 15. The igniter has two main electrodes 14 and thus extinguishes completely. Since the auxiliary electrode 16 is the -15. The main electrode 14 is a rod electrode which has the same voltage as the bimetal main electrode 15. B. consists of nickel. The other main electrode 15 has, the arc discharge between the is designed as a bimetal electrode and is z. B. from auxiliary electrode 16 and form the counter electrode iron and an iron-nickel alloy in itself ίο the main electrode 14 go out. Thus would the misunderstood Way put together. The bimetallic electrode cooling the bimetallic main electrode 15 and its removal

15 is arranged so that when exposed to a distance from the main heat forming the counter electrode against the other main electrode 14 moved electrode 14 immediately insert, if not the and comes into contact with it. When the auxiliary electrode 16 cools down due to its increased temperature, the metal electrode 15 the contact of the two 15 current temperature amounts of heat becomes another Er main electrodes 14 and 15 repealed. The igniter increases the temperature of the main bimetallic electrode 15 is also provided with an auxiliary electrode 16 which would cause the latter in its with the z. B. made of tungsten and held with the bimetallic main counter electrode 14 contact-closing position electrode 15 electrically directly, d. H. without interruption. The length of contact between the two circuit, e.g. B. of resistors, connected 20 main electrodes 14 and 15 is thus extended and is. One of its ends is attached to the main electrode- their mutual separation is delayed as this is due to closed. The other end of the auxiliary electrode 16 is the purpose of the invention.

is held in the base 11 of the igniter. In the illustrated embodiment, the lines 12 and 13 are each formed with one of the Hauptelek auxiliary electrodes 16 by a helix. They troden 14 or 15 connected. In the illustrated embodiment, the thread, a double helix, a plate, a band, an auxiliary electrode 16 is designed in such a way that its cross-section is formed as a mesh or a fabric. The cross-section less, z. B. by at least 50%, but the length of the auxiliary electrode 16 is to be interpreted as its electrically conductive greater than the corresponding dimensions of the bimetal cross-section, the main electrode 15 in the case of a thread. In this way, the auxiliary 30 of a helix or a double helix the transverse electrode 16 with the same thermal effect of a glow cut of the thread itself, with a plate or a discharge brought to a higher temperature than the bimetallic band the product of the width and the thickness of the main electrode 15. This heating takes place in the same way, and in the case of nets or fabrics as a whole, when a voltage is applied to the main electrodes 14 and 15 forming the cross section of the netting or fabric, and a glow discharge between elementary filaments is the same as a result.
see them being brought about. Since the auxiliary electrode in the embodiment according to FIG. 1 is used

16 the same potential as the bimetal main electrode switch for starting or igniting a

15, a glow discharge also occurs between known fluorescent lamps 17, the cathodes of which are marked with 18 the auxiliary electrode 16 and its counter electrode, d. H. and 19 are designated. Both cathodes 18 and 19 In the illustrated embodiment, the main 40 are designed as hot cathodes and consist of electrode 14, parallel to the glow discharge between double coils, which are known per se and desden two main electrodes 14 and 15. As a result of a manner not shown half with an electron Glow discharge between the rod electrode 14 emitting layer are coated. The cathodes and the auxiliary electrode 16 flows a current in the auxiliary 18 and 19 are on the one hand each to one of the main electrode 16, which additionally heats them. Since the 45 troden 14 and 15 of the detonator and on the other hand through Auxiliary electrode 16 is made of tungsten, it favors a ballast 20 and a main switch 21 to the the emission of electrons connected at least in the ratio terminals 22 and 23 of a network. the to the main electrode 15, so that after a certain supply lines 12 and 13, the glow discharge between the auxiliary electrode interference capacitor 24 is

16 and the counter electrode 14 are connected to one another in an arc discharge 50.

passes, whereby the resistance of the line between When closing the main switch 21 is the see the auxiliary electrode 16 and the counter electrode 14 voltage of the terminals 22, 23 through the ballast 20, is significantly lower than the resistance of the hot cathodes 18 and 19 of the fluorescent lamp 17 Distance between the two main electrodes 14 and and the supply lines 13 and 12 to the main 15. As a result, an increasing proportion of the 55 electrodes 14 and 15 of the igniter is placed, whereby the Energy of the gas discharge via the auxiliary electrode 16, the discharge between the electrical units described above the glow discharge between the two electrodes 14, 15, 16 is effected. Through the main heat electrodes 14 and 15 gradually decreases. The action of the auxiliary electrode 16 becomes the contact increasing energy flow creates a substantial amount between main electrodes 14 and 15 upright Joule heat in the auxiliary electrode 16, 60 obtained. This time is sufficient for the hot cathodes 18 which is heated to a temperature which is higher and 19 to a temperature at which than those of the main electrodes 14 and 15. By means of one for maintaining an arc discharge the bimetallic main electrode 15 will see this same sufficient amount of electrons is emitted against the main electrode forming the counter electrode.

14 bent. Your transverse movement is determined by 65. In the embodiment according to Fig. 2, the auxiliary

that amount of heat is promoted, which from the auxiliary electrode 16 completely through the supply line 13 or through

trode 16 supported by conduction and / or convection and / or the bimetallic main electrode 15. Also is

Radiation reaches her. During this transverse direction between the two legs of the U-shaped

Teten movement of the bimetal main electrode 15 reached the bimetal main electrode 15 arranged. Furthermore

its free end is the main 70 forming the counter electrode, this embodiment corresponds to the embodiment

form according to Fig. 1. Such an arrangement has the advantage that the gas discharge between the counter electrode forming the main electrode 14 and the auxiliary electrode 16 at least partially the bimetallic main electrode 15 surrounds and thereby causes accelerated heating of the same. With regard to that the auxiliary electrode 16 is held by the lead 13 or by the bimetallic main electrode 15 is unnecessary a separate pin for holding the auxiliary electrode 16 by means of the base 14, so that instead of three only two seals have to be provided.

The embodiment according to FIG. 2 operates in a manner analogous to the embodiment according to FIG. 1.

The auxiliary electrode 16 can also be arranged on the bimetal main electrode 15 in such a way that their spacing of the main electrode 14 forming the counter electrode is the largest. By such an arrangement the heating of the bimetallic main electrode 15 is also promoted.

It is also possible to provide the bimetal main electrode 15 with a coating through which the work function the bimetallic main electrode 15 is larger than the work function of the auxiliary electrode 16. Auf this way the temperature difference between these two electrodes increases and the delay increases in the separation of the main electrodes 14 and 15 even greater. Such an embodiment is for example shown in Fig. 3, where z. B. the bimetallic main electrode 15 is provided with a gold layer 27, the auxiliary electrode 16 being made of tungsten or molybdenum.

Such a coating of the bimetal main electrode 15 has the advantage that the ratio of the amounts of heat of the discharges acting on these electrodes are set and thus also the delay can be influenced in the separation of the main electrodes.

In the above-mentioned embodiments, only one main electrode was a bimetallic electrode educated. Both main electrodes can also be designed as bimetallic electrodes in the same way and arranged so that they move against each other when exposed to heat. then the heat content of the auxiliary electrode when the main electrodes touch both main electrodes and effectively delays their separation.

It is also possible to provide each bimetal main electrode with an auxiliary electrode and an additional one Achieve delay effect. Such an embodiment is shown in Fig. 4, where both main electrodes 14 and 15 are designed as bimetal electrodes and each of the main electrodes 14 and 15, respectively an auxiliary electrode 29 or 16 is assigned. When heated, the main bimetal electrodes bend 14 and 15 against each other in the manner as for the bimetal main electrode 15 of the embodiment according to Fig. 1 has been described.

The known design of both main electrodes as bimetallic electrodes has the advantage associated that the time preceding the contact of the main electrodes can be further reduced can. Furthermore, a relatively low temperature is sufficient for the two main electrodes, as a result of which the effect of the auxiliary electrode can be achieved more easily.

Finally, FIG. 5 shows an exemplary embodiment in which the bimetallic main electrode 15 is U-shaped is, wherein the one auxiliary electrode 16 is arranged between the legs of the bimetallic main electrode 15 is. The other main electrode 14 is designed as a rod electrode and is also provided with an auxiliary electrode 29, which is held at one end by the base 11. The main bimetal electrode 15 is here exposed to the heating effect of both auxiliary electrodes 16 and 29 without the Auxiliary electrode 29 is forced to have to follow the transverse movement of the auxiliary electrode 16.

ίο The additional heat content of the immovable auxiliary electrode However, when the two main electrodes 14 and 15 are touched, 29 is also applied to the bimetallic electrode 15 transmitted, thereby delaying the separation of the main electrodes 14 and 15 in addition is enlarged.

Claims (8)

Patent claims: 1. Glow Discharge Switch for igniting elekao Irish low voltage gas discharge lamps, in which apart from two main electrodes, at least one of which is designed as a bimetal electrode is, at least one of the bimetallic main electrode associated auxiliary electrode is provided as is, in which furthermore the power supply lines are ever on one of the main electrodes are connected in such a way that from the main electrode to the lead The current flowing does not flow or only partially flows through the auxiliary electrode that is connected to the bimetallic main electrode is so thermally and electrically directly connected that the cooling of the bimetallic main electrode delayed by the heat developed in the auxiliary electrode and thereby the length of time of the contact of the main electrodes is increased, characterized by such Formation of the auxiliary electrode (16) that before the contact closure of the main electrodes (15, 14) the glow discharge turns into an arc discharge between the auxiliary electrode (16) and the with it not connected main electrode (14), which up to the contact closure of the main electrodes continues as an arc discharge and by which the auxiliary electrode (16) is heated to a temperature which is higher than the temperature of each of the main electrodes, thereby creating in the auxiliary electrode (16) an amount of heat increasing the contact time of the main electrodes (15, 14) is accumulated will. 2. Switch according to claim 1, characterized in-5Q shows that the highest temperature of the auxiliary electrode (16) is at least 600 ° C. 3. Switch according to claim 1 or 2, characterized in that the auxiliary electrode cross-section is at least 50% smaller than the cross section of the bimetallic electrode Main electrode. 4. Switch according to one of claims 1 to 3, characterized in that the auxiliary electrode (16) from one of the metals tungsten and molybdenum consists, whereby their work function is less than the work function of the material B imetal main electrode. 5. Switch according to one of claims 1 to 4, characterized in that the bimetallic main electrode (15) is covered with a substance whose work function is greater than that of the auxiliary electrode. 6. Switch according to claim 5, characterized in that the coating (27) of the bimetal main electrode (15) is made of gold. 7. Switch according to one of claims 1 to 6, characterized in that both main electrodes (14, 15) are designed as bimetal electrodes and are arranged in such a way that they are at Heating in the opposite direction, d. H. bend against each other (Fig. 4). 8. Switch according to one of claims 1 to 7, in particular according to claim 7, characterized in that that two auxiliary electrodes (16, 29) are provided, each of which is thermal and electrical connected directly to another main electrode is closed, and that at least one bimetallic main electrode U-shaped and its assigned Auxiliary electrode is arranged within its two legs (Fig. 5). Documents considered: German Patent No. 829 184; German patent application A 6961 VIII c / 2.1 f, 84/01 (published on August 6, 1953); Swiss Patent No. 266 503; Austrian patent specification No. 165 822. 1 sheet of drawings © 009 587/171 8.60