DE839390C - Furnishing with glow discharge lamp - Google Patents

Description

Glow Discharge Lamp Device The invention has a device with glow discharge lamp with low pressure gas filling to the subject.

The use of discharge lamps for lighting always takes one a greater «grounding meaning. So far, lamps have been preferred for this application used, whose cathodes therefore have a certain organ to ignite the discharge to facilitate. Devices are used to effect this ignition in such lamps used, which cause a temporary overvoltage and between the electrodes the lamp shade a sufficient voltage to the gas, the gas mixture or ionize the gas and vapor mixture in the lamp. Have such devices the disadvantage of requiring a socket for the lamp, the insulation of which the Can withstand overvoltage causing ignition.

A high pressure gas filling was also used for lighting purposes Lamps used. Such lamps have a very high efficiency and are particularly suitable for illuminating roads, railroad tracks, i.e. in the general when it is not necessary that the colors of the so illuminated Objects resemble the colors shown in daylight as closely as possible. Until now the efforts made did not give a complete result. On the other hand have the discharge lamps with high pressure gas filling the disadvantage to generate their normal luminous flux only after a tempering period of a few minutes, while. which heats the gas contained in the lamp by the discharge in this way its pressure will increase. `If a lamp of this type is extinguished after it has reached its normal working condition, one must wait until the gas in the The inside of the lamp is being cooled before it can be lit again. This state of affairs poses major disadvantages for the lighting of the habitable rooms and in general the spaces in which the necessity can exist, the lighting duels switch it on or off frequently.

The invention aims to provide a device with a glow discharge lamp to create which does not require the application of high voltages for the ignition of the lamp requests or an almost instantaneous switching on and off of the said discharge lamp enables.

For this purpose, the discharge lamp in the invention Set up at least two main electrodes between which most of the Stroms passes, and at least one inside the lamp near one of the named main electrodes used at least temporarily as cathodes Auxiliary electrode, means being provided to at least this auxiliary electrode temporarily to a positive potential with respect to the applied main electrode in this way to bring that electrons from this main electrode against the other main electrode be thrown and that the ionization of said gas filling and the ignition the discharge between the main electrodes at a lower voltage than those between these electrodes for the ignition of the discharge in the absence the voltage required by the auxiliary electrode.

The figures represent three embodiments of the invention as examples Establishment.

Fig. I, 2 and 3 are electrical circuit diagrams of one of these three Embodiments; Fig.4 is an axial section of the end of a lamp with a main electrode and an associated auxiliary electrode; Figs. 5 and 6 are explanatory Diagrams explaining two ways in which the facility works.

The device according to Fig. I has a discharge lamp i with a low-pressure gas filling. This lamp is provided with two main electrodes 2 and two auxiliary electrodes 3. The auxiliary electrodes are supplied by the same source as the main electrodes Capacitors 4 fed. The discharge circuit of the main electrode 2 is with the terminals of a circuit to be connected to an AC voltage source 6 connected. The one opposite to the electrode connected to the auxiliary electrode 3 The electrode of each of the capacitors 4 is connected to the terminal of the circuit 6, which is opposite the terminal to which the main electrode 2 is connected, next to which the auxiliary electrode 3 is arranged.

When the device is energized, the capacitor transfers 4 the alternating current to the auxiliary electrode 3, and a large increase in potential becomes during the alternating voltage peaks between each main electrode 2 and the neighboring one Auxiliary electrode 3 generated. Each main electrode is designed to act as an anode and Cathode @ to serve alternately. Because of the small distance between each main electrode and the adjacent auxiliary electrode is the gas filling of the discharge lamp in the adjacent area of these electrodes is immediately ionized, and this ionization 'is effected the ignition: the discharge between the main electrodes: the capacities are like this measured, .that this is a relatively strong at the frequency of the supply voltage have capacitive impedance. The auxiliary electrodes3 could aim to that an appreciable part of the discharge current is diverted, but thanks to the aforementioned Impedance of the capacitors 4, the current of each auxiliary electrode remains very weak. Furthermore, when a current passes through the circuit one of the auxiliary electrodes is the one emanating from this electrode and connected to the voltage duel via the discharge lamp incoming circuit almost equivalent to a resistor, so that the on the called auxiliary electrode applied voltage d'urc'h this equivalent resistance and the capacitor 4 feeding this electrode is then shifted in phase. So the one between this auxiliary electrode and the adjacent main electrode is applied Voltage reduced by the voltage divider, which on the one hand by said equivalent resistance and the capacitor 4 and on the other hand by the phase shift the voltage applied to the auxiliary electrode 3 is formed.

The auxiliary electrodes 3 are arranged inside the discharge lamp.

The device shown in Fig. 2 is different from that of Fig. i can be distinguished by the fact that each auxiliary electrode is connected to the adjacent main electrode is connected via a resistor 7. The resistors 7 are used to adjust the phase shift increase the voltage applied to the auxiliary electrodes, and make this phase shift less dependent on the current flowing through the circuit of these electrodes. This device consists of a protective capacitor 5, which in one of the Main electrodes 2 with the feed circuit 6 connecting circuit switched on is.

The operation of this facility is the same as that of the facility identical according to section i. It is noticeable that when the discharge is ignited, a significant voltage drop occurs in the protective capacitor 5. This voltage drop has the effect of the potential difference on the one hand between the main electrodes 2 and on the other hand between each of the auxiliary electrodes and the main electrodes, on which they are ever attached. The resistors 7 have the effect to reduce the value of the voltage applied to the main electrodes and the To let the point in time of the Wediselstromperiod lead in which the Sl> aitiiiiirgstintersc'liieci between each auxiliary electrode and the adjacent main electrode is maximum what it possibly enables the duration of each of the successive discharges zti enlarge.

The device according to Fig. 3 is intended to work with a direct current to work. It has only a single auxiliary electrode, which is located near the Main electrode 2 lies, which with the: \, linusltol of a finite direct current to feeding circuit q is connected. This auxiliary electrode 3 is with that of her removed main electrode via a resistor 7 and with the adjacent main electrode connected via a capacitor 4. A protective resistor io is between one of the Main electrodes and the corresponding pole of the circuit 9 switched on.

When the circuit 9 is connected to a suitable direct current source, the capacitor 4 is charged via the resistors 7 and io. When this capacitor is charged, the source voltage is applied between one of the main electrodes 2 and the adjacent auxiliary electrode 3. When this voltage has become sufficient, the discharge is ignited, and the current flowing through the auxiliary electrode 3 passes through the resistor, in which it causes a voltage drop in such a way that the auxiliary electrode 3 is carried to a potential which is the potential of the negative. Main electrode is almost the same. In this device, the resistor 7 should be in different directions than the resistors 7 of the device according to . \] ) 1). 2 can be measured. It is intended to limit the current diverted through the auxiliary electrode to such a value that the light from the discharge lamp is distributed substantially regularly along this lamp. With the protective resistor to: it also serves to limit the discharge current to a selected value, this value being selected in such a way that premature blackening of the lamp due to the precipitation of material torn from the cathode by the ions is avoided.

Abbot). 4 represents a: @ embodiment vain I-laul> telelectrode and of the adjacent auxiliary electrode, the end of the discharge lamp in which these electrodes are classified, shown as an axial section. The real one Discharge lamp consists of a cylindrical glass collx ° n i i. its bottom is executed with a; rößereii thickness and on its inside with cincin axial Projection 12 is provided.

A (- main electrode 13, soft at least temporarily as a cathode is to serve is inserted around the projection 12 '. This electrode is cylindrical and at its end opposite the projection 12 through a base 15 closed. A resistance win: dting 14; via which the electrode 13 with the Feed circuit is connected, is introduced inside this electrode and on whose bottom 15 is fixed. The discharge current flows through this winding and serves to heat the electrode 13, against which it is embedded by an embedding, from ceramic shear mass 16 existing pipe is isolated. The inner surface of the electrode 13 is covered with a coating of an alkali metal such as cesium. Under the The effect of the heat and the electric current is the cesium outside the electrode 13 diffuses and increases their electron donation capacity.

The auxiliary electrode consists of a metal tube 17, which with the Bottom of the discharge lamp i i connected by an electrical connector and at its other end has a wide inner brim. This brim forms one with the electrode 13 and the tube 17 coaxial opening, so: that from the The main electrode and its associated auxiliary electrode system consists of an electron gun forms which electrons against the other auxiliary electrode according to the direction of the Lamp axis can spin and a virtual cathode between the two main electrodes forms, whereby the real distance between these electrodes as well as that for the Ignition of a discharge required voltage difference between these electrodes be decreased.

Most of the cylindrical inner surface of the tube 17 is through a shift Mica or isolated from any other suitable insulating material, around the ignition of an arc between this part of the auxiliary electrode and: the to prevent adjacent parts of the main electrode and to prevent the Substance torn from the main electrode under the action of an ionic impact is reflected on the bottom of the discharge lamp i i. One of those nearby Ionic impact resulting from the bottom of the discharge lamp i i would reduce the insulation between the auxiliary electrode and the adjacent auxiliary electrode. the Shape of the tube 17 has the effect of the main electrode by ionic impact Torn substance: to prevent it from getting on the side walls of the discharge lamp i i. and blacken these walls. The material torn out in this way mainly beats against the inner surfaces of the pipe that are not covered by insulation 18 17 lower.

The arrangements shown in Figs. I to 3 can either have cold cathodes or indirectly heated cathodes, such as those in Fig.4. In this last case, the auxiliary electrode is connected to one of the main electrodes (Fig. I) or to the two main electrodes (Fig: 2 and 3) via the heating coils 14 contained in at least one of these electrodes. These coils then also have the effect of dampening the rough-headed waves which arise when the discharge is ignited. Such an effect could also be brought about by means of either a resistor connected in the discharge circuit or a capacitor such as the capacitor 5 in FIG. This resistor or this capacitor can be dimensioned in such a way that they limit the discharge current and form a capacitor or a protective series resistor.

The light emitted in this way and that used in the facility Current can be adjusted by means of the capacitors 4. These capacitors determine the effective voltage applied to the corresponding auxiliary electrode 3 as well as the phase of this tension. According to the rating of these capacitors and the Resistors 7 of the embodiment according to Fig. 2 can ignite the by a Alternating voltage-fed facilities arise more or less early, namely before the voltage applied to the main electrodes 2 reaches its maximum value Has.

The diagram in Fig. 5 explains how a device works like that of Fig. i, in which the phase shift of the auxiliary electrodes 3 applied voltage is relatively weak, the capacitance of the capacitors 4 is relatively strong and the main electrodes' 2 have no heating coil. The sine curve i9 represents the voltage applied to the main electrodes 2, and the broad lines represent the discharge current as a function of time. As can be seen, the ignition of the discharge lamp occurs suddenly in 2o or in 20 ', namely before the terminal voltage at the main electrodes 2 reaches its maximum value Has.

The diagram of Fig. 6 illustrates the operation of such a device for alternating current like the facilities already described, in which the on each Auxiliary electrode lagging applied positive voltage or what the same effect exercises, is shifted by more than 180 ° in advance of the point in time at which the voltage between the main electrodes is maximum, with that of this auxiliary electrode associated main electrode is negative. It should be noted that the ignition point 21 or 21 'beyond the point where this voltage maximum between the main electrodes arises. The discharge lamp has heating windings for the main electrodes, and the jagged forehead of the resulting current wave at the time of ignition becomes therefore substantially subdued.

I: s was found to be the various circuits described can be realized in this way. d'ass the discharge ignition between the main electrodes already for a tension arises which is smaller than that for which the Discharge lamp is provided. So in practice such a facility can be immediate with a feed network, e.g. B. a @ \ 'ecliselstromnetz of 220N7, can be connected, which gives a significant advantage over the known devices, which require significantly higher ignition voltages.

A device realized according to the circuit diagram of Fig. 2, whose Electrodes were similar to those of Fig. 4, with or without heating the Main electrodes by means of the 'turns 14 (Fig. 4) proven, with these turns 14 were set up in such a way that they could be short-circuited. In this Device, the length of the discharge lamp was 80 cm, the applied alternating voltage 220V, the capacitor 5 had a capacity of 2, uF and each of the capacitors 4 a capacitance of o, i, uF, the resistors 7 were not used. The ones in the Resistance turns 14 power lost was approximately 0.8 W, which is in proportion with the full consumption of the lamp of 9 W is hardly to be accepted.

If the devices described are supplied with alternating current, then, in order to adjust their light emission, they can be controlled by that one acts on the voltage applied to each auxiliary electrode at any moment. Depending on the dimensions of the capacitors 4 in Fig. I and 2 and the resistors 7 of Fig. 2 one can see the amplitude and phase of the applied to the main electrode Change voltage and thereby the ignition timing between a point proportionally close to the point in time that the voltage between the main electrodes becomes zero, and an adjacent point in time close to the point in time that this voltage passes through goes through its maximum, fluctuates. One can get similar results using DC voltages which are used to polarize the auxiliary electrodes with respect to the main electrodes to serve.

By means of known phase shifters or current surge generators' can relatively large voltages are applied to the auxiliary electrodes, whereby these Electrodes in relation to the neighboring auxiliary electrodes become positive, depending after the voltage between the main electrodes has reached its maximum value. The discharge lamp can thus be ignited after the specified maximum and the duration of the current surges through the discharge lamp is still considerable be decreased. The diagram in Figure 6 explains this latter mode of operation.

Claims (4)

PATENT CLAIMS: i. Facility with a glow discharge lamp Low-pressure gas filling, characterized in that the discharge lamp with at least two main electrodes and at least one auxiliary electrode is provided in such a way that Most of the current passes between the main electrodes and the auxiliary IA trolleys iiii Inside the discharge lamp close to one of the above, at least temporarily 'main electrodes serving as cathodes are built in, with -means being provided, around said auxiliary electrode to a positive one compared to the adjacent main electrode To bring potential at least temporarily so that electrons from this Main electrode after the other »main electrode are thrown, and that one ionization of the gas filling and ignition of the discharge between the main electrodes be effected, at a smaller voltage than that which between to apply these main electrodes to this discharge in the ancient being to ignite the auxiliary electrode. 2. Set up with a glow discharge lamp after Claim i, intended to be fed from a vain electrical network, characterized in that the distances between the auxiliary electrode and the main electrodes, the pressure of the gas filling and the arrangement of the means mentioned are selected in such a way that that the voltage required for the initial ignition of the device is less than the voltage of the network mentioned. 3. Establishment with a glow discharge plan according to claim i and 2, provided to be fed from a direct current network be characterized in that it has two main electrodes and one love the one that is used as a cathode and is connected to this electrode via a capacitor connected auxiliary electrode is provided. .I. Setup with a glow discharge magnifying glass according to claim i and 2, provided to be fed from an alternating current network to be characterized in that it alternates with two as anode and cathode each serving main electrodes and two auxiliary electrodes, each of which is adjacent one of the main electrodes arranged and with the other main electrode via a Capacitor \ -erbuii, deli is. 5. Establishment of finite corona discharge lamp according to claim i and 2, characterized @gekeiinzeichuct that the auxiliary electrode with the a latile tele electrode over a capacitor and with the other latiptelectrocie connected via a resistor. 6. Finite establishment of a glow discharge lanily according to claim i and 2, characterized in that it is provided with at least one resistor is provided, which is between at least one of the main electrodes and the feed network is arranged in series and in addition dielit, which occurs when the discharge is ignited to dampen the resulting sclirottstirlwaves. 7. Device with a glow discharge lamp according to claim 1, 2 and 6, characterized in that said resistor in the main electrode and also serves to heat it in order to emit radiation of electrons from this electrode to enlarge. b. Device with a glow discharge lamp according to claim i and z, characterized in that it is provided with a protective resistor is provided, the task of which is to limit the discharge current, and which between one of the main electrodes and the feed network in series is switched on. cg. Device with a glow discharge lamp according to claim 1, 2 and .I, characterized in that they are provided with a protective capacitor whose task is to limit the discharge current and which at to dampen the abrupt waves of the discharge ignition, whereby the called capacitor between one of the main electrodes and the supply network in series connection is switched on. ok Device with a glow discharge lamp according to Claim i, characterized in that said auxiliary electrode adjoins said Main electrode comprises such that it forms with this an electron gun such that to emit a beam of electrons in the direction of the other main electrode and thus forming a virtual cathode between said main electrodes. i i. Device with a glow discharge lamp according to claims i and io, characterized in that that the main electrode and the associated auxiliary electrode are cylindrical and coaxial and the auxiliary electrode is one opposite a bottom of the associated main electrode inner rim with opening on the side of the other main electrode such that the one torn from the main electrode by ionic impact Fabric is prevented from falling on the side walls of the lamp. 12. Establishment with a glow discharge lamp according to claims i, io and i i, characterized in that that @ at least part of the cylindrical inner surface of the main electrode from the associated main electrode is separated by an insulating layer such that the Ignition of an arc between adjacent parts of the lamp wall of the aforesaid mutually associated electrodes is reduced. 13. Device with a glow discharge lamp according to claims i and io, characterized in that the main electrode is hollowed out and is covered on the inside with a coating of an alkali metal, which is intended to diffuse through the walls of said electrode and their To increase electron emissivity. 1. 4. Set up with a glow discharge lamp according to claims i, io and 13, characterized in that said alkali metal Cesium is. 15. Set up with a glow discharge lamp after Claim t and 9, characterized in that the discharge current flows through a Resistance inside the main electrode is arranged to heat it, and on the one hand with this electrode and on the other hand with a power source and a a capacitor electrically connecting an auxiliary electrode to said main electrode connected is.