DE336823C - Electric arc lamp with a closed lamp bell and electrodes made of hard-to-melt metal - Google Patents

Description

The present invention relates to an airtight closed lamp bell equipped electric arc lamp, in which the arc is in an indifferent gas atmosphere is generated between electrodes made of difficult-to-melt metal.

The characterizing feature of the invention is primarily that on the one hand the formation of the arc takes place between electrodes, one of which is in the Arranged central axis of the lamp and the second formed as an annular outer electrode is, and that on the other hand, the resulting arc has the effect of a magnetism Field is exposed and thereby set in a very rapid orbital motion.

These innovations show the advantage that

both electrodes evenly, in an unprecedented degree for generating light can be used because both electrodes are close to one another in the same plane and thus do not cover each other. The fact that the lamp for this reason is also practically a lamp is to be viewed with a point light source, also allows the arrangement of a concave mirror inside the bell, which is the outgoing from the back of the ring electrode Reflects light rays as a closed bundle of rays. Finally, through the rapid orbital movement of the arc which was previously limited to one point and therefore Very heavy wear of the electrodes distributed over the entire active surface of the electrodes and thereby their service life is extended considerably.

The invention also consists in that in a known manner by touch and subsequent separation taking place ignition either with the help of one, with one swingably fastened, provided as an electrode base serving anchor or one as Solenoid built electromagnet is run, and that all for the action of the Lamp required parts in a closed vessel made of glass, crystal or quartz are included, from which the air is removed and replaced by an inert gas. This per se known measure has the extremely significant advantage in the wake of that the gas atmosphere is well swirled by the circular motion of the arc, the speed of the arc movement is regulated and the formation of bubbles is avoided will. In addition, the light generated between the center and ring electrode is

bent into several individual arcs, all of which at the same speed and thus give the impression of a ring surface. Finally, the subject matter of the invention is characterized in that the positive electrode on a base made of carbon or graphite to prevent leakage of the enclosed gases is provided with a ίο layer of iridium, and that the one end of the electrode is provided with a capsule made of very high-melting metal, which becomes luminous in the company. The temperature of the crater zone can thereby be The purpose of a stronger light generation can be increased quite considerably, since the shape of the Electrode in spite of any softening occurring due to the infusible and its shape not changing document remains permanently secured. ao The subject of the invention is shown in the accompanying drawing in an exemplary embodiment and for comparison, some common ones Incandescent lamps shown, namely shows:

Fig. Ι the usual arrangement of the electrodes in an ordinary arc lamp,

2 shows an arc lamp with a cooled negative electrode,

Fig. 3, 4 and 5 ordinary arc lamps with tungsten electrodes,

6 shows the basic shape of a lamp according to the present invention,

7, 8 and 9 different embodiments in the attachment of the positive electrode,

Fig. 10 to 12 cutout shapes for the ring-shaped negative electrode can be used,

13 to 21 show the section of various Shapes of circular negative electrodes,

Figs. 22 and 23 are embodiments of the magnetic negative electrode holder Field,

24 shows the longitudinal section of a complete lamp according to the invention,

Fig. 25 shows another embodiment and

Figures 26 and 27 show two different circuit diagrams.

The previously known electric lamps have a number of significant disadvantages: The ordinary arc lamp or the arc lamp in a closed envelope (see Fig. 1) has two electrodes A, B, the positive elec-! Trode A emits an intense luminous flux at C according to its nature, j which is partially covered by the negative electrode by the j projection D. In addition, the electrodes are combustible, advertising ^one: the so ever smaller and make a very precise intricate automatic control required.

Things are very similar with arc lamps, which consist of tungsten electrodes in the form of two wires, two plates, a sphere and a plate or a plate and a wire (see Figs. 3 to 5), since here too the part of the Arc » C, which shines the brightest, and the point at which the arc arises on the positive electrode A is always almost completely darkened by the negative electrode B. In addition, the thread holders 5 are heat conductors, which a considerable part of the heat of the positive electrode. derive in zone F and thereby make it less luminous.

Avoid flame arc lamps and arc lamps with cooled negative ^electrode: Although these disadvantages but require inter alia a fairly cumbersome, easily be interfered operation and therefore provide a relatively very poor light output. j In the lamp, which forms the subject of the invention, the sheet C, D be- arises see 'two electrodes A, B (Fig. 6), the conductive very good bodies, usually metals, and consist only at very high temperature melt. These bodies can be made of tungsten, iridium, osmium, uranium alloys, molybdenum, etc.

The positive electrode is formed according to FIGS. 3 to 9 and has an active part T, e.g. B. made of tungsten, which is supported by a, a good conductor for the electricity and a bad conductor for the heat forming holder V.

FIGS. 6 to 9 show different embodiments of the positive electrode. The active part of the electrode, that is, the one that forms the crater, is formed by the piece T made of tungsten, osnium, etc. This piece T, which is produced mechanically or by electrolytic precipitation, rests on the base V made of graphite, carbon or another infusible substance that is not volatile in the electric furnace.

In the embodiment of FIGS. 8 and 9, nc holders are attached to the base V in order to improve the contact between the base and the piece T and thereby! to increase the temperature in the crater zone considerably, because the softening of the electrode is of no importance, since its shape is secured by the infusible and shape-unchanging base.

A small iron part R attaches the system to a base U, which is also made of iron (Fig. 6 and 7). These magnetic pieces allow the direction and lo-

calization of the magnetic field intended to cause the arc to rotate.

The supports V are covered by an electrolytic deposit of iridium (FIG. 7) so that the gas enclosed in them cannot worsen the evacuation of the lamp. Diffusion of the gases through the precipitate is prevented by the fact that during operation the pressure in the bell is somewhat higher than the external air pressure.

The negative electrode B is circular and surrounds the positive electrode A, and the arc that arises between them interrupts a magnetic field, which is indicated by the arrows (see Fig. 6). This field is coaxial with the positive electrode and the arc is therefore subjected to a magnetic coupling and rotates.

The magnetic field is formed either by a winding 19 on the outside of the lamp socket 16 (FIGS. 24 and 25) or by the spiral winding " 0 " of a tungsten filament which feeds the negative electrode B (FIGS. 22 and 23) and causes it to glow can be.

Under these conditions, point C, the positive crater, is completely free and all light that radiates from it can be used unhindered.

The negative electrode B is also brought to a very high temperature and this electrode is designed so that its cross-section is sufficiently weak and it has the profile shown in FIGS. 11 to 21. The temperature of the negative electrode can be made very close to that of the positive electrode, and thus a light can be emitted from it which is almost as bright as from the positive electrode, the light emanating from it being made uniform by the fact that the arc rotates.

Figs. 10-12 show various means for holding the circular negative electrode B. Figs. It is supported either by ears P (FIG. 10) or by a piece M (FIGS. 11 and 12) which ends in a tube L which is arranged on the support K and is formed similarly to the support V of the positive electrode.

Fig. 24 shows the lamp as a whole. The central electrode 1, which is described in the above Way is made, is here with her foot 5 made of soft iron on the Support 10 fixed by a flexible lamella 6; the arrangement is such that the electrode 1 against the electrode 2

when the lamp is de-energized. ,

The foot 5 forms the armature of an electromagnet 15 and a button 8 limits the Stroke of the armature at the moment of ignition. The negative electrode 2 will be in place held by a base 11, which like the base 10 of the electrode consists of invar, steel-nickel alloy, platinum or platinized iron, while the bell 16 is made of quartz, glass or crystal.

The holders 10 and 11 are conical and in Pipes 12 and 13 rotatable on one, in turn in the conical part 14 rotatable Bottom piece 17 are arranged and form part of the bell 16, so that a tight seal is created.

The holder 10 is designed so that his The curved part 9 forms the core of the ignition coil 15. This core ends in a pole-like one Formation 3. The coil 15 is connected in series with the arc. The current comes into the coil and goes through the carrier io, the plate 6 and the armature S to Electrode 1, from there to electrode 2 and leaves the lamp through holder 11.

The cooling of the bell 16 is through causes a sleeve with ribs 18, in the interior of which the cylindrical part of the socket is fixed is. A piece 20, which is also provided with ribs, is secured by screws 21 and serves as a cover for the cooling fins 18.

The magnetic field that is intended to cause the arc to rotate is housed in a part 19 of the piece 18 when they are outside the lamp target. The whole space between the lid 20 and the bottom piece 17 is filled with cement filled in to achieve a full closure.

The bell 16, which can be made of quartz, glass or crystal, is only freed from the air and then under suitable pressure with an inert gas or filled with vapors that make the room conductive at high temperatures. One could for this purpose in the bell some droplets of mercury or a mixture of it Use aluminum, titanium, calcium, thallium, cesium, lanthanum, lithium. This no Substances are vaporized in a few seconds when the lamp is running.

The way this lamp works is as follows: When the lamp is not under If voltage is present, electrodes 1 and 2 are in contact. As soon as you get the lamp puts under voltage, the current passes through the coil 15, the armature S is through the Core 9 ^ tightened and electrode 1 centered against electrode 2. The arc iao then arises between the two electrodes and migrates around the positive electrode, the

forms the center. A spherical mirror 7 of small diameter, the behind the positive electrode is attached, throws on .der back of the electrode 2 ent-S wrapped light back.

It is easy to understand that all of the light generated by the positive electrode is undiminished can be recovered. The same applies, of course, to the ίο from the front of the negative electrode 2 emitted light.

FIG. 25 shows another embodiment of the lamp according to FIG. 24, in which, for the magnet 15 provided for ignition is replaced by a suction magnet 22. In this Case, the positive electrode 1 is supported by a conical core 23, which is in a conical tube 24 moved, which sits inside a conical tube 25 on which the winding of the electromagnet 22 is attached. The conical core 23 is ins Inside the coil 25 drawn in and a stop 26 limits its stroke when the Power is interrupted. "A spring 27 supports this effect. At the same time it rotates the electrode 1 also around the stop 26 so that it is in contact with the electrode 2 comes.

The ignition could also be brought about by the space between the two electrodes ionized, with the help of an ionizable impregnated Thread, which would be brought to a sufficient temperature by the passage of current. The stream could be in series with the arc current and switched on and off by a relay.

FIG. 26 shows the circuit diagram of the lamp with contact ignition according to FIG. 24 and 25.

Fig. 27 shows the circuit for ignition by ionization. In this case the thread 28 to be ionized is traversed by the mains current. Through relay 29, which is in series with the arc, becomes the ignition circuit after ignition; interrupted.

The terms positive and negative electrodes are chosen for the convenience of understanding to facilitate the invention. It is also evident that the lamp described can work with both three-phase and alternating current.

Claims (3)

-Expectations : i. Electric arc lamp with a closed bell and electrodes made of difficult to melt metal, characterized in that it contains two electrodes which both emit light and consist of very high-melting metals, one of which is in the middle and the other is formed by an annular crown both electrodes are supported by infusible and non-deformable parts and the resulting arc is rotating under the action of a magnetic field that is formed by a winding that is on the outside or inside of the vessel, this magnetic field ¹ the light emission makes the positive and ¹ negative electrode equal. 2. Lamp according to claim 1, characterized in that the ignition by touch of the electrodes either with the aid of an anchor or an electromagnet built as a solenoid and all for the Effect of the lamp required parts in a closed vessel made of glass, Crystal or quartz are enclosed, from which the air is removed and passed through indifferent gas is replaced, the vessel zuir achievement of a good air cooling is surrounded by a metallic rib body. 3. Lamp according to claims 1 and 2, characterized characterized in that the positive electrode lies on a base made of carbon or graphite, which is covered with a layer made of iridium to expose the trapped in the substrate Prevent gases and cover one end of the electrode with a capsule very high-melting metal is provided, which becomes luminous. 1 sheet of drawings.