DE967658C - Vapor discharge lamp - Google Patents

Description

For lamps for the generation of visible light and UV radiation one has so far in the Practice uses gas discharge tubes that contain vapors from highly volatile metals - in particular Mercury and cadmium ■ - or a filling of noble gases, and also contain hydrogen. For the application is of particular interest depending on the deretni purpose a restriction on the broadcast Energy on certain spectral ranges in the visible or in the ultraviolet region; The aim is therefore to aim for radiators that are as selective as possible.

In addition to the appropriate spectral distribution, it is important that the energy supplied is largely removed from the discharge path as radiation and only to a minor extent by conduction or convection ^:. Care is therefore taken to ensure that the absolute emissivity is as high as possible.

The discharge lamps mentioned at the beginning correspond the. not yet mentioned claims sufficient by the emission in the spectral regions of interest compared with the emission in the other spectral ranges and the loss through thermal conduction and! Convection, too is low; for example, send the well-known Ouecksilberhochdrueklatnpen in the pigment-forming UV-A (315 to 400 ηιμ) only about 6% of the supplied Performance from and in the visible. Spectral range about 12%. The loss through conduction and convection is around 75%; the

The main reason for this lies in the concentration of the radiation on a few lines and their intensity it cannot be increased at will with increasing gas density.

The present invention is now based on the object of creating gas discharge vessels, which avoid the disadvantages mentioned.

It is also in particular the task of a vapor discharge lamp with a ίο strong emission to create that as a light source in the visible and in the UV spectrum with a sun-like spectrum Spectral curve is suitable. So far, you have a spectrum that is approximately similar to that of the sun produced with the xenon lamp, which is uncomfortably high for practical use Pressure of about 40 atm. needed.

The invention solves the problem by adding oxides or halides to the discharge vessel or mixtures of oxides and halides of ao metals of the secondary series of VI. and VII. group as well as metals of Group VIII of the Periodic Table are filled in, namely in such Amount that they eiinen at the wall temperature of the discharge vessel to produce a Pressure above 50 Torr have sufficient vapor pressure.

Discharge vessels equipped with electrodes are generally used for carrying out the invention for application, since an electrodeless excitation with high frequency in practice is cumbersome and expensive.

The invention thus achieves its task by "adding oxides or halides to the discharge vessel of metals of the secondary rows of the VI. and VII. group as well as of metals of the VIII. group of the periodic table in which to generate a vapor pressure above 50 Torr fills the required quantities when the lamp is operating. While the connections, as studies have shown, on the wall of the discharge vessel at the temperatures prevailing there are stable, is in the hot gas discharge core, whose temperature is due to the electrical current output is maintained, enough atomic substance for the emission of the atomic spectrum of the metallic component present. The metals mentioned are characterized by the abundance of electrons of the unsaturated outer electron shells and thus result in an extraordinary line-rich spectrum. Your lines are widened so much with increasing pressure that a sun-like spectral curve can easily be achieved. The relationships here are significant cheaper than the numerous other metals and noble gases, for example with the xenon, whose outermost electron shell is saturated and stable.

Thereby, a gas pressure for the area of existence is not created by means of more or less unstable connections generated by a few millimeters, but it is a matter of 'pressures above' 50 Torr for the high pressure area to generate during technical operating hours. The high pressure discharge is of particular advantage because the size of the discharge vessels is suitable for most applications a certain level should not be exceeded and one should not be exposed to low pressure in a discharge vessel limited size can not achieve sufficient radiation intensity. This differs the new discharge lamp from the arrangements in scientific investigations brief electrical discharges to study the spectra of the elements for which no radiation-related aspects are used.

When using, for example, quartz glass as the envelope of the discharge vessel, " the oxides or halides of the metals mentioned are filled in in such an amount that with consideration on the quartz glass envelope possible temperatures up to about 8oo ° C the operating pressure above of 50 Torr.

The filling with oxides or halides of metals of the secondary rows of the VI. and VII. Group as well as from metals of VIII. Group of the periodic table distinguishes the vapor discharge lamp of the invention from previously described vapor discharge lamps, which also contained a filling of compounds, but which served different purposes. In order to avoid the lack of red lines in mercury vapor lamps, salt vapors, namely zinc chloride ¹ , zinc bromide, aluminum chloride and titanium chloride, have been used in place of mercury and thus the spectral emission of metals of groups II to IV of the periodic table evaluated.

If in certain cases in the practice of the invention the equilibrium is also in If the edge zone lies too far on the side of the connecting components, the decomposition can be prevented hold back by increasing the proportion of the compound partner of the spectrally active substance, by increasing the concentration of oxygen or halogen or both. An excess This is where plasma-free metal is formed as a result of the precipitation of the excess metal Parts of the vessel, i.e. at a point that is harmless to the emission of light by the radiation.

A few examples are given to illustrate this.

With osmium tetroxide of 50 Torr with the addition of 10 Torr of oxygen, an extremely linear UV spectrum is obtained, which has practically constant energy down to almost 220 πιμ and in UV-A has the same radiation output per cm of discharge space as the usual high-pressure mercury lamp. In addition, there is a strong continuity in the long-wave UV and in the visible, which gives the discharge a sun-white appearance. With molybdenum oxide (MoO ₃ ) and rhenium heptoxide, the same can be achieved in the visible and long-wave UV.

So these substances show the sun-like continuum. In all of these cases the intensity of all lines increases with increasing vapor pressure considerably.

In a similar way to the oxides, the halides of the metals of the secondary series of the VL to VII. Group as well as the metals of VIII. Group of the Periodic Table. Even in general, the highest valence levels of the elements concerned come into consideration, that is, the priority levels that correspond to the group number of the element in question. Of the halides, those above all have proven themselves

ίο Chlorides, but also the other halides. It is also advisable to use compounds of the metals mentioned, which are two different at the same time Contains halogens.

The iodides have the advantage that they contain electron-emitting substances for activation of the electrodes are located, so that in this case there is an interaction between activated Electrode and the connection partner need not worry.

so mentioned are, for example, of the halides of group VIII of the Periodic Table Halides of platinum metals and of metals of the secondary series of the VI. Periodic group Systems also use the purple chromium chloride.

In the case of halides, too, the surprising observation was made that compounds for which, from the chemist's point of view, one should expect complete decomposition at the high plasma temperatures that Can dose quantities so that a state of equilibrium with a sufficient proportion of the volatile Connections is achieved. Here, too, the Reactants establish equilibrium.

The usual ignition aids can be used to initiate the discharge, for example Auxiliary electrodes and additional filling of an inert gas. In many cases, however, it is enough the connection partner of the spectrally evaluated element supplied in excess, i.e. the Oxygen or halogen.

The known, high-temperature-resistant metals, such as tungsten, and are suitable as electrodes Semiconductors, such as carbides and oxides, the emission being activated by substances known per se will. Activated alkaline earth electrodes are often activated by the connection partner in their Impaired effect. One then has to deal with the weakly emitting effect of the non-activated Oxyds content. As already mentioned, there are also activators, such as iron iodide, which are found in are stable in the atmosphere of halides and halogens.

The discharge vessels of the invention preferably consist of quartz glass or optionally the other temperature-resistant materials known for discharge vessels, in particular high-melting glasses.

For the shape of the vessels one chooses either the known tubular shape or in cases where the high gradient of the discharge results in a short discharge and an excessively large power per unit length causes the spherical shape. The choice of the diameter of the discharge vessel can also influence the intensity distribution in the spectrum as desired when the molecule is in individual parts of the spectrum has selective absorption.

When the natural air cooling of the vessel shape is not sufficient to achieve the required operating temperature and to produce the vapor pressure, the discharge vessel is cooled in a manner known per se. If the temperature is too low, the colder parts of the discharge vessel are thermally insulated.

By regulating the temperature of the wall of the discharge vessel, so in particular by the Choice of cooling conditions and heat insulation as well as choice of vessel shape and -size - ■ a smaller surface becomes hotter than a larger one, all other things being equal you have it in hand, the operation to a high pressure, possibly even extremely high pressure discharge to increase.

In summary, one can see how the selection of compounds of the metals of the secondary rows the VI. and VII. Group as well as the metals of VIII. Group of the Periodic Table of Circle of elements that are responsible for the spectral excitation in the visible and especially in the UV range in Come into consideration, can be expanded so that one can in particular the line-rich spectra of these Can evaluate elements that are equivalent to a continuum in their application.

According to the invention, special uses are made for the various ranges of the UV spectrum Advantage of the oxides and halides of ruthenium, rhodium, palladium, cobalt, nickel, Rhenium, molybdenum and also iridium, osmium, platinum, chromium and tungsten in the for Generation of a vapor pressure above 50 Torr when operating the lamps required quantities. If necessary, mixtures of compounds of different metals are used.

As far as the visible spectrum is concerned, it becomes white depending on the conditions Creates light and light of a certain color; by combining compounds of different Elements can be added to the spectral ranges in the required way.

A number of the elements mentioned show up particularly in the visible spectrum and in the long-wave UV at higher vapor pressures a strong, continuous spectrum, so that these elements come into consideration as an economical light source for pure white light. You have such a simple process to generate a spectrum similar to that of the sun.

In the case of some emitting elements that are of low volatility, partial condensation can occur as an aerosol, which then results in a desired Strengthening the continuum causes. The element then takes on the same role as the finely divided one Carbon in a glowing flame. In the colder parts of the discharge vessel then transferred the element back into the connection.

If the critical temperatures are exceeded in individual areas of the discharge or Dissociation occurs, this does not change anything in the preceding statements if it is then even in the strict sense of the word, not with steam but with gas discharge lamps has to do.

In the drawing is an example of a vapor discharge lamp of the present invention, for

ίο Half in section, shown schematically. In the Quartz pistons are through the foil seals 2, the power supply lines are brought up to the electrodes 3. The discharge space 4 is filled with one of the above compounds according to the examples given.

Claims (4)

Patent claims: i. Vapor discharge lamp, characterized in that to achieve a strong spectral Emission oxides and / or halides of metals of the secondary series of the VI. and VII. Group and metals of Group VIII of the Periodic Table, in particular compounds of the type mentioned in the highest valence level of these metals, in the discharge vessel are filled in such an amount that they are at the wall temperature of the discharge vessel, which is optionally regulated by cooling or thermal insulation, one have sufficient vapor pressure to generate a pressure above 50 Torr. 2. Vapor discharge lamp according to claim 1, characterized in that when using a compound which is in the colder part of the Discharge space is not stable, a sufficient excess of the stabilization Connection partner of the metal is added. 3. Vapor discharge lamp according to claim 1 or 2, characterized in that as electrodes Semiconductors are used. 4. Use of vapor discharge lamps according to claim 1 to 3 ails light sources in the visible and / or UV spectrum with a sun-like spectral course. Considered publications:
German patent specifications No. 288228, 656921. 1 sheet of drawings © 7 (S792 / 74 11.5T