DE2530076A1 - THORIUM OXIDE-YTTRIUM OXIDE EMISSION MIXTURE FOR DISCHARGE LAMPS - Google Patents

Description

Thorium Oxide-Yttria Emission Mixture for discharge lamps

High intensity discharge lamps such as high pressure mercury and metal halide vapor lamps have proven to be valuable light sources. Even if you are a relative high efficiency in lumens / watt can be expected from these lamps, start-up and service life have remained a problem and in the in general, a high voltage is required to start the electrical discharge.

Substantial efforts have been made in attempts to increase the voltage required to establish the arc reduce. The thermionically emitting tungsten electrodes that

509887/03 / ₊ G

Used in most discharge lamps have a coating of an emission material in the form of a refractory powder mixture to reduce the work of starting the arc at a lower voltage. The process of lowering the starter voltage by applying less work materials to the electrode surface is known as "activation" and there is much literature on cathode activation in theory and practice. With regard to the cathodes of the discharge lamps in question, the literature includes the following publications: ES Rittner, Philips Res. Reports, 8, 184 (1953); JM. Lafferty, J. Appl. Phys. 22, 229 (195O; DM Speros, J. Electrochem. Soc, 106 _} 791 (1959).

The search for better electrode activation materials has continued unabated. The rare earth oxides including ThOp and YpO ^. have been used separately or together as an emission mixture in high intensity discharge lamps because of their low work function, low vapor pressure and their chemical compatibility with the lamp components and arc materials. Certain metal halide lamps containing NaI, TlI and InI as arc materials used a mechanical mixture of ThOp and ^ν ₂ ° 3 ^{with four} rare earth oxides for the activation material. Such a mixture containing six mechanically mixed oxides was unsatisfactory and, in fact, less satisfactory than ThO ₂ alone. According to US Pat. No. 3,530,327, the rare earth oxides are most useful in high intensity discharge lamps in which the halides of the same rare earths are used as arc materials, that is, as the materials through whose vapors the arc discharge takes place. In all of these previously known cases, a rare earth oxide or a mechanical mixture of one or more of these oxides (including ThOp and YpO _7. ) Has been used as the emission mixture.

According to the invention, a solid solution of yttrium oxide Y ₃ O _{3 is created} in the lattice of thorium oxide ThOp, with one of the

509887/0346

9530076

like material forms an improved electron emission material with improved retention and constancy of color rendering when used for electrode activation in metal halide lamps. The amount of Y ₂ O. can range from a small amount effective in improving the emission characteristics up to about 50 mol%. It has been found that the range of 5 to 20 mole percent of Y ₃ O dissolved in ThO _{2 is} optimal.

The invention will now be explained in more detail with reference to the following description and the drawing of an exemplary embodiment.

Figure 1 is a side view of a metal halide lamp in which the electrodes of the discharge tube are connected to a Emission mixture are activated according to the invention.

Figure 2 is a graph showing the conservation (lifetime) compares lamps according to the invention with conventional lamps that use thorium oxide for electrode activation use.

Figure 3 is a graph showing the conservation (lifetime) of the lamps according to the invention with those lamps that have a mechanical mixture of use six oxides.

Figure 4 is a portion of a CIE hue diagram showing the compares the operational color line of the lamp according to the invention with a conventional thorium oxide activated lamp .

The emission material according to the present invention is a solid solution of Y ₂ ⁰ ^ t ^{in the} ThO lattice, which can be prepared as follows:

Appropriate amounts of Y ₂ O and Th (NO ^) ₁ , 4H "0 are weighed out and the mixture is dissolved in dilute nitric acid.

509887/0346

Th (NO _7. ) ^ · 4HpO is soluble in water at room temperature, whereas YpO .. dissolves in warm dilute nitric acid. The two materials can be dissolved separately and the solutions mixed later. The mixed solution should be frozen in a refrigerator for several hours. The metal ions (Th, Y) can now be excreted as oxalates by slowly adding a supersaturated solution of oxalic acid to the frozen nitrate solution, which is kept in an ice bath. The nitrate solution should be stirred constantly so that the oxalates do not form lumps. The precipitate is then filtered, washed well and dried at 120 ° for several hours. The fine precipitation, contained in a platinum crucible, heated to oxides at 900 ⁰ C

for several hours. The cooled oxide mixture is now ground, mixed and heated again at 1500 ^° C. for 3 to 4 hours.

The material resulting from the above manufacturing process shows only one phase in an X-ray diffraction analysis, namely ThOp solid solution. It is known that the solubility of Y ₂ ° 3 ^{in Tn0} ₂ ~ ^Gi ' ^{fcter increases with the} last sintering temperature (V. Subbarao et al, J.Amer. Ceramic Soc, Vol. 48, No. 9, 1965). Thus, at 150 and 1600 ° C., about 12 and 20 MoI-Ji Y ₂ O can be dissolved in the ThO ₂ lattice.

The resistance of the ThO “emission begins to improve as soon as the smallest amount of Y ₃ O is inserted into the lattice. Thus, the amount of YpO- can range from a small amount effective to improve emission characteristics to about 50 MoX-Jt, which is the largest amount that can be practically incorporated into ThO2. Depending on the fineness of the grinding, the intimacy of the mixture and the reaction time and temperature, less than all of the Y ₂ O can go into solid solution in the ThOp. In this case, the resulting material is a mixture of Y ₃ ⁰ ^ ^{unii e} ^ ^ne solid solution of Y ₂ O, in ThOp. The last material has the improved characteristics. It has been found that the range of 5 to 20 MoI-JS Y ₂ ° 3 dissolved in ThO ₂ is optimal as a single phase solid solution.

509887/0346

To activate an electrode, the sintered material is mixed with acetone, alcohol or another organic binder to a slurry and ground for several hours to form a homogeneous suspension of suitable particle size. The metal electrode is coated with the emissive material by immersing it in the suspension to a predetermined depth; then it is dried and loose emission material is brushed off. The amount of emission material on the electrode surface varies according to the sizes of the lamp (power). the arc chamber of the cathode, etc., and it can be adjusted by controlling factors such as the density of the suspension and the particle size. The organic binder is burned out and the electrode is degassed by being ^{burned and sintered in a vacuum in the temperature range from 1200 to 1900 0} C before it is inserted into the arc tube.

FIG. 1 shows an otherwise conventional metal halide lamp 1 of 400 watts, in which the improved emission material according to the invention can be used. The lamp comprises an outer glass envelope 2 in which an arc tube 3 made of quartz is contained with electrodes 4 and 5 which are sealed at opposite ends. The arc tube contains an ion. ¹ ^ i heritable filling, such as mercury, sodium iodide, thallium iodide, indium iodide and an inert starter gas such as argon. As shown in the figure, the electrodes can consist of two layers of tungsten wire windings over tungsten shafts 6, 7, which are connected to the lead-in conductors 8, 9 by the usual molybdenum foils. The electrodes are coated with the ThO ₂ -Y ₃ O., Emission mixture, which, as desired, also fills the spaces between the turns in the two layers. The lead-in conductors of the arc tube are connected to outer conductors 10, 12 which are sealed by the compression seal 12 of the glass holder 13 of the outer bulb 2. The outer conductors, in turn, are externally connected to the contact surfaces of the screw base 14 which is attached to the neck end of the piston.

509887/0346

Metal halide lamps using the emission material according to the invention show a better life and a higher efficiency than the known lamps. In Figure 2, the solid line 20 represents the life of 400 watt lamps as shown in Figure 1, using the ThO ^ -Y 0 emission material according to the invention, while the dashed line 21 shows the characteristics of comparison lamps, the pure ThO _? use as emission mixture. Many other high intensity discharge lamps are described in the literature and the ThO · YpO, material according to the invention can be used as a long term source of thermionic electrons in these lamps.

In FIG. 3, the solid line 22 shows the service life of the 400 watt lamps as shown in FIG Emission mixture is used according to the invention. In comparison, the lamp life is comparable to that mentioned above mechanical mixture made of six oxides are represented by the dashed line 23.

In addition to the extended life, the emission material shows according to the invention also an improved color and a lower shift in the color rendering of lamps that use the use emission material according to the invention. In Figure 4, which is an excerpt from the 1931 Commission Internationale d'Eclairage Is the hue diagram, the solid curve 24 represents the color output with the life of a lamp that produces the ThO · YO, emission mixture is used, while the dashed curve 25 shows the characteristics of a conventional lamp using / pure ThOp represents. The numbers in brackets next to the points indicate the service life in hours at these points. It can be seen that the lamp according to the invention has less displacement Has reversal in color from 100 to 4000 hours and less in color from 4000 to 8000 hours. The change in the lamp according to the invention also tends to be parallel to the black body line, which is a desirable characteristic is.

509887/0346

Claims (6)

Expectations 1./Electrode for an arc discharge device with a - 'highly heat-resistant metal substrate, characterized by an electron-emitting material carried on the metal substrate, which has a solid solution of YpO- in ThO ₂ , 2. Electrode according to claim 1, characterized in that the proportion of YpO is in the range from a small amount which is effective for improving the emission characteristics to about 50 MoI-JS in ThO ₂ . 3 · Electrode according to claim 2, characterized in that the proportion of YpO, in the range from 5 to 20 MoI-? is in ThO ₂ . Ii. Electric high-pressure discharge lamp with a translucent bulb in which electrodes made of highly heat-resistant metal are sealed at opposite ends and which contains an ionizable medium such as mercury, metal halide and an inert gas at low pressure, characterized in that an electron-emitting material is carried on the electrodes , which has a solid solution of Y ₂ ° 3 In ^Tn0 ₂ . 5. Lamp according to claim 4, characterized in that that the electrodes made of heat-resistant metal have tungsten windings around a tungsten shaft are wiggled, and the electron-emitting material is coated on the turns and arranged in the spaces between the turns. 6. Lamp according to claim 4, characterized in that net that the ionizable filling sodium, thallium and Includes indium iodide. 509887/0346