DE1539510C3 - Process for the production of halogen incandescent lamps with a bromine circuit - Google Patents

Description

The invention relates to a method with the features mentioned in the preamble of the main claim, how it z. B. from BE-PS 6 66 972 is known.

There are thus also incandescent lamps known whose bulb filling from noble gases contains an addition of bromine contains. With the help of this addition of bromine, a cycle takes place inside the lamp during operation the tungsten particles evaporated from the luminous element and otherwise deposited on the bulb wall converted to gaseous wolf ambromide at the operating temperature of the lamp vessel and again be transported back to the luminous body. The tungsten bromides decompose on the hot filament back to free bromine and tungsten, which is deposited on the luminous element. Light bulbs with the addition of bromine to the filling gas show no blackening during their entire service life, their luminous efficiency remains almost constant during its operating time (BE-PS 6 66 972).

It is difficult to give the filling gas the amount of bromine necessary for the cycle process described in elemental Add form. It is therefore already known to add bromine-containing compounds that can be easily added to the filling gas and only to make the bromine free from these compounds inside the lamp. Especially For this purpose, compounds are suitable which, through thermal decomposition on the hot luminous element, die deliver free bromine. Such compounds are, for example, brominated hydrocarbons such as dibromomethane. These substances already have a considerable vapor pressure at normal temperature, they can do without Difficulties are measured in the desired amount and mixed with the filling gas.

In the course of the manufacturing process for these incandescent lamps with bromine added to the filler gas, the filler gases are also added 5 'the admixed bromine-containing compounds and filled into the lamp bulb at the desired pressure. After the lamps are closed by melting the filler neck, they are put together bromine-containing compounds introduced with the filler gas when the luminous element is put into operation decomposed. The bromine-containing compound dissociates into elemental bromine and Hydrogen, furthermore elemental carbon is deposited. At least some of the carbon can be deposited on the tungsten filament and form a carbide there. the However, the formation of tungsten carbides on and in the luminous element is extremely undesirable, since this results in embrittlement of the luminous element.

Furthermore, incandescent lamps are known that contain blackening-preventing, halogen-containing getter substances, like silicon tetrafluoride or salts of silicofluoric acid, included (FR-PS 6 87 021).

It is the object of the invention to avoid the embrittlement of the luminous element due to the formation of carbide.

This task is performed in a process for the production of halogen incandescent lamps with a bromine circuit, in which the bromine with the help of thermal decomposition of a metered amount added to the filling gas bromine-containing compound is released, solved according to the invention in that the fill gas brominated Silanes are added. Dibromosilane is particularly suitable for this.

In the manufacture of incandescent lamps, after the filling gas has been introduced, with the addition of for example Dibrovnsilan in the lamp bulb and closing the bulb by melting the The filler neck of the filament is heated by the passage of current. The added is on the hot luminaire Dibromosilane decomposes, whereby elemental silicon is deposited and bromine and hydrogen or To be released hydrogen bromide. The elemental silicon is deposited on the built-in parts in the lamp bulb and also on the inner wall of the piston. When the silicon is deposited on the luminous element, tungsten silicides can form form. In contrast to tungsten carbides, however, tungsten silicides do not cause embrittlement of the filament. The service life of the incandescent lamp is therefore not adversely affected.

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of krypton or a mixture of krypton + argon or krypton + argon + neon equal or it contains more than 30 volume percent krypton and equal to or less than 70 volume percent argon. The following basic gas mixtures have been proven to be advantageous:

a) 40 percent by volume krypton + 40 percent by volume argon + 20 percent by volume neon

b) 30 percent by volume krypton + 70 percent argon by volume

c) 40 percent by volume argon + 60 percent by volume neon

In addition, the light output, operating voltage and re-ignition peak are independent of the basic gas filling due to the special shape of the discharge tube, in particular a dimple tube influence.

In Fig. 1 of the drawing, an embodiment of a sodium low-pressure discharge lamp is illustrated.

F i g. 2 shows the dependence of the running voltage as a function of the power consumption for various Basic gas fillings;

F i g. 3 illustrates the dependency of the re-ignition peak in the luminous flux maximum as a function the gas composition;

F i g. 4 shows the dependence of the luminous flux in the luminous flux maximum as a function of the filling pressure and

F i g. 5 the course of the luminous efficacy in the luminous flux maximum as a function of the filling pressure;

F i g. 6 illustrates the dependency of the light yield in the luminous flux maximum of different basic gas fillings.

The sodium low-pressure discharge lamp according to FIG. 1 consists of a discharge burner 1 with the holder 6, the foot 7 and the outer bulb 2. The discharge burner tube 1 has depressions or dents 3 transversely to the longitudinal axis, which are arranged practically evenly over the entire length, alternately offset by 180 °. Oxide coils 4 are provided as electrodes. The pump tube 5 is used to evacuate and fill the discharge burner t with sodium metal and with basic gas. The ends of the discharge tube 1 are resiliently supported by the holder 6 against the outer bulb 2 and the foot 7. At the same time, the holder 6 serves to fasten the getter rings 9. The foot 7 in turn has, in a known manner, a pump tube 8 through which the outer bulb 2 can be evacuated. To a vacuum of 10 ^-3 to maintain during operation of the lamp to 10 ~ ^5, a sufficient supply is provided to getter materials in the getter. 9 As the pressure in the outer bulb 2 increases, the thermal insulation deteriorates, as a result of which a shift in the luminous flux maximum to higher power consumption and thus a reduction in the luminous efficiency can occur. At an initial pressure of around 10 ~ ³ Torr, the getter's action results in a pressure equilibrium at around 10 ~ ⁴ Torr after around 1000 burning hours. The outer bulb 2 has an IR-reflecting layer 10 made of SnO2 on its inside, which is interrupted at It in order to reliably exclude electrolysis phenomena on the discharge tube. At the ends of the outer bulb 2 there is a zone free of SnCh in order to ensure a perfect fusion of the foot 7 with the outer bulb 2.

From the curves in Fig. 2, in which the position of the Luminous flux maximum is marked by dots, two characteristic dependencies can be seen. On the one hand, the operating voltage increases in the luminous flux maximum from krypton via argon to neon.

In the case of two-component mixtures, the mixture with the higher proportions of lighter noble gas also the higher operating voltage. In general, the operating voltage of a mixture between the operating voltages of the components. on the other hand

ίο teach the determined curves that when operating the Lamp below the maximum luminous flux, the operating voltage increases in any case. That is with it explain that as a result of the reduced power consumption, the temperature of the discharge tube and thus the Na vapor pressure drop. It has been found that the increase in the running voltage has the following characteristic differences having. With a large proportion of krypton, the increase in the burning voltage is very flat, at Argon steeper and, with a large amount of neon, very steep. the

ίο Burning voltage curve with reduced power consumption can therefore be flattened with base gas mixtures by higher Krypton additions, such. B. from the Curves for the mixtures Kr / Ar / Ne (0/100/0), (20/50/30) and (40/0/60) can be seen. From these Experimental results follow as a teaching for the practical implementation that a basic gas mixture is to be selected the use of which the operating voltage depends only on the power consumption of the lamp little changes.

In FIG. 3, Uss, that is the voltage difference measured between the re-ignition peaks of both half-waves, is plotted for the gas composition of Kr over Kr + Ar mixtures over pure Ar and finally over Ar + Ne mixtures to pure Ne. The lamps were operated on matched chokes without capacitances connected in parallel with about 220 V supply voltage for the mixtures containing krypton or with about 380 V for the other mixtures at maximum luminous flux. The maximum of the re-ignition peak occurring during the start-ups is shown in dashed lines.

If the lamp is to be started with a glow starter, then this is the run-up maximum in particular the re-ignition tip determines the operational safety of the lamp. Also from these test results it follows that only mixtures with a significant krypton content are suitable for this mode of operation. But it is notes that the absolute value of the re-ignition peak is also determined by the dent depth that the However, the course of the re-ignition peak as a function of the gas composition at a given dent depth preserved.

From Fig. 4 it can be seen that with the basic gas mixtures of Kr / Ar / Ne like (0/1/99), (2.7 / 7.3 / 90) and (0/30/70) the luminous flux maximum between 2 and 6 Torr lies.

From Fig. 5 it can be seen that with the examined gas mixtures Kr / Ar / Ne like (0/30/70) and (0/1/99) the maximum of the light output is also at filling pressures between about 2 and 6 Torr results.

From Fig. 6 it can be seen that the luminous efficiency in the luminous flux maximum for a lamp with 200 W power consumption with decreasing krypton content increases. In neon-argon mixtures, the light output is higher than in krypton-argon mixtures, and at a mixture of about 90% Neo.i + 10% Ar shows a maximum. It therefore makes sense no more

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To mix in Krypton than for reasons of operational safety necessary is. The requirements for good ignition, reliable start-up, high luminous flux and high Luminous efficacy therefore requires a compromise in the choice of the basic gas mixture.

As a result of the inferred from the experiments Findings, for example, an advantageous 200 W sodium vapor lamp was developed, its discharge tube with a diameter of 38 mm and a total length of 1200 mm has forty dents and In addition to the Na filling, it has a basic gas mixture of Kr / Ar / Ne such as (40/40/20). This lamp needed a current of about 2.2 Amp. and with a power consumption of 200 W results in a luminous flux of 29 klm. Because of its electrical properties, it can, as already mentioned, be used in a choke-glow starter circuit operate. The composition of the gas mixture ensures that the Because of the same, the lamp remains operationally reliable even with undervoltage in the critical start-up phase It can measure length together with fluorescent lamps of 1200 mm length in mixed light lamps be used.

The invention for a sodium low pressure vapor discharge lamp The findings obtained can also be applied to other vapor discharge lamps.

In addition 6 sheets of drawings

Claims (2)

Patent claims: 1. Process for the production of halogen incandescent lamps with bromine circuit, in which the bromine with With the help of thermal decomposition of a dosed amount of a bromine-containing one added to the filling gas Compound is released, characterized in that the fill gas is brominated silanes be added. 2. A method for producing halogen incandescent lamps with a bromine circuit according to claim 1, characterized characterized in that dibromosilane is added to the filling gas.