DE1937938C3 - Mercury vapor low pressure discharge lamp with major and minor amalgam - Google Patents

Description

The invention relates to a low-pressure mercury vapor discharge lamp with the features of the preamble of claim 1.

The vapor pressure in the lamps is determined by the property of the amalgam, with the same Temperature to have a lower Hg vapor pressure than free mercury. While the main amalgam the operating equilibrium vapor pressure is determined by that in a much hotter place than the place The main amalgam attached secondary amalgam accelerates the lamp start-up. The main amalgam is Indium amalgam used.

It is known that for the function of the amalgam the location of the amalgam-forming part is within the lamp Metal or amalgam and the composition of the latter both in terms of the chosen amalgam-forming metals as well as their quantitative proportion in the alloy are important; through the The place of attachment is even the selection of the amalgam-forming metal or metals and the composition of the amalgam or amalgams to be used (DEPS 10 86 8Ö4). For the choice of the installation location in the lamp is the one at this point during lamp operation existing temperature decisive.

The amalgam-forming metals cadmium are particularly suitable for use in lamps and / or indium and / or tin proved to be suitable, the gcometriscne form present in the lamp and the type of attachment of the amalgam-forming metals or the amalgams is very different. That's the way it is For example, known to bring amalgams in a certain composition in the lamp and in In the form of a line, film or pill, preferably to be glued to the inner wall of the discharge vessel or to roll (DE-PS 1104 060, DE-PS 11 40 286, DE-PS 11 49 818, DE-PS 11 96 292). It still is it also known, initially only the amalgaro-forming Introduce metal into the lamp so that the

to amalgam only forms in the lamp after dosed filling of the mercury. For example, indium was attached as a strip covering the inner circumference of the bulb wall in the middle of the lamp (Japanese patent application 40-8518 or indium was attached as a strip to the pinch feet in the lamp (German utility model 19 34 678) or housed in a sieve-shaped container (German utility model 19 37 402) or a nickel mesh was used around the lamp base, which was impregnated with indium, to which tin is usually added due to the difficult handling of the liquid indium during lamp operation Base tube can be extended in order to be able to maintain the distance from the filament of at least 20 to 60 mm necessary for the operating temperature of the amalgam present in this form (Dutch patent application 65 07 948). If indium was introduced into the lamp as the amalgam-forming metal alone, was the ratio of indium to mercury at that which forms after the lamp has been switched on en amalgam mostly 3: 1. It has also been found that when using indium amalgam, especially with the addition of tin, the temperature dependence of the luminous flux is lower, ie that the curve of the light bulge is flatter as a function of the vapor pressure than, for example, with cadmium amalgam; the light output does not fall while within a temperature range of 3O ⁰ C is not more than 5% and 45 ° C more ai 10% from (Holl.

Patent application 65 07 948, Dutch patent application 68 15 202).

The interaction of two amalgams with different functions is also known, e.g. B. a main amalgam, by which the mercury vapor pressure is determined during the operation of the lamp, and a Another amalgam that shortens the start-up time. Both when using cadmium as from Indium for the main amalgam, it is known, indium or an alloy of indium to form the ignition or to bring aniaufamalgams into the lamp (DE-PS 12 74 228, Dutch patent application 65 12 256, U.S. Patent 32 27 907).

The lamps in US Pat. No. 3,227,907 are so-called high-power lamps, that is to say lamps with a power consumption of more than 0.7 W per cm of discharge length. With these lamps, the maximum luminous flux is achieved at an ambient temperature of 50 ° C. It is emphasized that it is not possible to apply all of the indium to the hot spot, otherwise the mercury would condense on the colder spots of the lamp and the lamp would not be suitable for all operating conditions. In AT-PS 2 71 625, too, the main amalgam is at a point not influenced by the electrode temperature; the only ncbenamalgam is placed near the electrode. If the main amalgam consists of indium amalgam, the weight ratio of indium to mercury should be i: 1. At a

such composition of the main amalgam and the temperature specified in the patent of The mercury vapor pressure is already well above 90-95 ° C above the optimal location for the light output, which has an adverse effect on the efficiency of the lamp affects the lamps of DE-AS 12 74 228 Main amalgam also at locations far away from the electrodes, preferably on the wall, appropriate

Despite the progress already made in the production of lamps with amalgam, it was always possible up to now still necessary for every thermal load area, as it is for example with Operation of lamps in the various luminaires results in each one lamp type with a certain Provide dimensioning of the Amal yarn filling; the amalgam-forming Metal and the composition ratio of the amalgam selected so that the luminous flux maximum of the lamp is reached approximately in the middle of the intended area. For use in rooms with mil a temperature of 25 ° C when using an open light bar !! previously normal fluorescent lamps used without amalgam.

The invention is based on the object to reduce the number of different lamp types and one with regard to electrical load, dimensions, filling, starting properties and simplicity of the Manufacture to create optimal lamp at which the maximum luminous flux at an ambient temperature of about 35 ° C is reached.

The low-pressure mercury vapor discharge lamp with main and secondary amalgam, whereby the main amalgam determines the operating equilibrium vapor pressure and at a much hotter place than the location of the Main amalgam attached secondary amalgam accelerates lamp start-up, whereby the lamp consumes power has a discharge length of less than 0.7 W per centimeter and the main amalgam is indium amalgam is used, is according to the invention characterized in that the weight ratio Indium to mercury in the main amalgam is 12.1 to 3: 1, the main amalgam depends on the electrode temperature affected places with an operating temperature of 80-110 ° C in the lamp, and as In addition to amalgam, there are also several start-up amalgams in different places with different from each other Temperature are present in the lamp, its temperature is greater and its heat capacity is lower is as that of the attachment site of the main amalgam, so that the start-up amalgams are theirs Achieve maximum mercury release one after the other but before the main amalgam.

_R, it is advantageous when the mounting location for the main amalgam or the corresponding amalgambil · Dende metal has a temperature of 90 ° C during operation of the lamp and the weight ratio of indium to mercury in the amalgam 6: 1.

Surprisingly, if these conditions are observed, a substantial broadening is achieved the luminous flux temperature curve. While so far with an indium content in the amalgam of 88% by weight Luminous flux already within a temperature range of around 45 ° C by 10% of its maximum value fell, is achieved with the lamp according to the invention that the luminous flux within a temperature range does not decrease from 70 "C unto. 90% of its maximum, which is reached at .37'C. Within one The luminous flux amounts to a temperature interval of 45 ° C with the lamps according to the invention even more than 90% of the maximum value, while with the previously known lamps then only a temperature range of about 30 ° C can be covered. One Broadening the luminous flux temperature curve by more than 50% does not only bring about the Usability of the lamp at different ambient temperatures, but also with respect to the Usability in luminaires has obvious advantages. Since the lights used in the trade, for example in open light strips, louvre lights, tub, cassette and moisture-proof lights, the temperatures that occur If the room temperature remains constant, the lamp will assume values between 30 ° C and 75 ° C according to the invention for all lights suitable for interior lighting suitable and thus replaces both the normal fluorescent lamp intended for open luminaires as also the closed ones! . -jehten adapted various previously known arr.aigami lamps. Because both for a lamp with cadmium amalgam with a luminous flux maximum of 50 ° C as well as for a normal fluorescent lamp with a luminous flux maximum at 18 ° C the luminous flux decreases by 10% within a temperature range of 30 ° C

Since the mercury content of the indium amalgam in the lamps according to the invention is to be chosen to be low in order to achieve the favorable temperature behavior, it is necessary to provide an additional amalgam to shorten the start-up time in the lamp, similar to, for example, cadrnium amalgam lamps. This start-up amalgam is placed in a place that is quickly warmed up after the lamp has been ignited. However, it has been shown that the luminous flux of these lamps, after initially increasing rapidly, temporarily drops for a certain period of time, as the still cold indium main amalgam, which has a high affinity for mercury, absorbs the mercury and only releases it again in a defined manner after prolonged warming. Des.ialb further start-up amalgams are now provided in the lamp, which are dimensioned and the type of attachment belt selected so that the short-term decrease in luminous flux is absorbed by these amalgams. As mounting location is only a place with low Wä mekapazität ^r. which is closer to the electrode than that of the main amalgam.

With the lamp according to the invention it has been possible to cover the area of application of the standard fluorescent lamp operated with normal power consumption largely expand without having to make constructive changes. With everyone in the Temperatures occurring inside tium lighting The lamp according to the invention provides a high luminous flux, which in one case is below 95% of that in the case of the The value reached is the optimum temperature. While the fluorescent lamp without amalgam only with open Lights and the previous amalgam lamps designed for the various temperature ranges only in Closed luminaires work optimally with regard to their light flow, are the areas of work for all of these Lamps combined in the optimal range of the indium amalgam lamp, so that with the lamp according to the invention a universal lamp for interior lighting has been created

Embodiments of the invention are shown in the figures and are described in more detail below described.

F i g. I shows a black and white light with main and secondary amalgam;

in Fig. 2 is the curve of the relative luminous flux <[· / Φ ..,. _Λ as a function of the ambient temperature of the lamp in ^r C for different fluorescent lamps and underneath the temperature ranges covered in the commercially available luminaires (at a barely 28 "C), which result depending on the design and the number of lamps operated in the luminaire;

F i g. 3 shows the run-up behavior of 65 W-Leiichtstofflampen in a commercially available lamp, the internal temperature at 25 ⁰ C ambient temperature 5U "C.

The electrode pads 3 are fused to the ends of the inside with a phosphor coating 2 provided the lamp vessel 1 in Fig. I, which from the TellerfuQ 4 of the pinch seal 5 through which the current leads 6 nnrj 7 apffihrl ejnrt> jf "d de

umphr S bcStchcri

j jf the pump tube S bcStchcri

At the inner ends of the power supply lines 6 and 7, the oxide-pasted electrode coil 9 is attached, the is surrounded by an annular metal cap 10 made of sheet iron. The cap 10 is the first to carry a start-up amalgam a strip 11 made of an indium alloy, preferably made of indium, tin and lead in proportion 2: 6: 2. The total amount of amalgam-forming metals in the strip-shaped covering 11 is approximately 5 up to 10 mg. The amalgam-forming metal for the main amalgam is located on the plate foot 4 sprayed on indium metal 12 in an amount of 60mg. where the indium amalgam is 6: 1 amounts to. On the pinch 5 there is an indium patch 1.3 ^ up to 10 mg sprayed on.

In Fig. 2, the curve α gives the initial luminous flux level> of a normal fluorescent lamp without amalgam (maximum at 18 C). curve b that of an indium amalgam lamp according to the invention (maximum at 37 ° C.) and curve c that of a cadmium amalgam lamp (maximum at 50 ° C.)

in the specified operating temperatures within the different lights the advantage of the lamp according to the invention is clearly / u recognize. Under 1. is the temperature range for open light strips, under II for reflector strips open at the bottom, under III. for

π louvre lights, under IV. for tub and cassette lights and specified under V. for damp-proof luminaires or the like.

In Fig. 3, curve I shows the start-up behavior of a

65 W-Lcüchotufilämpc inii li'iuiüiVMUUipiiilMiligilMI and with two start-up amalgams, curve 2 for comparison. Rait a start-up amalgam, curve 3 without a start-up amalgam. In comparison, curve 4 shows a 65 W fluorescent lamp without amalgam. It is in each case the luminous flux as a function of that after the lamp has been ignited

2 ') elapsed time plotted in minutes. The curves show that the second start-up amalgam in the case of indium amalgam lamps significantly shortens the start-up time and almost eliminates the short-term decrease in luminous flux.

For this purpose 3 sheets of drawings

Claims (3)

Patent claims: 1. Low-pressure mercury vapor discharge lamp with main and secondary amalgam, whereby the main amalgam determines the operating equilibrium vapor pressure and the secondary amalgam, which is attached to a much hotter place than the location of the main amalgam, accelerates lamp start-up, with the lamp having a power consumption of less than 0.7 W per cm of discharge length and than main amalgam Indiumamalgam is used, characterized in that the weight ratio of indium to mercury in the main amalgam (12) 12: 1 to 3: 1, the main amalgam (12) located at the electrode temperature affected areas with an operating temperature of 80-110 ⁰ C in the lamp, and as a secondary amalgam there are also several start-up amalgams (11, 13) at different points with different temperatures in the lamp, the temperature is higher and the heat capacity is lower than that of the location of the main amalgam (12), so that the start-up amalgams (11, 13) their maximum Deliver mercury sequentially but before reaching the main amalgam. 2. Low pressure mercury vapor discharge lamp according to claim 1, characterized in that the weight ratio of indium to mercury in Main amalgam (12) is 6: 1. 3. Quecksilbsrdampfniederdruckentladungslampe according to claim 1 and 2, characterized in that the main amalgam (M) to a-.i points located in the lamp, which have a temperature of 90 ⁰ C during lamp operation.