NO140156B - ELECTRIC GAS DISCHARGE LAMP. - Google Patents

Description

The invention relates to an electric gas discharge lamp_ in which radiation emitted from the gas discharge is converted by means of luminescent material on a light-permeable support body into radiation in the visible part of the spectrum. The invention relates in particular to a gas discharge lamp in which the discharge takes place in a mercury vapor atmosphere of the low-pressure or high-pressure type. In previously known lamps, the luminescent material is usually placed on the inner surface of the wall of the discharge chamber. In another type of lamp, the luminescent material is usually placed on one flask which 'encloses the discharge pipe.

In order to achieve a certain desired color reproduction for such a lamp with a large light output, it has already been proposed to mix different luminescent materials with each other or to place these materials on the support body in overlapping layers.

According to U.S. Patent 3,602,758, the starting point is a "desired color emission point which can be achieved with a specific light yield and a specific color rendering by means of a single layer containing a mixture of luminescent materials. This is achieved by a mixture of more and less expensive luminescent materials, "and 'in order to obtain a more economical lamp, overlapping layers are used where the material which is directly placed on the support body is cheaper* than that which is "nearest" the discharge, because it has been shown that a smaller quantity of the more expensive material is needed than< when all the materials are mixed in a single layer?" These layers together produce light with the desired color rendering point, but the color rendering points for light from separate layers are naturally different. This is a major disadvantage because it has been shown in practice that when manufacturing lamps, the thickness of the layer, especially the thickness of the layer facing the discharge, must be kept within very narrow limits, because the color emission points for radiation from the different layers are different, and even a slight variation in the thickness of this layer, which for economic reasons must be made as thin as possible, will nevertheless convert a large part of the radiation from the discharge into light and produce a significant change in the color emission point and the color reproduction of the lamp. mass production, such conditions cannot therefore be accepted because they lead to expensive production, among other things because all manufacturing steps for the lamps must be carefully monitored.

If the desired combination of very good color reproduction and high light output is to be achieved only by using expensive luminescent materials, this cannot be achieved on the basis of U,i!S.. - patent document No. 3,602,758 for all such materials are expensive and a small economic gain that can be achieved by placing less expensive materials in separate layers located further from the discharge which is largely ignored as a result of increased costs for applying such additional layers. In these cases, it is cheaper to mix all the luminescent materials together and apply them in a single layer.

An electric gas discharge lamp according to the invention with a luminescence screen which comprises a light-permeable carrier body on which two luminescence layers are placed one on top of the other; which emits light under the influence of radiation from the discharge light, the layer facing the discharge consisting of luminescence material which per unit of weight is more expensive than the material in the second luminescence layer, is characterized according to the invention in that the difference between the color emission points in the light emitted by each layer is less than 4^- CIE units, where p is the part of the total radiation from the discharge that is converted into light by the luminescence layer facing the discharge, which p lies between the values 0.80 and 0.99.

They mentioned CIE units published in Paris in 1964 in a report of the CIE Congress held in Vienna in 1963.

The above-mentioned case where all the luminescent materials that were necessary for a satisfactory color rendering and high light output were more expensive, are used e.g. in lamps in which the layer facing the discharge comprises a mixture of three luminescent materials activated with rare earth metals and co-emission lines between 4^00 and 4900 Å, between 5200 and 5650 Å, respectively between 5900 and 6^00 Å.

By applying the characteristic of the present invention, the quantity of all these expensive luminescent materials can be reduced to a significant extent without loss of light and with the maintenance of satisfactory color reproduction as will be explained by the examples below. One condition is, however, as mentioned above-

so that at least 80% and at most 99% of the total radiation that is converted into light is converted by the layer facing the discharge. If this layer emits less than 80$, a small deviation from this value will have a relatively large effect on the color rendering of the light emitted from the lamp. If the layer emits more than 99$, the financial gain will be too small. Preferably, the release should be chosen to be over 90$.

The invention will be described in more detail below with reference to examples and to a drawing showing an axial section through a low-pressure mercury vapor discharge lamp according to the invention.

The lamp wall 1 limits the discharge space between the electrodes 2 and 3 - The discharge is formed between these electrodes in the discharge space which is filled with mercury vapor and one or more noble gases as usual with lamps of this type. The inner surface of the lamp wall 1

is coated with two luminescence layers 4 and 5 which lie on top of each other.

As is known, a suitably selected voltage produces a discharge in the discharge space and this discharge emits large ultraviolet radiation, particularly at one wavelength of 2540 Å. This radiation affects the luminescent material in layers 4 and 5. Depending on the nature of these materials, each emits of them radiation with a specific spectral energy distribution and a specific color emission point, the emitted radiation being the sum of the radiations from each of the layers 4 and 5-

According to the invention, the layer 4 consists of a luminescent material or a mixture of luminescent materials which per unit of weight is less expensive than the material or mixture of materials in layer 5« The color emission points for the radiation from the two layers are different. As mentioned above, this difference must not exceed CIE units. In layer 5, at least 80$ and at most 99$ of the ultraviolet radiation must be converted into light. The part of the ultraviolet radiation that is not converted in this layer is converted in layer 4 mainly

equal to light with a color emission point equal to or somewhat different from the color emission point of the light emitted from the layer 5" By the fact that the layers 4 and 5 lie on top of each other, it is possible that the layer 5 can be thinner than if the layer 4 were not present while maintaining approximately the same light yield. This will be apparent from table I, which shows data measured for a 40 watt fluorescent lamp.

In Table I, A is a luminescent material with the formula B is a luminescent material with the formula

C is luminescence material with the formula Y, OI_Eu't+t,-0-,.

1.95 0.05 3

In the table, the numbers 1 and 5 refer to lamps that are not manufactured in accordance with the invention.

A comparison of lamps 2, 3 and 4 with the reference lamp 1 shows that after 100 hours of operation there is practically no difference in light output, color emission coordinates and color reproduction, but lamps 2, 3 and 4 contain significantly smaller amounts of the expensive materials A, B and C.

A comparison of lamps 6 and 7 with the reference lamp

5 gives a similar picture. Only the Ra value is significantly increased in lamp no. 7 - Only 1.1 g of the mixture of materials A, B and C is used with the result that a financial gain is achieved. Consequently, the value of the transformation factor p is small in this very thin layer, namely 0.80. For lamp no. 4, the value of p is approx. 0.87.

An expression for the variation of light output as a function of layer thickness in the lamp containing only one layer of the mixture of 6% A, 25% B and 69% C is given in Table II.

A comparison of the values in Table II and Table I • clearly shows that the losses in light output caused by a reduction in the thickness of the layer in a single-layer lamp, which would naturally result in a cheaper lamp, do not occur or occur only to a significantly lesser extent in lamps according to the invention.

Use of several layers in the lamp according to the invention can be done in a completely normal way, e.g. by mixing the luminescence materials with a binder such as ethyl cellulose or nitro-cellulose 1 a solution of butyl acetate or another solvent and coating the lamp wall with such a solution with subsequent drying and heating to remove the binder.

Although low-pressure mercury vapor discharge lamps are given as an example above, the invention can be applied without significant modifications to other lamps, e.g. high-pressure mercury vapor discharge lamps.

Claims (3)

1. Electric gas discharge lamp with a luminescence screen comprising a light-permeable support body on which two luminescence layers are placed one on top of the other which emits light under the influence of radiation from the discharge light, the layer facing the discharge consisting of a luminescence material which per weight unit is more expensive than the material in the second luminescence layer, characterized by the fact that the difference between the color emission points in the light emitted by each layer is smaller than CIE units, where p is the part of the total radiation from the discharge that is converted into light by the luminescence layer facing the discharge, which p lies between the values 0.80 and 0.99- 2. Lamp according to claim 1, characterized in that the luminescent layer which is farthest from the discharge comprises one or more halogen phosphates of calcium and/or strontium activated with antimony and/or magnesium, and the layer which is closest to the discharge consists of a mixture of three luminescent materials which are activated with rare earth metals and has emission between 4300 and 4900 Å, rrSllom 5200 and 565O Å respectively between 5900 and 6300 Å. 3. Lamp according to claim 2, characterized in that the layer facing the discharge consists of a mixture of yttrium oxide activated with trivalent europium, cerium magnesium aluminate activated with trivalent terbium and barium magnesium aluminate activated with bivalent europium.