DE10225495A1 - Tubular fluorescent discharge lamp has insert along the length of the tube coated with a fluorescent layer - Google Patents

Abstract

A fluorescent discharge having a single or double socketed transparent tube (1) comprises an atmosphere suitable for a discharge and a fluorescent coating. A body (2) which is covered by a fluorescent coating (5) is inserted along the length of the tube.

Description

The invention relates to a fluorescent discharge lamp according to the preamble of claim 1.

Fluorescent discharge lamps include a glass tube with a base on one or both sides, which has a gaseous atmosphere, e.g. a metal vapor and krypton, filled with high or low pressure, in which a gas discharge is generated, causing ultraviolet radiation is produced. The inside of the glass tube is covered with a phosphor, such as a phosphorus compound that coats the ultraviolet light absorbed and converted into visible light. Through the fluorescent layer but the luminance is impaired due to absorption. Besides, will the luminous flux of the size of the Available Inner surface of the glass tube.

The object of the invention is a Fluorescent discharge lamp according to the preamble of claim 1 to create that enables an elevated Luminous flux and an increased To maintain luminance with the same outer geometry.

This task is done according to the characteristic Part of claim 1 solved.

This turns visible light on the surface one to the outside directed phosphor coating produced, which is applied to an insert body which makes the lighter side of the phosphor coating visible is and the luminous surface be significantly enlarged can. Absorption losses can thus be kept low. By reflecting accordingly of visible light to the outside the lamp efficiency can also elevated become.

It also improves heat distribution due to the insert body reached, whereby the burning position of the lamp also the lamp efficiency practically not affected.

Further refinements of the invention are to the following description and the dependent claims remove.

The invention is illustrated below from in the attached Illustrations shown embodiments explained in more detail.

• 1 shows in section an embodiment of a fluorescent discharge lamp.
• 2 shows a detail Z of 1 ,
• 3 to 6 branch further embodiments of a fluorescent discharge lamp in section.

At the in 1 In the embodiment shown, the fluorescent discharge lamp, for example a mercury, sodium or halogen vapor lamp, has a glass tube 1 , which is socketed on one or both sides, provided with appropriate electrical connections and filled with an appropriate atmosphere. In the glass tube 1 there is an insert body 2 which is essentially the length of the glass tube 1 extends.

The insert body 2 of 1 has a series of radial ribs 3 that in the middle area over webs 4 are connected, being between two adjacent ribs 3 the jetty 4 is missing, so that of the jetties 4 enclosed cavity is open to the outside to ensure easy manufacture. The bridges 4 expediently form outwardly concave regions.

The insert body 2 is electrically non-conductive and can for example consist of glass, ceramic or preferably plastic. The insert body 2 is at least on the outside and if necessary, as in 1 shown, overall with a fluorescent coating 5 Mistake. The insert body 2 can be selective, for example at the points 6 , over silicone or the like. on the inside of the glass tube 1 be attached. If through the in the glass tube 1 gas discharge taking place, UV light is generated by the phosphor coating 5 converted into visible light and through the glass tube 1 broadcast through. Because the surface of the phosphor coating 5 on the insert body 2 is much larger than the inner surface of the glass tube 1 , is the light output compared to a lamp with an internally coated glass tube without insert body 2 significantly increased with the same geometry. The absorption and reflection losses are reduced, resulting in a brighter outer surface of the lamp.

Because in the embodiment of 1 no fluorescent coating of the glass tube 1 is provided on the inside, however, UV light could escape to the outside. However, this can be done by using glass that is practically impervious to UV light for the glass tube 1 or by applying a UV light-absorbing lacquer on the inside and / or outside of the glass tube 1 prevent.

The inside of the glass tube 1 can be smooth or rough. If the inside of the glass tube 1 is rough, there is a corresponding scatter and equalization of the brightness.

Generates visible light that is not directly through the glass tube 1 emerges, can on the fluorescent coating 6 be reflected and then exit. The fluorescent coating 5 shines as it is on the insert body 2 is arranged to the outside, which also improves the luminous efficiency, since lower vapor pressure improves the lamp output.

The insert body 2 also leads to improved heat distribution due to heat conduction in low-pressure lamps, since otherwise there is no insert 2 the heat distribution because of that in the glass tube 1 prevailing negative pressure can essentially only take place via heat radiation. Accordingly, the cooling is improved.

At the In 3 shown embodiment consists of the insert body 2 radial ribs connected in the middle 3 that cover the entire surface with the fluorescent coating 5 are provided.

At the in 4 The embodiment shown is the insert body 2 on average essentially W-shaped, the two outer legs essentially corresponding to the glass tube 1 are curved so that the insert body 2 towards one side of the lamp that opens with the fluorescent coating only 5 is provided. The insert body 2 acts like a reflector and suitably colored white. The light is radiated in this way.

Other geometries of the insert body 2 can be used. So it is also possible, as in 5 shown the insert body 2 as a tube with a smaller diameter than the inner diameter of the glass tube 1 and to be formed from transparent material, at least on the outside and possibly also on the inside with the phosphor coating 6 is provided. Here, the volume of the annular space between the glass tube is expedient 1 and the insert body 2 approximately equal to the volume of the interior of the insert body 2 , The insert body 2 is here or the like preferably electrically non-conductive bracket. held. This also results in an advantageous reduction, narrowing, of the radiating surface in connection with reflectors, as a result of which more precise and thus narrower radiating light control can be achieved.

At the in 6 The discharge lamp shown is a high-pressure lamp or a lamp operating at medium pressure, which has a quartz tube which is permeable to UV light on the inside 7 in which the gas discharge takes place. The quartz tube 7 can, for example, via wire clips in the glass tube 1 be attached. The quartz tube 7 is inside one of the glass tube 1 recorded, in section essentially W-shaped insert body 2 that on the the quartz tube 7 facing side the phosphor coating 5 wearing. - If the insert body 2 is transparent, visible light can also escape through it to the outside.

It is also possible to use the glass tube 1 inside with a fluorescent coating 8th to be provided as in 5 is shown, which then leads to a reduction in the luminous efficacy, but avoids the need for UV protection.

The glass tube 1 can be straight or curved and have a circular or elliptical cross-section. In addition, this should also be understood to mean spherical, mushroom, pear or other shaped pistons.

Instead of a glass tube 1 a transparent tube made of preferably UV-resistant plastic can also be used.

Claims (12)

Fluorescent discharge lamp with a transparent tube on one or both sides ( 1 ), a gaseous atmosphere in it, suitable for gas discharge, and with a phosphor coating ( 5 ), characterized in that in the tube ( 1 ) essentially over the length of the pipe ( 1 ) extending insert body ( 2 ) is arranged, which with the phosphor coating ( 5 ) is provided. Fluorescent discharge lamp according to Claim 1, characterized in that the insert body ( 2 ) in the tube ( 1 ) is fixed. Fluorescent discharge lamp according to Claim 1 or 2, characterized in that the tube ( 1 ) consists of a glass that is impervious to UV light. Fluorescent discharge lamp according to Claim 1 or 2, characterized in that the tube ( 1 ) is provided on the inside and / or outside with a coating that is opaque to UV light. Fluorescent discharge lamp according to Claim 1 or 2, characterized in that the tube ( 1 ) inside with a fluorescent coating ( 8th ) is provided. Fluorescent discharge lamp according to one of Claims 1 to 5, characterized in that the insert body ( 2 ) is essentially star-shaped on average. Fluorescent discharge lamp according to one of Claims 1 to 5, characterized in that the insert body ( 2 ) is essentially W-shaped on average. Fluorescent discharge lamp according to one of Claims 1 to 5, characterized in that the insert body ( 2 ) tubular and at least on the outside with the phosphor coating ( 5 ) is provided. Fluorescent discharge lamp according to one of Claims 1 to 8, characterized in that the insert body ( 2 ) consists of transparent material. Fluorescent discharge lamp according to one of Claims 1 to 8, characterized in that the insert body ( 2 ) consists of white material. Fluorescent discharge lamp according to one of Claims 1 to 10, characterized in that the tube ( 1 ) is roughened on the inside. Fluorescent discharge lamp according to one of Claims 1 to 10, characterized in that the tube ( 1 ) is smooth on the inside.