DE102006033872A1 - Dielectric barrier discharge lamp with glass wall - Google Patents

Abstract

The invention relates to a discharge lamp with dielectrically impeded electrodes (3). These are separated from a discharge medium by a prefabricated glass wall (2). Both the prefabricated glass wall (2) and the electrodes (3) are arranged inside a glass tube (1), wherein they are within the glass tube (1) further than two-thirds of the glass tube diameter apart. Furthermore, the invention is also directed to a system comprising a dielectrically impeded discharge lamp according to the invention and a suitable socket.

Description

Technical area

The The invention relates to a dielectrically impeded discharge lamp and to a system of a dielectric barrier according to the invention Discharge lamp and a socket.

State of the art

dielectric Disabled discharge lamps are known in many variations. They have a discharge vessel filled with a discharge medium. typically, are the electrodes for coupling a power into the discharge medium separated from the discharge medium by a dielectric. Tubular discharge vessels are common and for certain applications particularly suitable.

at a common type of discharge lamp are two strip-shaped electrodes diametrically opposite applied internally to a tubular glass discharge vessel. Towards the discharge medium, the electrodes are through a glass solder layer isolated. Both layers are successively as a viscous paste applied and solidified by an annealing step.

The DE 10 2004 047 375 shows a tubular dielectrically impeded discharge lamp with electrodes, which are arranged along the longitudinal extension of the discharge vessel on the outside of the discharge vessel. Here, the discharge vessel wall itself, ie a prefabricated glass wall, serves as a dielectric barrier.

Presentation of the invention

Of the present invention is based on the object, an advantageous specify dielectrically impeded discharge lamp, in which the electrodes by a prefabricated glass wall are separated from the discharge medium.

The The invention is directed to a discharge lamp with dielectric disabled electrodes passing through a prefabricated glass wall separated from a discharge medium, characterized that they are arranged inside a glass tube, wherein they within the glass tube more than two thirds of the glass tube diameter away from each other.

Further The invention is also directed to a system of a discharge lamp according to the invention and a version for the discharge lamp.

preferred Embodiments of the invention are described in the dependent claims and shown in the description. The revelation in the description refers to both the dielectrically impeded discharge lamp as well as the system with the dielectrically impeded discharge lamp and the version. Further, it also refers to a manufacturing process for one discharge lamp according to the invention. The description is thus with respect their respective individual characteristics.

The Invention is based on the finding that it is advantageous Electrodes through a prefabricated glass wall of the discharge medium to separate the discharge lamp. A prefabricated glass wall as Dielectric hindrance allows one Controlled adjustment of mechanical and electrical properties the dielectric hindrance. In particular, a prefabricated Glass wall in advance of course lighter (see below) and also very evenly produced, compared with the use of a glass solder. In the above section The prior art has a discharge lamp is mentioned, in the discharge vessel itself acts as a prefabricated glass wall.

The Invention is further based on the idea of the prefabricated glass wall and to arrange the electrodes inside a glass tube. A Such arrangement has the advantage that the electrodes are inside the discharge lamp are protected by the glass tube and the high voltage Electrodes to the outside are isolated.

Tubular discharge vessels are are widespread and are re their shape is not limited to straight rod-shaped tubes. Even if discharge lamps, which are substantially circular along its circumference, particularly common are to be here by stopping on tubular discharge lamps the Invention should not be limited in this sense. So should in the context This invention also about oval discharge lamps or polygonal Discharge lamps are considered tubular.

Within the glass tube, the electrodes are placed further than two-thirds of the glass tube diameter apart. More preferable is a distance of more than three quarters of the glass tube diameter, more preferably a distance of more than four fifths of the glass tube diameter, and ideally the distance between the electrodes is more than nine-tenths of the glass tube diameter. In this case, the electrodes can be arranged approximately diametrically opposite the glass tube along the longitudinal extension thereof. But they can also be arranged in each case in the vicinity of the ends of the glass tube, which leads to distances that are much larger can be, as the diameter of the glass tube.

Of the Distance of the electrodes from each other determines the discharge length. are the electrodes according to the invention in the Glass tube relatively far apart, so are particularly slim Designs possible. The cross section of the glass tube and the volume of the Discharge medium well utilized.

at a preferred embodiment According to the invention, the prefabricated glass wall is a solid glass wall. A massive glass wall is characterized by a substantially continuous microscopic structure without relying on the macroscopic properties impacting boundary layers or grain boundaries. Examples of not massive glass walls are one piece Sintered glass and baked glass solder. In sintered glass and glass solder are many individual glass granules connected with each other. These examples show that a massive glass wall is characterized in particular by the fact that they are essentially grain-free is. A massive virtually enclosure-free glass wall has the advantage that with it a macroscopically particularly uniform and reliable dielectric can be formed, which has a positive effect on the required material thicknesses. The probability of breakdowns by the dielectric is correspondingly low.

in the For example, within the scope of this invention, the prefabricated glass wall the wall of the discharge vessel itself, introduced into the discharge vessel Glass panes or surrounding the electrodes envelope tubes correspond (see below). This possible embodiments are characterized by a particularly easy manufacturability. It For example, it is easier to have a discharge vessel, glass panes, or sheaths in To arrange a glass tube, as a viscous glass solder layer in one Apply glass tube.

Preferably The electrodes are also prefabricated electrodes. So these will not be during applied during the production of the discharge lamp, but during the Production as independent metal pieces placed in the lamp. In these prefabricated electrodes can for example, metallic wires or metallic pins act. Prefabricated electrodes can be used in the production of discharge lamps according to the invention be particularly advantageous because they are handled as a single piece can be. In particular, it is easier prefabricated electrodes in one To attach glass tube than the electrodes on the inside of the Glass tube as liquid Apply material.

prefabricated Electrodes, especially metallic wires or pins, can also easy without further contacting of the electrodes to the compound the discharge lamp can be used with a power source via a socket (Infra).

at a preferred embodiment According to the invention, the prefabricated glass wall corresponds to the wall of the wall The discharge vessel. at this embodiment is the discharge vessel of one Glass tube surrounded and the electrodes are in the space between the discharge vessel and the glass tube arranged. In this embodiment can designed the wall of the discharge vessel particularly thin be what the needed Supply voltages and thus the circuit complexity reduces and a particularly efficient operation of the discharge lamp favors. That the discharge vessel and the Electrodes surrounding additional Glass tube can have a greater wall thickness than have the discharge vessel, so as to ensure an overall mechanically stable discharge lamp.

The internal discharge vessel and the external Glass tube can about about Melting or sintering together or via a glass solder together get connected. The connection for the discharge vessel and the glass tube used area the two glass jars can different dimensions accept. So can the glass vessels, for example only be selectively connected to each other or segmentally along the circumference of the glass tube, or along the entire surface the entire lateral surface the glass tube or the discharge vessel.

Preferably the prefabricated electrodes, such as wire electrodes, pass through the connection between the discharge vessel and the glass tube.

there The prefabricated electrodes are preferably through this compound fixed. Such an arrangement is particularly advantageous in production, because the electrodes do not need to be held by further measures.

It has proved its worth, the wall thickness of the discharge vessel to choose an interval from 0.02 mm to 0.5 mm. More preferable is an interval of 0.02 mm to 0.25 mm. Even more preferred is an interval of 0.02 mm to 0.1 mm. Ideally, the discharge vessel has a wall thickness between 0.02 mm and 0.05 mm. Independently of the choice of wall thickness of the discharge vessel has it is proven the wall thickness of the outside Glass tube to set at least 0.6 mm. More preferred is one Wall thickness of at least 0.8 mm, and more preferably a wall thickness of at least 1 mm for the glass tube.

at An alternative preferred embodiment is the glass tube the discharge vessel. In the Discharge vessel are glass panes introduced, such as strip-shaped Flat glass sheets. In between the glass panes and the discharge vessel incurred interspaces the electrodes are arranged. The glass panes here correspond to the prefabricated glass wall and act accordingly as a dielectric disability

at a further alternative embodiment According to the invention, the electrodes are each arranged in a glass enveloping tube. The sheaths with the internal electrodes are on the inside of the lateral surface of the Discharge vessel attached. Here are the sheaths the prefabricated glass wall and the discharge vessel is the glass tube.

As already mentioned above, The invention also relates to a system of a dielectric according to the invention obstructed discharge lamp with prefabricated electrodes, ie about wire or pin electrodes, and a socket. The prefabricated Electrodes protrude from the lamp at one of its ends and the Lamp and the socket are coordinated so that the socket connect the prefabricated electrodes to a power source can and she can also hold the lamp. Such a system can be designed so that an insertion of the discharge lamp in the Version is particularly simple.

As also mentioned above The invention also relates to a process for the preparation a discharge lamp with dielectrically impeded electrodes with the steps: making a glass wall and arranging the electrodes inside a glass tube, leaving it at the finished discharge lamp separated from a discharge medium by the prefabricated glass wall and they are within the glass tube more than two thirds of the glass tube diameter away from each other.

Preferably the method comprises the further steps of: one of melting and sintering the glass tube with the prefabricated glass wall to the mutual Connecting the same and then introducing phosphor into the Discharge lamp. Namely the massive glass wall and the glass tube fused together or sintered, so it is advantageous to connect the phosphor only after this connection in the discharge lamp to bring an impairment of the phosphor by increased Temperature to avoid. This applies to all alternatives described embodiments the invention.

Brief description of the drawings

in the Below are embodiments of the Invention presented. Thereby revealed individual characteristics can each for themselves or in other than the combinations shown essential to the invention be.

1 shows a cross section through a first discharge lamp according to the invention.

2 shows a schematic representation of the discharge lamp 1 of the page.

3a , b show schematically two ways of connecting parts of the discharge lamp from the 1 and 2 ,

4 shows a cross section through a second discharge lamp according to the invention.

5 shows a cross section through a third discharge lamp according to the invention.

6 schematically shows a fourth discharge lamp according to the invention from the side.

7 shows a fifth discharge lamp according to the invention and a matching socket.

Preferred embodiment of invention

1 shows a cross section through a tubular discharge lamp according to the invention perpendicular to its length. An outside glass tube 1 includes a discharge vessel 2 , electrodes 3 are in the boundary layer between the discharge vessel 2 and the glass tube 1 arranged. On the inside of the discharge vessel 2 is a phosphor layer 4 applied.

The wall of the discharge vessel 2 has a thickness of 0.03 mm and the wall of the outer glass tube 1 has a thickness of 1.2 mm.

2 schematically shows the in 1 only in cross-section discharge lamp from the side. The meandering double line in the middle of the figure indicates an omission. Thus, only the ends of the discharge lamp are shown. The electrodes 3 protrude at both ends of the discharge lamp, so that a contact is possible at both ends. At the end of the discharge lamp shown in the figure below can be seen a welded-pump stems. Through this pump stalk is also the phosphor during production 4 introduced into the interior of the discharge vessel.

Possible variations of in 2 Discharge lamp shown include embodiments with different sockets or with one too additional second pumping stems at the other end of the discharge vessel.

3a schematically shows a section along the length of a discharge lamp. Below you can see the wall of the glass tube 1 and above the wall of the discharge vessel 2 , The wall of the glass tube 1 is selectively heated and vaulted, leaving the glass tube 1 and the wall of the discharge vessel 2 at these points 6 fused together. The punctual design of these connections 6 is up in 3a symbolized by the concentric circles, which is a contour line representation of the compounds 6 correspond.

3b shows connections 6 , which completely surround the circumference of the discharge vessel 2 walk around. Here too is the glass tube 1 at the connections 6 incur by heating and with the wall of the discharge vessel 2 fused in these places. That these connections 6 the entire circumference of the discharge lamp is shown by the dashed lines pointing upwards.

The in the 3a and b illustrated fusions 6 between the glass tube 1 and the discharge vessel 2 be the discharge lamp during production before the introduction of the phosphor 4 taught.

A second alternative embodiment of the invention is in 4 shown. Reference numerals for components of the invention shown in the preceding figures will continue to be used accordingly. This also applies to all following figures, even if they relate to further embodiments of the invention.

Also 4 shows a discharge lamp according to the invention in cross section perpendicular to its length. A glass tube 1 also includes electrodes here 3 and a phosphor layer 4 , In contrast to the previous figures, however, there is no further inner vessel here. The glass tube 1 is already the discharge vessel. The electrodes 3 are through flat glass panes 7 separated from the inside of the discharge lamp.

Here are the flat glass panes 7 with the glass tube 1 So, with the discharge vessel, fused before the phosphor 4 is introduced.

5 shows a third embodiment of a discharge lamp according to the invention in cross section perpendicular to its length. Again, includes a glass tube 1 which is like in 4 also corresponds to the discharge vessel, two electrodes and a phosphor layer 4 , The electrodes 3 are here through glass sheaths 8th separated from the inside of the discharge lamp. Here are the sheaths 8th to the inside of the glass tube 1 melted before the phosphor 4 is introduced.

In 6 schematically a discharge lamp according to the invention is shown as a fourth embodiment of the page. Unlike in the preceding embodiments, electrodes extend 3 not along the length of the inner surfaces of a glass tube also given here 1 but rather are at the ends of the glass tube 1 positioned. At the bottom of in 6 shown end passes an electrode 3 parallel to the end of the glass tube 1 , ie perpendicular to the lateral surface of the glass tube 1 , At the top of the figure is another electrode 3 shown, which is centered along the axis of rotation of the glass tube 1 is introduced. The glass tube 1 nestles against the upper electrode 3 and thus completes the discharge lamp above. The electrodes 3 are inside the glass tube 1 , which also corresponds here to the discharge vessel, each of a glass envelope tube 8th surround. Again, the inside of the discharge lamp with a phosphor 4 lined.

7 shows on the right a discharge lamp according to the invention with a glass tube to be recognized from the outside 1 and from the discharge lamp left protruding wire electrodes 3 , Left in 7 you recognize a version 9 with to the electrodes 3 matching blind holes 10 , The version 9 becomes the blind holes on the right 10 as a cylindrical shell 11 continued. This has a slightly larger inner diameter than the outer diameter of the discharge lamp shown on the right. The discharge lamp can in this version 9 are introduced so that the discharge lamp over the wire electrodes 3 and the blind holes 10 can be powered (a corresponding supply is not shown), wherein the cylindrical shell 11 the discharge lamp covers and holds.

Claims (9)

Discharge lamp with dielectrically impeded electrodes ( 3 ), which through a prefabricated glass wall ( 2 . 7 . 8th ) are separated from a discharge medium, characterized in that they are located inside a glass tube ( 1 ) are arranged inside the glass tube ( 1 ) are further than two-thirds of the glass tube diameter apart. Discharge lamp according to Claim 1, in which the prefabricated glass wall ( 2 . 7 . 8th ) is a massive glass wall. Discharge lamp according to one of the preceding claims, in which the electrodes ( 3 ) are prefabricated electrodes. Discharge lamp according to one of the preceding claims, in which the discharge vessel ( 2 ) the prefabricated glass wall ( 2 ) and the electrodes ( 3 ) in a space between the glass tube ( 1 ) and the discharge vessel ( 2 ) are arranged. Discharge lamp according to Claims 3 and 4, in which the prefabricated electrodes ( 3 ) through a connection ( 6 ) between the discharge vessel ( 2 ) and the glass tube ( 1 ) and are held by them. Discharge lamp according to Claim 4 or 5, in which the wall thickness of the discharge vessel ( 2 ) from 0.02 mm up to and including 0.5 mm and the wall thickness of the glass tube ( 1 ) is at least 0.6 mm. Discharge lamp according to one of Claims 1 to 3, in which the discharge vessel ( 1 ) the glass tube ( 1 ) and the electrodes ( 3 ) in each case by an inside on the lateral surface of the discharge vessel ( 1 ) adjoining glass pane ( 7 ) as a prefabricated glass wall ( 1 ) are separated from the discharge medium. Discharge lamp according to one of Claims 1 to 3, in which the discharge vessel ( 1 ) the glass tube ( 1 ) and the electrodes ( 3 ) in each case in an inside on the lateral surface of the discharge vessel ( 1 ) adjacent glass sheath ( 8th ) and through this as a prefabricated glass wall ( 1 ) are separated from the discharge medium. Discharge lamp system according to claim 3, also in combination with another of the preceding claims, and a socket ( 9 ), whereby the prefabricated electrodes ( 3 ) protrude from the lamp and the lamp and socket ( 9 ) are coordinated so that the version ( 9 ) the prefabricated electrodes ( 3 ) connects to a power source and the socket ( 9 ) holds the lamp.