DE102004011555B3 - Gas discharge lamp has conductors which are bound to envelope by glass with higher linear coefficient of expansion than envelope in surrounding area - Google Patents

Abstract

The invention relates to a gas discharge lamp having a glass body, which has a glass bulb, and having a flow guide enclosed by the glass bulb, the two current carrying wires, wherein the current feedthrough wires are connected in a gastight manner by means of a transition glass with the glass bulb and wherein the current feedthrough wires are formed at least in the region of the transitional glass of a tungsten or tungsten-containing material. In order to improve the reliability and service life of such a gas discharge lamp, it is provided according to the invention that the glass body is formed, at least in the region adjacent to the transition glass, from a glass material having a linear thermal expansion coefficient alpha (20 °, 300 °) in the range between 2.9 and 3.5 [10 * -6 * / K], and that the transition glass has a linear thermal expansion coefficient alpha (20 °, 300 °) in the range between 3.5 and 3.9.

Description

The invention relates to a gas discharge lamp with a glass body, which has a glass bulb, and having a flow guide enclosed by the glass bulb, the two current feedthrough wires, wherein the current feedthrough wires are connected in a gas-tight manner by means of a transition glass with the glass bulb and at least in the region of the transition glass are formed of tungsten or a tungsten-containing material. Such gas discharge lamps are described in Heinz G. Pfaender 1996, Schott Guide to Glass; Publisher Chapman &Hall; Page 131, described. They have a current feed with tungsten wires. These are guided as current feedthrough wires from the environment in the space surrounded by the glass envelope. To obtain a gas-tight seal here, a transitional glass is used, which connects the glass bulb with the tungsten material. The transition glass absorbs the different thermal expansion of the Verschmelzpartner. In the known gas discharge lamps, a glass material with a linear expansion coefficient in the range between 4.0 and 4.4 × 10 ^-6 / K is used for the transition glass. With this a plate glass is combined, which consists of the same material as the transition glass. Connected to the plate glass is a hood-like glass bulb made of special glass, which is available under the name "Suprax". The glass bulb is fused with the plate glass. It has been shown that the fusion point must be carried out carefully to avoid premature failure of the gas discharge lamp. In addition, it can cause damage to the glass body during extreme changes in temperature during lamp operation.

From the DE 29 20 042 C2 For example, a high pressure gas discharge lamp with a quartz glass bulb is known in which tungsten electrode pins are inserted. In this case, the tungsten electrode pins are fixed in a carrier, which is fused to the flange of the quartz glass bulb. The expansion coefficients of the support and the glass bulb are the same and are between 11 and 17 × 10 ^-7 ° C ^-1 in the temperature range of 30 to 800 ° C. This known short-arc discharge lamp has a simple structure and is suitable up to high pressures.

As the GB 2 030 000 A shows, introduced in a glass bulb with a high Schz Izpunkt electrode of an electric lamp in the lead-in area may also be provided with more than one glass coating. The coefficients of expansion of the glass coatings increase in the direction of the glass bulb.

However, it is also from the US 4,221,989 It is known to melt a molybdenum electrode directly into an alumina-aluminum borosilicate glass flask to obtain a direct connection.

at all these known gas discharge lamps is not sufficient Operational safety and service life achieved.

It Object of the invention, a gas discharge lamp of the beginning mentioned To create kind, characterized by an improved operational safety and durability.

This object is achieved in that the glass body is formed, at least in the adjoining the transition glass region of a glass material having a linear thermal expansion coefficient α (20 °, 300 °) in the range between 2.9 and 3.5 [10 ^-6 / K], preferably 3.2 to 3.3 [10 ^-6 / K], and that the transition glass has a linear thermal expansion coefficient α (20 °, 300 °) in the range between 3.5 and 3.9 [10 ^{. 6} / K], preferably 3.6-3.8 [10 ^-6 / K].

It has been shown that with this new glass composition for a gas discharge lamp, the temperature and thermal cycling capacity is significantly improved. As a departure from the glasses proposed throughout in the prior art, the inventor has recognized that, surprisingly, a transition glass with a coefficient of thermal expansion of less than 4 [10 ^-6 / K] can be used for application in gas discharge lamps, and this is precisely where the operating parameters are improved.

For the glass bulb let yourself use a glass material that is opposite to those used in the prior art glass a lower thermal expansion and therefore a higher one Temperature resistance has.

The The object of the invention is alternatively also solved by the vitreous starting from the transitional glass Consistently made of a glass material. In this arrangement is the for Temperature cycling critical transition area between plate glass and glass flasks made of a material with a uniform coefficient of expansion manufactured. This is a greater temperature-Wechselbeanspruchbarkeit created.

Such a gas discharge lamp can be produced cost-effectively, in particular, if it is provided that the glass body, starting from the transitional glass, consists uniformly of a glass material. In this case, a particularly preferred embodiment variant is such that the glass material of the glass bulb and the plate glass has the following constituents (in% by weight):

These glasses are resistant to thermal shock in a special way. In particular, the glass may contain the following constituents (in% by weight):

at This glass is a material that, for example under the name "Duran" is common and diverse used in other technical fields. It can be at one Glass pavers are thus continuously processed. With the novel Application, the glass paver thus its machine utilization improve further. This offers clear advantages over the Use of a special glass. This must be in the smelting plant for the needed Charge a remelt made from one to the other type of glass become.

A possible variant of the invention may be characterized in that the glass material of the transition glass has the following constituents (in% by weight):

In particular, the glass composition may have the following constituents (in% by weight):

Join these transition glasses works well with the tungsten material of the current feedthrough wires and bulb glass.

A Good sealing is achieved in particular if provided is that the transitional glass over one Range of at least 8 mm, preferably 10 mm, in the axial direction of the current feedthrough wire extends.

The Invention will be described below with reference to an illustrated in the drawings embodiment explained in more detail. It demonstrate:

1 in side view a gas discharge lamp and

2 the gas discharge lamp gem. 1 in a prefabricated state.

The 1 shows a gas discharge lamp with a current guide 10 and a glass body 20 , The vitreous 20 includes a glass bulb 23 , a plate glass 21 (please refer 2 ) and a transitional glass 15 , The power supply 10 has two current feedthrough wires 14 made of tungsten. These are in the usual way outside of the glass body 20 surrounded space with a screw socket 24 contacted. Following the screw socket 24 are the power feedthrough wires 14 in the glass body 20 formed glass flask 23 introduced. The current feedthrough wires 14 are in the glass bulb 23 each with a conductor 11 connected. These form an arc unit 13 , To shield one of the conductors 11 against the arc area is an insulation 12 from z. B. ceramic material used.

The current feedthrough wires 14 are by means of the transition glass 15 in the glass bulb 23 introduced. The transitional glass 15 consists of a glass material with the following glass composition (% by weight):

This material has an expansion coefficient α (20 °, 300 °) of 3.68 [10 ^-6 / K].

To the transitional glass 15 is how this is the 2 makes it clearer, the vitreous body 20 connected. The plate glass 21 forms the transition between the glass bulb 23 and the transitional glass 15 , Here are plate glass 21 and glass flasks 23 fused together and consist of a glass with the following composition (% by weight):

This material has an expansion coefficient α (20 °, 300 °) of 3.24 [10 ^-6 / K].

In the 2 a prefabricated state is shown. Here is the glass body 20 already merged with the transitional glass. To the glass body 20 is a pump tube 22 formed.

For the production of in 1 shown gas discharge lamp is according to 2 preassembled unit with the glass bulb 23 added. This is via the power supply 10 slipped and with its open end to a connecting section 21a of the plate glass 21 stated. The glass bulb 23 can then with the plate glass 21 be merged. Because the glass bulb 23 and the plate glass 21 Made of the same material, this is easy. In particular, then short cooling rates and thus lower cycle times can be realized. As the 1 can recognize, is the Verschmelzübergangsbereich plate glass 21 - glass flask 23 arranged in the area in which the lamp socket 24 on the glass body 20 supported. Since a uniform material pairing is selected here, the gas discharge lamp is overall temperature change resistant.

Furthermore, you get a greater freedom in the frame design. After the plate glass 21 with the glass bulb 23 was gas-tight fused, the resulting cavity can be evacuated through the pump tube and then possibly filled with a gas.

Subsequently, the screw socket 24 mounted and with the current feedthrough wires 14 contacted.

Claims (9)

A gas discharge lamp with a glass body, which has a glass bulb, and having a flow guide enclosed by the glass bulb, the two current feedthrough wires, wherein the current feedthrough wires are connected in a gas-tight manner by means of a transition glass with the glass bulb and at least in the region of the transition glass of tungsten or a tungsten-containing material are formed, characterized in that the glass body ( 20 ) at least in the transition glass ( 15 ) is formed of a glass material having a linear thermal expansion coefficient α (20 °, 300 °) in the range between 2.9 and 3.5 [10 ^-6 / K], and that the transition glass ( 15 ) has a linear thermal expansion coefficient α (20 °, 300 °) in the range between 3.5 and 3.9. A gas discharge lamp with a glass body, which has a glass bulb, and having a flow guide enclosed by the glass bulb, the two current feedthrough wires, wherein the current feedthrough wires are connected in a gas-tight manner by means of a transition glass with the glass bulb and at least in the region of the transition glass of tungsten or a tungsten-containing material are formed, wherein the transition glass a plate glass is connected to the with a cavity enclosing the piston glass is fused, characterized in that the glass bulb ( 23 ) and the plate glass ( 21 ) consist of the same glass material and that the transition glass ( 15 ) from one to the bulb glass ( 23 ) is formed of different glass material. Gas discharge lamp according to claim 2, characterized in that the glass material of the glass bulb ( 23 ) and the plate glass ( 21 ) has a linear thermal expansion coefficient α (20 °, 300 °) in the range between 2.9 and 3.5 [10 ^-6 / K], and that the transitional glass ( 15 ) has a linear thermal expansion coefficient α (20 °, 300 °) in the range between 3.5 and 3.9. Gas discharge lamp according to one of claims 1 to 3, characterized in that the entire glass body ( 20 ) starting from the transition glass ( 15 ) Consistently made of a glass material. Gas discharge lamp according to claim 4, characterized in that the glass material of the glass bulb ( 23 ) contains the following constituents (in% by weight):

Gas discharge lamp according to claim 5, characterized in that the glass material of the glass bulb ( 23 ) contains the following constituents (in% by weight):

Gas discharge lamp according to one of claims 1 to 6, characterized in that the glass material of the transition glass ( 15 ) contains the following constituents (in% by weight):

Gas discharge lamp according to claim 7, characterized in that the glass material of the transition glass ( 15 ) contains the following constituents (in% by weight):

Gas discharge lamp according to one of claims 1 to 8, characterized in that the transition glass ( 15 ) over a range of at least 8 mm, preferably 10 mm, in the axial direction of the current feedthrough wire ( 14 ).