EP1812951A1 - Cold cathode fluorescent lamp - Google Patents

Abstract

The invention relates to a cold cathode fluorescent lamp (1), which essentially comprises a discharge vessel (3), whose interior is coated with a fluorescent material (2) and which contains a filler gas component that emits UV light, two or more hollow cathodes (4) consisting of a material from the group containing Mo, W, Nb, Ta and their alloys and two or more current feed pins (5) consisting of a material from the group containing Mo, W and their alloys. According to the invention, the current feed pin (5) is connected to a cup (6) or a sleeve (7), consisting preferably of Fe, Ni, Co or their alloys and the cup (6) or sleeve (7) is connected in turn to the hollow cathode (4).

Description

 COLD cathode fluorescent lamp

The invention relates to a cold cathode fluorescent lamp which essentially comprises a discharge vessel coated on the inside with a phosphor which contains a filling component emitting UV light, two or more hollow cathodes made of a material of the group Mo, W, Nb, Ta and their alloys, two or more current feed-through pins made of a material of the group Mo, W and their alloys.

Cold cathode fluorescent lamps are used as backlighting for liquid crystal displays. A low-pressure mercury discharge generates UV radiation, which is converted into visible light by a phosphor layer applied to the inside of the discharge vessel. The discharge vessel is usually made of hard glass, such as borosilicate glass, and is usually tubular. In the area of the pipe ends there are electrodes, which have different shapes depending on the lamp type. Through the use of emission-enhancing substances containing, for example, Ba, Sr, rare earth metals or yttrium and applied to the electrode surface, the electron work function can be reduced. The contacting of the electrodes is carried out by current feedthrough pins. These are connected in a vacuum-tight manner to the discharge vessel by means of a squeezing or melting process. This area is referred to as a glass-metal pinch seal. Usually, in a first step, the current feedthrough pin is provided with a glass bead, which is produced by the melting of a glass ring. This process is called glazing. Subsequently, the glass bead is connected to the discharge vessel by a crimping or melting process. As a material for the current feedthrough Fe-Ni-Co (Kovar) materials, molybdenum, tungsten with low, adapted to the glass thermal expansion coefficient is used. With the miniaturization of the liquid crystal screens is also a

Miniaturization of cold cathode fluorescent lamps has gone along. This has led to the introduction of hollow cathodes, as described in JP 1-51148. The material used for the hollow cathodes usually nickel is used. The Ni hollow cathode is welded to a current feedthrough made of Kovar. For further miniaturization, however, the sputtering resistance of nickel is insufficient. For this reason, sputter-resistant materials such as niobium, tantalum, tungsten or molybdenum have been proposed for hollow cathodes. These are connected to current feed pins made of molybdenum, tungsten or kovar. Molybdenum and tungsten are advantageous because of the high thermal conductivity. Due to the high melting point and the intrinsic brittleness of tungsten and molybdenum, direct welding is extremely difficult and only possible with great effort. In addition, a recrystallization and the associated embrittlement of the potty must be avoided. The amount of heat input should therefore be kept as low as possible. In addition, an accurate positioning of the individual components is of great importance in the connection process, since only so the tight tolerances of the component can be achieved.

The object of the subject invention is therefore to provide a cold cathode fluorescent lamp, both hollow cathodes and

Having current feedthrough pins with high sputtering resistance, wherein the combination of hollow cathode and current feedthrough is inexpensive and reliable feasible.

The object is solved by the characterizing part of claim 1. The hollow cathode is not connected directly to the current feedthrough pin, but the connection is made via a potty or a sleeve. The potty has an inner diameter which is slightly larger than the diameter of the current feedthrough pin. The height of the potty moves advantageously from 0.5x to 4x diameter of the potty. The potty is connected in a first process step either with the hollow cathode or with the current feedthrough pin. Potties such as hollow cathode each have a cylindrical and a bottom portion. The connection potty / hollow cathode takes place on the bottom side. The potty preferably consists of a material with a significantly lower melting point compared to the hollow cathode. The heat input can be done for example by means of laser or resistance welding and is in the case of hollow cathodes of molybdenum or tungsten so low that a melting and preferably also a recrystallization of the hollow cathode can be avoided. During the bonding process, however, the areas of the potty where heat is applied locally may melt.

The potty can also be initially connected to the current feedthrough pin. The potty is slipped over one end of the current feedthrough pin. The heat input, for example by means of laser or resistance welding, can be done on the cylinder or bottom side of the potty. After this first connection process, the second connection process of the component with hollow cathode or current feedthrough pin produced by the first connection step takes place in an analogous manner. With components produced in this way, the heat input can be kept very low, so that embrittlement is avoided. In addition, the positioning of the current feedthrough pin in the potty is easy. Cold cathode fluorescent lamps with the components according to the invention therefore show no reduction in the service life even when shaken.

These advantages can also be generated when using a sleeve. Under sleeve is to be understood as a tube open on both sides that, for example, may have a flange or areas with different diameters. An easily manufactured connection between current feedthrough pin and hollow cathode can be achieved with a sleeve having a cylindrical and a flange portion. The current feedthrough pin is inserted into the cylindrical region of the sleeve. The heat input for the connection process is again preferably by means of laser or Resistance welding technology. In this case, the inner wall of the cylindrical

Area connected to the current feedthrough pin. The flange of the sleeve is connected in a further process step with the bottom of the hollow cathode.

The sleeve can advantageously also have two regions with different diameters. The first region has a diameter which is slightly larger than the diameter of the current feedthrough pin. This area is in turn connected in an analogous manner to the current feedthrough pin. The second region has a diameter which is slightly larger than the diameter of the hollow cathode. This area is connected to the near-surface cylindrical portion of the hollow cathode. Of the

Connection process, for example, in turn, by means of heat input by laser or resistance technology, in turn, is to be performed so that a melting and preferably also a recrystallization of the hollow cathode can be avoided.

Typically, the current feedthrough pin is connected to a power supply pin. While the current feedthrough pin, the requirement for similarity of the expansion coefficients pin / glass significantly limits the choice of materials, this does not apply to the lamp outside power supply pin. Typically, a copper clad wire (Dumet) is used for the power supply pin. This is butt welded to the current feedthrough pin to a so-called combination lift. In terms of process technology, it is better to carry out the current feedthrough pin / lead pin connection before connecting the current feedthrough pin / hollow cathode, i. to use a combi-stick for the process described above. As particularly advantageous materials for pots and sleeves have proved Ni, Fe, Co and their alloys.

In the following the invention will be explained in more detail with reference to figures. FIG. 1 shows a schematic representation of a cold cathode fluorescent lamp FIG. 2 Connection according to the invention

Current feedthrough pin / hollow cathode in cross section FIG. 3 Connection according to the invention

Current feedthrough pin / hollow cathode in cross section Figure 4 Connection according to the invention Current feedthrough pin / hollow cathode in cross section

FIG. 1 shows the essential components of a cold cathode fluorescent lamp -1-, namely a discharge vessel -3- coated on the inside with phosphor -2-, the hollow cathode -4-, the current feedthrough pin -5- and the current supply pin -20-.

The preparation of the potty -6- and the sleeve -7- took place in all variants by deep drawing.

Production of a component according to Figure 2: The compound of the potty -6- with the hollow cathode -4- was through

Laser welding of the bottom surface -10- performed with the outer bottom surface -11 - the hollow cathode -4-. The subsequently inserted into the potty -6- power supply pin -5- was connected to the cylinder wall -8- of the potty -6- by laser welding. Alternatively, this was done by bonding to the inner bottom surface of the potty -10-.

A further variant was produced by first connecting the potty -6- with the power supply pin -5- by laser welding. The subsequent connection of the hollow cathode -4- with the potty -6- was also carried out by laser welding the bottom surface -10- of the potty -6- with the outer bottom surface -11- of the hollow cathode -4-.

Production of a Component According to FIG. 3: The connection of the sleeve -7- to the hollow cathode -4- was effected by laser welding of the flange -13- to the bottom surface -11 - of the hollow cathode -4-. The subsequently introduced into the cylindrical region -12- Stromdurchf ührungsstift -5- was welded to the cylindrical portion -12- the sleeve -7-.

Production of a Component According to FIG. 4:

In a further variant, the connection of the sleeve -7- was carried out with the current feed-through pin -5- by laser welding of the cylindrical portion -15- of the sleeve -7- with the power supply pin -5-. The subsequent connection of the hollow cathode -A- with the sleeve -7- was carried out by laser welding of the transition region -17- with the outer bottom surface -11- of the hollow cathode -A-. In a further variant, the inner cylinder wall -19- of the cylindrical portion -16- of the sleeve -7- was connected to the hollow cathode -4- by laser welding.

Claims

claims

1. cold cathode fluorescent lamp (1) essentially comprising a on the inside with phosphor (2) coated discharge vessel (3) containing a UV light-emitting filling gas component, two or more hollow cathodes (4) made of a material of the group Mo, W. , Nb, Ta and theirs

Alloys, two or more current feedthrough pins (5) from one

Material of the group Mo, W and their alloys, that the current feedthrough pin (5) with a potty (6) or a sleeve (7) and this (s) in turn with the hollow cathode (4) is connected.

2. cold cathode fluorescent lamp (1) according to claim 1, characterized in that the current feedthrough pin (5) with at least a portion of the inner cylinder wall (8) or inner bottom surface (10) of the potty (6) is connected and this in turn with its outer Bottom surface with the outer bottom surface (11) of the hollow cathode (4) is connected.

3. cold cathode fluorescent lamp (1) according to claim 2, characterized in that the inner diameter of the potty (6) is slightly larger than the diameter of the current feedthrough pin (5).

4. cold cathode fluorescent lamp (1) according to claim 2 or 3, characterized in that the height of the potty (6) is 0.5 to 4 x diameter of the potty (6).

5. cold cathode fluorescent lamp (1) according to claim 1, characterized in that the current feedthrough pin (5) with the inner cylinder wall (14) of the sleeve (7) having a cylindrical portion (12) and a flange (13) connected is and the flange (13) of the sleeve (7) with the outer bottom surface (11) of the hollow cathode (4) is connected.

6. cold cathode fluorescent lamp (1) according to claim 5, characterized in that the inner diameter of the cylindrical portion (12) of the sleeve (7) is slightly larger than the diameter of the current feedthrough pin (5) and the outer diameter of the flange (13) equal or smaller than the outer diameter of the hollow cathode (4).

7. cold cathode fluorescent lamp (1) according to claim 1, characterized in that the current feedthrough pin (5) with a sleeve (7) having a cylindrical first portion, (15), a cylindrical second portion (16) with a larger diameter and a in between

Transition region (17), on the inner cylinder wall (18) of the first region (15) is connected, and the inner cylinder wall (19) of the second region (16) is connected to the hollow cathode (4).

8. cold cathode fluorescent lamp (1) according to claim 7, characterized in that the inner diameter of the cylindrical first portion (15) of the sleeve (7) is slightly larger than the diameter of the current feedthrough pin (5) and the inner diameter of the cylindrical second portion (16). the sleeve (7) is slightly larger than the outer diameter of the hollow cathode (4).

9. cold cathode fluorescent lamp (1) according to one of the preceding

Claims, characterized in that the current feedthrough pin (5) is connected to a power supply pin (20).

10. cold cathode fluorescent lamp (1) according to one of the preceding

Claims, characterized in that the potty (6) or the sleeve (7) consists of a material of the group Ni, Fe, Co and their alloys.

11. cold cathode fluorescent lamp (1) according to any one of the preceding claims, characterized in that the potty (6) or the sleeve (7) in the region of the connection to the current feedthrough pin (5) and / or hollow cathode (4) has solidification areas.

12. cold cathode fluorescent lamp (1) according to any one of the preceding claims, characterized in that the hollow cathode (4) is designed in two or more parts.