EP1366545A1

EP1366545A1 - Flat fluorescent light comprising a contact system

Info

Publication number: EP1366545A1
Application number: EP02712774A
Authority: EP
Inventors: Friedrich Lauter; Matthias Schweizer
Original assignee: Patent Treuhand Gesellschaft fuer Elektrische Gluehlampen mbH
Current assignee: Osram GmbH
Priority date: 2001-03-08
Filing date: 2002-02-13
Publication date: 2003-12-03
Also published as: TW521457B; WO2002078132A1; CA2408194A1; US20030153206A1; DE10111191A1; US6743036B2; JP2004519086A

Abstract

The invention relates to a flat fluorescent light (1), comprising a discharge vessel that is composed of a base plate (3), face plate (4) and frame (5). A contact system (2) for connecting an electric power supply device by means of connection lines is integrated into the narrow side of the flat fluorescent light. An insulation body, provided with U-shaped contact sections is located between a section of the base plate (3) and face plate (4), said section acting as a receptacle and projecting beyond the frame (5) of the discharge vessel. The contact surfaces of the contact sections are connected to the electrodes of the flat fluorescent light by means of connection surfaces of the receptacle. The connection parts of the contact sections are connected to the connection lines.

Description

Flat spotlight with contact system

Technical field

The present invention relates to a flat radiator.

The term flat radiators here means radiators based on electrical gas discharges, in particular on the basis of dielectrically impeded gas discharges, with a flat geometry that sees electromagnetic radiation both in the invisible range, for example ultraviolet (UV) or infrared (IR) Radiation, as well as in the visible range, ie Light, emit. In the latter case, the term "flat lamp" is also used. The light can also be generated by converting UV radiation using phosphors.

In the case of the flat radiators designed for dielectrically disabled discharges, the usually strip-shaped electrodes are either separated from the gas filling serving as the discharge medium (one-sided or bilaterally dielectric discharge). Such electrodes are also referred to in the following as "dielectric electrodes". State of the art

A flat radiator for the backlighting of liquid crystal displays, so-called LCDs (Liquid Crystal Displays), is already known from WO 98/43277. This flat radiator has a base plate, a cover plate and a frame, which are connected to one another in a gas-tight manner by means of solder to form a discharge vessel. Structures similar to conductor tracks function as electrodes in the interior of the discharge vessel, as bushings in the lead-through area and as external current leads in the outer area. The flat radiator is connected to a pulse voltage source that functions as an electrical supply device via the power supply lines.

A disadvantage is the direct connection between flat radiator and supply device, which is less well suited for flexible and automated production of the system.

Presentation of the invention

It is an object of the present invention to provide an improved contact system for a flat radiator which is used for connection to an electrical supply device.

This object is solved by the features of claim 1. Particularly advantageous refinements can be found in the dependent claims directed thereon.

In addition, a flat radiator with the contact system according to the invention according to claims 9 to 13 and a system with such a flat radiator and an electrical supply device according to claim 14 are claimed. The electrical contact system according to the invention comprises a contact part with a U-shaped section, an insulating body on which the U-shaped section of the contact part is mounted and a receptacle for the insulating body with the mounted contact part. The U-shaped section of the contact part has two side walls and a connecting wall connecting these two side walls, the outside of the connecting wall forming a contact surface. The U-shaped section of the contact part partially encompasses at least a portion of the insulating body. The contact part also includes a connection part for an electrical connection line. The receptacle in turn comprises two plates or at least a partial area of two plates which are suitable for this purpose and which are arranged at least in sections at a distance from one another in parallel, and an electrical connection surface which is arranged on one of the two mutually facing surfaces of the two plates. The insulating body is arranged with the mounted contact part between the two plates in such a way that the contact surface of the contact part is in electrically conductive contact with the connection surface of the receptacle.

In order to increase the contact force between the contact surface of the contact part and the connection surface of the receptacle, a spring element is preferably arranged between the insulating body and the rear side of the U-shaped section of the contact part with respect to the contact surface. So that the contact part and the insulating body can press against the two plates (partial areas) of the receptacle by means of the force of this spring element, it is expedient, at least during assembly, to place the contact part only relatively loosely on the insulating body. Before installation in the receptacle, the insulating body and the contact part mounted on it are pressed together against the spring force of the spring element until both components can be inserted into the receptacle. After insertion, the compressed spring element can relax and the pre- build up the specified contact pressure. The spring element can be formed separately from the contact part, for example in the form of a helical spring, and can also be integrated in the contact part, for example in the form of a spring tongue, optionally also in one piece.

In order to secure the two components from unintentional mutual loosening, it is advantageous to provide the relevant area of the insulating body with at least one locking lug, preferably with one or two locking lugs on each side wall of this area. Correspondingly, one or possibly both side walls of the U-shaped section of the contact part are provided with corresponding openings for engaging the associated latching lugs of the insulating body.

Another advantage of using one or more spring elements in the manner described above is that tolerances in the distance between the plate sub-regions forming the receptacle can thereby be compensated for. In the course of the spring travel of the spring element, a pressing and consequently a contact between the contact surface of the contact part and the connection surface of the receptacle is ensured.

In order to facilitate a sliding assembly of the U-shaped contact part, it is also advantageous to provide the corresponding edges of the insulating body with a chamfer.

To improve the contact, the contact surface of the contact part can be soldered to the connection surface of the receptacle, for example by means of HF soldering. To support the soldering process, it can be helpful if the contact surface has at least one hole in or in which solder is deposited. The contact system is preferably equipped with more than one contact part, namely according to the number of corresponding connection surfaces of the receptacle or of the electrical connection lines provided. For example, two contact parts for two connecting lines are mounted on an insulating body in the aforementioned manner.

One or more of the contact systems according to the invention explained above are integrated in a narrow side of a flat radiator of the type mentioned at the beginning. In this way it is also possible, for example, to control a plurality of electrode groups within the flat radiator independently of one another instead of a single electrode system. In addition, it can be particularly advantageous for large flat radiators, for example with a 20 inch diagonal or more, to use more than one electrode group. In this way, the electrical supply of large emitters can be realized in a modular manner by ensuring the total electrical power consumption with the aid of several ballasts of lower power, each individual ballast feeding a group of electrodes provided for this purpose. Among other things, this has the advantage that the electrical ballasts of smaller flat radiators can be used for large flat radiators. For details regarding flat radiators with electrode groups, reference is also made to EP-A 0926 705.

Preferably, one or each contact system is integrated in a flat radiator in such a way that a receptacle for the respective contact system is formed by an associated part of the base plate and front plate that projects above the frame of the discharge vessel.

Typically, two electrodes or bus electrodes connecting multiple electrodes are routed from the inside of the discharge vessel to the outside of the electrode system or possibly each electrode group. The end piece of each electrode or bus conductor track serves as a connection surface of the receptacle and is preferably adapted to the shape of the contact surface of the contact part.

The insulating body mounted with the contact part or the contact parts is inserted in the portion serving as a receptacle between the base plate and the front plate in such a way that the or each contact surface is arranged in an electrically connecting manner over the corresponding end piece serving as a connection surface. The components of the contact system are preferably designed and dimensioned such that the entire contact system can be accommodated in the narrow side of the flat radiator within the receptacles provided for this purpose. This has the advantage that this narrow side of the flat radiator can be covered with a screen as protection against contact or for aesthetic reasons.

The complete lighting system additionally has at least one electrical supply device that is or are connected to the corresponding connection parts of the (respective) contact system by means of electrical connecting lines.

Description of the drawings

The invention is to be explained in more detail below using an exemplary embodiment. Show it:

Figure la is a schematic plan view of a flat radiator,

FIG. 1b shows a schematic side view of the flat radiator from FIG. 1 a with a contact system built into the narrow side of the flat radiator,

FIG. 2a shows an enlarged view of the narrow side of the flat radiator, which shows a partial area of the contact system, FIG. 2b shows a sectional illustration along the line AB of a part of the flat radiator from FIG. 2a,

FIG. 3a shows a side view of an insulating body of the contact system,

FIG. 3b shows a top view of the insulating body from FIG. 3a,

FIG. 3c shows an enlarged section of the side view from FIG. 3a, which represents the area of the insulating body provided for the assembly of the contact part,

3c shows an enlarged detail of the top view from FIG. 3b, which represents the area of the insulating body provided for the assembly of the contact part,

FIG. 4 shows the contact part of the contact system,

FIG. 5 shows a further embodiment of the contact part of the contact system,

Figure 6 shows a further embodiment of the contact part of the contact system.

Figures la, lb show a schematic plan view or side view of a flat radiator 1 based on a dielectric barrier discharge with a contact system 2 according to the invention. The inside of the discharge vessel of this flat radiator is coated with a phosphor layer and is particularly suitable for the backlighting of Liquid crystal screens (LCD). Since the details of the structure of the flat radiator are only of secondary importance for understanding the invention, reference is made to the already cited document WO 98/43277, in particular to FIGS. 3a, 3b with the associated description of the figures. The contact system 2 is integrated in a narrow side of the flat radiator 1, specifically outside the actual discharge vessel, which is defined by the base plate 3, front plate 4 and a frame 5 connecting the two plates, but between the part area which is extended beyond the frame 5 and serves as a receptacle the base plate 3 and the front plate 4.

This can be seen in more detail in FIGS. 2a, 2b, which show an enlarged representation of the partial region of the narrow side of the flat radiator with the contact system (partially) or a sectional representation along the line AB. There, the same features as in FIGS. 1 a, 1 b are provided with the same reference symbols. In addition to the partial area of the base plate 3 and the front plate 4 serving as a receptacle, the contact system comprises an elongated insulating body 6 and a total of four contact parts 7 made of sheet metal (material: CuSn 6; surface: NiZnPbAg coated). Each contact part 7 has a U-shaped section 8 on, which merges into an elongated connector 9.

For the following explanations, reference is also made to FIGS. 3a to 3d, which show different views of the insulating body 6 and FIG. 4, which shows a representation of the contact part 7.

The insulating body 6 made of polycarbonate with 20% glass fiber content has a total of four areas 10 with an essentially rectangular circumference. Each area 10 is provided for receiving the U-shaped section 8 in each case one of the four contact parts 7. For this purpose, each area 10 has two latching lugs 11 on its two mutually opposite sides, which snap into the associated rectangular openings 12 in the side walls of the U-shaped section 8 of the respective contact part 7 during assembly. Furthermore, each of the named areas 10 of the insulating body 6 is adjoined by an elongated cutout 13, into which the connection associated with the U-shaped section 8 is in each case in the assembled state. part 9 extends. In addition, each area 10 of the insulating body 6 is provided with a bore 14, in each of which a spring 15 is arranged in the assembled state. After installation of the contact system 2 in the part of the edge region of the flat radiator 1 serving as a receptacle, each spring 15 presses the insulating body 6 and the associated plugged-on contact part 7 apart and against the corresponding inside of the respective plate 3, 4 Contact surface 16 of the U-shaped section 8 of each contact part 7 with an associated connection surface 17 in an electrically conductive connection. In this respect, a total of four connection surfaces 17 are to be regarded as components of the receptacle. Each of these four connection surfaces 17 is developed from an end piece of an electrical bus conductor track applied to the inner wall of the base or front plate, which is in each case led outwards from the inside of the discharge vessel (not shown). Within the discharge vessel, each bus conductor track connects several strip-like electrodes, which are also applied to the inner wall of the base or front plate. For further details on the electrode structure, which is otherwise not directly related to the invention and on the dielectric coating of this electrode structure, reference is made to WO 98/43277, already cited. The shape of each connection surface 17 is largely adapted to the shape of the contact surface 16 of the corresponding contact part 7. To improve the contact, each connection area 17 is connected to the associated contact area 16 with the aid of an electrically conductive solder, for example by HF soldering. In this context, four bores 18 in the connecting wall of the U-shaped section 8 of the contact part 7, which comprises the contact surface 16 (only two bores are visible in the illustration in FIG. 4), serve to deposit additional soldering tin. Each connecting part 9 has two areas 9a, 9b which, in the assembled state, clamp the strand or the insulation jacket of a connecting line 19. enclose mend. The other end of each connecting line 19 is connected to an output pole of an electrical pulse source which is suitable for a pulsed active power coupling known from EP-A 0 733 266 as particularly efficient. Such electrical pulse sources are known, for example, from WO 99/05892. In this way, the two separate electrode groups (not shown) of the flat radiator 1 can be controlled separately via two connecting lines each.

FIG. 5 shows a representation of a further embodiment of the contact part of the contact system, the same features being provided with the same reference symbols. In contrast to the embodiment shown in FIG. 4, the contact part 20 has a leaf spring 21 which acts as a spring element. The leaf spring 21 is inserted in a rectangular recess in the connecting wall 23 of the U-shaped section 24 of the contact part 20 connecting the two side walls 22a, 22b. In addition, the leaf spring 21 is curved in the direction facing away from the contact surface 25 of the contact part 20. As a result, the coil spring 15 mentioned in the description of FIGS. 2a, 2b and 3a to 3d can be dispensed with, at least in the case of small tolerances in the distance between base plate 3 and front plate 4 (see also FIG. 2b).

FIG. 6 shows a representation of a further embodiment of the contact part of the contact system, the same features again being provided with the same reference symbols. Here, the connecting wall (and consequently also the contact surface which is not visible in FIG. 6) of the contact part 25 is divided into two parts 27a, 27b by means of an expansion joint 26. Only one of the two partial surfaces 27a, 27b is soldered to the connection surface 17 mentioned above. In absolute terms, this means that the elongation is less than in the case of a one-piece connecting wall, since a percentage elongation corresponding to a specific temperature change only affects the shorter length of the Partial area 27a or 27b relates. The expansion joint 26 has essentially the shape of an "H", although the transverse joint connecting the two longitudinal joints of this "H" has a stepped shape. This special shape of the transverse joint effectively prevents the helical spring 15 mentioned above from becoming jammed in the expansion joint 26 during assembly.

Claims

claims

1. Electrical contact system with

• a contact part (7; 20) with o a U-shaped section (8; 24), comprising two side walls and a connecting wall connecting these two side walls, the outside of the connecting wall having a contact surface (16; 25), o one Connection part (9) for an electrical connection line,

An insulating body (6), on which the U-shaped section (8; 24) of the contact part (7; 20) is mounted and which partially encompasses at least a partial area of the insulating body (6),

• A receptacle for the insulating body (6) with the mounted contact part (7; 20), with

o two plates (3, 4) or at least part of two plates (3, 4), which are arranged at least in sections parallel to one another at a distance from one another, o an electrical connection surface (17) which is on one of the two mutually facing surfaces of the two plates (3, 4) is arranged,

wherein the insulating body (6) with the contact part (7; 20) is arranged between the two plates (3, 4) such that the contact surface (16; 25) of the contact part (7; 20) with the connection surface (17) of the receptacle is in electrically conductive contact.

2. Contact system according to claim 1, wherein the cross section of the insulating body (6) at least in the intended for the contact part (7; 20) loading rich (10) is essentially rectangular and at least one side wall of the insulating body (6) within this area (10) has at least one latching lug (11) and at least one side wall of the U-shaped section (8; 24) of the contact part (7; 20) at least one opening (12) for engaging an associated locking lug (11) of the

Have insulating body (6).

3. Contact system according to claim 1 or 2, wherein the contact part (7; 20) is made of the material CuSn 6 and the surface of the contact part (7; 20) consists of NiZnPbAg.

4. Contact system according to claim 1, 2 or 3, wherein the contact surface (16; 25) of the contact part (7; 20) is soldered to the connection surface (17) of the receptacle.

5. Contact system according to one of claims 1 to 4, wherein between the insulating body (6) and the rear side with respect to the contact surface (16; 25) of the U-shaped section (8; 24) of the contact part (7; 20)

Spring element (15; 21) is arranged.

6. Contact system according to one of the preceding claims, wherein the edges of the insulating body facing the U-shaped contact part have a chamfer for a sliding assembly of both components.

7. Contact system according to one of the preceding claims, wherein the

Insulating body (6) made of polycarbonate with 20% glass fiber.

8. Contact system according to one of the preceding claims with more than one contact part (17; 20).

9. Flat heater (1) with

• a discharge vessel enclosing a discharge medium with o a base plate (3), a front plate (4) and a frame (5) which connects the two plates (3, 4) in a gas-tight manner, o electrodes which on the surface of at least the Base plate are arranged,

• characterized by at least one contact system (2) according to one of claims 1 to 8.

10. Flat radiator according to claim 9, wherein the receptacle of the contact system is formed by a part of the base plate (3) and front plate (4) standing above the frame (5).

11. Flat radiator according to claim 10, wherein at least one electrode or optionally a multiple electrode connecting bus line from the

Is guided inside the discharge vessel to the outside and is further developed there on the protruding part of the base plate (3) or front plate (4) as a connection surface (17) for receiving the contact system (2).

12. Flat radiator according to one of claims 9 to 11, wherein the contact system (2) comprises two or more contact parts (7; 20) which are mounted on a common insulating body (6).

13. Flat radiator according to one of claims 9 to 11, wherein the electrodes are strip-shaped and for the purpose of generating a die- Electrically impeded discharge at least part of it are separated from the discharge medium by a dielectric layer.

14. Lighting system with a flat radiator according to one of claims 9 to 13, wherein the connecting part of the contact part of the contact system via electrical connection lines with an electronic

Supply device is connected.