WO2010112315A1 - Electrical lamp having an outer bulb - Google Patents

Abstract

The invention relates to an electrical lamp (1) having an inner bulb (2) which is closed on two ends by means of seals (5), the inner bulb having a lamp axis, and a lighting device being accommodated in the inner bulb. The inner bulb is surrounded by an outer bulb (3), said outer bulb having two ends that are directly connected to the seals of the discharge vessel. The outer bulb has two narrowed sections (10) to prevent convection.

Description

Title: Electric lamp with outer bulb

Technical area

The invention relates to an electric lamp with an outer bulb according to the preamble of claim 1. Such lamps are in particular high-pressure discharge lamps or halogen incandescent lamps.

State of the art

DE-A 103 25 552 describes a high-pressure discharge lamp with an outer bulb, in which an outer bulb is applied to an inner bulb. The outer bulb has a small constriction on one side. This serves to fix a getter in the outer bulb.

Presentation of the invention

The object of the present invention is to provide an electric lamp with outer bulb, are largely avoided in the high energy losses in the outer bulb.

This object is achieved by the characterizing features of claim 1.

Particularly advantageous embodiments can be found in the dependent claims.

Quartz glass electric lamps with inner pistons and outer pistons, in particular discharge lamps which are closed on both sides, generally suffer high energy losses due to free convection in the outer bulb and a Increasing the temperature caused by the outer bulb in the region of the open side of the film seal towards the free environment. The surrounding atmosphere is air here. This seal is usually a meltdown or pinch.

Previously, the temperature load was kept within limits by relatively long Einschmelzbereiche or by significantly more expensive designs of the lamp, for example, with vacuum and getter in the outer bulb or separately led out through additional Folieneinschmelzungen electrical connections.

According to the convection in a gas-filled atmosphere of the outer bulb is so strongly suppressed by a suitable shaping of the outer bulb, that the central lamp region in which the discharge vessel is located, reaches significantly higher temperatures.

The lower heat losses significantly increase the efficiency η (lm / W). As the final temperatures of the films are reduced, the area of the seal can be simplified, in particular by shortening the length of the film.

The shape of the outer bulb is such that a radially encircling constriction of the outer bulb is provided. This is to be installed in the area of the sealing of the inner piston. Preferably, the center of the constriction is attached at the level of the inner end of the film in the seal of the inner piston. The constriction should preferably be designed so that here the distance TF between the discharge vessel and outer bulb in the range of 0.5 mm ≤ TF ≤ 2 mm. The outer bulb has preferably two symmetrical spaced constrictions to its center. It depends less on the concrete shape of the constriction than on the depth F.

In particular, the depth F of the constriction should be seen from the radial outer edge of the outer bulb, ie the value of F = T-A, at least 40% of the depth T of the outer bulb until the seal out. This achieves a particularly effective prevention of convection. The seal is preferably a meltdown. In the case of a pinch, this dimension applies to the broad side of the pinch.

In particular, the width of the constriction should correspond at most to the depth TF at the most, rather less.

The outer bulb preferably has two symmetrical constrictions. It depends less on the concrete shape of the constriction than on the depth F.

The constriction is preferably radially symmetrical and thus creates all-round symmetrical temperature conditions during a melting process. In particular, when using bruises but the constriction can also be designed less symmetrical.

With suitable dimensioning of the two constrictions, the discharge vessel during operation is much more isothermal than without. In this case, a significant improvement of the isotherm is achieved when the depth F is at least 40%, good conditions can be achieved with 50 to 60%.

In a particularly preferred embodiment, the discharge vessel is characterized even better and more targeted and isothermal heated, that on the area of the outer bulb, which lies between the two constrictions, a reflection layer for the heat radiation is applied. Usually, for such a layer, an infrared coating (IRC) is used as known per se, this reflects the heat radiation back, while the visible radiation can pass through almost unhindered.

In a very particularly preferred embodiment, the center region of the outer bulb is designed so that it is adapted to the contour of the inner piston. In this way, the isotherm of the inner piston is further improved. The reflection of the heat radiation then heats the discharge vessel more effectively.

At best, both measures are mixed together. It is particularly sufficient if only one edge zone of the central region is provided with the coating, because the coldest regions are at the ends. In particular, a rule of thumb is that the marginal zones each make up one-third of the axial length of the central region.

In principle, a normal reflection layer can be used, but this is accompanied by a certain loss of light. When using an IRC layer plus the custom-fit center area of the outer bulb, the highest efficiencies (lm / W) can be achieved. They are at least 10% higher than normal lamps without constriction of the outer bulb.

The outer bulb filling can optionally be vacuum, nitrogen (50 mbar - 800 mbar), argon (50 mbar - 800 mbar) or noble noble gases and their mixtures or air (normal pressure, open system).

Typical applicable IRC layers are, as is known, systems of at least 20 pairs of layers, typically 50 to 90, of alternating high and low refractive index layers of SiO 2 and tantalum pentoxide or niobium pentoxide.

The shape of the constriction can in particular be chosen so that stresses between the discharge vessel and outer bulb are largely avoided. Such voltages are usually the result when a discharge vessel (in particular of quartz glass) and an outer bulb (in particular of quartz glass or hard glass ????) are directly connected to one another at two ends by fusion, etc. Both during manufacture and operation, very high stresses occur in the glass, which can easily lead to total failure. Typical are a ring jump on the outer bulb or a shank tear at the discharge vessel. With shaft here is meant the seal.

This problem can be solved within certain limits by choosing the thickness of the two materials for inner piston and outer bulb. However, even then there remains a certain amount of error, which is noticeable only after a long burning time.

Through a targeted shaping of the constriction, the tension forces caused by the different thermal expansion are reduced to a minimum. In this case, thin surfaces are formed substantially perpendicular to the direction of the stress, which then easily deformed without irreversible damage, much like a thin membrane buckles under pressure.

Low voltages between the outer bulb and discharge vessel reduce rejects and prevent early failures. The mechanical decoupling of the two pistons results in an increased degree of freedom in the design of the two components and a possibility of their optimization in relation to their actual tasks.

Only then is an optimized design of the piston possible.

The membrane effect can be achieved by steep, thin-walled end faces (essentially perpendicular to the lamp axis) on the outer bulb or by specific punctures in the outer bulb. Preferably, however, the constriction is designed as a puncture. It then lies in the middle region of the outer bulb and accordingly has two side walls approximately perpendicular to the longitudinal axis of the lamp and a base therebetween. The side walls are at production position as a puncture, curl oa. noticeably thinner than the other wall thickness of the outer bulb and therefore have the desired membrane effect.

Brief description of the drawings

In the following, the invention will be explained in more detail with reference to several embodiments. The figures show:

1 shows a first embodiment of a metal halide lamp with a straight outer bulb; FIG. 2 shows an exemplary embodiment of a halogen incandescent lamp; FIG.

Fig. 3 shows an embodiment of a metal halide lamp with a molded outer bulb;

4 shows a further embodiment of a metal halide lamp with a shaped outer bulb.

Figure 5 shows an embodiment according to the prior art;

6 shows an embodiment of a metal halide lamp with constrictions of the outer bulb shaped as punctures.

Preferred embodiment of the invention

1 shows a metal halide lamp 1. It consists of a discharge vessel 2 made of quartz glass, which is held along a longitudinal axis A in an outer bulb 3 made of quartz glass. The discharge vessel 2 consists of a bulbous central part 4 with electrodes 15 mounted therein and two seals 5 attached thereto, which are designed as melts. The outer bulb 3 has centrally a maximum diameter at the level of the discharge vessel. It has two ends 6 of reduced diameter, which extend in the direction of the seals 5. In the concrete embodiment, the end 6 of the outer bulb sits directly on the seal. The seals 5 have outside a tubular extension part 7, in which a base part 18 is inserted. The seals 5 each include a foil 8 to which the shaft of the electrode 15 is fixed inwardly and a power supply 16 is mounted outwardly. The discharge vessel has, for example, a filling of metal halides as known per se.

The outer bulb 3 has, in principle, a depth T up to the melting point 5. It also has a radial constriction 10 approximately at the level of the inward end of the foil 8, which may be approximately V-shaped, U-shaped or parallel in cross-section , It has two sloping or nearly vertical side walls and a base part between the side walls. The smallest distance TF is reached at the base part and is at most 50% of the value of T. The outer bulb has two symmetrical constrictions of this kind, which reduce the convection and thus improve the isotherm of the discharge vessel.

Figure 2 shows a halogen incandescent lamp 20 which is designed quite similar, but it has no electrodes, but a luminous element 21 in the interior of the inner piston.

FIG. 3 shows an exemplary embodiment of a lamp 30 in which the central region 31 of the outer bulb, that is to say the region between the two constrictions 10, is adapted in its contour to that of the inner bulb 2. The distance between the two pistons 2, 31 is chosen as narrow as possible, so that the contour begins at the base 11 of the constriction.

FIG. 4 shows an exemplary embodiment similar to FIG. 3, but in each case a radially encircling edge zone 41 is coated at both ends of the central region 31 with an infrared-reflecting coating 42 of interference filter layers (IRC coating). The axial length of the two edge zones is preferably maximum one third of the axial length of the entire center region 31. Typically, their length is 20 to 30% each.

The production of such shaped outer bulb takes place by rolling with forming wheels or takes place similarly as described in DE-A 103 25 554. In this case, a suitable overpressure in the outer bulb is used with simultaneous heating of the middle region in order to form the middle region plus constrictions.

FIG. 5 shows an outer bulb 45 whose end regions have been shaped by means of a puncture, but without constrictions. This achieves a membrane effect on the outer edge.

A significantly better membrane effect is achieved according to FIG. 6, when the outer bulb is provided with two constrictions 47 according to the invention. These constrictions can be formed as punctures, or by curling or molding, in particular with side walls 49 and base 48. The constriction is substantially preferably U- or V-shaped. The side walls 49 are preferably considerably thinner than the wall thickness in the cylindrical region 50 in the middle of the outer bulb.

The discharge vessel has, for example, a filling of metal halides as known per se. Furthermore, two electrodes are arranged in the discharge vessel, between which the discharge arc burns.

Essential features of the invention in the form of a numbered list are: An electric lamp having an elongated inner piston, a central part sealed on two sides with seals, the seals including foils, and wherein the inner piston has a longitudinal axis, and wherein a bulb is housed in the inner bulb, and wherein the inner bulb is surrounded by an outer bulb, characterized in that the outer bulb has two constrictions in the radial direction, which are each arranged within the outer end of the film, so that between the constrictions is a central region of the outer bulb.

2. An electric lamp according to claim 1, characterized in that the constriction is arranged axially so that it covers the front, the discharge end facing the film, and in particular its center is equal to this end.

3. An electric lamp according to claim 1, characterized in that the depth of the Einschürung corresponds to at least 50% of T, when T is the largest distance between the outer bulb and the seal.

4. Electric lamp according to claim 1, characterized in that the minimum distance between the seal and constriction is 0.5 to 2 mm.

5. Electric lamp according to claim 1, characterized in that the seal is a meltdown. 6. An electric lamp according to claim 1, characterized in that the constrictions are arranged symmetrically to the center of the inner piston.

7. An electric lamp according to claim 1, characterized in that the central region is tube-shaped.

8. An electric lamp according to claim 1, characterized in that the central region is adapted in its contour of the contour of the underlying part of the inner piston.

9. An electric lamp according to claim 1, characterized in that the contour of the inner piston is bulbous.

10. An electric lamp according to claim 1, characterized in that the center region is provided at least in sections with an infrared-reflecting coating.

11. An electric lamp according to claim 1, characterized in that the constriction is formed as a recess, wherein the wall thickness in the region of the constriction is less than the wall thickness in the central region.

Claims

claims

An electric lamp having an elongated inner piston, a central part sealed on two sides with seals, the seals including foils, and wherein the inner piston has a longitudinal axis, and wherein a bulb is housed in the inner bulb, and wherein the inner bulb is surrounded by an outer bulb, characterized in that the outer bulb has two constrictions in the radial direction, which are each arranged within the outer end of the film, so that between the constrictions is a central region of the outer bulb.

2. An electric lamp according to claim 1, characterized in that the constriction is arranged axially so that it covers the front, the discharge end facing the film, and in particular its center is equal to this end.

3. An electric lamp according to claim 1, characterized in that the depth of the Einschürung corresponds to at least 50% of T, when T is the largest distance between the outer bulb and the seal.

4. Electric lamp according to claim 1, characterized in that the minimum distance between the seal and constriction is 0.5 to 2 mm.

5. Electric lamp according to claim 1, characterized in that the seal is a meltdown.

6. An electric lamp according to claim 1, characterized in that the constrictions are arranged symmetrically to the center of the inner piston.

7. An electric lamp according to claim 1, characterized in that the central region is tube-shaped.

8. An electric lamp according to claim 1, characterized in that the central region is adapted in its contour of the contour of the underlying part of the inner piston.

9. An electric lamp according to claim 1, characterized in that the contour of the inner piston is bulbous.

10. An electric lamp according to claim 1, characterized in that the center region is provided at least in sections with an infrared-reflecting coating.

11. An electric lamp according to claim 1, characterized in that the constriction is formed as a recess, wherein the wall thickness in the region of the constriction is less than the wall thickness in the central region.