The invention relates to a halogen incandescent lamp in accordance with the precharacterizing clause of patent claim 1.
Such a mini system voltage halogen lamp is described, for example, on the Internet domain www.osram.de under the product designation “OSRAM HALOPIN®”. Bulb pinch technology is used with this halogen incandescent lamp in order to obtain a robust lamp. Owing to the small size and owing to the possibility for use without a protective cover, this mini system voltage halogen lamp makes filigree halogen luminaires possible with a simple design. The bulb pinch technology is described in detail in the European patent specification EP 0 446 460 B1.
In order to increase the efficiency of a halogen incandescent lamp, it is known to those skilled in the art from, for example, the laid-open specification U.S. Pat. No. 6,111,344 to apply a coating which reflects IR radiation to a lamp bulb which satisfies special design requirements.
Owing to the design of the lamp bulb using bulb pinch technology which is very different from the design in the laid-open specification U.S. Pat. No. 6,111,344, those skilled in the art do not consider a coating which reflects IR radiation on a lamp bulb of a halogen incandescent lamp for which bulb pinch technology is used for significantly increasing the efficiency.
The invention is based on the object of providing a halogen incandescent lamp with which the luminous efficiency is increased given the same life and of providing a method for its production.
This object is achieved according to the invention by the features of claim 1. Particularly advantageous embodiments of the invention are described in the dependent claims.
The electrical incandescent lamp according to the invention has a lamp vessel which is sealed at one end, in which at least one luminous element is accommodated, and which has two essentially rotationally symmetrical lamp vessel structural parts. Each of the lamp vessel structural parts surrounds a luminous element limb at least in sections, and the axes of the lamp vessel structural parts are designed to be spaced apart from one another. Such a design makes it possible to optimize the thermal performance of the luminous element and to operate the incandescent lamp in a more energy-efficient manner.
At least one wall face of the lamp vessel structural parts is preferably provided at least partially with a layer which reflects IR radiation, as a result of which the IRC effect is improved in the incandescent lamp and thus less energy needs to be supplied from the outside in order to bring the luminous element to the operating temperature.
In accordance with one advantageous design, the lamp vessel structural parts intersect one another. The overall size of the electrical incandescent lamp can thus be reduced.
One improvement in terms of production and with respect to a more uniform reflection onto the luminous element can be achieved by an essentially cylindrical design of the lamp vessel structural parts.
A robust lamp design can be achieved by the use of retaining pinches directly in the lamp bulb, in which case a long life is ensured even in the event of the lamp being subjected to a mechanical load. The use of the present invention is not restricted to the pinch-sealing technology, however, but the abovementioned design of the lamp vessel structural parts can also be used in luminous elements which are fixed in position by means of a support frame.
The axial extent of the luminous element limbs in the lamp vessel structural parts, in particular the extent of the luminous element limbs along the respective central axis of the lamp vessel structural parts, has an advantageous effect. The reflection of heat onto the luminous element is thereby brought to an optimum value.
In one method according to the invention for producing an abovementioned incandescent lamp, deformation of the lamp vessel so as to form the two lamp vessel structural parts is carried out at the same time as the main pinch sealing, with the result that a short production time is maintained.
The application of the layer which reflects IR radiation preferably takes place after deformation of the lamp vessel, while the pinch sealing is carried out prior to deformation. It is thus possible to effectively produce an energy-optimized incandescent lamp.
The invention will be explained in more detail below with reference to a preferred exemplary embodiment. In the figures:
As shown in
Arranged in the lamp vessel 2 is a luminous element 14 which, in the exemplary embodiment described, is designed to have two luminous element limbs 16, 18, on which the filament sections 16a, 18a are located which are connected to one another via a connecting part 20. As can be seen in
The two power supply lines 22, 24 embedded in the base 4 are not stable enough to hold the two luminous element limbs 16, 18 in their predetermined relative position within the bulb 8. Retaining pinches 34, 36 are therefore formed on the lamp vessel 2 approximately at the height of the connecting part 20, said retaining pinches 34, 36 being arranged, in the illustration shown in
In the exemplary embodiment illustrated, the bulb 8 has two intersecting, cylindrical bulb structural parts 42, 44 adjacent to the circumferential bevel 6, the luminous element limbs 16, 18 being arranged along the central axes of said bulb structural parts 42, 44. The intersecting, cylindrical bulb structural parts 42, 44 form essentially the shape of an eight in the sectional view in
In the region of the cylindrical bulb structural parts 42, 44, an infrared coating (IRC) is applied to the wall surface 42a, 44a of the bulb 10, by means of which infrared coating the heat is reflected back onto the luminous element limbs 16, 18. Owing to such a reflection, the heat remains within the lamp and less energy needs to be supplied from the outside in order to bring the luminous element limbs 16, 18 to the temperature.
The retaining pinches 34, 36 are each formed with an approximately elliptical cross section, whose longitudinal axis overlaps that region 38 of the connecting part 20 which is arranged horizontally in
During manufacture, once the luminous element 14 has been introduced into an unmachined quartz-glass part, initially the retaining pinches 34, 36 are pinched in order to retain the luminous element 14. Then, the bulb 8 is deformed such that the two intersecting bulb structural parts 42, 44 are obtained, the luminous element limbs 16, 18 with the filaments extending axially with respect to a respective bulb structural part 42, 44. At the same time as the bulb is deformed, the main pinch sealing takes place, with which the base 4 is formed. Subsequently, an exhaust tube is attached to the exhaust tube attachment 12, by means of which exhaust tube the interior of the bulb 8 is evacuated and is filled with a filling gas containing halogens. The high luminous efficiency owing to the infrared coating is assisted by a xenon gas filling. After filling, the exhaust tube is removed and fusing takes place so as to form the exhaust tube attachment 12.
The application of the present invention is not restricted to incandescent lamps having retaining pinches, but the rotationally symmetrical, preferably cylindrical design of the lamp vessel structural parts 42, 44 can also be applied to other lamps, such as lamps having a support frame.
Improved thermal recovery can even be achieved when the bulb 8 or the lamp vessel structural parts 42, 44 is/are only partially coated with the infrared coating.
The luminous element limbs 16, 18 preferably extend along the central axis of the lamp vessel structural parts 42, 44. An improvement in luminous efficiency can also be achieved if the luminous element limbs 16, 18 extend essentially parallel to the central axis of the lamp vessel structural parts.
In the exemplary embodiment described above, the lamp vessel structural parts 42, 44 have the same outer diameter, but it is also possible for different outer diameters to be used for the lamp vessel structural parts 42, 44 and it is possible for the outer diameter of the respective lamp vessel structural part 42, 44 to change over its axial extent, such as in the form of a truncated cone design.
The present invention relates to an electrical incandescent lamp, in particular a halogen incandescent lamp, in which luminous element limbs extend in lamp vessel structural parts, the lamp vessel structural parts surrounding the luminous element limbs in sections at a distance, and the axes of the lamp vessel structural parts extending at a distance from one another in order to increase the energy efficiency of the incandescent lamp, in particular if a layer which reflects IR radiation is applied to the lamp vessel structural parts. When using the pinch-sealing technology, it is possible to achieve a small system voltage halogen lamp having a long life expectancy and at the same time requiring little energy for reaching the operating temperature.
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10 2005 019 113 | Apr 2005 | DE | national |
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