DE102008022144A1 - Incandescent lamp e.g. H7 lamp, for use in motor vehicle head lamp, has lamp container provided with infrared radiation reflecting coating that is arranged on region of cylindrical container section circularly enclosing glow filament - Google Patents

Abstract

The lamp has a translucent lamp container (1) with a cylindrical container section (10), and a glow filament (3) arranged within the cylindrical container section. A roller axis (30) is aligned parallel to a cylinder axis of the cylindrical container section. The lamp container is provided with an infrared radiation reflecting coating (9) that is arranged on a region (11) of the cylindrical container section circularly enclosing the glow filament. Breadth and/or height of the region of the cylindrical container section corresponds to length of the glow filament.

Description

The The invention relates to an incandescent lamp according to the Preamble of claim 1.

I. State of the art

Such a light bulb is for example in the patent US 4,701,663 disclosed. This document describes a halogen incandescent lamp with a substantially cylindrical lamp vessel and an axially oriented therein filament. The complete outer surface of the lamp vessel is provided with a designed as interference filter, infrared radiation reflective coating to reflect the emitted from the filament infrared radiation back to the coil and to use for heating the filament and thus the efficiency of the lamp or the color temperature of the of Lamp to increase light emitted.

at Incandescent lamps for use in vehicle headlights provided with a light-dark boundary, such Infrared radiation reflective coating can not be used because it also reflects low levels of visible light, which cause increased light scattering at a figure of the filament in the optical system of Headlamps for the creation of bright-dark borders to increased glare leads.

II. Presentation of the invention

It is the object of the invention, a generic To provide incandescent lamp, on the one hand by the Incandescent filament or incandescent filaments generated infrared radiation can be used to increase efficiency and on the other the caused by the infrared radiation reflective coating, aforementioned disadvantages in terms of increased light scattering and increased glare levels are largely avoided.

These Task is performed by a light bulb according to the Claim 1 solved. Particularly advantageous designs The invention are defined in the dependent claims listed.

The Light bulb according to the invention has a translucent lamp vessel with a cylindrical vessel section and at least one Filament inside the cylindrical vessel section is arranged and the winding axis parallel to the cylinder axis aligned the cylindrical vessel section is, wherein the lamp vessel with an infrared radiation reflective coating is provided. Extends according to the invention the infrared radiation reflective coating does not overflow the complete surface of the lamp vessel, but is on a at least one filament annular enclosing portion of the cylindrical lamp vessel portion limited.

It has been shown to increase the efficiency of the incandescent lamp essentially only those infrared rays contribute that are perpendicular be emitted to the winding axis of the filament, since substantially only these infrared rays are reflected by the infrared radiation Coating reflected back to the filament be used and thus for heating the filament can be. Infrared rays, however, oblique to be emitted to the winding axis of the filament, meet generally after their reflection on the infrared radiation reflective No longer coating on the filament, but happen the cylinder axis of the cylindrical lamp vessel section above or below the filament. To increase the efficiency of Light bulb therefore satisfies an infrared radiation reflective Coating on an annular at least one Filament surrounding lamp filament section is limited. In addition, the reduction contributes the provided with the infrared radiation reflective coating Lamp vessel surface also to a corresponding Reduction of light scattering at.

advantageously, corresponds to the width or Height of the at least one filament annular enclosing portion of the cylindrical vessel portion essentially the length of the at least one filament. In incandescent lamps according to the invention with two or more axially oriented filaments can either For each filament a separate one, the corresponding filament annularly enclosing, provided with the infrared radiation reflective coating Lamp vessel section be provided or a single, all filaments spirally enclosing, provided with the infrared radiation reflective coating Lamp vessel section be provided.

Preferably, the infrared radiation reflective coating is interrupted at at least one location to further reduce light scattering and to increase the light transmission of the lamp vessel at that location or to avoid unwanted reflection of visible portions in the opposite direction. The infrared radiation-reflecting coating according to the invention therefore preferably does not form a closed ring around the at least one incandescent filament, but only a ring segment which extends along a circumferential angle of less than 360 degrees on the surface of the cylindrical lamp vessel section. According to the particularly preferred embodiment of the invention, the infrared radiation reflecting Be extends layering over a plurality of ring-segment-shaped sections which are arranged along the region of the cylindrical lamp vessel section which encloses the at least one incandescent filament and are separated from one another by uncoated regions of the lamp vessel surface.

The Infrared radiation reflective coating of the invention Incandescent lamp is advantageously designed as interference filter coating. It can thus the known per se techniques for the production of interference filters for the invention Incandescent lamp to be used.

The Infrared radiation reflective coating is from manufacturing technology Reasons preferably on the outside of the lamp vessel appropriate. In the case of one filled with halogen additives Lamp vessel offers one on the outside the lamp vessel arranged Infrarotstrah ment reflective coating has the further advantage that it does not is exposed to the corrosive attack of the halogen additives.

Preferably the winding axis of the at least one filament is parallel offset from the cylinder axis of the cylindrical lamp vessel section, thus mirror images of the filament caused by light reflection be caused on the lamp vessel, only in one Area can arise for the optical Illustration of the filament in the headlight does not matter. On the other hand, the distance between the winding axis of the filament must and the cylinder axis be chosen so that still a heating the filament is reflected by the infrared radiation Coating is possible. Because of this, the distance is between the winding axis of the at least one filament and the cylinder axis of the cylindrical lamp vessel section less than or equal to the outside diameter of the at least a filament to ensure that the reflected on the infrared radiation reflective coating Infrared rays still on the filament surface incident.

III. Description of the Preferred Embodiment

below the invention is based on a preferred embodiment explained in more detail. Show it:

1 A side view of a preferred embodiment of the light bulb according to the invention in a schematic representation

2 A cross section through the in 1 illustrated incandescent lamp along the plane AA in a schematic representation

3 A longitudinal section through the 1 Pictured light bulb in a schematic representation

In 1 schematically a halogen incandescent lamp for a motor vehicle headlight according to the preferred embodiment of the invention is shown. This halogen bulb is a so-called H7 lamp, which is intended for operation at a nominal voltage of 12 volts in a motor vehicle. The power consumption of this lamp is at an operating voltage of 13.2 volts about 55 watts.

This halogen incandescent lamp has a quartz glass or hard glass, for example aluminosilicate glass, existing lamp vessel 1 At one end with a pedestal 2 is provided and the other end of an opaque dome 8th is formed. Outside the dome 8th and the pedestal 2 owns the lamp vessel 1 a circular cylindrical vessel section 10 , Inside this lamp vessel section 10 is an axially oriented filament 3 arranged, whose spiral outlets 31 . 32 each with a power supply wire 4 . 5 made of molybdenum are welded. The winding axis 30 the filament 3 is offset parallel to the cylinder axis of the circular cylindrical lamp vessel section 10 arranged, wherein the distance between the winding axis and the cylinder axis, however, smaller than the outer diameter of the filament 3 is. The outer diameter of the filament 3 is in the range of about 1.4 millimeters to 2.1 millimeters. The two power supply wires 104 . 105 are each electrically conductive with one from the socket 2 outstanding electrical connection 6 . 7 connected to the lamp.

The filament 3 annularly enclosing area 11 of the circular cylindrical lamp vessel section 10 is on its outside with a translucent, infrared radiation-reflecting interference filter 9 Mistake. The interference filter 9 consists of a sequence of alternating optically low and optically high refractive index layers, such as silicon dioxide layers and titanium dioxide layers. The width or height H of the filament 3 annularly enclosing area 11 and the interference filter coating 9 corresponds essentially to the length of the filament 3 and is in the range of about 4.0 millimeters to 6.5 millimeters.

The interference filter coating 9 does not extend over the entire filament 3 annularly enclosing area 11 of the circular cylindrical lamp vessel section 10 but forms ring segments 91 . 92 . 93 . 94 off, along the aforementioned area 11 arranged on the lamp vessel surface and in each case by uncoated sites 12 . 13 . 14 . 15 the lamp vessel surface are separated from each other. The arrangement, number and size of these uncoated spots 12 . 13 . 14 . 15 depends on the specific application of the lamp and the design of the optical system of the headlamp, in which the lamp is used. The uncoated spots 12 . 13 . 14 . 15 correspond to the light emission directions and reflector surfaces in the headlight, which are important for generating the light-dark boundary of the optical system. The size and arrangement of uncoated spots 12 . 13 . 14 . 15 between the reflective with the infrared radiation coating 9 provided ring segments 91 . 92 . 93 . 94 is determined by the angles α1, α2, β1 and δ. These angles are against a diameter D1 of the circular cylindrical lamp vessel section 10 measured perpendicular to that through the power supply 5 extending diameter of the circular cylindrical lamp vessel section 10 runs. The orientation of the diameter D1, the filament 3 and the ring segments 91 . 92 . 93 . 94 as well as the uncoated areas 12 . 13 . 14 . 15 is about the pedestal 2 clearly defined and by means of several reference pimples 21 on the base flange 20 are arranged, is the location and orientation of the filament 3 , the ring segments 91 . 92 . 93 . 94 and the uncoated areas 12 . 13 . 14 . 15 also determined with respect to the reflector surfaces and the optical axis of the headlamp after the lamp has been inserted into the headlight. The winding axis of the filament 3 is then in the optical axis of, for example, elliptical or parabolic headlamp reflector and the uncoated spots 12 . 13 . 14 . 15 of the lamp vessel correspond to the reflector surfaces used for generating the cut-off line.

The extent of the uncoated areas 12 and 14 between the ring segments 91 and 92 respectively. 93 and 94 is determined by the sum of the values for the angles α1, α2. The extent of the uncoated areas 13 and 15 between the ring segments 92 and 93 respectively. 91 and 94 is determined by the value for the angle δ. The extent of the ring segments 92 and 94 along the circumference of the cylindrical lamp vessel section 10 is determined by the difference of the values of the angles δ and α1. The extent of the ring segments 91 and 93 along the circumference of the cylindrical lamp vessel section 10 is determined by the values of the angles δ, β1 and α2 and is calculated as 180 ° - δ - β1 - α2. The values for the angles α1 and α2 are each preferably in the value range from 0 ° to 10 °. The value for the angle β1 is preferably in the value range of 7 ° to 15 ° and the value for the angle δ is preferably in the value range of 2 ° to 16 °. Since the values for the angles α1 and α2 can be zero, the ring segment-like coating can 9 the lamp according to the invention only by two uncoated places 13 . 14 be interrupted. The coating 9 is in accordance with the preferred embodiment of the invention symmetrical with respect to 180-degree rotations about the cylinder axis of the circular cylindrical lamp vessel portion 10 educated.

The The invention is not limited to the above explained embodiment of the invention. For example, the values for the angles α1, α2, β1 and δ adapted to the desired application become. In addition, the invention can also be applied to incandescent lamps applied with several axially aligned filaments become.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• US 4701663 [0002]

Claims (8)

Incandescent lamp with a translucent lamp vessel ( 1 ), which has a cylindrical vessel section ( 10 ), and at least one filament ( 3 ), which within the cylindrical vessel section ( 10 ) is arranged and the winding axis ( 30 ) parallel to the cylinder axis of the cylindrical vessel section ( 10 ), wherein the lamp vessel ( 1 ) with an infrared radiation reflecting coating ( 9 ), characterized in that the infrared radiation reflecting coating ( 9 ) only on one the at least one filament ( 3 ) annularly enclosing area ( 11 ) of the cylindrical vessel section ( 10 ) is arranged. Incandescent lamp according to claim 1, wherein the width or height of the at least one filament ( 3 ) annularly enclosing area ( 11 ) of the cylindrical vessel section ( 10 ) substantially the length of the at least one filament ( 3 ) corresponds. Incandescent lamp according to claim 1 or 2, wherein the infrared radiation reflecting coating ( 9 ) in at least one place ( 12 . 13 . 14 . 15 ) is interrupted. Incandescent lamp according to one of claims 1 to 3, wherein the infrared radiation-reflecting coating ( 9 ) over a plurality of ring-segment-shaped sections ( 91 . 92 . 93 . 94 ) extending along the at least one filament ( 3 ) annularly enclosing area ( 11 ) of the cylindrical lamp vessel section ( 10 ) and uncoated areas ( 12 . 13 . 14 . 15 ) of the lamp vessel surface are separated from each other. Incandescent lamp according to one of claims 1 to 4, wherein the infrared radiation reflecting coating ( 9 ) as an interference filter coating on the lamp vessel ( 1 ) is trained. Incandescent lamp according to one of claims 1 to 5, wherein the infrared radiation reflecting coating ( 9 ) on the outside of the lamp vessel ( 1 ) is attached. Incandescent lamp according to one of claims 1 to 6, wherein the winding axis ( 30 ) the at least one filament ( 3 ) offset parallel to the cylinder axis of the cylindrical lamp vessel portion ( 10 ) is arranged. Incandescent lamp according to claim 7, wherein the distance between the winding axis ( 30 ) the at least one filament ( 3 ) and the cylinder axis of the cylindrical portion ( 10 ) of the lamp vessel ( 1 ) smaller than or equal to the outer diameter of the at least one filament ( 3 ).