EP0208574B1 - Dipped headlamp for a motor vehicle - Google Patents

Description

The present invention relates to a dipped headlight for a motor vehicle, in which the light beam is cut above two horizontal half-planes offset in height.

This type of cutoff, which is described in particular in FR-A-2 087 317 (corresponding to US-A-3 858 040) is very particularly suited to the lighting standards in force in the USA, such as they are for example defined by SAE J 579 C.

More precisely, the contour of the cut is defined by two horizontal half-lines, the half-line on the right side being at the level of the horizontal and the half-line on the left side being offset by approximately 1.5% below of the horizontal.

The beams meeting these standards are most often designed with a projector provided with a transverse filament lamp cooperating with a parabolic reflector of relatively large focal length, so as to reduce the thickness of the beam and consequently minimize the extra thicknesses due to prisms deflectors on the closing glass.

Projectors have also been proposed provided with an axial filament lamp. The filament is focused in a parabolic reflector, tilted downwards to reduce the deviation required from the prisms of the ice, and therefore the thicknesses of the latter.

More particularly, the aforementioned FR-A-2 087 317 describes a projector of this type, in accordance with the preamble of claim 1.

But, in both cases, it is necessary to use a parabolic reflector with a large focal length of the order of 29 to 32 mm) therefore with little flux recovery.

In fact, a short focal length would produce images that are too large and would not allow the desired beam to be produced, unless there are very strongly deflecting prisms at the closing glass, a requirement incompatible with the practical needs of molding (in particular for glass ices); in addition, highly deflecting prisms do not make it possible to obtain satisfactory cutting sharpness due to the light dispersions produced by the very accentuated bodies of the glass.

It has also been proposed, in order to reduce the role assigned to the prisms of ice, to form a reflector from two half-paraboloids, but the reflector of this projector has a surface discontinuity at the point of connection of the two half-paraboloids , so that a reflector manufactured according to the teachings of this document is difficult to produce and necessarily remains imperfect, in practice, at the point of connection of the two half-paraboloids, which results in an emission of light rays at the above the cut.

One of the aims of the invention is to propose a dipped headlight overcoming the aforementioned drawbacks and allowing maximum recovery of the light flux emitted by the filament of the lamp.

The proposed low-beam headlamp conventionally comprises a lamp, a reflector and a closing glass placed in front of the reflector, as well as means for cutting the light beam above two horizontal half-planes offset in height.

According to the invention, the headlight has the combination of the characteristics set out in the characterizing part of claim 1.

Preferred embodiments are given in dependent claims 2 to 9.

The description which follows will make it easier to understand how the invention can be produced, while revealing other characteristics and advantages.

• la figure 1 est une vue en coupe, schématique, du projecteur selon l'invention,
• la figure 2 est une vue de face du réflecteur de ce projecteur,
• la figure 3 est une vue de face de la glace de fermeture de ce projecteur,
• les figures 4 à 11 sont des courbes isolux relevées sur un écran normalisé, produites par les zones désignées respectivement 12 à 19 sur la figure 2,
• la figure 12 est une série de courbes isolux correspondant à la zone référencée 11 sur la figure 2,
• les figures 13 à 15 sont des vues du réflecteur conformes au second mode de réalisation précité, respectivement vue de dessus en coupe, vue de face et vue en élévation, en coupe selon la ligne XV - XV sur la figure 13.

In the drawings:

• FIG. 1 is a schematic sectional view of the headlight according to the invention,
• FIG. 2 is a front view of the reflector of this projector,
• FIG. 3 is a front view of the closing glass of this projector,
• FIGS. 4 to 11 are isolux curves recorded on a standardized screen, produced by the zones designated respectively 12 to 19 in FIG. 2,
• FIG. 12 is a series of isolux curves corresponding to the zone referenced 11 in FIG. 2,
• FIGS. 13 to 15 are views of the reflector in accordance with the second embodiment mentioned above, respectively seen from above in section, front view and view in elevation, in section along the line XV - XV in FIG. 13.

The projector according to the invention, shown schematically in Figure 1, comprises a reflector 10, an axial filament lamp 20, and a distribution glass 30 closing the projector.

The surface of the reflector is a surface without discontinuity, chosen so as to form images of the filament, all the points of which are advantageously situated below a horizontal plane, all of these images having their highest point aligned on this horizontal plane.

By "absence of discontinuity" is meant a second order continuity guaranteed at any point on the surface, that is to say that the radius of curvature and the position of the center of curvature always vary continuously; this arrangement makes it possible, in practice, to produce real surfaces having a very good conformity with the theoretical surfaces, thus avoiding the defects which were specific to the system with "offset paraboloids" described above, the second order continuity makes in particular the reflector perfectly stampable in principle.

avec:

• I - demi-longueur du filament
• f, - distance du centre du filament à l'origine des coordonnées

The theoretical calculation shows that the surface defined by the following equation has the stated properties:

with:

• I - half length of the filament
• f, - distance from the center of the filament at the origin of the coordinates

Ox being the axis of the reflector and the plane xOy being a substantially horizontal plane, that is to say horizontal for a reflector whose axis would be horizontal.

Such a surface has already been defined in FR-A-2 536 502 and FR-A-2 536 503, to which reference will be made for further details.

Preferably, when such a surface is used, the distance separating, in the radial direction, the surface of the reflector from the surface defined by the equation does not exceed 0.15 mm.

Preferably also, the normal difference separating, in the vertical plane passing through the origin of the coordinates, the trace of the surface of the reflector of the corresponding least-square parabola does not exceed 0.3 mm (the concept of "parabola least squares "is explained in the two aforementioned documents).

Also preferably, the distance from the emissive surface to the axis does not exceed 25% of the diameter of the filament, in one direction or the other.

Preferably also, the axial centering of the filament relative to the point of coordinates (f ,, 0, O) is carried out with a tolerance of 10% of the length of the filament, in one direction or the other.

Figures 4 to 11 and Figure 12 show the illumination provided by regions 12 to 16 and 11, respectively, of the bare reflector thus defined, with a horizontal axis Ox.

The regions 12 'to 19' produce an illumination symmetrical with respect to the vertical vv 'of the illuminations produced by the regions 12 to 19, respectively.

In these figures, the outermost curve corresponds to an illumination of 100 candelas, the next curve to an illumination of 1000 candelas and the other curves to increasing illuminations of 2000, 4000, ... candelas.

The use of the reflector thus defined alone is not sufficient (unlike the case of the two above-mentioned documents) to obtain the desired cut.

This is why, instead of keeping a horizontal Ox reflector axis (as was the case in the two above-mentioned documents), the filament-reflector assembly is tilted down and to the right towards the concentration point. maximum as defined by standard SAE J 579 c, as indicated above.

It is then necessary to bring the images produced by the lateral regions of the reflector (regions 16 to 19 and 16 'to 19') to the level of the two half-planes of the cut, by appropriate corrective means.

In a first embodiment, these correcting means consist of prisms formed on the homologous regions 30b and 30c of the closing glass (FIG. 3), which are provided with prisms of 1 to 3 °. The central region 30a of the closing glass can be striated in a conventional manner, to obtain the desired comfort and widening for the light beam.

In a second embodiment, illustrated in FIGS. 13 to 15, the surface 10a of the reflector is extended by two lateral surfaces 10b and 10c of the same equation, but slightly angularly offset (as can be seen in FIG. 15), also by an angle on the order of 1 to 3 °.

In other words, the reflector of the preceding embodiment is modified (FIG. 2) while retaining the same surface equation, except that the part comprising the regions 16 to 19 is tilted very slightly upwards. on the one hand, and that comprising the regions 16 'to 19' on the other. In this embodiment, the regions 30b and 30c of the closing glass can be devoid of prisms, or only very slightly prismatic, which makes it possible to eliminate the dazzling factors due to the multiplicity of horizontal drafts resulting from the presence prisms in the above case.

In either embodiment, the projector according to the invention is capable of collecting a luminous flux much greater than that given by a paraboloid of an axial filament projector of conventional design, projector whose focal length can hardly be reduced to values less than 29 mm.

On the contrary, for the projector of the invention, it is possible to use a low focal length f _o , for example of 22.5 mm, which makes it possible for example to produce a projector of generally rectangular, symmetrical shape, of 70 mm high and 150 mm wide.

The gain in flux is then close to 30% compared to conventional projectors, the most common focal length of which is 31.75 mm and the height always limited to minimum values of the order of 100 mm.

Claims (10)

1. A dipped headlamp for a motor vehicle, of the kind comprising an axial filament bulb (20), a reflector (10) and a re-distributing glass (30) placed in front of the reflector, together with means for masking the light beam above two horizontal half-planes at different heights, the said masking means comprising means for forming images of the filament all the points of which are situated below a horizontal plane, together with correcting means adapted to effect upward angular displacement of at least some of the said images, so that the images are situated at the level of the two said horizontal masking half-planes, characterised in that:

- the means for forming images of the filament of which all points are situated below a horizontal plane comprise the surface of the reflector, which is without any discontinuity, in cooperation with the filament (20) which is without any occulting mask; - the axis of the filament and the axis of the reflector surface are inclined downwardly by an angle corresponding to the angular level of the lower of the masking halfplanes, with respect to tne horizontal, and laterally by an angle approximately corresponding to the angular half-width of the images of concentration of the filament propagated from the side portions of the reflector, and

- the correcting means so act on the said images of concentration as to direct them towards the highest of the masking half-planes.

2. A headlamp according to Claim 1, wherein the correcting means comprise zones (30b, 30c) of the re-distributing glass (30), provided with prisms and situated facing the said side portions of the reflector.

3. A headlamp according to Claim 1, wherein the correcting means comprise two lateral surface portions (10b, 10c) of the reflector, adjoining the divergent surface portion (10a), being of the same equation as an extension of the latter, and being slightly tilted upwardly, the cover lens being correspondingly smooth or slightly prismatic in the vertical direction.

4. A headlamp according to Claim 1, wherein the divergent central portion is adapted to form images of the filament each of which has its highest point situated in a horizontal plane.

5. A headlamp according to Claim 4, wherein the filament is offset upwardly in a radial direction by a distance (8) such that its light-emitting surface is substantially tangential to the axis (Ox) and the surface is defined by the equation:

in which:

I = half-length of the filament,

f_o = distance of the centre of the filament in the plane yOz,

Ox being the axis of the reflector, and the plane xOy being a substantially horizontal plane.

6. A headlamp according to Claim 5, wherein the distance in a radial direction between the surface of the reflector and the surface defined by the equation does not exceed 0,15 mm.

7. A headlamp according to Claim 5, wherein in the vertical plane passing through the co-ordinate origin, the normal separation between the curve of the surface of the reflector and the corresponding "parabola of least squares" does not exceed 0.3 mm.

8. A headlamp according to Claim 5, wherein the distance between the light-emitting surface ana the axis does not exceed 25 % of the diameter of the filament in either one direction or the other.

9. A headlamp according to Claim 5, wherein the filament is axially centred, with respect to the point (F_o) of which the co-ordinates are [f_o; 0; 0;], with a tolerance of 10 % of the length (2 1) of the filament, in either one direction or the other.

Images