FR2509428A1 - REFLECTOR FOR HEADLIGHT OF MOTOR VEHICLE - Google Patents

Abstract

REFLECTOR FOR MOTOR VEHICLE HEADLIGHT, INCLUDING A DIFFUSION OF LIGHT DIFFUSION IN A PLAN. REFLECTOR CHARACTERIZED IN THAT THE REFLECTIVE SURFACE OF THE REFLECTOR IS FORMED BY A SURFACE ENVELOPED OF A GROUP OF PARABOLOIDS 12, 13 OF HOMOFOCAL REVOLUTION, AND THAT EACH PARABOLOID OF REVOLUTION IS IN CONTACT WITH AN EDGE CURVE 10 DETERMINING THE LIGHT DIFFUSION OF THE REFLECTOR. THE INVENTION CONCERNS HEADLIGHTS FOR MOTOR VEHICLES.

Description

The invention relates to a reflector for a motor vehicle headlight

  With such a divergence from a light beam, cylindrical lenses are generally available as optical means of action on the interior face of a diffuser which is placed in front of the light beam. When the diffuser is strongly inclined with respect to the optical axis of the headlamp or headlamp in one or in two planes, it is necessary to resort, for this purpose

  to optical organs whose configuration is complex.

  It is then necessary to provide costly compression molds for

the manufacture of diffusers.

  The reflector for automobile headlight

  according to the invention causes a different light diffusion

  in a plane, so that we do not need

  for this purpose, organs having an optical action, or

  It will be advantageous to protect the interior of the reflector by means of a plate of glass with flat and parallel faces, without optical effect, and whose inclination would have practically no influence on the diffusion of light. does not have any device

  optical, allows a significant saving on the weight of the lighthouse.

  This also has the advantage of requiring only a small number of types of reflectors to satisfy

  requirements of motor vehicle manufacturers.

  Provisions indicated below make it possible to obtain advantageous embodiments and

  improvements in construction.

  The invention will be better understood with regard to

  of the description below and the attached drawings showing:

  several examples of embodiment of the invention, drawings in which: Figures 1 and 2 each show a horizontal meridian section of the surface of the reflector, the corresponding horizontal sections are still indicated in Figure 1, by two curves producing parabolo to common outbreaks;

  Figure 3 represents the meridian section

  not horizontal in the form of any curve; FIGS. 4 and 5 show, for two different edge curves, the outline of the isohypse lines of a reflector corresponding to an edge curve such as that of FIG. 6. FIG. 6 shows the horizontal meridian section of a group parabolo which must be produced when the edge curve is a straight line; Figure 7 shows the corresponding plot

  isohypse lines of a reflector according to FIG. 6,

  FIG. 8 shows the layout of different light beams of the reflector of FIG. 7, in plan and in

side view.

  FIG. 1 represents the meridian section of a reflector whose edge curve 10 is in the form of a hyperbola, the latter determining the horizontal diffusion of the light. On the edge curve 10 is attached a group of paraboloids of The reflection surface of the reflector, which is not shown, is formed by an envelope surface of the group, so that the latter comprise a common focal point 11 and are in contact with each other by their horizontal meridian section. of paraboloids

  of revolution, of which the horizontal meridian section has been

  first and second paraboloid of revolution 12 and 13 It is admitted here that the focus of the conical sectional curve forming the edge curve 10 is identical to the homes of the group

  homofocal revolution paraboloids that must be produced.

  The dimensions of the meridian sections 12

  and 13 are subject to the following laws the angle formed between

  the positive x-axis and the point of contact is, for example, designated

  The correlation between the angle of rotation 4 of the para-

  boloide afferent with respect to the x-axis can be defined by the following equality sin t (1 + E cos t) (t) = t arc 'tan (1 2) + 2 E cost (1 cos t) represents l digital eccentricity of the edge curve

conical cut.

  The focal length of the afferent paraboloid is given for the equation f (t) = 2 = jo (1 j) 1 cst 2 2 X + 2 cos t po represents the distance between the vertex of the curve of

? -bord and the hearth.

  The isohypse lines of the reflecting surface of the reflector constitute an envelope of the cutting curves of the total set of these paraboloids of revolutio with the constant Z plane, the Z axis being perpendicular

drawing plan.

  FIG. 4 represents isohypal lines of this type for the case in which the edge curve 10 is a hyperbola with an eccentricity t = 1.2 and in FIG. 5 for this it is an ellipse with ú = 0.8 The focus common edge curve and homofocal pjirabololdes is here '

  each time at the origin of the coordinates.

  In FIG. 7, an example is shown in which the curve of the horizontal meridian section is composed of several curved parts. The outer zones always consist of straight lines 20 and, in the region of the neck of the reflector, the lines 20 are transformed by a continuous way, that is to say with the same tangent in a sector of circle 21 We could, in the same way, instead of the sector of circle also use a sector of a conical curve of a

  another type such as an ellipse, a parabola or a hyperbola.

  As a result, only the horizontal diffusion of the light reflected by the reflector, intended for this zone, would be modified: This average zone which surrounds the neck of the lamp corresponds to

  following the example shown in FIG.

  It can also be applied again to the outer straight parts of the edge curves, a group of homofocal paraboloids, so that they are in

contact with the straight lines 20.

  Figure 6 shows, in the same way that

  Figure 1, the horizontal meridian sections of these para-

  boloides It can be seen from this figure, as obtained precisely as an edge curve the line prescribed in the form of an envelope of this group of curves Si c characterized the angle of the radius of the reflector for which the cerc of Figure 2 is transformed to the right, there are in the area straight lines between the angle of revolution 'y of the paraboloid with respect to the x-axis and the angle of the radius vector with respect to the point of contact parabolo of with the right

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  the correlation "> = 20 <t The focal length of the paraboloid surface afferent has the value = = R cos (t -vo). In this way, the surface of the reflector is determined, and the isohypse lines of the reflector can be calculated, as it is shown by way of example in FIG. 7 The path of a few beams in a reflector of this kind is represented in plan and in lateral view in FIG. 0. The horizontal diffusion ranges from -45 degrees to +45.

  degrees while the vertical diffusion is zero, that is,

  say that the light beams go out in a wide range of the reflector without vertical diffusion Such a distribution of light is very desirable for example for the

fog lights.

  As can be seen from FIG. 7, the isohypse lines 71 of the reflector extend in the region of the straight portion 72 of the edge lines parallel to the latter. This means that the cutting curves of the surface of the reflector on planes perpendicular to the edge curves are parabolas The plot 73 of such a section plane is shown in Figure 7 The focal length of these parabolas is given, from Figure 2, by the distance R which

  separates the outboard curve from the common focus of the group of

  revolution of the revolution, which coincides in figure 2, with the

coordinate system.

  If the horizontal meridian section of the reflector is no longer a straight line, but an edge curve 30 of any shape t 1 (t), as shown in FIG. 3, this edge curve can be conceived as formed by assembling small sections of 31 different and apply the principle

  which we have just described to each of the different sections ds.

  From the example of the point P, we can see that the plane 32 normal to the tangent joins the edge curve at the point P The distance 34 which separates the tangent from the fixed origin of the coordinates (which is at the same time the location of the filament of the lamp) gives the focal length of the parabola which has its apex in P and which applies in P on the plane 32 normal to the tangent The axis of the parabola is located

  perpendicular to the tangent at P, in the horizontal plane.

  The parabola thus obtained is in contact with the surface of the reflector. A similar parabola can also be constructed for the points of the edge curve 30 adjacent to P. The inner envelope of all these parabolas then forms the surface of the reflector which ensures the horizontal diffusion of the

light without vertical deviation.

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Claims (3)

REVENDICATIONú   1) Reflector for the automobile window, comprising a diffusion of the light in a plane, characterized in that the reflective surface of the reflector is formed by a surface area covered by parabolopdes (12, 13) of hromofocal revolution and fse eachparaboloid of revolution is in contact with -re co-rte   board (10) determining the luminous diffusion of the reflector.   2) Reflector including: ruller   a horizontal divergence according to claim 1,   in that the expected edge curve (10) determines: a   light scattering in the horizontal direction.   3) Reflector according to one of the rev e; azrs cations 1 and 2, characterized in that the edge curve 10 planned is flat.   4) Reflector according to any one   Claims 1 to 3, characterized in that the short of   edge (10) is, at least partially, a conical section line.   5) Reflector according to claim 4.   characterized in that the focus (11) of the conical cutting line forming the edge curve (10) is identical to the foci of the   group formed by paraboloids of homofocal revolution.   ) Reflector according to the claim   3 characterized in that the edge curve is an ellipse.   Reflector according to Claim 3,   characterized in that the edge curve is a hyperbola.   Reflector according to Claim 3, characterized in that the edge curve is a segment of a circle   to which is connected on each side a straight branch.