FR2675443A1 - HEADLIGHT OF VEHICLES. - Google Patents

Abstract

a) Headlight of vehicles; b) lighthouse characterized in that the reflector (10) is subdivided into a left part (18) and a right part (19) which pass one into the other without discontinuity, while the first and second focal points ( F1HR, F2HR) of the curve obtained in horizontal longitudinal sections of part (19) located on the side opposite to the opposing traffic, are arranged at a greater distance from the top of the reflector than the first and second focal points (F1HL, F2HL) of the curve obtained in horizontal longitudinal sections of the part (18) located on the side of the traffic coming in the opposite direction; c) the invention relates to vehicle headlights.

Description

The invention relates to a vehicle headlamp with a

  reflector and with a light source, wherein the reflector comprises axially longitudinal sections substantially elliptical shaped curves with a common apex, whose first apices are arranged in the vicinity of the light source, and with a screen and a which are arranged far away from the reflector in the direction of the light, while the second focus of the curve obtained in vertical longitudinal section, is in the vicinity of the screen and that the second focus of the curve obtained in horizontal longitudinal section, himself

located near the lens.

  Such a lighthouse is known from document DE-AI 33 34 459 This headlight comprises a reflector containing ellipses in longitudinal axial sections The first foci of the ellipses coincide approximately and in their zones is disposed the filament of a filament lamp A far reflector in the direction of light, are disposed a screen extending substantially below the optical axis of the reflector and an objective The second focus of the ellipse obtained in vertical longitudinal section of the reflector, is located in the vicinity of the The second focus of the ellipse obtained in horizontal longitudinal section

  reflector, is located near the lens.

  Through the lens, the top edge of the screen is reproduced as a chiaroscuro dividing line

  in the distribution of light produced by the lighthouse.

  The reflector is then designed for use

  optimal light from the incandescent lamp.

  In the new types of headlamps, instead of incandescent lamps as light sources, gas discharge lamps are used which provide a significantly higher luminous flux and have a longer service life. a gas discharge lamp in the reflector of DE-Ai 33 34 459, most of the luminous flux of the gas discharge lamp can not however be used judiciously, and it appears on the contrary, in this case , in the center of the distribution of light, a luminous intensity

  maximum of a legally inadmissible level.

  Several values of the legal measure lying at different points in the distribution of light, do not

are not satisfied.

  The object of the invention is to remedy these drawbacks and concerns for this purpose a lighthouse characterized in that the reflector is subdivided into a left part and a straight part which pass into one another without discontinuity, while the first and second foci of the curve obtained in horizontal longitudinal section of the part lying on the opposite side to the traffic in the opposite direction are arranged at a greater distance from the top of the reflector than the first and second foci of the curve obtained in section longitudinal axis of the part on the traffic side in the opposite direction. The headlamp according to the invention with the characteristics indicated above has, on the other hand, the advantage that in its light distribution, the legally permissible maximum light intensity values are not exceeded and that the higher luminous flux made available. with the gas discharge lamp is used judiciously, that is to say that one has high values of light intensity in the lateral zones of the distribution of the light, so that one obtains a

  good lighting of the edges of the roadway.

  Advantageous forms and supplements

  of the lighthouse according to the invention are characterized

  below. According to another development the lighthouse is characterized in that the two parts are further subdivided into an upper part and a lower part, so that the reflector consists of four quadrants while the second focus of the curve obtained in longitudinal section vertical of the lower quadrants is arranged at a smaller distance from the top of the reflector than the second focus of the curve obtained for the upper quadrants, a part of the light reflected by the lower parts of the reflector passing in front of the screen and

  contributing to the distribution of light.

  According to another characteristic of the invention, the second focus of the curve obtained in vertical longitudinal section of the lower quadrants, is in the direction of the light before the screen, while the second focus of the curve obtained in vertical longitudinal curve. upper quadrants is in the direction of the

light after the screen.

  According to yet another characteristic of the invention, the curves obtained in the longitudinal axial sections in the vicinity of the outer edge of the reflector deviate from the shape of an ellipse, the distribution of the light of the headlight being

modeled appropriately.

  According to another characteristic of the invention, the light source is shifted by

  relative to the optical axis of the reflector.

  According to another characteristic of the invention, the screen is offset with respect to the axis

optical reflector.

  According to another characteristic of the invention, the light source is a lamp with

gas discharge.

  According to another characteristic of the invention, the reflective surface, continuing without discontinuity, of the reflector is interrupted in places by one or more facets whose shape and orientation deviate from those of the essentially continuous reflective surface, while the facet is disposed in an area of the reflector which, for a reflective surface substantially continuous throughout its extent, would cause undesirable local deviations in the distribution of light, or the facet is disposed at a location near this area, and thanks in the light reflected by the facet, these differences in the intensity of the light are at least diminished, local differences in the intensity of the light being undesirable.

  corrected in the distribution of light.

  According to another characteristic of the invention, the difference in luminous intensity is a local minimum of the luminous intensity, and thanks to the facet, light is reflected in the area of the light.

minimum of light intensity.

  According to another characteristic of the invention, the difference in luminous intensity is a local maximum of the luminous intensity and, thanks to the facet, the light constituting the maximum luminous intensity for a continuous reflecting surface in all its extent, is reflected in a scattered way. According to another characteristic of the invention, the differences in luminous intensity are a local maximum of luminous intensity and in the vicinity thereof, a minimum of luminous intensity and, thanks to the facet, the light which would constitute the maximum of luminous intensity for a continuous reflecting surface in all its extent, is reflected on the minimum of luminous intensity formed on the continuous reflection surface in all its extent and is possibly at the same time, dispersed more widely. According to another characteristic of the invention, the facet comprises a surface

reflective flat.

  According to another characteristic of the invention, the facet comprises a surface

  reflective concave or convex.

  According to another characteristic of the invention, the transition between the facet and the continuous reflecting surface is done without discontinuity. Finally, according to another characteristic of the invention, the reflective surface of the facet is inclined relative to the continuous reflecting surface which surrounds it, while at the transition between the facet and the reflection surface continues,

is provided a step.

  An exemplary embodiment of the invention is shown in the accompanying drawings and will be shown

  in more detail in the description below.

  FIG. 1 shows, in a greatly simplified manner, a headlight in perspective, FIG. 2 shows the reflector of the headlight in FIG. 1 in rear view, FIG. 3 shows the reflector in horizontal section along the line III-III. In FIG. 2, FIG. 4 shows on a measurement screen the light distribution obtained from the headlight, FIG. 5 shows on a measurement screen a distribution of the light obtained with a light.

reflector according to a variant.

  A lighthouse shown in FIG. 1 for the vehicle passing beam comprises a reflector in which a gas discharge lamp 11, whose luminous arc 12 during its operation, is set up as a light source, extends along the optical axis 13 of the reflector remote in the direction of the light of the reflector 10, are arranged one behind the other, a screen 14 extending substantially below the optical axis 13 of the As a reflector and a lens 16, which is remote in the direction of the light from the objective lens 16, it can also be provided, an ice-cream, not shown, which plays a role of covering. By virtue of the lens 16, the upper edge 17 of the lens 16 screen 14 is reproduced in the light distribution generated by the headlight, in the form of a delimitation line of the chiaroscuro The reflector 10 comprises, in longitudinal axial sections, that is to say in longitudinal sections which include the optical axis 13, essentially elliptically shaped curves with two focal points F 1 and F 2 respectively. These curves have, due to their two focal points, a first focal length which is defined as the distance between the vertex of the reflector and the respective first focus. F1 and a second focal length defined as the distance between the reflector vertex and the respective second focal point F 2. Looking in the direction of the light, the reflector 10 is subdivided into a left part 18 and a right part 19 which is connect continuously to each other in the vertical median plane 20 The reflector 10 shown in the figures is designed for right-hand traffic The curve 21 extending in axial longitudinal section through the right-hand part 19 of the reflector comprises a first and second focal lengths F 1 HR and F 2 HR longer than those of the curve 22 extending in the horizontal axial longitudinal section of the left part 18 of the reflector The first focus F 1 HR of the curve 21 of the right part 19 is then farther from the top of the reflector than the first focus F 1 HL of the left curve 22 For example the first focus F 1 HL of the curve left 22 may be a little forward of the end of the arc 12 to the top and the first focus F 1 HR of the right curve 21 may be located a little further from the vertex than F 1 HL to the median area of the arc 12 The second focus F 2 HR of the curve 21 of the right part 19 is farther in the direction of the light of the objective 16 than the second focus F 2 HL of the curve 22 of the left part 18 , which was also somewhat distant from the objective in the direction of light The first and second foci of the curves resulting from the axial longitudinal cuts placed between the axial horizontal longitudinal section and the axial vertical longitudinal section lie between the first foci or the second homes of curv es

  horizontal and vertical longitudinal cuts.

  Because of this conformation of the reflector, the part of the large luminous flux of the gas discharge lamp 12 reflected by the right part 19 of the reflector, does not contribute as strongly as a reflector according to the state of the art at maximum range in the center of the distribution of light, but thanks to the right portion% 19, the light is scattered to the left, so that we get a better lighting of the sides This clearly appears in the distribution of light, represented in FIG. 4, produced by the headlight on a measuring screen disposed perpendicularly to its optical axis 13 In FIG. 4 are indicated the curves of the same luminous intensity, called isophotic curves, with indication of the corresponding luminous intensity. 19 of the reflector 10 is advantageously designed so that in the center of the light distribution is formed a pronounced maximum of light intensity 23

  with a luminous intensity of about 40 to 50 lux.

  The position of the maximum luminous intensity 23 can be modified in the horizontal direction by a displacement of the screen 14 in the horizontal direction and perpendicularly to the optical axis 13, as well as by

  a displacement of the gas discharge lamp 11.

  The screen 14 as well as the gas discharge lamp 11 may also be slightly offset in the vertical direction, to change the position of the light intensity maximum in the vertical direction. When the reflector is designed for left-hand traffic, the resulting curve in this case of the longitudinal longitudinal section of the left part of the reflector, correspondingly comprises first and second focal lengths longer than the curve resulting from the right part, so that thanks to the left part of the reflector, the light

  is reflected scattered to the right.

  According to another embodiment, the left part and the right part 18, 19 of the reflector 10 are respectively subdivided into an upper part and a lower part which are connected without discontinuity in the horizontal median plane 20, so that the reflector 10, viewed in the direction of light, is constituted by an upper left quadrant 25, an upper right quadrant 26, a lower left quadrant 27, and a lower right quadrant 28 In the horizontal longitudinal section, the left quadrants 25, 27 and the quadrants rights 26, 28 are made as previously described In the vertical longitudinal section, the upper quadrants 25, 26 and the quadrants

  lower 27, 28 are shaped differently.

  The resulting curve 31 in the vertical axial longitudinal section of the lower quadrants 27, 28 comprises a second focal distance F 2 VU shorter than the curve 32 resulting in axial longitudinal section of the upper quadrants 25, 26 The second focus F 2 VU of the curve lower 31 can then be in the direction of the light before the screen 14, while the second focus F 2 VO of the upper curve 32 can be in the direction of the

light, behind the screen 14.

  The first focal lengths of the curves obtained in the vertical axial longitudinal section of the upper and lower quadrants may be identical. The first focal length of the curve 32 of the upper quadrants 25, 26 may, however, also be different (shorter) than

  that of the curve 31 of the lower quadrants 27, 28.

  Due to this subdivision of the reflector into different upper and lower quadrants, part of the light reflected by the lower quadrants 27, 28, which is normally obscured by the screen, can still be captured by the lens 16 and used to produce the distribution of light. The curves lying in the axial longitudinal sections of the reflector 10 may, as indicated in dashed lines in FIG. 3, deviate from the shape of the ellipse in the zone of the outer edge, that is to say towards the front edge of the reflector, and continue with another curvature As a result, the distribution of light obtained by the lighthouse can

  be optimized in detail.

  In the distribution of the light produced by the headlight previously described, it can be, as shown in FIG. 4, to the left of the maximum luminous intensity 23, first of all a minimum of luminous intensity and then, a secondary maximum 36 The minimum luminous intensity 35 in this area of the distribution of light, is necessary to prevent glare from the traffic coming in the opposite direction by reflection on the wet road The zone of the minimum luminous intensity 35 is denominated in the legal prescriptions, measuring point E 50 L The secondary maximum 36 connecting the minimum of light intensity 35 to the left is however not desired In the case of a variant, shown in Figures 2 and 3 of the lighthouse previously described, the reflector is subdivided according to the four quadrants 25 to 28 described above from an area of the reflector 10, which extends in the transition zone between the upper and lower quadrants 26, 28 in the vicinity of the top of the reflector 10, the light is reflected on the secondary maximum 36 The reflector 10 of the variant it comprises in this zone, which produces the secondary maximum 36, a facet 40 This facet 40 comprises a reflective surface 41, by which light is reflected by being dispersed, so that undesirable secondary maximum 36 is eliminated and light is distributed over a larger area and as a result, as shown in FIG. 5 , taking into account the measuring point E 50 L a continuous decrease in light intensity to the left The facet 40 is inclined relative to the reflective surface of the reflector 10 surrounding it, while the sides of the facet continue without discontinuity in the remaining reflective surface, but that nevertheless results in the external transition between the facet 40 and the remainder of the surface The facet 40 may, as shown in FIG. 3, have a flat reflective surface 41. The reflecting surface of the facet may, however, also be concave or convex. In addition, the facet 40 may also be formed. by a simple flattening of the reflective surface of the reflector, in which case there is then all around a transition without discontinuity between the facet and the rest of the reflective surface, which is technically favorable for manufacture Thanks to the arrangement of one or more facets with a configuration different from the continuous reflective surface of the reflector, it is also possible to avoid or at least reduce other undesirable local differences in light intensity in the

  distribution of the light of the lighthouse.

Claims (15)

  A vehicle headlamp with a reflector (10) and with a light source (11), in which the reflector comprises axially longitudinal sections, substantially elliptical shaped curves with a common vertex, the first vertices of which (Fl ) are arranged in the vicinity of the light source (11), and with a screen (14) and a lens (16) which are arranged away from the reflector (10) in the direction of light, while the second focus (F) 2 VU; F 2 VO), of the curve (31; 32) obtained in vertical longitudinal section, is situated in the vicinity of the screen (14) and that the second focus (F 2 HL, F 2 HR) of the curve (21; 22) obtained in horizontal longitudinal section is in the vicinity of the objective (16), a headlamp characterized in that the reflector (10) is subdivided into a left part (18) and a right part (19) which transforms into each other without discontinuity, while the first and second foci (Fl HR, F 2 HR) of the curve obtained in horizontal longitudinal section of the part (19) on the opposite side to the traffic coming in opposite direction, are arranged at a greater distance from the top of the reflector than the first and second foci (Fl HL, F 2 HL) of the curve obtained in section of the part (18)   on the side of traffic coming in the opposite direction.   Headlamp according to Claim 1, characterized in that the two parts (18, 19) are further subdivided into an upper part and a lower part, so that the reflector (10) consists of four quadrants (25, 26). , 27, 28), while the second focus (F 2 VU) of the curve (31) obtained in vertical longitudinal section of the lower quadrants (27, 28) is arranged at a smaller distance from the vertex of the reflector than the second focus (F 2 VO) of the curve (32) obtained for the quadrants higher (25, 26).   3. Lighthouse according to claim 2, characterized in that the second focus (F 2 VU) of the curve (31) obtained in vertical longitudinal sections of the lower quadrants (27, 28) is in the direction of the light before the screen (14), whereas the second focus (F 2 VO) of the curve (32) obtained in vertical longitudinal curves of the upper quadrants (25, 26) lies in the   direction of light after the screen (14). 4. Lighthouse according to any one of   Claims 1 to 3, characterized in that the   curves obtained in longitudinal axial sections near the outer edge of the reflector   (10) deviate from the shape of an ellipse. 5. Lighthouse according to any one of   Claims 1 to 4, characterized in that the source   of light (11) is shifted with respect to the optical axis (13) of the reflector (10). 6. Lighthouse according to any one of   Claims 1 to 5, characterized in that the screen   (14) is offset with respect to the optical axis (13) of the reflector (10). 7 Lighthouse according to any of the   Claims 1 to 6, characterized in that the source   light source (11) is a gas discharge lamp. 8. Lighthouse according to any one of   Claims 1 to 7, characterized in that the surface   reflective, continuing without discontinuity, the reflector (10) is interrupted in places by one or more facets (40) whose shape and orientation deviate from that of the essentially continuous reflective surface, while the facet (40) is disposed in an area of the reflector (10) which, for a substantially continuous reflective surface throughout its extent, would cause undesirable local deviations (35, 36) in the distribution of light, or the facet (40) is disposed to adjacent to this zone, and thanks to the light reflected by the facet (40), these differences in the intensity of the light (35, 36) are at least diminished.   Headlamp according to Claim 8, characterized in that the difference in light intensity is a local minimum (35) of the light intensity and in that, thanks to the facet (40) of the light, is reflected in the area of the minimum luminous intensity. Headlamp according to Claim 8, characterized in that the difference in luminous intensity is a local maximum of the luminous intensity (36) and that, thanks to the facet (40), the light constitutes the maximum luminous intensity. for a continuous reflecting surface in all its extent, is reflected in a scattered way.   Headlamp according to Claim 8, characterized in that the luminous intensity differences are a local maximum of luminous intensity (36) and in the vicinity thereof, a minimum of luminous intensity (35), and in that that thanks to the facet (40) the light, which would constitute the maximum of luminous intensity for a continuous reflecting surface in all its extent, is reflected on the minimum of luminous intensity formed on the continuous reflection surface in all its extent, and is possibly at the same time, dispersed more widely. 12. Lighthouse according to any one of   Claims 8 to 11, characterized in that the   facet (40) has a flat reflective surface (41).   13. Lighthouse according to any one of   Claims 8 to 11, characterized in that the   facet (40) has a reflective surface concave or convex.   14. Lighthouse according to any one of   12 or 13, characterized in that the   transition between the facet (40) and the surface   continuous reflective, is done without discontinuity.   15. Lighthouse according to any one of   12 or 13, characterized in that the   reflective surface of the facet (40) is inclined relative to the continuous reflecting surface surrounding it, while at the transition between the facet (40) and the continuous reflection surface is provided a step (42).