JP3223763B2 - Headlight reflector - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a light beam emitted from a light source bulb of a headlight and reflected by a reflector, and can form a substantially desired light distribution pattern without being adjusted by a lens. It relates to an improved reflector.

[0002]

2. Description of the Related Art The basic structure of a conventional headlamp is such that light emitted from a light source bulb disposed near the focal point of a rotating parabolic reflector is parallel to the optical axis by the rotating parabolic reflector. A desired light distribution pattern is obtained by appropriately dimming, for example, by reflecting the reflected light beam in the left and right directions with a front lens. Recently, the reflector is not configured as a simple paraboloid of revolution, and the reflective surface is sectioned into a plurality of parts by design, while the paraboloid of revolution is a reference shape,
Techniques for forming a composite reflecting surface by slightly changing the focal length for each portion or slightly tilting the optical axis direction have been studied. The reflected luminous flux of the reflector having such a composite reflecting surface has a substantially desired light distribution pattern without dimming through the lens, so that even if the light is projected forward of the lamp through a transparent lens, it can be used as a headlight. Can perform the optical function of However, even in the case of using a reflector having a complex reflecting surface as described above, there is an example in which a prism is provided in a portion (dummy portion) through which a projected light beam does not pass in order to adjust the appearance of the lens. There is also an example in which a prism for correcting a light distribution pattern is provided in a portion where the light distribution pattern changes. In the present invention, a transparent lens means a lens through which a projected light beam passes through or nearly transparent.

FIG. 2 shows an outline of a headlamp provided with a compound reflecting surface and a transparent lens, wherein (A) is a horizontal sectional view including the optical axis Z, and (B) is a vertical sectional view including the optical axis Z. Since it is a schematic diagram with a small scale, the difference between the conventional headlight and the headlight according to the embodiment of the present invention is not shown. That is, it is an explanatory diagram that can be used in common for both the conventional example and the embodiment. Reference numeral 4 denotes a lamp housing, on which a transparent lens 5 is mounted so as to cover the front opening. Reference numeral 6 denotes a reflector having a composite reflecting surface described in detail later. Although the composite reflecting surface does not have a single focal point in the strict sense, the difference in focal length between the plurality of paraboloids of revolution forming the composite reflecting surface is small and almost the same. Since the focus is shared, this can be treated as a pseudo focus. Similarly, the optical axis Z shown in FIG. 2 is a quasi-optical axis strictly speaking, but in the present invention, this is called an optical axis. The light source bulb 7 is installed near the pseudo focus F. Reference numeral 8 denotes an inner panel for mainly adjusting the appearance of the headlight. Reference numeral 9 denotes a partition plate for preventing fogging.

[0004]

A headlight in an automobile is a device that performs an important optical function for illuminating a front side of a traveling road. On the other hand, a headlight is also used to constitute an automobile design. It is an important factor. For this reason, in many cases, a design deformed based on design considerations, not for improving the optical function, is put to practical use. Also in the example of FIG. 2A described above, the shape of the reflector 6 is the optical axis Z.
Right not symmetrical, the dimension L ₁ shown is set to be larger than the dimension L ₂ with respect to a vertical plane including the (paper perpendicular). FIG. 3 is a front view schematically illustrating a state in which two asymmetric reflectors shown in FIG. 2 are mounted on one vehicle. Each of the right reflector 6R constituting the right front headlight of the car and the left reflector 6L constituting the left front headlight of the car are asymmetrical with respect to a vertical line VV passing through the optical axis. The right reflector 6R and the left reflector 6L are bilaterally symmetric. Therefore, when the left reflector 6L is considered in detail as an example, it is as follows. The horizontal line HH passing through the optical axis is vertically symmetrical. The right and left sides are asymmetrical with respect to a vertical line VV passing through the optical axis.
The reflecting surface of this reflector is partitioned into 3 × 6 = 18 portions. For convenience of explanation, A1, B
Names are given with reference numerals such as 1, B2 and the like. Section B1,
B2, B3 and sections B1 ', B2', B3 'are substantially symmetric. Sections C1, C2, C3 and sections C1 ', C2',
C3 'can be regarded as incomplete but approximately symmetric. For this reason, the portion 6a shown in the figure is substantially symmetrical, and is called a symmetrical portion. And the asymmetric portion 6b
, Ie, sections D1, D2, D
3 is vertically symmetric, but asymmetric with respect to the vertical line V-V. FIG. 4 is a view taken in the direction of the arrow G, which is obtained by cutting the left reflector shown in FIG. 3 described above by a plane including the horizontal line HH. It is understood from FIG. 4 that the sections B2 and B2 'are symmetric, the sections C2 and C2' are substantially symmetric, and the section D2 is asymmetric.

As described above, since the reflector has the left-right asymmetric portion, there arises a problem that the light distribution pattern is left-right asymmetric as described below. FIG.
FIG. 4 is an explanatory diagram showing a front view of the left-right asymmetric reflector shown in FIG. 3 and a light distribution pattern chart formed by the reflector in comparison with each other. FIG. (B) shows a light distribution pattern formed by the portions, and (B) shows a light distribution pattern formed by the entire reflector. (See FIG. 5A.) Except for the asymmetrical portion 6b drawn by a virtual line, the light distribution pattern 10 formed by the symmetrical portion 6a is a symmetrical figure both vertically and horizontally. However, as shown in FIG. 5 (B), the light distribution pattern 11 formed by the entire reflector 6 including the asymmetric portion 6b is asymmetric in the left and right direction. It is not easy to improve the left-right symmetry of the light distribution pattern by designing and designing the paraboloid of revolution of each of the 3 × 6 = 18 sections forming the reflector 6. There is also a possibility that a part of the light beam will be invalidated by the inner panel 8 described above. The present invention has been made in view of the above-described circumstances, and is an improvement of a vehicular lamp in which a left-right asymmetric reflector is used so that there is no risk of being hindered by an inner panel. The purpose is to provide squeezing technology.

[0006]

The basic principle of the present invention created to achieve the above object will be briefly described with reference to FIG. 5 which is an explanatory view of the problems of the conventional example. Like. That is, as shown in FIG. 5A, considering only the reflected light beam by the symmetrical portion 6b of the headlight 6, a symmetrical light distribution pattern 10 is formed, but the reflected light beam by the asymmetrical portion 6b is superimposed. Then, the left-right symmetry is broken as in the light distribution pattern 11 shown in FIG. Focusing on such an optical mechanism, it is necessary to prevent the reflected light beam from the asymmetric portion 6b from breaking the symmetry of the light distribution pattern, that is, to make the reflected light beam from the asymmetric portion 6b symmetrical with respect to the vertical line VV. What is necessary is just to make an emission pattern.

As a specific configuration based on the above principle, the reflector of the headlight according to the present invention reflects a light beam emitted from the light source bulb and projects the light forward of the lamp through a transparent lens. In a reflector having a reflecting surface that is substantially bilaterally symmetric with respect to the vertical plane including the optical axis, and a reflecting surface that is not bilaterally symmetric with respect to the vertical plane including the optical axis, the non-symmetrical reflecting surface is vertically oriented. Are divided into a plurality, and each of the divided reflection surfaces receives the light beam emitted from the light source bulb and reflects the light beam toward the vicinity of the center of the light distribution pattern. Features.

[0008]

According to the above-mentioned means, the symmetrical portion of the reflecting surface of the reflector forms a symmetrical light distribution pattern without any particular difficulty. Then, the reflected light from the left-right asymmetric reflection surface is superimposed on the above-mentioned left-right symmetric light distribution pattern, and the left-right asymmetric reflection surface is divided into a plurality in the present invention. Is reflected toward the vicinity of the center of the light distribution pattern, and therefore does not adversely affect the symmetry of the superimposed left-right symmetric light distribution pattern. In this case, it is not easy to concentrate the reflected light flux on the central portion of the light distribution pattern unless the left and right asymmetric reflection surface is divided into a plurality of sections. However, in the present invention, the left-right asymmetric reflection surface portion is vertically divided into a plurality of sections, and each of the divided reflection surfaces is relatively small. The design approach toward the center is easy. The greater the number of sections, the smoother the gradient of the luminous intensity distribution of the light distribution pattern formed by superimposing the reflected luminous flux from each section, but if the number of sections is increased, more invalid portions occur at the boundaries between the sections. Become. With these points in mind,
Good results are obtained when the number of sections of the asymmetric reflection surface is about three. As described above, among the reflecting surfaces of the reflector having the left-right symmetric reflecting surface and the left-right asymmetric reflecting surface, the left-right symmetric light distribution pattern formed by the reflected light flux from the left-right symmetric reflecting surface is used. Since the reflected light from the left-right asymmetric reflection surface is superimposed near the center, a left-right symmetric light distribution pattern is formed without being blocked by the inner panel.

[0009]

Next, an embodiment of a headlight reflector according to the present invention will be described with reference to FIG. This FIG.
FIG. 2 is an explanatory diagram illustrating a front view of a reflector configured by applying the present invention, and a light distribution pattern chart formed by each of light beams reflected from each portion of the reflector, wherein FIG. A left-right symmetric part, (B) depicts a left-right asymmetric part, and (C) depicts the entire reflector reflecting surface. FIG. 1A is essentially the same as FIG. 5A described above, and the symmetrical portion 13a of the reflector 13 according to the embodiment configured by applying the present invention is different from the conventional reflector 6 shown in FIG. The same or similar configuration as the symmetrical portion 6a.
Therefore, the reflected light beam from the symmetric portion 13a causes
As shown in (A), a symmetrical light distribution pattern 10 is formed.

The asymmetric portion 13b of the reflector shown in FIG. 1 (B) is a main component of the present invention, and is divided into three sections in the vertical direction to form sections E1, E2 and E3. Have been. Additional compartments E1 forms an emission pattern 11d ₁ toward the vicinity of the center of the light distribution pattern approximately parallel to the reflection optical axis of the incident light from the light source bulb. Similarly compartment E2 is emitted pattern 11d ₂ toward the vicinity of the center of the light distribution pattern, partition E3 is the extraction pattern 11d ₃ toward the vicinity of the center of the light distribution pattern is formed. The The extraction pattern 11d ₁ ~11d ₃ is a rectangular, respectively, because the filament of the light source bulb has a thickness and a length rather than a point. Since the luminous flux from the filament of the light source bulb is obliquely incident on the section E1 and the section E2, the emission pattern 11
a shape that is inclined so as to intersect with each other between d ₁ and the 11d _2. Since such an emission pattern is superimposed on the left-right symmetric light distribution pattern 10 of FIG. 1A, the light distribution pattern 12 formed by the reflected light flux of the entire reflector is formed on the left and right as shown in FIG. Become symmetric.

In this embodiment, the asymmetric portion 13b is divided into sections D1, D1.
The D2, 3 pieces of emission pattern 11d ₁ since divided into three equal D3, 3 pieces of emission pattern of the 11d _2, the 11d ₃ are formed. In practicing the present invention, when the asymmetric portion is partitioned into n pieces, n emission patterns are formed.
Increasing the number of n smoothes the gradient of the luminous intensity distribution of the light distribution pattern and can precisely control the light distribution characteristics. However, when the number of n is large, the boundaries of the sections increase, and the invalid portion of the boundary (incident light Since the number of parts that are not effectively used increases, the number n may not be too large or too small. It is appropriate in normal cases to make it about three sections as in this embodiment. FIG.
As shown in (B), the light beam reflected by the asymmetric portion 13b located at the left and right ends of the reflector 13 is reflected toward the center of the light distribution pattern. There is no fear of being interrupted by the panel 8 (see FIG. 2).

[0012]

When the reflector of the present invention is applied, the symmetrical portion of the reflecting surface of the reflector forms a symmetrical light distribution pattern without any particular difficulty. Then, the reflected light from the left-right asymmetric reflection surface is superimposed on the above-mentioned left-right symmetric light distribution pattern, and the left-right asymmetric reflection surface is divided into a plurality in the present invention. Is reflected toward the vicinity of the center of the light distribution pattern, and therefore does not adversely affect the symmetry of the superimposed left-right symmetric light distribution pattern. In this case, it is not easy to concentrate the reflected light flux on the central portion of the light distribution pattern unless the left and right asymmetric reflection surface is divided into a plurality of sections. However, in the present invention, the left-right asymmetrical reflective surface portion is divided into a plurality of vertical directions,
Since each of the partitioned reflecting surfaces is relatively small, it is easy to design a method of directing the reflected light beams to the center of the light distribution pattern. The greater the number of sections, the smoother the gradient of the luminous intensity distribution of the light distribution pattern formed by superimposing the reflected luminous flux from each section, but if the number of sections is increased, more invalid portions occur at the boundaries between the sections. Become. Taking these points into consideration, good results are obtained when the number of sections of the asymmetrical reflecting surface is about three. As described above, among the reflecting surfaces of the reflector having the left-right symmetric reflecting surface and the left-right asymmetric reflecting surface, the left-right symmetric light distribution pattern formed by the reflected light flux from the left-right symmetric reflecting surface is used. Since the reflected light from the left-right asymmetric reflection surface is superimposed near the center, an excellent practical effect is obtained in which a left-right symmetric light distribution pattern is formed without being blocked by the inner panel.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram illustrating a front view of a reflector configured by applying the present invention and a light distribution pattern diagram formed by each of light beams reflected from each portion of the reflector, (A) depicts the symmetrical portion, (B) depicts the asymmetrical portion, and (C) depicts the entire reflector reflecting surface.

FIG. 2 shows an outline of a headlamp provided with a compound reflecting surface and a transparent lens, where (A) is a horizontal sectional view including an optical axis Z, and (B).
Is a vertical sectional view including the optical axis Z, and is a schematic diagram with a small scale. Therefore, no difference is shown between the conventional headlamp and the headlamp according to the embodiment of the present invention. That is, it is an explanatory diagram that can be used in common for both the conventional example and the embodiment.

FIG. 3 is a front view schematically illustrating a state in which two asymmetric reflectors shown in FIG. 2 are mounted on one vehicle.

FIG. 4 is a view showing a case where the left reflector shown in FIG.
It is the G arrow view cut and drawn by the surface containing -H.

FIG. 5 is an explanatory view showing a front view of the left-right asymmetric reflector shown in FIG. 3 and a light distribution pattern chart formed by the reflector in comparison with each other. FIG. And (B) show a light distribution pattern formed by the entire reflector.

[Explanation of symbols]

4 lamp housing, 5 lens, 6 reflector
6L: left reflector, 6R: right reflector, 6a ...
Symmetrical portion, 6b asymmetrical portion, 7 light source bulb, 8 inner panel, 9 partition plate, 10 light distribution pattern, 11d _1-
11d ₃ ... emission pattern, 12 ... light distribution pattern, 13 ...
Reflector in the embodiment of the present invention;
13b: asymmetric part.

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ identification code FI F21Y 101: 00 (58) Investigated field (Int.Cl. ⁷ , DB name) F21S 8/12 F21S 8/10 F21V 7/09 F21V 13/00

Claims (1)

(57) [Claims] 1. A headlight reflector for reflecting a light beam emitted from a light source bulb and projecting the light forward of a lamp through a transparent lens, wherein the reflecting surface is substantially symmetric with respect to a vertical plane including an optical axis. In a reflector having a reflecting surface that is not symmetrical with respect to a vertical plane including the optical axis, the reflecting surface that is not symmetrical is divided into a plurality in the vertical direction, and each of the divided reflecting surfaces is
A reflector for a headlight, which receives a light beam emitted from a light source bulb and reflects the light beam toward a central portion of a light distribution pattern.