JPH0439137A - Projector lamp - Google Patents

Abstract

PURPOSE:To effectively utilize the light from a light source with no futility and improve radiation efficiency by integrally providing a translucent cylindrical section connected to the opening end section of a reflecting mirror and surrounding the second focal point on the outer periphery section of a convex lens arranged in front of the second focal point where the light reflected by the reflecting mirror is collected. CONSTITUTION:A projector lamp 11 has a reflecting mirror 12 with an elliptical cross section opened at the front end, and the reflecting mirror 12 has the first and second focal points f1, f2 on one optical axis passing the center. The filament 14 of a halogen lamp 13 fitted at the rear end section of the reflecting mirror 12 is located at the first focal point f1, and the focal point f3 of a convex lens 15 arranged in front of the reflecting mirror 12 coincides with the second focal point f2 where the light reflected by the reflecting mirror 12 is collected, and the light collected at the second focal point f2 is projected forward by the convex lens 15. A translucent cylindrical section 16 extended toward the front end opening section 12a of the reflecting mirror 12 is integrally formed on the outer periphery section of the convex lens 15, and the incident light into an inner periphery face 17b is refracted forward and radiated as the parallel light sent forward from the outer periphery face 17a of the cylindrical section 16.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a projector lamp that projects light reflected by a reflecting mirror having an elliptical cross section forward using a convex lens.

[Prior Art] Conventional headlamps for motorcycles have a reflector that is curved in a parabolic cross section, a so-called parabola.
A mirror is used, and a front lens is attached to the front end opening of this reflecting mirror.

In this headlamp, the light from the filament is converted into parallel light by the reflector and sent forward,
This parallel light is refracted by the front lens and distributed in an appropriate pattern.

Recently, a so-called projector lamp in which a reflecting mirror has an elliptical cross section has been developed as an alternative to the conventional headlamp, and has been put into practical use for motorcycles and four-wheeled vehicles.

This projector lamp has a halogen bulb placed at the first focal point of a reflecting mirror with an elliptical cross section, and a convex lens placed so that the focus coincides with the second focal point where the light reflected by the reflecting mirror gathers. , the light from the halogen bulb is projected forward through a convex lens.

A projector lamp with such a configuration uses a convex lens to convert the light from the halogen bulb concentrated at the second focal point into parallel light and send it forward, resulting in less light diffusion than a conventional headlamp that uses a parabolic mirror. This improves the illumination intensity of the road surface.

Moreover, even when emitting the same amount of light, the diameter of the reflecting mirror is smaller than that of a headlamp using a parabolic mirror, which has the advantage that the headlamp itself can be made smaller in diameter.

[Problems to be Solved by the Invention] However, even in this type of projector lamp, not all of the light from the halogen bulb is directed forward, and there is some wasted light that is not directed forward.

In other words, among the light from the halogen bulb, the light directed toward a position away from the second focal point is absorbed by the surrounding wall that covers between the front end opening of the reflector and the convex lens before reaching the convex lens, or is emitted to the outside. The light often leaked and could not be used to illuminate the front.

Therefore, there is still room for small improvements in terms of increasing irradiation efficiency.

The present invention was made based on these circumstances, and
An object of the present invention is to provide a projector lamp that can effectively utilize light emitted from a light source as illumination light without waste, and can improve irradiation efficiency.

[Means for Solving the Problems] Therefore, in the present invention, a reflecting mirror having an elliptical cross section with an open front end is provided, a light source is disposed at a first focal point inside the reflecting mirror, and the reflecting mirror is Assuming a projector lamp in which a convex lens is arranged in front of a second focal point where light reflected from The present invention is characterized in that a translucent cylindrical portion surrounding the second focal point is integrally provided on the outer periphery, continuous with the open end of the reflecting mirror.

[Function] According to this configuration, the light directed from the light source toward the reflecting mirror is reflected by the reflecting mirror and then concentrated at the second focal point in front, and
From here it is guided towards the convex lens.

Then, when this light passes through the convex lens, it is refracted and becomes a parallel light beam, which is projected in front of the convex lens.

In addition, some light from the light source is directed to a position far away from the second focal point, but this second focal point is surrounded by a translucent cylindrical part that is integrated with a convex lens. Therefore, light directed toward a position away from the second focal point is incident on the cylindrical portion. This incident light is refracted in the process of passing through the cylindrical portion, and becomes light directed forward or toward the periphery of the cylindrical portion.

For this reason, the light from the light source is irradiated not only from the convex lens but also from the cylindrical part, which allows for more effective use of light with no waste compared to conventional methods, and the light emitting area itself becomes much larger. .

[Embodiment] A first embodiment of the present invention will be described below based on FIGS. 1 and 2 in which the present invention is applied to a scooter type motorcycle.

The underbone-shaped frame indicated by reference numeral 1 in Fig. 2 is
A steering head vibe 2 is provided at its front end.

A front fork 4 is pivotally supported on the steering head vibe 2 via a steering shaft 3, and this front fork 4 supports a front wheel 5.

A steering bar handle 6 is connected to the upper end of the steering shaft 3, and the bar handle 6 is surrounded by a hollow handle cover 7.

The front part of the frame 1 and the upper part of the front fork 4 are covered with a leg shield 9 that is integrated with a front fender 8, and the upper part of this leg shield 9 is continuous with the handle cover 7.

Incidentally, a headlamp 10 is incorporated into the front surface of the handle cover 7. This headlamp 10 has
A projector lamp 11 according to the present invention is used, and details of this projector lamp 11 will be explained below with reference to FIG. 1.

That is, the projector lamp 11 includes a reflecting mirror 12 having an elliptical cross section and an open front end.

Although the reflecting mirror 12 has an elliptical vertical cross section, the overall shape is not a simple rotation of this ellipse, but a compound ellipse in which the elliptical cross section is gradually changed in the horizontal direction. ing.

The reflecting mirror 12 has two focal points, first and second, f, f2 on one optical axis passing through its center. The first focal point f1 is located inside the reflecting mirror 12, and the second focal point f2 is located outside the front end opening 12a of the reflecting mirror 12.

A halogen bulb 1 as a light source is installed at the rear end of the reflector 12.
3 is installed. The filament 14 of this halogen bulb 13 is located at the first focal point f.

A convex lens 15 is arranged in front of the reflecting mirror 12. In this embodiment, the focal point f of this convex lens 15 coincides with the second focal point f2 at which the light reflected by the reflecting mirror 12 gathers, and the convex lens 15 directs the light that gathers at the second focal point f2 forward. It is configured to project.

By the way, on the outer periphery of this convex lens 15, there is a reflecting mirror 12.
A translucent cylindrical portion 16 extending toward the front end opening 12a of the
are integrally formed. The diameter of the cylindrical portion 16 is continuously enlarged as it progresses from the convex lens 15 to the reflection [12], and the opening end 16a, which has the maximum diameter, is the front end opening 12a of the reflecting mirror 12. are matched against.

Therefore, the cylindrical portion 16 coaxially connects the convex lens 15 and the reflecting mirror 12, and the second focal point f2 of the reflection M12 is located inside the cylindrical portion 16. and,
This cylindrical portion 16 is connected to the handle cover 7 together with the convex lens 15.
exposed from the front.

Further, in the case of this embodiment, the outer circumferential surface 17a and the inner circumferential surface 17b of the cylindrical portion 16 are inclined in a direction that moves away from the optical axis as it advances toward the reflecting mirror 12, and the light on the inner circumferential surface 17b is The inclination angle α1 with respect to the axis is set larger than the inclination angle a2 of the outer peripheral surface 17a. Therefore, the wall thickness T of the cylindrical portion 16 becomes smaller toward the reflecting mirror 12 side.

According to such a configuration, light directed from the filament 14 of the halogen bulb 13 toward the reflecting mirror 12 is reflected by the reflecting mirror 12 and then reflected by the second mirror in front, as shown by the solid arrow in FIG.
The light converges at the focal point f2 and is guided toward the convex lens 15 from there. Then, when this light passes through the convex lens 15, it is refracted to become a parallel light beam and is projected in front of the convex lens 15.

On the other hand, the light from the filament 15 has a focal point f2 of ¥32
There is also light that travels toward the convex lens 15 through a position far away from the second focal point f2, but since this second focal point f2 is surrounded by the translucent cylindrical portion 16 that is integral with the convex lens 15, Light passing through a position far away from the focal point f2 is incident on the cylindrical portion 16, as shown by the chain arrow in the tJ1 diagram.

In this case, the inner circumferential surface 17b of the cylindrical portion 16 is inclined in a direction that moves away from the optical axis as it advances toward the reflecting mirror 12, so that the light incident on the inner circumferential surface 17b of the cylindrical portion 16 is , as shown in FIG. 1, is bent forward and the cylindrical part 1
The light is emitted from the outer circumferential surface 17a of the lens 6 as parallel light directed forward.

Therefore, the light from the halogen bulb 13 is transmitted through the convex lens 1
Since it is guided forward not only from 5 but also from the cylindrical part 16,
The light from this halogen bulb 13 can be used effectively and without waste for illuminating the front. Therefore, the irradiation efficiency is improved compared to the conventional method, and the light emitting area itself becomes larger.

Note that the present invention is not limited to the first embodiment described above, and FIG. 3 shows a second embodiment of the present invention.

This second embodiment differs from the first embodiment in that the inner circumferential surface 17b of the cylindrical portion 16 is formed parallel to the optical axis, and the thickness T of the cylindrical portion 16 is The structure is the same as that of the first embodiment, except that it becomes thicker toward the side.

According to the configuration of the second embodiment, among the light from the filament 14, the light that passes through a position far away from the second focal point f2 is incident on the inner circumferential surface 17b of the cylindrical portion 16 parallel to the optical axis. Ru. This incident light is refracted radially outward of the cylindrical portion 16, as shown by the chain line in FIG. 1, and becomes light that is diffused around the cylindrical portion 16.

Therefore, similarly to the first embodiment, the halogen bulb 13
The irradiation area can be expanded by making effective use of the light from the

In carrying out the present invention, the inner circumferential surface of the cylindrical portion may be used as a light diffusing surface by providing a large number of projections and depressions on the inner circumferential surface.

In addition, in the above embodiment, the focal point of the convex lens is set to the second point of the reflecting mirror.
Although the focal point is made to coincide with the focal point, the present invention is not limited to this, and the focal point of the convex lens may be shifted from the second focal point toward the reflecting mirror to spread the light projected by the convex lens.

Further, in the above embodiment, a halogen light bulb is used as a light source, but the present invention is not limited to this, and for example, a metal halide lamp may be used.

Furthermore, the projector lamp according to the present invention is not limited to use in motorcycles, but can be applied to other vehicles such as passenger cars and snowmobiles, and can also be used not only as a headlamp but also as a fog lamp. It is.

[Effects of the Invention] According to the present invention described in detail above, the light from the light source is guided not only through the convex lens but also from the cylindrical portion connected to the convex lens toward the front or the surroundings. can be used effectively for lighting without waste.

Therefore, there are advantages in that the irradiation efficiency is improved and the light emitting area itself is increased compared to the conventional method.

[Brief explanation of drawings]

1 and 2 show a first embodiment of the present invention, FIG. 1 is a sectional view of a projector lamp, FIG. 2 is a side view of a motorcycle, and FIG. 3 is a first embodiment of the present invention. FIG. 2 is a sectional view showing a second embodiment. 12...Reflector, 13...Light source (/\Rogen bulb)
, 15... Convex lens, 16... Cylindrical portion, f,...
First focal point, f2...second focal point. 12-...Tit 73--Halogen electric field 15, -Convex lens' 16--Condyle IQ Applicant's agent Patent attorney Takehiko Suzue Figure 1

Claims (1)

[Scope of Claims] A reflecting mirror having an elliptical cross section with an open front end, a light source disposed at a first focal point inside the reflecting mirror, and a second focal point at which the light reflected by the reflecting mirror is collected. in front of the
In a projector lamp in which a convex lens is arranged so as to focus at the second focal point or at a position shifted toward the light source from the second focal point, on the outer periphery of the convex lens, continuous to the opening end of the reflecting mirror, A projector lamp characterized in that a translucent cylindrical portion surrounding the second focal point is integrally provided.