EP0485818A1 - Headlight - Google Patents

Abstract

The headlight has a lens (4) convex towards the light source (1). Said lens is constructed as a one-piece moulded part, and has in its central zone (5), which is closest to the light source (1), a collector lens structure (9). Consequently, a substantial portion of the light emitted from the light source (1) directly into a front solid angle can be collected in the direction of the headlight axis. The lens (4) can be produced as a simple moulded part. Provided outside on the lens (4) is a transparent ring (15) in a signalling colour. As a result, the scattered light is utilised for lateral marking when the headlight is used, for example, in a cycle lighting unit. <IMAGE>

Description

The invention relates to a headlamp with a light source arranged in the headlamp axis, with a reflector and with a lens arranged in front of the light source, and in particular with a headlamp for relatively weak light sources, such as are present in bicycle lighting systems.

In lighting systems with a relatively low power output for the light sources, it is important that the light generated can be used in an optimal manner. The smallest possible part of it should be lost as stray light. A distinction must be made between the light that first falls on the reflector from the light source and is directed approximately parallel through it, and the light that falls directly on the diffuser at a front solid angle. The light of the first origin can be deflected relatively well in the desired direction by the diffusing lens optics in order to generate a corresponding light cone. With the light coming directly from the light source onto the lens, the problem arises that the beam path has to be deflected relatively strongly, for which purpose a collecting lens must be provided on the lens. The converging lens is intended to capture as large a solid angle as possible of the directly emitted light, without, however, taking up too large an area of the lens. For this purpose, it has already been proposed to cement a relatively thick converging lens on the inside of the lens, which bundles the direct light from the light source. However, this solution is complex in terms of production technology.

It is therefore the task of designing a headlamp of the type mentioned at the outset in such a way that, with essentially unchanged production expenditure, substantially better utilization of the direct light of the light source and a reduction in the false light.

This object is achieved by the features mentioned in the claims.

Because the lens is curved inwards, a much larger solid angle of the direct light can be used, whereby the collecting lens structure, which is preferably designed as a Fresnel lens, does not require a significant local thickening of the lens, which could not be controlled during manufacture. The spreading disc designed in this way can therefore be efficiently produced in a conventional manner as a one-piece molded part made of plastic or Olas. The scattered light, which is still reduced, is advantageously used to produce a laterally visible, illuminated zone on the headlamp, for which purpose a transparent ring is formed on the periphery of the lens, through which false light radially emerges.

• Figur 1 eine erste Ausführung des Scheinwerfers in Schnittansicht, längs einem Vertikalschnitt durch die Scheinwerferachse;
• Figur 2 eine Frontansicht auf die Streuscheibe;
• Figur 3 einen Schnitt entlang der Linie III-III in Figur 2;
• Figur 4 eine Seitenansicht des Scheinwerfers einschliesslich seinem Gehäuse;
• Figur 5 eine zweite Ausführung des Scheinwerfers in der Darstellung gemäss Figur 1, und
• Figur 6 eine weitere Ausführung des Scheinwerfers mit zusätzlichem Reflektorring.

Exemplary embodiments of the invention are explained in more detail below with reference to the drawings. Show it:

• Figure 1 shows a first embodiment of the headlight in a sectional view, along a vertical section through the headlight axis;
• Figure 2 is a front view of the lens;
• 3 shows a section along the line III-III in Figure 2;
• Figure 4 is a side view of the headlamp including its housing;
• Figure 5 shows a second embodiment of the headlamp in the representation of Figure 1, and
• Figure 6 shows another embodiment of the headlamp with an additional reflector ring.

With reference to Figures 1 and 2, the optical design of the headlamp is explained in principle before going into further details. The headlight has a light source 1, which is preferably is designed as a halogen lamp. The light source is drawn in a dot shape in FIG. 1, but is actually designed as a spiral. The light source is arranged in the focal point of a parabolically or elliptically shaped reflector 2. The light rays striking the reflector 2 from the light source are therefore reflected approximately parallel to the headlight axis 3 and thus strike a diffusing screen 4. The diffusing screen 4 is formed from a translucent material, for example a transparent plastic such as PMMA. Their shape essentially determines the beam path of the headlamp.

The lens 4 is divided into different zones. A central zone 5 is provided for deflecting the light coming directly from the light source 1. The outer peripheral zones 6, 7, 8 are divided into an upper zone 6, a central zone 7 and a lower zone 8 (see FIG. 2) and serve to deflect the light reflected in parallel by the reflector 2.

The lens 4 is curved toward the light source 1. This has the effect that the central zone 5 is close to the light source 1 and thus detects a relatively large solid angle of the directly emitted light from the light source. The light incident on the lens at this solid angle is collected by means of a converging lens structure to form a light bundle 10 which is emitted essentially in the direction of the headlight axis 3.

The converging lens structure in the central zone 5 is designed as a Fresnel lens 9 arranged concentrically to the axis 3, so that the thickness of the lens 4 remains relatively uniform. This is an important prerequisite for their manufacture as plastic molded articles. Superimposed on the Fresnel lens, the lens in the central zone 5 forms a fourth-order curve in vertical section, which means that the rays that pass through this central zone 5 are deflected somewhat more strongly, ie towards the axis 3, than the deeper rays that pass through Axis direction 3 run (see FIG. 1). Which in turn has the consequence that the cone of light falling obliquely onto the street or other surface leads to a light spot of essentially constant brightness. In contrast to conventional lamps, the brightness in the light spot generated by the obliquely incident light cone does not decrease with increasing distance from the headlight.

A corresponding configuration of the lens is present in the edge zones 6, 7, 8 already mentioned, of which only the upper zone 6 and the lower zone 8 are visible in FIG. 1. Here too, in vertical section, the diffusing screen forms a fourth-order curve with a correspondingly greater deflection of the higher-passing rays. Correspondingly, the light bundles 11 and 12 from these zones 6, 8 also lead to a light spot with a regular light distribution on a base in the case of oblique incidence.

If these zones are viewed in a horizontal section (cf. FIGS. 2 and 3), they have a scattering lens structure 14 of a type known per se, which, according to FIG. 3, leads to a lateral divergence of the light cone. The edge zone 7 has the same configuration.

If the headlight designed in this way is used as a bicycle lamp, it produces an essentially trapezoidal light spot of uniform brightness on the street at a distance of 4 m to 10 m from the lamp position. Since the direct light of the solid angle detected by the central zone 5 contributes to this, the luminous efficacy can be significantly improved.

As can be seen from FIG. 1, part of the light from the light source is neither reflected on the reflector nor collected as direct light from the central zone. This scattered light is now also used in that it emerges laterally radially through a transparent ring 15. The transparent ring preferably has a signal color, so that it appears in a side view as a streak glowing in the signal color occurs (see Figure 4). The scattered light from the headlight contributes to the lateral marking of, for example, a cyclist at night, which is otherwise often only possible with passive reflectors. The transparent ring 15 can also be designed as a mounting element for connecting the reflector 2 and the diffuser 4.

Figure 4 shows a possible embodiment of the described headlamp as a bicycle lamp. The headlight with signal ring 15 and reflector 2 is arranged on a housing 16.

Finally, FIG. 5 shows a somewhat modified configuration of the diffusing screen 4. As can be seen, this differs from the embodiment according to FIG. 1 only in that the central zone 5 itself forms a bulge against the light source 1. It can be achieved that the detected solid angle of the direct light is further increased.

As can be seen from FIG. 6, the described headlight can also be provided with a reflector ring 16 directed forward. Should the light source 1 or its supply fail, this serves to make the bike recognizable for oncoming traffic at night. The reflector ring 16 made of transparent plexiglass has a back 17 with a reflector structure. It is welded to a ring made of transparent red plexiglass designed as a signal ring 15, through which stray light can escape laterally in the manner described. The whole can be designed as a snap ring for mounting the lens 4 on the reflector 2. In this embodiment, the headlamp according to the invention is an integrated, active and passive effective, visual identification in traffic.

Overall, the described headlamp allows light sources with relatively low power, such as those used in bicycle light systems, to be used optimally for light generation by the false light losses are reduced and the light is emitted in an optimal manner, so that an extensive light spot with even light distribution is generated in front of the bicycle on the street. The components, in particular the diffusing screen, can be produced as molded parts in efficient processes.

Claims (12)

Headlamp with a light source (1) arranged in the headlamp axis (3), with a parabolic or elliptical reflector (2) and with a diffuser (4) arranged in front of the light source, characterized in that the diffuser (4) is designed as a one-piece molded part and is provided with a curvature towards the light source (1), a converging lens structure (9) being formed in a central zone (5) closest to the light source (1), such that a substantial part of the light source (1 ) light emitted directly into a front solid angle approximately in the direction of the headlight axis (3). Headlight according to claim 1, characterized in that the converging lens structure (9) is designed as a Fresnel lens at least in the radially outer region of the central zone. Headlight according to one of the preceding claims, characterized in that the lens (4) is designed as a molded part of approximately constant thickness. Headlight according to one of the preceding claims, characterized in that the central zone (5) of the diffusing screen (14) is surrounded by edge zones (6, 7, 8) for deflecting the light reflected approximately parallel by the reflector (2), in the edge zones the deflection in the lateral direction takes place in such a way that a laterally diverging light cone is generated. Headlight according to one of the preceding claims, characterized in that the central and optionally the edge zones are shaped such that the light rays in the lower region of each zone essentially in the headlight axis direction (3) and in its upper region are increasingly deflected towards the headlight axis. Headlamp according to claim 5, characterized in that in addition to the spherical sections, a fourth-order curve is superimposed on the lens surface in each edge zone (6, 7, 8) in vertical section. Headlight according to one of the preceding claims, characterized in that the central zone (5) is provided with an additional curvature towards the light source. Headlight according to one of the preceding claims, characterized in that a transparent ring (15) is formed on the periphery of the lens (4), through which stray light radially emerges. Headlight according to claim 8, characterized in that the transparent ring (15) has a signal color. Headlight according to one of claims 8 or 9, characterized in that the transparent ring (15) is designed as a retaining ring for fastening the lens to the reflector. Headlight according to one of the preceding claims, characterized in that the light source (1) is a halogen lamp. Use of the headlight as a bicycle light.

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