DE2714793C2 - Paraboloidal reflector for vehicle lights - Google Patents

Description

The invention relates to a parabolic reflector for vehicle lights, which is made of a transparent material and has total reflection prisms on the back which extends in the longitudinal direction in the direction from the apex to the outer edge and reflect the light emanating from the light source and entering the reflector body.

From AT-PS 1 08 844 and from US-PS 27 32 488 transparent reflectors are shown on their Rear have total reflection prisms, which extend from the apex to the outer edge of the reflector extend and reflect the light penetrating into the reflector body.

AT-PS 1 08 844 shows a reflector body with a very small focal length. This is the difference between the diameter of the upper reflector opening and the diameter of the lower reflector opening very low. This in turn has the consequence that the arranged outside on the reflector Prisms increase only insignificantly in width and height towards the outer diameter of the reflector. The disadvantage of such a reflector is that it is due to its small focal length at a given The outer diameter of the reflector requires a very large overall depth

In the reflector shown in US Pat. No. 2,732,488, it can be clearly seen how the reflector is radially on the back of the reflector extending prisms to the outer edge of the reflector both in width and in the The height will increase steadily. This leads to the fact that either the prisms in the apex of the reflector too small or too large in the outer area of the reflector. Very small prisms can only be used with the highest Manufacture precision and even then show inaccuracies in practice. Prisms leading to the outer edge become very high, form an injection molding obstacle during manufacture. Due to the different The wall thickness of the reflector essentially results during the solidification phase of the plastic

Dimensional inaccuracies.

The object of the invention is to provide a reflector of the above to create named genus, which is designed so that as much as possible of the incandescent lamp light impinging on the reflector is reflected in a predeterminable direction and that the reflector is in its wall thickness is the same as possible over its entire reflection surface. This object is achieved according to the invention solved in that the reflective surface

> o the reflector in several concentric to the optical Axis extending circular ring surfaces is divided, in which each further outward circular ring the number of roof prisms is increased so that the division between the individual roof prisms and the height of all roof prisms remains essentially the same

Another advantage of the reflector according to the invention compared to one that is silver-colored on the inside or high-gloss vapor-deposited reflector is that it is much easier, especially in mass production and is therefore cheaper to manufacture, without any disadvantage in its function being noticeable This applies to both use in lights and headlights.

In an advantageous further development of the inventive concept, the individual circular ring surfaces shifted against each other in the manner of a Fresnel lens. This embodiment enables a very flat design of the reflector even with a small focal length.

The drawing illustrates an advantageous embodiment of the invention, namely shows

F i g. 1 a vertical vertical section through the reflector along the line AA,

F i g. 2 is a rear view of the reflector and

F i g. 3 shows a section along the line BB, while
4 shows a detail at C with the beam path and
5 represent a partial view of the reflector from the X direction.

The reflector 1 is made of clear plastic and shows total reflection prisms on the back, which are designed as 90 ° roof prisms 2. These roof prisms 2 are arranged in such a way that the ridge 3 is directed from the apex of the parabolic reflector towards the outer edge.The course of the roof ridge 3 of the roof prisms in relation to the optical axis 4 is determined by the perpendiculars 6 on the bisector 5 of the angle α The angle α is formed by the incident light beam 7 running in the reflector material and the light emission beam 8. The course of the rays 8a emerging from the reflector in relation to the optical axis 4 thus determines the course of the curve of the roof ridge 3, taking into account the refractive index of the material.

Since the light incident on the roof surfaces 9 and the light incident on the roof surfaces 10 is reflected in the same direction can speak of an almost complete reflection of the light hitting the reflector will. Restrictions only have to be made with regard to the roof ridges and the joint surfaces between two adjacent roof prisms can be made.

Since the roof prisms remain the same from the apex of the reflector to the outer edge would be both wider and higher, so that the reflector because of the intensifying material

rial accumulation would be difficult to produce in the injection molding process while maintaining the same accuracy According to the invention, the reflective surface is divided into several circular surfaces possible, the annulus lying further out to give a higher number of roof prisms so that the division between the individual roof prisms and the height of all roof prisms are essentially remains the same

For this purpose 2 sheets of drawings

Claims (2)

Patent claims: 1. Paraboloid-shaped reflector for vehicle lights, which is made of a transparent material and total reflection prisms on the back which extend in the longitudinal extent in the direction from the apex to the outer edge (Roof prisms) and that emanating from the light source and penetrating into the reflector body Reflect light, characterized in that the reflective surface of the reflector in several concentric to the optical Axis (4) extending circular ring surfaces (11) is divided, in each case further outward Circular ring the number of roof prisms -srhöht is such that the division between the individual Roof prisms and the height of all roof prisms remains essentially the same 2. Reflector according to claim 1, characterized in that that the individual annular surfaces (11) axially against one another in the manner of a Fresnel line are shifted.