DE2148478A1 - Reflector with radial grooves - Google Patents

Description

2148473

FHN. 4953. Dr. Herbert See !, V / ii / RV.

Awn «M.- ^ Y. Philips' GIoeilampenfabriekeo

Na PHN-4959
Note ^ _{1,. Ill: 2} Sept. 8, 1971

Reflector with radial grooves.

The invention relates to a reflector for a elongated light source arranged axially therein with its longitudinal direction.

Such a reflector results when he is axially elongated light source arranged therein is provided, a light beam, which has a high light intensity, especially in the central part.

To maintain a light beam with a uniform light distribution, the reflector could be radially with a number provided extending grooves that contribute to the scattering of the reflected light beam. If, for manufacturing reasons, in Cross-section of the groove maintains a constant radius of curvature it turns out that along a groove which is narrower near the tip of the reflector than at the largest reflector circumference, the scattering

209817/0809

-2- PlIlI. 4959

is not constant, which is also undesirable.

Instead, one could use these grooves, the radius of curvature of which is not constant, to improve the constancy of the light scattering attach the groove for a long time. However, this is particularly difficult to achieve.

The invention now aims to create a reflector also provided with radial grooves which, on the one hand, is simple Wise can be produced and on the other hand has good light-scattering properties.

For this purpose, the reflector according to the invention has the characteristic that the reflective inner surface of the reflector has a number in the radial direction of the reflector extending, not continuously merging, light-scattering, opposite this reflector has concave and convex grooves, the scattering power of each convex groove in a direction transverse to the optical axis of the reflector decreases from a maximum near the side edges of the groove "after a minimum at a point between the two edges and the scattering power of each concave groove increases by one MinL-b mum in the vicinity of the edges of the groove to a maximum at a point lying between the edges and where the maximum scattering ratio of the convex grooves in one direction from the largest circumferential edge to the tip of the reflector decreases and the minimum scattering power of the mentioned concave grooves increases in the direction of the reflector. With one on this Wisely formed reflector each one concave groove and an adjacent konyex groove can be considered as a unit, the two Longitudinal edges of one of the grooves form places for maximum scattering power and the other two longitudinal edges of the other groove places for

209817/0809

-3- PHN. 4959.

form a minimum dispersion capacity. This combination is obtained that the distribution of the reflected light is almost uniformly over the entire length of the unit ¹ formed by two adjacent grooves.

According to a preferred embodiment of the reflector according to the invention, each groove has a cross section which is longitudinal the entire longitudinal dimension of the groove has the same radius of curvature.

An embodiment of the invention is shown in the drawing and is described in more detail below. Show it:

Pig. 1 shows a longitudinal section through the reflector according to the invention,

Fig. 2 is a section along the line II - II in Fig. 1, 3 shows a section along the line III - III in FIG. 1, The reflector of Fig. 1 is essentially as a

Paraboloid 1 formed; axially arranged therein is an elongated incandescent body 2, which is at the focal point F.

This reflector is provided with a number of radially extending convex and concave grooves 4 and 6 and these have (Fig. 2 and 3) a cross section that consists of an arc of a circle with the radii R and R "is formed. The concave groove is off two parts 6A and 6B are formed.

Each concave groove goes according to a discontinuous

tl

smooth transition into a convex groove. Each groove forms one Part of a circular cylindrical surface. As a result, the groove width decreases, depending on whether the cross section is closer to the tip 5 of the reflector.

209817/0809

-4- PHN. 4959.

The light beams reflected by the reflector are indicated schematically in FIG.

The rays a incident on the convex grooves 4 are reflected in an opposite direction, while the Rays Jb are reflected back scattered, depending on the point of impact approaches the intersection point indicated by 7 between a convex and a concave groove. The variability is therefore in the vicinity of this intersection 7 maximum.

In a corresponding way, the on the concave grooves

k incident rays £ reflected back in an opposite direction, while the rays d_ between the center of the edges of the groove 6A, 6B are thrown back more widely scattered. The diversification is so in the vicinity of the edge 8 at most.

At the point of section III-III are the convex ones Grooves 4 are narrower and the cross section contains less scattering parts, while in the case of the concave grooves 6 the less scattering parts Parts are practically missing. As a result, in the case of two adjacent concave and convex grooves, the scattering properties in the Longitudinal direction of the grooves, stronger or weaker inward

". This promotes an even reflection over the entire cross-section of the reflected light beam.

In the above, every pair of adjacent ribs is considered to be

convex groove 4 and a concave made up of two parts 6A and 6B Groove shown. Of course, a convex groove composed of several parts and a single concave groove for an approximate the same uniform light reflection can be selected. Combinations of the same can also be selected.

209817/0809

Claims (2)

2U8478 -5- - PHN. 4959 PATENT CLAIMS ; Reflector for an elongated light source arranged axially therein with its longitudinal direction, characterized in that the reflective inner surface of the reflector a number of extending in the radial direction of the reflector, not continuously having merging, light-diffusing, concave and convex grooves in relation to this reflector, the diffusion capacity of each concave groove in a direction transverse to the optical axis of the reflector decreases from a maximum in the vicinity of the side edges of the Groove toward a minimum at a point between the two edges, and the scattering power of each concave groove increases from one Minimum near the edges of the groove to a maximum at a two + see the edges lying point, with the maximum scattering power of the convex groove in a direction from the largest peripheral edge to the tip of the reflector decreases and the minimum scattering power of the said concave groove increases in the direction of the reflector, 2. Reflector according to claim 1, characterized in that each groove has a cross-section along the entire longitudinal dimension the groove has the same radius of curvature. 5. Reflector according to one of the preceding claims, characterized characterized by having one with its longitudinal dimension axially therein arranged light source is provided. 20981 7/0809 Blank page