DE1287031B - Mirror reflectors for surface illuminating light sources, especially fluorescent lamps - Google Patents

Description

In known mirror lights for fluorescent lamps, the special design of a biparabolic one pen, the mirror reflector channel has the cross section '·; Mirror reflector and its assignment to the upper one Parabola. Their focal length is roughly equal to the surface emitting light source due to overlapping Radius of the fluorescent lamp cylinder. The distance and overlap in the guidance of the luminous flux between reflector and fluorescent lamp is in the 5 especially in the luminaire axis and lower Sei-vertex also roughly equal to the radius, so that the tenwinkel different sections of the surface Focal point of the parabola on or within that of the lamp in the same beam direction at the same time Fluorescent lamp cylinder become effective on its vertical axis, lies. In particular, this is a part of the

As a result of the spatially extended surface of the 10 facing the reflector and the space section diffusely radiating light source is a distinct surface of the lamp cylinder facing away from it, additional focal point assignment, as with directed radiation borrowed on the same side through multiple reflection with one side point light source, not possible. borrowed surface sections of the surface of the

Such mirror reflector lights produce a lamp cylinder in the same beam direction, a narrow band of light with a maximum near the i ₅ overlapping and simultaneously overlapping the reflector axis. At a side angle of about 15 ° benefits. The light intensity of these reflector sections decreases the light intensity by about a fifth, this increases, these sections appear and at about M ⁰ 'are only about twice as bright as the naked lamp, and the illumination of the naked lamp. At a side angle of about 45 °, the space section determined by the reflector becomes ineffective, so that it is significantly increased for the further openings. A lateral abstraction angle only shines the bare lamp. ment outside of that determined by the reflector

This fact may be the reason why the room section that is preferred to be illuminated Manufacturers of mirror reflector lights are also significantly reduced to this, have passed, two or even three fluorescent For a simultaneous indirect and immediate

lamps to be arranged directly one behind the other, where- 25 reflection by mirror reflectors has since become only with one the focal length of the common reflector arrangements with two separate reflectors and accordingly known their opening width, with additional other parts of the has increased by about a third. Anticipation is DA lamp surface by a "second, separate in into account taken that reflector remains in the direction of the axis above the first reflector in a Raumnur the front lamp immediately effective. ₃₀ cutout to be reflected. An association of two or even three immediately This effect is achieved with one out of two

lamps arranged one behind the other to the focal-partial parabola cross-sections formed reflector body, point of a common larger parabola appears ... which envelops the fluorescent lamp at the top and on the sides to make the reflection even less possible. ", according to the invention, because the axes of the beam angle is indeed widened, but the ₃₅ two partial parabolas likely to the main axis, the efficiency tends laterally almost parallel or slightly angled gezum in a favorable ratio fluorescent lamp twice or more times the amount of energy comparable with the surface of the fluorescent lamp and are available material, such as the Lichtverteilungskur - run and the two focal points of the two parts emerge. The front lamp does not cover parabolas on or within the fluorescent lamp, only the ones behind it, both also cover ₄₀ cylinders ... ^ ;; ....;..

Parts of the otherwise effective reflector in side angles, the focal lengths of the partial parabolas and the distance

and only portions of its surface to come ^..: their focal axes of the main axis corresponds to reflection. expediently about half the size of the radius of the

With the invention, the disadvantages mentioned fluorescent lamp. The two reflector channels can avoided, and in particular a widening 45 will directly abut one another or via a preferential ridge of the light band into one another at side angles through a new, concavely curved partition Reached training of the mirror reflector, with a pass.

compared to the known prior art, the side wings of the mirror reflector channel can

reverse way is labeled. . until. to the distance "of, about, half the radius

Instead of a mirror reflector channel with the cross-s <5 ^: "below def'Leüctitstofflainpe", a parabola is used composes the ge-partial parabolas. . , the entire surface of the same used for reflexion

For the use of mirror reflector channels.

with a cross-hook - from two partial parabolas are "55 '-' · One such mirror reflector produces light bands, proposals are known which assume that a light intensity in the direction of the main axis has a light intensity as far as possible all of the beam emanating from the light source with about the 3rd The light sources that strike the reflector have 14 times that of the bare lamp, and, in contrast to the simple parabolic reflector, in the area of the light source, directly past the light source at an angle of -45 °, double the light intensity in different directions into the room 60 reflected the bare £ ampe · have .. - should ■ For page same angle _f occur in contrast.

In each beam direction so the the unused portion of the surface of the fluorescent lamp, · beam direction opposite side of the virtually each set to simple mirror reflector lamps not <the mirror image of another part of the surface dead zones of reflection more because the previously un- <the fluorescent lamp reflected Lamp cylinder 65 which faces the apex of the reflector, -; remains unused. due to the lateral displacement of the partial parabolas S

According to the present inventive idea is partly reflected directly into the room and \ held hitherto this teaching deliberately left by _t by partially external to the same side reflector

3 4

wing and only from there further into the free space, fluorescent lamp 1 is reflected into the room,

is reflected. For reflection points between S ₂ and F occurs. - how

The principle according to the invention can also be shown for the normal beam MN - first turn a recircular or pear-shaped lamp flexion on the reflector at R ₁ and then into space. In these cases the reflector body is as 5 in.

Paraboloid of revolution of the partial parabolic cross-sections With the tangential rays, which are shown in dashed lines, are drawn, the following relationships result:

In the drawing, an exemplary embodiment is shown in the case of the known parabolic reflector 2 (left), the mirror reflector according to the invention for a luminous tangential beam F is reflected at 8 approximately parallel to the main lamp in comparison with a simple parabolic axis H into the room. In contrast, the reflector is shown. It shows the tangential ray belonging to the normal ray MF ₁

F i g. 1 no longer reflects the cross-section of both reflector bodies at all. It behaves similarly

Scheme with section through the fluorescent lamp, a transverse beam at the lowest point U of the fluorescent

F i g. 2 the schematically indicated side reflection lamp,

of a well-known parabolic reflector, 15 In the biparabolic version (right), the

. Fig. 3 in comparison, the side reflection of a tangential ray through F first to R ₂ at the Re-

inventive reflector, reflector and then reflected into the room. The dem

4 shows the comparative cross section of FIG. 1 associated with normal ray MF ₂ ; tangential ray is

with drawn radiation and reflection at R ₃ on the reflector and from there into the room

course. 20 inflected. Likewise the cross beam at the lowest point U

In Fig. 1 and 4, the fluorescent lamp with 1, that of the fluorescent lamp with i? ₄ Parabolic reflector, which is known in the space as a dashed line, is reflected.

The comparison shows that the inventive reflector channel made of two partial parabolic cross-sections 3 _t denotes a biparabolic reflector according to the invention in contrast to the biparabolic reflector and 3 ₂ . Furthermore, S denotes the vertex ₃₅ known parabolic reflectors through the intersections of the known parabola, S ₁ and S ₂ the vertices of the and superimpositions of direct reflection and partial parabolas, F the focal point of the known indirect reflection in the same beam directions parabola, F ₁ and F ₂ the focal points the partial different points of the fluorescent lamp surface parabola, H the focal axis of the known parabola become spatially effective at the same time, so that the reflector and at the same time the main axis of the fluorescent lamp 1, H _{1 30} reflector a higher light intensity than the bare one and H ₂ the focal axes of the partial parabolas and r owns the lamp.
Radius of the lamp cylinder. The practical result is shown in FIGS. 2 and 3

It can be seen that the Re according to the invention is compared in comparison. The hatched ones The reflector bodies with the connecting edge of the two lines show the partial light parabolas emanating from the luminaire on the fluorescent lamp cylinder in 35 bands.

whose apex is on top. The vertices S ₁ In the known reflector according to FIG. 2 join and S _{2 of} the two partial parabolas S ₁ and 3 ₂ have the light bands to the left in about 30 ° side distance from the cylindrical surface of the fluorescent angle already at the outer edges of the reflector lamp 1 smaller than r. The two focal points F ₁ dead reflection zones. At about 45 ° side angle and F ₂ are within the fluorescent lamp 40, the reflector is completely ineffective and only cylinder 1 still has dead reflection zones.

To illustrate the novel effect of the biparabolic reflector according to FIG. 3 form

way of the reflector training according to the invention is fluorescent lamp and reflector with the same side

in Fig. 4 the beam path of different limit angles for the entire opening width of the re-

rays drawn in, namely on the left for a light band closed by a reflector. Only at still

known parabolic reflector and right for the right larger side angles show increasing from the

Channel of the biparabolic reflector according to the invention. Dead reflection zones similar to the outer edges, while

Because this is diffuse light, rend are at the same time opposing reflector edges

to illustrate border rays - normal - gradually cover the fluorescent lamp,

rays and tangential rays - shown. 50 The essential results from the foregoing

Under normal rays, such rays are to be enhanced lighting effect in the light exit

the space provided by a point on the lamp surface,

emerge vertically, as if they were from their central The reflectors according to the invention can be

axis go out. Tangential rays are those that are moderately in place of the previous execution

be made of plastic with glass mirrors,

walk. which are provided with a metallized reflective layer

First of all, the normal rays should be treated.

will. In the case of the well-known parabolic reflector 2 (left), the plastic version is simplified and

the MFS beam is reflected in itself and not only makes production cheaper, but also allows it

remains ineffective in terms of space. The beams MS ₁ and MF ₁ 60 in particular due to the significant weight reduction

are at 4 or 5 tion on the surface of the lamp, such mirror reflectors as top units

at 6 and 7, respectively, are reflected and in turn remain space to be developed with which subsequently existing ones

ineffective. This lack of room reflection consists of systems that can be equipped. The reflectors

for all normal rays approximately in the upper third of the, incisions or cutouts can be made for this purpose.

the area of the reflector facing the lamp 2. 65 savings, e.g. B. with longitudinal reflectors in width and

In the biparabolic execution according to the invention depth of the sockets and possibly the starter of the

on the other hand (right) the beam lamps to be compared will have, whereby by the snug fit of the re-

len MS ₂ and MF ₂ on the partial _{parabolic reflector 3 2} on the reflector simply by placing it on the fluorescent

lamps can be held and secured against twisting.

Claims (4)

Patent claims: 1. Mirror reflector for surface-illuminating light sources, in particular fluorescent lamps with a reflector body, the cross-section of which is composed of two partial parabolas which envelop the fluorescent lamp at the top and on the sides, characterized in that the axes (H ₁ , H ₂ ) of the two partial parabolas (3 _V 3 ₂₎ laterally to the principal axis (H) of the LeuchtstofE- m lamp (1) parallel or slightly angularly inclined by the surface of the fluorescent lamp (1) extend, and the two focal points (F _1, F ₂₎ of the two parabolas (S _1, 3 ₂ ) lie on or inside the fluorescent lamp (1), 2. Mirror reflector according to claim 1, characterized in that the two partial parabolas (3 ₁₅ 3 ₂ ) merge into one another directly or via a concavely curved intermediate piece. 3. mirror reflector according to claim 1 or 2, characterized in that it is spherical or pear-shaped design of the luminous element as a paraboloid of revolution of the partial parabola cross-sections is trained. 4. mirror reflector according to one of claims 1 to 3, characterized in that the focal length (F ₁ S ₁ ; F ₂ S ₂ ) of the partial parabolas (3 ₁₅ 3 ₂ ) and the distance between their axes (H ₁ , H ₂ ) from the The main axis (H) of the filament (X) corresponds approximately to half the size of the radius r of the filament cross section. 1 sheet of drawings