WO1999003729A1

WO1999003729A1 - Inset light

Info

Publication number: WO1999003729A1
Application number: PCT/DE1998/001980
Authority: WO
Inventors: Reinhard Goerke
Original assignee: Siemens Aktiengesellschaft
Priority date: 1997-07-15
Filing date: 1998-07-15
Publication date: 1999-01-28

Abstract

In inset lights it is essential to have an inset lamp to ensure light radiation and at least a deflector prism ensuring the radiation in a predetermined angle. Said deflector prism (9, 40) consists of a coloured glass acting as protective glass for the inset light, the colour of the radiated light corresponding to a precise shade of the colour-phase diagram. A unidirectional, bi-directional and/or omnidirectional radiation can be obtained. Suitable coloration of the protective glass (9, 40) results in the colours required for traffic lights. Besides the preferential use as inset light with panoramic radiation for air fields, said inset lights can also be used on the roads in the road network.

Description

description

Underfloor fire

The invention relates to an underfloor light according to the preamble of claim 1. Such an underfloor light should be universally usable.

Underfloor lights are proposed in a wide variety of designs in the prior art. For example, from WO-A-86/05157 a unit for airfield lighting is known in which the optical system has a lens with a prismatic character with which the radiation from a reflector lamp is emitted to the outside. A recess is provided in the center of the optical system for prism formation, a protective cap being arranged over the entire arrangement. Furthermore, from EP-B-0 544 799 a marking light with at least one sawtooth formation on the top of the optical system is known, the inclined surface sections of which have angles of inclination such that the incident light is reflected back by total reflection on the respective inclined surface sections and is as large as possible Refraction is emitted in the relevant adjacent, sloping surface section. With both devices, light can be emitted in two opposite main emission directions.

In addition, the use of so-called belt lenses in lighting devices has already been proposed. Such belt lenses, however, have a housing that protrudes relatively high from the ground and therefore cannot be used as an underfloor fire for the desired purpose. Furthermore, so-called axial beam distributors have been proposed in cooperation with prism ring end glasses or mirrored cone prism glasses with relatively large cross-sectional differences. The known devices frequently do not yet meet the requirements for the specifications of the light, in particular a symmetrical omnidirectional radiation. In addition, the facilities that have satisfactory specifications are still too large. They are therefore less suitable for movement areas such as aprons, airport runways and taxiways.

For this purpose, the older, unpublished patent applications 197 30 182.7 and 197 30 183.5 propose systems which are designed with an optical reflector system and a deflecting prism as a cover glass as all-round underfloor fire.

Starting from the above prior art, it is the object of the invention to propose underfloor lights which meet the specified specifications for the light from a lamp.

The object is achieved in an underfloor fire of the generic type by the entirety of the features of claim 1. Further developments are preferably characterized in the subclaims.

In the invention, a final prism is a first

"Colored" stepped lens is used, which meets the requirements for mechanical strength when rolling over, as well as all thermal loads caused by the light source, but also the color location according to the required specifications of the standard color table according to DIN 5033, especially for the specifications "ICAO Annex 14 (Colors for Aeronautical Ground Lights) "and" MIL-C-25050 A-Aviation Color Limits "with the required light or light intensity distribution.

In the invention, the “light radiation” of the light source is not used directly, but via a combination mirror reflected in ring zones depending on the angle and in such a way that the reflected beams are refractively deflected by the prism rings of the stepped lens, so that a signal color that meets specifications is generated in the main beam region. The different optical path length of the light rays through the prism rings has - in contrast to an optically transparent glass in the prior art - a considerable but calculable influence on the transmission. In principle, each light beam has its own transmission and thus its own color location. In contrast, the filter according to the earlier applications is a plane-parallel plate with essentially the same transmission factor τ for the same light beam directions.

The invention is suitable for unidirectional, bidirectional and / or omnidirectional underfloor lighting. In addition to the preferred application for airfield lighting, it can also be used in the general road network. The preferred application is realized as an all-round underfloor fire for airfield lighting.

Further details and advantages of the invention result from the following description of the figures of exemplary embodiments with reference to the drawing. Show it

FIG. 1 shows a sectional view of the new arrangement of an omnidirectional underfloor light,

2 and 3 the geometry of the closing prism with rotationally symmetrical profiling on the underside. FIG. 4 a section from the color table for the specification "blue" and

Figure 5 shows an alternative to Figure 1 arrangement of an underfloor light.

FIG. 1 shows an arrangement referred to as an underfloor fire consisting of a housing with a new optical device arranged therein. Specifically, 10 marks Upper part for arrangement in the floor, to which a housing part 11 with a holder 12 and a seal 13 for a so-called cover glass for all-round radiation of light of a predetermined color are attached. There is also a holder 14 for the optical device. The housing with the associated devices is designed to be vibration-compensated.

The optical device consists of a combination of the known lamp with mirrors for suitable reflection and a specifically designed deflection prism as a cover glass. Specifically, in Figure 1 5 mean a lamp whose axial filament is arranged below the point of symmetry of a spherical half mirror 6. A revolving barrel mirror 7 can connect to the open side of the spherical half mirror 6, for example. Both mirrors can be made from one molded part.

Above it is a closing glass 9 designed as a prism. The prism 9 is round-symmetrical with profiles 91 to 94 on the underside and a circumferential flank 96 on the top and is described in detail with reference to FIGS. 2 and 3.

From the combined representation of the top view and side view of the prismatic glass according to FIGS. 2 and 3 it can be seen that the profiles 91 to

Form 93 prism rings. The profiles are 91 to

94 each offset vertically from the outside inwards and enclose an angle so that the circumferential flanks are parallel to each other. The angle of inclination of the oblique circumferential flank 96 on the upper side of the prism 9 is also essential, the central region 98 being cut off here. The angle β of the flank 96 is, for example, 20 ° and is generally chosen between 5 and 20 ° depending on the desired radiation angle α. The closing prism 9 can be designed such that it can be driven over by suitable measures.

The prism 9 consists of colored gas, so that it emits the desired signal color directly - without using filters. With a suitable coloring, a red, a yellow, a blue or even a green radiation is possible.

A suitable manufacturing process can ensure that the cover glass with color specification is adequately mechanically stable and is insensitive to rolling over or the like even in the case of temperature fluctuations.

In Figure 2, two light rays are drawn, which run parallel through the prism rings of the colored prism 9. In this case, both light beams have a different optical path length, which must be taken into account when determining the color location. This is shown in the color table according to FIG. 4. It follows that each of the parallel light beams has its own transmission ti and τ ₂ and thus has its own color locus.

1 shows, by way of example, selected beams 1 to 4 with corresponding reflections or refractions: 1 shows the direct beam which is reflected by the coil of the light source 5 on the barrel mirror 7 and at a perpendicular angle to the outer profile flank 91 of the prism glass 9 falls. It reaches the opposite side without refraction and is broken from there and emitted at a flat angle as beam 1 ". The beam lr emitted by the helix in the other direction is reflected at the spherical mirror 6 and is then with the beam 1 or 1 ' congruent or slightly offset. It is essentially the same with the beam 2 or 2r, which strikes the end glass 9 in the profile edge 92 and after refraction is emitted as beam 2 'parallel to the beam 1 ". Beam 3 or 3' follows Corresponding reflection on the next profile edge 93 and after the refraction as beam 3 "is also emitted parallel to the beams 1" and 2 ".

It is quite the same with the beam 4 or 4r, which is deflected to the other side after reflection at the barrel mirror 7 as beam 4 'and on the other side of the rotationally symmetrical edge 91 of the end glass passes through the prism 9 and when the prism emerges in air broken and emerges at a flat angle as a 4 "jet.

The rotationally symmetrical profiling of the prism glass shown in FIG. 2 thus results in the desired radiation at a flat angle, for example 6 °.

In FIG. 1, a so-called barrel mirror with circumferential reflector ring zones with changing angles was used as a rotationally symmetrical circumferential reflector, since the light from the lamp filament can be reflected in a funnel shape. The ring zones each reflect the filament center of the helix in a common main beam direction, which is directed towards the entry surface of the prism end glass.

Instead of the barrel mirror, other asymmetrically conical, elliptical or other spherical mirrors can also be used. It is important that the rotating mirror has a rotationally symmetrical course created by affine distortion.

FIG. 5 shows an arrangement referred to as an underfloor fire consisting of a housing with a new optical device arranged therein. Specifically, 10 marks Upper part for insertion in the floor of an airfield, to which a housing part 11 with a socket 12 and a seal 13 for a so-called cover glass are attached downward. Furthermore, a known holder for the optical device is available. The housing with the associated devices is in turn designed to be vibration-compensated.

The optical device consists in particular in the novel combination of individual rotationally symmetrically radiating deflection elements. In FIG. 5, a reflector lamp is denoted by 50, in which a parabolic reflector 60 is provided in a known manner, so that the light radiation emerges as a parallel beam. For example, rays 1 and 2 and rays 1 ', V' and 2, 2 '' after the first and second refraction are shown.

An ellipsoid reflector is also possible to ensure a specific radiation field.

A radiation splitter 30 is arranged in front of the reflector 6. A colored cover glass 40 for the complete underfloor fire for rotationally symmetrical radiation is in turn attached above the radiation divider 30.

It can be seen from FIG. 5 that the initially parallel beams 1 and 2 are separated in the beam splitter 30 and - depending on which of the zigzag-shaped profile edges of the beam splitter 3 the beams hit - are deflected in different directions as beams 1 'and 2'. The cover glass 40 is formed in FIG. 1 at least with a dome-shaped area 41. The radiation incident in the cover glass 40 is deflected by the outer circumferential inclined surface 46, so that, for example, the beam 1 'leaves the arrangement at a flat angle α as the beam 1 ".

The geometrical coordination of the beam splitter 3 with the rotationally symmetrical profiles 31 to 33 attached to the underside is essential in the arrangement according to FIG and the cover glass 40 with the formation of the central dome-shaped region 41 and the outer flank 46. In particular, the dome-shaped region 41 of the prism 9 can be designed on the underside in such a way that individual incisions 341 to 344 are provided in a rotationally symmetrical manner. This will form a prism ring with the same strength throughout, which serves for stability.

It can be seen that the new arrangements meet the requirements for signal-color-oriented radiation in the way that was previously only possible with filters.

Claims

claims

1. Underfloor fire for roadways, with a recessed lamp as a radiation generator for light and at least one deflecting prism for radiation at a predetermined angle, characterized in that the deflecting prism (9, 40) consists of colored glass as a cover glass, with a for the emitted light defined color location according to the required specifications of the standard color chart.

2. Underfloor fire according to claim 1, so that the end glass (9, 40) is designed for unidirectional radiation.

3. Underfloor fire according to claim 1, so that the end glass (9, 40) is designed for a bidirectional radiation.

4. Underfloor fire according to claim 1, d a d u r c h g e k e n n z e i c h n e t that the cover glass (9, 40) for an omnidirectional, i.e. omnidirectional, radiation is formed.

5. Underfloor fire according to claim 1, g e k e n n z e i c h n e t by a red radiation.

6. Underfloor fire according to claim 1, g e k e n n z e i c h n e t by a yellow radiation.

7. Underfloor fire according to claim 1, g e k e n n z e i c h n e t by a blue radiation.

8. Underfloor fire according to claim 1, characterized by a green radiation.

9. Underfloor fire according to one of the preceding claims, g e k e n n z e i c h n e t by an application for lanes of airfields or the like ..

10. Underfloor fire according to one of the preceding claims, g e k e n n z e i c h n e t by an application for lanes in the road network.

11. Underfloor fire according to one of the preceding claims, g e k e n n z e i c h n e t by a round symmetrical

Education.

12. Underfloor fire according to claim 11, characterized in that the lamp (5) in the vicinity of the point of symmetry of a reflector arrangement from a hemispherical mirror (6), on the open side of which a circumferential mirror (7) of predetermined geometry connects, and that Closing prism (9) is profiled on the underside in a rotationally symmetrical manner such that the light radiation emerging from the mirror arrangement (6, 7) is emitted symmetrically on all sides at a flat angle (α).

13. Underfloor fire according to claim 12, so that the all-round mirror (7) has a rotationally symmetrical barrel-shaped geometry.

14. Underfloor fire according to claim 12, so that the circular mirror (7) has an asymmetrical conical geometry.

15. Underfloor fire according to claim 12, that the circular mirror (7) is segmented and has an elliptical and / or spherical geometry.

16. Underfloor fire according to one of claims 13 to 15, characterized in that the all-round mirror (7) has a rotationally symmetrical curve shape generated by affine distortion.

17. Underfloor fire according to claim 12, d a d u r c h g e - k e n n z e i c h n e t that the spherical and the all-round mirror form a unit.

18. Underfloor fire according to claim 12, so that at least one color filter (8) for selective color specification is located in front of the reflector arrangement (6, 7).

19. Underfloor fire according to claim 12, so that the deflecting prism (9) has an all-round serrated profile on the underside

(91, 92, 93), in which there are symmetrical to the axis of rotation each inclined areas against the horizontal, which differ in their altitude.

20. Underfloor fire according to claim 12, that the deflecting prism (9) acts as a cover glass for the overall arrangement.

21. Underfloor fire according to claim 20, d a d u r c h g e - k e n n z e i c h n e t that the cover glass (9) at its

Top has a circumferential flank (96) on all sides of the same angle (ß).

22. Underfloor fire according to claim 21, d a d u r c h g e - k e n n z e i c h n e t that the angle (β) of the circumferential flank is between 5 and 20 °, preferably 20 °.

23. Underfloor fire according to one of the preceding claims, characterized in that the arrangement of lamp (5), mirror combination (6, 7), final Prismatic glass (9) is held in a housing (10, 11) in a vibration-compensated manner.

24. Underfloor fire according to claim 12, d a d u r c h g e - k e n n z e i c h n e t that the radiation angle (α) of

Light radiation is 0 to 30 °.

25. Underfloor light according to claim 11, d a d u r c h g e k e n n z e i c h n e t that the lamp is a reflector lamp (6) between the reflector lamp (6) and deflecting prism (40) a radiation splitter (3) is present, which deflects the light radiation emerging from the reflector lamp (6) for rotationally symmetrical radiation.

26. All-round underfloor fire according to claim 25, d a d u r c h g e k e n n z e i c h n e t that the radiation splitter consists of a disc-shaped prism (3) with a flat top (36), the underside of which is provided with rotationally symmetrical circumferential profiles (31, 32, 33).

27. All-round underfloor fire according to claim 25, d a d u r c h g e k e n n z e i c h n e t that the deflecting prism (4) to the top of the beam splitter (3) has a dome-like recess (45).

28. All-round underfloor fire according to claim 25, d a d u r c h g e k e n n z e i c h n e t that on the dome-like recess there is an all-round serrated profile (341, 342, 343) in which there are areas of the same inclination symmetrical to the axis of rotation, which differ in their altitude.

29. All-round underfloor fire according to claim 25, characterized in that the Deflection prism has on its top a circumferential flank (46, 346) of the same angle (ß).

30. Omnidirectional underfloor fire according to claim 25, so that the angle (β) of the circumferential flank is between 5 and 20 °, preferably close to «20 °.