DE19938926A1 - Optical magnifying system has a lightweight structure for a lamp with a number of high power ceramic LEDs with a long life which do not need replacement - Google Patents

Abstract

The optical magnifying system has a holder (2) for the magnifying components, and a lamp (4) linked to a power supply. The lamp (4) has high power light emitting diodes (LED) and especially high power ceramic LEDs (6). A number of LEDs are distributed around the lamp carrier (7).

Description

The invention relates to an enlarging optical system, in particular an egg ne magnifying optical vision aid, like a magnifying glass, a reading glass, a lu pen glasses, telescope glasses or the like.

Such visual aids usually have a holder to enlarge the ßerenden optical elements, such as reading or magnifying glasses hold. In addition, it is already known on the holder for the optical Element also provide a lighting element to a surface that to be viewed by the system to illuminate or illuminate better.

It is known in the prior art to use conventional glow as light sources lamps or halogen lamps or the like. All of these light sources have the disadvantage that they are relatively large and relatively large Radiate heat, on the other hand only a limited life ha and therefore have to be replaced from time to time. Moreover require the light sources used on magnifying optical vision aids len relatively much energy, which disadvantageously leads to batteries need to be replaced relatively often.  

The invention is based, an enlarging optical Sy the task stem further with the features of the preamble of claim 1 to form that a change in the light source assuming normal Le Life of such an optical system can be omitted and the Sy systems can be manufactured in a more compact design.

This object is achieved in that the lighting element as a min at least a high-performance LED, especially a high-performance ceramic LED is trained.

Through the use of high-performance LEDs, especially Hochlei Stungskeramik-LEDs in connection with optical systems becomes one Achieved a number of advantages. First, the small size of the High-performance LED, especially high-performance ceramic LED Installation in relatively filigree brackets and housings too. The housing can leaner and lighter and are therefore over hold it effortlessly in your hand or head for a long period of time wear.

At low weight, the high-performance LEDs, in particular High-performance ceramic LEDs also have a high luminous efficiency and a almost unlimited lifespan of approx. 100,000 hours with continuous use urged so that visually impaired people who are the main user group of such represent magnifying visual aids, a relatively difficult lamp change is spared.  

Due to the low power consumption, battery changes are also rare conducive. Even with changing batteries, older visually impaired Big problems for people, which then disappear.

Rarely changing the battery also leads to a lower environmental impact and a significant cost saving for the user.

Due to the compact design of the high performance LEDs, in particular High-performance ceramic LEDs can also be used advantageously Plurality of high-performance LEDs, especially high-performance ceramic Arrange LEDs distributed on a lighting support, so that the problems me a point light source, in particular a glare or Gloss effect on smooth paper.

It is also possible to use the plurality of high-power LEDs, in particular High-performance ceramic LEDs with different beam angles arrange, creating an even better "broadband" lighting of a surface che becomes possible. Different arrangements of several Hochlei power LEDs, in particular high-performance ceramic LEDs, are possible at for example circular on a lighting support or invisible under the frame of a magnifying glass.

The arrangement of a plurality of high-performance LEDs, especially high-performance ceramic LEDs on a lighting carrier that can be swiveled or rotated in relation to the optical system, is trained.  

Will one or more ceramic LED (s) on a lighting bracket ordered, which at its the high-performance LED, in particular Hochlei end facing away from the ceramic ceramic LED in the manner of a screw or plug Version of a conventional light bulb is formed, and is in the Lighting bracket also an electronic voltage adjustment scarf device provided, so conventional systems can easily with a high-performance LED, in particular high-performance ceramic LED Lighting can be retrofitted.

The invention is based on exemplary embodiments in the drawings guren explained in more detail. These show:

Figure 1 is a side view of a grip sleeve for magnifying glasses or reading glasses with a lighting support with four Hochlei stungs-LEDs, in particular high-performance ceramic LEDs.

FIG. 2 shows a front view of the lighting element according to FIG. 1

Fig. 3 is a high-power LED, in particular Hochleistungske Ramik LED array pot in a closed magnifiers;

Fig. 4 is a plan view of the high power LED, in particular high-performance ceramic LED array in the magnifying glass pot;

Figure 5 is a high-power LED, in particular Hochleistungske Ramik LED lighting assembly in the base of a reading glass.

Fig. 6 is a high-power LED, in particular Hochleistungske Ramik LED array on a standard bags illuminated magnifier;

Fig. 7 is arranged on a lighting carrier Hochlei stungs-LED, in particular high-performance ceramic LED for replacing an existing light bulb and

Fig. 8 three high-power LEDs, in particular high-performance ceramic LED arrangements for use in front of Keppler or Galileo systems, such as those used for telescope glasses.

The magnifying optical visual aid 1 has a holder 2 which carries the magnifying optical element 3 . In addition, a lighting element 4 is provided, which is connected to an energy source S and fastened to the holder 2 . The lighting element 4 is a high performance LED, in particular high performance ceramic LED 6 . The connection to the bracket 2 is made via a lighting bracket 7 , which in the embodiment shown in FIG. 1 is attached to the front 8 of the grip sleeve 9 egg nes reading glass.

In the exemplary embodiment shown, the lighting carrier 7 carries four high-power LEDs, in particular high-performance ceramic LEDs 6 , which are arranged with different beam angles on a curved surface of the lighting carrier 7 .

In the embodiments shown in FIGS. 3 and 4, the number of high-power LEDs, in particular high-performance ceramic LEDs 6, is arranged under the frame 10 of a magnifying glass 11 , in a circular arrangement which can be seen in FIG. 4. In the embodiment shown in FIG. 4, the lighting carrier 7 also serves as a holder for the magnifying glass.

In FIG. 5, the high-power LEDs, arranged in particular Hochleistungskera mik-LEDs 6 on each other approximately at right angles aligned support surfaces 15, wherein a support surface 15 is the underside of a Linsenfas solution and the other support surface 15 of the inner side of a stand of a reading glass.

In the embodiment shown in Fig. 6, the ceramic LED 6 is arranged on the inclined front 20 of a handle 21 of a Taschenleuchtlu pe. A hinge-like connection 22 between the magnifying glass carrier 23 and the handle 21 allows a relative adjustment between the main optical axis of the magnifying glass and the beam angle of the Kera mic LED 6th

Fig. 7 shows that a high-performance LED, in particular high-performance ceramic LED 6 can be exchanged for an incandescent lamp of a conventional illuminated magnifying glass. In the embodiment shown in Fig. 1 it can still be seen that the lighting support 7 at its end of the high-performance LED, in particular high-performance ceramic LED 6 end 25 is formed out in the manner of a screw socket of a conventional incandescent lamp and can therefore be screwed in instead of a conventional incandescent lamp can.

A voltage adaptation circuit 26 can also be arranged in the lighting support 7 if the operating voltage of the high-power LEDs, in particular special high-performance ceramic LEDs 6, differs from that of the incandescent lamp to be replaced.

In Fig. 8a-8c it is shown how a ring-shaped lighting support 7 are easily attached magnifying optical systems 30 , where the voltage supply to the high-performance LEDs, in particular high-performance ceramic LEDs 6 via contacts and mating contacts on the lighting support 7 and on the optical System 30 can be done.

REFERENCES

1

optical vision aid

2nd

bracket

3rd

optical element

4th

Lighting element

5

Energy source

6

High-performance LED, especially high-performance ceramic LED

7

Lighting bracket

8th

Front

9

Grip sleeve

10th

frame

11

Magnifying glass

15

Carrier surface

20th

front

21

Grab handle

22

hinge-like connection

23

Magnifying glasses

25th

averted end

26

Voltage adjustment circuit

30th

optical system

Claims (16)

1. Magnifying optical system, in particular magnifying optical visual aid, such as magnifying glass, reading glass, magnifying glasses, telescope glasses and the like., With a holder for the magnifying optical elements and a lighting element which is connected to an energy source and arranged on the holder, characterized in that that the lighting element ( 4 ) is designed as a high-performance LED, in particular high-performance ceramic LED ( 6 ). 2. System according to claim 1, characterized in that a plurality of high-performance LEDs, in particular Hochlei stungskeramik-LEDs ( 6 ) is arranged distributed on a lighting support ( 7 ). 3. System according to claim 1 or 2, characterized in that the plurality of high-power LEDs, in particular high-performance ceramic LEDs ( 6 ) arranged with different beam angles. 4. System according to one of claims 2 or 3, characterized in that the plurality of high-performance LEDs, in particular high-performance ceramic LEDs ( 6 ) are arranged distributed around the entrance lens of a telescope system. 5. System according to any one of the preceding claims, characterized in that a plurality of high-power LEDs, in particular Hochlei stungskeramik-LEDs ( 6 ) are arranged under the frame ( 10 ) of a magnifying glass ( 11 ). 6. System according to any one of the preceding claims, characterized in that the high-power LEDs, in particular high-performance ceramic LEDs ( 6 ) are arranged in a circle distributed on a lighting support ( 7 ). 7. System according to any one of the preceding claims, characterized in that the beam angle of the high-performance LEDs, in particular Hochlei stungskeramik-LEDs ( 6 ) is arranged obliquely to the plane of extent of a magnifying glass. 8. System according to any one of the preceding claims, characterized in that a plurality of high-performance LEDs, in particular Hochlei stungskeramik-LEDs ( 6 ) on an approximately wedge-shaped lighting support ( 7 ) are arranged. 9. System according to any one of the preceding claims, characterized in that the lighting support ( 7 ) is arranged pivotably and / or rotatably towards its beam angle based on the optical system ( 30 ). 10. System according to one of the preceding claims, characterized in that the lighting support ( 7 ) is arranged pivotably with respect to the main optical axis of the optical system ( 30 ). 11. System according to any one of the preceding claims, characterized in that a plurality of high-performance LEDs, in particular high-performance ceramic LEDs ( 6 ) are arranged on surfaces approximately at right angles to one another ( 15 ). 12. System according to any one of the preceding claims, characterized in that the lighting support ( 7 ) is interchangeable. 13. System according to any one of the preceding claims, characterized in that the high-performance LEDs, in particular high-performance ceramic LEDs ( 6 ) are arranged on a conventional spectacle frame or are integrated therein. 14. System according to any one of the preceding claims, characterized in that one or more high-performance LEDs, in particular high-performance ceramic LEDs ( 6 ) are arranged on a lighting support ( 7 ), which on the ceramic LED (s) (s) ( 6 ) opposite end ( 25 ) is designed in the manner of a screw or jack of a conventional incandescent lamp. 15. System according to claim 14, characterized in that the lighting support ( 7 ) has an electronic voltage adjustment circuit ( 26 ). 16. System according to any one of the preceding claims, characterized in that the lighting support ( 7 ) is ring-shaped and can be plugged onto a tube of an optical system ( 30 ) and has electrical contact elements which interact with the energy source counter contacts on the tube.