DE3803763A1 - Optical irradition device for biological matter - Google Patents

Abstract

An optical irradiation device for biological matter having a light source, in which according to the invention a preferably transparent single crystal or a crystal arrangement with macro-crystalline crystal structure is provided between the light source and the biological matter to be irradiated, and the crystal main axis or axes of the crystal or crystals is or are arranged oriented in the direction of irradiation. <IMAGE>

Description

The invention relates to an optical radiation device for biological matter with a light source which e.g. B. as a light bulb, halogen light, neon light, quartz, Mercury or xenon lamp can be present.

When using such known devices for white or colored light, however, is the radiation device not in phase, d. H. Wave trough and waves The front of the individual light rays do not lie towards each other in phase.

For biological matter, especially for that However, light acupuncture is in-phase light much more effective. For this reason too laser beams have proven particularly useful for acupuncture.

On the one hand, laser devices are very apparatus-wise complex and chromatic or in relation to various Colors inflexible and weak on the other hand dosage difficult to adjust. Above all, they are not usable in terms of area.

The object of the invention is therefore an optical To provide radiation device of the known type, with the due to the phase-homogenizing effect of crystals, especially with natural mineral crystals different color effects, in a simple way Advantages of laser light can be achieved and which furthermore improvements for the treatment biological material e.g. B. also on the chakra or Man's acupuncture points.

Accordingly, the invention consists in the features of Claim 1.

So although single crystals can be used primarily, lets there is also a flat, in-phase radiation achieve by arranging a variety of inputs Crystals are used side by side, their optical Main axes are oriented in the direction of radiation. The crystals act both as Color filter (for the color puncture) as well as a means of Harmonization of phase equality.

By lens shaping the crystals according to the characteristics of claims 2 to 4 can be at least one Surface of the crystal or a crystal structure be concave, convex or flat. Also at a whole plate from a variety of crystals are different light distribution according to the invention effects possible, with the feature of claim 5 At least light scatter on the transition surfaces can be reduced.  

A special embodiment of the invention consists in the combination of features according to claim 6, in which the Advantages of fiber optic transmission at one light head to be used. It can also a synchronous multiple acupuncture at the same time different colors with in-phase light take place, namely when from a light source several independent fiber optic bundles with different colored light heads go out.

According to the invention, this arrangement is even of Advantage if a laser light source is used as the light source is used because it was originally in phase Laser light through the reflections within the glass fiber loses its phase equality greatly. in the A crystal light head according to the invention then takes place Readjustment of phase equality shortly before Irradiation of the biological material.

With the inventive features of claims 7 to 11 can the use of the device on the one hand in lighting efficiency improved and on the other hand different Requirements are adjusted.

The invention is in exemplary embodiments below described in more detail. Show it

Fig. 1 and 2 are schematic longitudinal sections through flat laid on biological material crystals or crystal structures,

FIGS. 3a to 3c show a schematic representation of a modern fiction, combined with fiber optic light guide, and

Fig. 5 and 5 variations of the light head embodiment in Fig. 3c.

A crystal 3 is arranged on or just above a biological material 4 , which can consist of a single crystal or a large number of individual crystals arranged next to one another and can be either planar or convex (as shown in FIG. 1) or also concave. The crystals 3 or the single crystal 3 are arranged such that their main optical axis 5 are in the direction of irradiation from the light source 2 to the biological material.

Referring to FIG. 3, the light source 2 in a housing 15, possibly with a concave mirror 16 via an optical lens system 14 to a fiber-optic light guide 7 in the form of a bundle of optical fibers 8 (or even a single optical fiber) is coupled.

At the freely manageable end of the bundle of glass fibers 8 there is a light head 1 made from a single crystal 3 (also from a bundle of parallel crystals), on the back 9 of which the glass fibers 8 are attached in such a way that the light enters the crystal without loss of transition and reflection whose outer side surface 10 can be provided with a reflection layer 11 .

The individual glass fibers 8 can be distributed over the entire back 9 of the crystal for better light distribution, and larger distances from one another can also be given.

The convexly designed light exit side of the crystal 3 according to FIG. 3 c can also have an area 13 with an intensely curved surface in order to provide different focal distances to the biological material 4 .

According to FIG. 4, the light exit side 17 may be planar and, according to FIG. 5, may also be convex, a light-transmitting liquid 6 and / or an aperture, for. B. can be provided in the form of a pinhole 12 .

All of the described inventive features are also as Combination with each other revealed.

Claims (11)

1. Optical irradiation device for biological matter with a light source, characterized in that a preferably transparent single crystal ( 3 ) or a crystal arrangement with a macro-crystalline crystal structure is provided between the light source ( 2 ) and the biological matter ( 4 ) to be irradiated, and that The main crystal axis (s) ( 5 ) of the crystal or crystals is or are oriented in the irradiation direction. 2. Optical irradiation device, characterized in that at least one surface of the crystal ( 3 ) or the crystal structure arranged transversely to the main crystal axis ( 5 ) is concave ( FIGS. 2 and 5). 3. Optical irradiation device, characterized in that at least one surface of the crystal ( 3 ) or the crystal structure arranged transversely to the main crystal axis ( 5 ) is convex ( FIGS. 1 and 3c). 4. Optical irradiation device, characterized in that at least one surface of the crystal ( 3 ) or the crystal structure, which is arranged transversely to the main crystal axis ( 5 ), is formed planar (FIGS . 2 and 4). 5. Optical radiation device according to one of the preceding claims, characterized in that between the biological matter ( 4 ) facing side of the crystal ( 3 ) or the crystal structure and the biological matter ( 4 ) a light-transmitting liquid ( 6 ) z. B. a light immersion oil is provided ( Fig. 4 and 5). 6. Optical radiation device for biological matter with a light source according to claim 1 and a light-transmitting glass fiber light guide device ( 7, 8 ), characterized in that the free ends of the light guide glass fibers ( 8 ) on the back of the crystal ( 3 ) or the crystal structure in the light are arranged in this way. 7. Optical irradiation device according to claim 6, characterized in that the light guide glass fibers ( 8 ) directly on the back ( 9 ) of the crystal ( 3 ) or the individual crystals of the crystal structure are firmly attached ( Fig. 3c). 8. Optical irradiation device according to claim 6 and 7, characterized in that the individual light guide glass fibers ( 8 ) of a glass fiber bundle ( 7 ) over the surface of the back ( 9 ) of the crystal ( 3 ) are distributed. 9. Optical radiation device according to one of the preceding claims, characterized in that the outer sides ( 10 ) of the crystal ( 3 ) or the crystal structure are provided with a reflection layer ( 11 ). 10. Optical irradiation device according to one of the preceding claims, characterized in that on the biological matter ( 4 ) facing side of the crystal ( 3 ) or the crystal structure, a pinhole ( 12 ) is provided. 11. Optical irradiation device according to claim 3 and claims 6 to 10, characterized in that the convex surface of a single crystal ( 3 ) in a narrowed area ( 13 ) around the main crystal axis ( 5 ) has an increased convex design.