DE4447325A1 - Camera for Kirlian photography - Google Patents

Abstract

The camera takes photographs of high voltage spark overs. It has a recording electrode (1) with a light permeable dielectric (4). High voltage spark overs (3) are exposed onto the film (5). The camera has conventional lenses, film spool compartments and reflex mirrors to allow easy processing. The camera components are located in one housing.

Description

The invention relates to a recording device for taking photos according to the Kirlian process (high-voltage electrophotography), in which the recording device, which includes the provision and transport of the film material 5 , and the high-voltage generation, which contains the pulse electronics, the control part and the high-voltage part, and the recording electrode 1 a housing are combined in such a way that recordings on commercially available film material are made possible, with appropriate additional equipment even in daylight.

In 1943, the Russian couple Semyon and Valentina Kirlian discovered a photographic process with the help of previously unseen energetic radiation of living matter could. This process was first patented in the Soviet Union in 1949 (No. 106401, class 57b). In In the following years, it became an interesting one for a few insiders in Europe Research area.

The method is based on the observation that high-voltage flashovers in ionized air create specific paths and shapes that correlate with the energetic radiation of living substances. These phenomena can be recorded on photosensitive materials. In practical application the receiving surface consists of a covered by a dielectric (insulating layer) High voltage electrode, while the object to be recorded, connected to the device ground, the other Electrode forms. The light-sensitive photo material is located between the recording electrode and Shooting object.

The energetic radiation pictures were systematized in many scientific areas and evaluated. This method was particularly important in human diagnostic applications. Extensive work by several authors enables use as a diagnostic as well as Therapy control procedures.

The biggest disadvantage of the previously common methods are the complex equipment and the Necessity of a dark room with own color or software laboratories.

The method according to the invention is based on the desire to make Kirlian photography broad To make users accessible. Therefore, a device was developed that works on a normal Desk workplace can be used. In order to avoid expensive laboratory equipment, the device is designed for the use of commercial KB films, the development in specialist laboratories in takes a few hours.

The method according to the invention is based on a newly developed Kirlian camera, which is a combination represents between a Kirliangerät (high voltage electrode) and a photo camera. The device was made for all common KB, roll and sheet films as slide or negative film, in color and SW designed.

Use in daylight is possible by using the appropriate accessories.  

A further possibility is the method presented in claim 2, in which the receiving electrode is made is made of a transparent, conductive material. This makes it possible to cross the beam path a deflecting mirror and an optical system consisting of one or more lenses on the film level to project using a conventional photo camera.

Some embodiments are shown in the drawings and are described in more detail below described.

Fig. 1 shows the basic principle of the receiving device,

Fig. 2 shows a recording device having transparent electrode 1 b,

Fig. 3 shows the recording device 9 with film slot 10,

Fig. 4 shows the recording device 9 with adapter side wall 18,

Fig. 5a shows the daylight attachment 19,

Fig. 5b shows the light-shielding slider 20,

Fig. 6 shows the principle of data display,

Fig. 7 shows the recording principle for the use of plan or instant film.

When high voltage is applied, as shown in FIG. 1, high-voltage flashovers 3 occur between the receiving electrode 1 and the receiving object 2 . These lead to an exposure of the light-sensitive film material 5 lying on the dielectric 4 . In the case of large bodies, the counterelectrode 6 can also be built up by the spatial potential; in the case of small objects, it is connected on the device side.

As shown in FIG. 3, the film insert 10 serves to provide and transport the film material 5 . It is fitted into the recording device 9 and completed by snapping into the side wall 11 .

A KB film is fixed out of the film can 12 via the deflection rollers 13 in the take-up reel 14 and inserted with the side wall 11 into the recording device 9 such that the film runs above the recording electrode 1 . The film is moved forward with the transport wheel 16 , wherein it snaps in at fixed image intervals. When the end of the film has been reached, it is rotated back into the film can 12 using the reset crank 17 and can be removed from the recording device 9 after opening the side wall 11 .

In the case of medium format films, the film is rolled up onto the take-up reel 14 and removed from the recording device 9 at the end of the recordings.

In FIG. 2, the recording electrode 1 b and the dielectric 4 b transparent executed. Electrically conductive glasses or foils, such as those used in shielding technology, are suitable as the material. The beam path of the high-voltage flashovers 3 can, as also shown in FIG. 4, be projected with a mirror 7 and a lens system 8 onto the film material 5 b of an external camera 15 , which is connected to the recording device 9 via the adapter side wall 18 .

The insertion of data can take place according to the principle shown in FIG. 6. Since conductive structures would trigger flashovers due to the high voltage in the recording electronics, a bundle of optical fibers is inserted into the electrode at the edge of the recording field. The other end of the optical waveguide is exposed to light individually or in groups. Appropriate coding can be used to insert both letters and numbers into the recording.

Since incident light exposes the film material 5 , the recording device 9 can only be operated in a dark room without additional devices. In order to be able to operate the recording device 9 even in daylight, the daylight attachment 19 is connected to the recording device 9 in a light-tight manner via the recording electrode 1 , as shown in FIG. 5a. To avoid electromagnetic interference radiation, the daylight attachment 19 is made of electrically shielding material. The recording objects 2 can be introduced through a light lock 20 and positioned on the recording electrode 1 .

Another daylight version, as shown in FIG. 5b, is achieved by using the light protection slide 21 , which prevents the incidence of extraneous light, whereas high voltage flashovers 3 appear on the film material 5 underneath.

With the device shown in FIG. 7, sheet films or instant film films can be used. The films are pushed from the magazine 22 onto the receiving electrode 1 and returned to the magazine 23 after the recording has ended. For instant film, it is possible to roll-squeeze after shooting.

Claims (12)

1. Device for generating recordings according to the Kirlian method, characterized in that both the recording electronics, consisting of pulse generation, high voltage part and recording electrode ( 1 ) and the parts required for the provision and further transport of the film material are in a common housing. 2. Device for generating recordings according to the Kirlian method, characterized in that the receiving plate consists of a translucent dielectric ( 4 b) and a conductive, transparent electrode ( 1 b), high-voltage flashovers ( 3 ) exposing an underlying film material ( 5 ) . 3. Apparatus according to claim 2, characterized in that the high voltage flashovers ( 3 ) by an arrangement of one or more lenses ( 8 ) are projected onto a film material ( 5 ). 4. Apparatus according to claim 2 and 3, characterized in that the beam path is deflected by a mirror ( 7 ). 5. Apparatus according to claim 2, 3 and 4, characterized in that a photo or film recording device ( 15 ) is coupled via an adapter ( 18 ). 6. The device according to claim 1, characterized in that a KB film (type 135) out of the film can ( 12 ) out over the receiving electrode ( 1 ) and rolled up in feed steps on a spool ( 14 ) and in the end after the recording the film can ( 12 ) is rewound. 7. The device according to claim 1, characterized in that a medium format film (type 120) out of the film roll over the receiving electrode ( 1 ) and rolled up in feed steps on a spool ( 14 ). 8. The device according to claim 1, characterized in that a sheet film from a magazine ( 22 ) is positioned over the receiving electrode ( 1 ) and is transported after the recording in the magazine ( 23 ). 9. The device according to claim 1, characterized in that an instant film from the magazine ( 22 ) is positioned on the receiving electrode ( 1 ) and developed after the recording by roller squeezing. 10. The device according to claim 1 or 2, characterized in that a daylight attachment ( 19 ) made of opaque electrically shielded material is placed on the device ( 9 ) and the object ( 2 ) is introduced via a light lock ( 20 ). 11. The device according to claim 1 or 2, characterized in that the recording object ( 2 ) is positioned on an opaque cover ( 21 ), which protects the film material ( 5 ) from external light, the high voltage flashovers ( 3 ) exposing the film material. 12. The apparatus according to claim 1 or 2, characterized in that encoded light figures are superimposed on the film material ( 5 ) via a bundle of optical fibers introduced into the receiving electrode ( 1 ).