DE1846386U - LIGHT VISOR, FOR EXAMPLE FOR RADIATION MEASURING DEVICES, RADIATION DEVICES OD. DGL. - Google Patents

Description

B erS e or the,; ; Size Irradiate our or ours, Meaergeräte. 2der The invention relates to a light visor, as it is, for example for devices for measuring the intensity distribution of radiation active isotropes is required. B. Used for diagnostic purposes or to control the therapeutic use of radioactive isotopes in medicine and have a so-called measuring head as an essential component, consisting of a radiation detector (e.g. scintillation counter) which is housed in a shield with a diaphragm-shaped opening.

The diaphragm only allows radiation from a certain solid angle range to reach the detector. For practical measurements it is desirable to mark the central axis of this solid angle range, which usually coincides with the measuring head axis, which can be done by a light beam. In medical examinations, the point of impact of this light beam on the upper body of the body area of the patient the measurement location. For the evaluation of the measurement results nisse is important e6, also the distance of this NeSortea Tcm. Beach ** to know the detector. It is therefore known to use the measuring head with two laterally attached ten light sights & uaznrästeh, whose light bundles are in a defined Cut the ned distance in front of the radiation detector on the measuring head axis. One could relocate the measuring location marked in this way at a defined distance from the radiation detector, which is unchangeable in known devices, by simultaneously adjusting the inclinations of the light visors with respect to the axis of the measuring head. Apart from the effort that would have to be made for such an adjustment to achieve the required precision, such a solution with two light bundles inclined to the device axis would have the following disadvantage; If the true measuring distance changes during the measurement, which will usually be the case when scanning the curved body surface of a patient, the two light marking marks move apart. where the straight from The measuring point targeted by the radiation detector is no longer displayed at all will.

The disadvantages mentioned are avoided according to the invention by that apart from a known light pointer, the one with the axis of the ray incidence area coincident marking light beam generated, attached to the side of the measuring head Means are provided for projecting a distance scale onto the measuring table, and in such a way that the image of the distance scale in that through the axis of the former Light bundle and the direction of projection running obliquely to this axis Scale defined level runs. In this way, the marker light beam is next to one embossed, always lying on the measurement axis crosshairs or the like. Which the Mark the measuring point on the patient's body surface, the exact one in each case Distance of this measuring point from the radiation detector can be read without a Adjustment of the sighting device would be required.

The subject matter of the invention will be explained below using a schematic diagram. The attached figure shows, partly in section, the measuring head of a medical radiation measuring device shown how it zln. used for the diagnosis of the thyroid gland, consisting of the scintillation counter 1 and the shield 2 with an aperture (collimator hole) 3 for the entry of the to measuring radiation. In one. lateral attachment of the measuring head is found in a tube 4, a projection lamp 5, which has a Illuminated condenser lens 6 and through a diaphragm 7 a crosshair 8 which is imaged by the lens 9 to mark the measurement location on the patient's body surface, the line of intersection with the plane of representation being symbolized by the straight line 10. For this purpose, the beam path is guided through a bore 11 in the shielding 2 to a deflecting mirror 12 attached to the device axis 13 and from there onwards runs in a manner conforming to the device axis 13.

This type of arrangement has, compared to a direct Bringing the light localizer in the collimator hole has the advantage of that a negligibly small absorption of the radiation occurs through the deflecting mirror 12. In addition, otherwise the sensitive scintillation crystal (single crystal @) would very soon be destroyed by the heating of the lamp which has to be attached in front of the radiation detector 1.

The lamp 5 can at the same time serve as a light source for a second imaging system with the condenser lens 15 accommodated in the tube 14, by means of which a scale 16 is imaged on the body surface 10 by means of the lens 17. The scale 16 is oriented in the tube 14 in such a way that, in the representation selected for the figure, its image 16a runs in the plane of the paper. The image locations of various scale points are intended to be indicated by the individual rays 18. It can be seen from this that the scale values will shift with respect to the crosshair image 8a if the distance between the measuring plane 10 and the scintillation counter 1 is changed. In the plan view sketch in the lower left part of the figure, this shift is illustrated by the projection image in the two planes 10 and 10a. The scale 16 in the tube 14 is expediently inclined in such a way to the tube axis 19 that the distances between the locations of the sharpest image of the individual scale parts from the radiation detectors increase with increasing measures. Based on ideal imaging properties of the projection system In this way, by means of a straight scale, achieve a sharp image in the device axis 13. Corrections to the sharpness of the image can be made with the aid of an adjustable objective lens 17. Likewise, a sharp image in different planes can be obtained for the crosshair 8 by allowing the objective lens 9 to be presented. A high depth of field for the crosshair image can, however, also be achieved by two or more crosshairs 8 arranged one behind the other at appropriate intervals.

The non-linear distance scale 16 can be produced in a simple manner in that one is attached to the device axis 13 Scale tSy the light sighting arrangement 14-17 or with a camera photographed from the appropriate focal length.

Claims (4)

Protection claims: 1. Light sight, for example for a radiation measuring device, Irradiation device or the like., With one with the axis of the radiation incidence area coincident marking light beam, characterized in that laterally a scale projection device (5 and 15-19) is attached to the device, whose Rays (18) are directed onto the harking light beam. 2. Light sight according to claim 1, characterized in that the scale (16) with respect to the axis (19) of the imaging optics of the scale projection device is arranged inclined towards the marking light beam. 3. Light visor according to claim l, characterized in that on the optical axis of the imaging system of the harking light beam one behind the other several crosshairs (8) are attached. 4. Light visor according to claim l, characterized in that from the light source (5) of the projection device for the distance scale (16) the marking light beam by means of a mirror mounted on the axis of the beam incidence region (13) (12) is branched off. CD