SU1725835A1 - Device for postioning an x-ray unit stand - Google Patents

Abstract

The invention relates to medical technology, more specifically to devices for monitoring the position of an X-ray emitter. The purpose of the invention is to eliminate the effect of radiation on the operator and to improve the accuracy of the adjustment. This is achieved by the fact that in the device for adjusting the X-ray tripod, which contains a point source of radiation, mounted on the vertical carriage of the tripod column, and an imaging device with two opaque filaments, located at a relative rotation of 45 °. a point source is used, which regenerates light in the visible range, and the imaging device contains a optical sight system including a lens, a rectangular prism located near the lens, and an eyepiece, one of which is crossed on the input face of the prism, and the second is located near the front focal plane the ocular, in addition, the target optical system is fixed on a horizontal carriage equipped with a mechanism for its movement in the longitudinal and transverse directions, equipped with a mic with meter screws and level adjustment mechanism. 1 hp ff, 3 ill. (Ls

Description

The invention relates to medical technology, more specifically to devices for monitoring the position of an x-ray emitter, and may be intended to control the verticality of an x-ray tripod column on which the x-ray emitter carriage is mounted.

A device for adjusting an x-ray tripod is known, which contains a sighting tube, at the end of which a slit diaphragm and a scintillation crystal are fixed, optically conjugated with a photomultiplier tube connected to an amplifier and an indicator.

The verticality of the x-ray tripod column is determined by electron-optical intersection of the position of the focal spot of the x-ray tube at different positions of the radiator in height.

The known device provides high accuracy of measurements, but it takes a long time (about an hour), which is a drawback of the known device.

It is also known a device for adjusting the X-ray tripod, which contains a light projector, including a glow lamp, a mirror and a plane-parallel transparent plexiglass plate with a switch |

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black crucifix. The device is located in the volumetric diaphragm of the X-ray emitter.

The verticality of the x-ray tripod column can be determined by observing the displacement of the shadow overlap on the screen, which is located on the deck of the horizontal x-ray table, as the x-ray emitter moves along the vertical column.

A disadvantage of the known device is its low accuracy, due to the large geometric unsharpness of the shadow image.

Closest to the invention is an X-ray tripod adjustment device comprising a parallelepiped-shaped body, in one of which walls there is a notch through which the bottom of the device is observed, covered with a fluorescent screen. On the screen and on the protruding parts of the bottom of the device there is a thin crosshair. Copper wires with a diameter of 0.3 mm are fixed diagonally on the device lid. The centers of the lower and upper crosshairs are on the same axis.

The device is mounted on a deck of a horizontal x-ray table under an x-ray emitter, which is brought to a horizontal position and moved along the column to a maximum height. By means of a light centralizer, the optimum width of the radiation beam is established. The room is darkened and the X-ray tube is switched on in the x-ray mode. Through the side opening of the device, the operator observes on the fluorescent screen two cross. By moving the device in the plane of the X-ray deck, the operator achieves the alignment of the centers of the crosshairs. After that, the operator moves the x-ray emitter to the lowest position and, based on the displacement of the centers of the crosshairs, estimates the deviation of the tripod column from the vertical axis.

The main disadvantage of the prior art device, taken as a prototype, is the large radiation load on the operator, which is caused by the need to work in the immediate vicinity of the included X-ray tube. In addition, the luminance of the fluorescent screen is insufficient for the image to be imaged by the cone apparatus of the eye, which naturally reduces the accuracy of the adjustment,

The purpose of the invention is to completely eliminate the effects of radiation on

operator and increase the accuracy of the adjustment.

The goal is achieved by the fact that in the device for adjusting the X-ray tripod, which contains an emitter mounted on the vertical carriage of the tripod column, and an imaging device with two opaque cross-hairs, aligned coaxially with a 45-degree turn, uses a point source of visible light as the emitter. imaging device contains a lens, a rectangular prism located

5 near the lens and the ocular p, with one of the intersections for designating the geometric center of the surfaces on the input face of the prism, and the second located near the front focal plane

0, the eyepiece, in addition, the imaging device is located on a horizontal carriage equipped with a longitudinal and transverse movement mechanism equipped with

5 micrometer screws and level adjustment mechanism.

FIG. 1 given the device, side view; in fig. 2 - the same, top view; in fig. 3 - image observed through the device's eye:

The device for adjusting the X-ray tripod contains a point light source 1, for example, an incandescent lamp mounted in the cartridge 2 on the X-ray emitter 3 (Fig. 1 a). The emitter 3 is mounted on the carriage 4 columns 5 x-ray tripod. The second part of the device is an imaging device. It contains the sighting

0 an optical system including a lens 6, a rectangular prism 7 mounted under the lens, and an ocular 8 that contains a field 9 and an eye 10 lens. Near the anterior focal plane of the ophthalmic lens 10, there is a plane-parallel glass 11 with a thin opaque intersection 12 (Fig. 16). The eyepiece 8 can be moved in the tube 13, which is necessary for refocusing of the optical system. On the entrance face 14 of the prism 7 is applied a thin

0 (e.g., 0.1 mm wide) an opaque intersection 15, the threads of which run along the diagonal of the face 14 (Fig. 1c).

The tube 13 of the optical system is fixed by means of the stand 16 on the carriage 17.

5 With micrometer screws 18 and 19, the carriage 17 can be moved along the longitudinal 20 and cross 21 guides, the micrometric screws 18 and 19 are equipped with scales that allow a high degree of

accuracy (for example, with an error of no more than 0.005 mm) measure the magnitude of the displacement of the carriage 17. The base 22 of the carriage is connected by thread with three adjustment screws 23 mounted on a stand 24, which is usually placed on the deck 25 of the X-ray table. By adjusting screws 23, the carriage 17 is adjusted to a horizontal position at level 26.

The x-ray tripod adjustment device is used as follows. The imaging device is mounted on deck 25 of the horizontal x-ray table so that the point light source 1 is in the field of view of the optical system. The adjustment screws 23 on level 26 bring the carriage 17 into a horizontal position. After that, the vertical carriage 4 with the X-ray emitter 3 along column 5 is moved to the extreme upper position and the reading is taken on a scale of 27 (Zi).

When turning on a point light source 1, the light wave enters the objective 6 of the imaging device. In this case, the light wave illuminates the crosshair 15 and is partially obscured by it; the image of source 1 is formed by lens 6 near the focal plane of the lens. Moving the eye tube 8 in the tube 13, the operator directs the sighting tube to the light source 1 in the defocus mode of the optical system relative to the light source. In this case, the observer sees in the field of view of the optical system illuminated by the source 1 of the entrance pupil of the lens 28, shaded by the crosshair 29 (Fig. 3a). In addition, in the field of view, you can see the crosshair of 30 ocular (cross over image 12). The center of the restrati 29 is shifted relative to the center of the cross 30 ocular, which is caused by the discrepancy between the optical axis of the sighting tube and the central beam of the light beam of the point source 1. The micrometer screws 18 and 19 combine the centers of the crosshairs 29 and 30 (Fig. 36), after which takes the readings on the scales of microscopic screws Ho and Wo. Next, the carriage 4 of the emitter 3 is moved downward so that the point light source 1 is approximately 20 cm from the lens 6.

On a scale of 27 heights take 2g. As a result of the installation error of the column 5 vertically there will be an offset to cross 29 from the center (Fig. Sv). With micrometer screws 18 and 19, the operator brings cross-hair 29 to the center (Fig. 3g), after which it takes readings on the scales of these screws X and Y.

The angle of deviation of the x-ray support column from the vertical can be determined by the following formulas:

X -Ho

PoosiHag "yes axis y

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arctg a

L - / LO

The proposed device for adjusting the X-ray tripod can be widely used both at the medical instrument making enterprises in the manufacture of X-ray diagnostic equipment and in clinics for the repair and adjustment of X-ray machines.

Claims (2)

1. An X-ray tripod alignment device containing an emitter mounted on a vertical carriage of the tripod column and an imaging device with two opaque intersections coaxially arranged with a 45 ° reciprocal rotation. This is so that, in order to improve the accuracy of the alignment and eliminate the effects of ionizing radiation on the operator, a point source of light of the visible range is used as the emitter, and the imaging device contains an objective lens, a right-angle prism, located near the lens, and an ocular, with one of the overlaps for designating the geometric center of the surfaces applied to the input face of the prism, a. the second is located near the focal plane of the ocular. 2. The device according to claim 1, wherein the imaging device is located on a horizontal carriage equipped with a mechanism for moving in the longitudinal and transverse directions, equipped with micrometric screws and a mechanism for adjusting the level. FIG. 1, and