DE1927633A1 - Introduction to visualize and / or record the flux density of gamma quanta or the two-dimensional density distribution of beta particles - Google Patents

Description

Patent attorney

Dipl.-Ing. H. straw tavern ₁

8 Munich 60 '

Musäusstrasse 5 ~,., _{/ R)} ../. _N

-S / 8p / Ru (4)

'' 190-715P

Arrangement for visualizing and / or recording the flux density of gamma quanta or the two-dimensional Density distribution of beta particles

The invention relates to an arrangement for visualizing and / or recording the flow density of Gammaquantea or the two-dimensional density distribution of Beta particles with a gas and vapor-filled spark discharge chamber and a flat cathode provided therein, to which a flat anode made of metal gauze runs parallel, with a likewise made of metal gauze between these electrodes existing auxiliary electrode arranged and the electrodes to a high voltage and an integrating recording device to determine the local distribution of spark discharges between the auxiliary electrode and the Anode are connected by the incident radiation quanta be evoked.

In particular, the invention relates to an arrangement of the type mentioned for use in the field of hadiodiagnostics and radiochromatography.

In a known arrangement of the type mentioned, gamma rays are at the cathode and in the gas layer between the cathode and the auxiliary electrode in primary electrons converted. The released by such primary electrons

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Set secondary electrons are, however, firmly attached to the gas filling bound. If the cloud of secondary electrons which enters the point discharge path is too small no spark discharge can be initiated.

The transition to this stage is promoted by setting the cathode to negative in relation to the auxiliary electrode Fotential is brought. The above-mentioned structure of the electrode system and the associated working principle of the known arrangement, however, has significant disadvantages.

First and foremost, the contribution of the cathode to this display process is negligible. This became an expensive one Xenon gas filling used to reduce the efficiency to improve with argon gas filling.

The number of spark discharges per unit of time is a consequence of the low conversion efficiency of the gas filling low during operation, which means that the creation of a detailed image of the radiation source requires a very long measurement time, which, especially when examining patients, is always unfavorable and in is even impossible in certain cases.

Another major disadvantage of the known arrangement is that as a result of the rather large distance between the cathode and the auxiliary electrode and thus scattering of secondary electrons between the cathode and the anode occurs, whereby in the plane of the anode, where these secondary electrons cause visible sparks, a blurred Image of the radiation source to be examined distorted.

The known arrangement has the additional disadvantage on that in converting gamma quanta into electrons a Conpton scatter much earlier in the gas than in the

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Cathode pops up. Thus, the arrangement is in terms of The maximum energy of the gamma quanta to be observed is limited. The image is heavily blurred by this Compton scattering.

The object of the present invention is to provide an arrangement of the kind mentioned, in which these disadvantages are avoided. This is generally achieved in that the auxiliary electrode is galvanically connected to the cathode and is at such a distance that the Electron cloud, which is introduced into the discharge path, contains enough electrons to trigger a spark discharge, and that the scattering of the electron cloud and the affinity of the electrons in this cloud for the gas molecules are minimal.

This electrode structure also has the advantage that the material for the auxiliary electrode has the highest possible resistance for the spark discharges can be chosen and that the material of the cathode with regard to the conversion of Gamma quanta in primary electrons can be optimized. Even the precipitation of waste products of the filling gas on the Auxiliary electrode does not interfere with the function of the cathode.

In the arrangement according to the invention, the number of spark discharges per unit of time in the space between the Auxiliary electrode and the anode almost entirely by the number of primary electrons leaving the cathode per unit of time certainly. Because this latter number is considerably higher than the number of primary electrons created by ionization the gas filling is obtained, is the time in which, with this arrangement according to the invention, a detailed going image of the radiation source to be examined is obtained, considerably shorter and certainly very much shorter than with an arrangement that works on the ionization principle.

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The small one used in the arrangement according to the invention The distance between the auxiliary electrode and the cathode has the further advantage that the anode is also closer together the cathode can be arranged, which makes it possible to increase the definition of the image of the radiation source significantly.

Furthermore, this small distance has the result that there is less disability on the part of the Compton scattering is to be expected, so that the energy range of the arrangement is increased above HO KeV. This will make the arrangement

M brought within range of the Tc 99 isotope, which is so important for radiodiagnostics. The short one used in the arrangement Distance is also absolutely necessary to read radiochromatograms. Because of the energy involved in these procedures The isotopes -014 (160 KeV) and H3 (18 KeV) used, the range is very short, especially for the last-mentioned electrons. The fact that these electrons are still displayed results from the presence of a stray electrical field, the penetrates through the auxiliary electrode.

Refinements relate to further details of the inventive Arrangement.

The invention is explained in more detail below with reference to the drawing. demonstrate:

Fig. 1 shows an embodiment of a erfindungagemässen Arrangement for visualization and recording of the flux density of gamma quanta in perspective and schematic representation,

2 shows an exemplary embodiment of an arrangement according to the invention for reading two-dimensional radiochromatograms in perspective and schematic representation,

3 shows a spark discharge chamber forming part of the arrangement according to FIG. 1 in an axial section and in contrast, enlarged representation,

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4 shows an enlarged section from FIG. 3 to illustrate a fastening for an electrode system,

FIG. 5 shows an exemplary embodiment of a spark discharge chamber that is modified compared to FIG. 3, in axial section;

Fij. 6 shows an enlarged section from FIG Illustration of a fastening for an electrode system similar to FIG. 4.

The arrangement according to FIG. 1 is used to produce images of the radiation density distribution of a radioisotope activated object, which can be an organ of the human body, for example the thyroid, the brain or the like.

An object 1 containing radiating atoms emits gamma radiation 2, which passes through a collimator 3, the one plate made of heavy material, for example lead or gold, with a large number of holes drilled in parallel 4 includes. Radiation passes through the holes 4 to a gas-filled chamber (not shown) Flat cathode 5. When gamma radiation hits this cathode, primary electrons are released, which are used in the absorption process Generate secondary electrons that move through a grid-shaped auxiliary electrode 6 under the influence of a stray electrical field in a spark discharge gap move. The auxiliary electrode 6 is arranged at a small distance between the cathode 5 and an anode 7, the is also designed as a grid. The electric field strength is set to such a value that a Electron cloud, which forms in the space between the auxiliary electrode 6 and the anode 7, a spark discharge triggers. In their entirety, these discharges enable the local distribution of the radiation density to be determined in the object to be examined. A picture of this

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Distribution can be recorded by a camera 8. In this way, not only the shape and dimensions of an object, for example a human organ Body, but also some of its defects, for example destruction caused by the presence of a cold tumor because isotopes do not penetrate where the organ is damaged and from there no radiation will be emitted, nor will point discharges be generated.

According to Pig. 2 is a radiochromatogram to be read 10 and grid electrodes 11, 12 arranged in a (not shown) gas-filled chamber. The chromatogram contains an electron-emitting substance and acts as a cathode. The emitted electrons run through a Auxiliary electrode placed a short distance from the chromatogram in the space between the cathode and the anode is. As a result of the electric field that exists in this space, the electrons generate spark discharges there. The shape of the spark discharges can be determined by a camera 13 or by electrical components Digital recording circuit are recorded, in which case the auxiliary electrode and the anode off alternately parallel wires are constructed, which are arranged so that the wires of the anode are those of the auxiliary electrode cross.

The spark discharge chamber according to FIG. 3 accommodates an electrode system and consists of a cylindrical metal jacket 20, a locking ring 21 on one end face, which is attached to an end plate 22 made of transparent material is arranged, as well as a retaining ring 23 on the other end face, which holds a collimator 24. By doing cylindrical metal jacket 20 are a gas supply nozzle 25 as well as an insulating sleeve 'for the electrical connection of the

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Electrode systems arranged. The areas between the The jacket 20, the end plate 22 and the retaining ring 23 are hermetically sealed by O-rings 27. In the Chamber is also attached a cylindrical gas distribution ring 28, which at both end portions with inward protruding portions of the jacket is connected, in this way a circular channel between the distributor ring and shell 20 communicating with the chamber interior through openings in the distributor ring stands.

The electrode system is fitted inside the gas distribution ring 28 and consists of a flat cathode 29, which rests against an end face of the collimator 24, an auxiliary electrode 30 made of a grid that has a small Having a distance from this, and a grid anode 31 at a distance from the auxiliary electrode.

The cathode 29 is made of a material with a

optimal conversion efficiency for the one to be displayed

1 2S radiation, e.g. silver for isotope I.

(Energy 27 KeV) and gold for the isotope Tc 99 ^M (energy HO KeV). This material is applied in the form of a thin layer (thickness of 1-10 microns) to a base, which conveniently consists of a synthetic material similar to Mylar.

According to another embodiment of the invention however, it is possible to obtain a substantial increase in the efficiency of the cathode by using the cathode material < is applied galvanically to a metal base, for example a copper foil with a surface roughened by etching or steel-raying. To this Manufactured in a wise manner, the cathode also has a roughness which is considerably greater than the area of a smooth one

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Cathode is the same size. Since the cathode efficiency is proportional to the area, it is proportional Increase in efficiency.

The auxiliary electrode 30 and the anode 31 are each attached to a thin metal ring 32 and 33, which with each other by a support ring 34 made of insulating material are connected of such a shape that the anode belonging ring 33 with one side into the central opening of the ring 32 extends on one side of the auxiliary electrode. Using a thin washer 35 made of insulating material, the arrangement is attached to one side of the retaining ring 23, with the cathode 29 thereon rests.

This structure of the electrode system guarantees a high precision of the distances between the electrodes, which is also the case in the In view of the very short distance between the cathode and the auxiliary electrode is required. Try with a sample of the device shown showed that the number of electrons, which reach the space between the auxiliary electrode and the anode, steadily through dispersion and by the affinity for the gas decreases when the distance is increased, whereas when the distance is decreased further it decreases Distance is the number of secondary electrons that are released by the absorption process of a primary electron, originating from the cathode is too small to trigger the spark discharge. Also a photoelectric one Feedback in the cathode can cause undesirable flashback phenomena. Therefore this should Distance between 0.5 and 4 mm.

4 shows the possibility of setting the distance between the anode 31 and the auxiliary electrode 30. For this purpose, the ring 33 is attached to the support ring 34

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fastened by adjusting screws 36 with springs 37, with which the distance between the anode and the auxiliary electrode can be varied so that any differences in the parallel position of these electrodes can be corrected can.

According to Pig. 5 are an auxiliary electrode 40 on a metal ring 42 and an anode 41 on a metal ring 43 fixed, and these are connected to each other by a support ring 44 of insulating material, the thickness of which gradually increases in a small area near the central passage to a value equal to that required alternate distance between these electrodes. The top and bottom of this ring are each coated with a material of low conductivity to prevent the occurrence of the so-called gap effect, which can cause undesirable point discharges along the inside of this ring.

With this structure, which is described in Pig. 6 shown enlarged it is achieved that the two grid electrodes are stretched in such a way that they have the same spacing, whereas for the accuracy of the distance between these planes only the tolerance of the inside edge of the ring plays a role. This tolerance can be under the use of normal machines without special precautions 40 microns.

The electrode systems described both have the advantage that they can be used, for example, to clean the electrodes can be easily disassembled and reassembled without affecting the accuracy of the position of the electrodes each other is influenced in some way.

In the arrangement according to the invention, cheap argon can be used as a filling for the display chamber. It showed also that an almost unlimited service life of the grid

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gazeelektroden can be achieved if they are made of metal having a melting temperature of more than 2000 ⁰ C, as well as from non-creeping material, in particular Wolframgaze with a wire diameter of, for example 30 microns.

In order to prevent the occurrence of corona discharges between the auxiliary electrode and the anode, which are made of gauze are produced, these electrodes are arranged in relation to one another in such a way that the wires from which they are put together are not parallel to each other.

To the facility to examine objects To make suitable by means of radioisotopes, the main idea of the invention can be further developed by the assembly is provided with a number of cathodes, which are represented by a strip of some material or are held by a transport mechanism, by means of which each of these cathodes of its own choice in the spark discharge chamber can be introduced.

Pat entan's gossip

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Claims (10)

Claims M J Arrangement for visualization and / or recording of the Flu3 density-of gamma quanta or the two-dimensional Density distribution of beta particles with a gas and vapor filled spark discharge chamber and one provided therein flat cathode, to which a flat anode made of metal gauze runs parallel, with a Also made of metal gauze auxiliary electrode is arranged and the electrodes are connected to a high voltage and an integrating one Recording device for determining the local distribution of the point discharges between the auxiliary electrode and the anode, which are caused by the incident radiation quanta, thereby characterized in that the auxiliary electrode is galvanically connected to the cathode and is at such a distance therefrom located that the electron cloud, which in the discharge path is initiated, contains enough electrons to trigger a spark discharge, and that the scattering of the electron cloud and the affinity of the electrons in this cloud for the gas molecules are minimal. 2. Arrangement according to claim 1, characterized in that the distance between the auxiliary electrode (30) and the cathode (29) is between 0.5 and 4 mm. 3. Arrangement according to one of claims 1-2, characterized in that that the anode (31) and the auxiliary electrode (30) are each attached to one side of a thin metal ring (32 or 33), the ring (33) for the anode smaller diameter than that (32) for the auxiliary electrode (30) and the rings together by a Support ring (34) made of insulating material of such a shape 909885/106 0 --fa - are connected that one side of the ring for the anode into the central opening of the ring (32) for the Auxiliary electrode (30) protrudes. 4. Arrangement according to claim 3, characterized in that the ring (33) for the anode on the support ring (34) is fastened by adjusting screws (36) with springs (37) so that the distance between the anode (31) and the auxiliary electrode (30) is changeable. 5. Arrangement according to one of claims 1-2, characterized in that that the anode (41) and the auxiliary electrode (40) are each attached to a metal ring (43) by means of which they stretched on the end faces of a substantially flat support ring (44) made of insulating material the thickness of which is gradually increasing in a small area around the central opening and that on both sides is provided with material of high conductivity. 6. Arrangement according to one of claims 1-5, characterized in that that the anode (41). and the auxiliary electrode (40) are made from tungsten wire. 7. Arrangement according to one of claims 1-6, characterized in that that the anode (41) and auxiliary electrode (40) made of gauze are arranged against one another in such a way that their Wires cross each other. 8. Arrangement according to one of claims 1-7 »characterized in that that the anode and the auxiliary electrode are made of alternating parallel wires and are arranged in relation to one another are that these wires cross each other. 9. Arrangement according to one of claims 1-8 for visualization and / or recording the flux density of gamma quanta, characterized in that the cathode is a roughened 909885/1060 Has surface which increases the effective area. 10. Arrangement according to one of claims 1-9 for visualizing and / or recording the flux density of gamma quanta, characterized by many cathodes on a support system and a mechanism by means of which each this cathode can be arranged opposite the auxiliary electrode (30) of any choice. 909885/1060