DE1764905C3 - Spark chamber - Google Patents

Description

A spark chamber according to the preamble of claim 1 is known from GB-PS10 89 018.

Such spark chambers are known to be used as image converters, i.e. used to capture invisible to be able to evaluate images produced by ionizing radiation, in particular in the case of fluoroscopy or the investigation of organs made radiant by radioactive isotopes.

With known spark image converters as well as those according to the above-mentioned GB-PS, one has in the As a rule, plates that face each other and are connected to an electrical voltage are used between where visible spark discharges occur depending on the radiation. To get a usable picture To obtain, one has thereby placed the electrodes perpendicular to the beam direction, which then runs in the same way as the electric field. The effectiveness of the rays is only slight. The quantum conversion can because of the difference between the absorption of the incident rays and the range of the released electrons, that behave like 40: 1 will only be slight. On the one hand, the conversion layer should be thick so that as many quanta as possible are absorbed. On the other hand, the thickness of the absorption layer, i.e. H. the photocathode, not be stronger than the middle one Range of the released electrons so that they can still penetrate to the outside. One known, consisting of silver cathode layer should, for. B. 0.015 mm thick. The resulting minor The quantum efficiency of the spark imager has therefore been widely used by imagers up to now this kind of prevented

The invention is based on the object of a spark chamber according to the preamble of the claim 1 to improve the turnover of ionizing rays. According to the invention, this object is achieved by

ίο those indicated in the label of this claim Measures resolved

Due to the new structure, i.e. the arrangement of the Cathode and anode, parallel to the direction of the radiation, results in a larger absorption path for the

IS incident quanta without any substantial Enlargement of the electron exit paths in the cathode material, which is known because of the ratio 1:40 stronger absorption of the electrons should be small, must be accepted. This is based on

ίο that you have a sheet metal for the construction of the cathode can use, which is thinner than the range of the generated electrons, so that both sides electrons exit and can be used for illustration. On the other hand, the great expanse extends of the sheet in the direction of the rays or according to an advantageous development of the invention this inclined z. B. so much that the projectoin of the cathode parts in the beam entrance plane this area fully covered so that the absorption paths run near the surface of the sheet and become long. at Inclination of the cathode parts also increases the absorption, i.e. the number of conversion processes the rays great. The arrangement of the sheets can be chosen so that even with large expansion of the Sheets in the direction of the rays no deterioration of the image occurs, for example if the sheets in the Form of closely spaced, preferably hexagonal cross-section having tubes configured are, in the center of which the anode parts z. B. are arranged as rods.

Tests have shown that when using Tubes made of nickel silver sheet with a wall thickness of 03 mm, a diameter of 6 mm and a length of 60 mm as cathodes and anodes arranged in their center, which have the shape of 1 mm have strong tungsten rods, at 60 KeV radiation a level of 400% compared to the known devices increased quantum yield is obtained. This yield can certainly be increased if the

so arrangement z. B. in terms of the materials used and the dimensions, etc. is optimized.

In a simpler way, particularly in isotope technology, it is possible to obtain useful images of sufficient resolution obtained by making both the cathode plate

SS and the anode plate are broken down into strips and these are at least approximately parallel to the direction of incidence of the rays and switches alternately as cathode and anode the electric field is given an expansion that

lies at least approximately transversely to the incidence of radiation. An improvement in this design can be achieved, for example are made by making the anode, in approximation of the formation with the tube, from individual rods that is made at one end in the shape of a

Comb are connected to one another in an electrically conductive manner. The rods lie with their longitudinal axes parallel to the width of the cathode strips.
As gas filling, all known, self-releasing

Seeing gases and gas mixtures can be used. Mixtures containing heavy atomic gases, such as about xenon or argon and an extinguishing gas additive of z. B. contain 10% methane.

The arrangement of the cathode and anode parts is done in such a way that the tube diameter or Strip spacing is given, the materials used for the production with given incident rays, Gas filling and applied voltage, result in an optimum of the effect. When training as adjacent, Strip-shaped plates, which are connected alternately as anode and cathode, result when using brass as cathode and anode material, a wall thickness of about 03 mm as well as a distance of 3 mm. Other metals with a medium to high atomic number also give good results expect. Any electrical can be used to support the anodes and cathodes on one another insulating materials are used, such as ~ acrylic glass, ceramic or glass.

An exemplary embodiment of the invention is explained below with reference to the figures.

In FIG. 1 an embodiment is drawn, in which a spark chamber with a honeycomb-shaped Cathode is provided

In FIG. 2 is a section from the photocathode-anode combination the spark chamber according to FIG. 1 so that especially the hexagonal Cross section of the tube is visible, in the longitudinal axes of which the anodes are in the form of round ones Stripes are arranged.

In Figure 3 is a schematic cross section depicted by an arrangement in which the cathodes and the anodes are plate-shaped and

in FIG. 4 shows a detailed drawing of a cross section from FIG. 3 with a chamber-like anode and

in FIG. 5 a detailed drawing in the event that the anode is also in the form of closed plates

In Fig. 1, the closed box provided with the taps la and \ b is denoted by 1 in which the anode 2, which is connected to the positive pole of the DC voltage source 3, is arranged. The negative pole of the current source 3 is connected to the cathode 4, which consists of a plurality of tubes combined in a bundle. For recording, the photographic recording device S is assigned to the free end face of the cathode tube. The cathode tubes are made of juxtaposed 60 mm wide strips 7 of 0.30 mm thick brass or heavy metal sheet (Fig. 2), which have a profile that is raised and pressed next to each other in the shape of a half hexagon, so that they at Placing the metal sheets next to one another results in hexagonal tubes with a diameter of 6 mm, arranged like a honeycomb. The anode is in the form of rods 8 in the longitudinal axis of the hexagonal tubes and is held there at the beginning and at the end of the tube by a piece of insulating material (9 and 10), a transparent material, namely acrylic glass.

When applying a voltage just below the breakdown voltage, in the present case 3 kV, and The impact of the ionizing rays according to the arrows 6 is dependent on the irradiated points get a 6} spark discharge from the number of absorbed quanta. In the tubes of the Cathode 4 is one made of 90% xenon and 10% methane Contain existing gas atmosphere, which are to be exchanged with respect to the space of the box 1 Holders 9 and 10 at the beginning and at the end of the cathode tube, each with an opening 9a and 10a Mistake. The spark discharge becomes visible on the surfaces of the cathode arrangement 4. It is Each tube of the cathode 4 has a cone 5 'with an angle of 40 ° at the tip transparent plastic, namely acrylic glass, assigned so that an axicon optic is created The visible Spark image can be registered by means of the tips of the cones 5 'upstream camera 5, so that a a recording usable for documentation is obtained.

In FIG. 3, an image intensifier is shown schematically in which the cathodes 11 and anodes 12 of the electrode arrangement are each connected to the voltage source 15 together via the lines 13 and 14. These parts 11 to 14 are in an over valves 11a and üb with gas which can be filled closed box lic

According to Figure 4, the cathode 11 is from the panels 16 arranged next to one another, which are 60 mm wide, 0.30 mm thick and made of a metal with an average atomic number. They have a distance of 3 mm, the one at the top and one at the lower edge of the plates 16 by spacers 17, 18 made of insulating plastic, namely acrylic glass, is held. In the plastic are 16 metal rods as anode 12 with their longitudinal axes parallel to the plates 19 held, which go through the spacers 18 on their underside and on their top End side before reaching the surface of the insulating spacers 17. The bars 19 are made of stainless steel, have circular cross-section with a diameter of 1mm and a Length which corresponds to that of the plate width up to about 0.5 mm. The applied voltage of the Power source 15 is approximately 3 kV.

When ionizing rays strike from the direction of the arrows 20, this too Arrangement between the cathode plates 16, the cathode 11 and the rods 19 of the anode 12 Spark discharges that can be observed, photographed and transmitted as electrical signals via corresponding Channels, e.g. B. core memory matrix can be displayed. For digital acceptance as electrical signals, which also in the training according to F i g. 2 can be carried out, however, discharges from the anodes 8 or 19 required so that the areal assignment of the Signals to the pixels is possible.

The one shown in FIG. 5 relates to a different embodiment of the cathode U and the Anode 12. They consist of sheet metal strips 21, 22 of 030 mm thickness and 60 mm width. The single ones .Strips 21 and 22 are at a distance of 035 mm next to each other in the closed box Hc. The distance is determined by the at the top and lower edge of the strips 21 and 22 inserted acrylic glass strips 23, 24 held. Because of the use With transparent acrylic glass, it is possible to observe the arrangement from both large surfaces. The gas exchange with respect to the gas space in the box lic is sufficient because the spaces between the strips 21, 22 are laterally open. The length of the cathode and anode strips 21, 22 is the adapted to the image format to be imaged and is for the present image converter, which is used in medical X-ray technology is used, as is the 30 cm

the width resulting from the number of individual strips arranged next to one another. The gas mixture filled between the cathode strips 21 and anode strips 22 consists of argon with an addition of 10% methane and has a pressure that is just above atmospheric pressure. The direct current applied via lines 25 and 26 has a voltage of 3 kV. The electrode strips 21, 22 are rotated about their longitudinal axes with respect to the central beam 27 from the radiation source 28 designated as X-ray tube by the angle of 3 ° designated by A , so that the entire entrance surface of the X-rays from the beam 29 of the projection of the cathode strips 21 against the Beam direction is covered. Otherwise, the effect corresponds to that in the exemplary embodiments of the invention which are shown in the other figures.

1 sheet of drawings

Claims (6)

Patent claims: 1. Spark chamber for converting a distribution of x-ray or gamma radiation into a visible spark pattern, with a cathode and an anode, each of which consists of several conductive, elongated ones Parts which are arranged parallel to each other, characterized in that that the rod-shaped or strip-shaped parts perpendicular to the radiation entrance surface of the spark chamber are arranged so that the direction of the electric field is parallel to the radiation entrance surface lies 2. spark chamber according to claim 1, characterized in that both the anode (12) and the cathode (11) consist of strips (21,22) which in Spacing parallel to each other and connected alternately as anode and cathode. 3. spark chamber according to claim 1, characterized in that the cathode (4.11) from parallel there is mutually arranged strips, between which the anode parts as a plurality of rods (9,18) are arranged. 4. spark chamber according to claim 1, characterized in that the cathode (4) forming Strips in the form of tubes are arranged, in the center of which there is an anode rod (8) is located (Figs. 1 and 2). 5. spark chamber according to claim 4, characterized in that the tubes are hexagonal Have cross-section (Fig. 2). 6. spark chamber according to claim 1, characterized in that the incident radiation is inclined with respect to the perpendicular to the radiation entrance surface in such a way that the perpendicular Projection of the parts forming the cathode covers the entire radiation cross section