DE1265879B - High-performance roentgen tube plant - Google Patents

Description

FEDERAL REPUBLIC OF GERMANY GERMAN -007WW PATENT OFFICE Int. CL:

H05g

EDITORIAL

HOIj
German class: 21g-20/01

Number: 1265 879

File number: L 42143 VIII c / 21 g

Filing date: June 5, 1962

Open date: April 11, 1968

The invention relates to a high-performance X-ray tube system for irradiating substances for the purpose of modification their physical, chemical or biological properties, preferably with continuous Material to be irradiated, by means of two X-ray tubes with penetrated radiation, in the tube wall lying outer anode, which face each other at a distance, so that the substance to be irradiated in the space between these two X-ray tubes can be introduced.

Systems of this type are known.

The invention is based on the object of providing an X-ray tube system of the specified type create, which can be adapted to the most varied of dimensions of the substances to be irradiated. Aus * 5 going from the known, two opposing X-ray tubes exhibiting the invention in that, to achieve an elongated radiation field, each tube has a plurality of in Partial cathodes arranged in the longitudinal direction of the tube or a ° Has cathode filaments and that each tube to enable adaptation to the dimensions of the Goods to be irradiated from independent ones containing the partial cathodes or cathode threads and on Their end faces are provided with connecting flanges and arranged one behind the other in the longitudinal direction of the tubes and structural units connected by seals.

In particular, when the material to be irradiated is transported on or in a transport device, there is no need for a flat design of the focal point; Rather, a narrow focal spot, for example 5 cm wide, can be used, the length of which is preferably perpendicular or at a large angle to the direction of transport and its length is adapted to the width of the transport. The width of the focal spot should in any case be small compared to its effective length. For example, the length can be up to 100 cm or even more. Structurally and technologically, this is very advantageous for the design of the anode, since it is mechanically much more stable and easier to manufacture than the large-area membrane anodes used in known systems with rectangular focal spots of, for example, 100 X 170 mm ² or with focal spots with a circular border of the focal spot area. In contrast to these known high-current X-ray tubes, the size of the focal spot and the radiation field in the system designed according to the invention can be easily adapted to the respective needs by placing the tube together with the focal spot in just one high-performance X-ray tube system

Applicant:

Licentia Patent-Verwaltungs-G. mb H.,
6000 Frankfurt, Theodor-Stern-Kai 1

Named as inventor:

Dipl.-Phys. Ernst Günter Hofmann, 1000 Berlin

Direction, the longitudinal direction, is shortened or lengthened.

This advantage is also with another known liquid-cooled membrane anode x-ray tube not achievable, with which only a band-shaped focal point is generated. Well known X-ray tubes with hollow anodes are obviously not specially adapted to the dimensions of the one to be irradiated Customizable fabric.

In order to obtain a radiation field that is approximately parallel to the anode surface, the outer focal spot areas with the same size on average more heavily loaded than the inner or at with the same average surface loading and the same length of the focal point in the outer areas.

The implementation of the invention is intended either so that each tube consists of several structural units consists, each of which has a partial cathode, or so that each tube has a plurality of partial cathodes contains, which are arranged in a structural unit, and that one or two with each structural unit Connection means provided structural units are flanged.

In both embodiments, it can be useful that one tube has N partial cathodes and the other tube N + 1 partial cathodes and that the tubes are then arranged in their longitudinal direction to each other so that each of the iV cathodes of one tube in the center plane between two Cathodes of the other tube come to rest.

In order to be able to work according to the modular principle, it is recommended to provide the following units:

a) a unit for cable connection and high voltage,

809 538/423

b) a unit for vacuum equipment, such as a nickel or irradiated letehtmetall pump, z. B. ion getter pump, measuring devices and anode - z. B. made of aluminum or aluminum connectors for the pre-evacuation of the alloy - all with heavy metal layers - cipients, e.g. B. made of gold - to increase the X-ray

c) a tube assembly that may yield ⁵ yields. When using Aliminjum again it is divided into anoden, however, on a special Zeieftea-

"_, ..,, .... .., _ sharpness of the focal spots are dispensed with, so that

1. A tube unit with a reinforced structure _{results in a simpler} cathode construction than before, including the overall performance for mounting on the outside

Sides of the entire _{tube, 10} ^g. _{The cathodes can be fixed> z} . _{B. m} two-point

And 2. a Röhrenbaueinheit be normal power storage, connected to insulators with the Röhrenbaueinheit for assembly in any number therebetween along respective two Röhrenbaueinheiten, f _este unit form. On the other hand it is possible

d) any end flanges for the assembly of the cathode on the one hand and the tube jacket with the Tube. 15 the anode, on the other hand, is not structurally fixed to one another

Connect the cathode axially to the tube - of course, depending on the design - the body (which in this case can be divided into a tubular shape. For example, it can be set) on special support insulator elements to also attach the tube unit in the tube body. In order to avoid uncontrollable transmission with the anode, the cathode and possibly in contact resistances, it is advantageous to use the Khd
Allocate special post insulator elements (for the cathode) to thread all the individual cathodes in series. Linear filaments can be used for the cathodes so that a constant emission of filaments is ensured in the cathode system at least for filaments,
are resiliently suspended on one side. The tubular vessel can be tubular or several cathode filaments or filaments 25, the focal spot with its lengthwise segments being grouped together to form partial cathodes, so on the tube jacket parallel to the axis that each Partial cathode runs a partial focal point band body. The material for the tubular shape on the outer anode of each individual body is made of stainless steel, aluminum tubes. The linear filaments can be par or aluminum alloys. With Vejwtn- * allel on the long side of each ribbon-shaped division of stainless steel, the anode must be focal point. The partial focal points, when flanged or welded on using a special process, then in their effect correspond to a single band-shaped or soldered on.

Focal point. When using aluminum or aluminum alloy, however, the Rojir itself can show exemplary embodiments of the invention 35 - possibly after appropriate processing - with the aid of the figures, some of which are schematically illustrated. serve as an anode. In the latter case it is e.g. B, safe * F ig, 1 schematically shows a tandem-lent X-ray, an aluminum pipe of 300 to 400 mxü DurcS 'tube system with two opposite X-ray diameter and 10 mm wall thickness to use, the tubes; on the anode side from the inside and outside in such a planar manner. 2 to 5 and 7 show the arrangement of the Ka- 4 ° is milled that a flat anode surface of about thoden or the focal spots produced by this; 3 mm wall thickness and 50 to IQO mm width ent-F i g. 6 shows an X-ray tube system made from multiple pieces. It is also possible to use a correspondingly thinner building blocks; Tube can be used without any additional processing; 45 in the anode area. To the Stim-F i g. 9 shows a section through the tubes of the rarely have the substantially tubular FIG. B- body be provided with flanges that a to-In Fig. 1 two X-ray tubes la and Ib are enable sammenbau with the other components, with the cathode la and % b , which are attached to the metal seals in Be * post insulators 3 β and 3 &. The individual costume, so that the tubes in the assembled cathode filaments lie opposite each other in the tube longitudinally evacuated state, if necessary, baked out, so that the overhangs can pass through.

Storage of the radiation fields of the individual focal spots 4 α During operation, the tube body and 4 b must be sufficient to homogenize the radiation field - in order to avoid heating. The tubes are to be through flanges Sa and 55. For this purpose, water is expediently used, 5 b sealed on the right side, while cooling stanchions 6 ff and 6 b for the high voltage and 6 b for the high voltage and 6 b for the high voltage and continuously attached to the outside of the tube on the left side each have a structural unit with a cable insert body in good thermal contact snake or - in the case of a double-walled design of the heater, to which the tall tubular bodies are also flanged - the space between the same vacuum pumps 7 s and 7 b are connected. 60 flows through. Furthermore, for the Röbrenkesssl a When building the tube as a structural unit can be provided with lead cover, so that essentially tubes with a large focal spot known construction only in the focal spot area radiation from the Rghre elements are used. This includes, among other things, is emitted. The anode cooling can also involve the use of mercury diffusion in a known manner by water circulation cooling in the. Qb $ r <or ion getter pumps, from high voltage area boiling area with turbulent flow, explosion-proof cable plugs as feed for high followers.

voltage and heating and from irradiated mem- The tube unit can veigchie =

bran anodes with lens-shaped cooling channels - z. B. to be made long so that the dh

5 6

tion of the radiation field, for example, the dimensions and disadvantages and the measures for radiation field

the width of the transport device is adapted to the homogenization are the same here as in the previous

can. However, since the cathode filaments with standing case,

Consideration of their thermal expansion as a result of the last-mentioned arrangement

the heating and the possible sag to 5 voltage, it is also possible to use the

Due to the effect of the electric field, the partial cathodes and filaments do not come off

can be made as long as you like, a

division of the cathode and thus of the focal spot emergency rows as before the partial cathodes, so that with one

agile. When using linear heating filaments, the cathode, which is shorter or longer as required, is

an effective emission length of about 100 to 10 can be made, a coherent combustion

It is advisable not to exceed 200 mm. To the spot according to FIG. 5 is formed. Particularly one

generation of a 5 cm wide focal spot, in this case the radiation field homogenization

Usually, however, several, z. B. two to five heaters at the tube ends. This can be realized

threads are arranged in parallel. They then generate sated that when using similar

a partial focal point about 5 cm wide and 10 15 cathode threads the distances between the cathode

up to 20 cm in length, ^{i.e. 50 to 100 cm 2} area, will denfäden and the associated individual burn spots

with an average surface loading of about to both ends of the tube successively in the

500 watts / cm ² worked, the anode needed to be reduced in size and thus the

performance of such a tubular element, depending on the length, surface loading towards the focal point ends in

about 25 to 50 kW. 20 means is enlarged.

You can now line up such tube elements in any number compared to the previous designs and so the tube units according to FIG. 6 form a long focal point. Subdivide the suspension further, e.g. B. in terminal and central device and the final cooling of the threads make tube units 11 "and Ub. However, it is impossible for each terminal component to produce a coherent focal point for a higher anode output if they are arranged in a linear sequence. designed as the associated central component between the focal points, intermediate elements are created. The structure of a tube is then depending on the spaces, so that the dose field of such a tube may have intensity minima by flanging together a desired one at these points, while maxima are present in a number of structural units with the cathodes 12a and the center of the focal spots. 30 12 b possible. Their construction from the requirement-According to the invention both tubes one-ended intermediate flanges 13 are therefore α and 13, however, the other b faced here so that each minimum the formation of a contiguous Brennder a tube, a maximum of the other counter flecks difficult. If the axis is parallel to the axis, the firing is superimposed. For this purpose, the one tube spots 14 a and 14 b of each sub-tube is expediently equipped with one less element than the distribution in the region of the flanges has minima, as shown in FIG. 1 is shown. This compensates for these minima - similar to an approximate homogenization of the field between previously shown - a tube (possible if the two tubes are the same. A homogeneity rather the length of the components) with a structural unit at the ends of the Tubes, on the other hand, build up less than the other and both tubes are achieved by arranging, for example, the surfaces 40 so that the center of the focal spot 14 of the other is increased on average for each flange 13 of the one loading the focal point of the end element tube or with the same area - faces. In this way there is always a mini-load whose focal spot width is enlarged. The mxim is opposed to a maximum, and an image of the focal spots of the tube Ib is shown in FIG. 2, relatively homogeneous dose distribution parallel to the. 4 ₅ focal spots to be expected.

To avoid the intensity minima between, it is also possible, according to FIG. 7 opposite the axis spots 8 and 9 - laterally offset - to be arranged so rotated that when passing through the that the partial focal spots - albeit laterally placed perpendicular to the long side of the part - have the same effect as a burned spot - so at an angle to the tube axis - the long coherent focal point are. This disorder effect of a coherent focal spot requires a somewhat wider anode than is. Such an arrangement, however, has exceeded from that in the former case, this disadvantage is above the advantage that two similar Röhden advantage that the GR with the same tube length _e JJI _e 55 can be used ren and the arrangement sentlich higher total capacity is achieved, a higher integral penetration capacity is compensated. Two similar seats can also be used here.

Tubes are juxtaposed. According to the FIGS. 8 and 9 are two tubes 16, 17

Dose field homogenization at the tube ends is arranged on a stand 18. Fig. 8 shows

follows as before by increasing the average fa the system is standing on level A. Both tubes

Surface loading or enlargement of the focal spot are used to characterize the concept of the invention

width of the terminal tubular elements. shown in different embodiments. In

Another possibility of arranging the part of the practice, both tubes became a matter of course

cathode consists in that, as shown in Fig. 4, they are designed according to roughly the same construction principle

to be arranged at an angle to the tube axis so that the probes. In the system, for example, the irradiation

jection of the partial focal spots 10 onto a material for tubing on a conveyor belt 19 (FIG. 9) in

axis parallel lateral surface in terms of one of the directions shown parallel to plane A between

coherent focal point corresponds. Run the provision through the two tubes. The lower one

Claims (1)

7 8 tube 17 is on the stand 18 with counter bearing 20 metal seals in question, so that the tube is firmly built. The X-ray radiation thus emerges upwards into the elements after evacuation, if necessary in this case. In contrast, the upper one can also be baked out. Tube 16 is movably arranged via a spindle drive, not shown. In contrast to the design of the upper tube in the present case, its radiation is directed downwards. On the 16 at the lower tube 17, support insulators for the attachment of the cathode to the d. H. in the drawing on the right, the upper tube tube housing can be omitted. The cathode is here also intercepted via a further adjustable spindle 21 special component between the feedthrough of the counter bearing 20. The upper tube 16 now consists of the following special support insulator of the end component 36 structural units: supports. The tube jacket is cooled in the 1. Assembly with cable feed 22 for high-contrast to the aforementioned upper tube groove voltage and heating. ^emer wasserdurchstiomtea KuhlscMange 37 m "_F. . , "", 15 good thermal contact with the pipe housing 2. Unit 23 with connection for vacuum pump is bound. Otherwise the execution takes place according to pen. This structural unit carries the vacuum pump according to _the above principles. 24, here an ion getter pump, and has Besides the embodiment shown in the drawing Aufeinen connecting flange 25 with valve for the _ste ilung of the tube at the level A is also a pre-evacuation of the tube and a comparable _ao formation at the level B, or on a closable to Assembly opening 26th drawing plane, parallel plane possible. in the 3. Tube assembly 27. The tube body in the latter case, the irradiated material, for example, consists of a thick-walled aluminum tube in a vertical channel through the radiation field tube, which is passed through on the underside from the inside and both tubes. This is outer to one thickness 3 mm flat, particularly advantageous for bulk goods. On the other hand, it is milled. With this arrangement, this plane-milled surface could also form the irradiation anode 28 (FIG. B. be carried out from both tubes. For this purpose gold - is provided. Around the actual, especially smaller items to be irradiated, such as the tube _{jacket, there is another 30} bottles, ampoules, cans, etc., which then have a jacket 29 for cooling the housing, which is done with irradiation water that is not too wide, but very long. The outside is on this jacket ment field would go through, whereby a very lead cover provided, so that the large throughput would be guaranteed. In this case radiation only from the actual anode, however, is a pulling apart of the focal spot on being emitted out. For the anode cooling system, a width of at least 10 cm is advisable. a cooling water connection 30 is provided, which is flanged to the tube from below, if possible. The fact that both feed tubes of the system in the stand cooling water runs expediently in one are suspended in such a way that they fork-shaped the decided circuit over a heat exchanger. Radiation space and include all additions, the cooling of the anode is carried out with strong turbu- ₄₀ for high voltage vacuum and cooling water flow as only by Lenter Oberflächensiedekühlung. attached to one side. This would make it possible to have two tubes on the upper side of the housing, the tube being attached to an existing transport connection piece with a flange, in which a belt can be inserted or if necessary it can be held without a support insulator 31. The cathode 32 dismantling of the conveyor belt is to be taken out again via the support insulators 31 firmly with the 45. Tubular assembly connected. The connections With an effective length of the connections for high voltage and heating take place via the partial focal point of 1 m, each of the cable entry 22 could optimally be - _a i _so w ith 250 to 60 oKW are loaded. As a side of the cathode arranged in such a way that on the ₅₀ operating voltages, tube anode 28 (FIG. 9) preferably have a connected voltage between 120 and 20OkV; Focal spot is formed. The arrangement in principle, however, also higher voltages corresponds in principle to that shown in FIG. 5. conceivable. For homogenization of the radiation field at the \ yi _e already mentioned, the outer anodes to the ends of the tube, the filaments with the ₅₅ increase in the X-ray yield with a cathode ends, successively decreasing waste heavy metal pad, for example, are provided from gold, arranged stalls. Because of the interaction of the X-ray focal point with, on average, generation towards the ends and the absorption should thereby increase surface loading, so that an isodose 60 to 100% of the anode plane approximately parallel to the layer thickness of the heavy metal coating - 60 of the maximum penetration depth of the Electrons in the field is created. The filaments can be connected in series with the acceleration voltage in question. The power leads 34 are hitting the heavy metal layer,
in the focusing body parallel to the longitudinal axis the tube arranged. Patent claims:
4. End flange 35 as a unit for connecting 65 close the tube. The individual components 1. High-performance X-ray tube system for loading are exposed to substances through flanges and seals in order to change their phy- connected to each other. Physical, chemical or biological properties are used as seals. shafts, preferably with irradiated material passing through, by means of two X-ray tubes with irradiated external anodes located in the tube wall, which are at a distance from each other, so that the substance to be irradiated can be introduced into the spacing space, characterized in that to achieve of an elongated radiation field, each tube has a plurality of tubes in the longitudinal direction of the tube having adjacent partial cathodes or cathode threads and that each Tube to enable adaptation to the dimensions of the item to be irradiated independent, containing the partial cathodes or cathode threads and on their end faces with Connecting flanges provided, arranged one behind the other in the longitudinal direction of the tube and structural units connected by seals is constructed. 2. High-performance X-ray tube system according to spoke 1, characterized in that in addition to the the cathodes and the external anodes having structural units with the special structural units electrical connections and the vacuum connections are provided. 3. Plant according to claim 1, characterized in that the structural units both the connection means as well as the electrode elements. 4. Plant according to claim 1 or 2, characterized in that each tube has only one cathode contains, which is arranged in a unit that in the cathode a plurality of similar Cathode filaments parallel to one another and overlapping at an angle to the longitudinal direction of the tube are arranged and that one or two units with the connecting means to this unit are flanged for the tube (Fi g. 5 and 8). 5. Plant according to claim 4, characterized in that the mutual spacing of the cathode heating filaments gradually becomes smaller towards the tube ends (FIG. 5). 6. Plant according to one of claims 1 to 3, characterized in that each tube consists of several There are structural units, each of which has a partial cathode (Figs. 6 and 7). 7. Plant according to claim 1 or 2, characterized in that each tube has a plurality of partial cathodes which are arranged in a structural unit, and that one of each structural unit or two structural units provided with connecting means are flanged (FIG. 1). 8. Plant according to claim 6 or 7, characterized in that one tube (Ib, Ub) has N partial cathodes (2 b, 12 b) and the other tube (la, Ua) N + l partial cathodes (2a, 12a) and that the tubes are arranged in their longitudinal direction to one another such that each of the N cathode (2b, 12b) of the (F i g a tube in the center plane between two cathodes (2 a, 12 a) is of the other tube. 1 and 7 ). 9. Plant according to one of claims 6 to 8, characterized in that the partial cathodes so are arranged that the focal spots generated by them with their long side in the tube longitudinal direction (Figs. 1, 2 and 6). 10. Plant according to one of claims 6 to 8, characterized in that the partial cathodes and the focal spots of each tube produced by these with their longitudinal side inclined to the longitudinal direction of the tube lie and abut or overlap in the direction of their long side (Fig. 4 and 7). 11. Plant according to claim 7, characterized in that the partial cathodes and those of these generated focal spots of each tube alternately perpendicular to the tube longitudinal direction against each other are offset (Fig. 3). 12. Plant according to one of claims 6 to 10, characterized in that the partial cathodes are dimensioned such that the focal spots closer to the tube ends are approximately the same The size of the individual focal spots are more heavily loaded than the inner focal spots. 13. Plant according to one of claims 6 to 10, characterized in that the partial cathodes are designed in such a way that the focal spots closer to the tube ends with the same mean one Surface loading and the same length are wider than the internal focal points. Considered publications:
German Auslegeschrifts No. 1009 325, 117, 1042142; German utility model No. 1846 708;
"Journal for Applied Physics", 1959, issue 4, Pp. 147/148. Legacy Patents Considered:
German Patent No. 1165 769. 1 sheet of drawings 809 538/423 4.68 © Bundesdruckerei Berlin