DE102012203807A1 - X-ray tube for use in mammography system, has units for rotation of sheath surface around cylinder longitudinal axis, and units for simultaneous translational movement of sheath surface in direction of cylinder longitudinal axis - Google Patents

Abstract

The x-ray tube (M2) has a vacuum housing with an exit window integrated for an x-ray radiation, and an electron source for transmission of electrons. A rotating cylindrical anode is provided, in which the electrons are retarded by generating x-ray radiation on a focal spot that is stationary relative to the housing. The units are provided for rotation of a sheath surface around a cylinder longitudinal axis. The units are placed for simultaneous translational movement of the sheath surface in the direction of the cylinder longitudinal axis.

Description

The invention relates to an X-ray tube, comprising a vacuum housing with an exit window for X-radiation, at least one electron source for emitting electrons and a rotating anode, in which the electrons to generate X-radiation on a stationary relative to the housing focal spot, which has a focal path on the anode surface describes, are braked, with means for rotating the mantle surface are provided about a cylinder longitudinal axis. In addition, the invention particularly also relates to a mammography and a CT system with such an X-ray tube.

Such x-ray tubes with cylindrical rotating anodes are well known in the art and are particularly used when relatively high x-ray powers are necessary, such as in mammography and CT or C-arm systems.

Due to the ever-increasing demands on performance and service life, the currently used rotary anodes reach their performance limits. The problem with conventional rotary anodes, for example for angiography or mammography, is that the heat on the anode, which typically has at least one tungsten tooth, is distributed only to a single burner ring. This heats up enormously during a scan and leads to evaporations coupled with deposits in the vacuum housing, which ultimately leads to the destruction of the tube.

It is therefore an object of the invention to improve the X-ray tube of the type mentioned in terms of their performance and their life.

This object is solved by the features of the independent claims. Advantageous developments of the invention are the subject of the subordinate claims.

The inventor has recognized that an improvement of the performance and life of the X-ray tube is possible in that in addition to the purely rotational movement of the anode to impose a - preferably cyclically opposite - translational movement such that the path of the focal spot on the mantle surface the anode is better distributed. While the torus ring surface is known to result from 2 · π · r · h (r = radius of the cylinder, h = height of the focal spot), the complete cylinder surface 2 · π · r · H (H = height of the cylinder jacket with H >> h ) be used. Of course, it is necessary that a cylinder height is used which is much larger than the height of the focal spot.

In this way, therefore, the focal spot - depending on the selected control of the translational and rotational movement of the anode cylinder - be moved to new lanes or at least on a relative to the cylinder circumference much longer path, so that each surface area is much less thermally stressed, more time for Has cooling and thus suffers less surface damage.

For this purpose, for example, a conventional plate assembly can be replaced by an anode cylinder, wherein the cylinder is arranged on a shaft or preferably a spindle. In this case, it is proposed to form the lateral surface completely or at least almost completely from the desired anode material (for example tungsten) or at least to cover the used burning surfaces of the cylinder surface with this anode material.

By specifying fixed rotational and translational speeds, a plurality of combustion ring paths, which are in the form of spiral paths, are possible on the lateral surface. It is also possible to define a plurality of separate webs, which are covered with different anode materials, so that X-ray radiation with different energy spectra can be emitted by appropriate control of the webs.

It is further proposed to use for the movements of the translation (feed speed), for example, a linear actuator or linear actuators. Hereby high resolutions (<1μm) are reproducible and fast feeds (> 1000mm / sec) can be achieved.

According to the invention rotational speed and feed rate can be programmed and controlled application specific.

• – Eine starke Leistungssteigerung der Röntgenröhre erzielt wird und hierdurch die thermische Anodenbelastung durch die Verschmierung auf die komplette Mantelfläche im Vergleich zur bekannten Kreisfläche signifikant reduziert wird und die Brennringfläche durch die Spiralbahn um Faktoren erhöht wird.
• – Die Bewegungen der Anode sehr genau und schnell durchführbar sind.
• – Eine hohe mechanische Stabilität erzielt wird.
• – Die Röntgenröhre flexibel einsetzbar ist und damit eine flexible Hublänge einstellbar ist, die lediglich abhängig von der Spindellänge ist.
• – Die Kühlung der Röhre analog zu heutigen Röhren implementierbar ist.
• – Die Spiralbahnen applikationsspezifisch steuerbar sind, zum Beispiel gekoppelt an die Scandauer etc.
• – Die Rotationsgeschwindigkeit der Anode durch eine erhöhte Translation reduziert werden kann und der einfachere Anodenaufbau Kosten bei der Herstellung reduziert.

The advantage of such an X-ray tube is that:

• - A strong performance increase of the X-ray tube is achieved and thereby the thermal anode load is significantly reduced by the smearing on the entire lateral surface compared to the known circular area and the torch surface is increased by the spiral path by factors.
• - The movements of the anode are very accurate and fast to carry out.
• - A high mechanical stability is achieved.
• - The X-ray tube is flexible and thus a flexible stroke length is adjustable, which is only dependent on the spindle length.
• - The cooling of the tube analogous to today's tubes can be implemented.
• - The spiral webs are application-specific controllable, for example coupled to the scan duration etc.
• The rotational speed of the anode can be reduced by increased translation and the simpler anode construction reduces manufacturing costs.

According to these considerations, the inventor proposes the per se known X-ray tube having a vacuum housing with an X-ray exit window, at least one electron source for emitting electrons and a rotating cylindrical anode in which the electrons generate X-radiation on a relative to the housing stationary focal spot, which describes a focal path on the cylindrical surface surface, are braked, wherein means are provided for rotating the mantle surface about a cylinder longitudinal axis to improve in that in addition means for simultaneous translational displacement of the mantle surface in the direction of the cylinder axis are mounted.

Advantageously, the means for rotation and the simultaneous translational displacement of the mantle surface can be designed so that the resulting path of the focal spot on the mantle surface only after more than simple complete rotation of the mantle surface goes back into itself.

In a particular embodiment, the mantle surface can be mounted longitudinally displaceable on a shaft and have both a separate rotary drive and a linear drive.

Alternatively, however, the mantle surface can also be fixedly connected to a shaft which is driven by a spindle drive at the same time rotationally and translationally.

Again alternatively, the mantle surface can also be arranged on a spindle, which has a linear actuator for longitudinal displacement of the mantle surface.

Furthermore, the mantle surface may be made of a different material than the cylinder at least along the path of the focal spot. As a result, the anode cylinder, for example, from a simple to produce or easily machined material to be machined, for example brass or a multi-layer cylinder made of stainless steel with graphite for heat storage and an anode material, and on the other hand, the path of the focal spot are covered with a desired anode material. Since the penetration depth of the electrons is relatively low, the Bennfleckbahn can also be covered by sputtering or plasma coating with materials that are otherwise difficult to work.

Finally, the mantle surface can also be covered with at least two possible tracks of the focal spot with different anode materials, so that different X-ray energy spectra can be generated by targeted control of the tracks.

A particular embodiment of the X-ray tube according to the invention further provides that the cylindrical anode is designed as a transmission anode and an electron emitter is arranged in the interior of the anode jacket.

It is also favorable if the mantle surface is part of a solid cylinder, since this results in a high heat absorption capacity.

Furthermore, the cylindrical anode may have an integrated axisymmetric flow channel for cooling and the shaft may have an inlet and outlet channel for a cooling medium.

It is also proposed to couple the means for rotational and translational movement of the anode with a programmable control device, so that depending on the current power output of the X-ray tube, so depending on the thermal load in the focal spot, different speeds are driven fast.

In addition to the X-ray tube according to the invention, the inventor also proposes its use in different X-ray systems, for example in a mammography system, a CT system or a C-arm system.

In the following the invention with reference to a preferred embodiment with reference to the figures will be described in more detail, with only the necessary features for understanding the invention features are shown. The following reference symbols are used: 1 : Anode cylinder; 1.1 : Graphite layer; 2 : Spindle / axis of rotation / hollow shaft; 3 : Actuator; 3.1 : translatory drive; 3.2 : rotary drive; 4 : Coolant flow; 5 : Cathode arm; 5.1 : Cathode holder; 7 : Casing; 8th : Deflection coil; B: train; C1: CT system / C-arm system; C2: X-ray tube; C3: detector; C6: housing; C7: C-arm; C8: patient couch; C9: system axis; C10: control and computing system; e ^- : electron beam; K: cathode; M1: mammography system; M2: X-ray tube; M2.1: tubular housing; M2.2: drive; M2.4: window; M3: area detector; M5: pressure plate; M6: housing; M10: Control and computing system; P: patient; Prg ₁ prg _n : computer programs; S: radiation beam; Δh: stroke.

They show in detail:

1 - 3 : Inventive rotating cylinder anode of an X-ray tube in different transverse positions along the axis of rotation;

4 : Schematic representation of a mammography system with an X-ray tube with rotatable and displaceable cylinder anode;

5 : Schematic representation of an anode-cathode arrangement with a displaceable along the axis of rotation anode with coolant flow;

6 : Schematic representation of an X-ray tube with an anode-cathode arrangement in two anode positions with cathode arm on the side of the X-ray window;

7 : Schematic representation of an X-ray tube with an anode-cathode arrangement in two anode positions with cathode arm on the opposite side to the X-ray window;

8th : Schematic representation of an X-ray tube with an anode-cathode arrangement with internal electron emitter and focal spot with X-ray emission on the inside of the shell;

9 : Schematic representation of an X-ray tube with an anode-cathode arrangement with a cylindrical transmission anode and an internal electron emitter;

10 : CT system with X-ray tube according to the invention;

11 : C-arm system with inventive X-ray tube.

In the 1 to 3 is in each case an inventive embodiment of a cylindrical anode 1 in three different longitudinal positions on a spindle 2 shown. Right next to the anode 1 there is a cathode K from the starting an electron beam e ^{- is} accelerated to the cylinder surface of the anode cylinder and there when entering the anode 1 X-ray generated. The resulting beam S is also shown schematically.

Due to the simultaneous rotating drive of the anode cylinder 1 and the transverse drive by the actuator 3 the anode surface, ie the cylinder jacket, is guided past the stationary position of the focal spot, so that the thermal power is smeared over the surface. Due to the simultaneous rotation and transverse movement of the anode cylinder 1 In contrast to a rotating cylinder jacket surface only, a substantially larger area is exposed to heat through the focal spot. A corresponding guidance and coordination or coupling of the rotational and translatory movements can thereby generate one or more tracks B on the cylinder surface, on which the focal spot runs along. In this way, compared to the prior art, a much more intense focal spot, that is, a much more powerful electron beam, can be used for X-ray generation without damaging the surface of the anode.

According to the invention, the mantle surface of the rotating anode cylinder 1 be covered on the tracks B of the focal spot with one or more specific anode materials, so that by appropriate control of the webs each different X-ray energy spectra are emitted.

The combined rotational and linear movement can be effected via a linear actuator or an electric motor or an asynchronous motor, in which a stator generates a rotating field in a known manner.

The 4 shows a schematic representation of a mammography system M1 with a housing M6, to which an X-ray tube M2 according to the invention is attached. Disposed below the X-ray tube M2 are an area detector M3 and an at least height-adjustable pressure plate M5, between which the breast of a patient P is located for radiological scanning. The X-ray tube itself consists of the tube housing M2.1, in which the simultaneously rotatable and transversely displaceable anode cylinder 1 is arranged, which is driven by both the rotation and the transverse movement along the cylinder longitudinal axis by the drive M2.2. The X-ray radiation generated at the anode material leaves the X-ray tube M2 through the window M2.4 as a radiation beam S directed to the detector M3, where the local radiation intensity or the absorption of the radiation through the patient's breast P is measured for imaging. The control of the mammography system M1 and in particular also the control of the X-ray tube M2, in particular also of the drive M2.2, is performed by a control and computing system M10, in which the computer programs Prg ₁ -Prg _{n are} executed during operation.

The 5 shows a schematic representation of an anode-cathode arrangement with a displaceable along the axis of rotation anode 1 with coolant flow 4 through the axis of rotation 2 , The rotation axis 2 is powered by a translatory drive 3.1 in the form of an actuator in the longitudinal direction and by a rotary drive 3.2 - here a stator sleeve - moves in a rotating manner. At the stator is over a cathode arm 5 a cathode holder 5.1 attached, which carries at least one cathode K. Also indicated is the possibility at the cathode holder 5.1 to arrange two cathodes, wherein one of the cathodes is more powerful and produces a relatively large focal spot, while the alternative operable second cathode produces a smaller focal spot for higher resolution. The anode itself is massive in this embodiment.

In the 6 2, there is shown schematically an X-ray tube with an anode-cathode arrangement in two fixed focal spot anode positions shifted relative to each other by Δh. The anodes 1 are designed as a hollow cylinder, wherein through the interior of the hollow cylinder, a coolant flow 4 is present. The relatively massive anode cylinder 1 sits on a hollow shaft 2 trained axis of rotation through the two drives 3.1 and 3.2 is moved linearly and rotationally. The anode-cathode assembly is passed through a vacuum housing 7 completed with respect to the environment, but the beam S generated at the focal point can pass through an X-ray exit window to the outside. The cathode K is located on a cathode holder 5.1 , in turn, through a cathode arm 5 is worn at a fixed position.

The two illustrations - left and right - of the X-ray tube show the stroke Δh of the anode cylinder 1 , To generate a meandering path of the focal spot on the anode surface, the rotation and the linear motion of the anode cylinder are controlled accordingly.

In the 7 is again a schematic representation of an X-ray tube with an anode-cathode arrangement shown in two anode positions, wherein the cathode arm 5 is arranged here on the opposite side to the X-ray window, thereby allowing a somewhat wider beam cone S. Otherwise, this version corresponds to the in the 6 shown X-ray tube.

A further embodiment of the X-ray tube according to the invention is shown in 8th showing an anode-cathode arrangement in which an electron emitter located within the cylinder barrel or cylinder radius is used, starting from which an electron beam e ^- by means of the magnetic field of a dipole deflection coil 8th to a certain fixed point on the inside of the relatively massive trained and rotating and moving along the axis of rotation cylinder jacket of the anode 1 incident and a focal spot with X-ray emission on the inside of the cylinder jacket of the anode 1 generated. In addition, on the outside of the cylinder jacket, a graphite layer 1.1 can be arranged, which serves for the thermal stabilization of the anode.

Finally, the shows 9 Yet another variant of an anode-cathode arrangement or an X-ray tube, in which a cylindrical transmission anode 1 in the case of an internal electron emitter with a cathode K. The structure basically corresponds to that of FIG 8th However, the outer graphite layer is missing and the cylindrical anode is made substantially thinner so that it can act as a transmission anode. Accordingly, the electron beam e ^- enters the anode cylinder from the inside 1 and generates at this focal spot X-ray radiation, which is aligned in accordance with the deceleration of the electrons and their energy in the anode material and by a suitably arranged exit window from the housing 7 can escape. In the two versions of the 8th and 9 The size of the focal spot can be determined by that of the dipole deflection coils 8th generated magnetic field can be influenced in a desired manner.

In the 10 For example, a conventional CT system C1 is shown with a housing C6 and an x-ray tube C2 located therein on a gantry. Again, the X-ray tube C2 is equipped with a rotatable and simultaneously displaceable along its longitudinal axis cylinder anode, so that the necessary in CT high X-ray powers can be achieved without sacrificing the life of the X-ray tube. Opposite the X-ray tube C2 is located in a known manner, a detector C3, with the help of the attenuation of the X-ray radiation in the scanning of the patient P, which is located on a displaceable along the system axis C9 patient bed C8. To control the CT system C1 and in particular also to control the X-ray tube C2, a control and computing system C10 is used, in which the correspondingly coordinated programs Prg ₁ -Prg _{n are} executed.

Finally, the shows 11 also a C-arm system C1 with a housing C6 at which a C-arm C7 is located, the terminal carries a detector C3 and an inventively designed X-ray tube C2. Again, the patient P is for scanning on a patient couch C8, wherein by a control and computing system C10 with the aid of stored therein and in operation programs Prg ₁ -Prg _n the entire C-arm system C1, including the X-ray tube C2 , is controlled.

Overall, an X-ray tube is presented with the invention, which is equipped with a rotatable cylindrical anode, both means for rotating the mantle surface about the cylinder axis of the anode and means for translational displacement of the anode are mounted in the direction of the cylinder axis. According to the invention, such an X-ray tube can be used in particular for a mammography system, a CT system, a C-arm system or a therapeutic radiation system.

Although the invention has been further illustrated and described in detail by the preferred embodiment, the invention is not limited by the disclosed examples, and other variations can be derived therefrom by those skilled in the art without departing from the scope of the invention.

LIST OF REFERENCE NUMBERS

1

anode cylinder

1.1

graphite layer

2

Spindle / rotary axis / hollow shaft

3

actuator

3.1

translatory drive

3.2

rotary drive

4

Coolant flow

5

Kathodenarm

5.1

cathode support

7

casing

8th

deflection coil

B

train

C1

CT system / C-arm system

C2

X-ray tube

C3

detector

C6

casing

C7

C-arm

C8

patient support

C9

system axis

C10

Control and computing system

e ^-

electron beam

K

cathode

M1

mammography system

M2

X-ray tube

M2.1

tube housing

M2.2

drive

M2.4

window

M3

area detector

M5

platen

M6

casing

M10

Control and computing system

P

patient

Prg ₁ prr _n

 computer programs

S

ray beam

.delta.h

stroke

Claims (17)

X-ray tube (C2, M2), with: 1.1. a vacuum housing (M2.1, 7 ) with an exit window (M2.4), which is continuous for X-ray radiation, 1.2. at least one electron source (K) for the emission of electrons (e ^- ) and 1.3. a rotating cylindrical anode ( 1 ), in which the electrons (e ^- ) are generated with the generation of x-ray radiation (S) on a relative to the housing (M2.1, 7 ) fixed focal spot, which describes a focal path (B) on the cylindrical surface, are braked, 1.4. where means ( 3 . 3.2 ) for rotating the mantle surface about a cylinder longitudinal axis ( 2 ) are provided, characterized in that 1.5. Medium ( 3.1 ) for simultaneous translational displacement of the mantle surface in the direction of the cylinder longitudinal axis ( 2 ) are mounted. X-ray tube (C2, M2) according to the preceding claim 1, characterized in that the means ( 3 . 3.2 . 3.1 ) are designed for rotation and for simultaneous translational displacement of the mantle surface in such a way that the resulting web (B) of the focal spot on the mantle surface only reverts to itself after more than simple complete rotation of the mantle surface. X-ray tube (C2, M2) according to one of the preceding claims 1 to 2, characterized in that the mantle surface is longitudinally displaceable on a shaft ( 2 ) and both a separate rotary drive ( 3.2 ) as well as a linear drive ( 3.1 ) having. X-ray tube (C2, M2) according to one of the preceding claims 1 to 2, characterized in that the mantle surface fixed to a shaft ( 2 ) connected by a spindle drive ( 3 ) is driven simultaneously rotationally and translationally. X-ray tube (C2, M2) according to one of the preceding claims 1 to 2, characterized in that the mantle surface on a spindle ( 2 ) which is a linear actuator ( 3.1 ) for longitudinal displacement. X-ray tube (C2, M2) according to one of the preceding claims 1 to 5, characterized in that the mantle surface at least along the path (B) of the focal spot of a material other than the cylinder ( 1 ) consists. X-ray tube (C2, M2) according to one of the preceding claims 1 to 6, characterized in that the mantle surface on at least two possible tracks (B) of the focal spot are covered with different anode materials. X-ray tube (C2, M2) according to one of the preceding claims 1 to 7, characterized in that the means ( 3 . 3.2 . 3.1 ) for the rotational and translational movement of the anode ( 1 ) are coupled to a programmable controller (C10, M10). X-ray tube (C2, M2) according to one of the preceding claims 1 to 8, characterized in that the cylindrical anode ( 1 ) is designed as a transmission anode. X-ray tube (C2, M2) according to one of the preceding claims 1 to 9, characterized in that in the interior of the anode jacket, an electron emitter (K) is arranged, the electron beam (e ^- ) to the inside of the anode ( 1 ) sends. X-ray tube (C2, M2) according to one of the preceding claims 1 to 8, characterized in that the mantle surface is part of a solid cylinder. X-ray tube (C2, M2) according to one of the preceding claims 1 to 11, characterized in that the cylindrical anode ( 1 ) has an integrated axisymmetric flow channel for cooling and the shaft ( 2 ) has a supply and discharge channel for a cooling medium. X-ray tube (C2, M2) according to one of the preceding claims 1 to 12, characterized in that a control means (C10, M10) for the movement of the cylindrical anode (C10, M10) 1 ) which is programmed in such a way that the path (B) of the focal spot on the anode surface runs in a meandering manner during operation. Mammography system (M1) with an X-ray tube (M2) according to one of the preceding claims 1 to 13. CT system (C1) with an X-ray tube (C2) according to one of the preceding claims 1 to 13. C-arm system (C1) with an X-ray tube (C2) according to one of the preceding claims 1 to 13. Therapeutic irradiation system with an x-ray tube according to one of the preceding claims 1 to 13.

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