EP3499545A1 - X-ray tube - Google Patents

Abstract

The invention relates to an X-ray tube with a vacuum housing (1) in which a cathode (2) and an anode (3) with an anode body (4) rotatably mounted about an axis of rotation (A) are arranged, the anode body (4) having an emission region ( 6), which is arranged on an outside of the anode body (4). According to the invention, the anode body (4) comprises an emission body (5) on which the emission area (6) is arranged, the emission body (5) being arranged on the radial outside of the anode body (4) and parallel to the axis of rotation (A) and the emission area (6) facing the axis of rotation (A). Such an X-ray tube has a more compact structure.

Description

The invention relates to an X-ray tube according to the preamble of claim 1.

Such an X-ray tube comprises a vacuum housing in which a cathode and an anode are arranged with a rotatably mounted anode body. The anode body is plate-shaped (anode plate) and rotationally mounted on a rotor shaft (anode shaft). The rotor shaft is rotatably mounted in a liquid metal plain bearing or in a rolling bearing. This ensures a reliable rotation of the anode plate about its axis of rotation (rotation axis). During operation, the cathode is on voltage and generates electrons (e.g., glow emission). The electrons are focused into an electron beam and accelerated in the direction of the anode body. The electron beam is incident in an emission region disposed on an axial outside of the anode body, and generates X-rays. The X-rays exit the vacuum housing via a beam exit window. The rotating anode body is thus struck parallel to its axis of rotation (axis of rotation) by the electron beam, whereas the exit of the generated X-rays in the radial direction, that is perpendicular to the axis of rotation of the anode body takes place.

This proves to be particularly advantageous for use in a computed tomography (CT) device, since the rotational axis of the CT device and the axis of rotation of the anode in the X-ray tube can be aligned in parallel. As a result, the resulting Coriolis forces of the X-ray tube around the isocenter can be avoided. This structure of an X-ray tube requires that the cathode and anode must be arranged one above the other, which limits the length of the X-ray tube or the X-ray source to a reduction of the overall length and therefore of the volume. The size in turn has Significant influence on the weight of the X-ray tube or X-ray source and thus on the dimensioning of the handling mechanism in the CT device.

Currently, the corresponding X-ray systems are dimensioned such that they can carry and handle all common X-ray tubes or X-ray sources.

For all applications outside computed tomography, the influence of the plane of rotation of the anode is significantly weaker or not at all relevant, which is why alternative, more compact concepts can be realized.

Object of the present invention is to provide an X-ray tube of the type mentioned, which is constructed more compact.

The object is achieved by an X-ray tube according to claim 1. Advantageous embodiments of the X-ray tube according to the invention are the subject of further claims.

The X-ray tube according to claim 1 comprises a vacuum housing in which a cathode and an anode are arranged with an about an axis of rotation rotatably mounted anode body, wherein the anode body has an emission region which is disposed on an outer side of the anode body and on the during operation of the X-ray tube Electron beam hits. According to the invention, the anode body comprises an emission body, on which the emission area is arranged, wherein the emission body is arranged on the radial outside of the anode body and parallel to the axis of rotation and the emission area faces the axis of rotation. In the solution according to the invention, the electron beam is thus guided perpendicular to the axis of rotation of the anode body (and thus parallel to its plane of rotation).

According to a particularly advantageous embodiment, the emission region of the anode body is thermally decoupled and between an inside of the vacuum housing and the anode body is a filled with a coolant coolant reservoir is arranged, with which the emission body is thermally coupled (claim 2). The fact that in this embodiment, the emission region is thermally decoupled from the anode body and disposed close to the coolant reservoir, the heat transfer takes place directly in the coolant in the coolant reservoir and thus ensures effective cooling of the emission body (direct cooling of the emission body). A heat flow from the emission body in the anode body thus hardly takes place, so that the anode body is heated significantly less in this cooling than in the previously known X-ray tubes. Since at most only a slight warming of the anode body takes place by heat radiation from the emission body, hardly any heat has to be dissipated via the rotor shaft and the corresponding bearings. This gives a good separation of storage and heat transfer.

Due to the separation of storage and heat transport (heat dissipation), the storage of the anode by the already known hydrodynamic bearing (liquid metal bearings) can be realized. For such storage then the previously required tight tolerances are no longer required.

By separating the functions storage and heat transport and storage are then possible, which previously could not be realized due to the heat dissipation (heat dissipation) on the storage. These include a slide bearing on high-temperature materials (for example, metal against ceramic) or high-temperature resistant and high-speed ball bearings or roller bearings.

Due to the functional separation of storage and heat dissipation can also be a variety of other materials for the Anode body (anode plate) may be used, for example ceramic instead of thermally conductive metals.

According to a particularly advantageous embodiment, the coolant reservoir is arranged on the inside of the vacuum housing (claim 3). The vacuum housing thus at least partially absorbs the heat of the coolant from the coolant reservoir. Since the vacuum housing is arranged in a radiator housing filled with coolant, the heat absorbed by the vacuum housing is cooled by the coolant circulating in the radiator housing. If in individual cases, the circulation of the coolant in the radiator housing should not be auseichend, the coolant in the radiator housing can also be performed via a heat exchanger. The coolant in the coolant reservoir is thus particularly effectively cooled by the coolant circulating in the radiator housing.

Advantageously, the coolant in the coolant reservoir is a liquid metal (claim 4). A suitable liquid metal is a eutectic alloy of gallium (Ga), indium (In) and tin (Sn). Such a GaInSn alloy is e.g. known under the trade name Galinstan® and consists of 68.5 wt .-% gallium and 21.5 wt .-% indium and 10 wt .-% tin.

The solution according to the invention is suitable both for an X-ray tube in which the anode body is arranged rotationally fixed on an anode shaft (claim 5) and for an X-ray tube in which the anode body is formed as an anode ring (claim 6).

An anode body designed as an anode ring (claim 6) has a correspondingly lower mass than an anode plate made of the same material. In addition, eliminates the rotor shaft on which the anode plate is arranged rotationally, which leads to a further reduction of the rotating mass. Thus, during operation, the forces occurring in the movement of the X-ray tube in space are advantageously absorbed. Due to the significantly lower mass or the significantly lower weight, this embodiment is particularly well suited for use in which the X-ray tube and thus the X-ray source tilting and / or rotation is exposed, as is the case for example in computed tomography devices.

In an embodiment of the anode body as the anode ring, a configuration of the x-ray tube in which the anode ring is mounted at a position remote from the axis of rotation is particularly advantageous (claim 7). Thus, the emission body is arranged drehachsenfern.

For certain applications, an embodiment can be selected for the X-ray tube, in which the anode ring is mounted at a position near the axis of rotation (claim 8). Thus, the emission body is arranged drehachsennah.

The electric drive of the anode body is preferably designed as a brushless drive. For this purpose, a predeterminable number of permanent magnets is arranged on a lower side of the anode body. An outer side of the vacuum housing (claim 10) or an inner side of the vacuum housing (claim 11) has a predetermined number of current-carrying windings.

According to a further advantageous embodiment, the X-ray tube is characterized in that the vacuum housing in the region of the coolant reservoir has at least one isolation ring (claim 12).

An embodiment of the x-ray tube in which the anode ring is mounted at a position remote from the axis of rotation (claim 7) is particularly advantageous. Thus, the emission range is arranged drehachsenfern. Characterized in that the inner diameter of the anode ring is removed from the axis of rotation of the anode ring, a range can be selected for the storage position which is thermally well decoupled from the waste heat of the beam generation in the emission area.

For certain applications, an embodiment can be selected for the X-ray tube, in which the anode body is mounted at a position near the axis of rotation (claim 8). Thus, the focal point region is arranged drehachsennah.

In a further advantageous embodiment of the X-ray tube, the storage of the anode body is in a region which is at least partially thermally decoupled from the heat generated in the anode body in a beam generation waste heat (claim 9). In this case, the anode body is preferably mounted at a position remote from the axis of rotation (claim 7).

Hereinafter, a schematically illustrated embodiment of the invention will be explained with reference to the drawing, but without being limited thereto. FIG. 1 shows an embodiment of an X-ray tube in a sectional view.

The in the FIG. 1 illustrated X-ray tube comprises a stationary vacuum housing 1 in which a cathode 2 and an anode 3 are arranged with an about an axis of rotation A (rotation axis) rotatably mounted anode body 4. The anode body 4 is formed in the illustrated embodiment as an anode ring. In the context of the invention, the anode body 4 can also be designed as an anode plate (anode plate). According to the invention, the anode body 4 comprises an emission body 5 on which the emission region 6 is arranged, wherein the emission body 5 is arranged on the radial outer side of the anode body 4 (anode ring) and parallel to the rotation axis A and the emission region 6 faces the rotation axis A.

The vacuum housing 1 of the X-ray tube is arranged in a radiator housing, not shown, in which a cooling medium circulates.

According to the invention, the emission body 5 is arranged perpendicular to the plane of rotation of the anode body 4 and thus extends parallel to the axis of rotation A of the anode body 4.

In order to ensure a trouble-free exit of the X-rays, the emission body 5 on the side facing the cathode 2 has a correspondingly beveled emission region 6.

Characterized in that in the illustrated embodiment, the X-ray tube disposed on the anode ring 4 emissive body 5 is thermally decoupled and on the one hand close to the vacuum housing 1 and on the other hand disposed close to the coolant reservoir 8, the heat transfer takes place directly into the coolant and thus ensures effective cooling of the emission body. 5 A heat flow from the emission body 5 into the anode body 4 thus hardly takes place, so that the anode body 4 is heated significantly less in this heat dissipation than in the previously known x-ray tubes. Since at most only a slight heating of the anode body 4 takes place by heat radiation from the emission body 5, hardly any heat has to be dissipated via the corresponding bearings 7. This gives a separation of storage and heat transport.

At the in FIG. 1 illustrated embodiment of the X-ray tube according to the invention, a coolant reservoir 9 is arranged between an inner side of the vacuum housing 1 and the radial outer side of the anode body 4 (lateral surface of the anode ring 4) in an advantageous manner. By means of this measure, the radial outer surface of the anode ring 4, including the emission body 5, provides reliable cooling of the anode body 4 which is hot due to the jet generation, since the anode body 4 radiates the thermal energy in the direction of the vacuum housing 1 via its radial outer side. Since the vacuum housing 1 is surrounded by a circulating in the radiator housing cooling medium, there is an effective cooling of the emission body 5 and the emission region arranged thereon 6 instead. Advantageously, the coolant reservoir 9 is filled with a liquid metal.

The embodiment shown offers a variety of advantages. For example, e.g. Storage, Ankontaktierung and cooling functionally separated. Furthermore, by additional measures a direct cooling of the emission body 5 in the direction of the vacuum housing 1 (direct cooling) can be realized.

During operation, the cathode 2 is at voltage and emits electrons (not shown). The emitted electrons are accelerated in the direction of the anode ring 4 and generate upon impact with the material of the focal region 5 X-rays (not shown). The X-rays exit via a beam exit window 7 from the vacuum housing 1.

In the illustrated embodiment, the anode ring 4 is mounted via a bearing 7 at a position remote from the axis of rotation. Characterized in that the inner diameter of the anode ring 4 is remote from the axis of rotation A of the anode ring 4, one obtains for the storage of the anode ring 4 in the bearings 7 a region which is thermally well decoupled from the waste heat of the beam generation in the emission region 6.

At the in FIG. 1 illustrated embodiment of the X-ray tube according to the invention, a coolant reservoir 9 is arranged between an inner side of the vacuum housing 1 and an outer side of the anode ring 4. By means of this measure, a reliable cooling of the anode ring 4 that is hot by the jet generation is obtained via the lower outer side of the anode ring 4, including the emission region 6, since the anode ring 4 radiates the thermal energy in the direction of the vacuum housing 1 via its lower outer side. Since the vacuum housing 1 is surrounded by a circulating in the radiator housing cooling medium, an effective cooling of the emission area 6 takes place. Advantageously, the coolant reservoir 8 is filled with a liquid metal.

In the FIG. 1 embodiment shown offers a variety of advantages.

Characterized in that the anode body is formed in the illustrated embodiment as the anode ring 4, the rotating mass is significantly reduced. Furthermore, it is possible to constructively design or dimension the bearings 7 in such a way that an occurring unbalance and a tilting of the anode 3 can be absorbed better than in the known arrangements. Thus, e.g. Coriolis forces are collected at a position that introduces significantly lower loads in the storage due to the leverage laws.

Moreover, in the illustrated X-ray tube storage, Ankontaktierung and cooling are functionally separated from each other.

Due to the advantageous measure to perform the anode body as the anode ring 4, the vacuum housing 1 no longer has to be designed for receiving an anode plate and an anode shaft (rotor shaft). Due to the associated reduction of the rotating mass (no anode plate, no anode wave), the forces on the bearing 7 are reduced accordingly. Furthermore, the required vacuum volume and thus the size of the vacuum housing 1 are significantly reduced. At the same time the assembly is simplified accordingly.

Finally, by further measures a direct heat dissipation of the emission body 5 in the direction of the vacuum housing 1 (direct cooling) can be realized.

The electric drive of the anode ring 4 is preferably designed as a brushless drive, the predetermined number of permanent magnets 10 and a predetermined number of current-carrying windings 11 comprises. The permanent magnets 10 are arranged on a lower side of the anode ring 4, whereas the current-carrying windings 11 are arranged on the adjacent outer side of the vacuum housing 1.

Furthermore, in the illustrated embodiment, the vacuum housing 1 in the region of the coolant reservoir 9 to a predetermined number of insulation rings 12. Through the optionally provided isolation rings 12, a contacting of the anode 3 is obtained via the liquid metal in the coolant reservoir 9.

The number of heat transfers is reduced, since no heat transfer between the focal zone 5 and an existing in known solutions anode disc can take place.

Furthermore, the heat conduction resistance is significantly reduced in the illustrated variant, since no heat conduction takes place between an anode disk and an anode shaft.

Furthermore, in the X-ray tube according to the invention, the good heat dissipation due to the large area can be further improved, for example by constructive enlargement of the outer surface of the vacuum housing 1 by attaching ribs. This can usually be dispensed with a structurally complex intermediate water cooling. This reduces the complexity of the arrangement accordingly, resulting in increased reliability.

Instead of the bearing shown by means of rolling bearings designed as bearing 7 on the inner diameter of the anode ring 4, alternative, not shown in the drawing bearings are possible.

These alternatives include, for example, a bearing on the outer diameter of the anode ring 4 and outside the outer diameter of the emission body 5. Also, a use of the liquid metal in the coolant reservoir 9 for supporting the anode ring 4 can be realized within the scope of the invention.

As a further alternative, a storage on the end faces of the anode ring 4 is possible.

In the context of the invention, the bearing 7 may also be designed as a rolling bearing, sliding bearing or hydrodynamic bearing.

If the bearing 7 is designed as a magnetic bearing without mechanical contact (magnetic levitation bearing) and the Ankontaktierung realized only by liquid metal for cooling and electrical contact, then any occurring imbalance of the anode 3 is not transmitted directly to the vacuum housing 1.

Although the invention has been illustrated and described in detail by a preferred embodiment, the invention is not limited to the embodiment shown in the drawing. Starting from the solution according to the invention, other variants can be derived by the person skilled in the art without departing from the spirit of the invention.

Claims (12)

X-ray tube with a vacuum housing (1) in which a cathode (2) and an anode (3) with an about an axis of rotation (A) rotatably mounted anode body (4) are arranged, wherein the anode body (4) has an emission region (6), which is arranged on an outer side of the anode body (4), characterized in that the anode body (4) comprises an emission body (5) on which the emission region (6) is arranged, wherein the emission body (5) on the radially outer side of the anode body (4) and parallel to the axis of rotation (A) is arranged and the emission region (6) of the axis of rotation (A) facing. X-ray tube according to Claim 1, characterized in that the emission body (5) is thermally decoupled from the anode body (4) and a coolant reservoir (9) filled with a coolant is arranged between an inner side of the vacuum housing (1) and the anode body (4), with which the emission body (5) is thermally coupled. X-ray tube according to claim 2, characterized in that the coolant reservoir (9) on the inside of the vacuum housing (1) is arranged. X-ray tube according to claim 2, characterized in that the coolant is a liquid metal. X-ray tube according to claim 1, characterized in that the anode body is arranged rotationally fixed on an anode shaft. X-ray tube according to claim 1, characterized in that the anode body is designed as an anode ring (4). X-ray tube according to claim 6, characterized in that the anode ring (4) is mounted at a position remote from the axis of rotation. X-ray tube according to claim 6, characterized in that the anode ring (4) is mounted at a position near the axis of rotation. X-ray tube according to claim 1 or 2, characterized in that the bearing of the anode body (4) is located in a region which is at least partially thermally decoupled from the heat generated in the anode body (4) in a beam generation waste heat. X-ray tube according to claim 1, characterized in that on a lower side of the anode body (4) a predeterminable number of permanent magnets (10) and on an outer side of the vacuum housing (1) has a predetermined number of current-carrying windings (11). X-ray tube according to claim 1, characterized in that on a lower side of the anode body (4) a predeterminable number of permanent magnets (10) and on an inner side of the vacuum housing (1) has a predetermined number of current-carrying windings. X-ray tube according to claim 2, characterized in that the vacuum housing (1) in the region of the coolant reservoir (9) has at least one insulating ring (12).

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