The embodiments described herein relate to x-ray tubes. In particular, some embodiments described herein relate to non-rectilinear focusing structures.
X-ray tubes are used in a variety of industrial and medical applications. For example, x-ray tubes are employed in medical diagnostic examination, therapeutic radiology, semiconductor fabrication, and material analysis. Regardless of the application, most x-ray tubes operate in a similar fashion. X-rays, which are high frequency electromagnetic radiation, are produced in x-ray tubes by applying an electrical current to a cathode to cause electrons to be emitted from the cathode by thermionic emission. The electrons accelerate towards and then impinge upon an anode. When the electrons impinge upon the anode, the electrons can collide with the anode to produce x-rays. The area on the anode in which the electrons collide is generally known as a focal spot.
The subject matter claimed herein is not limited to embodiments that solve any disadvantages or that operate only in environments such as those described above. Rather, this background is only provided to illustrate one exemplary technology area where some embodiments described herein may be practiced.
This summary is provided to introduce a selection of concepts in a simplified form that are further described below. This summary is not intended to identify key features of the claimed subject matter, nor is it intended to be used as an aid in determining the scope of the claimed subject matter.
An example embodiment includes a cathode assembly. The cathode assembly includes a cathode head, a filament, a focusing structure, and a non-rectilinear focusing aperture. The cathode head defines a filament slot. The filament is positioned in the filament slot that is capable of emitting electrons by thermionic emission. The focusing structure is positioned at least partially between the filament and an anode assembly. The non-rectilinear focusing aperture is defined in the focusing structure. The non-rectilinear focusing aperture is configured to shape an emission profile of electrons emitted by the filament.
Another example embodiment includes a focusing structure. The focusing structure is configured to compensate for a lack of rectilinear conformity of a focal spot produced on an anode by emission of electrons by a filament. The focusing structure includes a surface and a non-rectilinear focusing aperture. The non-rectilinear focusing aperture is defined in the surface. The non-rectilinear focusing aperture includes two linear edges configured to be oriented substantially perpendicular to a longitudinal dimension of the filament and two curved edges configured to be oriented along the longitudinal dimension of the filament.
Another example embodiment includes an x-ray tube. The x-ray tube includes a cathode head, a filament, an anode, a focusing structure, and a non-rectilinear focusing aperture. The cathode head includes a filament slot defined therein in a first direction. The filament that is capable of emitting electrons is positioned within the filament slot such that a longitudinal dimension of the filament is oriented parallel to the first direction. The anode includes a target surface on which a focal spot is produced due to impingement of electrons emitted from a filament. The focusing structure is positioned at least partially between the filament and the anode. The focusing structure is configured to shape an emission profile of electrons emitted by the filament. The non-rectilinear focusing aperture is defined in the focusing structure. The non-rectilinear focusing aperture includes at least one curved edge.
Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by the practice of the invention. The features and advantages of the invention may be realized and obtained by means of the instruments and combinations particularly pointed out in the appended claims. These and other features of the present invention will become more fully apparent from the following description and appended claims, or may be learned by the practice of the invention as set forth hereinafter.
A more particular description of the invention will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. It is appreciated that these drawings depict only example embodiments of the invention and are therefore not to be considered limiting of its scope. These example embodiments will be described and explained with additional specificity and detail through the use of the accompanying drawings in which:
Reference will now be made to figures wherein like structures will be provided with like reference designations. It is understood that the drawings are diagrammatic and schematic representations of exemplary embodiments, and are not necessarily limiting to embodiments described herein nor are they necessarily drawn to scale.
In x-ray tubes, x-rays are generated when the electrons, which have been thermionically emitted from a filament of a cathode assembly, impinge upon an anode. Collisions of the electrons with the anode produce x-rays that may exit the x-ray tube and may be implemented in some application. The area on the anode in which the electrons collide is generally known as a focal spot. The cathode assembly can include a focusing structure. The focusing structure can shape an emission profile of the electrons as the electrons are emitted from the filament. Accordingly, geometry of the focal spot is determined at least partially by geometry of the focusing structure.
In some x-ray tubes, a desirable focal spot is substantially rectilinear. Additionally, it may be desirable to reduce the size of the focal spot. However, in cathode assemblies in which the focusing structure is substantially rectilinear, the focal spot may include a non-rectilinear shape. For example, the focal spots may include focal spot protrusions (hereinafter “spot protrusions”) that extend from a central portion of the focal spot, may include an hourglass shape, or may include an oval shape.
With reference to
With reference to
With reference to
The fourth focal spot 100D is similar to the first focal spot 100A of
Similarly, the third focal spot 100C includes the spot protrusions 106 on a first side 116 of the third focal spot 100C. Additionally, the third focal spot 100C includes the arced contour 110 that includes a generally arced shape on a second side 118 of the third focal spot 100C and permeates throughout the third focal spot 100C.
The third focal spot 100C and the fourth focal spot 100D depict how the misshapen curvature of the focal spots 100C and 100D is related to a focusing geometry. For example, the third focal spot 100C and the fourth focal spot 100D are generated from a cathode assembly including mirror image areas of the cathode assembly. Accordingly, the third focal spot 100C and the fourth focal spot 100D are a mirror image, misshapen curvature that depart from the rectilinear spot approximation 104.
With reference to
Accordingly, some embodiments described herein include focusing structures that define non-rectilinear focusing apertures. The focusing structures and in particular the focusing apertures may shape the electron profile of the electrons which may result in a focal spot that is more rectilinear and may have a smaller area when compared to the focal spots 100.
The x-ray tube 200 includes a window 208. The window 208 is positioned in an opening 210 defined in the vacuum structure 202. The window 208 allows some of the x-rays generated in the x-ray tube 200 to exit the x-ray tube 200. The x-rays that exit the x-ray tube 200 may be directed towards a detector such as a digital detector or photographic film. The window 208 may be composed of beryllium or another suitable material.
The x-ray tube 200 may include one or more electrical conductors 212. The electrical conductors 212 are configured to transfer electrical energy into the vacuum structure 202 and to a cathode assembly 214 (
With reference to
A rotating anode 222 is positioned within the evacuated volume 218 of the x-ray tube 200. The rotating anode 222 may rotate about an axis substantially parallel to the z-axis in an arbitrarily defined coordinate system of
The rotating anode 222 is configured to rotate as an electron beam is emitted from the cathode assembly 214. Accordingly, the target surface 228 is shaped as a ring around the rotating anode 222. The location in which the electron beam impinges on the target surface 228 is referred to herein as a focal spot (not shown in
The rotating anode 222 may be at least partially composed of a thermally conductive material. For example, the conductive material may include tungsten or molybdenum alloy. The target surface 228 may be composed of tungsten or a similar material having a high atomic (“high Z”) number. A material with a high atomic number may be used for the target surface 228 so that the material correspondingly includes electrons in “high” electron shells that may interact with the electron beam to generate x-rays.
With reference to
As the electron beam 230 leaves the filaments 250, a focusing aperture shapes the emission profile of the electrons. For example a focusing aperture can be defined in the cathode head 216, which may shape the emission profile. Additionally or alternatively, the cathode head insert 220 and a focusing aperture defined therein can shape the emission profile of the electrons. The emission profile, and the evolution thereof as the electron beam propagates towards the target surface 228, at least partially determines the shape of the focal spot.
In the depicted x-ray tube 200, the filaments 250 include a helix or spiral structure that extends in a longitudinal direction. In
The x-ray tube 200 of
Additionally, the x-ray tube 200 of
Referring back to
As best illustrated in
The cathode head insert 220 defines two non-rectilinear focusing apertures 400A and 400B (generally, focusing aperture 400 or focusing apertures 400). The focusing apertures 400 are openings defined in the cathode head insert 220 through which an electron beam is emitted. As the electron beam propagates through the focusing apertures 400, an emission profile of the electron beam is shaped.
In the cathode head 216, there are two focusing apertures 400. A first focusing aperture 400A is positioned over a first filament slot 312A. In particular, the first focusing aperture 400A is positioned over a portion of the first filament slot 312A in which a filament may be positioned. Accordingly, the filament in the first filament slot 312A emits an electron beam that propagates through the first focusing aperture 400A. The emission profile of the electron beam is shaped, at least partially, by the first focusing aperture 400A. Likewise, a second focusing aperture 400B is positioned over a portion of a second filament slot 312B in which a filament may be positioned. Thus, the filament in the second filament slot 312B emits an electron beam that propagates through the second focusing aperture 400B. The emission profile of the electron beam is shaped, at least partially, by the second focusing aperture 400B. In typical operation, an electron beam may only be emitted through the first focusing aperture 400A or the second focusing aperture 400B at any time.
The focusing apertures 400 are examples of non-rectilinear focusing apertures. Generally, a non-rectilinear focusing aperture (e.g., 400) includes at least one portion of at least one edge that is arced and/or curved. For example, the first focusing aperture 400A includes two substantially linear edges 406A and 406B and two curved edges 406C and 406D.
As used herein, the term “linear” is meant as a dissimilar characteristic to “curved.” One with skill in the art, with the benefit of this disclosure may appreciate, limitations associated with manufacturing capabilities and that creating an absolutely linear feature (e.g., a radius of curvature equal to infinity) as well as two features being absolutely parallel or perpendicular may be difficult if not impossible. Accordingly, all such relational and geometric characteristics are meant herein to incorporate such manufacturing limitations as well as substantially equivalent structures.
The linear edges 406A and 406B are oriented perpendicular to the first direction 314. The curved edges 406C and 406D are generally oriented along the first direction 314. As used herein, “oriented along a direction” indicates that a linear approximation of the curved edge 406C or 406D that is substantially perpendicular to the linear edges may be parallel to the direction.
In the embodiment of
The second focusing aperture 400B may be similar to the first focusing aperture 400A. For example, in the embodiment of
In the embodiment of
In some embodiments, the curved edges 406C and 406D of the first focusing aperture 400A and the curved edges 440C and 440D may not be substantially parallel. Instead, in these and other embodiments, the radii of curvature 408, 410, 420, 422 may differ in magnitude, which may affect a shape of a focal spot. Moreover, in some embodiments, the focusing apertures 400A and/or 400B may include only one curved edge, three curved edges, or four curved edges. More generally, in some embodiments, the focusing apertures 400A and/or 400B may include one or more edges, and any subset of them may be curved or linear.
The curve of the focusing apertures 400 may be oriented to compensate for a lack of rectilinear conformity of a focal spot. For example, with combined reference to
With reference to
The cathode head insert 500 is configured such that it can be received in a cathode head. The cathode head may be similar to the cathode head 216 discussed herein. However, the cathode head configured to receive the cathode head insert 500 might include a single filament slot, which may be configured to have a single filament positioned therein. When the filament and the cathode head insert 500 are positioned in the cathode head, the filament may be oriented such that the longitudinal dimension of the filament is parallel to a first direction 514. An emission profile of an electron beam emitted by such filament may be shaped by the focusing aperture 502. By shaping the emission profile, the shape of a resulting focal spot may be altered.
The curved edges 506C and 506D may be curved according to radii of curvature 508 and 510, respectively. The radii of curvature 508 and 510 may be substantially equivalent, such that the curved edges 506C and 506D are parallel. For instance, the radii of curvature 508 and 510 may have substantially equivalent magnitudes and may be oriented in substantially the same direction. Alternatively, the radii of curvature 508 and 510 may differ such that at least some portion of the radii of curvature 508 and 510 are not parallel. In some embodiments, the radii of curvature 508 and 510 may be determined in relation to a length 512, an angle 516 (
The focusing aperture 502 includes a general curved profile. The curved profile of the focusing aperture 502 may be oriented and/or shaped to compensate for a lack of rectilinear conformity of a focal spot. For example, with combined reference to
The focusing cup 600 defines another example non-rectilinear focusing aperture 602. The focusing aperture 602 can be implemented to improve rectilinear conformity of a focal spot generated on an anode. For example, the focusing aperture 602 may reduce rounded corners and/or an hourglass shape of the focal spot.
The cathode focusing cup 600 includes a surface 604. The focusing aperture 602 is defined in the surface 604 such that an electron beam may propagate through the surface 604. The focusing aperture 602 includes two linear edges 606A and 606B and two curved edges 606C and 606D. The curved edges 606C and 606D are generally oriented along a first direction 614. The linear edges 606A and 606B are generally oriented perpendicular to the first direction 614. The cathode focusing cup 600 is configured such that it can be positioned in relation to a cathode head. The cathode head may be similar to the cathode head 216 discussed herein. However, the cathode head configured to receive the cathode focusing cup 600 might include a single filament slot, which may be configured to have a filament positioned therein. When the filament and the cathode focusing cup 600 are positioned in the cathode head, the filament may be oriented such that the longitudinal dimension of the filament is parallel to the first direction 614. An emission profile of an electron beam emitted by such filament may be shaped by the focusing aperture 602 as the electron beam propagates though the focusing cup 600. By shaping the emission profile, the shape of a resulting focal spot may be altered.
The curved edges 606C and 606D may be curved according to radii of curvature 608 and 610, respectively. The radii of curvature 608 and 610 have substantially equivalent magnitudes and are oriented in opposite directions. For example, a first radius of curvature 608 is oriented in the positive x-direction and a second radius of curvature 610 is oriented in the negative x-direction.
Alternatively, in some embodiments, the radii of curvature 608 and 610 may have differing magnitudes. For example, the focusing aperture 602 may not be centered on the surface 604 and/or the geometries of the cathode assembly may dictate asymmetric radii of curvature 608 and 610.
The curved edges 606C and 606D are generally oriented along the first direction 614, which corresponds to the longitudinal dimension of a filament, and creates an hourglass profile. The hourglass profile of the focusing aperture 602 may be oriented and/or shaped to compensate for a lack of rectilinear conformity of a focal spot. For example, with combined reference to
The present invention may be embodied in other specific forms. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope.