1. The Field of the Invention
The present invention generally relates to rotating machinery. In particular, some example embodiments relate to an x-ray tube bearing assembly with a resonant frequency tuned to enable operation at one or more desired operating frequencies.
2. The Related Technology
X-ray producing devices are extremely valuable tools that are used in a wide variety of applications, both medical and industrial. For example, such equipment is commonly employed in areas such as medical diagnostic examination and therapeutic radiology, semiconductor manufacture and fabrication, and materials analysis.
Regardless of the applications in which they are employed, x-ray devices operate in similar fashion. In general, x-rays are produced when electrons are emitted, accelerated, and then impinged upon a material of a particular composition. This process typically takes place within an evacuated enclosure of an x-ray tube. Disposed within the evacuated enclosure is a cathode, or electron source, and an anode oriented to receive electrons emitted by the cathode. The anode can be stationary within the tube, or can be in the form of a rotating annular disk that is mounted to a rotor shaft which, in turn, is rotatably supported by a bearing assembly. The evacuated enclosure is typically contained within an outer housing, which also serves as a reservoir for a cooling fluid, such as dielectric oil, that serves both to cool the x-ray tube and to provide electrical isolation between the tube and the outer housing.
In operation, an electric current is supplied to a filament portion of the cathode, which causes a cloud of electrons to be emitted via a process known as thermionic emission. A high voltage potential is placed between the cathode and anode to cause the cloud of electrons to form a stream and accelerate toward a focal spot disposed on a target surface of the anode. Upon striking the target surface, some of the kinetic energy of the electrons is released in the form of electromagnetic radiation of very high frequency, i.e., x-rays. The specific frequency of the x-rays produced depends in large part on the type of material used to form the anode target surface. Target surface materials with high atomic numbers (“Z numbers”) are typically employed. The target surface of the anode is oriented so that the x-rays are emitted as a beam through windows defined in the evacuated enclosure and the outer housing. The emitted x-ray beam is then directed toward an x-ray subject, such as a medical patient, so as to produce an x-ray image.
In x-ray devices that include a rotating anode, the intensity of the emitted x-ray beam depends in part on the rotational frequency of the anode, usually expressed in Hertz (“Hz”). To obtain high x-ray beam intensities required for certain applications, such as in high-speed CT scanners, the rotating anode may be required to operate at frequencies as high as 150 Hz or higher, for instance.
Regardless of the actual or desired operating frequency, all rotating anode designs are characterized by one or more resonant frequencies. Vibrations of the rotating anode caused by imbalances in the anode or other rotating components reaches a maximum when the anode is operated at or near a characteristic resonant frequency. Although rotating anodes may briefly rotate at a resonant frequency during acceleration to an operating frequency above or below the resonant frequency, maximized vibration levels at the resonant frequency prevent prolonged operation at the resonant frequency.
In the case of conventional x-ray devices, the characteristic resonant frequency of a rotating anode is measured after manufacture of the rotating anode and bearing assembly has been completed. Once the resonant frequency has been determined, the manufacturer typically specifies one or more permitted operating frequencies. A user is thus constrained to operate at the operating frequencies specified by the manufacturer without regard to the operating frequencies that may be desired by the user to achieve a particular x-ray beam intensity.
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.
In general, example embodiments of the invention relate to an x-ray tube with a tuned bearing assembly and/or tuned anode assembly.
In one example embodiment, an x-ray tube comprises a rotating anode configured to rotate at an operating frequency, and a bearing assembly configured to rotatably support the rotating anode and tuned to a resonant frequency that is different than the operating frequency.
In another example embodiment, an x-ray tube comprises an evacuated enclosure, an electron source disposed within the evacuated enclosure, and an anode assembly at least partially disposed in the evacuated enclosure. The anode assembly is tuned to a resonant frequency different than an operating frequency. The anode assembly includes an anode positioned to receive electrons emitted by the electron source, a bearing assembly rotatably supporting the anode, and a rotor sleeve to which the anode and a portion of the bearing assembly are coupled. The rotor sleeve is responsive to applied electromagnetic fields such that a rotation motion is imparted to the anode.
In yet another example embodiment, a method of manufacturing a bearing assembly comprises selecting a desired operating frequency for the bearing assembly and tuning the bearing assembly to a predetermined resonant frequency that does not materially impair operation of the bearing assembly at the desired operating frequency.
These and other aspects of example embodiments of the invention will become more fully apparent from the following description and appended claims.
To further clarify various aspects of some embodiments of the present invention, 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 typical embodiments of the invention and are therefore not to be considered limiting of its scope. The invention 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 the figures wherein like structures will be provided with like reference designations. It is understood that the figures are diagrammatic and schematic representations of some embodiments of the invention, and are not limiting of the present invention, nor are they necessarily drawn to scale.
Reference is first made to
Disposed within the evacuated enclosure 104 are an anode 108 and a cathode 110. The anode 108 is spaced apart from and oppositely disposed to the cathode 110, and may be at least partially composed of a thermally conductive material such as copper or a molybdenum alloy. The anode 108 and cathode 110 are connected in an electrical circuit that allows for the application of a high voltage potential between the anode 108 and the cathode 110. The cathode 110 includes a filament 112 that is connected to an appropriate power source and, during operation, an electrical current is passed through the filament 112 to cause electrons, designated at 114, to be emitted from the cathode 110 by thermionic emission. The application of a high voltage differential between the anode 108 and the cathode 110 then causes the electrons 114 to accelerate from the cathode filament 112 toward a focal track 116 that is positioned on a target surface 118 of the anode 108. The focal track 116 is typically composed of tungsten or other material(s) having a high atomic (“high Z”) number. As the electrons 114 accelerate, they gain a substantial amount of kinetic energy, and upon striking the target material on the focal track 116, some of this kinetic energy is converted into electromagnetic waves of very high frequency, i.e., x-rays 120, shown in
The focal track 116 is oriented so that emitted x-rays are directed toward an evacuated enclosure window 122. The evacuated enclosure window 122 is comprised of an x-ray transmissive material that is positioned within a port defined in a wall of the evacuated enclosure 104 at a point aligned with the focal track 116. An outer housing window 124 is disposed so as to be at least partially aligned with the evacuated enclosure window 122. The outer housing window 124 is similarly comprised of an x-ray transmissive material and is disposed in a port defined in a wall of the outer housing 102. The x-rays 120 that emanate from the evacuated enclosure 104 and pass through the outer housing window 124 may do so substantially as a conically diverging beam, the path of which is generally indicated at 126 in
Additionally, the anode 108 includes a substrate 128, comprising graphite in some embodiments. The anode 108 is part of an anode assembly 130 that further includes an anode support assembly 132. The anode 108 is supported by the anode support assembly 132, which generally comprises a tuned bearing assembly 134 including a bearing housing 136, and a rotor sleeve 138. The tuned bearing assembly 134 is at least partially disposed in the evacuated enclosure 104. The bearing housing 136 is fixedly secured to a portion of the evacuated enclosure 104 such that the anode 108 is rotatably supported within the evacuated enclosure 104 by the tuned bearing assembly 134, such that the anode 108 is able to rotate with respect to the bearing housing 136. A stator 140 is disposed about the rotor sleeve 138 and utilizes rotational electromagnetic fields to cause the rotor sleeve 138 to rotate. The rotor sleeve 138 is attached to the anode 108, thereby providing the needed rotation of the anode 108 during operation of the x-ray tube 100.
While a specific x-ray tube 100 configuration has been disclosed, embodiments of the present invention can be practiced with x-ray tubes having different configurations from that described herein.
Reference is now made to
In
As will be appreciated by those skilled in the art, the rotational speed of the gantry 202, and consequently that of the x-ray tube 100, can vary depending on the CT scanner 200 application. Furthermore, the intensity of the x-ray beam in beam path 126 required to obtain a desired image quality depends on the rotational speed of the x-ray tube 100 on the gantry 202. In particular, higher x-ray beam intensities are typically required for higher rotational speeds of the x-ray tube 100.
One manner for increasing the intensity of the x-ray beam in beam path 126 is to rotate the anode 108 at a relatively higher frequency and increase the density of the electrons 114 emitted by and accelerated from the cathode 110 to the anode 108. For instance, x-ray tubes on gantries rotating at about two RPMs may include an anode operating at approximately 110 Hz, while x-ray tubes on gantries rotating faster than two RPMs may require an anode with a relatively higher operating frequency, such as 150 Hz, to obtain images of similar quality. In some instances, however, characteristic resonant frequencies associated with components such as the bearing assembly can prevent operation of the anode at the desired operating frequency, whatever it may be.
With additional reference to
As shown, the tuned bearing assembly 300 includes a shaft 302, which may comprise high-temperature tool steel, tungsten tool steel, molybdenum tool steel, ceramic, or other hard material. The shaft 302 includes a rotor hub 303 and defines a lower inner race 304 and upper inner race 306 disposed circumferentially about shaft 302. Lower and upper inner races 304 and 306, in turn, can include bearing surfaces that may be coated with a solid metal lubricant or other suitable lubricant.
Tuned bearing assembly 300 additionally includes lower bearing ring 308 and upper bearing ring 310 disposed about shaft 302 and separated by a spacer 312. While other spacer arrangements could be used, in the illustrated example an “O”-shaped spacer 312 is used. Alternately or additionally, a tubular-shaped spacer and/or “C”-shaped spacer can be used alone or in combination. Lower bearing ring 308 defines lower outer race 314 and upper bearing ring 310 defines upper outer race 316. Each of the lower outer race 314 and upper outer race 316 can include respective bearing surfaces that may be coated with a solid metal lubricant or other suitable lubricant. As in the case of shaft 302, lower and upper bearing rings 308 and 310, and spacer 312, may comprise high temperature tool steel or other suitable material(s). However, it will be appreciated that various other materials may be employed for the shaft 302, lower and upper bearing rings 308 and 310, and/or spacer 312 consistent with a desired application.
With more specific reference now to lower and upper bearing rings 308 and 310, and spacer 312, additional details are provided regarding the arrangement of such components with respect to shaft 302. In particular, lower bearing ring 308, upper bearing ring 310, and spacer 312, are disposed about shaft 302 so that lower outer race 314 and upper outer race 316 are substantially aligned with, respectively, lower inner race 304 and upper inner race 306 defined by shaft 302. In this way, lower outer race 314 and upper outer race 316 cooperate with, respectively, lower inner race 304 and upper inner race 306 to confine a lower ball set 318 and an upper ball set 320, respectively. Both lower ball set 318 and upper ball set 320 comprise respective pluralities of balls. In general, lower ball set 318 and upper ball set 320 cooperate to facilitate high-speed rotary motion of shaft 302, and thus of anode 108.
It will be appreciated that variables such as the number and diameter of balls in each of the lower ball set 318 and upper ball set 320 may be varied as required to suit a particular application. Further, in some embodiments of the invention, each of the balls in lower ball set 318 and upper ball set 320 are coated with a solid metal lubricant or other suitable material.
Directing continuing attention to
In some embodiments, a plurality of bolts or other fasteners 323 serve to attach lower bearing ring 308 to bearing housing 322, thereby retaining upper bearing ring 310, spacer 312, and shaft 302 in position within bearing housing 322. It will be appreciated however, that various other fasteners may alternately or additionally be employed. Alternately, such fasteners may be eliminated and one or more of the aforementioned components attached to bearing housing 322 by way of processes including, but not limited to, welding and brazing.
The positioning of bearing rings 308 and 310, as well as shaft 302, within bearing housing 322 is facilitated by the spacer 312, which serves to, among other things, properly orient lower and upper bearing rings 308 and 310 with respect to shaft 302 and to properly orient lower outer race 314 and upper outer race 316 with respect to lower inner race 304 and upper inner race 306. Spacer 312, lower and upper bearing rings 308 and 310, and shaft 302 are securely retained in bearing housing 322 by way of fasteners 323 which secure lower bearing ring 308 to bearing housing 322, thereby substantially foreclosing axial movement of spacer 312 and lower and upper bearing rings 308 and 310.
The rotor hub 303 of the shaft 302 is configured to interconnect the shaft 302 with an anode, such as anode 108 of
Directing continuing attention to
As mentioned above, a stator, such as stator 140 of
Imbalances in the shaft 302, anode (not shown), and/or other rotating components coupled to the shaft 302 cause vibrations in the anode that may negatively affect x-ray tube operation and which increase as rotational frequency approaches a resonant frequency. The resonant frequency of the bearing assembly and/or anode depends on various factors, including the geometries of the moving and stationary components, the materials from which the components are made, the masses of the components, the centers of gravity of the components, the bulk moduli of the components, and the like.
In conventional x-ray tubes, the manufacturer determines one or more operating frequencies for the anode, based at least in part on the characteristic resonant frequency of the bearing assembly. In conventional x-ray tube designs, for instance, the bearing assembly may have a resonant frequency at 70-80 Hz. Upon determining the resonant frequency, the manufacturer may define one or more operating frequencies for the x-ray tube, such as a low-speed operating frequency below the resonant frequency and a high-speed operating frequency above the resonant frequency. The manufacturer selects the low-speed and high-speed operating frequencies such that prolonged operation at the resonant frequency is avoided.
In some instances, the materials and geometries of the bearing assembly and/or anode in a particular x-ray tube design result in a resonant frequency that may prevent operation at, or near, a desired operating frequency. For example, in the absence of a tuned bearing assembly 134 (of
According to embodiments of the invention, however, the bearing assembly 300 is tuned to a resonant frequency that does not prohibit operation at, or near, the desired operating frequency. In contrast with typical processes that involve manufacturing a bearing assembly, determining its resonant frequency, and specifying one or more operating frequencies that avoid operation near the resonant frequency, some embodiments of the invention may involve selecting one or more desired operating frequencies and then tuning the bearing assembly to a resonant frequency that does not materially impair operation of the device at the desired operating frequency(ies).
As used herein, a device, assembly, or component is “tuned” if affirmative steps have been taken or implemented on one or more components of the device, assembly, or component to produce a physical configuration having one or more predetermined characteristic resonant frequencies. An x-ray device can be tuned by, e.g. adding material to or removing material from one or more moving or stationary components of the x-ray device; replacing one or more components comprising a first material with one or more components comprising a second material different from the first material; modifying the geometry of the one or more components of the x-ray device, or the like or any combination thereof The characteristic resonant frequency(ies) to which the x-ray device is tuned can be above, below, and/or between the desired operating frequency(ies). Further, embodiments of the invention include x-ray devices and/or other components that are tuned and installed as brand-new devices as well as x-ray devices and/or other components that are removed from a larger assembly, tuned, and re-installed after market.
In some embodiments, an operating frequency of 150 Hz is desired, and the tuned bearing assembly 300 is provided that has been tuned to a resonant frequency of approximately 130 Hz, allowing the anode to be rotated at a desired operating frequency of 150 Hz. Alternately, the tuned bearing assembly 300 can be tuned to different resonant frequencies to allow the anode to be rotated at different desired operating frequencies.
In the embodiment of
In the examples of
Alternately or additionally, tuning can be accomplished by selecting appropriate materials for the shaft 302/302A. For example, the shaft 302/302A may comprise high-temperature tool steel in some embodiments, having a bulk modulus of approximately 35 million psi. Alternately, a shaft characterized by a single diameter substantially along the entire length of the shaft, formed from a material with a lower modulus of about 10 million, for example, could alternately be implemented to tune the resonant frequency of a tuned bearing assembly according to embodiments of the invention.
Alternately or additionally, tuning can be accomplished by modifying one or more components of the tuned bearing assembly 300 and/or in a corresponding anode assembly using one or more of the affirmative steps described below. For instance, the resonant frequency can be tuned by modifying one or more of the shaft 302, lower bearing ring 308, upper bearing ring 310, spacer 312, bearing housing 322, anode 108 (
With reference now to
As can be seen from the graph of
With additional reference to
The method 700 begins by selecting 702 one or more desired operating frequencies for a bearing assembly. The desired operating frequency(ies) of the bearing assembly may depend on, for example, an x-ray intensity that an anode rotatably supported by the bearing assembly is desired to produce. In some instances, the bearing assembly may already exist in a default configuration having one or more characteristic resonant frequencies that would materially impair operation of the bearing assembly at the desired operating frequency. In some embodiments, the desired operating frequency is 150 Hz and the default configuration of the bearing assembly has a characteristic resonant frequency that prevents operation at 150 Hz.
After the desired operating frequency(ies) has been selected, the method 700 continues by tuning 704 the bearing assembly to one or more predetermined characteristic resonant frequencies that do not materially impair operation of the bearing assembly at the desired operating frequency(ies). In the embodiments of
More generally, tuning 704 a device, assembly, or component may include taking one or more affirmative steps to a produce a device, assembly, or component with a physical configuration having the one or more predetermined characteristic resonant frequencies that do not prevent operation at the desired operating frequency(ies). The one or more affirmative steps can be taken on one or more moving or stationary components of the device, assembly, or component and can include, for example: adding material to one or more components, removing material from one or more components, modifying the geometry of one or more components, replacing one or more components made from a first material with one or more components made from a second material different from the first material, changing the mass of one or more components, changing the center of gravity of one or more components, or the like or any combination thereof.
In some embodiments of the invention, producing the desired physical configuration, e.g. the physical configuration having the one or more predetermined characteristic resonant frequencies, involves selecting one or more components of the device, assembly, or component to modify using the one or more affirmative steps and calculating, using the desired operating frequency(ies), a potential modification to make on the one or more components that will produce the desired physical configuration. Alternately or additionally, producing the desired physical configuration can involve an iterative process of modifying the one or more components and then testing the device, assembly or component until one or more characteristic resonant frequencies of the device, assembly or component reach the predetermined characteristic resonant frequencies or are within a predetermined range of the predetermined characteristic resonant frequencies.
The present invention may be embodied in other specific forms without departing from its spirit or essential characteristics. 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.
Number | Name | Date | Kind |
---|---|---|---|
2648025 | Agule | Aug 1953 | A |
3619696 | De Lucia | Nov 1971 | A |
4679220 | Ono | Jul 1987 | A |
Number | Date | Country |
---|---|---|
0 189 297 | Jul 1986 | EP |
2006103006 | Oct 2006 | WO |
2008058267 | May 2008 | WO |
Number | Date | Country | |
---|---|---|---|
20100322385 A1 | Dec 2010 | US |