The present application is related generally to x-ray sources.
X-ray tubes can include a target material for production of x-rays in response to impinging electrons from an electron emitter. It can be advantageous to have multiple target regions, and the ability to selectively direct the electron beam to each region. For example, a new region of the target can be used when a previously used region has worn out or become too pitted for further use. Another advantage is selecting x-ray energy spectra emitted from different target materials in different target regions. For example, if the target includes a silver region and a gold region, x-rays emitted when the electron beam is directed at the silver region will have a different energy spectra than x-rays emitted when the electron beam is directed at the gold region.
Redirecting the electron beam to different regions of the target can be undesirable due to a different resulting direction or location of emitted x-rays. If x-rays are emitted in one direction while using one region of the anode, then emitted in another direction while using another region of the anode, the x-ray user may need to re-collimate and/or realign the x-ray tube with each different use. This need to re-collimate or realign optics can be undesirable.
Information relevant to attempts to address these problems can be found in U.S. Pat. No. 3,753,020, U.S. Pat. No. 2,298,335, U.S. Pat. No. 2,549,614, U.S. Pat. No. 6,560,315, U.S. Pat. No. 3,900,751, U.S. Pat. No. 7,973,394, and U.S. Pat. No. 5,655,000; U.S. Patent Publication Number US 2011/0135066; and Japan Patent Number JP 3,812,165.
It has been recognized that it would be advantageous to allow use of multiple regions of a target in an x-ray tube, while maintaining a stationary electron beam position (i.e. keeping the electron beam directed in a single direction). The present invention is directed to a x-ray tube and a method that satisfy these needs.
The x-ray tube can comprise an electron emitter, a flexible coupling with a coupling axis, and a window hermetically sealed to an enclosure. An anode can be attached to the flexible coupling. The electron emitter can be configured to emit electrons to the anode. The anode can include a target configured to produce x-rays in response to impinging electrons from the electron emitter. The anode can be spaced-apart from the window by a gap through which the x-rays emitted from the target travel to the window. The anode can be selectively tiltable or deflectable in all directions in a 360 degree circle around the coupling axis to selectively position a region of the target material in the electron beam.
The method, of utilizing different regions of an x-ray tube target, can comprise (a) disposing a target in an electron beam, the target being disposed at an end of an anode and configured to produce x-rays in response to impinging electrons; (b) emitting x-rays from the target to an x-ray tube window through a gap between the target and the window; and (c) deflecting or tilting the anode in all directions in a 360 degree circle to selectively position a region of the target in the electron beam.
As illustrated in
An anode 11 can be attached to the flexible coupling 4. The anode 11 can extend through a core of the flexible coupling 4. A first end 4a of the flexible coupling 4 can be attached to or hermetically sealed to the anode 11 and a second end 4b of the flexible coupling 4 can be hermetically sealed to the enclosure 1. The coupling 4 can have a top face 4t at the first end 4a.
The coupling axis 14 is an imaginary straight reference line. The coupling axis 14 can be disposed at a center of individual coupling rings (if the coupling is a bellows); can extend from the first end 4a to the second end 4b of the coupling 4; and can be disposed at a center of the top face 4t and perpendicular to a plane of the top face 4t. The coupling axis 14 is defined with the coupling 4 in an unflexed condition. Thus, the coupling axis 14 will not bend or change position as the coupling 4 is flexed.
The electron emitter 3 can be configured to emit electrons 7 from the electron emitter 3 to the anode 11. The electron emitter 3 can be part of or can be attached to a cathode 2. The electron emitter 3 can emit electrons to the anode 11 due to a high electron emitter 3 temperature and a large voltage differential between the electron emitter 3 and the anode 11. An electron beam axis 6 can be an approximate center of the electron beam. The anode 11 can include a target material configured to produce x-rays 8 in response to impinging electrons from the electron emitter 3.
The anode 11 can be spaced-apart from the window 5 by a gap 12 through which the x-rays 8 emitted from the target travel to the window 5. The gap 12 can be a hollow portion of the enclosure between the anode 11 and the window 5. The gap 12 can be an evacuated inner portion of the enclosure 1.
The anode 11 of x-ray tube 10 in
The anode 11 can include a longitudinal anode axis 13. The anode axis 13 can extend from an anode face on which the target material is deposited (target face 11t) to an opposite, outward face 110 or end. The target face lit can be tilted at an acute angle A1 with respect to the electron beam axis 6. The target face lit can be tilted towards the window 5 to allow x-rays 8 emitted from the target to transmit through the window 5. The target material can face the electron emitter 3 and the window 5 in all directions in which the anode 11 is tilted.
On x-ray tube 10 in
As shown in
The anode 11 of x-ray tube 40 in
One device or means for tilting the anode 11 in different directions is shown on x-ray tube 70 in
A ring support 71 can be attached to the enclosure 1. The ring 73 can rotate around the ring support 71. The ring support 71 can include a channel and the ring 73 can include a mating channel. A fastening device 72 can be used to attach the ring 73 to the ring support, and allow the ring 73 to rotate around the ring support 71. Examples of possible fastening devices 72 include a snap ring, ball bearings, or an e clip. Lubricant in the channels can minimize friction as the ring 73 rotates around the ring support 71.
In one embodiment, the cavity 74 can include a slanted face 79 facing an end portion of the anode 11. The slanted face 79 can be tilted at an acute angle with respect to the coupling axis 14. The slanted face 79 can cause the anode 11 to tilt at the acute angle. Use of this design can cause the anode 11 to tilt at a single acute angle as this acute angle orbits in a 360 degree circle 9 or 16 around the coupling axis 14.
The ring 73 can include a device 76, such as a handle on the ring 73 configured to allow an operator to rotate the ring 73 to different positions, or an electromechanical mechanism configured to rotate the ring 73 to different positions based on input from an operator. The ring 73 can have gears that intermesh with a gear drive mechanism for rotating the ring 73. A force on the device 76 out 79 of the page, tangential to a side 78 of the ring 73, can cause the ring 73 to rotate clockwise with respect to a top face 75 of the ring 73. Continued force on the device 76 tangential to a side 78 of the ring 73 can cause the acute angle A1 between the anode axis 13 and the coupling axis 14 to orbit around the coupling axis 14 to a different position, such as for example the position shown in
A force on the device 76 into 77 the page, tangential to a side 78 of the ring 73, can cause the ring 73 to rotate counter-clockwise with respect to a top face 75 of x-ray tube 70. Continued force tangential to a side 78 of the ring 73 can cause the acute angle A1 to orbit around the coupling axis 14 to a different position. Thus, as the ring 73 rotates, the acute angle A1 can orbit in a 360 degree circle 16 (counter-clockwise with respect to a top face 75 of x-ray tube 70) around the coupling axis 14.
Use of the ring can keep the anode 11 tilted at a single angle A1 regardless of the direction of tilt. Thus, the anode 11 can maintain substantially the same angle A1 with respect to the coupling axis 14 while the acute angle A1 orbits in a 360 degree circle 9 or 16 around the coupling axis 6. The amount of tilt can be altered by the extent of eccentricity of the cavity 74 and/or by the angle of the slanted face 79.
The ring 73 can be a rotational means for applying force F to the anode 11 from any direction in a 360 degree circle 9 or 16 around and perpendicular with the coupling axis 14. The force F from the rotational means can be capable of causing the anode 11 to tilt at the acute angle A1 in any direction in the 360 degree circle 9 or 16.
Although the ring 73 and other associated devices were shown on a side-window 5 type design, use of the ring and associated devices may be used on the embodiments shown in
As mentioned above in reference to x-ray tube 10 in
The anode 11 can be positioned with the electron beam axis 6 impinging on one non-central region 15 of the target; then the anode 11 can be deflected to cause the electron beam axis 6 to impinge on a different non-central region 15 of the target. On x-ray tube 90 in
Tilting the anode rather than deflecting can be preferable due to decreased stress on the flexible coupling 4. Tilting the flexible coupling 4 can cause a flexure in only one direction. Deflecting, without tilting, as shown in
The design of
One device or means for deflecting the anode 11 in different directions is shown on x-ray tube 100 in
The above discussion regarding a device 76 to rotate the ring 73 is incorporated herein by reference with the exception of the following modified section. A force on the device 76 out 79 of the page, tangential to a side 78 of the ring 73, can cause the ring 73 to rotate clockwise with respect to a top face 75 of the ring 73. Continued force on the device 76 tangential to a side 78 of the ring 73 can cause the anode axis 13 to orbit around the coupling axis 14 to a different position, or to orbit in a 360 degree circle 9 (clockwise with respect to a top face 75 of x-ray tube 70) around the electron beam axis 6. A force on the device 76 into 77 the page, tangential to a side 78 of the ring 73, can cause the ring 73 to rotate counter-clockwise with respect to a top face 75 of x-ray tube 70. Continued force tangential to a side 78 of the ring 73 can cause the anode axis 13 to orbit around the coupling axis 14 to a different position. Thus, as the ring 73 rotates, the anode axis 13 can orbit in a 360 degree circle 16 (counter-clockwise with respect to a top face 75 of x-ray tube 70) around the coupling axis 14.
The designs in
Shown in
Use of various target regions 15 has been discussed. There are multiple advantages to having an ability to use different regions 15 of the target (i.e.
allowing the electron beam 7 to impinge on different regions 15 of the target at different times). One advantage is to allow use of a new region 15 of the target when a previously used region 15 has worn out or become too pitted for further use.
Another advantage is to allow for different x-ray energy spectra, which can be done by use of different target materials in different target regions 15. Shown in
X-ray tube users sometimes want to temporarily stop the emission of x-rays, such as when the user is moving from one location to another or recording data. Temporarily shutting off the x-ray tube can be undesirable—subsequent x-ray tube start up can take time and x-ray emission may differ due to changes in temperature or electronics of the unit. Shown in in
The target well region 15w can be a cavity or a well. The target well region 15w can be made of the same material as the anode 11—no additional material added. Alternatively, the target well region 15w can have an additional material added. The additional material added can be the same as another region. Whether to add additional target material to the target well region 15w can depend on the effect of x-rays 8 emitted from the target well region 15w on other x-ray tube components and on manufacturability considerations.
X-rays 8 emitted from the target well region 15w can be blocked by walls 11w of the cavity or well. By tilting or deflecting the anode 11 to direct the electron beam 7 toward the target well region 15t, the x-ray tube can remain powered on without emission of x-rays 8. As shown in
In various embodiments described herein, various regions 15 of the target can be used while maintaining a stationary electron beam 7 position. The electron beam 7 need not shift to impinge on different target regions 15. This can allow the x-ray user to change to a different target region 15 without the need to re-collimate and/or realign the x-ray tube with each different use.
A method of utilizing different regions 15 of an x-ray tube target can comprise (1) disposing a target in an electron beam 7, the target being disposed on a target face lit end of an anode 11 and configured to produce x-rays 8 in response to impinging electrons 7; (2) emitting x-rays 8 from the target to an x-ray tube window 5 through a gap 12 between the target and the window 5; and (3) deflecting or tilting the anode 11 in all directions in a 360 degree circle 9 or 16 to selectively position a region 15 of the target in the electron beam 7.
This claims priority to U.S. Provisional Patent Application No. 61/772,411, filed on Mar. 4, 2013, and to U.S. Provisional Patent Application No. 61/814,036, filed on Apr. 19, 2013, which are hereby incorporated herein by reference in their entirety.
Number | Date | Country | |
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61772411 | Mar 2013 | US | |
61814036 | Apr 2013 | US |