The present application is related generally to electron emitters in x-ray tubes.
A critical component of x-ray tubes is the electron emitter, such as a filament for example. A solid support for the electron emitter can be important because motion of such support can cause the electron emitter to bend or distort. Bending or distortion of the electron emitter during use can result in early electron emitter failure, which can cause the x-ray tube to fail. The cost of the electron emitter support, both material and manufacturing cost, can be important for a low x-ray tube cost. Precise and repeatable placement of the electron emitter in the x-ray tube during manufacturing can be important to ensure consistency of x-ray output between different units of a single x-ray tube model. Long x-ray tube life also can be important.
It has been recognized that it would be advantageous to have an x-ray tube with a sturdy, low cost electron emitter support that can be placed precisely and repeatedly in the correct location in manufactured x-ray tubes. It has been recognized that long x-ray tube life can be important. The present invention is directed to various embodiments of x-ray tubes with electron emitter supports that satisfy these needs. Each embodiment may satisfy one, some, or all of these needs. The present invention is also directed to a method of evacuating and sealing an x-ray tube that satisfies one, some, or all of these needs.
The x-ray tube comprises an evacuated, electrically-insulative enclosure with a cathode and an anode at opposite ends thereof. Dual, electrically-conductive emitter tubes can extend from the cathode towards the anode. The emitter tubes can comprise an inner tube and an outer tube with the inner tube disposed at least partially within the outer tube. The inner and outer tubes can have opposite ends comprising a near end associated with the cathode and a far end disposed closer to the anode. There can be a first gap between the far end of the outer tube and the anode and a second gap between the far end of the inner tube and the anode. An electron emitter can be coupled between the far end of the inner tube and the far end of the outer tube. The inner and outer tubes can be electrically isolated from one another except for the electron emitter.
The method, of evacuating and sealing an x-ray tube, can comprise some or all of the following steps:
As illustrated in
The inner tube 14i and the outer tube 14o can have or share a common central region 8. The inner tube 14i and the outer tube 14o can be concentric. The inner tube 14i and the outer tube 14o can have a common longitudinal axis 17. Alternatively, there can be some offset between a longitudinal axis 17 of the inner tube 14i with respect to a longitudinal axis 17 of the outer tube 14o. It can be beneficial to align the longitudinal axis 17 of both of the emitter tubes 14 with each other to allow sufficient gap 7 between the inner tube 14i and the outer tube 14o for voltage isolation (to force electrical current to flow through the filament 18 rather than from direct contact between the inner tube 14i and the outer tube 14o). For some designs, some misalignment of the longitudinal axis 17 of the inner tube 14i with respect to the longitudinal axis 17 of the outer tube 14o may be preferred, such as for example for manufacturability considerations.
The longitudinal axis 17 of the emitter tubes 14 can be substantially aligned with a longitudinal axis 6 of the enclosure 11. Alternatively, there can be some offset between a longitudinal axis 17 of the emitter tubes 14 and a longitudinal axis 6 of the enclosure 11. It can be beneficial to align the longitudinal axis 17 of both of the emitter tubes 14 with a longitudinal axis 6 of the enclosure 11 if x-ray emission from anode 12 center is desired.
Each of the inner 14, and outer 14o tubes can have opposite ends (N and F) comprising a near end N associated with, disposed adjacent to, or attached to the cathode 13 and a far end F disposed closer to the anode 12. An electron emitter 18 can be coupled between a far end Fi of the inner tube 14i and a far end Fo of the outer tube 14o. The inner 14i and outer 14o tubes can be electrically isolated from one another except for the electron emitter 18. For example, an electrically insulative material 9 can be disposed near or attached to the cathode 13 and can, along with the gap 7 (possibly a vacuum-filled gap), electrically insulate the inner tube 14i from the outer tube 14o. This electrically insulative material 9 can be an electrically insulative spacer ring and can partially fill a gap between the inner tube 14i and the outer tube 14o and can hold the inner tube 14i in proper position with respect to the outer tube 14o.
The electron emitter 18 can be a filament. The filament can be various types or shapes including helical or planar.
The far end Fi of the inner tube 14i can include a radial projection 16 extending radially outwardly from the inner tube 14i towards the outer tube 14o. The radial projection 16 can extend towards a groove 15 in the far end Fo of the outer tube 14o. Use of the radial projection 16 can allow the electron emitter 18 to be substantially centered across the far end Fo of the outer tube 14o. A center 18c of the electron emitter 18 can be substantially aligned with a longitudinal axis 6 of the enclosure 11, which can result in x-ray emission from a center of a transmission window on the anode 12.
The far end Fo of the outer tube 14o can substantially surround a circumference of the far end Fi of the inner tube 14i with the exception of the groove 15. This design can smooth out electric field gradients around the electron emitter 18 and the far end F of the emitter tubes 14.
A length Li of the inner tube 14i can be greater than a length Lo of the outer tube 14o. In one embodiment, the near end No of the outer tube 14o can terminate within the enclosure 11 and can contact an inner surface 13i of the cathode 13. The near end Ni of the inner tube 14i can extend through the cathode 13 outside the enclosure 11.
The inner tube 14i can initially remain open to allow the inner tube 14i to be a vacuum port to draw a vacuum on the inside of the x-ray tube. See for example, open inner tube 14i in
The inner tube 14i can be made of or can comprise a soft or ductile metal that can be pinched shut, such as copper or nickel for example. The outer tube 14o can comprise titanium. Use of titanium can help in maintaining a vacuum inside of the enclosure 11 because titanium can absorb hydrogen. Due to the small size of the H2 molecule, hydrogen can penetrate minute gaps in the x-ray tube, increase pressure therein, and cause the x-ray tube to malfunction. Thus, use of a titanium outer tube 14o can be beneficial for maintaining a desired level of vacuum in the x-ray tube and thus prolong the life of the x-ray tube. It can be beneficial to use a titanium outer tube 14o that has a high percent of titanium because other metals alloyed with the titanium might outgas and reduce the vacuum in the x-ray tube. For example, the outer tube 14o can comprise a mass percent of at least 85% titanium in one aspect, at least 95% titanium in another aspect, at least 99% titanium in another aspect, or at least 99.8% titanium in another aspect.
There can be an annular hollow 19 between the far end Fo of the outer tube 14o and the enclosure 11. In other words, there can be an absence of solid material between the far end Fo of the outer tube and the enclosure 11. A common feature of x-ray tube design is a cathode optic surrounding the electron emitter, to block electrons from extending radially outwards to the enclosure 11. These electrons can electrically charge the enclosure 11 and can result in early x-ray tube failure. With the x-ray tube design of the present invention, this optic can be avoided because the outer tube can substantially block electrons from extending radially outwards to the enclosure 11. By not using this cathode optic, manufacturing cost can be reduced. A cathode optic, however, may still be used with the present invention if needed for a highly focused electron beam.
There can be a first gap G1 between the far end Fo of the outer tube 14o and the anode 12 and a second gap G2 between the far end Fi of the inner tube 14i and the anode 12. The first gap G1 can be approximately equal to the second gap G2, thus keeping a plane of the electron emitter 18 substantially parallel to a face of the anode 12.
If a divergent x-ray emission is desired, it can be beneficial to dispose the electron emitter 18 near the anode 12. In addition to a divergent emission of x-rays, another benefit of disposing the electron emitter 18 closer to the anode 12 is that the electron emitter 18 can output the same power at a lower temperature, thus increasing filament life. The dual, electrically-conductive emitter tubes 14 can provide a sturdy support for the electron emitter 18, even if the electron emitter 18 extends a substantial distance from the cathode 13 towards the anode 12. In one embodiment, the first gap G1 can be smaller than a length Lo of the outer tube 14o. The first gap G1 can be between 4% and 25% of a length of the outer tube 14o in one embodiment or between 7% and 15% of a length of the outer tube 14o in another embodiment. The electron emitter 18 can be disposed between 0.4 millimeters and 8 millimeters from the anode 12 in one embodiment or between 0.3 millimeters and 4 millimeters from the anode 12 in another embodiment.
As shown on x-ray source 40 in
The cathode electrical connections 45 can include a first cathode electrical connection 45o that is electrically coupled to the near end No of the outer tube 14o and a second cathode electrical connection 45i that is electrically coupled to the near end Ni of the inner tube 14i. The power supply 41 can provide a small voltage differential, such as a few volts for example, between the first and second cathode electrical connections 45 to cause an electrical current to flow through the electron emitter 18 to heat the electron emitter 18. The heat of the electron emitter 18 and the large bias voltage between the electron emitter 18 and the anode 12 can cause electrons to emit from the electron emitter 18 towards the anode 12.
A helical spring 42 can be used to provide electrical contact between the first cathode electrical connection 45o and the near end No of the outer tube 14o. The helical spring 42 can be especially beneficial in a removable x-ray tube design because it can allow for easy electrical connection during x-ray tube insertion and removal and it can provide a large amount of electrical contact to the outer tube 14o. The electrical contact between the helical spring 42 and the outer tube 14o can be through a base plate of the cathode 13 if the outer tube 14o terminates within the enclosure 11.
The pinched-shut near end Ni of the inner tube 14i can be an electrical contact and can be configured to be electrically coupled to the power supply 41. The pinched-shut near end Ni of the inner tube 14i can electrically contact the second cathode electrical connection 45i by various means, including by a hinge spring or a leaf spring 44. A leaf spring 44 can be convenient for providing electrical contact to the inner tube 14i in a removable x-ray tube design.
A plunger pin, or various other types of electrical connectors, can also be used for electrical connection between the cathode electrical connections 45 and the emitter tubes 14.
The helical spring 42 and/or the leaf spring 44 can be substantially or totally enclosed within an electrically-conductive cup 43 that is capped off with the cathode 13. This cup can act as a corona guard to shield sharp edges of the helical spring 42, the leaf spring 44, and/or the emitter tubes 14. This corona guard can help to prevent arcing between these components and surrounding or near-by components having a large voltage differential.
There are various advantages of the dual, electrically-conductive emitter tube 14 designs described herein. These designs can be manufactured at a relatively low cost due to the low cost and simplicity of the dual emitter tubes 14 and the potential use of the inner tube 14i as a vacuum port. These designs can provide a stable support for the electron emitter 18, thus increasing electron emitter 18, and x-ray tube, lifetime. These designs can be helpful if the electron emitter 18 is to be disposed close to the anode 12 because the dual tubes 14 can provide a stronger support than posts over this extended distance. The emitter tubes 14, the cathode 13, and the electron emitter 18 can all be pre-assembled, then conveniently connected to the enclosure 11, thus allowing precise and repeatable placement of the electron emitter 18 in the x-ray tube during manufacturing, thus improving consistency of x-ray output between different units of a single x-ray tube model.
Method
A method, of evacuating and sealing an x-ray tube, can comprise some or all of the following steps, which can be performed in the order specified:
Sealing the x-ray tube 50 can be done by pinching the near end Ni of the inner tube 14i with a hydraulic tool operated at high pressure, such as greater than 500 psi, while the inner tube 14i is still connected to a vacuum.
This claims priority to U.S. Provisional Patent Application No. 61/876,036, filed on Sep. 10, 2013, which is hereby incorporated herein by reference in its entirety.
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Entry |
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PCT Application No. PCT/US14/45987: Filing date Jul. 9, 2014; Moxtek, Inc.; International Search Report mailed Nov. 18, 2014. |
Number | Date | Country | |
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20150071410 A1 | Mar 2015 | US |
Number | Date | Country | |
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61876036 | Sep 2013 | US |