Abstract:
Several different embodiments of high-intensity rotating-anode X-ray are shown which use a liquid or fluid-cooled rotating-anode. No ferrofluid-type rotating joints or O-ring gasket-type seals are required so that the interior of the tube maintains a high vacuum without pumping. A bellows permits mechanical coupling to interior structures of the tube while providing a completely vacuum tight enclosure. All joints may be hard soldered or brazed together so the entire system can be baked at a high temperature during pumpdown.

Description:
FIELD OF THE INVENTION 
     This invention pertains to a high intensity source of X-rays using a fluid cooled rotating anode, more particularly to a source incorporating a bellows to accommodate relative motions of the cathode and anode. 
     BACKGROUND OF THE INVENTION 
     The classic X-ray tubes have a thermionic cathode at one end and a fixed anode at the other end. Electrons emitted from the cathode are accelerated by a high potential and impact the anode thereby producing X-rays. The electron beam, which must be tightly focused to produce a high-definition image, produces extreme heating of the anode target. The power capability of this tube is limited by the conductive cooling of the anode target. 
     High intensity X-ray sources are in increasing demand for applications such as X-ray Lithography for Producing Integrated Circuits, Computerized Tomography for X-ray Imaging, and for X-ray Diffraction for Analyzing Materials. High intensity X-ray sources can be constructed by impinging a high intensity beam of electrons on an anode, but cooling the anode becomes a significant technical problem. A latter advance was the rotating-target tube in which the target is the surface of a metal disk spinning rapidly on bearings inside the vacuum envelope and driven by the rotor of an electric induction motor whose stator is outside the envelope. The rotating anode spreads the heat over an annular area of the target and provides much higher power for a short operating time, as in medical radiography. The ultimate cooling of the anode is mostly by thermal radiation in the high vacuum, so these tubes are inadequate for heavy duty operation. One has to wait for the massive anode to slowly cool. 
     U.S. Pat. No. 1,160,177 to Kelley discloses an X-ray which uses an externally applied cooling medium with a fixed anode. Some improvement in distributing the heat from the beam can be achieved by steering the electron beam to different parts of the anode. U.S. Pat. No. 2,229,152 to Walsweer and U.S. Pat. No. 4,336,476 to Holland disclose an anode sealed entirely in the vacuum which rotates in response to the field from coils exterior to the vacuum. The heat from the anode must be conducted through bearings irradiated through the vacuum to an external cap. U.S. Pat. No. 4,128,781 to Flisikowski et al. discloses an X-ray tube having a cathode rotatable relative to an anode. Electrons from a rotating cathode are incident on a stationary anode ring. The X-rays are emitted from different positions in space as a cathode is rotated. For most applications it is important that the X-rays be emitted from a fixed position in space. 
     U.S. Pat. Application Ser. No. 683,988 filed Dec. 12, 1984 by the inventor of the present invention, a continuation of which is now U.S. Pat. No. 4,788,705, describes methods by which the anode is rotated while the cathode is operationally fixed in space. One method is to have the rotating thermionic cathode emit along the axis of rotation and the electron beam is deflected by a stationary magnetic field to a stationary spot on the rotating anode. In another variation, the cathode is held stationary off axis by hanging on bearings from the rotating envelope and being held stationary by a magnetic or gravitational field. 
     U.S. Pat. Application Ser. No. 843,960 filed Mar. 25, 1986 by the inventor of the present invention, a continuation of which is now U.S. Pat. No. 4,821,305, describes an X-ray tube having the whole vacuum envelope rotate with the anode. The anode being part of the vacuum envelope, it can be cooled from the outside by liquid or air. The cathode also rotates. It is an axially symmetric band of photocathode surface which is illuminated by a focused, stationary spot of light entering the envelope through an auxiliary symmetric transparent window, part of the vacuum envelope. Photoelectrons from the cathode are focused, as by a stationary magnetic field, onto a small stationary spot through which the anode rotates. 
     Thus, there are many ways a high power X-ray tube can be designed to dissipate the heat over a large area of anode. However, nearly all involve a rotating seal in the form of a sliding 0-ring seal or a Ferrofluidic seal. These seals cause problems by limiting the rotation speed or life of the tube due to seal failure. 
     OBJECTS OF THE INVENTION 
     An object of the invention is to provide a high intensity source of X-rays which avoids the use of rotating seals. 
     SUMMARY OF THE INVENTION 
     These objects of the invention and other objects, features and advantages to become apparent as the specification progresses are accomplished by the invention according to which, briefly stated, a bellows type arrangement permits mechanical coupling to interior structures of the tube while providing a completely vacuum tight enclosure. All joints may be hard soldered or braced together so the entire system may be baked at high temperature during pump down. No ferrofluid-type rotating joints or 0-ring gasket-type seals are required so that the tube may be sealed off and the interior of the tube maintains a high vacuum without further pumping. The tube uses liquid or fluid-cooled rotating anode. 
     These and further constructional and operational characteristics of the invention will be more evident from the detailed description given hereinafter with reference to the figures of the accompanying drawings which illustrate one preferred embodiment and alternatives by way of non-limiting examples. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 shows a schematic sectional drawing of a first embodiment of the invention. 
     FIG. 2 shows a schematic sectional drawing a second embodiment of the invention. 
     FIG. 3 shows a schematic sectional drawing of a third embodiment of the invention. 
     FIG. 4 shows a schematic sectional drawing of a fourth embodiment of the invention. 
     FIG. 5 shows a blow-up of a part of FIG. 4 encompassed by the line 5--5 of FIG. 4. 
     FIG. 6 shows a schematic sectional drawing of an alternate embodiment of the tube of FIG. 4. 
     FIG. 7 shows a schematic sectional drawing of alternate embodiment of the tube of FIG. 6. 
    
    
     GLOSSARY 
     The following is a glossary of elements and structural members as referenced and employed in the present invention. 
     10 vacuum enclosing shell 
     12 anode support 
     14 window 
     16 insulating cylinder 
     17 cathode support 
     18 bellows 
     20 cathode stabilizer 
     22 motor 
     24 insulating coupling 
     26 shell bearings 
     28 internal bearings 
     32 external cathode stabilizer bearings 
     33 internal cathode stabilizer bearings 
     34 cathode 
     36 primary of transformer 
     38 secondary of transformer 
     39 stationary cathode member 
     40 slip ring 
     42 internal cathode support 
     44 anode 
     46 base 
     48 heater power supply 
     110 vacuum enclosing shell 
     112 anode support 
     114 window 
     116 insulating cylinder 
     118 bellows 
     122 motor 
     126 shell bearings 
     134 cathode 
     136 cathode support 
     138 heater power supply 
     140 vacuum feedthrough 
     142 pair of slip rings 
     144 anode 
     146 base 
     210 vacuum enclosing shell 
     214 window 
     216 insulating cylinder 
     218 bellows 
     222 motor 
     234 cathode 
     242 focus electrode 
     244 anode 
     246 coolant gland 
     248 bearings 
     300 rotary ceramic or glass insulator 
     302 fixed cathode 
     304 rotating anode 
     306 cathode support 
     308 fixed shaft 
     310 first set of two bearings 
     312 bearing support 
     314 second set of two bearings 
     316 support frame 
     318 glass-to-metal or ceramic-to-metal sealing ring 
     320 bellows 
     322 end cap 
     324 bearing 
     326 pair of outer bearings 
     328 slip ring 
     330 spring-loaded bearing 
     334 insulating ring 
     336 anode stator 
     338 shaft 
     340 coolant inflow passage 
     342 coolant outflow passage 
     344 rod 
     346 spring-loaded bearing 
     347 0-ring 
     348 metal ring 
     350 graphite face 
     352 silicon carbide ring 
     354 0-ring 
     356 collar 
     358 support ring 
     359 0-ring 
     360 pair of bearings 
     362 pulley 
     364 belt 
     366 drive pulley 
     368 motor 
     370 coolant manifold 
     372 insulating plate 
     374 secondary of heater transformer 
     376 primary of heater transformer 
     400 cathode assembly 
     402 shaft 
     404 pair of bearings 
     406 internal support 
     408 cathode positioner 
     410 shaft 
     412 spring-loaded bearing 
     414 bellows 
     416 cathode 
     418 insulator 
     420 shaft 
     422 ring bearing 
     424 cathode positioner 
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     Referring now to the drawings wherein reference numerals are used to designate parts throughout the various figures thereof, there is shown in FIG. 1, a vacuum enclosing shell 10, including an anode support 12, a window 14, an insulating cylinder 16, the cathode support 17, a bellows 18, and a cathode stabilizer 20. These parts can all be hard soldered or brazed together such that the enclosed volume can be pumped out and maintained under high vacuum conditions. A motor 22 rotates this whole shell 10 at a high angular speed of several thousand RPM&#39;s. As shown, the motor 22 supports one end of this structure through the insulating coupling 24 and the other end is supported by shell bearings 26 which have a rotational axis A2 common to that of the motor 22. In addition, internal bearings 28 are aligned on the same axis so that the internal cathode 34 can be maintained at a fixed position as the shell rotates. The cathode is constrained from rotating by the cathode stabilizer 20 on the axis A1 which is offset from the motor axis A2. In this sketch the two axes A1 and A2 are shown parallel to each other. However, the cathode stabilizer axis may also be tilted with respect to the motor axis and so long as the cathode stabilizer bearings 32 and 33 are properly supported and maintain a common axis with each other. In order to couple heater power to the cathode 34, a transformer with a primary 36 outside of the rotating shell is magnetically coupled through the insulating cylinder 16 to the secondary 38 of the transformer which is attached to the stationary cathode 39 member inside of the rotating shell 10. Power is thereby coupled from the outside to the interior cathode structure. The positive high voltage is applied to the anode support 12 by a slip ring 40 on the driving shaft. This voltage may be insulated from the motor by the insulating mechanical coupling 24. The negative supply may be coupled to the cathode through another slip ring or through bearings 26 and 28 or through bearings 32 and 33. Although the cathode stabilizer 20 rotates along with the rest of the structure, its axis is fixed with respect to the base and does not coincide with the motor axis. The internal cathode support 42 is constrained from rotating by its contact with the cathode stabilizer 20. In this configuration the cathode 34 is stationary with respect to the motor 22 so that the electron beam pattern provided can be rectangularly shaped if desired, permitting the bombardment pattern on the anode 44 also to be in the form a rectangle with the long axis along the radial direction. When such a pattern is viewed obliquely through the window, one can achieve a foreshortened view of the elongated pattern and thereby attaining effectively a small X-ray source spot size. This technique is used in order to spread the heat out along the radial direction of the anode 44 and thereby reduce the instantaneous heat load to the anode 44 and still obtain the small X-ray spot size. The motor 22, stabilizer bearings 32 and primary 36 are all mounted on a base 46. 
     Another X-ray tube configuration is sketched in FIG. 2. This configuration is much like that of FIG. 1 except the cathode 134 is directly attached to the cathode support member 136. The electrical power leads for the heater are coupled to the region outside the vacuum and to the power supply 138 through a standard vacuum feedthrough 140 and then coupled to the external heater current source through a pair of slip rings 142. Since the cathode 134 itself rotates relative to the anode in this configuration, one must use a cathode geometry that emits a circular electron beam pattern so that the X-ray pattern will be independent of the angular position of the cathode 134 or anode 144. With the proper electron optics, one can still achieve a reduction in the instantaneous anode power density by having the electrons impact the anode 144 at a substantial angle from the normal to the anode surface. By taking the X-rays off at the same angle but on the opposite side of the normal, one achieves the desired foreshortening of the X-ray spot size. 
     FIG. 3 shows a third configuration where the bellows 218 are used on the anode side of the tube rather than the cathode side. This permits the use of a small circular X-ray window 214. In this configuration the cathode 234 is in the form of a circle that surrounds the X-ray window 214. The electrons form a converging cone that is incident upon the anode 244. To reduce the instantaneous heat load on the anode, a V-groove anode configuration may be used. The V-groove permits a spreading of the instantaneous electron heating over a larger anode surface area. The X-rays are extracted through the X-ray window 214 so they leave the anode 244 surface at approximately the same angle that the electrons arrived permitting the proper foreshortening of the X-ray spot size. The V-groove geometry also permits a more symmetric distribution of the X-ray intensity and energies making this configuration a good candidate as a source for X-ray lithography. As in the embodiment of FIG. 2, feedthroughs are used in order to couple the heater current to the external world and slip rings are used to couple the current to the filament current source. The X-ray anode 244 is contained almost completely within the vacuum enclosure 2-0. It may be readily cooled by circulating a liquid coolant within the anode structure by bringing the liquid in and out through channels in the drive shaft. The coolant gland 246 permits one to circulate the fluid through an external heat exchanger. In all of the configurations an insulating coupling can be used as in FIG. 1 to electrically isolate the motor from the X-ray anode. Electrically insulating coolants should be used whenever the anode is not grounded. No internal bearings are contained in the embodiments shown in FIGS. 2 and 3 so that the vacuum bearing problems of prior rotating-anode X-ray tubes are eliminated. 
     Although fairly sharp bending of the bellows is shown in all of the sketches, one can readily go to smaller bending angles by extending the length of the structure. The bellows life will depend upon the bending angle, their length and size. In FIGS. 1 and 2 a cylindrical window is shown that traverses the entire circumference of the vacuum cylinder. In practice, this window may just be part of the insulating cylinder as materials such as alumina have low loss to X-rays as well as good insulating properties. Another question deals with the choice of coolant and the exact cooling configuration. The present generation of rotating anode X-ray tubes for medical use have balanced power supplies with the anode positive with respect to ground and the cathode negative with respect to ground. If the whole tube is immersed in oil, then one must be concerned about the drag of the oil. By confining the oil to the back of the anode region (which is compatible with all three configurations), then one would expect very little drag by the oil, particularly if the oil is fed in and out close to the axis of rotation. The remainder of the tube could easily be cooled by air or another gas. 
     There is shown in FIG. 4 an embodiment similar to that disclosed in FIG. 1. Here the bellows is bent. The advantage of this arrangement is that for a given offset, one provides less stress to the bellows, and results in longer bellow lifetimes since each point on the bellows rotates in a plane normal to the curved centerline of the bellows. Here a shaft 308 extends through the bearings 310 and 314 that support the cathode and bends to follow the contour of the bellows. At the end is a spring-loaded ball contact that locks the cathode in place so that it does not rotate and provides the dc path for the anode to cathode current. As was shown in the previous embodiments, heater current is provided by a thru-the-wall transformer that magnetically couples ac power from the region outside of the rotating ceramic cylinder to the inside coil which in turn is connected to the cathode heater. Experiments have been done that demonstrate such a transformer system operating at 13.56 MHz can provide adequate power to the heater. 
     FIG. 4 also shows a way of cooling the backside of the anode which was not explicitly shown in any of the embodiments above. Several cooling arrangements were shown in an earlier disclosure which has now been filed as U.S. Pat. Application Ser. No. 06/683,988 referred to above. 
     The tube of FIG. 4 has a rotating glass or ceramic insulator 300, a fixed cathode 302 and a rotating anode 304. The cathode 302 is mounted on a cathode support 306 which is attached to a fixed shaft 308. A first set of two bearings 310, allow the shaft 308 to remain fixed while the bearing support 312 rotates around it. A second set of two bearings 314 separates the rotating bearing support 312 from the support frame 316. With a glass tube envelope 300 a sealing ring 318 at both ends provide a glass-to-metal seal. The bearing support 312 is also sealed to the bellows 320. An opposite end of the bellows is sealed to the end cap 322. Within the end cap 322 an inner bearing 324 constrains the motion of the fixed shaft 308, thereby permitting the end cap 322 and bellows 320 to rotate around the shaft 308. The end cap 322 is mounted on the support frame 316 with a pair of bearings 326. Negative high voltage is fed to the cathode via a slip ring 328. Electrical contact is maintained between the end cap 322 and the shaft 308 with a spring-loaded ball 330. FIG. 5 shows additional detail of the anode end of the tube of FIG. 4. 
     The rotating glass insulator 300 is attached to the anode 304 with a second sealing ring 318. The anode 304 is attached to an insulating ring 334 made of a suitable plastic or ceramic insulator. Within the anode 304, a stator 336, supported by the shaft 338 is used to divert coolant around the inside of the anode to achieve maximum cooling efficiency. The shaft 338 is kept from rotating by attachment of the coolant manifold 370 at its end to the support frame 316. Within the shaft 338 there are passages for inflow 340 and outflow 342 of coolant to the anode 304. A rod 344 down the center of the shaft 338 maintains positive electric potential on the anode 304 via a spring-loaded ball 346. An 0-ring 347 provides a coolant seal between the insulating ring 334 and the back of the anode 304. A metal ring 348 attached to the outside end of the insulating ring 334 has a graphite face 350. The metal ring 348 and graphite face 350 are part of the rotating assembly. A stationary lapped silicon carbide ring 352 is in sliding contact with the graphite face 350 to provide a rotating water-tight seal. A seal between the ring 352 and the shaft 338 is provided with an 0-ring 354 compressed by collar 356. A cylindrical bearing support ring 358 is mechanically attached to both the ring 348 and the insulating ring 334. An 0-ring 359 provides the coolant seal between metal ring 348 and insulating ring 334. The cylindrical bearing support ring 358 is isolated from the frame 316 with a pair of bearings 360. 
     As shown in FIG. 4, a pulley 362 is also attached to the cylindrical bearing support ring 358 between the pair of bearings 360. A belt 364 driven by a drive pulley 366 and motor 368 is used to drive the pulley 362 and the anode assembly. At the outer end of the shaft 338, a coolant manifold 370 is used to distribute the coolant and support the shaft 338. An insulating plate 372 is attached to the insulating ring 334 to prevent arcing between the sealing ring 318 and parts of the frame 316. A single turn secondary coil 374 attached to the cathode support 306 is used to power the heater for the cathode. The primary 376 located outside the tube is concentric with the secondary and operates at 13.56 MHz. 
     In an alternate embodiment shown in FIG. 6, the cathode assembly 400 is mounted via a shaft 402 and pair of bearings 404 to an internal support 406. At the opposite end of the shaft 402, a cathode positioner 408 is held fixed in space by a shaft 410 having a springloaded bearing 412. The shaft 410 rotates with the bellows 414 which is attached to the rotating insulator 418 and anode as in the previous embodiment. The cathode 416 is fixed in space and decoupled from the motion of the shaft 410 by the bearing 412. 
     In another alternate embodiment shown in FIG. 7, the shaft 410 is replaced by the shaft 420 and the cathode positioner 408 is replaced by the cathode positioner 424. The functions of the shaft and cathode positioner remain the same, but a ring bearing 422 fitted into the cathode positioner 424 provides for relative rotation of the rod 420. 
     The bellows used in such a tube must be compatible with bakeout in a high vacuum environment and with continuous flexure during rotation. Such bellows are generally stainless steel or inconel bellows with welded joints at flexure points. (Sources of supply are: the Metal Bellows Co., 1075 Providence Hwy., Sharon, Mass. 02067; John Crane-Houdaille, Inc., 6400 West Oakton Street, Morton Grove, Ill. 60053). 
     This invention is not limited to the preferred embodiment and alternatives heretofore described, to which variations and improvements may be made including mechanically and electrically equivalent modifications to component parts, without departing from the scope of protection of the present patent and true spirit of the invention, the characteristics of which are summarized in the following claims.