High-power X-ray sources and methods of operation

Information

  • Patent Grant
  • 10600609
  • Patent Number
    10,600,609
  • Date Filed
    Wednesday, January 31, 2018
    6 years ago
  • Date Issued
    Tuesday, March 24, 2020
    4 years ago
Abstract
The present specification discloses a high power continuous X-ray source having a rotating target assembly that is cooled by circulation of a liquid material in contact with the target assembly, whereby the target assembly has a front surface being impinged by electrons and a mechanism for rotating the target assembly. The cooling liquid is always in contact with at least one surface of the target for dissipating the heat generated by the energy deposited by the stream of electrons, thereby lowering the temperature of the target to allow for continuous operation.
Description
FIELD

The present specification generally relates to X-ray systems and in particular to high power, high-energy X-ray sources operating continuously comprising a rotating target cooled by circulating a fluid in communication with the target assembly.


BACKGROUND

High-power electron sources (up to 500 kW) have conventionally been used in X-ray irradiation applications, including food irradiation and sterilization. Usually, a pencil beam of electrons is rastered, which includes scanning an area from side to side while a conveyance system translates the object to cover the irradiated object. The electrons traverse a thin window that separates the source vacuum from air. The window can be easily cooled to prevent rupture since it is thin and since the electron beam is rastered, it spreads the electron energy over a large area. Thus, it is easier to cool than heat concentrated in a small spot.


In typical X-ray radiography, electrons in a beam impinge upon a stationary target to generate X-rays. The target is usually tungsten-rhenium brazed with copper that is cooled with chilled circulating water to remove the heat deposited by the electrons. High-energy X-ray inspection systems typically employ sources up to 1 kW that may include the use of this type of target. There are, however, emerging inspection applications where there is a need to increase power to approximately 20 kW to allow for greater penetration and enable new technologies. However, at these higher powers, the heat from the target cannot be removed fast enough to the point of target liquefaction, thus destroying the target.


Medical X-ray tubes used in Computed Tomography (CT) applications require very high power (up to 100 kW) with sub-millimetric focal spots. FIG. 1 illustrates a typical rotating anode X-ray tube 100 used in medical applications. Glass envelope 102 encloses a cathode 104 comprising a filament 106 in a focusing cup, and an anode/target 108 coupled with a tungsten/rhenium, anode disk 110 via an anode stem 114. In order to prevent melting of the anode/target 108 in such tubes, the target 108 is rotated at very high speed (˜8,000 rpm) by using a motor comprising a rotor 109 and a stator 111, causing the heat within target 108 to dissipate over a large area. Since it is impractical to pass a rotating shaft through a high-vacuum seal, the rotating parts of the tube are positioned within the glass vacuum envelope 102 comprising a port 116 through which generated X-rays leave the tube 100. Temperature management is achieved by the heat storage capacity of the target 108. Since the heat removal by conduction is negligible and the heat storage capacity is limited, the tube 100 needs to be turned off for some time before turning it on again, thereby reducing the duty factor. Unlike medical applications, however, some security inspection systems require continuous operation. Hence, there is a need for a high-power X-ray source that can be operated continuously and that does not have issues with overheating.


Another method that has been used for high-power targets is based on a liquid metal target. FIG. 2 illustrates a typical liquid metal target assembly for use in an X-ray source. At least a portion of the target 202 is cooled by a circulating liquid metal 204. A heat exchanger 206 is used to cool down the liquid metal 204 and a pump 208 is used to recirculate the liquid metal 204. The liquid metal 204 serves as both the X-ray production target as well as the cooling fluid, in that the heat generated by an electron beam 210 hitting the target surface 202 is carried away by the flowing stream of liquid metal 204. The advantage of this method is that it allows for continuous operation as the liquid metal can be cooled fast enough.


Possible liquid metals include liquid Gallium, which has high thermal conductivity, high volume specific heat and low kinetic viscosity. However, Gallium has a low atomic number (Z) of 32 as compared to Tungsten (Z=74), which results in lower X-ray conversion efficiency and a narrower Bremsstrahlung fan angle. Mercury is a liquid metal at room temperature with a high Z (80), however it is not usually used for this application due to its hazardous nature. A suitable metal alloy consists of 62.5% Ga, 21.5% In and 16% Sn. However, the atomic number of the aforementioned alloy is also quite low as compared to Tungsten. Another suitable alloy may be composed of elements having a higher Z, such as of 43% Bi, 21.7% Pb, 18.3% In, 8% Sn, 5% Cd and 4% Hg. However, Mercury, Cadmium and Lead are all hazardous materials. Another disadvantage of the liquid metal targets is that they require a thin window to separate the vacuum from the liquid target. The probability of such window rupturing and contaminating the vacuum is high.


Therefore, there is a need for a high-power X-ray production target that can be cooled in a safe and effective manner. Further, an X-ray tube with such a target should be capable of operating in a continuous mode.


SUMMARY

The following embodiments and aspects thereof are described and illustrated in conjunction with systems, tools and methods, which are meant to be exemplary and illustrative, and not limiting in scope. The present application discloses numerous embodiments.


In some embodiments, the present specification discloses a high power radiation production target assembly comprising: a target sub-assembly having a copper body and a target positioned along a periphery of the copper body, wherein said target is impinged by a stream of particles to produce radiation; a plurality of paddles positioned on said copper body; a stream of water to propel said paddles to cause rotation and cooling of said copper body; and, at least one coupling to provide vacuum sealing under rotation.


Optionally, said stream of particles comprises electrons that impinge upon the rotating target sub-assembly to produce X-rays. Optionally, the energy of the electrons is 6 MV or higher.


Optionally, the target is a ring made of tungsten.


Optionally, the target assembly further comprises one or more flow directors for directing the stream of liquid in a predefined direction and for propelling the plurality of paddles.


Optionally, said liquid is water. Optionally, the at least one coupling is a ferro-fluidic coupling for providing vacuum sealing.


In some embodiments, the present specification discloses a high power radiation production target assembly comprising: a target sub-assembly having a copper body and a target along a periphery of the copper body, wherein said target is impinged by a stream of particles to produce radiation; a stream of liquid used to cool said copper body; a direct motor drive configured to cause rotation of the copper body; and, a coupling to provide vacuum sealing under rotation.


Optionally, said stream of particles is an electron beam that impinges upon the rotating target to produce X-rays. Optionally, the energy of the electrons is 6 MV or higher.


Optionally, the target is a ring made of tungsten.


Optionally, the direct motor drive comprises a brushless torque motor.


Optionally, said liquid is water.


Optionally, the coupling is a ferro-fluidic coupling for providing vacuum to water sealing.


In some embodiments, the present specification discloses a high power radiation production target assembly comprising: a target sub-assembly having a copper body and a target along a periphery of the target body, wherein said target is impinged by a stream of particles to produce radiation; a stream of liquid used to cool said copper body; a chain drive motor configured to cause rotation of the copper body; and, a coupling to provide vacuum sealing.


Optionally, said stream of particles is an electron beam that impinges upon the rotating target to produce X-rays. Optionally, the energy of the electrons is 6 MV or higher.


Optionally, the target is a ring made of tungsten.


Optionally, the chain drive motor is operated in conjunction with one of: a chain, a timing belt, a continuous cable, and a direct spur-gear coupling.


Optionally, said liquid is water.


Optionally, the coupling is a ferro-fluidic coupling for providing vacuum to water sealing.


In some embodiments, the present specification discloses a method of continuously operating a radiation production target assembly comprising: rotating a target, wherein said target is formed on a periphery of a copper body, and wherein said target is rotated using a mechanism for causing rotation; impinging a stream of particles onto the rotating target to produce radiation; and circulating a cooling liquid around the target, such that the liquid is always in contact with at least one surface of the target for dissipating heat generated by the impinging stream of particles, thereby cooling the target to allow for continuous operation, wherein the target assembly comprises a coupling to provide vacuum sealing.


Optionally, the mechanism for rotating the target comprises a plurality of paddles attached to said copper body, wherein said paddles are propelled by a jet stream of said cooling liquid, thereby causing rotation of the target.


Optionally, the mechanism for rotating the target comprises a direct motor drive attached to said target assembly, said motor comprising a brushless torque motor.


Optionally, the mechanism for rotating the target comprises a chain drive motor attached to said target assembly. Optionally, the chain drive motor is operated in conjunction with one of: a chain, a timing belt, a continuous cable, and a direct spur-gear coupling.


Optionally, said stream of particles is an electron beam that impinges upon the rotating target to produce X-rays. Optionally, the energy of the electrons is 6 MV or higher.


Optionally, the target is a ring made of tungsten.


Optionally, said cooling liquid is water.


Optionally, the coupling is a ferro-fluidic coupling for providing vacuum to water sealing.


In some embodiments, the present specification describes a high power radiation source comprising a rotating target assembly being cooled by circulation of a liquid in contact with the assembly, the assembly comprising: a target, wherein said target is impinged by particles to produce radiation; a plurality of paddles attached to said target assembly, wherein said paddles are propelled by a jet stream of the liquid causing rotation of the target; and, at least one coupling to provide water to vacuum sealing. Optionally, the target assembly further comprises one or more flow directors for directing the jet stream of the liquid material in a predefined direction and for propelling the plurality of paddles.


In some embodiments, the present specification discloses a high power radiation source comprising a rotating target assembly being cooled by circulation of a liquid in contact with the assembly, the assembly comprising: a target, wherein said target is impinged by particles to produce radiation; a direct motor drive attached to said target assembly causing rotation of the target assembly; and, a coupling to provide water to vacuum sealing. Optionally, the direct motor drive comprises a brushless torque motor.


In some embodiments, the present specification discloses a high power radiation source comprising a rotating target assembly being cooled by circulation of a liquid in contact with the assembly, the assembly comprising: a target, wherein said target is impinged by particles to produce radiation; a chain drive motor attached to said target assembly causing rotation of the target assembly; and, a coupling to provide water to vacuum sealing. Optionally, the chain drive motor is operated in conjunction with one of: a chain, a timing belt and a continuous cable.


In some embodiments, the present specification discloses a method of operating a continuous radiation source using a rotating target assembly comprising: rotating a target, wherein said target is rotated using a mechanism for causing rotation; directing a particle stream onto the rotating target to produce radiation; circulating a liquid in contact with the target assembly to cool the target; and, a coupling to provide water to vacuum sealing. Optionally, the mechanism for rotating the target comprises a plurality of paddles attached to said target assembly, wherein said paddles are propelled by a jet stream of the liquid causing rotation of the target. Optionally, the mechanism for rotating the target comprises a direct motor drive attached to said target assembly comprising a brushless torque motor causing rotation of the target. Optionally, the mechanism for rotating the target comprises a chain drive motor attached to said target assembly causing rotation of the target. Optionally, the chain drive motor is operated in conjunction with one of: a chain, a timing belt and a continuous belt. Optionally, the particles are electrons impinging upon said target to produce X-rays. Optionally, the target is made of tungsten.


In some embodiments, the present specification discloses a high power radiation source comprising a rotating target assembly being cooled by circulation of a liquid in contact with the assembly, the assembly comprising: a target, wherein said target is impinged by particles to produce radiation; and, a plurality of paddles attached to said target assembly, wherein said paddles are propelled by a jet stream of the liquid causing rotation of the target.


Optionally, the high power radiation source further comprises a coupling to provide water to vacuum sealing. Optionally, the coupling is a dynamic ferro-fluidic coupling for providing water to vacuum sealing. Optionally, the high power radiation source further comprises at least one coupling to provide sealing to separate between water and vacuum, water and air, or vacuum and air.


The aforementioned and other embodiments of the present specification shall be described in greater depth in the drawings and detailed description provided below.





BRIEF DESCRIPTION OF THE DRAWINGS

These and other features and advantages of the present specification will be appreciated, as they become better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:



FIG. 1 illustrates a conventional rotating anode X-ray tube 100 used in medical applications;



FIG. 2 illustrates a liquid-metal target assembly for use in a high-power X-ray source;



FIG. 3A is a side cross-sectional view of an X-ray production target assembly comprising a target sub-assembly propelled by a water jet, in accordance with an embodiment of the present specification;



FIG. 3B is a front cross-sectional view of a portion of the X-ray target sub-assembly of FIG. 3A, in accordance with an embodiment of the present specification;



FIG. 4A illustrates a side cross-sectional view of an X-ray production target assembly comprising a target sub-assembly rotated via a direct drive motor, in accordance with an embodiment of the present specification;



FIG. 4B is a front cross-sectional view of a portion of the X-ray target sub-assembly of FIG. 4A, in accordance with an embodiment of the present specification;



FIG. 5A illustrates a side cross-sectional view of an X-ray production target assembly comprising a target sub-assembly rotated via a chain motor drive, in accordance with an embodiment of the present specification;



FIG. 5B is front cross-sectional view of a portion of the X-ray target sub-assembly of FIG. 5A, in accordance with an embodiment of the present specification; and



FIG. 6 is a flowchart illustrating the steps of operating a rotating radiation production target assembly, in accordance with an embodiment of the present specification.





DETAILED DESCRIPTION

The present specification describes several embodiments of high-power, rotating X-ray production targets. In various embodiments, the target is fabricated from a ring of tungsten brazed to a copper body, rotating at a high speed and cooled down by use of a high-speed flow of chilled water. In embodiments, the speed of the flow of water ranges between 100 RPM and 5000 RPM. In embodiments, the speed of the flow of water varies based on target material thickness, target material type, beam current, and cooling temperature. In an embodiment, the jet stream of water used for cooling the target is also used to rotate the target. Further, in embodiments, a target sub-assembly is connected to the electron accelerator, via physical interfaces, using an O-ring or gasket. A cooling liquid, such as water or a water and glycol mixture, is always in contact with at least one surface of the target for dissipating the heat generated by the energy deposited by the stream of electrons, thereby lowering the temperature of the target and allowing for continuous operation.


The term “high power” for a radiation production target assembly refers to a target assembly configured to generate at least 2 kW and up to 100 kW of X-ray radiation. The embodiments of the present specification are employed for target assemblies that operate in a power or energy ranging from 2 kW and 20 kW. Design of the target assemblies depends on both the required power and an optimization of the required power with corresponding size of the target assemblies. It should be appreciated that the power capability of the target assemblies of the present specification can be increased by making the X-ray production target assembly larger.


The present specification is directed towards multiple embodiments. The following disclosure is provided in order to enable a person having ordinary skill in the art to practice the invention. Language used in this specification should not be interpreted as a general disavowal of any one specific embodiment or used to limit the claims beyond the meaning of the terms used therein. The general principles defined herein may be applied to other embodiments and applications without departing from the spirit and scope of the invention. Also, the terminology and phraseology used is for the purpose of describing exemplary embodiments and should not be considered limiting. Thus, the present invention is to be accorded the widest scope encompassing numerous alternatives, modifications and equivalents consistent with the principles and features disclosed. For purpose of clarity, details relating to technical material that is known in the technical fields related to the invention have not been described in detail so as not to unnecessarily obscure the present invention. In the description and claims of the application, each of the words “comprise” “include” and “have”, and forms thereof, are not necessarily limited to members in a list with which the words may be associated.


It should be noted herein that any feature or component described in association with a specific embodiment may be used and implemented with any other embodiment unless clearly indicated otherwise.



FIG. 3A illustrates a side cross-sectional view of an X-ray production target assembly 300 comprising a target sub-assembly 302 which includes a target propelled and cooled by a water jet, in accordance with an embodiment of the present specification. FIG. 3B illustrates an exploded, front cross-sectional view, through a line 340 of FIG. 3A, of a portion of the target sub-assembly 302, in accordance with an embodiment of the present specification. Referring to FIGS. 3A and 3B, the target sub-assembly 302 comprises a copper body 330 that supports a target ring 303 brazed into the copper body 330. In an embodiment, the target ring 303 comprises a tungsten ring. However, in alternate embodiments, for energies above approximately 7.5 MeV the copper body 330 is used as a target when neutron production is not desired. In some embodiments, the copper body 330 is disc shaped and may optionally include a protruding center wheel portion. In embodiments, the target ring 303 may be positioned around the center wheel portion of copper body 330. The target ring 303 is positioned along an edge or periphery of the copper body 330, wherein the target sub-assembly 302 or portions thereof directly oppose an electron source or electron accelerator, such as, for example, a linac. The copper body 330 is housed within a hollow stainless steel cylinder 355. In an embodiment, top portion 330a and bottom portion 330b of the copper body 330 is brazed to an inner surface of the hollow cylinder 355. A target enclosure 320 houses the target sub-assembly 302. In embodiments, the target enclosure is comprised of a thin material that does not significantly attenuate X-rays.


Rotation of the target sub-assembly 302 and the cylinder 355, about a central longitudinal axis 380, is enabled by a first bearing 310 (in vacuum) and a second bearing 312 disposed between the cylinder 355 and the enclosure 320. In some embodiments, the first and second bearings 310, 312 are radial open bearings of stainless steel having a plurality of balls sandwiched between a stationary portion and a rotatory portion. The stationary portions of the bearings 310, 312 are attached to an inner surface of the enclosure 320 while the rotatory portions of the bearings 310, 312 are coupled to and rest on an outer surface of the cylinder 355. A dynamic Ferro-fluid coupling or seal 306, which, in an embodiment comprises first and second portions 306a and 306b, is also positioned between the cylinder 355 and the enclosure 320. In some embodiments, two ferro-fluidic couplings may be employed. In some embodiments, only one ferro-fluidic coupling is employed. A static O-ring 308, positioned at a distal end or periphery of the enclosure 320, serves as a vacuum/air seal between the target sub-assembly 302 electron source interfaces 316 which abut the enclosure 320. A retaining member or threaded nut bearing 314 is coupled to the inner surface of the enclosure 320 while retaining member 315 is coupled to the outer surface of the cylinder 355. As shown in FIG. 3A, the second bearing 312 is positioned proximal to a vertical plane 341 positioned through the copper body 330, the first bearing 310 is positioned distal to the vertical plane 341 through the copper body 330. In embodiments, the Ferro-fluidic coupling 306 is positioned between the first and second bearings 310, 312. The threaded nut bearing 314 and retaining member 315 are disposed distal to and abutting the first bearing 310. Threaded nut bearing 314 and retaining member 315 allow for one bearing to be movably attached so that it can be adjusted in case of misalignment. In an alternative embodiment, a single bearing may be employed. Ideally, if a single bearing is employed, it should be able to withstand moment forces. In an embodiment, where a single bearing is employed, it may be placed at a position proximal to a vertical plane 341 of the copper body 330. Persons of ordinary skill in the art would appreciate that the current arrangement of the bearings 310, 312, 314 and the Ferro-fluidic coupling 306 is only exemplary and may differ in alternate embodiments.


Still referring to FIGS. 3A and 3B, the target sub-assembly 302 also comprises a plurality of paddles 322 configured as radially elongated members. In embodiments, the paddle size is dependent on the overall size of the target. In embodiments, the plurality of paddles 322 is coupled to the copper body 330. In embodiments, paddles 322 are coupled to the copper body via any suitable adhering means, such as, but not limited to machining, gluing, or welding. In embodiments, any two consecutive paddles are spaced at a distance from one another wherein the distance ranges from a first value to a second value. In embodiments, it should be noted that the distance between the paddles 322 is dependent on the overall size of the target and target sub-assembly. In some embodiments, the plurality of paddles 322 are configured as first and second concentric rings 322a, 322b positioned behind the copper body 330 relative to the plane of the copper body 330. It should be understood by those of ordinary skill in the art that the X-ray production target assembly 300 is positioned between the electron source interfaces 316 and collimators 350 of an X-ray source assembly (not shown in its entirety). It should be noted herein that an electron accelerator, which may be part of the X-ray source assembly, may be employed in embodiments of the present specification. In embodiments, the electron accelerator may be a tube for operating energies of less than 600 kV. In embodiments, the electron accelerator may be a linac for operating energies of greater than 1 MeV and for generating high energy electrons.


In accordance with an aspect of the present specification, the target sub-assembly 302 is cooled by a flow of circulating water 304. In operation, a stationary electron beam 318 is directed to the periphery of the copper body 330 such that is impinges upon the target ring 303. In some embodiments, the energy of the electrons in the electron beam 318 is on the order of 6 MV or higher. When the electron beam 318 hits the target ring 303, which rotates via water flow, X-rays are produced and the energy deposited by the electrons is spread around the rotating target's ring 303. Cold water flowing into the enclosure 320 via conduit or opening 324 strikes concentric rings 322a and 322b, comprising paddles 322, thus rotating the copper body 330 and concurrently cooling the target sub-assembly 302. After cooling the target sub-assembly 302, the heated water flows out of the enclosure 320 via conduit or opening 326 to a chiller to cool the water. Flow directors 328 are provided to guide the flow of water in a desired direction. In an embodiment, the target sub-assembly 302 is propelled by a jet of water at a pressure of approximately 100 psi.



FIG. 4A illustrates a side cross-sectional view of an X-ray production target assembly 400 comprising a target sub-assembly 402 that is rotated via a direct drive motor, in accordance with an embodiment of the present specification. FIG. 4B illustrates a front cross-sectional view, through a line 440 of FIG. 4A, of a portion of the target sub-assembly 402 cooled by flowing water, in accordance with an embodiment of the present specification. Referring to FIGS. 4A and 4B, the target sub-assembly 402 comprises a copper body 430 that supports a target ring 403 brazed into the copper body 430. In an embodiment, the target ring 403 comprises a tungsten ring. However, in alternate embodiments, for energies above approximately 7.5 MeV the copper body 430 is used as a target when neutron production is not desired. In some embodiments, the copper body 430 is disc shaped and may optionally include a protruding center wheel portion. In embodiments, the target ring 403 may be positioned around the center wheel portion of copper body 430. In embodiments, the tungsten ring 403 is positioned along an edge or periphery of the copper body 430, wherein the target sub-assembly 402 or portions thereof directly oppose an electron source, such as, for example, a linac. The copper body 430 is housed within a hollow stainless steel cylinder 455. In an embodiment, top portion 430a and bottom portion 430b of the copper body 430 is brazed to an inner surface of the hollow cylinder 455. A target enclosure 460 houses the target sub-assembly 402. In embodiments, the target enclosure is comprised of a thin material that does not significantly attenuate X-rays.


At least one, and preferably a first ferro-fluidic seal 406a and a second ferro-fluidic seal 406b are also positioned between the cylinder 455 and the target enclosure 460 to provide vacuum to motor/air sealing as well as motor/air to water sealing. At least one static O-ring 408 serves as a vacuum/air seal between the target sub-assembly 402 and electron-source interfaces 420 which abut the target enclosure 460. Optionally, two static O-ring seals 408 are employed and serve as vacuum/air seals between the target sub-assembly 402 and the target enclosure 460.


Rotation of the target sub-assembly 402 and the cylinder 455, about a central longitudinal axis 480, is enabled by a first bearing 410 and a second bearing 412 positioned between the hollow cylinder 455 and the target enclosure 460. In some embodiments, the first and second bearings 410, 412 are radial open bearings of stainless steel having a plurality of balls sandwiched between a stationary portion and a rotatory portion. The second bearing 412 is disposed proximal to a vertical plane 441 of the copper body 430, the first bearing 410 is disposed distal to the vertical plane 441 of the copper body 430. In an embodiment, first bearing 410 is positioned on a distal side of first ferro-fluidic seal 406a and second bearing 412 is positioned on a proximal side of second ferro-fluidic seal 406b, wherein said distal and proximal sides are defined in relation to a vertical plane 441 through copper body 430, with the proximal position being closer to the vertical plane 441 while the distal position is farther from the vertical plane 441. Thus, in the embodiment just described, first and second bearings 410, 412 “sandwich” the first and second ferro-fluidic seals 406a, 406b to provide vacuum sealing under rotation. In an alternate embodiment, first bearing 410 may be positioned in air on a proximal side of a first ferro-fluidic seal 406a while second bearing 412 may be positioned in air on a distal side of a second ferro-fluidic seal 406b, whereby first and second bearings 410, 412 are “sandwiched” in air between the first and second ferro-fluidic seals 406a, 406b. In an alternative embodiment, a single bearing may be employed. Ideally, if a single bearing is employed, it should be able to withstand moment forces. In an embodiment where a single bearing is employed, it may be either first bearing 410 positioned in air on a proximal side of a first ferro-fluidic seal 406a or second bearing 412 positioned in air on a distal side of a second ferro-fluidic seal 406b.


The stationary portion of the bearing 410 is attached to a structural member 490 while the stationary portion of the bearing 412 is attached to an inner surface of the target enclosure 460. The rotatory portions of the bearings 410, 412 are coupled to and rest on an outer surface of the cylinder 455. An external bearing retaining member 414 is positioned on the periphery of the enclosure 460 at a distal end while an internal bearing retaining member 416 is coupled to the outer surface of the cylinder 455. The internal bearing retaining member 416 is positioned distally to the bearing 410 while the external bearing retaining member 414 is positioned distally to the internal bearing retaining member 416 and proximate the periphery of the enclosure 460. Bearing retaining members 414 and 416 allow for one bearing to be movably attached so that it can be adjusted in case of misalignment. Persons of ordinary skill in the art would appreciate that the current arrangement of the bearings 410, 412, and the two ferro-fluidic seals 406a, 406b is only exemplary and may differ in alternate embodiments.


A direct motor drive comprising a brushless torque motor 409 is provided directly on and attached to the target sub-assembly 402 to cause the sub-assembly 402 (and therefore the copper body 430) and the cylinder 455 to rotate. In an embodiment, the target sub-assembly 402 can be brazed to a stainless motor rotor where permanent magnets are bonded to the rotor. It should be understood by those of ordinary skill in the art that the X-ray production target assembly 400 is positioned between the electron-source interfaces 420 and collimators 450 of an X-ray source assembly (not shown in its entirety) that may, in an embodiment, include a linac for generating high-energy electrons.


In accordance with an aspect of the present specification, the target sub-assembly 402 is cooled by circulating water 404 while the sub-assembly 402, and therefore the copper body 430, is being rotated by the motor 409. In operation, a stationary electron beam 418 is directed to the periphery of the copper body 430 and impinges upon the target ring 403. In some embodiments, energy of electrons in the electron beam 418 is on the order of 6 MV or higher. When the electron beam 418 hits the target ring 403, which is being rotated by the motor 409, X-rays are produced and the energy deposited by the electrons is spread around the target's tungsten ring 403. In an embodiment, for example, an allied motion model HTO5000 brushless motor may be employed to rotate the target and circulate the water. In other embodiments, any suitable brushless torque motor may be used. Further, depending on the actual configuration, the motor may modify the electron beam trajectory due to the electrical and magnetic fields induced by the motor. Referring back to FIGS. 4A and 4B, the target sub-assembly 402 is cooled by cold water flowing through the enclosure 460 via conduit or opening 424, circulating and cooling the target sub-assembly 402. Heated water flows out of the enclosure 460 via conduit or opening 426 to a chiller to cool the hot water. Flow directors 428 are provided to guide the flow of water in a desired direction. In embodiments, at least one tube 490 is employed to cool the target enclosure or housing 460 with water. Optionally, three tubes 490 are employed.



FIG. 5A illustrates a side cross-sectional view of an X-ray production target assembly 500 comprising a target sub-assembly 502 rotated via a motor drive, in accordance with an embodiment of the present specification. FIG. 5B illustrates a front cross-sectional view, through a line 540 of FIG. 5A, of a portion of the target sub-assembly 502 cooled by flowing water, in accordance with an embodiment of the present specification. Referring to FIGS. 5A and 5B, the target sub-assembly 502 comprises a copper body 501 that supports a target ring 503 brazed in the copper body 501. In an embodiment, the target ring 503 is comprised of a tungsten ring. However, in alternate embodiments, for energies above approximately 7.5 MeV the copper body 501 may be used as a target when neutron production is not desired. In some embodiments, the copper body 501 is disc shaped and may optionally include a protruding center wheel portion. In embodiments, the target ring 503 may be positioned around the center wheel portion of copper body 501. In embodiments, the tungsten ring 503 is positioned along an edge or periphery of the copper body 501, wherein the target sub-assembly 502 or portions thereof directly oppose an electron source, such as, for example, a linac. The copper body 501 is housed within a hollow stainless steel cylinder 555. In an embodiment, top portion 501a and bottom portion 501b of the copper body 501 is brazed to an inner surface of the hollow cylinder 455. A target enclosure 560 houses the target sub-assembly 502. In embodiments, the target enclosure is comprised of a thin material that does not significantly attenuate X-rays.


At least one, and preferably a first ferro-fluidic seal 506a and a second ferro-fluidic seal 506b are also positioned between the cylinder 555 and the target enclosure 560 to provide vacuum to motor/air sealing as well as motor/air to water sealing. At least one static O-ring 508 serves as a vacuum/air seal between the target sub-assembly 502 and electron-source interfaces 524 which abut the target enclosure 560. Optionally, two static O-ring seals 508 are employed and serve as vacuum/air seals between the target sub-assembly 502 and the target enclosure 560.


Rotation of the target sub-assembly 502 and the cylinder 555, about a central longitudinal axis 580, is enabled by a first bearing 514 and a second bearing 516 disposed between the cylinder 555 and the enclosure 560. In some embodiments, the first and second bearings 514, 516 are radial open bearings of stainless steel having a plurality of balls sandwiched between a stationary portion and a rotatory portion. The second bearing 516 is disposed proximal to a vertical plane of the copper body 501, the first bearing 514 is disposed distal to the vertical plane of the copper body 501. In an embodiment, first bearing 514 is positioned on a distal side of first ferro-fluidic seal 506a and second bearing 516 is positioned on a proximal side of second ferro-fluidic seal 506b, wherein said distal and proximal sides are defined in relation to a vertical plane 541 through copper body 501, with the proximal position being closer to the vertical plane 541 while the distal position is farther from the vertical plane 541. Thus, in the embodiment just described, first and second bearings 514, 516 “sandwich” the first and second ferro-fluidic seals 506a, 506b. In an alternate embodiment, first bearing 514 may be positioned in air on a proximal side of a first ferro-fluidic seal 506a while second bearing 516 may be positioned in air on a distal side of a second ferro-fluidic seal 506b, whereby first and second bearings 514, 516 are “sandwiched” in air between the first and second ferro-fluidic seals 506a, 506b. In an alternative embodiment, a single bearing may be employed. Ideally, if a single bearing is employed, it should be able to withstand moment forces. In an embodiment where a single bearing is employed, it may be either first bearing 514 positioned in air on a proximal side of a first ferro-fluidic seal 506a or second bearing 516 positioned in air on a distal side of a second ferro-fluidic seal 506b.


The stationary portion of the bearing 514 is attached to a structural member 590 while the stationary portion of the bearing 516 is attached to an inner surface of the enclosure 560. The rotatory portions of the bearings 514, 516 are coupled to and rest on an outer surface of the cylinder 555. An external bearing retaining member 518 is positioned proximal to a periphery of the enclosure 560 while an internal bearing retaining member 520 is coupled to the outer surface of the cylinder 555. Bearing retaining members 518 and 520 allow for one bearing to be movably attached so that it can be adjusted in case of misalignment. Persons of ordinary skill in the art would appreciate that the current arrangement of the bearings 514, 516, and the two ferro-fluidic seals 506a, 506b is only exemplary and may differ in alternate embodiments. Also, the internal bearing retaining member 520 is positioned distal to the bearing 514 while the external bearing retaining member 518 is positioned distal to the internal bearing retaining member 520 and proximate the periphery of the enclosure 560.


The assembly 500 further comprises a DC brush gear motor 509, a roller chain drive 510 and chain 512, wherein the motor 509 is coupled to the target sub-assembly 502 to cause rotation of the sub-assembly 502 and the cylinder 555. In an embodiment, a number 25 size roller chain is used for a 5:1 chain gear ratio in conjunction with a size 16 DC brushed gear motor. In various embodiments, determination of the chain to gear ratio is based upon a desired target sub-assembly rotation speed and motor size/operating speed or running torque.


It should be understood by those of ordinary skill in the art that the X-ray production target assembly 500 is positioned between the electron-source interfaces 524 and collimators 550 of an X-ray source assembly (not shown in its entirety) that optionally includes a linac for generating high-energy electrons.


In accordance with an aspect of the present specification, the target sub-assembly 502 is cooled by circulating water 504 while the sub-assembly 502 is being rotated by the motor 509. In operation, a stationary electron beam 507 is directed to the periphery of the copper body 501 and impinges upon the tungsten ring 503. In some embodiments, energy of electrons in the electron beam 507 is on the order of 6 MV or higher. When the electron beam 507 hits the tungsten ring 503, which is being rotated by the motor 509, X-rays are produced and the energy deposited by the electrons is spread around the target's tungsten ring 503. Since the motor 509 is attached to the chain 512 which in turn is coupled with the target sub-assembly 502 via chain drive 510, rotation of the motor 509 causes movement of the chain 512, which in turn causes rotation of the target sub-assembly 502 and therefore rotation of the copper body 501. In various embodiments, a timing belt, a continuous cable, friction drive, a series of spur gears or direct spur-gear couplings and any drive train which allows remoting the motor from the target shaft may be used instead of the chain 512. This embodiment overcomes the potential deviation of the electron trajectory, as the motor 509 is positioned at a distance from the electron beam 507 and therefore, the motor-induced magnetic and electrical fields do not disturb the electrons.


Referring back to FIGS. 5A and 5B, the target is cooled by cold water flowing in enclosure 560 via conduit 530, circulating and cooling the target sub-assembly 502. Heated water flows out of the enclosure 560 via conduit 532. Flow directors 534 are provided to guide the flow of water in a desired direction. In embodiments, at least one tube 590 is employed to cool the target enclosure or housing 560 with water. Optionally, three tubes 590 are employed.


Persons of ordinary skill in the art would appreciate that the above embodiments are merely illustrative of the many configurations of the target assemblies of present specification. In other embodiments, the target material may comprise pure copper or may be fabricated from other suitable materials such as, but not limited to, a combination of tungsten and rhenium. In addition, as described above, the bearings may be repositioned and placed in air. Alternatively, a single bearing which can resist a moment load (such as a cross-roller or four-point contact bearing) may be employed, thus eliminating the need for the second bearing. Further, other liquids may be used for cooling the target, such as a water and glycol mixture, which is suitable for conditions wherein the target is exposed to near freezing or frozen temperatures. In an embodiment, the water used for cooling the target may also contain corrosion inhibitors. In an embodiment, the target is hit by particle beams other than electrons, such as protons or deuterons. Also, in various embodiments, different types of vacuum seals may be used in place of the ferro-fluidic seal.



FIG. 6 is a flowchart illustrating the steps of operating a rotating radiation production target sub-assembly, in accordance with an embodiment of the present specification. At step 602 a target of the radiation production target sub-assembly is rotated. In an embodiment, the target sub-assembly comprises a copper body that supports the target comprising a target ring brazed in the copper body. In an embodiment, the target ring is comprised of tungsten. In an embodiment, the target is rotated by propelling a jet stream of water at a set of paddles attached to the copper body. In another embodiment, the target is rotated by using a motor coupled with the target sub-assembly. In an embodiment, the motor is a direct motor drive comprising a brushless torque motor. In another embodiment, the motor comprises chain sprockets, threaded through which a chain, a timing belt, friction drive and a continuous cable move to rotate the target.


At step 604, a particle stream is directed toward the rotating target for producing radiation. In an embodiment, the particle stream is a stationary electron beam generated by an electron accelerator which produces X-rays upon hitting the tungsten ring portion of the rotating target.


At step 606, a cooling liquid is circulated around the target, such that the liquid is in contact with at least one surface of the target for dissipating the heat generated by the energy deposited by the stream of particles, thereby lowering the temperature of the target to allow for continuous operation. In an embodiment, the jet stream of water used for rotating the target is also used for cooling the target. In various embodiments, liquids such as but not limited to water or a water and glycol mixture may be used to cool the target.


In an embodiment, the continuously operable rotating X-ray production target assembly of the present specification may be integrated with security systems that can be deployed in locations such as, but not limited to, border control, sea ports, commercial buildings, and/or offices/office buildings.


The above examples are merely illustrative of the many applications of the system of present invention. Although only a few embodiments of the present invention have been described herein, it should be understood that the present invention might be embodied in many other specific forms without departing from the spirit or scope of the invention. Therefore, the present examples and embodiments are to be considered as illustrative and not restrictive, and the invention may be modified within the scope of the appended claims.

Claims
  • 1. A high power radiation production target assembly comprising: a target sub-assembly having a copper body and a target positioned along a periphery of the copper body, wherein said target is configured to be impinged by a stream of particles to produce radiation;a plurality of paddles positioned on said copper body;a stream of liquid adapted to propel said paddles thereby causing a rotation and a cooling of said copper body; and,at least one coupling configured to provide vacuum sealing under rotation.
  • 2. The high power radiation production target assembly of claim 1, wherein said stream of particles comprises electrons that impinge upon the rotating target to produce X-rays.
  • 3. The high power radiation production target assembly of claim 2, wherein the electrons have an energy level and wherein the energy level is 6 MV or higher.
  • 4. The high power radiation production target assembly of claim 1, wherein the target is a ring made of tungsten.
  • 5. The high power radiation production target assembly of claim 1, wherein the target sub-assembly further comprises one or more flow directors configured to direct the stream of liquid in a predefined direction and to propel the plurality of paddles.
  • 6. The high power radiation production target assembly of claim 1, wherein said liquid is water.
  • 7. The high power radiation production target assembly of claim 1, wherein the at least one coupling is a ferro-fluidic coupling configured to provide the vacuum sealing.
  • 8. A high power radiation production target assembly comprising: a target sub-assembly having a copper body and a target along a periphery of the copper body, wherein said target is configured to be impinged by a stream of particles to produce radiation;a stream of liquid adapted to cool said copper body;a chain drive motor configured to cause a rotation of the copper body; and,a coupling configured to provide vacuum sealing.
  • 9. The high power radiation production target assembly of claim 8, wherein said stream of particles comprises an electron beam configured to impinge upon the rotating copper body to produce X-rays.
  • 10. The high power radiation production target assembly of claim 9, wherein the electrons have an energy level and wherein the energy level is 6 MV or higher.
  • 11. The high power radiation production target assembly of claim 8, wherein the target is a ring made of tungsten.
  • 12. The high power radiation production target assembly of claim 8, wherein the chain drive motor is configured to operate with at least one of a chain, a timing belt, a continuous cable, or a direct spur-gear coupling.
  • 13. The high power radiation production target assembly of claim 8, wherein said liquid is water.
  • 14. The high power radiation production target assembly of claim 8, wherein the coupling is a ferro-fluidic coupling configured to provide the vacuum sealing.
  • 15. A method of continuously operating a radiation production target assembly comprising: rotating a target, wherein said target is formed on a periphery of a copper body, and wherein said target is rotated using at least one of a plurality of paddles attached to the copper body, wherein the paddles are adapted to be propelled by a stream of cooling liquid, thereby causing a rotation of the target or a chain drive motor attached to the target;impinging a stream of particles onto the rotating target to produce radiation; andcirculating the cooling liquid around the target, such that the cooling liquid is in contact with at least one surface of the target for dissipating heat generated by the impinging stream of particles, thereby cooling the target and allowing for continuous operation, wherein the target assembly further comprises a coupling adapted to provide a vacuum seal.
  • 16. The method of claim 15, wherein the chain drive motor is operated with at least one of a chain, a timing belt, a continuous cable, or a direct spur-gear coupling.
  • 17. The method of claim 15, wherein said stream of particles comprises an electron beam that impinges upon the rotating target to produce X-rays.
  • 18. The method of claim 17, wherein the electrons have an energy level and wherein the energy level is 6 MV or higher.
  • 19. The method of claim 15, wherein the target is a ring made of tungsten.
  • 20. The method of claim 15, wherein said cooling liquid is water.
  • 21. The method of claim 15, wherein the coupling is a ferro-fluidic coupling.
CROSS-REFERENCE

The present application relies on U.S. Provisional Patent Application No. 62/452,756, entitled “High Power X-Ray Source and Method of Operating the Same” and filed on Jan. 31, 2017, for priority.

US Referenced Citations (320)
Number Name Date Kind
2250322 Atlee Jul 1941 A
2636619 Alexander Apr 1953 A
3275831 Martin Sep 1966 A
3374355 Parratt Mar 1968 A
3439166 Chope Apr 1969 A
3837502 Hornagold Sep 1974 A
3904923 Schwartz Sep 1975 A
4164138 Burkhart Aug 1979 A
4165472 Wittry Aug 1979 A
4239969 Galetta Dec 1980 A
4352021 Boyd Sep 1982 A
4523327 Eversole Jun 1985 A
4658408 Amor Apr 1987 A
4943989 Lounsberry Jul 1990 A
4945562 Staub Jul 1990 A
5014293 Boyd May 1991 A
5041728 Spacher Aug 1991 A
5065418 Bermbach Nov 1991 A
5091924 Bermbach Feb 1992 A
5168241 Hirota Dec 1992 A
5181234 Smith Jan 1993 A
5185778 Magram Feb 1993 A
5197088 Vincent Mar 1993 A
5202932 Cambier Apr 1993 A
5259012 Baker Nov 1993 A
5363940 Fahrion Nov 1994 A
5491734 Boyd Feb 1996 A
5493596 Annis Feb 1996 A
5503424 Agopian Apr 1996 A
5504791 Hell Apr 1996 A
5508515 Enge Apr 1996 A
5600303 Husseiny Feb 1997 A
5606167 Miller Feb 1997 A
5692028 Geus Nov 1997 A
5692029 Husseiny Nov 1997 A
5818054 Randers-Pehrson Oct 1998 A
5842578 Cordeiro Dec 1998 A
5909478 Polichar Jun 1999 A
5910973 Grodzins Jun 1999 A
5940468 Huang Aug 1999 A
5974111 Krug Oct 1999 A
6056671 Marmer May 2000 A
6067344 Grodzins May 2000 A
6081580 Grodzins Jun 2000 A
6151381 Grodzins Nov 2000 A
6192104 Adams Feb 2001 B1
6216540 Nelson Apr 2001 B1
6220099 Marti Apr 2001 B1
6249567 Rothschild Jun 2001 B1
6292533 Swift Sep 2001 B1
6301327 Martens Oct 2001 B1
6320933 Grodzins Nov 2001 B1
6347132 Annis Feb 2002 B1
6418194 McPherson Jul 2002 B1
6421420 Grodzins Jul 2002 B1
6424695 Grodzins Jul 2002 B1
6459761 Grodzins Oct 2002 B1
6459764 Chalmers Oct 2002 B1
6542574 Grodzins Apr 2003 B2
6542580 Carver Apr 2003 B1
6546072 Chalmers Apr 2003 B1
6552346 Verbinski Apr 2003 B2
6614872 Bueno Sep 2003 B2
6628745 Annis Sep 2003 B1
6658087 Chalmers Dec 2003 B2
6665373 Kotowski Dec 2003 B1
6702459 Barnes Mar 2004 B2
6713773 Lyons Mar 2004 B1
6735279 Jacobs May 2004 B1
6843599 Le Jan 2005 B2
6920197 Kang Jul 2005 B2
6924487 Bolozdynya Aug 2005 B2
6928141 Carver Aug 2005 B2
7010094 Grodzins Mar 2006 B2
7046768 Gilevich May 2006 B1
7099434 Adams Aug 2006 B2
RE39396 Swift Nov 2006 E
7151447 Willms Dec 2006 B1
7203276 Arsenault Apr 2007 B2
7207713 Lowman Apr 2007 B2
7215738 Muenchau May 2007 B2
7218704 Adams May 2007 B1
7233644 Bendahan Jun 2007 B1
7322745 Agrawal Jan 2008 B2
7366282 Peschmann Apr 2008 B2
7369643 Kotowski May 2008 B2
7379530 Hoff May 2008 B2
7397891 Johnson Jul 2008 B2
7400701 Cason Jul 2008 B1
7417440 Peschmann Aug 2008 B2
7418077 Gray Aug 2008 B2
7453987 Richardson Nov 2008 B1
7471764 Kaval Dec 2008 B2
7483510 Carver Jan 2009 B2
7486768 Allman Feb 2009 B2
7505556 Chalmers Mar 2009 B2
7517149 Agrawal Apr 2009 B2
7519148 Kotowski Apr 2009 B2
7525101 Grodzins Apr 2009 B2
7526064 Akery Apr 2009 B2
7538325 Mishin May 2009 B2
7555099 Rothschild Jun 2009 B2
7579845 Peschmann Aug 2009 B2
7593506 Cason Sep 2009 B2
7593510 Rothschild Sep 2009 B2
7646851 Liu Jan 2010 B2
7660388 Gray Feb 2010 B2
7720195 Allman May 2010 B2
7742568 Smith Jun 2010 B2
7769133 Carver Aug 2010 B2
7783004 Kotowski Aug 2010 B2
7783005 Kaval Aug 2010 B2
7817776 Agrawal Oct 2010 B2
7856081 Peschmann Dec 2010 B2
7860213 Akery Dec 2010 B2
7864920 Rothschild Jan 2011 B2
7876879 Morton Jan 2011 B2
7876880 Kotowski Jan 2011 B2
7915596 Clothier Mar 2011 B2
7928400 Diawara Apr 2011 B1
7963695 Kotowski Jun 2011 B2
7982191 Friedman Jul 2011 B2
7991133 Mills Aug 2011 B2
7995705 Allman Aug 2011 B2
7995707 Rothschild Aug 2011 B2
8054938 Kaval Nov 2011 B2
8059781 Agrawal Nov 2011 B2
8073099 Niu Dec 2011 B2
8135110 Morton Mar 2012 B2
8138770 Peschmann Mar 2012 B2
8170177 Akery May 2012 B2
8243876 Morton Aug 2012 B2
8275091 Morton Sep 2012 B2
8284898 Ho Oct 2012 B2
8325871 Grodzins Dec 2012 B2
8345819 Mastronardi Jan 2013 B2
8356937 Kotowski Jan 2013 B2
8385501 Allman Feb 2013 B2
8389942 Morton Mar 2013 B2
8428217 Peschmann Apr 2013 B2
8433036 Morton Apr 2013 B2
8439565 Mastronardi May 2013 B2
8442186 Rothschild May 2013 B2
8457274 Arodzero Jun 2013 B2
8457275 Akery Jun 2013 B2
8483356 Bendahan Jul 2013 B2
8491189 Kotowski Jul 2013 B2
8503605 Morton Aug 2013 B2
8503606 Rothschild Aug 2013 B2
8532823 McElroy Sep 2013 B2
8579506 Morton Nov 2013 B2
8604723 Chen Dec 2013 B2
8644453 Morton Feb 2014 B2
8668386 Morton Mar 2014 B2
8674706 Peschmann Mar 2014 B2
8687765 Kotowski Apr 2014 B2
8690427 Mastronardi Apr 2014 B2
8735833 Morto May 2014 B2
8750452 Kaval Jun 2014 B2
8774357 Morton Jul 2014 B2
8798232 Bendahan Aug 2014 B2
8824632 Mastronardi Sep 2014 B2
8831176 Morto Sep 2014 B2
8837670 Akery Sep 2014 B2
8840303 Morton Sep 2014 B2
8842808 Rothschild Sep 2014 B2
8861684 Al-Kofahi Oct 2014 B2
8908831 Bendahan Dec 2014 B2
8929509 Morton Jan 2015 B2
8958526 Morton Feb 2015 B2
8971485 Morton Mar 2015 B2
8971487 Mastronardi Mar 2015 B2
8993970 Morton Mar 2015 B2
9014339 Grodzins Apr 2015 B2
9020095 Morton Apr 2015 B2
9020096 Allman Apr 2015 B2
9020103 Grodzins Apr 2015 B2
9025731 Kotowski May 2015 B2
9042511 Peschmann May 2015 B2
9052271 Grodzins Jun 2015 B2
9052403 Morton Jun 2015 B2
9057679 Morton Jun 2015 B2
9086497 Bendahan Jul 2015 B2
9099279 Rommel Aug 2015 B2
9111331 Parikh Aug 2015 B2
9117564 Rommel Aug 2015 B2
9121958 Morton Sep 2015 B2
9146201 Schubert Sep 2015 B2
9158027 Morton Oct 2015 B2
9218933 Langeveld Dec 2015 B2
9223049 Kotowski Dec 2015 B2
9223050 Kaval Dec 2015 B2
9223052 Morton Dec 2015 B2
9257208 Rommel Feb 2016 B2
9268058 Peschmann Feb 2016 B2
9274065 Morton Mar 2016 B2
9279901 Akery Mar 2016 B2
9285488 Arodzero Mar 2016 B2
9285498 Carver Mar 2016 B2
9291582 Grodzins Mar 2016 B2
9310322 Panesar Apr 2016 B2
9310323 Bendahan Apr 2016 B2
9316760 Bendahan Apr 2016 B2
9329285 Gozani May 2016 B2
9332624 Morton May 2016 B2
9417060 Schubert Aug 2016 B1
9465135 Morton Oct 2016 B2
9466456 Rommel Oct 2016 B2
9535019 Rothschild Jan 2017 B1
9541510 Arodzero Jan 2017 B2
9622333 Nighan, Jr. Apr 2017 B2
9658343 Arodzero May 2017 B2
20020094064 Zhou Jul 2002 A1
20030043964 Sorenson Mar 2003 A1
20030068557 Kumashiro Apr 2003 A1
20040017888 Seppi Jan 2004 A1
20040051265 Nadeau Mar 2004 A1
20040081269 Pan Apr 2004 A1
20040109532 Ford Jun 2004 A1
20040120454 Ellenbogen Jun 2004 A1
20040141584 Bernardi Jul 2004 A1
20040252024 Huey Dec 2004 A1
20040258198 Carver Dec 2004 A1
20050023479 Grodzins Feb 2005 A1
20050024199 Huey Feb 2005 A1
20050053185 Sukovic Mar 2005 A1
20050100135 Lowman May 2005 A1
20050117683 Mishin Jun 2005 A1
20050117694 Francke Jun 2005 A1
20050135668 Polichar Jun 2005 A1
20050157842 Agrawal Jul 2005 A1
20050169421 Muenchau Aug 2005 A1
20050198226 Delia Sep 2005 A1
20050226364 Bernard Oct 2005 A1
20060002515 Huber Jan 2006 A1
20060027751 Kurita Feb 2006 A1
20060056584 Allman Mar 2006 A1
20060114477 Cox Jun 2006 A1
20060140341 Carver Jun 2006 A1
20060182221 Bernhardt Aug 2006 A1
20060249685 Tanaka Nov 2006 A1
20060257005 Bergeron Nov 2006 A1
20060284094 Inbar Dec 2006 A1
20070085010 Letant Apr 2007 A1
20070140422 Elyan Jun 2007 A1
20070140423 Foland Jun 2007 A1
20070170375 Tang Jul 2007 A1
20070172129 Tortora Jul 2007 A1
20070189454 Georgeson Aug 2007 A1
20070210255 Bjorkholm Sep 2007 A1
20070228284 Polichar Oct 2007 A1
20070237293 Singh Oct 2007 A1
20070280502 Paresi Dec 2007 A1
20080037707 Rothschild Feb 2008 A1
20080043910 Thomas Feb 2008 A1
20080048872 Frank Feb 2008 A1
20080084963 Clayton Apr 2008 A1
20080128624 Cooke Jun 2008 A1
20080137805 Forster Jun 2008 A1
20080159591 Ruedin Jul 2008 A1
20080170670 Bhatt Jul 2008 A1
20080198970 Kirshner Aug 2008 A1
20080205594 Bjorkholm Aug 2008 A1
20080211431 Mishin Sep 2008 A1
20080230709 Tkaczyk Sep 2008 A1
20080260097 Anwar Oct 2008 A1
20080304622 Morton Dec 2008 A1
20090067575 Seppi Mar 2009 A1
20090086907 Smith Apr 2009 A1
20090116617 Mastronardi May 2009 A1
20090127459 Neustadter May 2009 A1
20090168964 Safai Jul 2009 A1
20090238336 Akery Sep 2009 A1
20090245462 Agrawal Oct 2009 A1
20090257555 Chalmers Oct 2009 A1
20090285353 Ellenbogen Nov 2009 A1
20090292050 He Nov 2009 A1
20090316851 Oosaka Dec 2009 A1
20100020937 Hautmann Jan 2010 A1
20100066256 Meddaugh Mar 2010 A1
20100111260 Motz May 2010 A1
20100127169 Whittum May 2010 A1
20100161504 Casey Jun 2010 A1
20100177868 Smith Jul 2010 A1
20100177873 Chen Jul 2010 A1
20100188027 Treas Jul 2010 A1
20100202593 Spence Aug 2010 A1
20100295689 Armistead Nov 2010 A1
20110019797 Morton Jan 2011 A1
20110019799 Shedlock Jan 2011 A1
20110038453 Morton Feb 2011 A1
20110064192 Morton Mar 2011 A1
20110075808 Rothschild Mar 2011 A1
20110103554 Charette May 2011 A1
20110204243 Bendahan Aug 2011 A1
20110206179 Bendahan Aug 2011 A1
20110235777 Gozani Sep 2011 A1
20110266643 Engelmann Nov 2011 A1
20120081042 Cheung Apr 2012 A1
20120099710 Kotowski Apr 2012 A1
20120104276 Miller May 2012 A1
20120116720 Klann May 2012 A1
20120206069 Zavadtsev Aug 2012 A1
20120294423 Cheung Nov 2012 A1
20120321049 Langeveld Dec 2012 A1
20130001048 Panesar Jan 2013 A1
20130016814 Treas Jan 2013 A1
20130063052 Ho Mar 2013 A1
20140029725 Ueda Jan 2014 A1
20140185771 Morton Jul 2014 A1
20140197321 Bendahan Jul 2014 A1
20140211919 Ogura Jul 2014 A1
20140270086 Krasnykh Sep 2014 A1
20150036798 Morton Feb 2015 A1
20150078519 Morton Mar 2015 A1
20150301220 Morton Oct 2015 A1
20150355117 Morton Dec 2015 A1
20150355369 Morton Dec 2015 A1
20160025889 Morton Jan 2016 A1
20160033674 Allman Feb 2016 A1
Foreign Referenced Citations (39)
Number Date Country
101006929 Aug 2007 CN
8713042 Jan 1989 DE
19756697 Jul 1999 DE
0077018 Apr 1983 EP
0919186 Jun 1999 EP
0672332 Feb 2000 EP
1413898 Apr 2004 EP
1875866 Jan 2008 EP
1907831 Apr 2008 EP
2212975 Aug 1989 GB
2255634 Nov 1992 GB
2409268 Jun 2005 GB
2424065 Sep 2006 GB
2438317 Nov 2007 GB
201351156 Mar 2013 JP
9855851 Dec 1998 WO
2004010127 Jan 2004 WO
2005098400 Oct 2005 WO
2006036076 Apr 2006 WO
2006053279 May 2006 WO
2006078691 Jul 2006 WO
2007035359 Mar 2007 WO
2007055720 May 2007 WO
2007068933 Jun 2007 WO
2007103216 Sep 2007 WO
2008017983 Feb 2008 WO
2008027706 Mar 2008 WO
2009106803 Sep 2009 WO
2009143169 Nov 2009 WO
2010141101 Dec 2010 WO
2011069024 Jun 2011 WO
2011091070 Jul 2011 WO
2013116549 Aug 2013 WO
2013119423 Aug 2013 WO
2014107675 Jul 2014 WO
2014121097 Aug 2014 WO
2014124152 Aug 2014 WO
2014182685 Nov 2014 WO
2016011205 Jan 2016 WO
Non-Patent Literature Citations (10)
Entry
Heikkinen et al: “Tritium-Target Performance at RTNS-II”, Lawrence Livermore National Laboratory, Livermore, CA 94550, 1983.
International Search Report for PCT/US2018/016284, dated Jun. 15, 2018.
CRS Report for Congress, Aviation Security Technologies and Procedures: Screening Passengers and Baggage, Oct. 26, 2001, pp. 1-12.
Molchanov P A et al: ‘Nanosecond gated optical sensors for ocean optic applications’ Sensors Applications Symposium, 2006. Proceedings of the 2006 IEEE Houston, Texas,USA Feb. 7-9, 2006, Piscataway, NJ, USA,IEEE, Feb. 7, 2006 (Feb. 7, 2006) , pp. 147-150, XP010917671 ISBN: 978-0-7803-9580-0.
Mobile X-Ray Inspection Systems, Internet Citation, Feb. 12, 2007, pp. 1-2, URL:http:// web.archive.org/web/20070212000928/http://www.bombdetecti- on.com/cat--details.php?catid=20.
Smith C. R. et al: ‘Application of 450 kV computed tomography to engine blocks with steel liners’ Materials Evaluation vol. 65, No. 5, 2007, pp. 458-461, XP055108238.
Miller, “Comparison of Standing-Wave and Travelling-Wave Structures”, SLAC Linear Accelerator Conferernce, (1986).
Gao, “Analytical formula for the coupling coefficient Beta of a cavity waveguide coupling system”, Physics Research A, vol. 309, pp. 5-10 (1991).
Ogorodnikov et al., “Processing of interlaced images in 4-10 MeV dual energy customs system for material recognition”, Phys. Rev. Special Topics—Accelerators and Beam, vol. 5, 104701 (2002).
Krasnykh et al., “Concept of RF Linac for Intra-Pulse Multi-Energy Scan”, SLAC Pub-15943, (Apr. 18, 2014).
Related Publications (1)
Number Date Country
20190043686 A1 Feb 2019 US
Provisional Applications (1)
Number Date Country
62452756 Jan 2017 US