子分类:
- G21K1/003: .{利用辐射压力对带电粒子的操纵,例如,光悬浮(带电粒子的加速入H05H5/00, H05H7/00, H05H9/00, H05H11/00, H05H13/00)}
- G21K1/006: .{利用辐射压力对中性粒子的操纵,例如,光悬浮(中性粒子的产生或加速入H05H3/00)}
- G21K1/02: .使用光阑、准直器
- G21K1/06: .应用衍射、折射或反射,如单色仪(G21K1/10,G21K7/00优先)
- G21K1/08: .用电或磁装置使束流偏转、集中或聚焦(放电管的电子光学的装置入H01J29/46;零部件,如用于直流电压加速器或使用单脉冲的加速器中的电或磁偏转装置入H05H5/02;用于向轨道内注入粒子的装置入H05H7/08;用于从轨道中射出粒子的装置入H05H7/10)
- G21K1/10: .散射器件;吸收器件;电离辐射过滤器
- G21K1/14: .使用电荷交换器件,例如用于束流的电荷中性化或改变其符号(中性粒子束的产生或加速入 H05H3/00)
- G21K1/16: .应用极化装置,如用于获得极化的离子束{(离子源, 离子枪入H01J27/02 ; 用于产生核反应的极化靶入 H05H6/005)}
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 181 | JPH0164060U - | JP12873988 | 1988-09-30 | JPH0164060U | 1989-04-25 | |
| 182 | Method of obtaining x ray image data and apparatus for storing x ray image | JP6799988 | 1988-03-22 | JPS6426834A | 1989-01-30 | ARUBAATO MAKOBUSUKII |
| PURPOSE: To obtain X-ray image data on a photographic film with two different X-ray spectra by providing a couple of flash screens which receive a high- and a low-energy X-ray beam and a filter which is arranged between those flash screens, and separating the spectra of two images. CONSTITUTION: The X-ray beam 12 from an X-ray source 11 is passed through an object 10 and projected on a parallel array consisting of the flash screens 14 and 20, base bodies 15 and 18 having photosensitive surfaces 16 and 19, and an optically nonconductive X-ray filter 17. The low-energy X rays are selectively absorbed by the screen 14 and the high-energy X rays reach the screen 20, so that the lights from the screens are recorded on the photosensitive surfaces 16 and 19 respectively. The X-ray filter 17 is arranged between the screens 14 and 20 and filters the X-ray beam passed through the screen 14. Consequently, the separation of spectra is improved to obtain X-ray projection data on the photosensitive films with different X-ray spectra. | ||||||
| 183 | JPS63501100A - | JP50464086 | 1986-08-27 | JPS63501100A | 1988-04-21 | |
| 184 | Thermal neutron generator | JP22633386 | 1986-09-26 | JPS6280600A | 1987-04-14 | BORUFUGANKU SHIYURUTSU |
| 185 | Assembly of moderator and beam-port | JP895085 | 1985-01-21 | JPS60162947A | 1985-08-24 | UIRIAMU RESURII HOITSUTOMOA |
| 186 | Level discriminating deflection magnet for atomic beam tube | JP1287981 | 1981-02-02 | JPS57128088A | 1982-08-09 | KARIYA NORIJI; TOYAMA JIROU; JIYUUMONJI HIROMICHI; KIHARA MASAMI |
| PURPOSE:To augment signals a beam carries running through an atom beam tube in an efficient level discriminating deflection magnet by a method wherein a gap is formed between concentrically arranged inner and outer magnetic poles and the atomic beam is let to pass through the magnetic path in the yoke. CONSTITUTION:An inner magnetic pole 9 is positioned in a yoke 8 with a cylindrical hollow core. A circular gap 11 is provided between the inner magnetic pole 9 and outer magnetic pole 10 arranged concentrically. Poles of the same polarity of permanent magnets 7 facing inward are positioned between the yoke 8 and the outer magnetic pole 10. A plurality of slits 12 is boredly provided on an end surface of the yoke 8, the diameter of the slits roughly equal to the width of the gap 11. An atomic beam 13 is let to transmit through the gap 11 and the slits 12, which augments the signal that is carried by the atomic beam 13 and prevents magnetic force from leaking through the sides of the slits 12 provided in the yoke 8. The cross sections of the inner and outer magnetic poles can be other than circular and the beam path is partially corrugated to enhance magnetic field irregularity therein. | ||||||
| 187 | ROTARY CHARGE STRIPPING FILM IN CHARGE STRIPPING DEVICE OF ION BEAM AND CHARGE STRIPPING METHOD OF ION BEAM | US16320340 | 2017-07-27 | US20190237212A1 | 2019-08-01 | Mutsuaki Murakami; Masamitsu Tachibana; Atsushi Tatami; Hiroo Hasebe |
| An object of the present invention is to provide a charge stripping film in a charge stripping device of an ion beam, which has high heat resistance and no toxicity, with which there is no risk of activation, with which an ion beam can be made multivalent even if the charge stripping film is thin, and which is resistant to high-energy beam radiation over an extended period of time. The present invention comprises a charge stripping film used in a device which strips a charge of an ion beam, wherein the charge stripping film is a rotary charge stripping film comprising a carbon film having a thermal conductivity of 20 W/mK or more in a film surface direction at 25° C., and a film thickness of the carbon film is more than 3 μm and less than 10 μm. The present invention also comprises a charge stripping film used in a device which strips a charge of an ion beam, wherein the charge stripping film is a rotary charge stripping film comprising a carbon film produced by a polymer annealing method, and a film thickness of the carbon film is more than 3 μm and less than 10 μm. | ||||||
| 188 | X-ray battery adapter system | US15478369 | 2017-04-04 | US10122102B1 | 2018-11-06 | Gilbert John Garduno; Orlando Thomas Lopez; Kyle Matthew Sternberg |
| An x-ray battery adapter system may include an x-ray battery adapter and a geometry adapter. The x-ray battery adapter may include a circuit board, a baseplate, a heat sink, a cover, and a battery input. The baseplate may include a connector that connects to an x-ray generating device. The geometry adapter may include a cable, a battery receptacle configured to house a battery, and a voltage sensor and battery connector block assembly. The x-ray battery adapter may allow a user of an x-ray generating device to utilize different power sources. | ||||||
| 189 | ADVANCED FISSILE NEUTRON DETECTION SYSTEM AND METHOD | US15488382 | 2017-04-14 | US20180299568A1 | 2018-10-18 | Andrew INGLIS; Alison FORSYTH; Zach HARTWIG; Philip TABER; Timothy TEAL; Hidefumi TOMITA |
| A fissile neutron detection system includes an ionizing thermal neutron detector arrangement including an inner peripheral shape that at least substantially surrounds a moderator region for detecting thermal neutrons that exit the moderator region but is at least generally transparent to the incident fissile neutrons. A moderator is disposed within the moderator region having lateral extents such that any given dimension that bisects the lateral extents includes a length that is greater than any thickness of the moderator arrangement transverse to the lateral extents. The moderator can include major widthwise and major lengthwise lateral extents such that any given dimension across the lengthwise and widthwise lateral extents includes a length that is greater than any thickness of the moderator arrangement transverse to the lateral extents. | ||||||
| 190 | Device and method for generating vortex beam generation | US15481578 | 2017-04-07 | US10101505B2 | 2018-10-16 | Jian Wang; Jing Du; Jifang He |
| A vortex beam device includes: a metal reflector, a low refractive index layer, and multiple elliptical dielectric elements. The low refractive index layer located on the metal reflector. The multiple elliptical dielectric elements are embedded in the low refractive index layer and arranged in an array, major axes of the multiple elliptical dielectric elements are parallel or coincident. The multiple elliptical dielectric elements have a same thickness. A thickness of the low refractive index layer is greater than a thickness of the elliptical dielectric element. An outer surface of each elliptical dielectric element is flush with an outer surface of the low refractive index layer. A refractive index of the low refractive index layer is less than a refractive index of the elliptical dielectric element. | ||||||
| 191 | PARTICLE BEAM TRANSPORT SYSTEM, AND SEGMENT THEREOF | US15747903 | 2016-07-07 | US20180214715A1 | 2018-08-02 | Shigeki TAKAYAMA; Ikuo WATANABE; Yoshifumi NAGAMOTO; Takeshi YOSHIYUKI; Takashi YAZAWA |
| Provide a particle beam transport system that contribute to reduction of construction period and cost for a particle beam treatment facility including plural treatment rooms accommodating a particle-beam irradiation equipment.A particle beam transport system 10 includes: a main line 31 configured to transport a particle beam generated by an accelerator outward; a branch line 22 branching from the main line 31; irradiation equipments 30(30a-30d) provided at respective ends of the branch line 22 and configured to irradiate a patient with the particle beam, wherein at least a part of the main line 31 and the branch line 22 is configured as plural segments 20; and beam characteristics of the particle beam of each of the plural segments 20 are substantially equal at both ends. | ||||||
| 192 | EUV MULTILAYER MIRROR | US15576116 | 2016-07-20 | US20180137948A1 | 2018-05-17 | Satoshi ICHIMARU; Masatoshi HATAYAMA; Masaharu NISHIKINO; Masahiko ISHINO |
| To suppress the breakage of a mirror for reflecting high-intensity EUV light, an EUV multilayer mirror presenting a Bragg diffraction effect is formed by a pile of a plurality of heavy-element layers (102) and a plurality of light-element layers (103) disposed on a substrate (101), wherein the light-element layers and the heavy-element layers are alternately deposited. The heavy-element layers (102) contain niobium as a main component, and the light-element layers (103) contain silicon as a main component. For example, the heavy-element layers (102) made of niobium and the light-element layers (103) made of silicon are alternately deposited on the substrate (101) made of single-crystal silicon. | ||||||
| 193 | Control system using a phase modulation capable acousto-optic modulator for diverting laser output intensity noise to a first order laser light beam and related methods | US15342372 | 2016-11-03 | US09958711B1 | 2018-05-01 | Randall K. Morse; Peter A. Wasilousky; Lee M. Burberry; Michael R. Lange; Catheryn D. Logan; Pat O. Bentley |
| A laser system may include a laser source configured to generate a laser light beam and an acousto-optic modulator (AOM). The AOM may include an acousto-optic medium configured to receive the laser light beam, and a phased array transducer comprising a plurality of electrodes coupled to the acousto-optic medium and configured to cause the acousto-optic medium to output a zero order laser light beam and a first order diffracted laser light beam. The system may further include a beamsplitter downstream from the AOM and configured to split a sampled laser light beam from the zero order laser light beam, a photodetector configured to receive the sampled laser light beam and generate a feedback signal associated therewith, and a radio frequency (RF) driver configured to generate an RF drive signal to the phased array transducer electrodes so that noise is diverted to the first order diffracted laser light beam based upon the feedback signal. | ||||||
| 194 | Light-trapping cancer cell stage testing method | US15235159 | 2016-08-12 | US09958663B2 | 2018-05-01 | Shih-Kun Liu; Li-Chin Chen; Chia-Ching Tsai; Wen-Kai Hsieh; Fong-Min Hsu; Yong-Jai Shen; Wei-Yi Sung |
| A light-trapping cancer cell stage testing method includes: measuring a first average escape velocity or range of first cancer cells and a second average escape velocity or range of second cancer cells whose stage is known and differ from that of the first cancer cells and whose types are known; utilizing the first average escape velocity and the second average escape velocity to calculate a reference ratio to build a database; selecting stage-unknown cancer cells and measuring an escape velocity of the stage-unknown cancer cells (type-known); utilizing the escape velocity of the stage-unknown cancer cells and an escape velocity of reference-stage cancer cells to calculate a ratio; and determining a stage of the stage-unknown cancer cells with a result comparing the ratio of the escape velocities for the stage-unknown cancer cells with the reference ratios stored in the database. | ||||||
| 195 | UNDULATOR | US15527447 | 2015-11-13 | US20180098412A1 | 2018-04-05 | SHAN QIAO; RUI CHANG; FUHAO JI; MAO YE |
| An undulator comprises at least M permanent magnet periods arranged sequentially in a transmission direction of electron beams, each of the permanent magnet periods comprises four rows of permanent magnet structures, in which each row comprises N rows of permanent magnet groups, and each row of the permanent magnet groups comprises K permanent magnet units, wherein M, N and K are natural numbers greater than or equal to 1; the four rows of the permanent magnet structures are pairwise matched, then relatively disposed on both sides of the transmission direction of electron beams, and are capable of forming at least one composite magnetic fields by relative displacement, such that elliptically polarized light, circularly polarized light, or linearly polarized light with an arbitrary polarization angle of 0°˜360° is generated when electron beams pass through the composite magnetic fields, and such that velocity directions of electrons are deviated from an axis direction of the undulator. | ||||||
| 196 | ATOM AND ION SOURCES AND SINKS, AND METHODS OF FABRICATING THE SAME | US15724906 | 2017-10-04 | US20180098411A1 | 2018-04-05 | Jonathan J. Bernstein |
| A bi-directional device for generating or absorbing atoms or ions. In some embodiments, the device comprises a solid-phase ion-conducting material, a first electrode positioned on a first surface of the solid-phase ion-conducting material, and a second electrode positioned on a second surface of the solid-phase ion-conducting material. The first electrode includes a plurality of triple phase boundaries, each located at an interface between the solid-phase ion-conducting material and the first electrode. A density of the triple phase boundaries is in the range of about 104 m/m2 to about 2×107 m/m2 on the first surface of the ion-conducting material. A method of operating the bi-directional device and a method of fabricating a bi-directional device are also provided. | ||||||
| 197 | Apparatus, Systems and Methods for Conversion of Scalar Particle Flow to an Electrical Output | US15487212 | 2017-04-13 | US20170323692A1 | 2017-11-09 | Graham K. Hubler; Joseph Aviles, JR. |
| A scalar particle conversion apparatus, system and method are disclosed. The apparatus includes an anode and a crystalline cathode disposed within an electrolytic fluid or gas. A voltage source is configured to generate a current between the anode and the cathode and one or more components within the electrolytic fluid or gas are loaded into the crystalline cathode. The crystalline cathode generates photons through the interaction between a scalar particle flow and oscillating magnetic hyperfine fields within the crystalline cathode via the inverse Primakoff effect. One or more energy conversion devices are arranged with respect to the crystalline cathode so as to convert the photons or heat from the crystalline cathode to an electrical output. | ||||||
| 198 | ROTATING ENERGY DEGRADER | US15265230 | 2016-09-14 | US20170229205A1 | 2017-08-10 | Alexandre DEBATTY; Nicolas GÉRARD |
| Embodiments disclose an energy degrader for attenuating the energy of a charged particle beam, comprising a first energy attenuation member presenting a beam entry face having the shape of a part of a first helical surface, a second energy attenuation member presenting a beam exit face having the shape of a part of a second helical surface, the beam exit face being positioned downstream of said beam entry face with respect to the beam direction, and a drive assembly for rotating the first and/or the second energy attenuation members about respectively a first and/or a second rotation axis while crossed by the particle beam. The first and second helical surfaces are continuous surfaces and have the same handedness, to enable a more compact degrader with a smaller moment of inertia. | ||||||
| 199 | DEVICE AND METHOD FOR GENERATING VORTEX BEAM GENERATION | US15481578 | 2017-04-07 | US20170212282A1 | 2017-07-27 | Jian WANG; Jing DU; Jifang HE |
| A vortex beam device includes: a metal reflector, a low refractive index layer, and multiple elliptical dielectric elements. The low refractive index layer located on the metal reflector. The multiple elliptical dielectric elements are embedded in the low refractive index layer and arranged in an array, major axes of the multiple elliptical dielectric elements are parallel or coincident. The multiple elliptical dielectric elements have a same thickness. A thickness of the low refractive index layer is greater than a thickness of the elliptical dielectric element. An outer surface of each elliptical dielectric element is flush with an outer surface of the low refractive index layer. A refractive index of the low refractive index layer is less than a refractive index of the elliptical dielectric element. | ||||||
| 200 | Method of inspecting a part using a marking template for radiography | US14991179 | 2016-01-08 | US09658172B2 | 2017-05-23 | James Raphord Barrett; Jason Armstrong; Doug Nikolas; Andrew Isaac Deceuster; Lawrence Lang |
| A method of inspecting a part is provided that includes the steps of aligning a contoured sheet having at least one surface that corresponds to at least one surface of the part, the contoured sheet having first portions and second portions, the first portions being radiodense and the second portions being radiolucent, and at least some of the second portions corresponding to internal features of the part. The part with the contoured sheet is exposed to x-rays to produce a first radiograph with markings that correspond to the first and second portions of the contoured sheet. | ||||||
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