| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 具有带泵接纳腔的磁轭的同位素生产系统及回旋加速器 | CN201080020361.2 | 2010-04-16 | CN102422723A | 2012-04-18 | J·诺尔林; T·埃里克松 |
| 一种回旋加速器,其包括用以产生磁场来沿所期望的路径引导带电粒子的磁体组件。回旋加速器还包括磁轭,磁轭具有围绕加速室的轭体。磁体组件定位在轭体中。轭体形成流体地联接到加速室上的泵接纳(PA)腔。回旋加速器还包括真空泵,真空泵构造成将真空引入加速室中。真空泵定位在PA腔中。 | ||||||
| 2 | 移动式直线加速器系统及具备该移动式直线加速器系统的移动式中子源 | CN201480081684.0 | 2014-09-03 | CN106717132A | 2017-05-24 | 山本和男; 川崎定博; 井上博光 |
| 本发明的目的在于,提供一种能抑制从轨道偏离的损耗离子射束的入射,能高效、且低成本地实现放射能力的降低的移动式直线加速器系统及具备该移动式直线加速器系统的移动式中子源,移动式直线加速器系统(100)采用如下结构:在紧靠后级加速器(3)的入口(3a)前设有斩束器(6),排除由前级加速器(2)预加速后的质子射线中未被控制的质子射线,仅使被控制的质子射线射出至后级加速器(3),防止质子射线冲击后级加速器的加速电极等。 | ||||||
| 3 | 具有可移隔板的声延迟线 | CN98109293.4 | 1998-04-04 | CN1147210C | 2004-04-21 | 丰田英二郎 |
| x射线沿轴向传到真空导管。多个第一隔板设在导管中。各隔板中心有第一通孔。该隔板轴向划分导管内部成多个分隔空间。多个第二隔板对应各第一隔板。第二隔板设在相对第一隔板之一的某间隙处,各第二隔板中心有第二通孔。x线穿过第二通孔。支撑件将第二隔板连在一起并固定其相对位置。驱动单元将支撑件支撑在导管内部并驱动该构件,以按内部x射线通量中心轴的摆动移动第二隔板。膜片密封导管输出端和传送x射线。 | ||||||
| 4 | 具有可移隔板的声延迟线 | CN98109293.4 | 1998-04-04 | CN1206200A | 1999-01-27 | 丰田英二郎 |
| X射线沿真空导管的轴向传送到真空导管。多个第一隔板设置在真空导管中。每个第一隔板在其中心区形成有第一通孔。第一隔板划分在轴方向上的真空导管的内部空间和限定多个分隔空间。多个第二隔板被提供成每个相应于每个第一隔板。第二隔板设置在相对于第一隔板之一的某个间隙,每个第二隔板在其中心区形成有第二通孔。通过真空导管传送的X射线穿过第二通孔。支撑构件把第二隔板连接在一起和固定第二隔板的相对位置。支撑构件驱动单元把支撑构件支撑在真空导管的内部空间和驱动支撑构件,以根据传送真空导管的内部空间的X射线的通量的中心轴的摆动移动第二隔板。膜片密封真空导管的输出端和传送X射线。 | ||||||
| 5 | ターゲットアセンブリの生成チャンバ内の固体ターゲットを作製するためのシステムおよび方法 | JP2018083529 | 2018-04-25 | JP2018190711A | 2018-11-29 | マーティン・パーナステ; フレドリック・ハンス・レンセイ; キャサリン・マリー・ガグノン; ミカエル・カールボム; トーマス・エリクソン |
| 【課題】ターゲットアセンブリの生成チャンバ内の固体ターゲットを作製するためのシステムおよび方法を提供する。 【解決手段】システムは、生成チャンバを有するターゲットアセンブリを含む。ターゲットアセンブリは、電極と、生成チャンバに露出された導電性ベースと、を含む。ターゲットアセンブリは、生成チャンバへのアクセスを提供する流体ポートを有する。システムはまた、貯蔵容器と、流体ポートに接続する流体ラインと、を有する流体制御システムを含む。貯蔵容器および生成チャンバは、流体ラインの少なくとも1つを介して流体連通している。システムはまた、電極および導電性ベースに電気的に接続されるように構成された電源を含む。生成チャンバ内に電解液が配置されると、生成チャンバ、電極、および導電性ベースが電解槽を形成する。電源は、導電性ベースに沿って固体ターゲットを堆積させるために、電極および導電性ベースに電圧を印加するように構成される。 【選択図】図1 |
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| 6 | 可搬型線形加速器システムおよびそれを備えた可搬型中性子源 | JP2016546230 | 2014-09-03 | JP6239133B2 | 2017-11-29 | 山本 和男; 川▲崎▼ 定博; 井上 博光 |
| 7 | Sonic shock delay line of X-ray lithography for beam line | JP10084497 | 1997-04-04 | JP3190596B2 | 2001-07-23 | 英二郎 豊田 |
| 8 | Cyclic accelerator for accelerating charge carriers and method for manufacturing a cyclic accelerator | US15000777 | 2016-01-19 | US10136508B2 | 2018-11-20 | Karl Haberger |
| What is shown is a cyclic accelerator for accelerating charge carriers. The cyclic accelerator includes a charge carrier source configured to generate free charge carriers, a vacuum chamber configured to receive the free charge carriers, wherein the vacuum chamber is produced by means of MEMS technology, and wherein at least a main surface region of the vacuum chamber has a semiconductor material. In addition, the cyclic accelerator has electrodes configured to accelerate the free charge carriers in the vacuum chamber by means of an alternating current field, and a magnetic field generator configured to generate a magnetic field perpendicularly to the direction of movement of the charge carriers. | ||||||
| 9 | Cyclotron and method for controlling the same | US15616502 | 2017-06-07 | US10123406B1 | 2018-11-06 | John Hans Melin; Erik Koffmar; Nils Tynelius; Oskar Svedberg |
| Cyclotron includes an acceleration chamber, a vacuum system, an ion source system, and a control system that is configured to determine at least one operating parameter as a particle beam is directed along a beam path of the cyclotron. The control system is configured to decrease a supply of the charged particles for the particle beam based on the at least one operating parameter. The particle beam continues after decreasing the supply of the charged particles. The control system is also configured to increase the supply of the charged particles for the particle beam after a predetermined time period or in response to determining that an amount of gas molecules has reduced based on the at least one operating parameter. | ||||||
| 10 | APPARATUS AND METHODS FOR DEPOSITION OF MATERIALS ON INTERIOR SURFACES OF HOLLOW COMPONENTS | US15696836 | 2017-09-06 | US20180073128A1 | 2018-03-15 | Andre Anders |
| This disclosure provides systems, methods, and apparatus related to deposition techniques using laser ablation. In one aspect, an optical fiber and target of a material to be deposited on a first region of an interior surface of a hollow component are positioned in the hollow component. A first end of the optical fiber is coupled to a laser system. A second end of the optical fiber is proximate the target. The material is deposited on the first region of the interior surface of the hollow component by directing a first laser pulse from the laser system through the optical fiber to impinge on the target. | ||||||
| 11 | Beam Guiding Apparatus | US15067691 | 2016-03-11 | US20160198557A1 | 2016-07-07 | Andreas Enzmann |
| A beam guiding apparatus includes a vacuum chamber that includes a target region arranged to receive a target material for generating EUV radiation. The vacuum chamber includes a first and second opening for receiving into the vacuum chamber a first and second laser beam, respectively. The first and second laser beam have different wavelengths. The beam guiding apparatus further includes a superposition apparatus arranged to superpose the first and second laser beams entering into the vacuum chamber through the first and second openings, respectively, for common beam guidance in the direction of the target region. The superposition apparatus comprises a first optical element configured to seal the first opening of the vacuum chamber in a gas-tight manner and transmit the first laser beam, or a second optical element configured to seal off the second opening of the vacuum chamber in a gas-tight manner and transmit the second laser beam. | ||||||
| 12 | ISOTOPE PRODUCTION SYSTEM AND CYCLOTRON HAVING A MAGNET YOKE WITH A PUMP ACCEPTANCE CAVITY | US12435949 | 2009-05-05 | US20100282979A1 | 2010-11-11 | Jonas Norling; Tomas Eriksson |
| A cyclotron that includes a magnet assembly to produce a magnetic field to direct charged particles along a desired path. The cyclotron also includes a magnet yoke that has a yoke body that surrounds an acceleration chamber. The magnet assembly is located in the yoke body. The yoke body forms a pump acceptance (PA) cavity that is fluidicly coupled to the acceleration chamber. The cyclotron also includes a vacuum pump that is configured to introduce a vacuum into the acceleration chamber. The vacuum pump is positioned in the PA cavity. | ||||||
| 13 | Acoustic delay line with movable partition plates | US49229 | 1998-03-27 | US6031889A | 2000-02-29 | Eijiro Toyota |
| X-rays transmit through a vacuum duct along an axial direction of the vacuum duct. A plurality of first partition plates are disposed in the vacuum duct. Each of the first partition plates is formed with a first through hole at a central area thereof. The first partition plates divide the inner space of the vacuum duct in the axial direction and define a plurality of partitioned spaces. A plurality of second partition plates are provided each corresponding to each of the first partition plates. The second partition plate is disposed at a certain gap relative to a corresponding one of the first partition plates, each of the second partition plates being formed with a second through hole at a central area thereof, the X-rays transmitting through the vacuum duct passing through the second through hole. A support member connects the second partition plates together and fixes a relative position of the second partition plates. A support member driving unit supports the support member in the inner space of the vacuum duct and drives the support member to move the second partition plates in accordance with a swing of a central axis of a flux of the X-rays transmitting through the inner space of the vacuum-duct. A film hermetically seals an output end of the vacuum duct and transmits the X-rays therethrough. | ||||||
| 14 | Wall structure for vacuum enclosure | US539102 | 1975-01-07 | US3980446A | 1976-09-14 | Paolo della Porta; Tiziano A. Giorgi |
| A wall structure comprising a first surface defining the commencement of a thickness of a metal or ceramic sheet, and a second surface defining the end of said thickness of said sheet said second surface also defining the commencement of a thickness of a three dimensional network defining a multiplicity of interconnecting free cells and a third surface defining the end of said thickness of said three dimensional network. | ||||||
| 15 | High power chamber | US3489894D | 1966-07-21 | US3489894A | 1970-01-13 | CRAM ROBERT D |
| 16 | Electron accelerator tube | US32932753 | 1953-01-02 | US2822491A | 1958-02-04 | ROLF WIDEROE |
| 17 | SYSTEM AND METHOD FOR MAKING A SOLID TARGET WITHIN A PRODUCTION CHAMBER OF A TARGET ASSEMBLY | US15586696 | 2017-05-04 | US20180322972A1 | 2018-11-08 | Martin Pärnaste; Fredrik Rensei; Katherine Gagnon; Mikael Carlbom; Tomas Eriksson |
| System includes a target assembly having a production chamber. The target assembly includes an electrode and a conductive base exposed to the production chamber. The target assembly has fluidic ports that provide access to the production chamber. The system also includes a fluidic-control system having a storage vessel and fluidic lines that connect to the fluidic ports. The storage vessel and the production chamber are in flow communication through at least one of the fluidic lines. The system also includes a power source that is configured to be electrically connected to the electrode and the conductive base. The production chamber, the electrode, and the conductive base form an electrolytic cell when an electrolytic solution is disposed in the production chamber. The power source is configured to apply voltage to the electrode and the conductive base to deposit a solid target along conductive base. | ||||||
| 18 | Magnetic field compensation in a linear accelerator | US15450666 | 2017-03-06 | US10021774B2 | 2018-07-10 | Shmaryu M. Shvartsman; James F. Dempsey |
| A system has a linear accelerator, ion pump and a compensating magnet. The ion pump includes an ion pump magnet position, an ion pump magnet shape, an ion pump magnet orientation, and an ion pump magnet magnetic field profile. The compensating magnet has a position, a shape, an orientation, and a magnetic field profile, where at least one of the position, shape, orientation, and magnetic field profile of the compensating magnet reduce at least one component of a magnetic field in the linear accelerator resulting from the ion pump magnet. | ||||||
| 19 | DEVICE FOR ELECTRICALLY CONNECTING SYNCHROTRON RING SECTIONS | US15463770 | 2017-03-20 | US20170279205A1 | 2017-09-28 | Loys GOIRAND; Thierry BROCHARD; Joel PASQUAUD |
| A device of electric connection between two successive sections of the ring-shaped pipe of a synchrotron, including: first and second end parts capable of being fastened to the sections, each including a tubular portion with facets; electrically-conductive resilient fingers, each of which bears on each of the two tubular portions while being able to slide on one of said facets; and at least one arm bearing on each finger, each arm being fixed with respect to one of the end parts. | ||||||
| 20 | TRANSPORTABLE LINEAR ACCELERATOR SYSTEM AND TRANSPORTABLE NEUTRON SOURCE EQUIPPED THEREWITH | US15324870 | 2014-09-03 | US20170223815A1 | 2017-08-03 | Kazuo YAMAMOTO; Sadahiro KAWASAKI; Hiromitsu INOUE |
| For the purpose of providing a transportable linear accelerator system which can restrain entering of losing ion beams deviated from a trajectory therefor, to thereby efficiently achieve reduction in radioactivity at low cost, and a transportable neutron source equipped therewith, a transportable linear accelerator system is configured to be provided with a beam chopper just before an inlet of a post-accelerator, thereby to cut off, from the proton beams pre-accelerated by a pre-accelerator, uncontrolled proton beams, and thus to radiate only the controlled proton beams to the post-accelerator, so that the proton beams are prevented from hitting an acceleration electrode, etc. of the post accelerator. | ||||||
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