| 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 | Movable x-ray apparatus | JP21818198 | 1998-07-31 | JP2000041976A | 2000-02-15 | KADOWAKI TOSHIO; HIRATA GORO; NAKAMURA TOSHIAKI; KONO MASAHIRO |
| PROBLEM TO BE SOLVED: To provide a movable X-rays apparatus wherein a counter wt. such as iron corresponding to wt. of a holding part holding an X-rays tube can be equipped in the hollow part of a support by making thickness and height of the support smaller. SOLUTION: A revolving support 3 is vertically provided on a movable truck 1 and a counter wt. 8 connected with the holding part of an X-rays tube 10 movable in the up and down direction along this support 3 with a wire 9 is hung movably up and down in the support 3. The X-rays tube 10 is rotated in the horizontal plane by a support revolving part provided on the movable truck 1 and constituted of a bearing part 2 and a rotating shaft 4 with a hollow part 5. In addition a projected part 12 entering into the hollow part 5 is provided on the lower part of the counter wt. 8 in the support 3 and when the X-ray tube holding part is elevated to the uppermost level, the counter wt. 8 and the projected part 12 are lowered to the lowermost level on the contrary. In this case, by entering the projected part 12 provided on the lower part of the counter wt. into the hollow part 5 of the support revolving part, the vol. of the hollow part 5 can be utilized as the vol. of the counter wt. COPYRIGHT: (C)2000,JPO | ||||||
| 182 | Radiation equipment | JP31042288 | 1988-12-08 | JPH0695159B2 | 1994-11-24 | 敬 堀内; 良美 山下 |
| 183 | Polymerization method and polymerization apparatus of the molded body made from dental plastic | JP7904790 | 1990-03-29 | JPH0649041B2 | 1994-06-29 | シユテフエン・オツパヴスキ; ペーター・フイツシヤー |
| 184 | Radiation angle variable laser irradiating device | JP20545489 | 1989-08-08 | JPH02154753A | 1990-06-14 | KAGAMI KAZUHIRO; KATAOKA KENZOU; NAKAJIMA TSUNEYUKI; HAYASHIDA MINORU |
| PURPOSE: To improve the incising capacity and the bleeding stopping capacity of the title device by providing a means to vary the radiation angle of a laser beam to radiate from the tip part of a contact probe under a condition in which the diameter of the base edge part of the contact probe is standardized to a fixed diameter. CONSTITUTION: A laser beam 10A to be made incident from a light guiding fiber 1 to an incoming edge surface 2C of a tapered contact probe 2 at an incident angle θ 1 is reflected on a peripheral surface and emitted from a tip part 2B having an angle to exceed a critical angle. For this probe 2, an entire length L 1, a length L 2 of a columnar base edge part 2A, the incident angle θ 1 to the light incoming edge surface 2C, probe cone angle θ 2, and an outer diameter D 1 of the base edge part 2A are standardized to fixed values, a local tapered stage part (reflection surface) 4 having a cone angle θ 5 larger than the cone angle θ 2 of the probe itself is formed with a length L 4 on the outer peripheral surface between the base edge part 2A and the tip part 2B, and a laser beam 10B radiates from the tip part 2B with a large radiation angle θ 3. Thus, the incising capacity and the bleeding stopping capacity of the device can be improved. COPYRIGHT: (C)1990,JPO&Japio | ||||||
| 185 | Ion-beam irradiation device | JP6486387 | 1987-03-18 | JPS63230876A | 1988-09-27 | SASAKI SHIGEO; MATSUMURA YASUSHI; NUSHIHARA AKIRA |
| PURPOSE:To stably neutralize an ion beam with high precision by providing a means for retaining the secondary electron emitted from a sample in the sample at the time of projecting the ion beam on the sample through a neutralizer. CONSTITUTION:When the sample 7 is irradiated by the ion beam 14, the beam is passed through the neutralizer 15, and the electron emitted from a electron source 1 is pulled out by a means 9 and taken out into an ion beam orbit through a control means 11 for controlling the energy of the electron to neutralize the electric charge of the ion beam 14. A first diffusion preventive means 4 for preventing the diffusion of the electron emitted from the electron source 1 to the outside and a second diffusion preventive means 6 for preventing the diffusion of the electron taken out into the ion beam orbit are provided to the neutralizer 15. When the ion beam 14 is projected on the sample 7 in this way, a secondary electron is emitted from the sample 7, hence the space in the vicinity of the surface of the sample 7 is surrounded with the negative potential by a secondary electron emission preventive electrode 17, and the secondary electron is retained in the sample 7. | ||||||
| 186 | Ion-beam irradiation device | JP6486187 | 1987-03-18 | JPS63230875A | 1988-09-27 | SASAKI SHIGEO; FUJISHITA NAOMITSU; MATSUMURA YASUSHI |
| PURPOSE:To stably neutralize the electric charge of the ion on the surface of a sample irrespective of the current density and shape of the ion beam by providing a means for pulling out an electron toward an ion beam and a means for controlling the energy of the electron to the neutralizer of the title ion-beam irradiation device. CONSTITUTION:When an ion beam 10 is projected on the surface of the sample 7, an electron is emitted from the electron source 1 of the neutralizer 11 to neutralize the ion beam 10. A first diffusion preventive means 4 for preventing the diffusion of the electron emitted from the electron source 1 to the outside, a second diffusion preventive means 6 for preventing the diffusion of the electron taken into the ion beam orbit in the direction opposite to the flow of the ion beam 10, a means 20 for pulling out the electron emitted from the electron source 1 toward the ion beam orbit, and a means 22 for controlling the energy of the pulled-out electron are provided to the neutralizer 11. As a result, the probability of capturing electrons by the ion beam 10 is maximized irrespective of the current density, etc., of the ion. | ||||||
| 187 | X-ray transcriber | JP15465584 | 1984-07-25 | JPS6132998A | 1986-02-15 | YAMABE MASAKI; KITAMURA YOSHITAKA; FURUKAWA YASUO |
| PURPOSE:To enable optimum transcription to be constantly performed by detecting the intensity of X-rays irradiated upon each sample or the distribution of X-ray intensity by installing an X-ray intensity detector between an X-ray generator and the sample. CONSTITUTION:An X-ray intensity detector 21 is installed on the support frame 7 of an X-ray window 6 upon which X-rays 12 are irradiated or on a shutter 8 moving from side to side for each transcription, which is located between an X- ray generator and a sample upon which X-rays are irradiated, so that X-ray intensity can be detected during transcription or for each of successive transcriptions. And, it becomes possible to detect the distribution of X-ray intensity by installing some X-ray intensity detectors. Therefore, the duration of exposure to X-ray radiation for each wafer 10 can be optimally controlled. Furthermore, it is also possible to correct X-ray intensity by using X-ray scattering data to control an alignment coil 5. | ||||||
| 188 | Ultraviolet irradiating device | JP4318584 | 1984-03-07 | JPS60191038A | 1985-09-28 | FUSE YOSHIROU; NAGANUMA TAKAO; FUJIMORI AKIYOSHI; ARAI KOUZOU; IGARASHI KATSUTOSHI; NAITOU YUUJI |
| PURPOSE: To obtain the titled device capable of curing efficiently an ultraviolet- setting resin coated on an optical fiber by specifying the major diameter/minor diameter ratio of the elliptic form of the inner circumferential surface of a reflector having an elliptic cylinder-shaped specular inner circumferential surface. CONSTITUTION: A reflector 3 having an elliptic cylinder-shaped inner circumferential surface having 1.02W1.3 major diameter/minor diameter ratio is halved in the direction of the major axis, and assembled and fixed in a case body 10. An air-cooled high-voltage mercury-vapor lamp or an ultraviolet generating source 2 having a light-emitting tube 7 wherein Hg and a metal other than Hg are enclosed and which has 12W24mm diameter and ≥15cm light-emitting diameter is arranged and fixed on the center axis of the first focus of the specular surface of the reflector 3 or around the center axis, and an ultraviolet-transmissive hollow tube 1 is arranged and fixed on the center axis of the second focus or around the center axis. And an opening part for cooling air having an air filter 4 is formed on one side surface of the case body 10, and an air discharge duct 6 is provided. COPYRIGHT: (C)1985,JPO&Japio | ||||||
| 189 | JPS56501381A - | JP50002679 | 1979-10-18 | JPS56501381A | 1981-09-24 | |
| 190 | JPS50143000A - | JP4383475 | 1975-04-10 | JPS50143000A | 1975-11-18 | |
| 191 | JPS49133460A - | JP10100673 | 1973-09-07 | JPS49133460A | 1974-12-21 | |
| 192 | JPS4914168B1 - | JP4934167 | 1967-08-02 | JPS4914168B1 | 1974-04-05 | |
| 193 | レーザ生成プラズマ極端紫外線光源のターゲット | JP2016500295 | 2014-02-18 | JP6397884B2 | 2018-09-26 | ラファック,ロバート ジェイ; タオ,イエジョン |
| 194 | イオン注入均一性を制御するための装置及び技術 | JP2016512063 | 2014-05-02 | JP6379182B2 | 2018-08-29 | スタニスラフ エス トドロフ; ジョージ エム ギャンメル; リチャード アレン スプレンクル; ノーマン イー ハシー; フランク シンクレア; シュヨンウー チャン; ジョセフ シー オルソン; デイヴィッド ロジャー ティンバーレイク; カート ティー デッカー−ルッケ |
| 195 | 電子ビーム照射装置 | JP2015513667 | 2014-04-09 | JP6373262B2 | 2018-08-15 | バクタリ カーヴェ; 坂井 一郎; 横林 孝康 |
| 196 | 光照射装置 | JP2017016371 | 2017-01-31 | JP2018122245A | 2018-08-09 | 紫藤 和孝 |
| 【課題】小型でありながらも、照射強度の高い光を、光ファイバ等の照射対象物の外周面全体に照射可能な光照射装置を提供する。 【解決手段】第1の方向に沿って相対的に移動可能な照射対象物に対して光を照射する光照射装置が、第1の方向と第2の方向とによって規定される基板上に複数列に並んで配置され、照射対象物に対して、第3の方向から光を照射する複数の固体素子を有する光源と、第3の方向に対して、各固体素子から出射される光の広がり角を狭めると共に、各固体素子からの光をそれぞれ所定の角度で屈折させて出射する光学素子と、照射対象物よりも第3の方向下流側に配置された少なくとも2つの第1反射面を有し、光学素子から第1反射面に入射する光の一部を照射対象物に対して反射する第1反射部と、光学素子と第1反射部との間に配置された一対の第2反射面を有し、光学素子から第1反射面に対して光を導光する第2反射部と、を備える。 【選択図】図5 |
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| 197 | 紙製品のマーキング法 | JP2017245752 | 2017-12-22 | JP2018111307A | 2018-07-19 | メドフ マーシャル |
| 【課題】紙製品にマーキングをする新規な方法および該方法によりマーキングされた紙製品を提供する。 【解決手段】肉眼では見えないマーキングで紙製品がマーキングされるように、該紙製品の照射される部分のセルロース系部分の上または中に存在する官能基を変更するために選択された条件下、電子ビーム線の電子が少なくとも0.25MeVのエネルギーを有する電子ビーム線によりもたらされる少なくとも0.10MRadの線量の電離放射線を用いて処理する。 【選択図】なし |
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| 198 | 電子線照射装置 | JP2016209675 | 2016-10-26 | JP2018072076A | 2018-05-10 | 松村 達也; 服部 剛明; 内山 圭吾 |
| 【課題】延在するロッド部の先端側に設けられた電子線出射窓の冷却を効率よく行う。 【解決手段】電子線照射装置1は、電子銃EGと、本体部10及びロッド部20を有する筐体3と、電子線出射窓11と、を具備する。ロッド部20は、先端側の端部に電子線出射窓11が設けられ電子線EBが内部を通過する第1筒状部材21と、第1筒状部材21を包囲する第2筒状部材22と、第1筒状部材21の外壁面と第2筒状部材22の内壁面との間に設けられた冷却気体流路33を少なくとも含む冷却気体流通空間32と、電子線出射空間Rと冷却気体流通空間32とを仕切るように設けられた壁部材24と、を備える。壁部材24には、冷却気体流通空間32から電子線出射空間Rへ冷却気体を噴出させる冷却気体噴出孔40が設けられている。冷却気体噴出孔40は、冷却気体流路33の流路断面積より小さい流路断面積を有する。 【選択図】図6 |
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| 199 | 未硬化の光活性化硬化ポリマーを含む放射線硬化可能媒質を硬化するための方法 | JP2016127329 | 2016-06-28 | JP6313371B2 | 2018-04-18 | フレデリック・エー・バーク・ジュニア; トゥアン・ヴォー−ディン |
| 200 | 撮像装置および電子線照射装置 | JP2016181848 | 2016-09-16 | JP2018045958A | 2018-03-22 | 鈴木 一嘉; 大久保 憲治; 河▲崎▼ 喜代司 |
| 【課題】チャンバ内を減圧することでチャンバに変形が生じても、撮像部の位置ずれや姿勢の変化を緩和ないし防ぐことができる撮像装置を提供する。 【解決手段】減圧された雰囲気内にある撮像対象を撮像する撮像装置1であって、チャンバ2と、撮像部3と、連通部4と、チャンバ2とは離隔して配置されて、撮像部3を所定の姿勢で固定する剛性構造の基準フレーム5とを備え、連通部4は、撮像部3を気密に接続する弾性気密保持部40を備えた撮像装置1である。 【選択図】図1 |
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