| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 81 | 粒状硝酸铵产品 | CN93105353.6 | 1993-05-05 | CN1079458A | 1993-12-15 | R·奥利弗; A·卡尔达斯 |
| 炸药级硝酸铵颗粒的制造方法,它包括:(A)制得基本上尺寸均一的硝酸铵种粒;(B)用硝酸铵或混合的硝酸盐熔体/溶液,将种粒在倾斜的旋转带夹套的盘式制粒器或多级串联的上述盘中加油脂,并干燥,热处理,制得最好不超过约4mm直径的最终加油脂的EGAN颗粒产品。 | ||||||
| 82 | 코팅 장치 및 코팅 방법 | KR1020127020045 | 2010-12-07 | KR101778583B1 | 2017-09-14 | 우메모토켄지; 호소노테츠야; 엔도타로; 카마다히토시; 아키모토나나오; 하세가와코지 |
| 코팅장치는회전드럼(1) 내부의정제층(A)을촬영하는고속도카메라(3)와, 고속도카메라(3)의촬영데이터에의거하여정제층(A)의정제의유동속도를산출하는퍼스널컴퓨터(4)와, 퍼스널컴퓨터(4)에의한정제의유동속도산출값에의거하여회전드럼(1)의회전속도를제어하는제어장치(5)를구비하고있다. | ||||||
| 83 | 팬 코팅 장치 | KR1020117011494 | 2009-10-09 | KR101580487B1 | 2015-12-28 | 후세지마야스토요; 나카무라다쿠야; 데라다다카시; 이소베시게미 |
| 수평의회전축선(O)을중심으로회전하는회전드럼(1)을구비한팬 코팅장치(10)에서, 회전드럼의앞면개구부(7)의전단에개구부(7)보다도큰 단면적을갖는급기챔버(13)를설치한다. 급기챔버(13)는케이스(2)의정면에장착된챔버도어(11) 내에형성되고, 일단측은개구부(7)와연통하고, 타단측은급기구멍(18)을통해서급기덕트(19)와접속된다. 급기덕트(19)로부터급기챔버(13) 내로유입된에어는급기챔버(13)에서유속이저하되고, 기류가안정된상태에서개구부(7)로부터회전드럼(1) 내로공급된다. | ||||||
| 84 | 파우더 처리 방법 | KR1020107002453 | 2003-11-13 | KR1020100029266A | 2010-03-16 | 나이토마키오; 아베히로야; 노기기요시; 호소카와마스오; 후쿠이다케히사; 요시카와마사히로 |
| A powder treatment device (100) having a deposition surface (3a) on which treated powder (50) is deposited and a treatment surface (5a) arranged opposite to the deposition surface (3a) and curved in a projected shape for efficiently manufacturing composite powder and porous granulated matter, comprising a moving means (16) moving the deposition surface (3a) and the treatment surface (5a) relative to each other along the deposition surface (3a), and an excitation treatment means (20) capable of providing an excitation energy from an excitation energy supply part (5a) arranged opposite to the deposition surface (3a) to the treated powder (50) deposited on the deposition surface (3a) or a vibration means (40) vibrating the deposition surface (3a) or the treatment surface (5a) along a direction crossing the deposition surface (3a). | ||||||
| 85 | 파우더 처리 방법, 파우더 처리 장치, 및 다공질 과립의제조 방법 | KR1020057024245 | 2003-11-13 | KR1020060021385A | 2006-03-07 | 나이토마키오; 아베히로야; 노기기요시; 호소카와마스오; 후쿠이다케히사; 요시카와마사히로 |
| A powder treatment device (100) having a deposition surface (3a) on which treated powder (50) is deposited and a treatment surface (5a) arranged opposite to the deposition surface (3a) and curved in a projected shape for efficiently manufacturing composite powder and porous granulated matter, comprising a moving means (16) moving the deposition surface (3a) and the treatment surface (5a) relative to each other along the deposition surface (3a), and an excitation treatment means (20) capable of providing an excitation energy from an excitation energy supply part (5a) arranged opposite to the deposition surface (3a) to the treated powder (50) deposited on the deposition surface (3a) or a vibration means (40) vibrating the deposition surface (3a) or the treatment surface (5a) along a direction crossing the deposition surface (3a). | ||||||
| 86 | 분말 입자를 과립으로 소결하는 공정 및 그 장치 | KR1020000055648 | 2000-09-22 | KR1020010039908A | 2001-05-15 | 게르트트린클; 헬무트야우니히; 안드레아스안조르게; 라이문트반디스작 |
| PURPOSE: Sintering of powder particles into granules is provided, which manufactures a granule having desired size by baking powdery fine particles without using a binder. CONSTITUTION: A process of sintering powder particles(3) into granules comprises: (a) providing a laser(7) to emit a beam(9) of electromagnetic radiation to heat the powder particles; (b) providing a supply of powder particles(3) to be sintered; and (c) causing relative movement between the powder particles and the laser beam such that each particle is subjected to heating by the laser beam for a predetermined duration and the heated particles are thereby sintered to form a plurality of granules. | ||||||
| 87 | 분쇄 및 펌프 가능한 물질 분쇄 및 분배장치 | KR1019990010559 | 1999-03-26 | KR1019990078313A | 1999-10-25 | 킬러안톤 |
| 본발명에따른분쇄및 분배장치는분쇄및 펌프가능한물질특히기계적으로탈수된슬러리를거의같은사이즈의조각으로분쇄하고, 그것을제어가능한량으로다운스트림장치즉 건조기로공급하는데이용될수 있다. 이때문에슬러리는두 개의대향으로이동가능한부분에의해형성된갭을통해운반된다. 본발명에따른장치의바람직한실시예에있어서, 두부분은갭과면하는측상의리세스를나타내며, 이들은상기두 부분이사전설정된회전방향으로서로대향으로회전하는경우크고작은단면적을가지는주기적으로변하는영역을가진슬러리스트랜드가형성되고외측으로운반되어작은단면적을나타내는위치에서부어지는식으로설계된다. | ||||||
| 88 | 회전식 남비형 펠레타이저 | KR1019790001331 | 1979-04-26 | KR1019830001915B1 | 1983-09-23 | 죤소튜아르트닉슨 |
| 내용없음. | ||||||
| 89 | A ROTARY PAN | PCT/IB2006000994 | 2006-04-07 | WO2006109173A9 | 2007-02-15 | GANDOLFI NICOLA; TREBBI ROBERTO |
| Described is a rotary pan (1) of the type comprising a central hollow cylindrical body (3) with end portions (4, 4') shaped substantially like truncated cones, and mixing/deflecting means (7) attached to at least one inside surface of the pan (1) itself; the peripheral inside cylindrical surface (5) of the hollow body (3) comprises an extended zone (A) defined by a uniform distribution of through holes (6) and at least one zone (B) within the zone (A) forming an area by which the mixing/deflecting means (7) are attached or fixed to the peripheral surface (5) . | ||||||
| 90 | METHOD AND DEVICE FOR PRODUCING SPHERICAL FORMS FROM FIBRE PORTIONS | PCT/DE2004002498 | 2004-11-12 | WO2005056172A3 | 2005-08-04 | AY PETER; GLASER CLAUDIA; HILDEBRANDT SVEN; MUELLER-FEHN SIEGFRIED |
| The invention relates to a method and device for producing spherical forms from fibre portions, for which a bonding adhesive is not required. The aim of the invention is to develop a method and an expedient device for carrying out said method, which allow the production of pellets with a low specific gravity and a high porosity, from fibres that can have relatively long lengths, without the use of an additional adhesive. To achieve this, the adhesive characteristics of the individual particles in the product to be processed, i.e. the roughness of the fibres, are used to bond said fibres together and a fibre portion is subjected to a rolling process between at least two roughened surfaces. The working means can consist of horizontal, parallel planar bodies, which are configured to permit displacements in relation to one another by means of an appropriate construction and between which the fibre portions are introduced. | ||||||
| 91 | Drum coater for applying a surface layer on bulk-like materials and mixing tool to be used in a drum coater | US15457010 | 2017-03-13 | US10105724B2 | 2018-10-23 | Pascal Ueberschlag; Juergen Krumm; Jochen Thies |
| A drum coater for applying a surface layer on bulk-like materials includes a rotatably mounted drum for accommodating bulk-like materials, inlet and outlet openings, at least one spray nozzle for applying the surface material, a drying device for a drum interior, at least first and second radially-offset mixing tools in the drum, the first mixing tool protruding into the drum interior. The at least one second mixing tool has at least one mixing surface such that the first mixing tool is at least partially arranged on the drum inner surface and the at least one second mixing tool has at least one opening on the at least one mixing surface. A mixing tool to be used in a drum coater to gently blend and/or homogenize bulk-like materials has a first mixing surface angled relative to a second mixing surface, at least one mixing surface having at least one opening. | ||||||
| 92 | DEVICE FOR PRODUCING A GRANULATE | US15556923 | 2016-03-03 | US20180243748A1 | 2018-08-30 | Alexander SCHMIDT |
| The present disclosure concerns a device for granulating coarse material. Examples of course material include pulverulent solids such as powder, grain, or mixtures thereof. The device disclosed includes a rotor, a screen, and an automatic distance adjusting unit. The rotor is configured to rotate/oscillate and press the coarse material through the screen in order to produce a granulate with a smaller granulate unit size compared to the coarse material. The automatic distance adjusting unit is configured to adjust a distance between the rotor and the screen. | ||||||
| 93 | METHOD OF MANUFACTURING A COMPOSITE GRANULAR GROUTING MATERIAL | US15859019 | 2017-12-29 | US20180193811A1 | 2018-07-12 | Sun Bai |
| A method of manufacturing a composite granular grouting material according to the present invention comprises: mixing bentonite and auxiliary component; forming spherical composite granules by agritating the mixture of bentonite and auxiliary component; drying the formed composite granules; and forming bentonite layer having lower density for forming slurry outside the composite granules by mixing bentonite with the spherical composite granules and agritating the same. The grouting material according to the present invention has excellent thermal conductivity and water blocking capability. | ||||||
| 94 | Seed preparation | US15316120 | 2015-06-01 | US09949424B2 | 2018-04-24 | Robert Meakin |
| A coated seed product, the product comprising: at least one plant seed; and a coating adhered to the exterior of the plant seed, the coating comprising one or more evaporite minerals, preferably polyhalite. | ||||||
| 95 | IRRADIATION TARGET FOR RADIOISOTOPE PRODUCTION, METHOD FOR PREPARING AND USE OF THE IRRADIATION TARGET | US15546184 | 2016-01-19 | US20170365370A1 | 2017-12-21 | Beatrice Schuster |
| The invention provides a sintered rare earth metal oxide target for producing a radioisotope in an instrumentation tube of a nuclear power reactor, wherein the sintered target has a density of at least 90 percent of the theoretical density, and wherein the sintered target contains chromium in an amount of from 500 to 2000 μg/g, and Mg and/or Ca in an amount of from 1000 to 6000 μg/g. The sintered target is prepared by providing a rare earth metal oxide powder, blending the rare earth metal oxide powder with chromium oxide, dry granulating and consolidating the powder in a mold to form a spheroidal green body, and sintering the green body in solid phase to form a spheroidal ytterbia target. | ||||||
| 96 | Powder granulation method and granulation device | US13637042 | 2011-02-22 | US09427717B2 | 2016-08-30 | Hidetoshi Iwamatsu; Yoshiyuki Kato; Katsunobu Yoshimoto; Tsutomu Kurita; Masahiro Suzuki; Katsunori Ishii; Yoshiyuki Kihara |
| A powder granulation method affords greater operation efficiency and working efficiency and enhanced product recovery rate by preventing powder from being adhered to a container inner wall while suppressing variability in particle size of product to the utmost. A plurality of scrapers are disposed so as to abut or come close to the inner face of a bottomed cylindrical container that accommodates powder so that the powder in the container is granulated by causing an inner bottom surface of the container to rotate on a horizontal plane. | ||||||
| 97 | MIXING APPARATUS FOR POWDER RAW MATERIAL AND LIQUID RAW MATERIAL AND METHOD FOR MANUFACTURING MIXTURE USING SAME | US14439710 | 2013-06-21 | US20150290601A1 | 2015-10-15 | Yoshihiro Tsuchimoto |
| A mixing apparatus is provided that evenly mixes a powder raw material and a liquid raw material. The powder raw material is supplied to and spread out on a rotating disk to form a thin layer of dispersed particle swarms close to the periphery of the rotating disk. A rotary atomizer that synchronously rotates on the same axis is provided above the rotating disk. The liquid raw material is supplied to an inside surface of the rotary atomizer. Then, the liquid raw material is conducted to an atomizing head where the liquid raw material is atomized, and droplet swarms are horizontally radiated. The dispersed particle swarms and the droplet swarms are merged and condensed within a tapered wedge-shaped space, with the result that these swarms change into a fine and homogeneous mixture. The mixture is then radiated from the periphery. | ||||||
| 98 | Spray gun | US13502556 | 2010-10-19 | US09073077B2 | 2015-07-07 | Kazuomi Unosawa; Shigemi Isobe; Takerou Adachi; Hirotsune Yasumi; Kouji Fukuda; Naoya Watanabe |
| A spray gun (1) forms a desired spray pattern by atomizing by means of atomizing air (A) a spray liquid which is sprayed from a liquid ejection port (44) opened/closed by a needle valve (4), and jetting pattern air (P) to the flow of spray mist of the atomized spray liquid. A nozzle taper angle (θ1) is set in a range of 5° to 15°, and a cap taper angle (θ2) is set in a range of 20° to 40°. Atomizing air (A) is jetted from a nozzle insertion hole (58) toward the center of a nozzle (3). Pattern air (P) is jetted in a spreading suppressed region (R) wherein the flow of the spray mist does not spread over an area greater than or equal to a predetermined cross-sectional area, to the flow of spray mist, and as a result, the spray mist is more uniformly sprayed over a wide range. | ||||||
| 99 | Pelletizing device and method | US13638295 | 2011-03-28 | US08808590B2 | 2014-08-19 | Jan Lampke; Steffen Silge; Gunther Schurig; Vincent Delatour; Sandra Weyrauch |
| Pelletizing device and method for pelletizing pelletizing materials having a pelletizing disk inclined to the horizontal and provided rotatable wherein the pelletizing disk is driven via a motor device. The pelletizing disk comprises a bottom and a side wall, the effective height of the side wall being variable. The side wall comprises an inner side wall device and an outer side wall device, the inner side wall device being disposed height-adjustable relative to the outer side wall device. | ||||||
| 100 | COATING DEVICE AND COATING METHOD | US13635716 | 2010-12-07 | US20130011548A1 | 2013-01-10 | Kenji Umemoto; Tetsuya Hosono; Tarou Endou; Hitoshi Kamada; Nanao Akimoto; Koji Hasegawa |
| A coating apparatus comprises a high speed camera for imaging a tablet layer in a rotating drum, personal computer for calculating a flow rate of a tablet in the tablet layer based on image data from the high speed camera, and a control apparatus for controlling a rotational speed of the rotating drum based on a calculation value of the flow rate of the tablet obtained by the personal computer. | ||||||
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