子分类:
- B01J2/003: .{后续颗粒涂覆}(阻止颗粒粘结聚集入B01J 2/30)
- B01J2/006: .{涂覆颗粒,但是没有描述方法或所用设备}(预防颗粒粘结聚集入B01J 2/30)
- B01J2/02: .将液体原料分成珠滴,例如喷雾和固化成珠(喷雾蒸发入B01D 1/16)
- B01J2/10: .在装备有搅拌或混合装置的静置罐或槽内
- B01J2/12: .在旋转罐内
- B01J2/14: .在旋转盘或锅内
- B01J2/16: .将粉末原料悬浮在一种气体中,例如在流化床内或像一个向下流动的帘幕内
- B01J2/18: .用一振动装置
- B01J2/20: .将原料挤压,例如,通过网眼并切断挤出的长条
- B01J2/22: .在模子内或在两辊子间挤压
- B01J2/24: .从一表面刮掉固体层而获得片状粉末
- B01J2/26: .在环形传送带上
- B01J2/28: .使用特殊的黏合剂
- B01J2/30: .使用附加剂防止颗粒黏结在一起;使颗粒物质成为自由流动材料,例如使它们成为憎水的
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 121 | 制备带静电颗粒的方法 | CN95194735.4 | 1995-06-13 | CN1156466A | 1997-08-06 | J·F·休斯 |
| 一种制备带静电的高电阻材料颗粒的方法,包括在等于或高于其玻璃相变温度,或高于其熔点温度时,把一种单极电荷加到材料中,该单极电荷加到材料本体中,并接着将带电材料粉碎,或者在生成其颗粒的同时,将电荷加到材料中。 | ||||||
| 122 | 化学物质的净化方法和设备 | CN95190397.7 | 1995-04-20 | CN1128505A | 1996-08-07 | A·柯尼格; J·乌尔里希 |
| 化学物质的净化方法和设备。洗涤柱,它在熔体结晶中用于从残留熔体中去除杂质,洗涤柱的生产能力受到以下限制,即通常所输送的结晶糊具有不同大小的固体成分,这些固体成分也易于部分团聚。因此基于环绕这些固体成分的流动的净化作用受到限制。建议用单分散粒子供给洗涤柱,该粒子事先借助相应的造粒装置产生。用于净化并得到化学物质的用途。 | ||||||
| 123 | 造粒的工艺方法 | CN86104552 | 1986-07-24 | CN1004470B | 1989-06-14 | 利奥·蒙赫米厄斯; 斯坦尼斯劳斯·马蒂纳斯; 皮特勒斯·马泽斯 |
| 一个由液体组分制备颗粒的方法。该法是把液体组分喷到或喷涂于在造粒区中保持运动状态的固体颗粒上,其结果导致这些颗粒被包裹并逐渐增大,从造粒区中排出的颗粒流可分为三股,即合乎要求粒度的颗粒、高于要求粒度的颗粒和低于要求粒度的颗粒,低于要求粒度的颗粒流最少有一部分返回造粒区,而高于要求粒度的颗粒流被贮存于缓冲罐,并随后在一个缩粒设备中经过缩粒到可用作粒子核的粒度之后,以恒定的速率返回造粒区。 | ||||||
| 124 | 颗粒制备技术及应用此技术所获得的颗粒 | CN86106504 | 1986-09-30 | CN86106504A | 1987-04-01 | 约翰尼斯·休伯特斯·范德利克; 斯坦尼斯劳斯·马蒂纳斯·皮特勒斯·马泽斯 |
| 采用易于控制的和有效的造粒工艺技术,制备既坚固又圆的颗粒。在造粒区中将液体组分分布于固体粒子上,接着将来自造粒区的颗粒分离成过小尺寸的颗粒,较小的合格尺寸的颗粒,较大的合格尺寸的颗粒和过大尺寸的颗粒物流,在较小的合格尺寸的颗粒中,至少一部分随过小尺寸的颗粒和(或)压碎后的过大尺寸的颗粒一起再循环到造粒区。 | ||||||
| 125 | NANOSCALE PARTICLES, AND USES FOR SAME | PCT/US9510815 | 1995-08-25 | WO9606700A2 | 1996-03-07 | LIU SHENGZHONG; MISTRY PRAVIN; TURCHAN MANUEL C |
| Nanoscale particles and powders are made from a starting material, including larger-size starting particles and solid targets. Various techniques are disclosed all of which generally involve heating and decomposing the starting material with an energy source selected from the group consisting of laser, electric arc, flame and plasma. The various techniques disclosed herein all exhibit a high throughput and a nearly instantaneous rate of production of nanoscale powders for a variety of applications. In certain of the embodiments, cooling is required to prevent agglomeration of the nanoscale particles into larger (non-nanoscale) particles. The nanoscale particles are useful for painting, coating, joining, bonding, brazing, soldering, welding, etc. For example, thermal stresses normally associated with joining (e.g., brazing) may be alleviated by a low-temperature joining technique of the present invention. A low-temperature joining material is applied (as a paste, or as a powder spray, or as a tape, or as a paint, or as a putty) at the junction of two components desired to be joined together. Energy from a source such as a laser beam (for example an Nd:YAG or a CO2 laser) or by a flame, arc, plasma, or the like, is either "walked" along the joining material to react the entire amount joining material, or the joining material is self-sustaining and simply requires igniting a selected portion of the joining material by the energy source. In an exemplary application of the process, vanes are brazed to the bowl and/or to the shroud of an automatic transmission bowl (impeller or turbine) assembly, preferably using the low-temperature joining material. Systems for delivering the joining material and the energy are described. The fabrication of hollow vanes is described. The fabrication of shroudless bowl components, and stator components subsuming the function of the shroud are described. | ||||||
| 126 | NEW AND IMPROVED SYSTEM FOR PROCESSING VARIOUS CHEMICALS AND MATERIALS | PCT/US2014038290 | 2014-05-15 | WO2014153570A9 | 2015-08-06 | KALPAN ALLEN; BRADLEY RANDALL |
| Eco-friendly systems, methods and processes/processing (EFSMP) or an integrated Matrix encompasses stand-alone and/or interconnected modules for completely self-sustained, closed-loop, emission-free processing of mutiple source feedstock that can include pretreatment, with poisoning materials isolated during pretreatment being further recycled to provide useful materials such as, for example, separated metals, carbon and fullerenes for production of nano materials, sulfur, water, sulfuric acid, gas, heat and carbon dioxide for energy production, and production of refined petroleum, at a highly-reduced cost over the best state-of-the-art refining methods/systems that meets new emissions standards as well as optimizes production output with new ultra-speed cycle times. By-products from the petroleum refining process which were previously discarded also now are recycled as renewable sources of energy (water, waste oil and rubber/coal derived pyrolyic (pyro lysis) oil, carbon gases and process gases), or recyclable resources, such as metals and precious metals, oxides, minerals, etc., can be obtained. | ||||||
| 127 | IN-FIBER PARTICLE GENERATION | PCT/US2013046694 | 2013-06-20 | WO2013192368A3 | 2015-04-02 | ABOURADDY AYMAN F; BANAEI ESMAEIL H; DENG DAOSHENG S; FINK YOEL; JOHNSON STEVEN G; KAUFMAN JOSHUA J; LIANG XIANGDONG; SHABAHANG SOROUSH; TAO GUANGMING |
| A fiber is provided, including a cladding material that is disposed along a longitudinal-axis fiber length. A plurality of spherical particles are disposed as a sequence along a longitudinal line parallel to the longitudinal fiber axis in at least a portion of the fiber length. Each spherical particle is of a spherical particle material that is interior to and different than the fiber cladding material. The spacing between adjacent spherical particles in the sequence of particles is greater than the spherical particle diameter. Each spherical particle can be provided as a core- shell particle that includes a spherical core that is surrounded by at least one spherical shell. Each spherical particle can be provided with a plurality of azimuthal sections of at least two distinct materials. | ||||||
| 128 | METHOD FOR PREPARING HARDENED GRANULES FROM A PARTICULATE MATERIAL | PCT/EP9604849 | 1996-11-05 | WO9717307A3 | 1997-08-21 | STOTT KARL REGINALD; WHITE LEROY ALAN; BRESLER ANDRE CHRISTIAAN; MAHADEW DEWANAND |
| A method for preparing hardened granules from a particulate material which comprises admixing to the particulate material an aqueous inorganic binder, converting the resulting moist mixture into granules and hardening said granules, characterised in that it comprises the steps of: (i) selecting a particulate material comprising ingredients suitable as a raw material or an agent in a selected chemical or physical process; (ii) where applicable bringing the particulate material to a particle size distribution suitable for aggregation into granules; (iii) composing and mixing a mixture comprising: the particulate material; an aqueous inorganic binder selected from the group consisting of a calcareous binder, cementitious binder, hydraulic cement, Portland cement, high alumina cement, a mixture of a source of calciumhydroxide with a source of silica, lime, gypsum and dolomite; bringing about a moisture content so that a granulatable mixture is obtained; (iv) forming granules; (v) hardening said granules at a temperature above room temperature and below the boiling temperature of the moisture whilst sticking together of the granules is avoided and where applicable excess moisture from the granules is extracted; (vi) withdrawing the hardened granules in the form of a feed stock component for said selected process. | ||||||
| 129 | A PROCESS FOR MANUFACTURING POLYMER COATED, CONTROLLED RELEASE FERTILIZER, AND RELATED SYSTEMS | US15749405 | 2016-04-18 | US20180214834A1 | 2018-08-02 | Santosh Yadav |
| A frame for holding a small object while coating the small object with a coating composition includes a first plate and a second plate coupled to the first plate and movable relative to the first plate. The first plate includes a platform having a longitudinal axis. The second plate includes a wall adjacent a hole, wherein the hole receives the first plate's platform and is configured to allow the wall to move relative to the platform in a direction along the platform's longitudinal axis. When the first and second plate are coupled together, the first plate's platform and the second plate's wall define a receptacle of the frame that is operable to hold a small object. | ||||||
| 130 | COATED PARTICLES | US15740371 | 2016-06-21 | US20180179067A1 | 2018-06-28 | Ryutaro WADA; Masaya UEDA |
| In a coated particle, a surface of a base material particle is coated with a carbon particle. The carbon particle is produced by disposing an explosive substance with a detonation velocity of 6,300 m/sec or higher in a periphery of a raw material substance containing an aromatic compound having two or less nitro groups, and detonating the explosive substance. | ||||||
| 131 | BIOCHAR EXTRACTS AND METHOD FOR CAPTURING MATERIAL EXTRACTED FROM BIOCHAR | US15806107 | 2017-11-07 | US20180126349A1 | 2018-05-10 | Richard Wilson Belcher; Han Suk Kim; Ranko Panayatov Bontchev |
| A method for capturing material extracted from biochar, the method comprising the steps of: (i) providing a biochar; (ii) contacting the biochar with a treating liquid, where the treating liquid causes the removal of solids from the pores and surface of the biochar, thereby creating a resulting solution or extract comprised of the treating liquid and removed solids; and (iii) collecting the resulting solution or extract. The method further comprises the step of apply the resulting solution or extract to soil or for use in other applications. | ||||||
| 132 | Apparatus for producing hybrid carbon black particles | US15589425 | 2017-05-08 | US09938465B2 | 2018-04-10 | Fikret Dülger; Niels Raeder; Holger Merz |
| The invention relates to a process for producing hybrid carbon black particles (12), which comprises the steps: a) production of first carbon black starting particles (16); b) production of second carbon black starting particles (22); c) milling of the second carbon black starting particles (22); d) mixing of the second carbon black starting particles (22) into a particle stream (48) of the first carbon black starting particles (16); and d) pelletization of the first and second carbon black starting particles (16, 22) to form hybrid carbon black particles (12). The invention further relates to an apparatus (10) for producing hybrid carbon black particles (12) and to hybrid carbon black particles (12) produced by means of the process or the apparatus (10). | ||||||
| 133 | Method and System for Processing Whole Hemp Stalks | US15821093 | 2017-11-22 | US20180093275A1 | 2018-04-05 | Lyall D. Bates |
| A method and system for processing whole hemp stalks is disclosed. The method and system use an entirety of the whole hemp stalks in producing the particulate hemp such that the particulate hemp comprises both bast fiber and shire of the original whole hemp stalks. Additionally, hemp crumbs or crumbles may be processed from whole hemp stalks, or from particulate hemp which is larger than the hemp crumbs such as hemp pellets. The hemp crumbs may be formed by crushing the hemp pellets. | ||||||
| 134 | UREA PRODUCTION METHOD | US15553527 | 2016-04-01 | US20180037542A1 | 2018-02-08 | Shuhei NAKAMURA; Keigo SASAKI |
| The present invention is a urea production method, including: a first concentration step of concentrating an aqueous urea solution; a granulation step of producing solid urea from the concentrated urea solution generated in the first concentration step; a urea recovery step of treating exhaust gas from the granulation step and recovering urea dust in the exhaust gas to generate a recovered aqueous urea solution, the granulation step being configured so as to treat a concentrated urea solution containing an additive; and a second concentration step of concentrating the recovered aqueous urea solution as an additional concentration step, wherein the concentrated recovered urea solution generated in the second concentration step is joined to the concentrated urea solution in the downstream of the first concentration step, and an additive is added downstream of the first concentration step. The present invention can produce a urea solution containing no additive for producing solid urea, while using the additive. | ||||||
| 135 | IMPROVED PROCESS FOR PRODUCING PELLETIZED POLYMER COMPOSITIONS | US15318141 | 2014-06-12 | US20170129976A1 | 2017-05-11 | Brian W. Kolthammer; Michael J. Zogg, JR. |
| The instant invention provides an improved process for producing pelletized polymer compositions, and pelletized polymer compositions. The process for producing a pelletized polymer composition according to the present invention comprises: (1) polymerizing one or more alpha-olefins in one or more solution reactors thereby producing a molten polymer composition comprising one or more solvents; (2) removing at least a portion of said one or more solvents thereby forming a polymer composition having a low solvent content (typically less than 1,000 parts of solvent per million of polymer on a weight basis); (3) removing heat from said polymer composition having low solvent content to a temperature in the range of equal to or greater than the crystallization point of the polymer composition having low solvent content to less than or equal to a temperature in the range of from (the crystallization point of the polymer composition having low solvent content+20° C.) thereby forming a viscous polymer melt; and (4) pelletizing said viscous polymer melt via an underwater pelletizer thereby forming said pelletized polymer composition. | ||||||
| 136 | UREA GRANULATION PROCESS WITH SCRUBBING SYSTEM | US15260018 | 2016-09-08 | US20160376230A1 | 2016-12-29 | Matthias POTTHOFF; Harald FRANZRAHE; Luc Albert VANMARCKE |
| A urea granulation process with a scrubbing system may involve at least one gaseous waste stream for removal of dust and ammonia whereby the waste stream may be processed through a combination of process steps. In some examples, the process steps may involve washing the dust and ammonia laden stream with water and/or an aqueous urea solution whereby a dust-laden liquid stream and a dust-reduced stream is generated. The process steps may further involve reacting the dust-reduced stream with formaldehyde to form a stream comprising hexamethylenetetramine and urea-formaldehyde and clean off-gas. In some cases, the gas stream may be directed first through the washing step and then through the reacting step. | ||||||
| 137 | Oil Exraction From Processed Hemp | US15147016 | 2016-05-05 | US20160324908A1 | 2016-11-10 | Lyall D. Bates |
| Oil is extracted from processed hemp which is better suited for transportation than whole hemp stalks particularly when oil extraction and initial processing of the hemp from the whole hemp stalks is performed at separate facilities. For example, the processed hemp may be characterized in that it was pelletized as part of its processing from the whole hemp stalks. Used processed hemp lacking/deprived of oil that is generated from the step of extracting the cannabinoid oil may be reused in a vendible product, for example where the lack of oil does not alter performance of the hemp in use of that vendible product. | ||||||
| 138 | ULTRASONIC LIQUID LEVEL SENSING SYSTEMS | US15079708 | 2016-03-24 | US20160207153A1 | 2016-07-21 | Charles Michael Birtcher; Thomas Andrew Steidl |
| Embodiments of the present invention provide an ultrasonic probe having an increased number (e.g., twelve) of ultrasonic sensors for measuring the level of liquid within a sealed container. The ultrasonic probe includes a neck tube that enables the ultrasonic probe to be used with existing, standardized container fittings despite having an enlarged barrel to accommodate the increased number of ultrasonic sensors. Embodiments of the present invention also provide a system and method in which ultrasonic sensors within an ultrasonic probe are activated one at a time to reduce crosstalk between the ultrasonic sensors and their wiring. | ||||||
| 139 | AGRICULTURAL BLEND, AGRICULTURAL BINDER SYSTEM, AND PROCESS OF FORMING AN AGRICULTURAL BLEND | US14612909 | 2015-02-03 | US20150152016A1 | 2015-06-04 | Stephen R. MIRANDA; Kimberly A. PAPANIA |
| An agricultural blend, an agricultural binder system, and a process of forming an agricultural blend are described. The agricultural blend includes a binder system having soy polymer and one or both of metal slag by-product and synthetic gypsum. The agricultural binder system includes soy polymer. The agricultural binder system is a powder. The process of forming an agricultural blend includes blending a binder system having soy polymer with one or both of metal slag by-product and synthetic gypsum to form the agricultural blend. | ||||||
| 140 | Ultrasonic liquid level sensing systems | US14163407 | 2014-01-24 | US08959998B2 | 2015-02-24 | Charles Michael Birtcher; Thomas Andrew Steidl |
| Embodiments of the present invention provide an ultrasonic probe having an increased number (e.g., twelve) of ultrasonic sensors for measuring the level of liquid within a sealed container. The ultrasonic probe includes a neck tube that enables the ultrasonic probe to be used with existing, standardized container fittings despite having an enlarged barrel to accommodate the increased number of ultrasonic sensors. Embodiments of the present invention also provide a system and method in which ultrasonic sensors within an ultrasonic probe are activated one at a time to reduce crosstalk between the ultrasonic sensors and their wiring. | ||||||
QQ群二维码
意见反馈
意见反馈