| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 41 | 蜂窝结构体 | CN200910136946.X | 2009-04-28 | CN101585004A | 2009-11-25 | 国枝雅文; 吉村健; 后藤真之助 |
| 本发明提供一种蜂窝结构体,其具有良好的强度和催化剂担载性能。该蜂窝结构体具有包含沸石和无机粘结剂且具有蜂窝形状的蜂窝单元,在以孔道壁的细孔径为横轴、log微分细孔容积为纵轴的细孔分布曲线中,蜂窝单元在细孔径0.006μm~0.06μm的范围内具有一个以上log微分细孔容积的峰值,在细孔径大于0.06μm并小于等于1μm的范围内具有一个以上log微分细孔容积的峰,在细孔径大于0.06μm并小于等于1μm的范围内,与该范围内的细孔容量的log微分细孔容积的峰中的log微分细孔容积的峰值最大的峰相对应的细孔径±0.03μm的范围内的细孔的容积是在所述范围内的细孔的细孔容积的60~95%。 | ||||||
| 42 | 复合材料及其制造方法和用途 | CN200680009510.9 | 2006-01-25 | CN101146674A | 2008-03-19 | S·C·布朗; A·W·凯恩; R·L·汤普森 |
| 本申请描述了相对轻质、高强度并且低热导率的复合材料。本申请还描述了所述复合材料的制造方法和用途。 | ||||||
| 43 | 分离膜 | CN200580008128.1 | 2005-03-15 | CN1929901A | 2007-03-14 | 相泽正信 |
| 本发明提供一种既具有高分离特性又能同时获得高透过速度的分离膜。本发明的分离膜具有主要成分由氧化铝组成的陶瓷烧结材料的多孔基体和在该多孔基体表面成膜的沸石薄膜,其中,上述多孔基体至少具有基层和在该基层表面形成的上述沸石薄膜的底层,上述底层的平均细孔径小于上述基层的平均细孔径。 | ||||||
| 44 | 两步法生产带有泡沫底层的密实表面材料的方法 | CN96192898.0 | 1996-03-26 | CN1061287C | 2001-01-31 | D·E·斯瓦尔茨 |
| 一种采用湿盖湿两步浇铸生产密实表面材料的方法,所述材料的填充聚合物的薄层与空心填料填充聚合物背衬形成整体,在聚合物混合体中设有界面或过渡区。 | ||||||
| 45 | 陶瓷膜孔梯度陶瓷 | CN92105179.4 | 1992-07-15 | CN1081394A | 1994-02-02 | 沈君权; 潘缉涵; 王瑞琍; 李从勤; 唐竹兴; 马俊峰; 马明江 |
| 本发明属于硅酸盐工学,精细陶瓷与功能陶瓷领域。一种耐高温、耐腐蚀、高分离性能和低阻力的,其膜在内或在外表面上的陶瓷膜孔梯度和高气体选择、催化分离支撑体的孔梯度陶瓷,它是由氧化铝或二氧化硅或二氧化钛为主料,加粘土和长石配制而成,经注浆、热灌注和挤出单独或相结合的成型方法成型,然后经湿式干燥、紧密堆叠卧装和吊装的方式装窑,在1100—1550℃高温下烧制而成。陶瓷膜的孔径为0.1—15μm,气孔率30—55%,膜厚为1—200μm,共有2—10层。直径为4—40mm,长度为25—1500mm,厚度为3—10mm的管状陶瓷膜孔梯度陶瓷。 | ||||||
| 46 | 内有通道的陶瓷制品及其制造方法 | CN87106230 | 1987-09-10 | CN87106230A | 1988-07-06 | 丹尼·R·怀特; 迈克尔·K·阿格哈扎尼安; 哈里·R·茨威克尔 |
| 提高制造自支承陶瓷体的一种方法,包括制做一个成形散逸金属和母金属的组合件,也可包含渗透性的填料床,加热组合件形成熔融母金属熔体。在选自条件下熔融母金属氧化,生长出来的多晶材料淹没了成形的散逸金属(如果有填料存在,透过填料)并造成散逸金属扩散进入淹没它的多晶材料中,从而留下了成为一条或几条孔道的以前被成形散逸金属占据的空间。因此该方法提供了内部有反复制成散逸金属形状的孔道的自支承陶瓷体。 | ||||||
| 47 | HONEYCOMB STRUCTURE | US15616213 | 2017-06-07 | US20170355645A1 | 2017-12-14 | Takahiro KONDO; Yasushi KATO; Junki MATSUYA |
| The honeycomb structure body has a dense part at a part in axial direction including a center region of the inflow end face, the dense part having a change ratio of porosity calculated by the following Expression (1) that is 2 to 8%, and has an outside-diameter increasing part, and the honeycomb structure body has a change ratio of average diameter calculated by the following Expression (2) that is 0.2 to 3%, (1−Px/Py)×100, Expression (1): in Expression (1), Px denotes the porosity (%) at the center region of the inflow end face, and Py denotes the porosity (%) of a circumferential region of the inflow end face. (1−Dx/Dy)×100, Expression (2): in Expression (2), Dx denotes the average diameter (mm) of the inflow end face, and Dy denotes the average diameter (mm) of the outflow end face. | ||||||
| 48 | METHOD AND SYSTEM FOR ON-LINE BLENDING OF FOAMING AGENT WITH FOAM MODIFIER FOR ADDITION TO CEMENTITIOUS SLURRIES | US15431444 | 2017-02-13 | US20170152177A1 | 2017-06-01 | Annamaria Vilinska; Alfred C. LI; Weixin D. SONG |
| Disclosed is a method and system for blending a foam modifier with foaming agent online, e.g., as may be particularly useful for gypsum or cement slurries. The foam modifier comprises a fatty alcohol that is added to a gypsum or cement slurry that includes foaming agent, such as an alkyl sulfate surfactant. The fatty alcohol can be a C6-C16 fatty alcohol in some embodiments. The use of such a foam modifier can be used, for example, to stabilize the foam, reduce waste of foaming agent, improve void size control in the final product, and improve the gypsum board manufacturing process. | ||||||
| 49 | Gypsum wallboard and method of making same | US13207885 | 2011-08-11 | US09523198B2 | 2016-12-20 | William C. Martin; Eli Stav; Matthew J. Plante; Maryn L. Heermann |
| A coalescing additive is used in the manufacturing process for gypsum wallboard. Such an additive increases the surface area and density of the slurry at the paper to core interface by coalescing the foam cells away from the paper core interface. This permits a stronger paper to core bond to form and increases the compressive strength of the gypsum wallboard as compared to standard wallboards made from slurries with reduced water levels. | ||||||
| 50 | Geodesic Dome using pre-casted panels of Magnesium-Phosphate ceramic cement connected with a plurality of hubs. | US14641259 | 2015-03-06 | US20160258152A1 | 2016-09-08 | Morgan Lance Bierschenk; Lawrence Dobson |
| A Geodesic Dome made of triangular panels pre-casted with Magnesium Phosphate ceramic cement is described. Said triangular panels consist of multiple layers of Magnesium Phosphate ceramic cement poured into a mold with successive layers at various levels of porosity, reinforced with basalt and hemp fibers. A plurality of hubs joins a plurality of triangular panels at specific dihedral angles to enclose space. The hubs are bolted into a threaded sleeve that is embedded into the corner of each triangular panel, thus creating a Geodesic Dome. | ||||||
| 51 | Method for producing a ceramic filter element | US14019156 | 2013-09-05 | US09333449B2 | 2016-05-10 | Andreas Franz |
| In a method for manufacturing a ceramic filter element for an exhaust gas filter of internal combustion engines, a combustible non-ceramic filter medium is shaped to a coil and impregnated with a ceramic slurry having a powder size distribution selected such that the ceramic filter element in the finished state has a desired porosity distribution that varies across the coil cross-section of the ceramic filter element. | ||||||
| 52 | CERAMIC HONEYCOMB STRUCTURE AND ITS PRODUCTION METHOD | US14762071 | 2014-09-18 | US20150360162A1 | 2015-12-17 | Shunji OKAZAKI |
| A ceramic honeycomb structure including large numbers of flow paths partitioned by porous cell walls; (a) the cell walls having porosity of 55-65%; and (b) in a pore diameter distribution in the cell walls measured by mercury porosimetry, (i) pore diameters at cumulative pore volumes corresponding to specific percentages of the total pore volume being within specific ranges and satisfying specific relationships; (ii) the difference of a logarithm of the pore diameter at a cumulative pore volume corresponding to 20% of the total pore volume and a logarithm of the pore diameter at 80% being 0.39 or less; and (iii) the volume of pores of more than 100 μm being 0.05 cm3/g or less. | ||||||
| 53 | Method for the manufacturing of a composite | US11795787 | 2006-01-25 | US09199394B2 | 2015-12-01 | Scott C. Brown; Andrew W. Cain; Randell L. Thompson |
| Described herein are composites that are relatively lightweight, high strength and low thermal conductivity. Also described herein are methods for the manufacture and use thereof. | ||||||
| 54 | POLYCRYSTALLINE CERAMICS, THEIR PREPARATION AND USES | US14809309 | 2015-07-27 | US20150329777A1 | 2015-11-19 | Bernd Hoppe; Peter Nab; Volker Hagemann; Yvonne Menke; Wlofram Beier |
| Polycrystalline ceramics with specifically adjusted scattering power are provided, as well as methods for the preparation of such ceramics and uses thereof. The polycrystalline ceramic include an optoceramic phase and a pore phase, wherein the polycrystalline ceramic has a remission of at least 70% at a wave length of 600 nm and a sample thickness of 1 mm. | ||||||
| 55 | HONEYCOMB STRUCTURAL BODY | US14373824 | 2013-01-17 | US20150047307A1 | 2015-02-19 | Naohiro Hayashi; Masakazu Murata; Oji Kuno; Hiromasa Suzuki; Hiroyuki Matsubara |
| A honeycomb structural body Is made of cordierite ceramic, and composed of partition walls and cells. A cell density is changed continuously or step by step from a central section to an outer peripheral section in a radial direction. The honeycomb structural body has a relationship of M1>M2>M3, and a relationship of K1 | ||||||
| 56 | POROUS ARTICLES, METHODS, AND APPARATUSES FOR FORMING SAME | US14311784 | 2014-06-23 | US20150004521A1 | 2015-01-01 | Satyalakshmi K. Ramesh; Chuanping Li; Paul Braun; Michael J. Ferrecchia; John D. Pietras; Brian P. Feldman; James A. Salvatore |
| A mold for forming a porous article can include a first material having a first thermal conductivity and a second material having a second thermal conductivity different from the first thermal conductivity. The first material may be at least partially embedded within the second material and configured to create regions of different thermal conductivity in the body, such as configured to create distinct nucleation regions within a material formed within the mold. A method for forming a porous article can include providing a slurry within a mold and freeze-casting the slurry to form a porous article having a burst-like distribution of porosity. A porous article according to embodiments herein can include a burst-like distribution of porosity. | ||||||
| 57 | POROUS ARTICLES, METHODS, AND APPARATUSES FOR FORMING SAME | US14311745 | 2014-06-23 | US20150001372A1 | 2015-01-01 | Satyalakshmi K. Ramesh; Chuanping Li; Paul Braun; Michael J. Ferrecchia |
| A mold for forming a porous article can include a first material having a first thermal conductivity and a second material having a second thermal conductivity different from the first thermal conductivity. The first material may be at least partially embedded within the second material and configured to create regions of different thermal conductivity in the body, such as configured to create distinct nucleation regions within a material formed within the mold. A method for forming a porous article can include providing a slurry within a mold and freeze-casting the slurry to form a ceramic article having a burst-like distribution of porosity. A porous article according to embodiments herein can include a burst-like distribution of porosity. | ||||||
| 58 | PRESSURE CASTING SLIP AND REFRACTORY CERAMIC PRODUCED THEREFROM FOR GAS TURBINE UNITS | US14239032 | 2012-08-01 | US20140228198A1 | 2014-08-14 | Christos Aneziris; Nora Gerlach; Holger Grote; Uwe Klippel; Friederike Lange; Stefan Schafföner; Harm Speicher |
| A pressure casting slip for producing a refractory ceramic for use as a heat shield, e.g. in the hot gas path of gas turbine units, includes a particulate mixture of at least two materials having different coefficients of thermal expansion and also organic and/or inorganic binders and floating agents. The particulate mixture has a multimodal particle size distribution divided into 10-20 percent by weight of coarse particles in the size range 1-5 mm in diameter, 10-20 percent by weight of medium particles in the size range 0.5-1 mm in diameter and 60-80 percent by weight of fine particles in the size range up to 0.5 mm in diameter which together make up 100 percent by weight of the particle mixture. | ||||||
| 59 | METHOD FOR PRODUCING A CERAMIC FILTER ELEMENT | US14019156 | 2013-09-05 | US20140167331A1 | 2014-06-19 | Andreas Franz |
| In a method for manufacturing a ceramic filter element for an exhaust gas filter of internal combustion engines, a combustible non-ceramic filter medium is shaped to a coil and impregnated with a ceramic slurry having a powder size distribution selected such that the ceramic filter element in the finished state has a desired porosity distribution that varies across the coil cross-section of the ceramic filter element. | ||||||
| 60 | METHOD OF TREATING FIBROPROLIFERATIVE DISORDERS | US13856035 | 2013-04-03 | US20130209467A1 | 2013-08-15 | Charles E. HART; Stavros TOPOUZIS; Debra G. GILBERTSON |
| Materials and Methods for reducing cell proliferation or extracellular matrix production in a mammal are disclosed. The methods comprise administering to a mammal a composition comprising a therapeutically effective amount of a zvegf4 antagonist in combination with a pharmaceutically acceptable delivery vehicle. Exemplary zvegf4 antagonists include anti-zvegf4 antibodies, inhibitory polynucleotides, inhibitors of zvegf4 activation, and mitogenically inactive, receptor-binding variants of zvegf4. The materials and methods are useful in the treatment of, inter alia, fibroproliferative disorders of the kidney, liver, and bone. | ||||||
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