| 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 | 用于热绝缘的毫微复合材料 | CN98804996.1 | 1998-05-13 | CN1255149A | 2000-05-31 | 赫尔穆特·施密德特; 马丁·门尼格; 格哈特·琼施克尔 |
| 本发明涉及用于热绝缘,特别是用于防火的毫微复合材料,该复合材料可通过组合(A)(B)(C)组分而制得。(A)至少35重量%的毫微量级的任意表面改性的无机化合物颗料;(B)10~60重量%的具有至少二个能与毫微级颗粒(A)的表面基团反应和/或相互反应的化合物;(C)1~40重量%的水和/或没有或仅有一个在(B)中定义的官能基团的有机溶剂,其中,上述百分比基于组分(A)、(B)和(C)之总和,以及(D)=0~10重量%(基于毫微复合材料)的添加剂。 | ||||||
| 2 | 用于热绝缘的毫微复合材料及其用途 | CN98804996.1 | 1998-05-13 | CN100352853C | 2007-12-05 | 赫尔穆特·施密德特; 马丁·门尼格; 格哈特·琼施克尔 |
| 本发明涉及用于热绝缘,特别是用于防火的毫微复合材料,该复合材料可通过组合(A)(B)(C)组分而制得。(A)至少35重量%的毫微量级的任意表面改性的无机化合物颗料;(B)10~60重量%的具有至少二个能与毫微级颗粒(A)的表面基团反应和/或相互反应的化合物;(C)1~40重量%的水和/或没有或仅有一个在(B)中定义的官能基团的有机溶剂,其中,上述百分比基于组分(A)、(B)和(C)之总和,以及(D)=0~10重量%(基于毫微复合材料)的添加剂。 | ||||||
| 3 | 玻璃陶瓷组合物及使用了该组合物的电子部件和叠层式LC复合部件 | CN99808630.4 | 1999-06-16 | CN1172872C | 2004-10-27 | 胜村英则; 齐藤隆一; 平贺将浩 |
| 本发明涉及对树脂基板具备良好的安装可靠性、制造容易、且高频电气特性良好的玻璃陶瓷组合物和以银或铜为主成分的内部电极所构成的叠层式LC复合部件。玻璃陶瓷组合物由45~35重量%的镁橄榄石粉末和55~65重量%的玻璃组合物粉末构成,玻璃组合物粉末由40~50重量%的SiO2、30~40重量%的BaO、3~8重量%的Al2O3、8~12重量%的La2O3和3~6重量%B2O3组成。上述玻璃陶瓷组合物具备高抗弯强度和适当的热膨胀系数,未烧结片状物容易制造,且在低于950℃的温度下能够致密地进行烧结。 | ||||||
| 4 | 制备复合材料的方法、所产生的材料及其用途 | CN200880004896.3 | 2008-02-13 | CN101631512B | 2013-08-28 | 里奇德·泽纳提; 埃洛迪·帕卡尔 |
| 本发明涉及一种制备具有均匀组成的复合材料的方法,所述复合材料包含至少一种生物活性陶瓷相和至少一种可生物再吸收的聚合物。本发明的方法特征在于,所述方法包括下述步骤:a)获得粉形式的生物活性陶瓷相,b)将所述生物活性陶瓷粉悬浮在溶剂中,c)将可生物再吸收聚合物加入在b)中得到的悬浮液中并混合,以便产生所述生物活性陶瓷粉在由所述溶剂和所述聚合物形成的溶液中的粘性均匀分散体,d)在c)中得到的分散体在水溶液中沉淀以便获得均匀的复合材料。本发明还涉及所得到的复合材料及其在可植入医疗器械的制造中的用途。 | ||||||
| 5 | 有机-无机混杂玻璃态材料及其制造方法 | CN200580003655.3 | 2005-02-21 | CN1914250B | 2011-04-27 | 国吉稔; 横尾俊信; 高桥雅英 |
| 一种制造有机-无机混杂玻璃态材料的方法,其特征在于将具有可熔融性的原料熔融或熔融/老化之后,在比熔融原料的温度高100℃或更多的温度下对得到的材料进行热处理。 | ||||||
| 6 | 制备复合材料的方法、所产生的材料及其用途 | CN200880004896.3 | 2008-02-13 | CN101631512A | 2010-01-20 | 里奇德·泽纳提; 埃洛迪·帕卡尔 |
| 本发明涉及一种制备具有均匀组成的复合材料的方法,所述复合材料包含至少一种生物活性陶瓷相和至少一种可生物再吸收的聚合物。本发明的方法特征在于,所述方法包括下述步骤:a)获得粉形式的生物活性陶瓷相,b)将所述生物活性陶瓷粉悬浮在溶剂中,c)将可生物再吸收聚合物加入在b)中得到的悬浮液中并混合,以便产生所述生物活性陶瓷粉在由所述溶剂和所述聚合物形成的溶液中的粘性均匀分散体,d)在c)中得到的分散体在水溶液中沉淀以便获得均匀的复合材料。本发明还涉及所得到的复合材料及其在可植入医疗器械的制造中的用途。 | ||||||
| 7 | 玻璃陶瓷组合物及使用了该组合物的电子部件和叠层式LC复合部件 | CN200410034203.9 | 1999-06-16 | CN1323969C | 2007-07-04 | 胜村英则; 齐藤隆一; 平贺将浩 |
| 本发明涉及由对树脂基板具备良好的安装可靠性、制造容易、且高频电气特性优良好的玻璃陶瓷组合物和以银或铜为主成分的内部电极所构成的叠层式LC复合部件。玻璃陶瓷组合物基本由50~65重量%的玻璃组合物粉末、0.2~5重量%(换算成CuO)氧化铜、和50~35重量%Mg2SiO4所构成的混合物进行成型烧结而获得,而玻璃组合物粉末由40~50重量%的SiO2、30~40重量%的BaO、3~8重量%的Al2O3、8~12重量%的La2O3和3~6重量%B2O3组成。上述玻璃陶瓷组合物具备高抗弯强度和适当的热膨胀系数,未烧结片状物容易制造,且在低于950℃的温度下能够致密地进行烧结。 | ||||||
| 8 | 有机-无机混杂玻璃态材料及其制造方法 | CN200580003655.3 | 2005-02-21 | CN1914250A | 2007-02-14 | 国吉稔; 横尾俊信; 高桥雅英 |
| 一种制造有机-无机混杂玻璃态材料的方法,其特征在于将具有可熔融性的原料熔融或熔融/老化之后,在比熔融原料的温度高100℃或更多的温度下对得到的材料进行热处理。 | ||||||
| 9 | 玻璃陶瓷组合物及使用了该组合物的电子部件和叠层式LC复合部件 | CN200410034203.9 | 1999-06-16 | CN1552661A | 2004-12-08 | 胜村英则; 齐藤隆一; 平贺将浩 |
| 本发明涉及由对树脂基板具备良好的安装可靠性、制造容易、且高频电气特性优良的玻璃陶瓷组合物和以银或铜为主成分的内部电极所构成的叠层式LC复合部件。玻璃陶瓷组合物基本由50~65重量%的玻璃组合物粉末、0.2~5重量%(换算成CuO)氧化铜、和45~35重量%镁橄榄石Mg2SiO4所构成的混合物进行成型烧结而获得,而玻璃组合物粉末由40~50重量%的SiO2、30~40重量%的BaO、3~8重量%的Al2O3、8~12重量%的La2O3和3~6重量%B2O3组成。上述玻璃陶瓷组合物具备高抗弯强度和适当的热膨胀系数,未烧结片状物容易制造,且在低于950℃的温度下能够致密地进行烧结。 | ||||||
| 10 | 玻璃陶瓷组合物及使用了该组合物的电子部件和叠层式LC复合部件 | CN99808630.4 | 1999-06-16 | CN1309625A | 2001-08-22 | 胜村英则; 齐藤隆一; 平贺将浩 |
| 本发明涉及对树脂基板具备良好的安装可靠性、制造容易、且高频电气特性良好的玻璃陶瓷组合物和以银或铜为主成分的内部电极所构成的叠层式LC复合部件。玻璃陶瓷组合物由45~35重量%的镁橄榄石粉末和55~65重量%的玻璃组合物粉末构成,玻璃组合物粉末由40~50重量%的SiO2、30~40重量%的BaO、3~8重量%的Al2O3、8~12重量%的La2O3和3~6重量%B2O3组成。上述玻璃陶瓷组合物具备高抗弯强度和适当的热膨胀系数,未烧结片状物容易制造,且在低于950℃的温度下能够致密地进行烧结。 | ||||||
| 11 | 萘并吡喃衍生物、含此类化合物的组合物和(共)聚合物基体 | CN98803439.5 | 1998-03-17 | CN1250438A | 2000-04-12 | O·布雷内; Y-P·占 |
| 本发明的主题是新颖的以下化学式(Ⅰ)所示的萘并吡喃衍生物,该衍生物在2、3、4、6、7、8、9或/和10位上可任选地进行取代;5位上的取代基Z是化学式为-C(R1)(R2)(OR3)的基团。本发明还涉及含有这些衍生物的组合物和(共)聚合物基体。所述衍生物具有令人感兴趣的光致变色性能。 | ||||||
| 12 | GALLIUM-BASED GLASS COMPOSITION | US15517894 | 2015-10-09 | US20170239292A1 | 2017-08-24 | Owen Clarkin; Caitriona Lally |
| A gallium silica glass composition is described. The glass can be used in variety of biomedical applications | ||||||
| 13 | GLASS-PHOSPHOR COMPOSITE CONTAINING RARE-EARTH ION AND LIGHT-EMITTING DIODE INCLUDING SAME | US14836876 | 2015-08-26 | US20150364658A1 | 2015-12-17 | Jong Heo; Byoung Jin So; Seung Ryeol Lee |
| A method of manufacturing a glass-phosphor composite is disclosed. The method comprises: preparing rare earth ion-containing parent glass; mixing the rare-earth ion-containing parent glass in a power state with a phosphor in a powder state; and providing a glass-phosphor composite using the powder mixture of the rare earth ion-containing parent glass and the phosphor, wherein the mixing includes mixing the rare earth ion-containing parent glass in the powder state with the phosphor in the powder state so that the phosphor in the glass-phosphor composite is in an amount of 5 wt % to 30 wt %, and the preparing includes using a glass frit having a glass transition point of 300° C. to 800° C. and a sintering temperature of 200° C. to 600° C. | ||||||
| 14 | PHOTOCHROMIC SUBSTANCE AND METHOD FOR PRODUCING SAME | US14368389 | 2012-11-01 | US20140326932A1 | 2014-11-06 | Morito Akiyama |
| Provided is a photochromic substance that has lower toxicity, exhibits good sensitivity in a visible light region, changes color deeply, has slow speed of color fading, has chemical and thermal stability, and has good durability. The photochromic substance has a composition represented by the formula: Ba(a-b)CabMgcSidOe:FefMgM′h where 1.8≦a≦2.2, 0≦b≦0.1, 1.4≦c≦3.5, 1.8≦d≦2.2, e=(a+c+2d), 0.0001≦f, 0.0001≦g, 0≦h, M is at least one of Al and Eu, and M′ is at least one element selected from the group consisting of Na, K, Nd, Li, S, C, Ti, V, Mn, Cr, Cu, Ni, Co, Ge, Zn, Ga, Zr, Y, Nb, In, Ag, Mo, Sn, Sb, Bi, Ta, W, La, Ce, Pr, Nd, Sm, Gd, Er, Ho, Tb, Tm, Yb, Lu, P, Cd, and Pb. | ||||||
| 15 | METHOD FOR PREPARING A COMPOSITE MATERIAL, RESULTING MATERIAL AND USE THEREOF | US12527080 | 2008-02-13 | US20100094418A1 | 2010-04-15 | Rachid Zenati; Elodie Pacard |
| The invention relates to a method for preparing a composite material having a homogeneous composition, containing at least one bioactive ceramic phase and at least one bioresorbable polymer. The inventive method is characterised in that it comprises the following steps: a) a bioactive ceramic phase in powder form is obtained, b) the bioactive ceramic powder is suspended in a solvent, c) a bioresorbable polymer is added to the suspension obtained in (b) and mixed to produce a viscous homogeneous dispersion of said bioactive ceramic powder in a solution formed by the solvent and the polymer, and d) the dispersion obtained in (c) is precipitated in an aqueous solution in order to obtain a homogeneous composite material. The invention also relates to the resulting composite material and to the use thereof in the production of implantable medical devices. | ||||||
| 16 | Pigmented vitreous material | US10335727 | 2003-01-02 | US20030140820A1 | 2003-07-31 | Patrice Bujard; Veronique Hall-Goulle; Zhimin Hao; Hitoshi Nagasue; Gerardus De Keyzer |
| The present application relates to a process for the manufacture of pigmented vitreous materials, as well as to pigmented vitreous materials, characterized by the use of soluble pigment precursors and preferably the absence of significant amounts of dispersants. These pigmented vitreous materials can be used as coloured materials for any known purposes. Soluble pigment precursors comprising a partial structure 1 are also claimed, wherein X1 is an aromatic or heteroaromatic ring, B is hydrogen or a group of the formula 2 but at least one group B is not hydrogen, and L is a solubilizing group. | ||||||
| 17 | Silica materials | US609425 | 1996-03-01 | US5869152A | 1999-02-09 | Luis A. Colon |
| The present invention relates to silica materials and particles having surfaces which define an interior. The interior includes interior silicon atoms at least a portion of which is bonded to a substituted or unsubstituted alkyl moiety. In a preferred aspect of the present invention, the silica material also has surface silicon atoms to which are bonded substituted or unsubstituted alkyl moieties. A capillary tube coated on its inner surface with the silica material of the present invention is also disclosed. The silica materials of the present invention are resistant to degradation at high or low pH and are particularly useful as chromatographic stationary phases, especially for use in open tubular liquid chromatography and open tubular electrochromatography. | ||||||
| 18 | Inorganic-organic composite compositions exhibiting nonlinear optical response | US261583 | 1988-10-24 | US4898755A | 1990-02-06 | Tessie M. Che; Dagobert E. Stuetz; Alan Buckley; Donald R. Ulrich |
| This invention provides an optical medium which consists of an inorganic glass monolith with a microporous structure containing an organic component which exhibits nonlinear optical response.In one embodiment this invention provides a sol-gel process for producing a composite of a transparent homogeneous microporous inorganic oxide glass monolith and an organic compound which exhibits nonlinear optical response. | ||||||
| 19 | Inorganic-organic composite compositions exhibiting nonlinear optical response | US261582 | 1988-10-24 | US4861129A | 1989-08-29 | Tessie M. Che; Dagobert E. Stuetz; Alan Buckley; Donald R. Ulrich |
| This invention provides an optical medium which consists of an inorganic glass monolith with a microporous structure containing an organic component which exhibits nonlinear optical response.In one embodiment this invention provides a sol-gel process for producing a composite of a transparent homogeneous microporous inorganic oxide glass monolith and an organic compound which exhibits nonliner optical response. | ||||||
| 20 | Gallium-based glass composition | US15517894 | 2015-10-09 | US10149861B2 | 2018-12-11 | Owen Clarkin; Caitriona Lally |
| A gallium silica glass composition is described. The glass can be used in variety of biomedical applications. | ||||||
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