| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 21 | LED灯、LED照明装置及LED模组 | CN201180011579.6 | 2011-02-16 | CN102782396B | 2015-05-06 | 松林容子; 八木裕司; 清水正则; 真锅由雄; 元家淳志; 松尾和寻; 森俊雄 |
| 提供一种能够使鲜艳的红色也看起来自然的LED灯。LED灯(1)具备:LED模组(5),包括在440nm~460nm的波长域中具有主要的发光尖峰的蓝色LED(12)、受蓝色LED(12)的射出光激励的绿色或黄色荧光体(14)、以及受蓝色LED(12)及绿色或黄色荧光体(14)的至少一个的射出光激励的红色荧光体(15);过滤器(16),将从LED模组(5)射出的光的570nm~590nm的波长域的至少一部分的分光放射强度降低。 | ||||||
| 22 | 用于恶劣环境的馈通元件 | CN201410471331.3 | 2014-09-16 | CN104466520A | 2015-03-25 | 查尔斯·里德克; 大卫·菲尔金斯; 延斯·沙佛; 爱伦·凯·雷特; 朱里奥·卡斯蒂略; 萨宾·皮克勒威廉 |
| 用于恶劣环境的馈通元件包括具有至少一个检查开口的支撑体,至少一个功能元件布置在检查开口中的电绝缘固定材料中。电绝缘固定材料包含体积电阻在350℃下高于1.0×1010Ω·cm的玻璃或玻璃陶瓷。这样的玻璃或玻璃陶瓷在系统SiO2–B2O3–MO中具有限定的组分范围。 | ||||||
| 23 | 一种新型荧光灯 | CN201310351532.5 | 2013-08-13 | CN104377111A | 2015-02-25 | 张雁达 |
| 本发明提供一种新型荧光灯,由无铅玻璃管(1)、荧光粉层(2)、灯头冒(3)、玻璃芯柱(6)、长寿命灯丝(9)组成,其特征在于:灯头冒(3)顶部外侧镶嵌上端子(4)和下端子(5),灯头冒(3)内部设有玻璃芯柱(6)固定上灯丝支撑导丝(7)和下灯丝支撑导丝(8),二灯丝支撑导丝之间串联一长寿命灯丝(9),所述长寿命灯丝为钨丝,所述钨丝外表粘敷3-5层电子粉,另在电子粉的外层再烧结一层网状陶瓷。 | ||||||
| 24 | 闪烁体面板以及闪烁体面板的制造方法 | CN201280025379.0 | 2012-05-25 | CN103563006A | 2014-02-05 | 井口雄一朗; 滨野翼; 小林康宏 |
| 闪烁体面板,其为具备闪烁体层的闪烁体面板,所述闪烁体层包含平板状的基板、在该基板上设置的格子状的隔壁、以及在由前述隔壁划分而成的单元内填充的荧光体,前述隔壁是通过以含有2~20质量%碱金属氧化物的低熔点玻璃为主要成分的材料构成的。本发明提供高精度且大面积地形成宽度窄的隔壁、发光效率高、实现鲜明画质的闪烁体面板。 | ||||||
| 25 | 在玻璃制造过程中消除气泡的方法 | CN200680046405.2 | 2006-12-08 | CN101326129B | 2011-06-22 | W·G·多尔夫德; A·J·埃利森; 李乔; S·L·希费尔贝因 |
| 一种通过求得气泡指数,并确定临界气泡指数值,从而控制在包括一个或多个高熔点金属容器的系统中流过的玻璃熔体中形成气泡的方法。所述气泡指数的临界值可用来控制造成气泡形成的主要变量,包括熔体中的水含量,熔体中还原的多价氧化物的浓度,以及与高熔点金属容器外表面接触的气氛中的氢气分压。还揭示了用基本不含砷和锑的玻璃制造基本无气泡的玻璃制品所需的氢气的最小分压。 | ||||||
| 26 | 玻璃组合物及玻璃物品的制造方法 | CN200480029247.0 | 2004-10-19 | CN100569680C | 2009-12-16 | 青木重明; 永井裕树; 高木雅隆 |
| 本发明的玻璃组合物是无机玻璃的玻璃组合物,在玻璃中所含氦内,质量数为3的同位素与质量数为4的同位素的体积比(0℃,1大气压),比大气中的3He/4He的值小。而且本发明的玻璃物品的制造方法,包括将玻璃原料加热熔融的工序、将熔融玻璃均质化的工序、将熔融玻璃成形为所需形状的工序和冷却到室温的工序,根据该方法制成本发明的成形品,使其含有给定重量比的氦。 | ||||||
| 27 | 等离子显示面板用含无机粒子组合物、转印薄膜和等离子显示面板的制造方法 | CN200480010919.3 | 2004-02-25 | CN1777970A | 2006-05-24 | 川岸诚治; 山下隆德; 伊藤克美; 井上靖健 |
| 本发明提供一种等离子显示面板用含无机粒子组合物、使用该组合物的转印薄膜和等离子显示面板的制造方法。该组合物含有[A]无机粒子和[B]具有用式(I)表示的重复单元的聚合物。该组合物也可以进一步含有增塑剂和/或硅烷耦联剂。该组合物提供具有出色的各种特性的转印薄膜。本发明的等离子显示面板的制造方法能够在低温、短时间内的烧成工序中,有效地形成各种特性出色的等离子显示面板的构成要素。该制造方法例如具有通过将从由该组合物得到的膜形成材料层转印到基板上,烧成已转印的膜形成材料层,在上述基板上形成电介质层的工序。 | ||||||
| 28 | 玻璃球的制造方法和制造装置 | CN02809253.8 | 2002-12-25 | CN1234629C | 2006-01-04 | 平贺将浩; 古川成男; 藤田光宏 |
| 本发明是玻璃球制造装置,该装置具有:熔化坩埚2,其加热、熔化玻璃;喷嘴2A,其设置在该熔化坩埚2的下方、使熔化坩埚2中的熔化玻璃4滴下;玻璃液滴接收部11,其设在该喷嘴2A的下方,充填了用于冷却从喷嘴2A滴下的玻璃液滴10的冷却液体150;该冷却液体150由玻璃液滴10于冷却液体150中冷却到玻璃转变温度以下期间,玻璃液滴10)的热量使冷却液体150汽化而在玻璃液滴10周围形成汽泡层的材料组成;本发明是使用该装置的制造方法,能连续、高效、低价制造圆度良好的玻璃球。 | ||||||
| 29 | LED LAMP, LED ILLUMINATION DEVICE, AND LED MODULE | EP11750317.7 | 2011-02-16 | EP2543920B1 | 2017-11-15 | MATSUBAYASHI, Yoko; YAGI, Hiroshi; SHIMIZU, Masanori; MANABE, Yoshio; MOTOYA, Atsushi; MATSUO, Kazuhiro; MORI, Toshio |
| An LED lamp provides a strong red color with a natural appearance. The LED lamp 1 is provided with an LED module 5 and a filter 16. The LED module 5 includes a blue LED 12 with a main emission peak in the 440 nm to 460 nm wavelength band, a green/yellow phosphor 14 that is excited by light emitted by the blue LED 12, and a red phosphor 15 that is excited by light emitted by at least one of the blue LED 12 and the green/yellow phosphor 14. The filter 16 reduces the spectral radiation intensity of at least a portion of the 570 nm to 590 nm wavelength band among light emitted by the LED module 5. | ||||||
| 30 | VERFAHREN ZUR HERSTELLUNG VON TITAN-DOTIERTEM KIESELGLAS FÜR DEN EINSATZ IN DER EUV-LITHOGRAPHIE | EP14744804.7 | 2014-07-22 | EP3033306B8 | 2017-08-16 | OCHS, Stefan; BECKER, Klaus; THOMAS, Stephan |
| 31 | Method of eliminating blisters in a glass making process | EP11153802.1 | 2006-12-08 | EP2311780A3 | 2013-03-13 | Dorfeld, William G; Ellison, Adam J; Li, Qiao; Schiefelbein, Susan L |
A method of controlling blister formation in a glass melt flowing through a system comprising one ore more refractory metal vessels by developing a blister index and determining the critical blister index value. The critical value of the blister index may be used to control the principal variables responsible for blister formation, including the water content of the melt, the concentration of reduced multivalent oxide compounds in the melt, and the hydrogen partial pressure of an atmosphere in contact with the outside surface of the refractory metal vessel. Also disclosed is a minimum partial pressure of hydrogen necessary to produce an essentially blister-free glass article in a glass essentially free of arsenic and antimony
|
||||||
| 32 | Method of eliminating blisters in a glass making process | EP11153802.1 | 2006-12-08 | EP2311780A2 | 2011-04-20 | Dorfeld, William G; Ellison, Adam J; Li, Qiao; Schiefelbein, Susan L |
A method of controlling blister formation in a glass melt flowing through a system comprising one ore more refractory metal vessels by developing a blister index and determining the critical blister index value. The critical value of the blister index may be used to control the principal variables responsible for blister formation, including the water content of the melt, the concentration of reduced multivalent oxide compounds in the melt, and the hydrogen partial pressure of an atmosphere in contact with the outside surface of the refractory metal vessel. Also disclosed is a minimum partial pressure of hydrogen necessary to produce an essentially blister-free glass article in a glass essentially free of arsenic and antimony
|
||||||
| 33 | PROCESS AND APPARATUS FOR PRODUCING SPHERICAL GLASS | EP02791993.5 | 2002-12-25 | EP1460043A1 | 2004-09-22 | HIRAKA, Masahiro; FURUKAWA, Shigeo; FUJITA, Mitsuhiro |
The apparatus for producing glass beads of the present invention comprises a melting pot 2 for heating and melting glass, a nozzle 2A for dripping molten glass 4 in the melting pot 2, which is disposed at the bottom of the melting pot 2, and a liquid glass droplet receiver 11 filled with cooling solution 150 for cooling the liquid glass droplet 10 dripped from the nozzle 2A, which is disposed under the nozzle 2A, wherein the cooling solution 150 is made from a material that forms a bubble layer around the liquid glass droplet 10 as the cooling solution 150 is vaporized due to the heat of the liquid glass droplet 10 during a period when the liquid glass droplet 10 is cooled down to a temperature lower than the glass transfer temperature in the cooling solution 150. |
||||||
| 34 | NOUVELLES COMPOSITIONS A BASE DE DERIVES DE SILICE MODIFIEE PAR DES GROUPEMENTS ORGANIQUES, LEUR PREPARATION ET LEUR APPLICATION, NOTAMMENT COMME CONDUCTEURS CATIONIQUES | EP87904276.0 | 1987-07-02 | EP0274488B1 | 1991-11-06 | ARMAND, Michel; CHARBOUILLOT, Yves; HAMMOU, Abdelkader; Ravaine, Denis |
| Composition based on derivatives of silica modified by organic groups, characterized in that said derivatives are amorphous solids having formula (I) SiO2-0,5(x+y)(Z1)x(Z2)y.(XA)z, wherein Z1 is a group having formula (II), R1 being an alkylene having from 3 to 8 carbon atoms optionally interrupted by a heteroatomic group -NH-, R3 and R4 representing each -H or representing together a group -CH=CH-N=CH-, Z2 is a group -R2-SO3H, R2 being an alkylene having from 3 to 8 carbon atoms optionally interrupted by a heteroatomic group -NH-; XA is an acid (case where X=H) or a salt (case where X=metal) soluble in water; x is a number different from 0 and lower or equal to 1; y is a number which may vary from 0 to 0.5 and not higher than x; x and y being such that the sum (x+y) is higher or equal to 1/3; it being understood that the sum (x+y) is at the most equal to 1; and z is a number which is optionally nil and such that the ratio (z+y)/x is higher than 0 and lower than or equal to 1; its preparation and its application as an agent for the transmission of electromagnetic waves and/or electric currents. | ||||||
| 35 | Method for making sodium-containing glass or ceramic | EP85308787.2 | 1985-12-03 | EP0198980A2 | 1986-10-29 | Bocko, Peter Lawrence; Wein, William Joseph; Thompson, David Allen |
A method for producing sodium-containing ceramics or, particularly, sodium-containing glasses, by a vapor deposition process wherein a vapor mixture containing a sodium fluoroalkoxide compound is reacted to provide a particulate sodium-containing vapor deposition product which can be sintered to a glass. |
||||||
| 36 | Method for drying oxide glasses | EP83305066.9 | 1983-09-01 | EP0103441B1 | 1986-07-23 | Beales, Keith John; Carter, Steve Fitzgerald; Partington, Sally; France, Paul William |
| 37 | Coil component | US15452051 | 2017-03-07 | US10134519B2 | 2018-11-20 | Yuya Ishida |
| A coil component including: a magnetic core that contains an Fe-based magnetic powder and a binding agent, the Fe-based magnetic powder having an insulator film and having a volume resistivity of 107 Ω·cm or more; and a coil conductor. The average particle size D50 of the Fe-based magnetic powder is 5 μm or smaller and the magnetic permeability of the magnetic core is 5 or more. | ||||||
| 38 | Cover glass article | US15348095 | 2016-11-10 | US10051753B2 | 2018-08-14 | Karl David Ehemann; Keith Raymond Gaylo; William Brashear Mattingly, III; Connor Thomas O'Malley; Ljerka Ukrainczyk; Kevin Lee Wasson |
| A cover glass article includes a glass body having a three-dimensional shape, an inside surface, and an outside surface. Each of the inside and outside surfaces has a surface roughness (Ra) less than 1 nm and is free of indentations having diameters larger than 150 μm. | ||||||
| 39 | GTMS connector for oil and gas market | US14930742 | 2015-11-03 | US09741463B2 | 2017-08-22 | Charles Leedecke; David Filkins; Jens Suffner; Ellen Kay Little; Julio Castillo; Sabine Pichler-Wilhelm |
| A feed-through element for harsh environments is provided that includes a support body with at least one access opening, in which at least one functional element is arranged in an electrically insulating fixing material. The electrically insulating fixing material contains a glass or a glass ceramic with a volume resistivity of greater than 1.0×1010 Ω cm at the temperature of 350° C. The glass or a glass ceramic has a defined composition range in the system SiO2—B2O3-MO. | ||||||
| 40 | CHEMICALLY STRENGTHENED GLASS AND METHODS OF MAKING SAME | US15429994 | 2017-02-10 | US20170204004A1 | 2017-07-20 | Qiang Huang; Kenneth P. Rodbell; Asli Sahin |
| In one aspect, a method for use in preparing a glass comprises: performing a first ion exchange process to replace at least a first ion in the glass with at least a second ion, the second ion being smaller than the first ion; and performing a second ion exchange process to replace at least the second ion in the glass with at least a third ion, the third ion being larger than the first ion. In another aspect, a glass is prepared at least in part by: performing a first ion exchange process to replace at least a first ion in the glass with at least a second ion, the second ion being smaller than the first ion; and performing a second ion exchange process to replace at least the second ion in the glass with at least a third ion, the third ion being larger than the first ion. | ||||||
