| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 161 | 일체형 냉각 통로를 구비한 세라믹 매트릭스 복합 구조 및제조 방법 | KR1020047004278 | 2002-09-17 | KR1020040037105A | 2004-05-04 | 모리슨제이; 버트너스티븐씨; 캠프벨크리스찬엑스; 알브레흐트해리에이; 슈테이만예브게이 |
| 다중층 세라믹 매트릭스 복합 구조(40)는 그 안에 형성된 복수의 섬유-보강 냉각 통로(42)를 갖고 있다. 냉각 통로는 퓨지티브 물질의 제거에 의해 형성된다. 퓨지티브 물질은 다중층 구조를 적층하는데 사용되는 보강 세라믹 섬유(26)의 층을 포함하는 둘러싸인 퓨지티브 물질 구조의 일부이다. 세라믹 직물의 중간층은 냉각 통로를 상부와 하부 냉각 통로로 분리하기 위하여 둘러싸인 퓨지티브 물질 구조의 위 아래에 교대로 놓여질 수 있다. 냉각 통로를 둘러싸는 횡방향으로 배향된 섬유는 종래기술 설계에 비하여 구조의 층간 강도를 증가시키는 역할을 한다. 보강된 일체형 냉각 통로를 포함하는 에어포일 부재가 제공된다. | ||||||
| 162 | 세라믹 접합체 | KR1020037009501 | 2002-08-12 | KR1020040031691A | 2004-04-13 | 이토야스타카; 오쿠라가즈테루 |
| 본 발명의 목적은, 반도체 제품의 제조/검사 단계에 사용하기 위해, 서로 강하게 접합된 세라믹 기판과 원통체 등의 세라믹체를 구비하고, 세라믹 기판에서의 내부식성이 뛰어난 세라믹 접합체를 제공하는 것이다. 본 발명에 따른 세라믹 접합체는, 도전체가 제공된 세라믹 기판; 및 세라믹 기판의 바닥면에 접합된 세라믹체를 구비하고, 세라믹 접합체는, 세라믹 기판과 세라믹체 사이의 접합계면의 위쪽영역의 적어도 일부에, 도전체가 형성되지 않은 영역을 갖는다. | ||||||
| 163 | 반도체 제조 장치용 웨이퍼 지지체와 그 제조 방법 및반도체 제조 장치 | KR1020010003124 | 2001-01-19 | KR100420456B1 | 2004-03-02 | 구이비라아끼라; 나까따히로히꼬 |
| A wafer holder for a semiconductor manufacturing apparatus that has a high heat conductivity and includes a conductive layer such as heater circuit pattern which can be formed with a high precision pattern, a method of manufacturing the wafer holder, and a semiconductor manufacturing apparatus having therein the wafer holder are provided. On a surface of a sintered aluminum nitride piece (10a), paste containing metal particles is applied and fired to form a heater circuit pattern (11) as a conductive layer. Between the surface of the sintered aluminum nitride piece (10a) having the heater circuit pattern (11) formed thereon and another sintered aluminum nitride piece (10b), a glass layer (14) is provided as a joint layer to be heated for joining the sintered aluminum nitride pieces (10a and 10b) together. <IMAGE> <IMAGE> | ||||||
| 164 | 세라믹 히터 및 세라믹 접합체 | KR1020037003473 | 2002-07-08 | KR1020030072324A | 2003-09-13 | 이토야스타카 |
| 본 발명의 목적은 반도체 웨이퍼를 안정하게 지지할 수 있으며, 또한, 반도체 웨이퍼 등에 휘어짐이 발생하지 않고, 반도체 웨이퍼 등의 전체를 균일하게 가열할 수 있는 세라믹 히터를 제공하는 것에 있고, 본 발명은 원판 형상 세라믹 기판 표면 또는 내부에 발열체가 형성되며, 상기 세라믹 기판에 리프터 핀을 삽입 관통하기 위한 관통 구멍이 형성된 세라믹 히터에 있어서, 상기 관통 구멍은 3개 이상 형성됨과 더불어, 상기 세라믹 기판의 중심으로부터 가장자리까지의 거리에 대하여, 상기 중심으로부터 1/2 이상의 거리인 영역에 형성되어 있는 것을 특징으로 한다. | ||||||
| 165 | 이종 부재 접합용 접착제 조성물, 동 조성물을 이용한접합 방법 및 동 접합 방법에 의해 접합된 복합 부재 | KR1020000060642 | 2000-10-16 | KR100372796B1 | 2003-02-25 | 신카이마사유키; 기다마사히로 |
| There are provided an adhesive composition for bonding two or more different members which can give a bonded material excellent in heat resistance and others with inhibiting breakage of the materials to be bonded by reducing expansion coefficient, and, besides, Young's modulus and proof stress value, a method for bonding two or more different members using the adhesive composition, and a composite member comprising two or more different members bonded by the above method. The above can be provided by the adhesive composition which comprises a hard solder and a mixture of at least two fine particle materials differing in wettability with the hard solder and is controlled in expansion coefficient, Young's modulus and proof stress value. | ||||||
| 166 | 반도체 제조 장치용 웨이퍼 지지체와 그 제조 방법 및반도체 제조 장치 | KR1020010003124 | 2001-01-19 | KR1020010076378A | 2001-08-11 | 구이비라아끼라; 나까따히로히꼬 |
| PURPOSE: A method of manufacturing wafer holder is provided to have a high heat conductivity, and enable a conductive layer to be embedded therein with a high precision pattern. CONSTITUTION: On a surface of a sintered aluminum nitride piece(10a), paste containing metal particles is applied and fired to form a heater circuit pattern(11) as a conductive layer. Between the surface of the sintered aluminum nitride piece(10a) having the heater circuit pattern(11) formed thereon and another sintered aluminum nitride piece(10b), a glass layer(14) is provided as a joint layer to be heated for joining the sintered aluminum nitride pieces(10a,10b) together. | ||||||
| 167 | Joined body manufacturing method | US15254035 | 2016-09-01 | US10150709B2 | 2018-12-11 | Tomoyuki Minami; Kazuhiro Nobori; Tetsuya Kawajiri |
| In a step (a), a guard ring is disposed on a ceramic substrate (a second member) such that one of openings of a through hole of the guard ring is covered with a joint surface of the ceramic substrate. In a step (b), a brazing material made of a metal, a powder made of a material having a smaller thermal expansion coefficient than the brazing material, and a feeding terminal are inserted into the through hole. In a step (c), the brazing material is fused to impregnate the powder with the brazing material to thereby form a joint layer including the brazing material and the powder. In this manner, the joint surface and the joint surface are joined to each other through the joint layer. | ||||||
| 168 | 3-D PRINTING OF A CERAMIC COMPONENT | US15778365 | 2016-11-24 | US20180339946A1 | 2018-11-29 | Oswin ÖTTINGER; Dominik RIVOLA; Stefan KLEIN; Andreas KIENZLE; Ingrid KRÄTSCHMER |
| A method for producing the component, and to the use of the component. The method for producing a three-dimensional, ceramic component containing silicon carbide, by a) providing a powdery composition having a grain size (d50) between 3 microns and 500 microns and comprising at least 50 wt % of coke, b) providing a liquid binder, c) depositing a layer of the material provided in a) in a planar manner and locally depositing drops of the material provided in b) onto said layer and repeating step c), the local depositing of the drops in the subsequent repetitions of the step is adapted in accordance with the desired shape of the component to be produced, d) at least partially curing or drying the binder and obtaining a green body having the desired shape of the component, e) carbonising the green body, and 0 siliconising the carbonised green body by infiltration with liquid silicon. | ||||||
| 169 | Ceramic matrix composite component and method of forming thereof | US14099225 | 2013-12-06 | US10071537B2 | 2018-09-11 | Brian Lee Muench; Morris Dahmen |
| A method of forming a ceramic matrix composite component is provided. The method includes applying a first amount of adhesive across a surface of a release film, providing a first ceramic foam panel including a plurality of channels formed on a first side of the first ceramic foam panel, contacting the first ceramic foam panel and the release film such that adhesive transfers to the first side of the first ceramic foam panel, and coupling the first ceramic foam panel to a second ceramic foam panel. | ||||||
| 170 | High-K LTCC dielectric compositions and devices | US15310155 | 2016-06-29 | US10065894B2 | 2018-09-04 | Walter J. Symes, Jr. |
| Electronic devices are produced from dielectric compositions comprising a mixture of precursor materials that, upon firing, forms a dielectric material comprising a barium-strontium-titanium-tungsten-silicon oxide. | ||||||
| 171 | HYBRID CERAMIC MATRIX COMPOSITE COMPONENTS FOR GAS TURBINES | US15554727 | 2015-03-27 | US20180238178A1 | 2018-08-23 | Stefan Lampenscherf; Ramesh Subramanian; Jay A. Morrison |
| A hybrid component (45) is provided including a plurality of laminates (10) stacked on one another to define a stacked laminate structure (58). The laminates (10) include a ceramic matrix composite material (22) and at least one opening (24) defined therein. A metal support structure (56) may be additively manufactured through each opening (24) so as to extend through the stacked laminate structure (58). | ||||||
| 172 | Method of making carbon fiber preforms | US14788217 | 2015-06-30 | US10035305B2 | 2018-07-31 | Mark L. La Forest; Slawomir T. Fryska |
| In some examples, a method includes depositing a mixture including a resin and an additive powder via a print head of a three-dimensional printing system to form a carbon fiber preform including a plurality of individual carbon fiber layers, wherein each individual layer of the plurality of individual carbon fiber layers includes a plurality of carbon fibers and the mixture of the resin and the additive powder. | ||||||
| 173 | LAMINATED CERAMIC MOLDED ARTICLE HAVING RECESSES | US15324954 | 2015-07-10 | US20170267591A1 | 2017-09-21 | Thomas BETZ; Harald KRESS |
| The invention relates to a ceramic molded article (1) that has recesses (2) and comprises at least two plates (joined parts) (3) made of a ceramic material, i.e. a lower base plate (9), an upper cover plate (8) and, optionally, one or more intermediate plates (7) which are stacked on top of each other and are joined to each other on the surfaces thereof to form the molded article (1); a joining material (paste) is placed between the plates (joined parts) (3). | ||||||
| 174 | Sintered body for varistor, multilayer substrate using same, and production method for these | US15101650 | 2014-12-05 | US09741477B2 | 2017-08-22 | Naoyuki Okamoto; Hiroyuki Ito; Toshiki Kida |
| To provide a zinc oxide-based varistor that exhibits adequate characteristics without using antimony. Disclosed is a sintered body for a varistor, including zinc oxide as a main component; 0.6 to 3.0 mol % of bismuth oxide in terms of bismuth (Bi); 0.2 to 1.4 mol % of cobalt oxide in terms of cobalt (Co); 0.1 to 1.5 mol % of chrome oxide in terms of chrome (Cr); and 0.1 to 1.5 mol % of manganese oxide in terms of manganese (Mn), wherein the contents of antimony (Sb), a rare earth element and tin (Sn) are not more than a level of impurities. | ||||||
| 175 | Monolithic Ceramic Component and Production Method | US15358702 | 2016-11-22 | US20170236634A1 | 2017-08-17 | Christian Block; Pavol Dudesek; Thomas Feichtinger; Christian Hoffmann; Guenter Pudmich |
| A film stack made from compacted green films and capable of being sintered to form a ceramic component with monolithic multi-layer structure is disclosed. The film stack includes a functional layer comprising a green film comprising a functional ceramic and a tension layer comprising a green film comprising a dielectric material. The tension layer is directly adjacent to the functional layer in the multi-layer structure. The multilayer structure also includes a first metallization plane and second metallization plane. The functional layer is between the first metallization plane and the second metallization plane. | ||||||
| 176 | Carbon ceramic brake disc and method for manufacturing the same | US14995908 | 2016-01-14 | US09732811B2 | 2017-08-15 | Dong Won Im; Yeon Ho Choi; Kang Yoo; Nam Cheol Lee |
| A carbon ceramic brake disc according to the present invention includes: a support body having cooling channels at the center portion; and friction layers directly attached to the top and the bottom of the support body without a bonding layer and having components different from the components of the support body, in which the support body is composed of a plurality of layers having components similar to the friction layers, gradually toward the friction layers from the cooling channels as the center.Accordingly, the support body can perform thermomechanical shock absorbing that is an original function and the friction layers and the support body can be prevented from separating while the carbon ceramic brake disc is manufactured. | ||||||
| 177 | METHOD FOR PRODUCING A DOUBLE-WALLED THERMOSTRUCTURAL MONOLITHIC COMPOSTE PART, AND PART PRODUCED | US15514900 | 2015-09-24 | US20170217843A1 | 2017-08-03 | Marc BOUCHEZ; Steffen BEYER; Stephan Schmidt-Wimmer |
| A fibrous preform (1) is produced, provided with a sandwich structure comprising an intermediate flexible core (4) and two outer fibrous frames (2, 3), respectively arranged on opposing outer faces of said flexible core (4) and assembled by sections of wire (8, 9) passing through said fibrous frames (2, 3), said preform (1) being impregnated with resin. Said preform is then hardened and the core (4) is removed, preferably by pre-densification with chemical vapour infiltration, and the structure produced is then densified with liquid-phase infiltration. | ||||||
| 178 | Method for manufacturing liquid ejecting head | US14222002 | 2014-03-21 | US09634235B2 | 2017-04-25 | Junhua Zhang |
| A method for manufacturing a liquid ejecting head including a laminate formed of a flow path substrate having a flow path communicating with nozzle openings that eject a liquid, a first electrode, a piezoelectric layer, and a second electrode, the method including stacking the first electrode, the piezoelectric material, the second electrode, and a reinforcing member on top of one another to form a laminate; heating the laminate to form a piezoelectric layer made of the piezoelectric material; bonding the laminate to the flow path substrate on a first electrode side; and removing the reinforcing member. | ||||||
| 179 | CERAMIC MATRIX COMPOSITE COMPONENT AND PROCESS OF PRODUCING A CERAMIC MATRIX COMPOSITE COMPONENT | US14878084 | 2015-10-08 | US20170101873A1 | 2017-04-13 | Victor John MORGAN; Jacob John KITTLESON; Andres Jose GARCIA-CRESPO; Benjamin Paul LACY |
| A process of producing a hot gas path turbine component. The process includes forming a void in a first ceramic matrix composite ply and forming a void in a second ceramic matrix composite ply. The second ceramic matrix composite ply is positioned on the first ceramic matrix composite ply such that the positioning aligns the voids to at least partially define a cavity in the component. A third ceramic matrix composite ply is positioned on the first ceramic matrix composite ply and the first ceramic matrix composite ply, the second ceramic matrix composite ply and the third ceramic matrix composite ply are densified to form a densified body. The cavity is present in the densified body. A ceramic matrix composite having cavities therein is also disclosed. | ||||||
| 180 | INTERCONNECT FOR SOLID OXIDE FUEL CELL AND METHOD FOR MANUFACTURING THE SAME | US15341460 | 2016-11-02 | US20170077525A1 | 2017-03-16 | Sung Han KIM; Jong Ho CHUNG; Jong Sik YOON; Bon Seok KOO |
| Disclosed herein are an interconnect for a solid oxide fuel cell and a method for manufacturing the same, the interconnect including: a conductive core; an oxidation-resistant insulating part receiving therein; and an oxidation-resistant conductive material layer coated on an exposed surface of the conductive core, which is exposed to an external environment by removing a portion of the oxidation-resistant insulating part, so that the interconnect can maintain durability against high-temperature heat generated from a flat type solid oxide fuel cell for a long time and thus have a very small voltage loss due to oxidation even with the use over a long-time period; have no sealing problem and no delaminating problem of a coating film due to a difference in coefficient of thermal expansion; be inexpensive; and have a simple structure. | ||||||
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