公开(公告)号：US20190119803A1

公开(公告)日：2019-04-25

申请号：US15789393

申请日：2017-10-20

Applicant: United Technologies Corporation

Inventor： Xia Tang ,  David C. Jarmon ,  James T. Beals ,  R. Wesley Jackson ,  Paul Sheedy

IPC: C23C4/10 ,  C23C4/12 ,  C23C4/134 ,  C23C4/129

Abstract: A coated article including an article having a surface; an oxidation resistant bond coat layer deposited on the surface, the oxidation resistant bond coat layer comprising a healing silica matrix and at least one oxygen scavenger forming a metal silicide network dispersed within the healing silica matrix; and a top coat layer disposed upon the oxidation resistant bond coat layer, whereby the oxidation resistant bond coat layer is operable to seal a crack in the top coat layer.

公开(公告)号：US20190062911A1

公开(公告)日：2019-02-28

申请号：US15685830

申请日：2017-08-24

Applicant: United Technologies Corporation

Inventor： Paul Sheedy ,  Neal Magdefrau

IPC: C23C16/455

Abstract: A method for atomic layer deposition of high temperature materials from single source precursors includes placing a substrate in a reaction zone in gas isolation from other reaction zones and contacting the substrate in the reaction zone with a reactant to allow atoms in the reactant to combine with reaction sites on the substrate to form a layer of the reactant on the substrate. The substrate is then placed in a purge zone and purged with a flowing inert gas. The substrate is then placed in a final reaction zone in gas isolation from the other zones wherein the final reaction zone has an atmosphere and temperature to decompose adsorbed reactant and/or form desired phases with crystallinity to form a layer of material. The substrate is then placed in a purge zone and the process is repeated until a layer of material of desired thickness is formed on the substrate.

公开(公告)号：US20190024532A1

公开(公告)日：2019-01-24

申请号：US15652837

申请日：2017-07-18

Applicant: United Technologies Corporation

Inventor： Sameh Dardona ,  Dustin D. Caldwell ,  Paul Sheedy ,  Thomas D. Kasprow

IPC: F01D21/00 ,  F01D5/12 ,  F01D11/12 ,  G01B7/14

CPC classification number: F01D21/003 ,  F01D5/12 ,  F01D11/122 ,  F05D2220/32 ,  F05D2260/80 ,  G01B7/14

Abstract: In combination a wear indication sensor and a component of a gas turbine engine is provided. The wear indication sensor is secured to a first surface of the component of the gas turbine engine. The wear indication sensor comprises: a first terminal; a second terminal electrically connected to the first terminal; two or more of resistors electrically connecting the first terminal to the second terminal, each of the two or more resistors including a first end electrically connected to the first terminal and a second end electrically connected to the second terminal, wherein each of the two or more resistors has a known resistance; and a first electrode electrically connecting the first terminal to the first end of each of the two or more resistors; wherein the first end of each of the two or more resistors is electrically connected to the first electrode through primary conductive lines.

公开(公告)号：US10087110B2

公开(公告)日：2018-10-02

申请号：US15490306

申请日：2017-04-18

Applicant: United Technologies Corporation

Inventor： Paul Sheedy ,  Wayde R. Schmidt

IPC: C04B38/06 ,  C04B38/00 ,  C04B35/573 ,  C04B35/80 ,  C04B35/657 ,  C04B35/65 ,  F01D5/28 ,  F01D25/00 ,  F02K3/06

Abstract: A method of creating a component comprises forming a substrate and depositing a template material within the substrate, such that there are a plurality of template member. The component is heated to a temperature above a melting point of the template material, such that the template material wicks into a porosity of the substrate and forms a component with voids. An average hydraulic diameter of the voids is less than 1 millimeter.

公开(公告)号：US20170335118A1

公开(公告)日：2017-11-23

申请号：US15158640

申请日：2016-05-19

Applicant: United Technologies Corporation

Inventor： Xia Tang ,  David C. Jarmon ,  Paul Sheedy ,  Virginia H. Faustino

IPC: C09D5/08 ,  B01J20/02 ,  B01J20/10 ,  C03C17/02

CPC classification number: C09D5/084 ,  B01J20/02 ,  B01J20/0218 ,  B01J20/10 ,  C03C17/02 ,  C23C24/08 ,  C23C30/00

Abstract: An article comprising a substrate and at least one coating layer disposed on the substrate. The coating layer includes a silicate glass matrix, an oxygen scavenger phase dispersed through the silicate glass matrix, and at least one metal in metallic form.

公开(公告)号：US20170002249A1

公开(公告)日：2017-01-05

申请号：US15267198

申请日：2016-09-16

Applicant: United Technologies Corporation

Inventor： Wayde R. Schmidt ,  Tania Bhatia Kashyap ,  Paul Sheedy

IPC: C09K5/14 ,  C04B35/628 ,  B05D3/02 ,  C04B35/80 ,  C04B35/63 ,  C04B35/65 ,  C04B35/622

CPC classification number: C09K5/14 ,  B05D3/0254 ,  B05D2601/28 ,  C04B35/571 ,  C04B35/589 ,  C04B35/62227 ,  C04B35/6269 ,  C04B35/62842 ,  C04B35/62844 ,  C04B35/6303 ,  C04B35/65 ,  C04B35/76 ,  C04B35/80 ,  C04B35/806 ,  C04B2235/3891 ,  C04B2235/40 ,  C04B2235/404 ,  C04B2235/408 ,  C04B2235/421 ,  C04B2235/428 ,  C04B2235/48 ,  C04B2235/483 ,  C04B2235/5216 ,  C04B2235/522 ,  C04B2235/5244 ,  C04B2235/5248 ,  C04B2235/5252 ,  C04B2235/5268 ,  C04B2235/616 ,  C04B2235/6584 ,  C04B2235/661 ,  C04B2235/80 ,  C04B2235/9607 ,  C22C29/065

Abstract: A method for fabricating a ceramic material includes impregnating a porous structure with a mixture that includes a preceramic polymer and a filler. The filler includes at least one free metal. The preceramic polymer material is then rigidized to form a green body. The green body is then thermally treated to convert the rigidized preceramic polymer material into a ceramic matrix located within pores of the porous structure. The same thermal treatment or a second, further thermal treatment is used to cause the at least one free metal to move to internal porosity defined by the ceramic matrix or pores of the porous structure.

Abstract translation: 制造陶瓷材料的方法包括用包含预陶瓷聚合物和填料的混合物浸渍多孔结构。 填料包括至少一种游离金属。 然后将预陶瓷聚合物材料硬化以形成生坯体。 然后对生坯进行热处理以将刚性化的陶瓷前体陶瓷聚合物材料转化成位于多孔结构孔内的陶瓷基体。 使用相同的热处理或第二次进一步的热处理以使至少一种游离金属移动到由多孔结构的陶瓷基体或孔隙限定的内部孔隙中。

公开(公告)号：US20160243722A1

公开(公告)日：2016-08-25

申请号：US15026094

申请日：2014-09-29

Applicant: UNITED TECHNOLOGIES CORPORATION

Inventor： Shahram Amini ,  Wayde R. Schmidt ,  Tania Bhatia Kashyap ,  Mark A. Hermann ,  Paul Sheedy ,  Andi M. Limarga ,  Michael G. McCaffrey

IPC: B28B1/24 ,  C04B38/00 ,  B28B1/52

CPC classification number: B28B1/24 ,  B28B1/52 ,  B28B11/243 ,  C04B35/524 ,  C04B35/532 ,  C04B35/806 ,  C04B38/0022 ,  C04B2235/48 ,  C04B2235/5252 ,  C04B2235/602 ,  C04B2235/616

Abstract: A disclosed method of forming a ceramic article includes forming a pre-ceramic polymer article within a mold tool, and performing a first pyrolizing step on the initial pre-ceramic polymer article to form a ceramic article. The method further includes performing at least one pre-heat treatment polymer infiltration and pyrolizing (PIP) cycle on the ceramic article and an initial heat treatment cycle of the ceramic article after the at least one pre-heat treatment PIP cycle. Subsequent PIP cycles and heat treatment cycles are performed in combination to form a ceramic article including a desired density.

Abstract translation: 公开的形成陶瓷制品的方法包括在模具工具内形成预陶瓷聚合物制品，并在初始预陶瓷聚合物制品上进行第一热解步骤以形成陶瓷制品。 该方法还包括在至少一个预热处理PIP循环之后，在陶瓷制品上进行至少一个预热处理聚合物浸渍和热解（PIP）循环和陶瓷制品的初始热处理循环。 随后的PIP循环和热处理循环组合进行以形成包括所需密度的陶瓷制品。

公开(公告)号：US20160236986A1

公开(公告)日：2016-08-18

申请号：US15027705

申请日：2014-09-24

Applicant: UNITED TECHNOLOGIES CORPORATION

Inventor： Andi Limarga ,  Paul Sheedy ,  Wayde R. Schmidt ,  Douglas M. Berczik ,  Tania Bhatia Kashyap ,  Mark A. Hermann

IPC: C04B35/571

CPC classification number: C04B35/571 ,  C04B35/58 ,  C04B35/806 ,  C04B2235/3821 ,  C04B2235/383 ,  C04B2235/3852 ,  C04B2235/386 ,  C04B2235/3865 ,  C04B2235/3873 ,  C04B2235/422 ,  C04B2235/425 ,  C04B2235/427 ,  C04B2235/5244 ,  C04B2235/5288 ,  C04B2235/5454 ,  C04B2235/616

Abstract: Disclosed is a method for providing a crystalline ceramic material. In an example, the method includes providing a silicon-containing preceramic polymer material that can be thermally converted to one or more crystalline polymorphs. The silicon-containing preceramic polymer material includes dispersed therein an effective amount of dopant particles. The silicon-containing preceramic polymer material is then thermally converted to the silicon-containing ceramic material. The effective amount of dopant particles enhance the formation of at least one of the one or more crystalline polymorphs, relative to the silicon-containing preceramic polymer without the dopant particles, with respect to at least one of formation of a selected polymorph of the one or more crystalline polymorphs formed, an amount formed of a selected polymorph of the one or more crystalline polymorphs formed, and a temperature of formation of the one or more crystalline polymorphs.

Abstract translation: 公开了一种提供结晶陶瓷材料的方法。 在一个实例中，该方法包括提供可以热转化成一种或多种结晶多晶型物的含硅预陶瓷聚合物材料。 含硅预陶瓷聚合物材料包括分散有效量的掺杂剂颗粒。 然后将含硅预陶瓷聚合物材料热转化成含硅陶瓷材料。 相对于没有掺杂剂颗粒的含硅预陶瓷聚合物，相对于形成所选择的多晶型物的一个或多个结晶多晶型物中的至少一种，掺杂剂颗粒的有效量增加了至少一个， 形成更多的结晶多晶型物，由所形成的一种或多种结晶多晶型物的选定多晶型物形成的量和形成一种或多种结晶多晶型物的温度。

公开(公告)号：US20210155760A1

公开(公告)日：2021-05-27

申请号：US16692620

申请日：2019-11-22

Applicant: United Technologies Corporation

Inventor： Wayde R. Schmidt ,  Paul Sheedy

IPC: C08G77/60 ,  C04B35/571 ,  C04B35/56 ,  C08G77/398

Abstract: Disclosed is a modified preceramic polymer having a polymer backbone consisting of silicon or a combination of silicon and carbon; and a pendant modifier bonded to the backbone wherein the modifier includes silicon, boron, aluminum, a transition metal, a refractory metal, or a combination thereof. The modified preceramic polymer can be used to form a ceramic matrix composite.

公开(公告)号：US20210071537A1

公开(公告)日：2021-03-11

申请号：US16562078

申请日：2019-09-05

Applicant: United Technologies Corporation

Inventor： Xia Tang ,  Richard Wesley Jackson ,  Paul Sheedy ,  James T. Beals

IPC: F01D5/28 ,  B32B9/00 ,  C04B35/622 ,  C04B35/63

Abstract: A coating fabrication method includes providing engineered granules and thermally consolidating the engineered granules on a substrate to form a silicate-resistant barrier coating. Each of the engineered granules is an aggregate of at least one refractory matrix region and at least one calcium aluminosilicate additive region (CAS additive region) attached with the at least one refractory matrix region. In the thermal consolidation, the refractory matrix region from the engineered granules form grains of a refractory matrix of the silicate-resistant barrier coating and the CAS additive region from the engineered granules form CAS additives that are dispersed in grain boundaries between the grains.