子分类:
| 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 | 多層フィルム | JP2016539079 | 2014-12-10 | JP6434520B2 | 2018-12-05 | トーマス エドワード カーニー; ジェフリー マイケル バートリン; クリストファー ロバート ベックス |
| 42 | ガスバリア性積層体、電子デバイス用部材及び電子デバイス | JP2018099371 | 2018-05-24 | JP2018171929A | 2018-11-08 | 鈴木 悠太; 岩屋 渉; 永元 公市; 近藤 健 |
| 【課題】高いガスバリア性と耐折曲げ性を有するガスバリア性積層体、該積層体からなる電子デバイス用部材、及び、電子デバイスを提供する。 【解決手段】基材と、ガスバリア性ユニットとを有するガスバリア性積層体であって、前記ガスバリア性ユニットが、少なくとも2層の無機層を含み、少なくとも1層は酸窒化珪素層4であり、前記酸窒化珪素層が、ポリシラザン系化合物を含む層にイオン注入処理を行うことによって形成されたものである。更に、厚みが25nm以上であり、層中の厚み方向に対して基材側へ向かうにしたがって酸素元素の存在比が減少し、窒素元素の存在比が増加する傾斜組成領域4aを有するものであり、前記傾斜組成領域の厚みの酸窒化珪素層全体の厚みに対する比が0.15以上である。 【選択図】図1 |
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| 43 | ガスバリア性積層体、電子デバイス用部材及び電子デバイス | JP2015508800 | 2014-03-28 | JP6353828B2 | 2018-07-04 | 鈴木 悠太; 岩屋 渉; 永元 公市; 近藤 健 |
| 44 | 可塑性PCMシート材 | JP2016568623 | 2015-05-19 | JP2017523061A | 2017-08-17 | ディルク、ビュットナー; アンジェロ、シュッツ; マルティン、ガイセンヘーナー |
| 本発明は、熱調節目的に高潜熱蓄熱密度を有する可塑性PCMシート材に関する。可塑性PCMシート材は、可塑性支持構造およびその上に別々に配置された特定の形状の相変化物質を含んでなる。相変化物質要素自体にポリマー結合相変化物質から成る幾何学的に画定した構造が含まれている。可塑性PCMシート材は、高潜熱蓄熱容量および最適化された熱伝導性によって特徴付けられ、温度変化および相転移後の場合においても寸法的に安定であり、問題なく、ロール状にし、折りたたみ、巻き付け、またはサイズに合わせて切断することができ、単一層または多層で輸送、保存、処理または使用することができる。 | ||||||
| 45 | 複合材及びその製造方法 | JP2015063641 | 2015-03-26 | JP6034910B2 | 2016-11-30 | 藤田 博康; 関根 尚之; 川島 愛 |
| 46 | Carbon fiber preforms and methods for their production | JP51052890 | 1990-07-24 | JP2894828B2 | 1999-05-24 | IIBANSU MOORISU JEEMUZU; UIRIAMUZU KEISU ARAN; FUITSUSHAA RONARUDO |
| 47 | Three dimensional structural body and its production | JP10190696 | 1996-03-31 | JPH09273059A | 1997-10-21 | MORITA HIROAKI |
| PROBLEM TO BE SOLVED: To obtain a new material, composed of a structural raw material mainly consisting of carbon fibers, enabling the effective utilization of the features such as excellent strength, frictional and abrasive resistances and chemical stability of carbon fibers, capable of creating a carbon fiber laminar structural body having adequate elasticity, compressive repulsion, compressive durability, etc., which are never available in a carbon fiber itself as a raw material and accordingly can be used in applications closely related to human sensitivity. SOLUTION: This new material is composed of a fiber aggregate containing a carbon fiber in an amount of ≥50wt.% based on the total of fibers and consisting of a crimped fiber in an amount of 50-100wt.% based on the total of fibers, and a binding agent consisting of a thermosetting resin and/or a heat fusing fiber. The new material is a three dimensional structural body of a carbon fiber having a three dimensional network structure bonded at contact points of fibers to themselves with a bonding agent and has a bulk density of 20-80kg/m 3 and a compressive hardness LC of 0.7-0.9 at a maximum load of 100gf/cm 2. COPYRIGHT: (C)1997,JPO | ||||||
| 48 | JPS5714894B2 - | JP4835577 | 1977-04-26 | JPS5714894B2 | 1982-03-27 | |
| 49 | REINFORCED COMPOSITES, METHODS OF MANUFACTURE, AND ARTICLES THEREFROM | US15945856 | 2018-04-05 | US20180229469A1 | 2018-08-16 | Lei Zhao; Zhiyue Xu |
| A reinforced composite comprises: a reinforcement material comprising one or more of the following: a carbon fiber based reinforcing material; a fiberglass based reinforcing material; a metal based reinforcing material; or a ceramic based reinforcing material; and a carbon composite; wherein the carbon composite comprises carbon and a binder containing one or more of the following: SiO2; Si; B; B2O3; a metal; or an alloy of the metal; and wherein the metal is one or more of the following: aluminum; copper; titanium; nickel; tungsten; chromium; iron; manganese; zirconium; hafnium; vanadium; niobium; molybdenum; tin; bismuth; antimony; lead; cadmium; or selenium. | ||||||
| 50 | Structures constructed using coal combustion materials | US15710580 | 2017-09-20 | US09988317B2 | 2018-06-05 | Francis Norbert Hector, Jr.; Juan Keith Carroll |
| Beneficial use structures are disclosed that include coal combustion residuals (“CCR”) mixed with water and a binder to form a structural material and adapted to be compacted for use in the formation of the beneficial use structure. Various structures having beneficial uses described, including survival bunkers, composting pits, mine reclamation encapsulation and carbon sequestration facilities, water storage facilities, compressed air storage facilities, carbon sequestration/mineral carbonation facilities and a pumped hydroelectric facility adapted for use with a lock system of a waterway. | ||||||
| 51 | Composite Film | US15555387 | 2015-08-24 | US20180037010A1 | 2018-02-08 | Lambert Nekula; Martin Kornfeld; Adolf Schedl; Harald Gruber |
| A composite film including at least one backing film made of a backing material, at least one barrier layer made of a barrier film and at least one laminating adhesive layer therebetween. On the side of the barrier layer away from the backing layer, the composite film has a raised pattern, and in the area of the raised pattern, the barrier layer has stretched stretching regions relative to the non-stretched barrier film. In the area of the raised pattern, the barrier layer has on the side facing the backing layer surfaces that are not joined to the backing layer. | ||||||
| 52 | COMPOSITION AND METHOD FOR MAKING A FLEXIBLE PACKAGING FILM | US15463712 | 2017-03-20 | US20170190854A1 | 2017-07-06 | Ashley LEIDOLF; Brad Dewayne RODGERS; Benjamin SOUCY |
| Composition and method for making a flexible packaging film having highly loaded with at least one inorganic filler. A blown HDPE film comprising at least 50% by weight inorganic filler is oriented in the machine direction to increase yield and tensile strength, and reduce gauge variation to improve print qualities. | ||||||
| 53 | Flexible PCM Sheet Materials | US15311633 | 2015-05-19 | US20170087799A1 | 2017-03-30 | Dirk BÜTTNER; Angelo SCHÜTZ; Martin GEISSENHÖNER |
| The invention relates to flexible PCM sheet materials having a high latent thermal energy storage density for the purpose of heat management. The flexible PCM sheet material includes a flexible supporting structure and phase-change-material elements arranged thereon separately in a specific geometry. The phase-change-material elements are geometrically defined structures composed of polymer-bound phase-change material. The flexible PCM sheet materials are characterized by a high latent heat storage capacity and optimized thermal conductivity, are dimensionally stable even in the event of temperature changes and after phase transitions, can be rolled, folded, wound, or cut to size without problems, and can be transported, stored processed, or used in a single layer or in multiple layers. | ||||||
| 54 | LINOLEUM FLOORING | US15090784 | 2016-04-05 | US20160215507A1 | 2016-07-28 | Jeffrey S. Ross; Dong Tian; Larry W. Leininger; Bennett E. Wallick |
| Described herein is a linoleum flooring product that includes a linoleum substrate and a printed wear layer having decorative indicia. The printed wear layer includes a wear layer and an ink print layer. The linoleum substrate may include a base linoleum layer applied on a backing material and the printed wear layer may be adhesively bonded onto the linoleum substrate. | ||||||
| 55 | Food Package | US14428651 | 2013-09-13 | US20150210461A1 | 2015-07-30 | Brendan Leigh Morris; David Colin Jacka |
| This invention relates to food packaging and to methods for its manufacture. It is particularly suited to packaging of perishable foodstuffs which require that oxygen transmission occur across the packaging barrier, but that water vapour transmission be restricted. | ||||||
| 56 | SINTERED BORON NITRIDE BODY AND METHOD FOR PRODUCING A SINTERED BORON NITRIDE BODY | US14549722 | 2014-11-21 | US20150147520A1 | 2015-05-28 | Rudolf K. Grau; Rodrigue N. Yappi; Hubert J. Schweiger |
| In order to provide a sintered, hexagonal boron nitride body (2a, 2b), same is produced by at least one pressing process and subsequent sintering process from a powder (P) made of a hexagonal boron nitride, its density being deliberately set to a value of <1.6 g/cm3. Studies have shown that, due to the selection of this lower density, the boron nitride body (2a, 2b) exhibits very high isotropy, when compared with conventional hexagonal boron nitride bodies. This relates in particular to thermal conductivity and the coefficient of thermal expansion, which are also largely temperature-independent. | ||||||
| 57 | EXTRUSION-COATED STRUCTURAL MEMBERS HAVING EXTRUDED PROFILE MEMBERS | US14496529 | 2014-09-25 | US20150110988A1 | 2015-04-23 | Jennifer Lynne Peavey; Mohan Sasthav; James Wilson Mercer, JR.; Scott Allen Clear; Chanandh Cheowanich |
| The present disclosure relates to extrusion-coated structural systems including at least one extruded profile member coupled to and extending outwardly from an extrusion-coated structural member, as well as methods of making and using the same. Structural systems of the present invention that include at least one extruded profile member may exhibit enhanced flexibility, functionality, and/or durability. Structural systems according to embodiments of the present invention can be suitable for use in a variety of applications, including in ready-to-assemble furniture or cabinetry applications or as building and construction materials such as wall board, flooring, trim, and the like. | ||||||
| 58 | GRAPHENE AND FLUORPOLYMER COMPOSITE | US14044446 | 2013-10-02 | US20150093584A1 | 2015-04-02 | Qi Zhang; Yu Qi; Brynn Dooley; Nan-Xing Hu |
| A composition comprises a liquid continuous phase and a plurality of composite particles dispersed therein. The composite particles each comprise a fluorosilane-treated graphene-comprising particle and a fluoropolymer particle. | ||||||
| 59 | Composite graphene oxide-polymer laminate and method | US12931407 | 2011-01-31 | US08709213B2 | 2014-04-29 | Owen C. Compton; Karl W. Putz; L. Catherine Brinson; SonBinh T. Nguyen |
| A macroscale, self-supporting, composite laminate sheet includes individual, layered graphene oxide sheets and a polymer in spaces between the sheets. This composite product can be fabricated by combining a suspension of individual graphene oxide sheets and a solution of polymer, passing the resulting fluid through a fluid-permeable support, and assembling the graphene oxide sheets and polymer as a laminate sheet by flow-directed assembly. The laminate is dried and released from the membrane filter as a self-supporting thin films. | ||||||
| 60 | PHOTOLUMINESCENT OBJECTS | US13657953 | 2012-10-23 | US20140065442A1 | 2014-03-06 | Edward D. Kingsley; Satish Agrawal |
| An object comprising a low rare earth mineral photoluminescent structure incorporated onto or into one or more portions of the object, the object being a photoluminescent object is disclosed. Further disclosed is a method for fabricating the object. An object comprising a low rare earth mineral photoluminescent composition incorporated onto or into one or more portions of the object, the object being a photoluminescent object is also disclosed, as well as, a method for fabricating the object. | ||||||
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