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 | METAL RESIN COMPOSITE MOLDED BODY AND METHOD FOR PRODUCING THE SAME | US15580175 | 2016-04-28 | US20180229263A1 | 2018-08-16 | Yusuke Nishikori; Masanori Endo; Miyuki Yoshida |
| A metal resin composite molded body wherein various metal bases and a resin molded body are integrally and firmly bonded with each other; and a versatile method for producing this metal resin composite molded body are provided. Particularly provided are: a metal resin composite molded body wherein an aluminum base and a polyolefin resin molded body are integrally and firmly bonded with each other; and a simple method for producing this metal resin composite molded body. A metal resin composite molded body comprises a metal base, a polypropylene resin layer and a thermoplastic resin molded body. The polypropylene resin layer is bonded to the metal base with a hydrophilic surface being interposed therebetween. The hydrophilic surface is formed on the metal base. The thermoplastic resin molded body is bonded to the polypropylene resin layer by means of anchoring effect and compatibilizing effect with the polypropylene resin layer. | ||||||
| 42 | Fabrication and application of nanofiber ribbons and sheets and twisted and non-twisted nanofiber yarns | US15216614 | 2016-07-21 | US09862607B2 | 2018-01-09 | Mei Zhang; Shaoli Fang; Ray H. Baughman; Anvar A. Zakhidov; Kenneth Ross Atkinson; Ali E. Aliev; Sergey Li; Chris Williams |
| Fabricating a nanofiber sheet, ribbon, or yarn by a continuous process that includes synthesizing a nanofiber forest in a forest growth region on a substrate, wherein the nanofiber forest comprises a parallel array of nanofibers, and further includes drawing said nanofibers from the nanofiber forest to form a primary assembly that is a sheet, ribbon or yarn. The substrate continuously moves from the furnace growth region into a region where the nanofibers in the forest are drawn. | ||||||
| 43 | Fabrication and application of nanofiber ribbons and sheets and twisted and non-twisted nanofiber yarns | US15055395 | 2016-02-26 | US09845554B2 | 2017-12-19 | Mei Zhang; Shaoli Fang; Ray H. Baughman; Anvar A. Zakhidov; Ali E. Aliev; Sergey Li; Chris Williams |
| The present invention is directed to nanofiber yarns, ribbons, and sheets; to methods of making said yarns, ribbons, and sheets; and to applications of said yarns, ribbons, and sheets. In some embodiments, the nanotube yarns, ribbons, and sheets comprise carbon nanotubes. Particularly, such carbon nanotube yarns of the present invention provide unique properties and property combinations such as extreme toughness, resistance to failure at knots, high electrical and thermal conductivities, high absorption of energy that occurs reversibly, up to 13% strain-to-failure compared with the few percent strain-to-failure of other fibers with similar toughness, very high resistance to creep, retention of strength even when heated in air at 450° C. for one hour, and very high radiation and UV resistance, even when irradiated in air. Furthermore these nanotube yarns can be spun as one micron diameter yarns and plied at will to make two-fold, four-fold, and higher fold yarns. Additional embodiments provide for the spinning of nanofiber sheets having arbitrarily large widths. In still additional embodiments, the present invention is directed to applications and devices that utilize and/or comprise the nanofiber yarns, ribbons, and sheets of the present invention. | ||||||
| 44 | FABRICATION AND APPLICATION OF NANOFIBER RIBBONS AND SHEETS AND TWISTED AND NON-TWISTED NANOFIBER YARNS | US15299553 | 2016-10-21 | US20170327377A1 | 2017-11-16 | Mei Zhang; Shaoli Fang; Ray H. Baughman; Anvar A. Zakhidov; Kenneth Ross Atkinson; Ali E. Aliev; Sergey Li; Chris Williams |
| A nanofiber forest on a substrate can be patterned to produce a patterned assembly of nanofibers that can be drawn to form nanofiber sheets, ribbons, or yarns. | ||||||
| 45 | Methods to dismantle hermetically sealed chambers | US15237953 | 2016-08-16 | US09809019B2 | 2017-11-07 | Raymond Miller Karam; Thomas Wynne; Anthony Thomas Chobot |
| Embodiments generally relate to apparatus and methods for dismantling a hermetically sealed chamber. In one embodiment, an apparatus facilitating the opening of a hermetically sealed chamber in a device comprises a fixture configured to hold the device, and a system configured to create sufficient tensile or shear stress at a bond interface of the seal to open the seal under controlled conditions. In one embodiment, a method for opening a hermetic seal between first and second elements forming a chamber in a microfluidic chip comprises using a release technique creating sufficient tensile or shear stress at a bond interface of the seal to open the seal under controlled conditions. The release technique comprises introducing a tool to the vicinity of the interface without any contact between the tool and any material within the chamber. The breaking of the seal results in the complete separation of the first and second elements. | ||||||
| 46 | Fabrication and application of nanofiber ribbons and sheets and twisted and non-twisted nanofiber yarns | US15204643 | 2016-07-07 | US09688536B2 | 2017-06-27 | Mei Zhang; Shaoli Fang; Ray H. Baughman; Anvar A. Zakhidov; Kenneth Ross Atkinson; Ali E. Aliev; Sergey Li; Chris Williams |
| A process of producing a yarn, ribbon or sheet comprising nanofibers that includes infiltrating a liquid into the yarn, ribbon or sheet and evaporating the liquid from the yarn, ribbon, or sheet to strengthen the yarn, ribbon or sheet. The yarn, ribbon, or sheet can be formed by solid-state draw from a carbon nanotube forest. | ||||||
| 47 | Multilayer system having reconfigurable dynamic structure reinforcement using nanoparticle embedded supramolecular adhesive and method | US14739128 | 2015-06-15 | US09557479B2 | 2017-01-31 | Sofya A Suntsova; Christopher J Felker |
| Methods, systems and apparatuses are disclosed comprising a tunable multilayered array reinforcement system having a supramolecular adhesive embedded with nanoparticles that are reoriented on-demand in response to or in advance of vibrational effects in a moving or stationary structure. | ||||||
| 48 | FABRICATION AND APPLICATION OF NANOFIBER RIBBONS AND SHEETS AND TWISTED AND NON-TWISTED NANOFIBER YARNS | US15204643 | 2016-07-07 | US20170001866A1 | 2017-01-05 | Mei Zhang; Shaoli Fang; Ray H. Baughman; Anvar A. Zakhidov; Kenneth Ross Atkinson; Ali E. Aliev; Sergey Li; Chris Williams |
| A process of producing a yarn, ribbon or sheet comprising nanofibers that includes infiltrating a liquid into the yarn, ribbon or sheet and evaporating the liquid from the yarn, ribbon, or sheet to strengthen the yarn, ribbon or sheet. The yarn, ribbon, or sheet can be formed by solid-state draw from a carbon nanotube forest. | ||||||
| 49 | Multilayer System Having Reconfigurable Dynamic Structure Reinforcement Using Nanoparticle Embedded Supramolecular Adhesive and Method | US14739128 | 2015-06-15 | US20160363727A1 | 2016-12-15 | Sofya A. Suntsova; Christopher J. Felker |
| Methods, systems and apparatuses are disclosed comprising a tunable multilayered array reinforcement system having a supramolecular adhesive embedded with nanoparticles that are reoriented on-demand in response to or in advance of vibrational effects in a moving or stationary structure. | ||||||
| 50 | Fabrication and application of nanofiber ribbons and sheets and twisted and non-twisted nanofiber yarns | US14332632 | 2014-07-16 | US09481949B2 | 2016-11-01 | Mei Zhang; Shaoli Fang; Ray H. Baughman; Anvar A. Zakhidov; Kenneth Ross Atkinson; Ali E. Aliev; Sergey Li; Chris Williams |
| The present invention is directed to nanofiber yarns, ribbons, and sheets; to methods of making said yarns, ribbons, and sheets; and to applications of said yarns, ribbons, and sheets. In some embodiments, the nanotube yarns, ribbons, and sheets comprise carbon nanotubes. Particularly, such carbon nanotube yarns of the present invention provide unique properties and property combinations such as extreme toughness, resistance to failure at knots, high electrical and thermal conductivities, high absorption of energy that occurs reversibly, up to 13% strain-to-failure compared with the few percent strain-to-failure of other fibers with similar toughness, very high resistance to creep, retention of strength even when heated in air at 450° C. for one hour, and very high radiation and UV resistance, even when irradiated in air. Furthermore these nanotube yarns can be spun as one micron diameter yarns and plied at will to make two-fold, four-fold, and higher fold yarns. Additional embodiments provide for the spinning of nanofiber sheets having arbitrarily large widths. In still additional embodiments, the present invention is directed to applications and devices that utilize and/or comprise the nanofiber yarns, ribbons, and sheets of the present invention. | ||||||
| 51 | FABRICATION AND APPLICATION OF NANOFIBER RIBBONS AND SHEETS AND TWISTED AND NON-TWISTED NANOFIBER YARNS | US15055395 | 2016-02-26 | US20160251778A1 | 2016-09-01 | Mei Zhang; Shaoli Fang; Ray H. Baughman; Anvar A. Zakhidov; Ali E. Aliev; Sergey Li; Chris Williams |
| The present invention is directed to nanofiber yarns, ribbons, and sheets; to methods of making said yarns, ribbons, and sheets; and to applications of said yarns, ribbons, and sheets. In some embodiments, the nanotube yarns, ribbons, and sheets comprise carbon nanotubes. Particularly, such carbon nanotube yarns of the present invention provide unique properties and property combinations such as extreme toughness, resistance to failure at knots, high electrical and thermal conductivities, high absorption of energy that occurs reversibly, up to 13% strain-to-failure compared with the few percent strain-to-failure of other fibers with similar toughness, very high resistance to creep, retention of strength even when heated in air at 450° C. for one hour, and very high radiation and UV resistance, even when irradiated in air. Furthermore these nanotube yarns can be spun as one micron diameter yarns and plied at will to make two-fold, four-fold, and higher fold yarns. Additional embodiments provide for the spinning of nanofiber sheets having arbitrarily large widths. In still additional embodiments, the present invention is directed to applications and devices that utilize and/or comprise the nanofiber yarns, ribbons, and sheets of the present invention. | ||||||
| 52 | METAL-AND-RESIN COMPOSITE AND METHOD FOR MAKING THE SAME | US14610154 | 2015-01-30 | US20160159029A1 | 2016-06-09 | CHWAN-HWA CHIANG; BAO-SHEN ZHANG; CHIEH-HSIANG WANG |
| A metal-and-resin composite includes a metal substrate having a plurality of nano pores, an intermediate layer formed on the metal substrate, and a resin member. The intermediate layer fills at least portion of each nano pore. The resin member covers and bonds with the intermediate layer, thus to bond with the metal substrate. | ||||||
| 53 | Methods to form and to dismantle hermetically sealed chambers | US14270265 | 2014-05-05 | US20150314585A1 | 2015-11-05 | Raymond Miller Karam; Thomas Wynne; Anthony Thomas Chobot |
| Embodiments generally relate to methods for forming and dismantling a hermetically sealed chamber. In one embodiment, the method comprises using room temperature laser bonding to create a hermetic seal between a first element and a second element to form a chamber. A bond interface of the hermetic seal is configured to allow the hermetic seal to be opened under controlled conditions using a release technique. In one embodiment, the chamber is formed within a microfluidic chip and the chamber is configured to hold a fluid. In one embodiment a chip comprises a first hermetic seal bonding first and second elements to create a first chamber and a second hermetic seal bonding third and fourth elements to create a second chamber encompassing the first chamber. The first hermetic seal may be broken open independently of the second hermetic seal by the application of a mechanical or thermal technique. | ||||||
| 54 | Large Area Graphene Composite Material | US14028862 | 2013-09-17 | US20150079340A1 | 2015-03-19 | Steven Edward Bullock; Clinton M. Newell |
| Large area graphene (LAG) sheets can be embedded in a polymer-based material as a mechanical reinforcement or to otherwise enhance the properties of the polymer-based material. The LAG sheets can be nanoperforated and/or functionalized to enhance interaction between the graphene and the polymer. Reactive functional groups can facilitate formation of covalent bonds between the graphene and the polymer so that the LAG sheets become an integral part of the cross-linked structure in curable polymer-based materials. Nanoperforations in the LAG sheets provide useful sites for the functional groups and can allow cross-links to form through the nanoperforations. | ||||||
| 55 | MULTILAYERED SHEET | US14386842 | 2013-04-17 | US20150056440A1 | 2015-02-26 | Dariusz Wlodzmierz Kawka |
| This invention pertains to a layered sheet structure comprising a carrier having a first and second surface, a metalized layer contacting one of the surfaces of the carrier and an inorganic refractory layer contacting the surface of the metalized layer not in contact with the carrier. The refractory layer has a dry area weight of from 15 to 50 gsm and a residual moisture content of no greater than 10 percent by weight. The carrier is a polymeric film, preferably polyethyleneterephthalate. | ||||||
| 56 | Device for the coating of metal strips | US11693 | 1998-03-10 | US06083336A | 2000-07-04 | Leonidas Kiriazis |
| Apparatus for coating metal sheets with plastic film, consisting of a sequential arrangement of metal sheet feed (1), oven (3), film feeding unit (4), corona stations (9), laminating rolls (10), texturing or smoothing rolls (7) and printing mechanism (8). | ||||||
| 57 | Packaging material and method of making a packaging material | US30750 | 1993-03-12 | US5484654A | 1996-01-16 | Walter B. Mueller |
| A packaging laminate which includes a layer of polymethylpentene film and a sealant film. The films may be bonded by corona treatment. The laminate displays high oxygen transmission and heat resistance and may be used as a packaging material for produce such as cauliflower, broccoli and lettuce. | ||||||
| 58 | Method and apparatus for direct bonding two bodies | US197495 | 1994-02-16 | US5421953A | 1995-06-06 | Masao Nagakubo; Seiji Fujino; Kouji Senda; Tadashi Hattori |
| Bodies of at least one material are held in a contacting holder 12 in a vacuum chamber. The surfaces of the bodies are cleaned by a low energy ion etching. Water vapor from a pure water bottle is supplied through a nozzle as a water molecule beam so that water molecules and hydroxide groups are chemically adsorbed on the surfaces of the bodies. A plasma beam or microwaves are applied to the surfaces of the bodies to remove the water molecules and leave only hydroxide groups remaining on the surfaces. The holder is operated to bring the surfaces of the bodies into contact with each other, to thereby obtain direct bonding of the bodies. | ||||||
| 59 | ナノファイバーのリボンおよびシートならびにナノファイバーの撚り糸および無撚り糸の製造および適用 | JP2016001971 | 2016-01-07 | JP6088075B2 | 2017-03-01 | チャン メイ; シャオリ ファン; レイ エイチ. ボーマン; アンワル エー. ザヒドフ; ケネス ロス アトキンソン; アリ イー. アリエフ; セルゲイ リー; クリス ウィリアムズ |
| 60 | ナノファイバーのリボンおよびシートならびにナノファイバーの撚り糸および無撚り糸の製造および適用 | JP2016181624 | 2016-09-16 | JP2016216888A | 2016-12-22 | チャン メイ; シャオリ ファン; レイ エイチ. ボーマン; アンワル エー. ザヒドフ; ケネス ロス アトキンソン; アリ イー. アリエフ; セルゲイ リー; クリス ウィリアムズ |
| 【課題】ナノファイバーの糸、リボン、およびシートに関するものであって;前記糸、リボン、およびシートを製造する方法;そして前記糸、リボン、およびシートの応用を提供すること。 【解決手段】幾つかの実施形態において、ナノチューブの糸、リボンおよびシートはカーボンナノチューブを含む。詳細には、本発明のその様なカーボンナノチューブは以下の様な独特な特性および特性の組み合わせを提供する。例えば、極度の靭性、ノットにおける破損に対する耐性、高レベルの電気および熱伝導性、可逆的に出現する高いエネルギー吸収性、破損歪みが同様な靭性を有するその他のファイバーにおける数%と比較して13%まであること、クリープに対する耐性が非常に高いこと、空気中で450℃にて1時間加熱した場合でさえも強度を保持すること、および空気中で照射された時でさえも非常に高い放射線耐性およびUV耐性などである。 【選択図】なし |
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