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 |
|---|---|---|---|---|---|---|
| 1 | 面板层叠体的制造方法和固化状态判别方法 | CN201480012388.5 | 2014-02-21 | CN105026136A | 2015-11-04 | 菊地亮; 土田健一郎 |
| 本发明的面板层叠体(16)的制造方法具备:第1贴附工序,将粘接片(15)的一个面贴附于第1面板体(110)的板面,第1面板体(110)具有板材(11)、框状的遮光部(14),粘接片(15)是包含紫外线固化型粘接剂的片,具有:主体部(15a),其主要覆盖遮光部(14)的内侧的上述板面;以及试验部(15b),其从主体部(15a)的周缘朝向外侧延伸设置,重叠于遮光部(14)上;第2贴附工序,以试验部(15b)从第2面板体(12)的周缘露出到外侧的方式,将第2面板体(12)的一个板面贴附到未固化状态的粘接片(15)的另一个面;照射工序,对粘接片(15)照射紫外线;剥离工序,从遮光部14剥离试验部(15b);以及判别工序,基于试验部(15b)的剥离时的状态,判别粘接片(15)的固化状态。 | ||||||
| 2 | 纳米纤维纱线、带和板的制造和应用 | CN201310153933.X | 2005-11-09 | CN103276486A | 2013-09-04 | 张梅; 房少立; R·H·鲍曼; A·A·扎希多夫; K·R·阿特金森; A·E·阿利耶夫; S·利; C·威廉斯 |
| 本发明涉及一种用于生成纳米纤维带或板的工艺,所述工艺包括以下步骤(a)布置纳米纤维以提供基本平行的纳米纤维阵列,该纳米纤维阵列在该纳米纤维阵列内具有纤维间连接性;以及(b)从所述纳米纤维阵列拉伸所述纳米纤维作为带或板,而基本上不对所述带或板加捻,其中所述带或板的宽度至少约1毫米。本发明还涉及纳米纤维纱线、带和板的制造工艺、装置及其应用。 | ||||||
| 3 | 面板层叠体的制造方法和固化状态判别方法 | CN201480012388.5 | 2014-02-21 | CN105026136B | 2016-11-30 | 菊地亮; 土田健一郎 |
| 本发明的面板层叠体(16)的制造方法具备:第1贴附工序,将粘接片(15)的一个面贴附于第1面板体(110)的板面,第1面板体(110)具有板材(11)、框状的遮光部(14),粘接片(15)是包含紫外线固化型粘接剂的片,具有:主体部(15a),其主要覆盖遮光部(14)的内侧的上述板面;以及试验部(15b),其从主体部(15a)的周缘朝向外侧延伸设置,重叠于遮光部(14)上;第2贴附工序,以试验部(15b)从第2面板体(12)的周缘露出到外侧的方式,将第2面板体(12)的一个板面贴附到未固化状态的粘接片(15)的另一个面;照射工序,对粘接片(15)照射紫外线;剥离工序,从遮光部14剥离试验部(15b);以及判别工序,基于试验部(15b)的剥离时的状态,判别粘接片(15)的固化状态。 | ||||||
| 4 | 纳米纤维带和板以及加捻和无捻纳米纤维纱线的制造和应用 | CN200580046210.3 | 2005-11-09 | CN101437663A | 2009-05-20 | 张梅; 房少立; R·H·鲍曼; A·A·扎希多夫; K·R·阿特金森; A·E·阿利耶夫; S·利; C·威廉斯 |
| 本发明涉及纳米纤维纱线、带和板,制造所述纱线、带和板的方法,以及所述纱线、带和板的应用。在一些实施例中,纳米管纱线、带和板包括碳纳米管。本发明的这些碳纳米管纱线提供了独特特性和特性组合,例如极高的韧度,对结头处失效的抵抗力,高的导热和导电性,高的可逆能量吸收,与其它具有相似韧度的纤维的百分之几的失效应变相比高达13%的失效应变,对蠕变的极高抗性,甚至在450℃下在空气中加热1小时时都保持强度,以及甚至在空气中照射也极高的辐射和UV抗性。另外,这些纳米管纱线可以被纺成直径1微米的纱线,并随意合股成双股、四股和更多股的纱线。另外的实施例提供了具有任意大宽度的纳米纤维板的纺织。在另外的实施例中,本发明涉及利用和/或包括本发明的纳米纤维纱线、带和板的应用和器件。 | ||||||
| 5 | 有表面性能增强的聚甲醛共混物基材和至少一层于其上的层状物品及其制造工艺 | CN200380106813.9 | 2003-12-17 | CN1729100A | 2006-02-01 | E·A·弗莱克斯曼; S·格罗伊利希; K·L·里奇曼; P·斯卡拉穆兹诺 |
| 本发明涉及层状物品,包含(a)一种基材,包含99.5~40wt%聚甲醛聚合物,和0.5~60wt%至少一种非缩醛热塑性聚合物;和(b)至少一个沉积于其上的附加层。 | ||||||
| 6 | 纳米纤维纱线、带和板的制造和应用 | CN201310153933.X | 2005-11-09 | CN103276486B | 2017-12-15 | 张梅; 房少立; R·H·鲍曼; A·A·扎希多夫; K·R·阿特金森; A·E·阿利耶夫; S·利; C·威廉斯 |
| 本发明涉及一种用于生成纳米纤维带或板的工艺,所述工艺包括以下步骤(a)布置纳米纤维以提供基本平行的纳米纤维阵列,该纳米纤维阵列在该纳米纤维阵列内具有纤维间连接性;以及(b)从所述纳米纤维阵列拉伸所述纳米纤维作为带或板,而基本上不对所述带或板加捻,其中所述带或板的宽度至少约1毫米。本发明还涉及纳米纤维纱线、带和板的制造工艺、装置及其应用。 | ||||||
| 7 | 纳米纤维带和板以及加捻和无捻纳米纤维纱线的制造和应用 | CN200580046210.3 | 2005-11-09 | CN101437663B | 2013-06-19 | 张梅; 房少立; R·H·鲍曼; A·A·扎希多夫; K·R·阿特金森; A·E·阿利耶夫; S·利; C·威廉斯 |
| 本发明涉及纳米纤维纱线、带和板,制造所述纱线、带和板的方法,以及所述纱线、带和板的应用。在一些实施例中,纳米管纱线、带和板包括碳纳米管。本发明的这些碳纳米管纱线提供了独特特性和特性组合,例如极高的韧度,对结头处失效的抵抗力,高的导热和导电性,高的可逆能量吸收,与其它具有相似韧度的纤维的百分之几的失效应变相比高达13%的失效应变,对蠕变的极高抗性,甚至在450℃下在空气中加热1小时时都保持强度,以及甚至在空气中照射也极高的辐射和UV抗性。另外,这些纳米管纱线可以被纺成直径1微米的纱线,并随意合股成双股、四股和更多股的纱线。另外的实施例提供了具有任意大宽度的纳米纤维板的纺织。在另外的实施例中,本发明涉及利用和/或包括本发明的纳米纤维纱线、带和板的应用和器件。 | ||||||
| 8 | 有表面性能增强的聚甲醛共混物基材和至少一层于其上的层状物品及其制造工艺 | CN200380106813.9 | 2003-12-17 | CN100528556C | 2009-08-19 | E·A·弗莱克斯曼; S·格罗伊利希; K·L·里奇曼; P·斯卡拉穆兹诺 |
| 本发明涉及层状制品,包含(a)一种基材,包含99.5~40wt%聚甲醛聚合物,和0.5~60wt%至少一种非缩醛热塑性聚合物;和(b)至少一个沉积于其上的附加层。 | ||||||
| 9 | Chips with hermetically sealed but openable chambers | US15237965 | 2016-08-16 | US10005271B2 | 2018-06-26 | Raymond Miller Karam; Thomas Wynne; Anthony Thomas Chobot |
| Embodiments generally relate to chips containing one or more hermetically sealed chambers that may be dismantled under controlled conditions using a release technique. 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. | ||||||
| 10 | Fabrication and application of nanofiber ribbons and sheets and twisted and non-twisted nanofiber yarns | US15204737 | 2016-07-07 | US09944529B2 | 2018-04-17 | 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 that includes nanofibers in which the process includes forming a yarn, ribbon or sheet comprising nanofibers, and applying an enhancing agent comprising a polymer to the yarn, ribbon or sheet. | ||||||
| 11 | Fabrication and application of nanofiber ribbons and sheets and twisted and non-twisted nanofiber yarns | US15299553 | 2016-10-21 | US09815699B1 | 2017-11-14 | 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. | ||||||
| 12 | FABRICATION AND APPLICATION OF NANOFIBER RIBBONS AND SHEETS AND TWISTED AND NON-TWISTED NANOFIBER YARNS | US15216614 | 2016-07-21 | US20170137290A1 | 2017-05-18 | 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 furnace 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 the sheet, ribbon or yarn. The substrate continuously moves from the furnace growth region into a region where the nanofibers in the forest are drawn. | ||||||
| 13 | FABRICATION AND APPLICATION OF NANOFIBER RIBBONS AND SHEETS AND TWISTED AND NON-TWISTED NANOFIBER YARNS | US15204737 | 2016-07-07 | US20170096750A1 | 2017-04-06 | 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 that includes nanofibers in which the process includes forming a yarn, ribbon or sheet comprising nanofibers, and applying an enhancing agent comprising a polymer to the yarn, ribbon or sheet. | ||||||
| 14 | Methods to dismantle hermetically sealed chambers | US15237953 | 2016-08-16 | US20160368258A1 | 2016-12-22 | 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. | ||||||
| 15 | Nanofiber ribbons and sheets and fabrication and application thereof | US14581092 | 2014-12-23 | US09512545B2 | 2016-12-06 | 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. | ||||||
| 16 | Methods to form and to dismantle hermetically sealed chambers | US14270265 | 2014-05-05 | US09440424B2 | 2016-09-13 | 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. | ||||||
| 17 | FABRICATION OF NANOFIBER RIBBONS AND SHEETS | US14952179 | 2015-11-25 | US20160083872A1 | 2016-03-24 | Mei Zhang; Shaoli Fang; Ray H. Baughman; Anvar A. Zakhidov; Kenneth Ross Atkinson; Ali E. Aliev; Sergey Li; Chris Williams |
| Fabricating a nanofiber ribbon or sheet with a process that includes providing a primary assembly by arranging carbon nanotube nanofibers in aligned arrays, the arrays having a degree of inter-fiber connectivity, drawing the carbon nanotube nanofibers from the primary assembly into a sheet or ribbon, and depositing the sheet or ribbon on a substrate. | ||||||
| 18 | FABRICATION AND APPLICATION OF NANOFIBER RIBBONS AND SHEETS AND TWISTED AND NON-TWISTED NANOFIBER YARNS | US14332632 | 2014-07-16 | US20150308018A1 | 2015-10-29 | 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 IJV 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. | ||||||
| 19 | INDUCTION WELDING PROCESS AND DEVICE FOR PARTS MADE OF COMPOSITE MATERIALS | US14623143 | 2015-02-16 | US20150231869A1 | 2015-08-20 | Florian CHOTARD; Cyrille COLLART; Didier TRICHET, I; Javad FOULADGAR |
| A device comprising at least one pressure generation unit and a heating unit, the heating unit comprising a two-sided inductor and being configured to generate a uniform alternating magnetic field in an assembly comprising two parts made of composite materials comprising carbon fibers embedded in a resin and a field absorber. The field absorber is configured to absorb the magnetic field and comprising a ferromagnetic material. The field absorber is arranged at the contact walls of the two parts, so as to heat them to at least a transformation temperature of the resin. | ||||||
| 20 | Fabrication of twisted and non-twisted nanofiber yarns | US11718954 | 2005-11-09 | US08926933B2 | 2015-01-06 | Mei Zhang; Ray H. Baughman; Kenneth Ross Atkinson |
| The present invention is directed to methods of making nanofiber yarns. In some embodiments, the nanotube yarns 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. | ||||||
QQ群二维码
意见反馈
意见反馈