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1.发明申请Joining via Nano-Scale Reinforced Bonding Media: Materials, Procedures and Applications Thereof 有权通过纳米级强化粘合介质加入:材料,程序和应用公开(公告)号:US20150367617A1
公开(公告)日:2015-12-24
申请号:US13963197
申请日:2013-08-09
CPC分类号: B23K35/327 , B23K35/0222 , B23K35/0244 , B23K35/0255 , B23K35/262 , B23K35/284 , B23K35/286 , Y10T156/10
摘要: Method of joining articles using microscale brazing alloy particles reinforced with slender nanomaterials is described. Surface modified graphite nanomaterials were dispersed in a medium comprised of metal alloy particles, this dispersion was introduced at the interface between the joining articles followed by heating under ultra high vacuum. The nanomaterial-to-metal alloy surface contacts were enhanced by at least one of fusion, embedment and chemical reaction phenomena under high temperature and ultra high vacuum yielding true nanocomposite at the interface. The fusion, embedment and chemical reaction phenomena enhance at least one of the mechanical, electrical, thermal, durability and functional attributes of these contact points, which translate into improved properties of the joined article. The enhanced contact points enable effective use of the distinct qualities of nanomaterials towards development of joints which offer unique balances of strength, ductility, toughness, energy absorption, thermal stability, weathering resistance and other characteristics.
摘要翻译: 描述了使用细长的纳米材料增强的微细钎焊合金颗粒连接制品的方法。 将表面改性石墨纳米材料分散在由金属合金颗粒组成的介质中,将该分散体引入接合制品之间的界面处,然后在超高真空下加热。 通过在高温和超高真空下的融合,嵌入和化学反应现象中的至少一种在界面处产生真正的纳米复合材料,纳米材料 - 金属合金表面接触得到增强。 融合,嵌入和化学反应现象增强了这些接触点的机械,电气,热,耐久性和功能属性中的至少一个,这转化为改进的接合制品的性质。 增强的接触点能够有效地利用纳米材料的不同质量对接头的开发,其提供强度,延展性,韧性,能量吸收,热稳定性,耐候性和其它特性的独特平衡。
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2.发明申请ULTRA HIGH PERFORMANCE CONCRETE REINFORCED WITH LOW-COST GRAPHITE NANOMATERIALS AND MICROFIBERS, AND METHOD FOR PRODUCTION THEREOF 有权具有低成本石墨纳米微粒和微晶纤维的超高性能混凝土及其生产方法公开(公告)号:US20140060388A1
公开(公告)日:2014-03-06
申请号:US13600358
申请日:2012-08-31
IPC分类号: C04B28/04 , C08L79/00 , C08L29/04 , C08L23/12 , C08K3/20 , C08K3/04 , C08K3/08 , C08K3/36 , C08K11/00 , C08K3/22 , C08J3/28 , C04B16/00 , C04B14/48 , C04B16/02 , C04B18/06 , C04B28/08 , C04B28/06 , B29C70/02 , C08L33/02 , B82Y30/00
CPC分类号: C04B28/02 , B82Y30/00 , C08G10/04 , C08G73/0206 , C08L61/18 , C08L61/32 , C08L79/02 , C08L2205/16 , Y02W30/92 , Y02W30/94 , Y02W30/97 , C04B14/024 , C04B14/22 , C04B14/383 , C04B14/386 , C04B14/42 , C04B14/48 , C04B16/0633 , C04B16/0641 , C04B16/0691 , C04B18/08 , C04B18/101 , C04B18/141 , C04B18/146 , C04B18/24 , C04B22/008 , C04B24/26 , C04B24/2641 , C04B2103/12 , C04B2103/22 , C04B2103/302 , C04B2103/304 , C04B2103/32 , C04B2103/408 , C04B2103/54 , C04B2103/58 , C04B2103/65
摘要: Ultra-high-performance cementitious materials are made using suitably functionalized and relatively low-cost carbon nanofibers and graphite platelets. Polyelectrolytes and surfactants are physisorbed upon these graphite nanomaterials in water, and dispersion of nanomaterials in water is achieved by stirring. Stable and well-dispersed suspensions of nanomaterials in water are realized without using energy-intensive and costly methods, and also without the use of materials which could hinder the hydration and strength development of ultra-high-performance cementitious materials. The water incorporating dispersed nanomaterials is then mixed with the cementitious matrix and, optionally, microfibers, and cured following standard concrete mixing and curing practices. The resulting cementitious materials incorporating graphite nanomaterials and optionally microfibers offer a desired balance of strength, toughness, abrasion resistance, moisture barrier attributes, durability and fire resistance.
摘要翻译: 使用适当功能化且相对低成本的碳纳米纤维和石墨血小板制造超高性能水泥质材料。 聚电解质和表面活性剂在这些石墨纳米材料在水中被物理吸附,纳米材料在水中的分散是通过搅拌实现的。 实现了纳米材料在水中的稳定和良好分散的悬浮液,而不使用能量密集和昂贵的方法,并且也不使用可能阻碍超高性能水泥质材料的水合和强度发展的材料。 然后将掺入分散的纳米材料的水与水泥基质和任选的微纤维混合,并按照标准混凝土搅拌和固化实践进行固化。 所产生的石墨纳米材料和任选的微纤维的水泥质材料提供了所需的强度,韧性,耐磨性,防潮性,耐久性和耐火性的平衡。
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3.发明授权Nano-engineered structural joints: materials, procedures and applications thereof 有权纳米工程结构接头:材料,程序和应用公开(公告)号:US09387655B2
公开(公告)日:2016-07-12
申请号:US13854182
申请日:2013-04-01
CPC分类号: B32B37/1284 , B29C65/00 , B29C65/02 , B29C65/4815 , B29C65/486 , B29C65/5021 , B29C65/5028 , B29C65/5057 , B29C65/8215 , B29C66/02 , B29C66/0222 , B29C66/026 , B29C66/0342 , B29C66/1122 , B29C66/3494 , B29C66/41 , B29C66/71 , B29C66/7212 , B29C66/73115 , B29C66/7313 , B29C66/73921 , B29C66/73941 , B29C66/919 , B29C66/929 , B29C66/949 , B29K2105/124 , B29K2105/128 , B32B37/06 , B32B37/24 , B32B2037/1246 , B32B2037/243 , B82Y30/00 , C09J5/02 , C09J5/06 , F16B11/006 , Y10S977/847 , Y10T428/12444 , B29K2023/12 , B29K2309/08 , B29K2307/04 , B29K2063/00
摘要: A method of joining two articles through a nano-enhanced joining medium is described. Nanomaterials are applied to the surfaces of sheets made of the joining medium via casting or spraying. Said sheets with nanomaterial coatings are then placed between the joining surfaces of the articles, and then application of pressure and heating is used to form a nano-engineered structural joint at the interface of said articles. The distinctly high specific surface area of nanomaterials and the energetic preference of their functionalized surfaces for bonding facilitate the joining process. Nano-engineered structural joints complement high strength levels with desired toughness and the compliance needed for accommodating deformation (e.g. thermal expansion) mismatches of joined articles without generating high stress levels near their interface. The limited quantity (per unit joint surface area) of nanomaterials utilized in nano-engineered joints benefits their economic viability.
摘要翻译: 描述了通过纳米增强连接介质接合两种制品的方法。 通过铸造或喷涂将纳米材料施加到由接合介质制成的片材的表面上。 然后将具有纳米材料涂层的所述片材放置在制品的接合表面之间,然后使用压力和加热来在所述制品的界面处形成纳米工程结构接头。 纳米材料的明显高的比表面积和它们的官能化表面用于粘合的能量偏好有利于接合过程。 纳米工程结构接头补充高强度水平,具有所需的韧性和所需的适应性,以适应连接制品的变形(例如热膨胀)不匹配,而不会在其界面附近产生高应力水平。 在纳米工程接头中使用的纳米材料的有限数量(每单位接合面积)有利于其经济可行性。
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4.发明申请Nano-Engineered Structural Joints: Materials, Procedures and Applications Thereof 有权纳米工程结构接头:材料,程序和应用公开(公告)号:US20150375490A1
公开(公告)日:2015-12-31
申请号:US13854182
申请日:2013-04-01
CPC分类号: B32B37/1284 , B29C65/00 , B29C65/02 , B29C65/4815 , B29C65/486 , B29C65/5021 , B29C65/5028 , B29C65/5057 , B29C65/8215 , B29C66/02 , B29C66/0222 , B29C66/026 , B29C66/0342 , B29C66/1122 , B29C66/3494 , B29C66/41 , B29C66/71 , B29C66/7212 , B29C66/73115 , B29C66/7313 , B29C66/73921 , B29C66/73941 , B29C66/919 , B29C66/929 , B29C66/949 , B29K2105/124 , B29K2105/128 , B32B37/06 , B32B37/24 , B32B2037/1246 , B32B2037/243 , B82Y30/00 , C09J5/02 , C09J5/06 , F16B11/006 , Y10S977/847 , Y10T428/12444 , B29K2023/12 , B29K2309/08 , B29K2307/04 , B29K2063/00
摘要: A method of joining two articles through a nano-enhanced joining medium is described. Nanomaterials are applied to the surfaces of sheets made of the joining medium via casting or spraying. Said sheets with nanomaterial coatings are then placed between the joining surfaces of the articles, and then application of pressure and heating is used to form a nano-engineered structural joint at the interface of said articles. The distinctly high specific surface area of nanomaterials and the energetic preference of their functionalized surfaces for bonding facilitate the joining process. Nano-engineered structural joints complement high strength levels with desired toughness and the compliance needed for accommodating deformation (e.g. thermal expansion) mismatches of joined articles without generating high stress levels near their interface. The limited quantity (per unit joint surface area) of nanomaterials utilized in nano-engineered joints benefits their economic viability.
摘要翻译: 描述了通过纳米增强连接介质接合两种制品的方法。 通过铸造或喷涂将纳米材料施加到由接合介质制成的片材的表面上。 然后将具有纳米材料涂层的所述片材放置在制品的接合表面之间,然后使用压力和加热来在所述制品的界面处形成纳米工程结构接头。 纳米材料的明显高的比表面积和它们的官能化表面用于粘合的能量偏好有利于接合过程。 纳米工程结构接头补充高强度水平,具有所需的韧性和所需的适应性,以适应连接制品的变形(例如热膨胀)不匹配,而不会在其界面附近产生高应力水平。 在纳米工程接头中使用的纳米材料的有限数量(每单位接合面积)有利于其经济可行性。
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公开(公告)号:US09605181B2
公开(公告)日:2017-03-28
申请号:US14275966
申请日:2014-05-13
IPC分类号: C09J7/00
CPC分类号: C09J7/00 , C09J2201/626 , C09J2400/22 , Y10T428/2481
摘要: The present invention is directed towards an article suitable for attachment to facial skin or other surfaces, which comprises microfibrils and continuous microribbons. The article provides good sealing when used on a regular skin, and on a challenge skin surface with facial hair, sweat and acnes. The article also provides good adhesion and sealing on any other rough surfaces, and can be used repeatedly against different surfaces. These dry adhesives can be used for improving sealing of mask respirators, swimming goggles, or for other applications such as medical bandage, working gloves, and protective clothing seal.
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6.发明申请MICROPATTERNED STRUCTURES FOR FORMING A SEAL WITH THE FACE SKIN AND OTHER SURFACES AND METHOD OF MAKE 审中-公开用于形成与皮肤和其他表面及其制造方法密封的微结构公开(公告)号:US20150329743A1
公开(公告)日:2015-11-19
申请号:US14275966
申请日:2014-05-13
IPC分类号: C09J7/00
CPC分类号: C09J7/00 , C09J2201/626 , C09J2400/22 , Y10T428/2481
摘要: The present invention is directed towards an article suitable for attachment to facial skin or other surfaces, which comprises microfibrils and continuous microribbons. The article provides good sealing when used on a regular skin, and on a challenge skin surface with facial hair, sweat and acnes. The article also provides good adhesion and sealing on any other rough surfaces, and can be used repeatedly against different surfaces. These dry adhesives can be used for improving sealing of mask respirators, swimming goggles, or for other applications such as medical bandage, working gloves, and protective clothing seal.
摘要翻译: 本发明涉及适于附着于面部皮肤或其它表面的制品,其包括微纤丝和连续微型胶带。 该物品在常规皮肤上使用时具有良好的密封性,并且在面部毛发,汗水和痤疮的挑战皮肤表面上提供良好的密封性。 该物品还可以在任何其他粗糙表面上提供良好的粘附和密封,并且可以反复用于不同的表面。 这些干燥粘合剂可用于改进面罩呼吸器,游泳镜或其他应用如医用绷带,工作手套和防护服密封件的密封。
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7.发明授权Ultra high performance concrete reinforced with low-cost graphite nanomaterials and microfibers, and method for production thereof 有权用低成本石墨纳米材料和微纤维增强的超高性能混凝土及其生产方法公开(公告)号:US08951343B2
公开(公告)日:2015-02-10
申请号:US13600358
申请日:2012-08-31
IPC分类号: C04B28/04
CPC分类号: C04B28/02 , B82Y30/00 , C08G10/04 , C08G73/0206 , C08L61/18 , C08L61/32 , C08L79/02 , C08L2205/16 , Y02W30/92 , Y02W30/94 , Y02W30/97 , C04B14/024 , C04B14/22 , C04B14/383 , C04B14/386 , C04B14/42 , C04B14/48 , C04B16/0633 , C04B16/0641 , C04B16/0691 , C04B18/08 , C04B18/101 , C04B18/141 , C04B18/146 , C04B18/24 , C04B22/008 , C04B24/26 , C04B24/2641 , C04B2103/12 , C04B2103/22 , C04B2103/302 , C04B2103/304 , C04B2103/32 , C04B2103/408 , C04B2103/54 , C04B2103/58 , C04B2103/65
摘要: Ultra-high-performance cementitious materials are made using suitably functionalized and relatively low-cost carbon nanofibers and graphite platelets. Polyelectrolytes and surfactants are physisorbed upon these graphite nanomaterials in water, and dispersion of nanomaterials in water is achieved by stirring. Stable and well-dispersed suspensions of nanomaterials in water are realized without using energy-intensive and costly methods, and also without the use of materials which could hinder the hydration and strength development of ultra-high-performance cementitious materials. The water incorporating dispersed nanomaterials is then mixed with the cementitious matrix and, optionally, microfibers, and cured following standard concrete mixing and curing practices. The resulting cementitious materials incorporating graphite nanomaterials and optionally microfibers offer a desired balance of strength, toughness, abrasion resistance, moisture barrier attributes, durability and fire resistance.
摘要翻译: 使用适当功能化且相对低成本的碳纳米纤维和石墨血小板制造超高性能水泥质材料。 聚电解质和表面活性剂在这些石墨纳米材料在水中被物理吸附,纳米材料在水中的分散是通过搅拌实现的。 实现了纳米材料在水中的稳定和良好分散的悬浮液,而不使用能量密集和昂贵的方法,并且也不使用可能阻碍超高性能水泥质材料的水合和强度发展的材料。 然后将掺入分散的纳米材料的水与水泥基质和任选的微纤维混合,并按照标准混凝土搅拌和固化实践进行固化。 所产生的石墨纳米材料和任选的微纤维的水泥质材料提供了所需的强度,韧性,耐磨性,防潮性,耐久性和耐火性的平衡。
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公开(公告)号:US20190315654A1
公开(公告)日:2019-10-17
申请号:US15237510
申请日:2016-08-15
申请人: Metna Co
IPC分类号: C04B14/02 , C04B40/00 , C04B28/10 , C04B14/48 , C04B16/06 , C04B14/42 , C04B14/38 , B28C5/40 , B28B1/14 , B28B11/24
摘要: The present invention relates generally to beneficiation of inorganic matrices via addition of nano-materials without altering the production conditions of the inorganic matrix, and more specifically it relates to enhancement of concrete with wet graphite nanoplatelets using conventional concrete production equipment and procedures without any need for extra measures such as sonication, use of surfactants or functionalization of nanomaterials for dispersion of nanoplatelets.
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9.发明申请Joining via Slender Nanomaterials: Materials, Procedures and Applications Thereof 审中-公开通过细长的纳米材料连接:材料,程序和应用公开(公告)号:US20160059534A1
公开(公告)日:2016-03-03
申请号:US13534196
申请日:2012-06-27
CPC分类号: B29C66/71 , B29C65/1425 , B29C65/1435 , B29C65/148 , B29C65/3412 , B29C65/3416 , B29C65/3492 , B29C65/8207 , B29C65/8215 , B29C65/8253 , B29C65/8261 , B29C66/1122 , B29C66/3024 , B29C66/30341 , B29C66/45 , B29C66/721 , B29C66/7212 , B29C66/72141 , B29C66/72143 , B29C66/73921 , B29C66/8122 , B29C66/929 , B29C66/949 , B29K2105/167 , B29K2909/02 , B29K2823/12 , B29K2067/003 , B29K2023/12 , B29K2077/00 , B29K2071/00 , B29K2081/06 , B29K2069/00 , B29K2309/08 , B29K2309/14 , B29K2311/10 , B29K2223/06 , B29K2277/00
摘要: A method of joining two articles using slender nanomaterials is described. Randomly oriented nanomaterial mats or aligned nanomaterial arrays are introduced at the interface between the two articles followed by their energization via at least one of microwave irradiation and heating. The nanomaterial-to-nanomaterial and nanomaterial-to-surface contacts are enhanced by at least one of fusion, embedment and chemical reaction phenomena upon energization. The fusion, embedment and chemical reaction phenomena enhance at least one of the mechanical, electrical, thermal, durability and functional attributes of these contact points, which translate into improved properties of the joined article. The enhanced contact points enable effective use of the distinct qualities of nanomaterials towards development of joints which offer unique balances of strength, ductility, toughness, transport qualities, thermal stability, weathering resistance and other characteristics.
摘要翻译: 描述了使用细长纳米材料接合两个制品的方法。 在两个物品之间的界面处引入随机取向的纳米材料垫或对准的纳米材料阵列,随后通过微波照射和加热中的至少一个进行通电。 在通电时,通过融合,嵌入和化学反应现象中的至少一种来增强纳米材料与纳米材料与纳米材料之间的接触。 融合,嵌入和化学反应现象增强了这些接触点的机械,电气,热,耐久性和功能属性中的至少一个,这转化为改进的接合制品的性质。 增强的接触点能够有效地利用纳米材料的不同特性来发展接头,提供强度,延展性,韧性,运输质量,热稳定性,耐候性和其他特性的独特平衡。
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公开(公告)号:US20150217535A1
公开(公告)日:2015-08-06
申请号:US13592767
申请日:2012-08-23
CPC分类号: E04C5/085 , Y10T428/24628 , Y10T428/24744 , Y10T428/249921
摘要: A structurally efficient rod-stiffened panel incorporating pretressing benefits is provided, the prestress provided by pultruded rod which is already in the system. The pultruded rods being retained in either tension or compression stresses apply prestressing via interfacial behavior. The new system improves the efficiency of structural composites by tailoring the stress system within structure to fully utilize the structural potential of various components, and to avoid premature local failures within composite structures. A method for producing a prestressed rod stiffened composite structure is also provided.
摘要翻译: 提供了具有预应力优点的结构有效的杆加强板,由已经在系统中的拉挤杆提供的预应力。 拉挤杆被保持在拉伸或压缩应力中,通过界面行为施加预应力。 新系统通过调整结构内的应力系统来提高结构复合材料的效率,充分利用各种构件的结构潜力,避免复合结构内的过早局部失效。 还提供了一种用于生产预应力棒加强复合结构的方法。
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