公开(公告)号：US09376601B2

公开(公告)日：2016-06-28

申请号：US13395783

申请日：2010-09-03

Applicant: Yoshitomo Ono ,  Tadahiro Tominou ,  Yumiko Amino ,  Shigeyuki Yaguchi

Inventor： Yoshitomo Ono ,  Tadahiro Tominou ,  Yumiko Amino ,  Shigeyuki Yaguchi

IPC: C09J11/04 ,  C09J9/00 ,  C09J167/00 ,  H01F1/34 ,  H01F1/37 ,  C08K3/22

CPC classification number: C09J11/04 ,  C08K3/22 ,  C08K2003/2265 ,  C08K2201/01 ,  C09J9/00 ,  C09J167/00 ,  C09J2201/61 ,  C09J2201/622 ,  C09J2205/102 ,  C09J2400/10 ,  H01F1/344 ,  H01F1/37 ,  Y10T156/10 ,  Y10T428/2857

Abstract: An adhesive composition for slide rail exhibits excellent workability in attaching a slide rail to a vehicle body and has a strong adhesive force after heating, the magnetic flux density of which can be lowered, which sustains the strong adhesive force after heating and then returning to room temperature so as to allow the firm fixation of the slide rail to the vehicle body, and which can lower the volume of the noise caused by opening/closing of a door. Specifically disclosed is an adhesive composition for slide rail which includes a hot-melt adhesive and a ferromagnetic substance, wherein the composition shows a density at 20° C. of 1.4-4.5 g/cm3 and has such magnetic properties that the magnetic flux density of an adhesive sheet, that is obtained by molding the composition, at a position 1 cm apart from the surface of the adhesive sheet is 10 mT or more.

Abstract translation: 用于滑轨的粘合剂组合物在将滑轨安装到车体上具有优异的可加工性，并且在加热之后具有强的粘合力，其磁通密度可以降低，其在加热之后维持强的粘合力然后返回到室 温度，以便滑轨牢固地固定在车身上，并且能够降低门的打开/关闭引起的噪音的体积。 具体公开了一种用于滑轨的粘合剂组合物，其包括热熔粘合剂和铁磁性物质，其中所述组合物在20℃下的密度为1.4-4.5g / cm 3，并且具有这样的磁特性，即磁性密度 通过模塑该组合物在距粘合片表面1cm的位置处获得的粘合片为10mT以上。

公开(公告)号：US20150357099A1

公开(公告)日：2015-12-10

申请号：US14377276

申请日：2013-02-11

Applicant: Cellutech AB

Inventor： Sylvain GALLAND ,  Richard T. OLSSON ,  Lars BERGLUND

IPC: H01F1/01 ,  D06M11/36 ,  D06M11/49 ,  D06M11/83

CPC classification number: H01F1/01 ,  B82Y25/00 ,  C01G49/0018 ,  C01G49/0072 ,  C01G49/02 ,  C01P2004/64 ,  C01P2006/42 ,  C08K3/22 ,  C08K2201/01 ,  C08L2205/16 ,  D06M11/36 ,  D06M11/49 ,  D06M11/83 ,  D06M2101/06 ,  D21C9/001 ,  D21H11/16 ,  D21H17/67 ,  H01F1/0045 ,  H01F1/0063 ,  Y10T428/2927 ,  Y10T428/2958 ,  C08L1/02

Abstract: The present invention relates to cellulose nanofibrils decorated with magnetic nanoparticles as well as a method for the preparation thereof and a material comprising the nanofibrils.

Abstract translation: 本发明涉及用磁性纳米颗粒装饰的纤维素纳米纤丝及其制备方法和包含纳米原纤维的材料。

公开(公告)号：US09074053B2

公开(公告)日：2015-07-07

申请号：US14215803

申请日：2014-03-17

Applicant: Mackinac Polymers LLC

Inventor： Ralph Locke ,  Michael Kerman ,  Melissa Arredondo ,  William Cowell

IPC: C08F283/00 ,  C08G75/14 ,  C09D5/23 ,  C08G18/83 ,  C08G63/91

CPC classification number: C08G75/14 ,  C08G18/4202 ,  C08G18/7671 ,  C08G18/838 ,  C08G63/91 ,  C08K3/042 ,  C08K3/22 ,  C08K2003/2272 ,  C08K2003/2275 ,  C08K2201/01 ,  C08K2201/011 ,  C09D5/23 ,  H01F1/0063 ,  C08L75/06

Abstract: A polymeric composition that includes at least one polymer and an effective amount of a nanoparticulate component. The nanoparticulate component is at least one of inorganic functional nanoparticulate compounds and graphene in which the nanoparticulate component is associated with the polymer. The polymer disclosed herein can have electromagnetic activity. The resulting polymeric composition exhibit a measurable electrical conductivity (σ) range of 10−14 to 4.7*106 (S/m) at 20° C. A polymeric precursor that includes at least one component selected from the group that includes isocyanates, polyisocyanates, MDI-terminated prepolymers and an effective amount of a nanoparticulate component. The nanoparticulate component is at least one of inorganic functional nanoparticulate component being at least one of inorganic functional nanoparticulate compounds and graphene that is associated with the prepolymer.

Abstract translation: 包含至少一种聚合物和有效量的纳米颗粒组分的聚合物组合物。 纳米颗粒组分是无机功能纳米颗粒化合物和石墨烯中的至少一种，其中纳米颗粒组分与聚合物缔合。 本文公开的聚合物可具有电磁活性。 所得的聚合物组合物在20℃下表现出10-14至4.7×10 6（S / m）的可测量的电导率（＆sgr）范围。包含至少一种选自包括异氰酸酯，多异氰酸酯 ，MDI封端的预聚物和有效量的纳米颗粒组分。 纳米颗粒组分是无机功能纳米颗粒组分中的至少一种，其是与预聚物相关的无机功能性纳米颗粒化合物和石墨烯中的至少一种。

公开(公告)号：US09050362B2

公开(公告)日：2015-06-09

申请号：US13848917

申请日：2013-03-22

Applicant: Kaohsiung Medical University

Inventor： Li-Fang Wang ,  Shuo-Li Sun ,  Yu-Lun Lo

IPC: A61K9/50 ,  A61K48/00 ,  B82Y5/00 ,  C08K9/04 ,  C08K9/08 ,  B82Y30/00 ,  C12N15/85

CPC classification number: A61K48/0025 ,  A61K48/0033 ,  A61K48/0041 ,  B82Y5/00 ,  B82Y30/00 ,  C08K9/04 ,  C08K9/08 ,  C08K2201/005 ,  C08K2201/01 ,  C08K2201/013 ,  C12N15/85

Abstract: Disclosed are the nanoparticle and the method for the same, and the preparing method includes steps of mixing polyethylenimine (PEI) with the poly(acrylic acid)-bound iron oxide (PAAIO) to form a PEI-PAAIO polyelectrolyte complex (PEC) and mixing the PEI-PAAIO PEC with genetic material such as plasmid DNA to form the PEI-PAAIO/pDNA magnetic nanoparticle. The PEI-PAAIO/pDNA magnetoplex is highly water dispersible and suitable for long term storage, shows superparamagnetism, low cytotoxicity, high stability and nice transfection efficiency, and thus the PEI-PAAIO PEC can replace PEI as a non-viral gene vector.

Abstract translation: 公开了纳米颗粒及其制备方法，其制备方法包括将聚乙烯亚胺（PEI）与聚（丙烯酸）键合的氧化铁（PAAIO）混合以形成PEI-PAAIO聚电解质络合物（PEC）和混合 PEI-PAAIO PEC与遗传物质如质粒DNA形成PEI-PAAIO / pDNA磁性纳米颗粒。 PEI-PAAIO / pDNA磁复合物具有高水分散性，适合长期保存，显示出超顺磁性，低细胞毒性，高稳定性和良好的转染效率，因此PEI-PAAIO PEC可代替PEI作为非病毒基因载体。

公开(公告)号：US20140316073A1

公开(公告)日：2014-10-23

申请号：US14215803

申请日：2014-03-17

Applicant: Mackinac Polymers LLC

Inventor： Ralph Locke ,  Michael Kerman ,  Melissa Arredondo ,  William Cowell

IPC: C08G75/14 ,  C08G63/91 ,  C08G18/83

CPC classification number: C08G75/14 ,  C08G18/4202 ,  C08G18/7671 ,  C08G18/838 ,  C08G63/91 ,  C08K3/042 ,  C08K3/22 ,  C08K2003/2272 ,  C08K2003/2275 ,  C08K2201/01 ,  C08K2201/011 ,  C09D5/23 ,  H01F1/0063 ,  C08L75/06

Abstract: A polymeric composition that includes at least one polymer and an effective amount of a nanoparticulate component. The nanoparticulate component is at least one of inorganic functional nanoparticulate compounds and graphene in which the nanoparticulate component is associated with the polymer. The polymer disclosed herein can have electromagnetic activity. The resulting polymeric composition exhibit a measurable electrical conductivity (σ) range of 10−14 to 4.7*106 (S/m) at 20° C. A polymeric precursor that includes at least one component selected from the group that includes isocyanates, polyisocyanates, MDI-terminated prepolymers and an effective amount of a nanoparticulate component. The nanoparticulate component is at least one of inorganic functional nanoparticulate component being at least one of inorganic functional nanoparticulate compounds and graphene that is associated with the prepolymer.

Abstract translation: 包含至少一种聚合物和有效量的纳米颗粒组分的聚合物组合物。 纳米颗粒组分是无机功能纳米颗粒化合物和石墨烯中的至少一种，其中纳米颗粒组分与聚合物缔合。 本文公开的聚合物可具有电磁活性。 所得的聚合物组合物在20℃下表现出10-14至4.7×10 6（S / m）的可测量的电导率（＆sgr）范围。包含至少一种选自包括异氰酸酯，多异氰酸酯 ，MDI封端的预聚物和有效量的纳米颗粒组分。 纳米颗粒组分是无机功能纳米颗粒组分中的至少一种，其是与预聚物相关的无机功能性纳米颗粒化合物和石墨烯中的至少一种。

公开(公告)号：US20140305874A1

公开(公告)日：2014-10-16

申请号：US14152800

申请日：2014-01-10

Applicant: Advantageous Systems, LLC

Inventor： Adam L. Stein

IPC: B03C1/00

CPC classification number: B03C1/00 ,  B01J20/28007 ,  B01J20/28009 ,  B01J20/3204 ,  B01J20/321 ,  B01J20/3212 ,  B01J20/3238 ,  B01J20/324 ,  B01J20/345 ,  B01J20/3475 ,  B03C1/01 ,  B03C1/015 ,  B03C1/288 ,  B03C2201/18 ,  B03C2201/26 ,  B82Y30/00 ,  C02F1/265 ,  C02F1/488 ,  C02F1/683 ,  C02F2101/12 ,  C02F2103/08 ,  C02F2303/04 ,  C02F2305/08 ,  C08K3/22 ,  C08K5/1545 ,  C08K2201/01 ,  C08K2201/011 ,  H01F1/0054 ,  Y02W10/37 ,  C08L5/02

Abstract: Disclosed are magnetic nanoparticles and methods of using magnetic nanoparticles for selectively removing biologics, small molecules, analytes, ions, or other molecules of interest from liquids.

Abstract translation: 公开了磁性纳米颗粒和使用磁性纳米颗粒从液体中选择性除去生物物质，小分子，分析物，离子或其它分子的磁性纳米颗粒和方法。

公开(公告)号：US08765183B2

公开(公告)日：2014-07-01

申请号：US12993047

申请日：2009-05-15

Applicant: Brian Stanley Hawkett ,  Nirmesh Jain

Inventor： Brian Stanley Hawkett ,  Nirmesh Jain

IPC: A61K9/14

CPC classification number: A61K9/0009 ,  A61K9/0019 ,  A61K9/1611 ,  A61K9/1635 ,  A61K41/0052 ,  A61K51/1213 ,  C08F2/32 ,  C08F2/38 ,  C08F2/44 ,  C08F4/00 ,  C08F220/56 ,  C08K2201/01

Abstract: The present invention relates to polymer microgel beads having a polymeric matrix with nanomagnetic particles dispersed substantially uniformly therethrough, wherein a steric stabiliser is associated with the particles, the steric stabiliser being a polymeric material that (i) does not form part of the polymeric matrix of the beads, and (ii) comprises a steric stabilising polymeric segment and an anchoring polymeric segment, wherein the steric stabilising polymeric segment is different from the anchoring polymeric segment, and wherein the anchoring polymeric segment has an affinity toward the surface of the nanomagnetic particles and secures the stabiliser to the particles.

Abstract translation: 本发明涉及具有基本均匀地分散有纳米磁性颗粒的聚合物基质的聚合物微凝胶珠粒，其中空间稳定剂与颗粒缔合，空间稳定剂是聚合物材料，（i）不形成聚合物基质的一部分 所述珠粒和（ii）包含空间稳定聚合物链段和锚定聚合物链段，其中所述空间稳定聚合物链段不同于所述锚定聚合物链段，并且其中所述锚定聚合物链段对所述纳米磁性颗粒的表面具有亲和性， 将稳定剂固定在颗粒上。

公开(公告)号：US08728830B2

公开(公告)日：2014-05-20

申请号：US13494797

申请日：2012-06-12

Applicant: Kazumasa Nishimura

Inventor： Kazumasa Nishimura

IPC: H01L21/00

CPC classification number: H01L43/12 ,  B82Y10/00 ,  B82Y25/00 ,  C08K2201/01 ,  G01R33/093 ,  G01R33/098 ,  G11B5/3906 ,  G11B5/3909

Abstract: The present invention provides a manufacturing method of a magneto-resistive element capable of obtaining a higher MR ratio, in a method of forming a metal oxide layer (e.g., MgO layer) by oxidation treatment of a metal layer (e.g., Mg layer). An embodiment of the present invention includes the steps of; providing a substrate having a first ferromagnetic layer; fabricating a tunnel barrier layer on the first ferromagnetic layer; and forming a second ferromagnetic layer on the tunnel barrier layer. The step of fabricating the tunnel barrier layer includes; the steps of; depositing a first metal layer on the first ferromagnetic layer; oxidizing the first metal layer; depositing a second metal layer on the oxidized first metal layer; and performing heating treatment on the oxidized first metal layer and the second metal layer at a temperature at which the second metal layer boils.

Abstract translation: 本发明提供了在通过金属层（例如Mg层）的氧化处理形成金属氧化物层（例如，MgO层）的方法中能够获得较高MR比的磁阻元件的制造方法。 本发明的实施例包括以下步骤： 提供具有第一铁磁层的衬底; 在所述第一铁磁层上制造隧道势垒层; 以及在隧道势垒层上形成第二铁磁层。 制造隧道势垒层的步骤包括： 的步骤; 在第一铁磁层上沉积第一金属层; 氧化第一金属层; 在氧化的第一金属层上沉积第二金属层; 并且在第二金属层沸腾的温度下对氧化的第一金属层和第二金属层进行加热处理。

公开(公告)号：US20140117290A1

公开(公告)日：2014-05-01

申请号：US14125312

申请日：2012-06-08

Applicant: Yong Kok Chong

Inventor： Yong Kok Chong

IPC: C08L7/00

CPC classification number: C08J3/247 ,  C08J2315/00 ,  C08K3/04 ,  C08K2201/001 ,  C08K2201/01 ,  C08L7/00 ,  C08L2310/00 ,  H01B1/04 ,  C08L15/00

Abstract: Epoxidised natural rubber [ENR] based vulcanised-blends with two different types of electrical conductive filler (i.e. conductive grade-carbon black and intrinsically electrical conductive polymer) may be produced respectively by using either internal mechanical mixing method or open milling method or the combination of the two methods. All these ENR based vulcanised-blends show high consistent reversible electrical behaviour under the tensile straining process. They also exhibit useful mechanical property ties with tensile strengths up to 28.0 MPa, elongations at break up to 800.0% and Dunlop rebound resiliencies up to 55.0%. The lower the rebound resilience, the better the damping property and shock absorption ability for the ENR based vulcanised-blends. As a result, these ENR based vulcanised-blends are ideal to be used for manufacturing flexible sensors that may correspond to the tensile straining process.

Abstract translation: 可以通过使用内部机械混合法或开放式研磨法或两种不同类型的导电填料（即导电级 - 炭黑和本体导电聚合物）的环氧化天然橡胶[ENR]基硫化 - 共混物 两种方法。 所有这些基于ENR的硫化共混物在拉伸应变过程下显示出高度一致的可逆电性能。 它们还显示出有效的机械性能关系，拉伸强度高达28.0MPa，伸长率分解达到800.0％，Dunlop回弹韧性高达55.0％。 回弹性越低，ENR型硫化混合物的阻尼性能和冲击吸收能力越好。 因此，这些基于ENR的硫化共混物非常适用于制造可对应于拉伸应变过程的柔性传感器。

公开(公告)号：US08598868B2

公开(公告)日：2013-12-03

申请号：US12305246

申请日：2007-05-30

Applicant: Tomonobu Abe ,  Shigeru Tsuchiya ,  Shigeru Hayashida

Inventor： Tomonobu Abe ,  Shigeru Tsuchiya ,  Shigeru Hayashida

IPC: G01R33/00 ,  G01N27/82

CPC classification number: C09K3/1009 ,  C08K2201/01

Abstract: A gasket according to the present invention is for sealing a valve or pipe used in a high-pressure gas supplying equipment, which is comprised of a polymer material containing magnetic particles. Also, in a determination method of deterioration and damages of a gasket according to the present invention, the aforementioned gasket is used as the gasket for sealing a valve or pipe in a high-pressure gas supplying equipment, and the magnetic force of the gasket is measured to determine the deterioration and the damages of the gasket.

Abstract translation: 根据本发明的垫圈用于密封由含有磁性颗粒的聚合物材料组成的高压气体供应设备中使用的阀或管道。 此外，在根据本发明的垫圈的劣化和损坏的确定方法中，使用上述垫圈作为用于密封高压气体供给设备中的阀或管的垫圈，并且垫圈的磁力为 测量以确定垫圈的劣化和损坏。