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    • 2. 发明申请
    • Magnetic recording medium
    • 磁记录介质
    • US20040253483A1
    • 2004-12-16
    • US10863714
    • 2004-06-08
    • Sony Corporation
    • Akiko WatanabeKatsunori MaeshimaTomoo FukudaNoboru Sekiguchi
    • B32B005/16
    • G11B5/714G11B5/70
    • The coating-type magnetic recording medium has a non-magnetic layer mainly composed of a non-magnetic powder and binder, and a magnetic layer mainly composed of a ferromagnetic powder and a binder, which are stacked in this order on a non-magnetic substrate, wherein dispersion nullL/L of long-axis length of all ferromagnetic powder particles contained in the magnetic layer falls in a range of nullL/Lnullnull10%, where L is an average long-axis length and nullL is a standard deviation thereof, and dispersion nullW/W of short-axis length of all ferromagnetic powders contained in the magnetic layer falls in a range of nullW/Wnullnull15%, where W is an average short-axis length and nullW is a standard deviation thereof. The average long-axis length L is typically adjusted within the range of 0.08 nullm and 0.12 nullm, and the Switching Field Distribution (SFD) of the medium is adjusted to 0.25 or less.
    • 涂布型磁记录介质具有主要由非磁性粉末和粘合剂组成的非磁性层和主要由铁磁性粉末和粘合剂组成的磁性层,它们依次层叠在非磁性基板上 其中,包含在磁性层中的所有铁磁性粉末颗粒的长轴长度的分散SigmaL / L落在sLL /L≤±10%的范围内,其中L是平均长轴长度,sigmaL是标准偏差 并且包含在磁性层中的所有铁磁粉末的短轴长度的色散σW / W落在σW/ W <=±15%的范围内,其中W是平均短轴长度,sigmaW是标准偏差 其中。 平均长轴长度L通常在0.08μm和0.12μm的范围内调节,并且将介质的开关场分布(SFD)调节至0.25或更小。
    • 4. 发明申请
    • Magnetic recording medium
    • 磁记录介质
    • US20040247859A1
    • 2004-12-09
    • US10489735
    • 2004-03-16
    • Yuji Sasakimikio KishimotoNaoki Usuki
    • B32B005/16
    • H01F10/126G11B5/70G11B5/70615G11B5/714H01F10/142
    • A magnetic recording medium comprising a nonmagnetic support and a magnetic layer formed on the support and containing a magnetic powder and a binder, wherein said magnetic powder comprises substantially spherical or ellipsoidal particles and at least one element selected from the group consisting of rare earth elements, silicon and aluminum, and has a Fe16N2 phase, an average particle size of 5 to 30 nm and an axis ratio (a ratio of a major axis to a minor axis) of 1 to 2. This magnetic recording medium achieves a high output and has excellent short wavelength recording properties, since it uses a magnetic powder having a very small particle size and has a very high coercive force and a saturation magnetization suitable for high density recording.
    • 一种磁记录介质,包括形成在所述载体上并含有磁性粉末和粘合剂的非磁性载体和磁性层,其中所述磁性粉末包含基本上球形或椭圆形的颗粒和至少一种选自稀土元素, 硅和铝,并且具有Fe-160N2相,平均粒度为5〜30nm,轴比(长轴与短轴的比)为1〜2。该磁记录介质实现了高输出,具有 优异的短波长记录性能,因为它使用具有非常小的粒径的磁粉,并且具有非常高的矫顽力和适用于高密度记录的饱和磁化强度。
    • 6. 发明申请
    • Magnetic materials, metallic particles and method of making same
    • 磁性材料,金属颗粒及其制造方法
    • US20040234767A1
    • 2004-11-25
    • US10363996
    • 2004-06-23
    • Johna LeddyShelly D MinteerWayne L. Gellett
    • B32B005/16
    • B22F1/0062B03C1/01B22F1/02B22F2001/0066B22F2998/00H01F1/0027H01F1/0552H01F1/0572H01F1/112H01F1/20H01F1/36H01F41/16H01M4/8647H01M4/8817H01M4/9041Y10T428/2991Y10T428/2993
    • New magnetic materials and new metallic particles, new methods of making and using same, for example, to prepare magnetically modified electrodes and fuel cells, and coated metallic particles in general. The present invention discloses methods of preparation of cheaper and more uniformly sized magnetic and metallic microparticles formed from the exemplary materials magnetite, nickel, samarium cobalt and neodymium iron boron. In addition, the present invention discloses methodology for preparation and use of coated magnetic and metallic microparticles, in particular, exemplary siloxyl coating of magnetic particles, metallic particles, and magnetic and metallic microparticles with an exemplary silane, 3-aminopropyltrimethoxysilane, that is cross linked thereon. In addition, methods and results are described for preparing and using larger siloxyl coated samarium cobalt milliparticles. Coated magnetic milliparticles and magnetic microparticles are useful as component of composites that are applied to electrodes to alter electrochemical fluxes across those electrodes, as well as to alter chemical reactions on surfaces of those electrodes, when magnetically susceptible reactions occur there.
    • 新的磁性材料和新的金属颗粒,新的制造和使用它们的方法,例如制备磁性改性的电极和燃料电池,以及一般涂覆的金属颗粒。 本发明公开了制备由示例性材料磁铁矿,镍,钐钴和钕铁硼形成的更便宜和更均匀尺寸的磁性和金属微粒的方法。 此外,本发明公开了用于制备和使用涂覆的磁性和金属微粒的方法,特别是具有示例性硅烷,3-氨基丙基三甲氧基硅烷的磁性颗粒,金属颗粒和磁性和金属微粒的示例性硅氧烷涂层,其是交联的 上。 此外,描述了制备和使用较大的含有硅氧烷的涂覆的钐钴微粒的方法和结果。 涂覆的磁性微粒和磁性微粒可用作复合材料的组分,其用于电极以改变跨过这些电极的电化学通量,并且当磁性敏感反应发生在那里时,改变这些电极的表面上的化学反应。
    • 7. 发明申请
    • Solid-state hydrogen storage systems
    • 固态储氢系统
    • US20040213998A1
    • 2004-10-28
    • US10851313
    • 2004-05-21
    • Andrew K. HearleyScott D. Redmond
    • B32B005/16
    • B82Y30/00B22F1/0018B22F9/082B22F2998/00B22F2999/00C01B3/0078C01P2004/64Y02E60/327Y10S420/90Y10T428/2982Y10T428/2991B22F3/1208B22F2202/13
    • Improved hydrogen storage materials are disclosed. A first material comprises a hydrogen storage nanomaterial that contains nanoparticles or nanoparticle clusters of a metal that is capable of combining with hydrogen to form a metal hydride. The nanomaterials may be formed using a thermal spray process. A second material comprises a micro-sized support that contains a hydrogen storage material deposited thereon. The hydrogen storage material may comprise a thermal spray deposit formed on a fly ash particle. A third material comprises a hydrogen permeable container having a hydrogen storage material therein. The container may comprise a microparticle having an internal void (e.g., a fly ash cenosphere or glass microsphere) containing a hydrogen storage material that has been permeated therein. Alternatively, the container may comprise an enclosing layer formed over a hydrogen storage material. The enclosing layer may be a deposited protective layer formed over a particle of a hydrogen storage material
    • 公开了改进的储氢材料。 第一种材料包括含有可与氢结合以形成金属氢化物的金属的纳米颗粒或纳米颗粒簇的储氢纳米材料。 纳米材料可以使用热喷涂方法形成。 第二种材料包括含有沉积在其上的储氢材料的微尺寸载体。 储氢材料可以包括形成在飞灰颗粒上的热喷涂沉积物。 第三种材料包括其中具有储氢材料的氢渗透性容器。 容器可以包括具有内部空隙(例如,飞灰碳粉或玻璃微球)的微粒,其含有已经渗透在其中的储氢材料。 或者,容器可以包括形成在储氢材料上的封闭层。 封闭层可以是在储氢材料的颗粒上形成的沉积保护层
    • 8. 发明申请
    • Method of manufacturing composite board
    • 制造复合板的方法
    • US20040202857A1
    • 2004-10-14
    • US10410979
    • 2003-04-09
    • Larry Singer
    • B32B005/16
    • B27N3/00B27N3/002B27N3/007B27N3/28B29C70/58B29K2711/14B32B27/04B32B27/06Y10T428/253Y10T428/31989
    • A composite board is made from waste medium density fiber (MDF) board or waste particle board that includes solid urea formaldehyde. The waste board is chopped and milled into particles having a size between 20 mesh and 150 mesh, creating a waste flour. After removing moisture from the waste flour, the dried waste flour is mixed with a thermoplastic to bind and encapsulate the waste flour. Internal lubricants are added to improve the flow characteristics of the blended material, and external lubricants are added to present sticking of the mixture to an extruder or mold. Mineral fillers are added to improve the flexural modules of the composite board, and a plasticizer can be added to improve the physical properties or mechanical characteristics of the mixture. An ultraviolet absorber, a biocide, and a pigment can also be added. The blended material is extruded or molded into a desired shape. When cooled, the thermoplastic hardens to form a solid composite board.
    • 复合板由废中密度纤维(MDF)板或包含固体脲甲醛的废料板制成。 将废板切碎并研磨成尺寸在20目至150目之间的颗粒,形成废粉。 在从废粉中除去水分后,将干燥的废粉与热塑性混合物结合并包封废粉。 添加内部润滑剂以改善混合材料的流动特性,并加入外部润滑剂以使混合物粘附到挤出机或模具上。 添加矿物填​​料以改善复合板的弯曲模块,并且可以加入增塑剂以改善混合物的物理性能或机械特性。 还可以加入紫外线吸收剂,杀生物剂和颜料。 将混合的材料挤出或模制成所需的形状。 当冷却时,热塑性硬化以形成固体复合板。