Ceramics-coated heat resisting alloy member
    1.
    发明授权
    Ceramics-coated heat resisting alloy member 失效
    陶瓷涂层耐热合金构件

    公开(公告)号:US5209645A

    公开(公告)日:1993-05-11

    申请号:US538759

    申请日:1990-06-15

    IPC分类号: C23C4/02 C23C28/00

    摘要: A gas turbine bucket and a gas turbine nozzle applied with a ceramic coating comprises a base material of the bucket and the nozzle made of a heat resisting alloy; a plurality of coating layers for the front portion consisting of, a mixture layer which comprises a ceramic material and metal and which is formed on the base material, an alloy layer which comprises an alloy material exhibiting excellent resistance to high temperature oxidation and corrosion and which is formed on the mixture layer, and a ceramic layer which comprises ceramic material and formed on the alloy layer. Such ceramic coating has a satisfactory thermal barrier effect on the base material of the gas turbine bucket and nozzle.

    摘要翻译: 应用陶瓷涂层的燃气轮机桶和燃气轮机喷嘴包括铲斗的基材和由耐热合金制成的喷嘴; 用于前部的多个涂层由包含陶瓷材料和金属的复合层组成,并且形成在基材上,合金层包括耐高温氧化和腐蚀性优异的合金材料,并且其中 形成在复合层上,并且在合金层上形成陶瓷层,该陶瓷层包含陶瓷材料。 这种陶瓷涂层对燃气涡轮机桶和喷嘴的基材具有令人满意的隔热效果。

    Co-Cr-Mo Alloy for Artificial Joint Having Excellent Wear Resistance
    4.
    发明申请
    Co-Cr-Mo Alloy for Artificial Joint Having Excellent Wear Resistance 审中-公开
    用于具有优异耐磨性的人造接头的Co-Cr-Mo合金

    公开(公告)号:US20080195214A1

    公开(公告)日:2008-08-14

    申请号:US11909979

    申请日:2005-03-28

    CPC分类号: C22C19/07 A61L27/045

    摘要: In the field of biocompatible Co—Cr—Mo alloys for use in artificial joints or the like, the formation of wear debris in a living body is a matter of concern. The purpose of the invention is to provide a technique for improving the wear resistance of a Co—Cr—Mo alloy for use in an artificial joint to thereby prevent the formation of wear debris in a living body. The improvement in wear resistance of a Co—Cr—Mo alloy for use in an artificial joint can be achieved by finely dividing the crystal particles of the alloy, by preparing an alloy composition having a higher Mo content than any known standard Co—Cr—Mo alloy (e.g., Co-29Cr-6Mo alloy), by increasing the proportion of the σ phase that is dispersedly precipitated, by sintering an alloy powder produced by gas atomization technique to form pores on the surface of the alloy material, or the like. The Co—Cr—Mo alloy having high wear resistance is applicable to medical devices including artificial hip joints, artificial knee joints and the like which have less biotoxicity, namely which are safer and have a longer useful life.

    摘要翻译: 在用于人造关节等的生物相容性Co-Cr-Mo合金领域中,生物体中磨损碎屑的形成是令人担忧的问题。 本发明的目的是提供一种用于改善用于人造接头的Co-Cr-Mo合金的耐磨性从而防止在生物体中形成磨损碎屑的技术。 用于人造接头的Co-Cr-Mo合金的耐磨性的改善可以通过将合金的结晶颗粒细分,通过制备具有比任何已知的标准Co-Cr- Mo合金(例如Co-29Cr-6 Mo合金),通过烧结由气体雾化技术产生的合金粉末,在合金材料的表面上形成孔隙,通过增加分散析出的σ相的比例,或 类似。 具有高耐磨性的Co-Cr-Mo合金可应用于生物毒性小的人造髋关节,人造膝关节等医疗装置,即更安全,使用寿命更长的医疗装置。

    Method of forming fine grains of Co-Cr-Mo alloy with nitrogen addition and Co-Cr-Mo alloy with nitrogen addition
    5.
    发明授权
    Method of forming fine grains of Co-Cr-Mo alloy with nitrogen addition and Co-Cr-Mo alloy with nitrogen addition 有权
    用氮添加和Co-Cr-Mo合金与氮添加形成Co-Cr-Mo合金细晶粒的方法

    公开(公告)号:US08460485B2

    公开(公告)日:2013-06-11

    申请号:US13060593

    申请日:2009-09-02

    IPC分类号: C22F1/10

    摘要: A Co—Cr—Mo alloy with nitrogen addition composed of 26 to 35% by weight of Cr, 2 to 8% by weight of Mo, 0.1 to 0.3% by weight of N, and balance of Co is subjected to solution treatment and then subjected to isothermal aging treatment holding the alloy at 670 to 830° C. for a predetermined period of time to form a multi-phase structure composed of an ε-phase and a Cr nitride by means of an isothermal aging effect. After cooling, the alloy subjected to reverse transformation treatment in which the alloy is heated at a temperature range of 870 to 1100° C. for reverse transformation to a single γ-phase from the multi-phase structure composed of an ε-phase and a Cr nitride.

    摘要翻译: 将由26〜35重量%的Cr,2〜8重量%的Mo,0.1〜0.3重量%的N和余量的Co组成的Co-Cr-Mo合金进行固溶处理,然后 进行等温时效处理,将合金在670〜830℃保持规定时间,通过等温时效作用形成由ε相和Cr氮化物构成的多相结构体。 冷却后,对合金进行逆相变处理,其中将合金在870〜1100℃的温度范围内加热,以便从由ε相和 氮化铬。

    METHOD OF FORMING FINE GRAINS OF CO-CR-MO ALLOY WITH NITROGEN ADDITION AND CO-CR-MO ALLOY WITH NITROGEN ADDITION
    6.
    发明申请
    METHOD OF FORMING FINE GRAINS OF CO-CR-MO ALLOY WITH NITROGEN ADDITION AND CO-CR-MO ALLOY WITH NITROGEN ADDITION 有权
    用硝酸添加剂和CO-CR-MO合金形成具有硝酸添加剂的CO-CR-MO合金微粒的方法

    公开(公告)号:US20110209799A1

    公开(公告)日:2011-09-01

    申请号:US13060593

    申请日:2009-09-02

    IPC分类号: C23C8/24

    摘要: A Co—Cr—Mo alloy with nitrogen addition composed of 26 to 35% by weight of Cr, 2 to 8% by weight of Mo, 0.1 to 0.3% by weight of N, and balance of Co is subjected to solution treatment and then subjected to isothermal aging treatment holding the alloy at 670 to 830° C. for a predetermined period of time to form a multi-phase structure composed of an ε-phase and a Cr nitride by means of an isothermal aging effect. After cooling, the alloy subjected to reverse transformation treatment in which the alloy is heated at a temperature range of 870 to 1100° C. for reverse transformation to a single γ-phase from the multi-phase structure composed of an ε-phase and a Cr nitride.

    摘要翻译: 将由26〜35重量%的Cr,2〜8重量%的Mo,0.1〜0.3重量%的N和余量的Co组成的Co-Cr-Mo合金进行固溶处理,然后 进行等温时效处理,将合金在670〜830℃保持一段时间,通过等温老化作用形成由相等和氮化铬组成的多相结构。 冷却后,将合金进行逆相变处理,其中将合金在870〜1100℃的温度范围内进行加热,以从由相等相组成的多相结构反相转变成单个γ相, 氮化铬。

    NANOCRYSTAL-CONTAINING TITANIUM ALLOY AND PRODUCTION METHOD THEREFOR
    7.
    发明申请
    NANOCRYSTAL-CONTAINING TITANIUM ALLOY AND PRODUCTION METHOD THEREFOR 有权
    含纳米钛合金及其生产方法

    公开(公告)号:US20130284325A1

    公开(公告)日:2013-10-31

    申请号:US13988123

    申请日:2011-11-22

    IPC分类号: C22F1/18 C22C14/00

    CPC分类号: C22F1/183 C22C14/00 C22F1/00

    摘要: An alloy having an α′ martensite which is a processing starting structure is hot worked. The alloy is heated at a temperature increase rate of 50 to 800° C./sec, and strain is given at not less than 0.5 by a processing strain rate of from 0.01 to 10/sec in a case of a temperature range of 700 to 800° C., or by a processing strain rate of 0.1 to 10/sec in a case of a temperature range of 800° C. to 1000° C. By generating equiaxial crystals having average crystal particle diameters of less than 1000 nm through the above processes, a titanium alloy having high strength and high fatigue resistant property can be obtained, in which hardness is less than 400 HV, tensile strength is not less than 1200 MPa, and static strength and dynamic strength are superior.

    摘要翻译: 具有作为加工起始结构的α'马氏体的合金被热加工。 以50〜800℃/秒的升温速度加热合金,在700〜700℃的温度范围内,通过0.01〜10 /秒的加工变形速度,使应变为0.5以上 800℃,或者在800〜1000℃的温度范围内,通过加工应变速度为0.1〜10 /秒。通过生成平均结晶粒径小于1000nm的等轴晶体,通过 可以得到硬度小于400HV,拉伸强度不小于1200MPa,静态强度和动态强度优异的高强度,高耐疲劳性的钛合金。

    Method of Producing Co-Ni-Based Alloy
    9.
    发明申请
    Method of Producing Co-Ni-Based Alloy 审中-公开
    生产Co-Ni基合金的方法

    公开(公告)号:US20160097115A1

    公开(公告)日:2016-04-07

    申请号:US14966817

    申请日:2015-12-11

    摘要: Provided is a Co—Ni-based alloy in which a crystal is easily controlled, a method of controlling a crystal of a Co—Ni-based alloy, a method of producing a Co—Ni-based alloy, and a Co—Ni-based alloy having controlled crystallinity. The Co—Ni-based alloy includes Co, Ni, Cr, and Mo, in which the Co—Ni-based alloy has a crystal texture in which a Goss orientation is a main orientation. The Co—Ni-based alloy preferably has a composition including, in terms of mass ratio: 28 to 42% of Co, 10 to 27% of Cr, 3 to 12% of Mo, 15 to 40% of Ni, 0.1 to 1% of Ti, 1.5% or less of Mn, 0.1 to 26% of Fe, 0.1% or less of C, and an inevitable impurity; and at least one kind selected from the group consisting of 3% or less of Nb, 5% or less of W, 0.5% or less of Al, 0.1% or less of Zr, and 0.01% or less of B.

    摘要翻译: 提供一种易于控制晶体的Co-Ni基合金,控制Co-Ni系合金的结晶的方法,Co-Ni系合金的制造方法以及Co-Ni系合金的制造方法, 具有受控的结晶度。 Co-Ni基合金包括Co,Ni,Cr和Mo,其中Co-Ni基合金具有其中Goss取向为主要取向的晶体结构。 Co-Ni系合金优选具有质量比:Co:28〜42%,Cr:10〜27%,Mo:3〜12%,Ni:15〜40%,Ni:0.1〜1 ,Ti:1.5%以下,Fe:0.1〜26%,C:0.1%以下,不可避免的杂质; 以及选自由3%以下的Nb,5%以下的W,0.5%以下的Al,0.1%以下的Zr和0.01%以下的B组成的组中的至少1种。

    Nanocrystal titanium alloy and production method for same
    10.
    发明授权
    Nanocrystal titanium alloy and production method for same 有权
    纳米晶钛合金及其制作方法相同

    公开(公告)号:US09260773B2

    公开(公告)日:2016-02-16

    申请号:US13496750

    申请日:2010-09-22

    摘要: A titanium alloy has high strength and superior workability and is preferably used for various structural materials for automobiles, etc. The titanium alloy is obtained by the following production method. An alloy having a structure of α′ martensite phase is hot worked at conditions at which dynamic recrystallization occurs. The working is performed at a heating rate of 50 to 800° C./second at a strain rate of 0.01 to 10/second when the temperature is 700 to 800° C. or at a strain rate of 0.1 to 10/second when the temperature is more than 800° C. and less than 1000° C. so as to provide a strain of not less than 0.5. Thus, equiaxed crystals with an average grain size of less than 1000 nm are obtained.

    摘要翻译: 钛合金的强度高,加工性优异,优选用于汽车等的各种结构材料。钛合金通过以下的制造方法得到。 具有α'马氏体相结构的合金在发生动态再结晶的条件下热加工。 当温度为700至800℃时,以0.1至10 /秒的应变速率,以0.1至10 /秒的应变速率,以50至800℃/秒的加热速率进行加工,应变速率为0.01至10 /秒 温度超过800℃且小于1000℃,以提供不小于0.5的应变。 因此,得到平均粒径小于1000nm的等轴晶体。