公开(公告)号：US4168967A

公开(公告)日：1979-09-25

申请号：US928773

申请日：1978-07-27

申请人： Ramamritham Sridhar ,  Warren L. Shellshear ,  Carlos A. Landolt ,  William Kantymir ,  Howard L. Schooley

发明人： Ramamritham Sridhar ,  Warren L. Shellshear ,  Carlos A. Landolt ,  William Kantymir ,  Howard L. Schooley

IPC分类号： B22F9/00 ,  B22F9/08 ,  C22C1/02 ,  C22C1/03 ,  C22C19/00 ,  C22C19/03 ,  C22F1/10 ,  B22D23/08

CPC分类号： C22C1/03 ,  B22F9/08 ,  Y10T428/29

摘要： A granulate consisting of smooth irregularly shaped granules is produced by preparing a molten bath of nickel and/or cobalt containing amounts of carbon and silicon which are correlated so that:8.03 C-4.42 C.sup.2 +7.23 Si>3.6pouring the molten alloy at a temperature 50.degree.-100.degree. C. above its liquidus temperature onto the surface of a pool of water which is agitated and maintained at 30.degree.-60.degree. C.

摘要翻译： 由平滑的不规则形状的颗粒组成的颗粒通过制备相互关联的含有碳和硅的镍和/或钴的熔池而产生，使得：

公开(公告)号：US4157943A

公开(公告)日：1979-06-12

申请号：US924631

申请日：1978-07-14

申请人： Anthony J. Scarpellino, Jr. ,  James McEwen ,  William G. Borner

发明人： Anthony J. Scarpellino, Jr. ,  James McEwen ,  William G. Borner

IPC分类号： C23F13/00 ,  C25B11/04 ,  C25B11/08 ,  C25B11/10 ,  C25C1/08 ,  C25C7/02 ,  H01M4/86 ,  H01M4/90 ,  C25D3/50 ,  C25D5/50

CPC分类号： C25B11/0484 ,  Y10S205/917

摘要： A composite electrode especially suitable for electrowinning processes comprising an electrically conductive substrate having on at least a part of its surface a multilayer coating, said coating comprising:(a) a barrier layer directly on the substrate;(b) a ruthenium dioxide-containing non-electrodeposited surface layer; and(c) between the barrier layer and the surface layer, an intermediate layer consisting of an electroplated ruthenium-iridium deposit, said ruthenium-iridium deposit being at least partially in an oxidized state.

摘要翻译： 一种特别适用于电沉积方法的复合电极，包括导电基底，其表面的至少一部分具有多层涂层，所述涂层包括：

公开(公告)号：US4157315A

公开(公告)日：1979-06-05

申请号：US427243

申请日：1973-12-21

申请人： Harold T. Michels ,  Raymond P. Jackson

发明人： Harold T. Michels ,  Raymond P. Jackson

IPC分类号： B01D53/94 ,  B01D53/86 ,  B01J23/74 ,  B01J23/755 ,  B01J23/86 ,  B01J35/04 ,  B01J37/02 ,  B01J21/08 ,  B01J23/26 ,  B01J23/72

CPC分类号： B01J23/866 ,  B01D53/86 ,  B01J23/755 ,  B01J23/86 ,  B01J35/04 ,  B01J37/0215 ,  B01J37/0225

摘要： A method is provided for preparing a supported catalyst composed of a structural substrate having an adherent, coherent, coating of a catalytic material which comprises applying on the substrate a dispersion comprising a stabilized colloidal silica solution having dispersed therein a fine metal powder which contains at least two of the metals nickel, chromium, and copper as mixtures or alloys or a combination thereof, and firing the coated substrate in a protective atmosphere at an elevated sintering temperature to form an adherent, coherent, coating.

摘要翻译： 提供了一种用于制备由具有粘附，粘附的催化材料涂层的结构基材组成的负载型催化剂的方法，该催化剂材料包括将包含稳定的胶体二氧化硅溶液的分散体施加到其上，所述分散体分散有至少含有金属粉末的细金属粉末 两种金属镍，铬和铜作为混合物或合金或其组合，并且在保护气氛中在升高的烧结温度下焙烧涂覆的基材以形成粘附的，粘合的涂层。

公开(公告)号：US4153453A

公开(公告)日：1979-05-08

申请号：US831471

申请日：1977-09-08

申请人： Anthony C. Hart ,  William R. Wearmouth

发明人： Anthony C. Hart ,  William R. Wearmouth

IPC分类号： C25D5/50 ,  C25D15/02 ,  C25D3/56 ,  C22C19/03 ,  C22C19/05 ,  C22C38/00

CPC分类号： C25D15/02 ,  C25D5/50

摘要： An alloy difficult to produce by conventional electrodeposition techniques is produced by electrodepositing at least one metal selected from the group comprising nickel, up to 50% cobalt, and iron with particles incorporating metal in chemically combined state. The particles contain a reactive element, such as carbon, nitrogen, and boron, and a metallic element, such as chromium, molybdenum, and tungsten. The electrodeposit of the particles in a metal matrix is treated in a reducing atmosphere so that the particles react, releasing at least some of their incorporated metal into the matrix to form the alloy while transferring the reactive element to the reducing atmosphere.This invention relates to a process for the production of an alloy.It is known to codeposit two or more metals on a substrate by electrodeposition either as permanent coatings or as coatings subsequently removed from the substrate, such as electroforms, to form an alloy with or without diffusion heat treatment. However, electrodeposition is subject to electrochemical restrictions which at best limit the alloy composition depositable or make it necessary to use commercially unsatisfactory process conditions and which at worst prevent certain alloys being produced as electroforms or even being produced at all by electrodeposition.For example, while attempts have been made to produce a nickel-chromium alloy electrodeposit by codepositing nickel and chromium metal, it has not proved possible in this way to produce commercially satisfactory nickel-chromium alloy electrodeposits containing useful amounts of chromium in the nickel matrix. Indeed the deposition processes used in these attempts have suffered from defects which have tended to make the processes themselves unsuitable for commercial usage.It is an object of the present invention to provide a process of making an electrodeposit of an alloy which is normally difficult to produce by conventional electrodeposition techniques.Generally speaking, the present invention is a process for producing an alloy comprising: coelectrodepositing a matrix of at least one metal selected from the group consisting of nickel, less than 50% by weight cobalt, and iron, with reactive particles incorporating metal in chemically combined state, said particles are compounds of at least one reactive element selected from the group consisting of carbon, nitrogen, and boron, and of at least one metallic element selected from the group consisting of chromium, molybdenum, and tungsten, thereby providing a composite electrodeposit; and heating said composite electrodeposit to temperatures of from about 1000.degree. C. to about 1400.degree. C. for at least 24 hours in a reducing gas atmosphere to release at least some of said metallic element of said particles from its chemically combined state into said matrix thereby forming said alloy while transferring at least some of said reactive element to said reducing gas atmosphere.While the process of the invention primarily is intended for the production of alloys which are difficult or even impossible to produce by conventional electrodeposition techniques, it is of course equally applicable to the production of alloys which can readily be produced by conventional electrodeposition techniques. Furthermore, the process of the invention can be used for the formation of alloy permanent coatings on a substrate or for the formation of coatings which are subsequently removed from the substrate, such as electroforms. References throughout this specification to "coatings" are to be taken to include electroforms which have been removed from the substrate upon which they were formed.The thermally decomposable reactive particles incorporating metal in chemically combined state may be codeposited in conjunction with particles which do not react under the conditions used to make the reactive particles react. In this way, an alloy may be produced containing particles which constitute, for example, a dispersion hardening dispersoid. The reactive particles incorporating metal in chemically combined state may alternatively or additionally to the foregoing non-reactive particles be codeposited with metal particles and/or with coated metal particles, for example, carbide coated metal particles.Although it has been proposed in the past to electrodeposit coatings made up of particles, incorporating metal in chemically combined state, in a metal matrix to improve the hardness and/or wear resistance of the matrix metal, such proposals have only resulted in the production of a composite coating of particles incorporating metal in chemically combined state in a metal matrix and not an alloy. Alloy production, it is thought, was precluded by the use of: (a) unreactive particles incorporating metal in chemically combined state, or (b) the wrong metal or metals, or (c) the use of process conditions or relative proportions of particles incorporating metal in chemically combined state, and matrix metal, which prevented reaction of the particles. For example, chromium carbide (Cr.sub.3 C.sub.2) and cobalt have been codeposited to form a Co--Cr.sub.3 C.sub.2 composite coating with improved initial hardness values, but have not been used to form an alloy.Preferably the process of the invention is used to codeposit nickel or nickel and up to 50% cobalt with chromium carbide particles to form an electrodeposited nickel-chromium or nickel-cobalt-chromium coating. Advantageously, sufficient chromium carbide particles should be utilized to give at least 13% chromium in the electrodeposited coating. However, when the electrodeposited coating contains both cobalt and chromium carbide particles, less than 50% by weight of the matrix should be cobalt, since more than this amount of cobalt leads to excessively high internal stress which precludes the use of such electrodeposites.The particles incorporating metal in chemically combined state can be reacted by heating in a reducing atmosphere such as hydrogen for at least 24 hours at temperatures of from about 1000.degree. C. to about 1400.degree. C. The degree of reaction of the particles incorporating metal in chemically combined state may be controlled, for example, by variation of the heat treatment temperature and/or time to allow different desired amounts of metal incorporated in the particles to be released. In this way, different properties may be achieved in the electrodeposited coatings. An advantageous heat treatment is to heat in hydrogen at 1000.degree. C. for 24 hours and air cool. It is preferred to transfer at least 50% of the reactive element from the electrodeposit to the reducing gas atmosphere.Deposits prepared according to the invention may be applied electrolytically, using any convenient electroplating solution such as a Watts bath or sulfamate solution which may be used for electroforming. Preferably an aqueous electroplating solution should be used, although a non-aqueous solution may be employed where suitable. Whether aqueous or non-aqueous, the solution used in the process according to the present invention may deteriorate with time, and it is recommended that such solutions be used while fresh and/or frequently discarded and replaced with fresh solutions. When an electroform is being prepared by the process according to the invention, the particles incorporating metal in chemically combined state should be reacted, for example, by heating, preferably after the electroform is stripped from the substrate upon which it was formed.Alloys made according to the invention may be harder or softer in the as-plated condition than an electrodeposited coating of the alloy matrix metal in the as-plated condition, depending upon the particular metal or metals being considered. However, no matter whether the alloy is harder or softer in the as-plated condition than an electrodeposited coating of the matrix metal alone in the as-plated condition, the alloy retains its hardness after or on heating, to a much greater extent than does the coating of the matrix metal alone. Furthermore, such hardness property improvements may be obtained with alloys made according to the invention, without unduly affecting the electroformability of the alloys.

公开(公告)号：US4144102A

公开(公告)日：1979-03-13

申请号：US824810

申请日：1977-08-15

申请人： Darrell F. Smith, Jr. ,  Edward F. Clatworthy ,  Donald E. Wenschhof, Jr.

发明人： Darrell F. Smith, Jr. ,  Edward F. Clatworthy ,  Donald E. Wenschhof, Jr.

IPC分类号： C22C19/05 ,  C22C38/52 ,  C21D7/14 ,  C22C38/06 ,  C22C38/48 ,  C22F1/10

CPC分类号： C22C19/058 ,  C22C38/52

摘要： Nickel-iron and nickel-iron-cobalt alloys contain chromium and gamma-prime hardening elements in proportions balanced according to special compositional relationships providing desired thermal expansion, inflection temperature, strength and ductility characteristics, particularly including notch strength needed in machinery and structures subjected in use to varying temperatures and thermal gradients where operating temperatures become elevated above 500.degree. F.

公开(公告)号：US4133426A

公开(公告)日：1979-01-09

申请号：US880959

申请日：1978-02-24

申请人： Pierre P. Turillon ,  Gary D. Sandrock

发明人： Pierre P. Turillon ,  Gary D. Sandrock

IPC分类号： B65D81/18 ,  C01B3/00 ,  F17C11/00 ,  B65D25/00 ,  C01B1/26 ,  F16L55/04

CPC分类号： F17C11/005 ,  B65D81/18 ,  C01B3/0005 ,  C01B3/0026 ,  C01B3/0063 ,  C01B3/0068 ,  Y02E60/321 ,  Y02E60/327

摘要： A hydrogen-storage vessel having particles of hydrideable alloy in a multiplicity of closed containers permeable to hydrogen within the vessel to prevent localized pressure effects acting against the walls of the vessel.

摘要翻译： 一种具有可氢化合金颗粒的储氢容器，其在容器内可渗透氢的多个密封容器中，以防止作用在容器壁上的局部压力作用。

公开(公告)号：US4102225A

公开(公告)日：1978-07-25

申请号：US742429

申请日：1976-11-17

申请人： Harold Thomas Michels

发明人： Harold Thomas Michels

IPC分类号： C22C38/00 ,  C22C38/40 ,  C22C38/02 ,  C22C38/06

CPC分类号： C22C38/40

摘要： Nickel-chromium stainless steel is of austenitic composition specially controlled to enable achieving resistance to elevated-temperature oxidation and corrosion at desirably economical levels of alloy content as low as 10% chromium and 10% nickel. Oxidation and corrosion resistant characteristics of the steel particularly include resistance to air-water atmospheres and gasoline exhaust atmospheres that are cyclically heated and cooled with heating to temperatures as high as 1800.degree. F. and cooling to room temperature. Steel has special utility for automotive exhaust train components and is generally useful for cyclically heated structural articles.

摘要翻译： 镍铬不锈钢具有特殊控制的奥氏体组成，能够实现耐高温氧化和腐蚀的耐受性，合金含量低于10％铬和10％镍。 钢的耐氧化和耐腐蚀特性特别包括耐空气 - 水气氛和汽油排放气氛，其循环加热和加热至高达1800°F的温度并冷却至室温。 钢具有汽车排气系列零件的特殊用途，通常用于循环加热的结构件。

公开(公告)号：US4096639A

公开(公告)日：1978-06-27

申请号：US739483

申请日：1976-11-08

申请人： Gary Dale Sandrock

发明人： Gary Dale Sandrock

IPC分类号： C01B3/00 ,  C22C19/03 ,  F17C11/00 ,  F26B5/04

CPC分类号： F17C11/005 ,  C01B3/0057 ,  C22C19/03 ,  Y02E60/321 ,  Y02E60/327 ,  Y10S420/90

摘要： A nickel-mischmetal-calcium compound is used to store gaseous hydrogen at pressures up to about 15 atmospheres at ambient temperatures. The Ni.sub.5 M.sub.1-y Ca.sub.y compounds have values of y ranging from about 0.2 to about 0.9. Alloys conforming to this formula contain from about 4% to about 27% mischmetal, from about 2% to about 11% calcium, up to about 15% copper, and the balance essentially nickel.

摘要翻译： 使用镍 - 稀土金属钙化合物在环境温度下以高达约15个大气压的压力存储气态氢。 Ni5M1-yCay化合物的y值范围为约0.2至约0.9。 符合该配方的合金含有约4％至约27％的混合稀土，约2％至约11％的钙，至多约15％的铜，余量基本上为镍。

公开(公告)号：US4087338A

公开(公告)日：1978-05-02

申请号：US770472

申请日：1977-02-22

申请人： Aubrey Stewart Gendron ,  John Ambrose ,  Victor Alexander Ettel

发明人： Aubrey Stewart Gendron ,  John Ambrose ,  Victor Alexander Ettel

IPC分类号： C25C1/08

CPC分类号： C25C1/08

摘要： An electrolyte containing an organic buffering agent is used to electrowin nickel with a comparatively high bite in a diaphragm-free cell.

摘要翻译： 含有有机缓冲剂的电解质用于在无隔膜的电池中以较高的咬合率电解镍。

公开(公告)号：US4079523A

公开(公告)日：1978-03-21

申请号：US739486

申请日：1976-11-08

申请人： Gary Dale Sandrock

发明人： Gary Dale Sandrock

IPC分类号： C22C1/00 ,  C01B3/00 ,  C22C1/02 ,  C22C14/00 ,  C22C33/04 ,  C22C38/00 ,  C22C38/14 ,  F17C11/00

CPC分类号： C01B3/0057 ,  C01B3/0036 ,  C01B3/0052 ,  C22C38/14 ,  F17C11/005 ,  Y02E60/321 ,  Y02E60/325 ,  Y02E60/327 ,  Y10S420/90

摘要： A method for the preparation of an iron-titanium-mischmetal alloy which is used for the storage of hydrogen. The alloy is prepared by air-melting an iron charge in a clay-graphite crucible, adding titanium and deoxidizing with mischmetal. The resultant alloy contains less than about 0.1% oxygen and exhibits a capability for hydrogen sorption in less than half the time required by vacuum-melted, iron-titanium alloys.

摘要翻译： 一种用于制备用于储存氢的铁 - 钛 - 稀土合金的方法。 该合金通过在粘土 - 石墨坩埚中空气熔化铁装料，加入钛并用混合稀土脱氧来制备。 所得合金含有小于约0.1％的氧，并且在真空熔融的铁 - 钛合金所需的时间的一半以下显示出氢吸附的能力。