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Grain corrosion resistance

The etching process is similar to a corrosion process. Therefore, special acids and etching techniques are required for graining corrosion resistant steels. The steel should be selected together with the steel manufacturer and the graining experts. [Pg.595]

The Fe, Co, and Ni deposits are extremely fine grained at high current density and pH. Electroless nickel, cobalt, and nickel—cobalt alloy plating from fluoroborate-containing baths yields a deposit of superior corrosion resistance, low stress, and excellent hardenabiUty (114). Lead is plated alone or ia combination with tin, iadium, and antimony (115). Sound iasulators are made as lead—plastic laminates by electrolyticaHy coating Pb from a fluoroborate bath to 0.5 mm on a copper-coated nylon or polypropylene film (116) (see Insulation, acoustic). Steel plates can be simultaneously electrocoated with lead and poly(tetrafluoroethylene) (117). Solder is plated ia solutioas containing Pb(Bp4)2 and Sn(Bp4)2 thus the lustrous solder-plated object is coated with a Pb—Sn alloy (118). [Pg.168]

Rea.ctivity ofLea.d—Ca.lcium Alloys. Precise control of the calcium content is required to control the grain stmcture, corrosion resistance, and mechanical properties of lead—calcium alloys. Calcium reacts readily with air and other elements such as antimony, arsenic, and sulfur to produce oxides or intermetaUic compounds (see Calciumand calciumalloys). In these reactions, calcium is lost and suspended soHds reduce fluidity and castibiUty. The very thin grids that are required for automotive batteries are difficult to cast from lead—calcium alloys. [Pg.59]

Addition of niobium to austenitic stainless steels inhibits intergranular corrosion by forming niobium carbide with the carbon that is present in the steel. Without the niobium addition, chromium precipitates as a chromium carbide film at the grain boundaries and thus depletes the adjacent areas of chromium and reduces the corrosion resistance. An amount of niobium equal to 10 times the carbon content is necessary to prevent precipitation of the chromium carbide. [Pg.26]

Iridium [7439-88-5] Ir, and rhodium [7440-16-6] Rh, iadividually iacrease corrosion resistance, hardness, and strength of platinum alloys. They can be used to reduce grain size (140). [Pg.483]

These standards also outline requirements for surface finish, grain size, heat treatment, metallurgical cleanness, absence of delta ferrite and alloy segregation to ensure that besides having a well balanced chemistry the alloys shall be in the proper metallurgical condition to yield optimum mechanical and corrosion resistant properties. [Pg.470]

Austenitic steels of the 304S15 type are normally heat treated at 1 050°C and cooled at a fairly rapid rate to remove the effects of cold or hot working, and in this state much of the carbon is in supersaturated solid solution. Reheating to temperatures below the solution treatment temperature leads to the formation of chromium-rich MjjCj precipitates predominantly at the grain boundaries with the production of chromium gradients and reduced corrosion resistance as is the case with the martensitic steels. Any attack is... [Pg.539]

While lead of purity in excess of 99.99% is commercially available, it is very rarely used owing to its susceptibility to grain growth and fatigue failure by intercrystalline cracking, and indifferent mechanical properties. Because of its generally superior corrosion resistance, pure lead to BS 334 1982 type A, shown in Table4.13, is occasionally used in chemical plant, but only if there is no suitable alternative. [Pg.720]

Of the elements commonly found in lead alloys, zinc and bismuth aggravate corrosion in most circumstances, while additions of copper, tellurium, antimony, nickel, silver, tin, arsenic and calcium may reduce corrosion resistance only slightly, or even improve it depending on the service conditions. Alloying elements that are of increasing importance are calcium especially in maintenance-free battery alloys and selenium, or sulphur combined with copper as nucleants in low antimony battery alloys. Other elements of interest are indium in anodesaluminium in batteries and selenium in chemical lead as a grain refiner ". [Pg.721]


See other pages where Grain corrosion resistance is mentioned: [Pg.2733]    [Pg.342]    [Pg.182]    [Pg.398]    [Pg.377]    [Pg.7]    [Pg.114]    [Pg.117]    [Pg.396]    [Pg.397]    [Pg.391]    [Pg.107]    [Pg.3]    [Pg.402]    [Pg.446]    [Pg.451]    [Pg.313]    [Pg.126]    [Pg.233]    [Pg.247]    [Pg.279]    [Pg.280]    [Pg.339]    [Pg.72]    [Pg.904]    [Pg.41]    [Pg.45]    [Pg.46]    [Pg.237]    [Pg.528]    [Pg.536]    [Pg.676]    [Pg.721]    [Pg.737]    [Pg.737]    [Pg.783]    [Pg.850]    [Pg.1197]    [Pg.1203]    [Pg.1207]    [Pg.1207]    [Pg.1211]   
See also in sourсe #XX -- [ Pg.13 ]




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Grain resistance

Grain resistivities

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