Disclosed are an aluminum alloy substrate for a magnetic disc, which includes an aluminum alloy consisting of Mg:4.5-10.0 mass % (hereinafter referred to as %), Be: 0.00001-0.00200%,Cu: 0.003-0.150%, Zn: 0.05-0.60%, Cr: 0.010-0.300%, Si: 0.060% or less, and Fe: 0.060% or less, with a balance being Al and an unavoidable impurity, an amount of an Mg-based oxide being 50 ppm or less, (I.sub.Be/I.sub.bulk)(C.sub.Be)0.1000% where (I.sub.Be) is a maximum optical emission intensity of Be in a surface depth direction using a glow discharge optical emission spectrometer (GDS) prior to performing a plating pretreatment, (I.sub.bulk) is a mean optical emission intensity of Be in an interior of a base material of the aluminum alloy prior to performing a plating pretreatment, and (C.sub.Be) is an amount of the Be, and a method of manufacturing the magnetic disc aluminum alloy substrate.

A titanium composite material 1 is provided that includes: an inner layer 5 consisting of a commercially pure titanium or a titanium alloy; an outer layer 3 formed on at least one surface of the inner layer 5 and having a chemical composition that is different from a chemical composition of the inner layer 5; and an intermediate layer formed between the inner layer 5 and the outer layer 3 and having a chemical composition that is different from the chemical composition of the inner layer 5. The thickness of the outer layer 3 is 2 ?m or more, and occupies no more than 40% of the overall thickness per side. The thickness of the intermediate layer is 0.5 ?m or more. Despite being inexpensive, this titanium composite material has desired characteristics.

The disclosure relates to a device (10) and a method for machining at least one surface of a continuous strip material (B) made of non-ferrous metals, which in particular comprises aluminum or aluminum alloys or consists of such materials. A rotating roller brush (12) is used, the roller length of which can be brought into contact with a surface of the strip material (B). Such roller brush (12) has a diameter of 200 mm to 1,000 mm and can rotate at a rotational speed of 100 to 3,600 rpm using an assigned motor drive (14).

A precious alloy for horological applications contains by mass, in parts per thousand of the total, 540 to 630 parts of gold, 150 to 220 parts of palladium, 100 to 265 parts of silver, more than 150 to 265 parts of copper, from 0.0 to 0.2 parts of iridium, 0.0 to 4.0 parts of zinc, and the remainder containing iron and/or nickel and/or cobalt. The proportion by mass of the total content of gold, palladium, silver, copper, iridium and zinc is greater than 999.900 parts, the proportion by mass of the remainder is less than 0.100 parts. The density of the alloy includes between 13.5 and 14.5 g/cm.sup.3. The proportion by mass of cobalt is less than 0.005 parts, that of iron is less than 0.005 parts, and that of nickel is less than 0.0005 parts. The total of copper and zinc includes between 150 and 270 parts.

An aluminum alloy foil for a current collector of an electrode is provided which has not only high electric conductivity but also high strength before and after a drying step, and is low in manufacturing cost. Provided is an aluminum alloy foil for a current collector of an electrode, containing 1.0 to 2.0 mass % (hereafter, simply referred to as %) of Fe, 0.01 to 0.2% of Si, 0.0001 to 0.2% of Cu, and 0.005 to 0.3% of Ti, the remainder being Al and inevitable impurities, wherein an amount of Fe contained as a solid solution is 300 ppm or more, and particles of intermetallic compounds having an equivalent circle diameter of 0.1 to 1.0 ?m exist at 1.0?10.sup.5 particles/mm.sup.2 or more.

The disclosure is directed to methods of forming glassy alloys. A glassy alloy is cold rolled at a temperature less than Tg of the glassy alloy to form a flattened glassy alloy. Then, the cold rolled glassy alloy is thermoplastically formed at a temperature above Tg of the glassy alloy. In certain embodiments, the flattened glassy alloy may have one or more shear bands and/or micro-cracks, and the thermoplastic forming may heal the shear bands and/or micro-cracks. The resulting glassy alloy may thereby have reduced or eliminated shear bands and/or micro-cracks.

An apparatus, method and composition for long length tubing includes continuous production of long length seamless aluminum tubing suitable for use as coiled tubing in hydrocarbon wells. A 2XXX aluminum alloy may be used in combination with a continuous casting/extrusion apparatus using aluminum from a melt. Other metals may be used, as well as continuously cast rod from a casting wheel and belt or conform extruder, which is processed to form a hollow and then sized by drawing.

A copper-aluminum composite plate material prepared by aluminum liquid continuous casting and a process thereof. The method includes: S1, heating an aluminum ingot to 700-800 C. and smelting for 1-3 h; S2, degassing smelted aluminum liquid, and keeping the temperature and standing; S3, texturing a copper strip, and then cleaning; S4, heating the pretreated copper strip to 200-650 C.; S5, under the protection of inert gas, continuously casting the treated aluminum liquid on the treated copper strip, performing quenching crystallization on a copper-aluminum composite material, and performing oxygen-free continuous casting; and S6, continuous rolling: rolling the continuously cast copper-aluminum composite material to obtain the copper-aluminum composite plate material prepared by aluminum liquid continuous casting.

A copper-aluminum composite plate material prepared by aluminum liquid continuous casting and a process thereof. The method includes: S1, heating an aluminum ingot to 700-800 C. and smelting for 1-3 h; S2, degassing smelted aluminum liquid, and keeping the temperature and standing; S3, texturing a copper strip, and then cleaning; S4, heating the pretreated copper strip to 200-650 C.; S5, under the protection of inert gas, continuously casting the treated aluminum liquid on the treated copper strip, performing quenching crystallization on a copper-aluminum composite material, and performing oxygen-free continuous casting; and S6, continuous rolling: rolling the continuously cast copper-aluminum composite material to obtain the copper-aluminum composite plate material prepared by aluminum liquid continuous casting.