Described are nosetips for continuous casting of a metal alloy. The nosetip may include a first portion having a first surface parallel to a second surface opposite the first surface. The nosetip may include a second portion having a third surface directed toward an extended first surface. The extended first surface may be in a common plane with the first surface. The nosetip may include a third portion having an arcuate surface connecting the third surface to the extended first surface. The arcuate surface may include a point of curvature at a vertical distance from the extended first surface. The vertical distance may be configured to limit a maximum meniscus height for liquid metal, cast using the nosetip, between the nosetip and a continuous casting surface. Also described are methods of continuous casting a metal alloy at a casting speed of greater than 12 m/min.

Machine for continuous casting of a lead alloy for forming grids for plates of electric storage batteries, which comprises a rotary drum having an external peripheral surface with a plurality of grooves obtained according to the grid design to be made and a sliding block coupled in sliding relation with the external surface of the rotary drum and with a distribution duct obtained in order to insert the molten lead in the plurality of grooves. The plurality of grooves comprises circumferential notches and transverse notches that meet in respective vertices. At the vertices and within the circumferential notches, a plurality of studs are placed that are intended to shape corresponding corners of smoothed form of the grids.

A method and apparatus for continuous Near Net Shape casting of a liquid metal (10) into a metal strip are described. The method comprises transferring the liquid metal in a velocity adjusted manner from a headbox (50) a chilled substrate (36), via a meniscus gap (69). The headbox (50) comprising a slot nozzle (68) defined in a bottom portion (66) for the headbox (50) above (36) onto the chilled substrate. The slot nozzle (68) defining a smooth elongated cavity with a slot width (67) and the slot length (65) of the metal strip (34). It has been surprisingly found that the generation of some turbulence at the outlet of the apparatus described herein promotes stable Near Net Shape Continuous Casting. The present method and apparatus increase the level of turbulence in the liquid metal of the outlet nozzle upstream of the chilled substrate (36) to minimize premature metal freezing. In a particularly preferred embodiment the slot nozzle is adjustable.

A weathering steel made by preparing a molten melt producing an as-cast carbon alloy steel strip with a corrosion index of at least 6.0 comprising, by weight, 0.02%-0.08% carbon, <0.6% silicon, 0.2%-2.0% manganese, <0.03% phosphorus, <0.01% sulfur, <0.01% nitrogen, 0.2%-0.5% copper, 0.01%-0.2% niobium, 0.01%-0.2% vanadium, 0.1%-0.4% chromium, 0.08%-0.25% nickel, <0.01% aluminum, and the remainder iron and impurities. The molten melt is solidified and cooled into a cast strip 4 mm in thickness in a non-oxidizing atmosphere. The strip is hot rolled in an austenitic temperature range above Ar.sub.3 to between 10% and 50% reduction, cooled at above 20 C./s and coiled below 700 C. to form a steel strip with a microstructure comprising bainite and acicular ferrite with more than 70% niobium in solid solution. Then, age hardening the strip resulting in a yield strength of at least 550 MPa and a total elongation of at least 8%.

The invention relates to the reduction of core losses in soft magnetic applications utilizing amorphous foil as the core material. Amorphous foil is known to have lower losses when compared to crystalline silicon steel laminations. It is found that a reduction of 10-40% of losses can be achieved over the current state of the art amorphous material by mechanical scribing of the surface of the soft magnetic laminations comprising the wound core in power conditioning devices such as a transformer. The scribing process introduces control of the magnetic domains causing ease of magnetic flux reversal

A method of making weathering steel by preparing a molten melt producing an as-cast carbon alloy steel strip with a corrosion index of at least 6.0 comprising, by weight, 0.02%-0.08% carbon, <0.6% silicon, 0.2%-2.0% manganese, <0.03% phosphorus, <0.01% sulfur, <0.01% nitrogen, 0.2%-0.5% copper, 0.01%-0.2% niobium, 0.01%-0.2% vanadium, 0.1%-0.4% chromium, 0.08%-0.25% nickel, <0.01% aluminum, and the remainder iron and impurities. The molten melt is solidified and cooled into a cast strip 4 mm in thickness in a non-oxidizing atmosphere. The strip is hot rolled in an austenitic temperature range above Ar.sub.3 to between 10% and 50% reduction, cooled at above 20 C./s and coiled below 700 C. to form a steel strip with a microstructure comprising bainite and acicular ferrite with more than 70% niobium in solid solution. Then, age hardening the strip resulting in a yield strength of at least 550 MPa and a total elongation of at least 8%.

In one embodiment, a lead strip caster for battery grids includes a nozzle, a pair of rollers, and a molten lead supply to the nozzle. The lead strip caster produces a continuous lead strip for making battery grids. The nozzle has at least one passage that communicates with generally opposed faces of the nozzle at least partially received between the rollers to supply molten lead to exterior surfaces of the corotating rollers to form a continuous solid strip of lead from which battery grids may be made.

A metal delivery nozzle for a twin roll caster adapted to extend along and above a pair of casting rolls has a main portion with one or two refractory pieces with outlets adapted to deliver molten metal to a casting pool supported by the casting rolls during casting; refractory delivery end portions separately supported adapted to move relative to the main portion at each end portion of the metal delivery nozzle, each refractory delivery end portion having a reservoir portion with passages there through adapted to deliver molten metal to the casting pool adjacent the side dams and the end portions of the casting rolls; and a mechanism connected to each refractory delivery end portion adapted to move said refractory delivery end portion relative to the main portion as casting proceeds to maintain desired distance between the refractory delivery end portions and the side dams.

Provided is a method that includes ejecting an FeSiB-based molten alloy containing iron (Fe), boron (B), and silicon (Si) as essential components from a tapping nozzle to a surface of a cooling roll and rotating the cooling roll at a surface speed of 15 m/sec or more and 50 m/sec or less to rapidly cool the FeSiB-based molten alloy on the surface of the cooling roll to manufacture an alloy ribbon, the tapping nozzle includes a single slit formed to have a width of 0.6 mm or more and less than 2.0 mm, the cooling roll has a curvature of 810.sup.4 or more and less than 210.sup.3, and the method includes passing cooling water in an amount of 0.3 m.sup.3/min or more and less than 20 m.sup.3/min at 5 C. or more and less than 60 C. through the cooling roll to manufacture a rapidly solidified alloy ribbon having an average thickness of 30 m or more and less than 55 m.

Disclosed is an apparatus having a rotatable wheel with a planar external circumferential surface, which is flat in a direction parallel to the axis of rotation of the wheel, at least one nozzle having a nozzle opening for directing a molten metal onto the circumferential surface and a collection means for collecting solidified fibers of metal formed on the circumferential surface from the molten metal and separated from the circumferential surface by centrifugal force generated by rotation of the wheel. The nozzle has a rectangular cross-section having a width of the nozzle opening in the circumferential direction of rotation of the wheel and a length transverse to the circumferential surface of the wheel which is greater than the width. An apparatus is provided for controlling a gas pressure applied to the liquid metal and delivers it to the circumferential surface of the rotatable wheel.