A method for casting a melt uses a melt container in which a melt receiving space is formed. The melt container has a spout in the form of a lance on the bottom on the melt container. The method includes the following steps: filling the melt container with melt, wherein the melt is introduced into the melt receiving space of the melt container from a crucible using a spout orifice of the lance; casting at least one cast workpiece with melt; filling the melt container with melt again. When filling the melt container with melt, more melt is received in the melt receiving space than is needed for casting the cast workpiece. Directly before the renewed filling of the melt container, a remainder of melt having an oxide skin formed at the melt surface is present in the melt receiving space of the melt container.

A method for casting a melt uses a melt container in which a melt receiving space is formed. The melt container has a spout in the form of a lance on the bottom on the melt container. The method includes the following steps: filling the melt container with melt, wherein the melt is introduced into the melt receiving space of the melt container from a crucible using a spout orifice of the lance; casting at least one cast workpiece with melt; filling the melt container with melt again. When filling the melt container with melt, more melt is received in the melt receiving space than is needed for casting the cast workpiece. Directly before the renewed filling of the melt container, a remainder of melt having an oxide skin formed at the melt surface is present in the melt receiving space of the melt container.

A tundish, in particular a tundish for continuous steel casting for placement between a steel casting ladle and a continuous casting mold, with an inlet region and an outlet region, wherein in the inlet region, molten steel can be supplied in particular through a ladle shroud and in the outlet region, the molten steel can be drained from the tundish in particular by means of a plug and an outlet opening; in the vicinity of the inlet region in the tundish, a threshold or ramp is provided, which forms a region of the tundish bottom into a cup or tundish; the threshold or ramp has at least one channel at the side, which locally reduces the height of the threshold or ramp or breaks through the threshold.

A tundish, in particular a tundish for continuous steel casting for placement between a steel casting ladle and a continuous casting mold, with an inlet region and an outlet region, wherein in the inlet region, molten steel can be supplied in particular through a ladle shroud and in the outlet region, the molten steel can be drained from the tundish in particular by means of a plug and an outlet opening; in the vicinity of the inlet region in the tundish, a threshold or ramp is provided, which forms a region of the tundish bottom into a cup or tundish; the threshold or ramp has at least one channel at the side, which locally reduces the height of the threshold or ramp or breaks through the threshold.

A method and apparatus for manufacturing an equiaxed crystal aluminum alloy cast ingot by using additive manufacturing and rapid solidification techniques are provided. The apparatus comprises: a metal heating mechanism and a negative pressure cooling mechanism. The metal heating mechanism is located above the negative pressure cooling mechanism and is connected thereto by a nozzle. The negative pressure cooling mechanism comprises a vacuum chamber having an air inlet hole and an air outlet hole, and a three-dimensional moving ingot mechanism disposed inside the vacuum chamber. The three-dimensional moving ingot mechanism comprises a moving ingot and a two-dimensional moving platform vertically connected to the moving ingot. A water cooling mechanism is disposed outside the moving ingot, and the moving ingot is driven by a precision motor to precisely move up and down.

A method and apparatus for manufacturing an equiaxed crystal aluminum alloy cast ingot by using additive manufacturing and rapid solidification techniques are provided. The apparatus comprises: a metal heating mechanism and a negative pressure cooling mechanism. The metal heating mechanism is located above the negative pressure cooling mechanism and is connected thereto by a nozzle. The negative pressure cooling mechanism comprises a vacuum chamber having an air inlet hole and an air outlet hole, and a three-dimensional moving ingot mechanism disposed inside the vacuum chamber. The three-dimensional moving ingot mechanism comprises a moving ingot and a two-dimensional moving platform vertically connected to the moving ingot. A water cooling mechanism is disposed outside the moving ingot, and the moving ingot is driven by a precision motor to precisely move up and down.

The present invention provides a method for coating the bottom of a steel pan comprising the steps of positioning a mold on the bottom of the steel pan; securing the mold by means of a clamping mechanism; applying refractory material to the bottom of the pan and below the mold; applying a load to the mold; and removing the mold from the refractory material. The present invention is advantageous because it enables an increase in the metallic yield of pans and the reduction of non-metallic inclusions, which are normally dragged by the vortex formed.

The present invention provides a method for coating the bottom of a steel pan comprising the steps of positioning a mold on the bottom of the steel pan; securing the mold by means of a clamping mechanism; applying refractory material to the bottom of the pan and below the mold; applying a load to the mold; and removing the mold from the refractory material. The present invention is advantageous because it enables an increase in the metallic yield of pans and the reduction of non-metallic inclusions, which are normally dragged by the vortex formed.

An isostatically pressed product (10, 11, 12, 13, 14) for use in handling of molten metals comprising: a body (20) made from a first refractory composition (50); the body (20) comprises a surface (21); and at least one liner section (30.1) applied partially onto the surface (21) of the body (20); the at least one liner section (30.1) is made from a second refractory composition (51); the at least one liner section (30.1, 30.2) forming the liner (30) of the body (20); whereas in at least one cross-section of the product, the surface (21) of the body (20) in a region covered with the liner (30), comprises at least one convex (41) and at least two concave (42) sections and a method for manufacturing an isostatically pressed product (10, 11, 12, 13, 14) for use in handling of molten metals.

A ladle bottom being part of a metallurgical ladle for treating a metal melt as well as a corresponding metallurgical ladle.