The present application discloses a diffusion furnace, including: a furnace tube structure including a furnace tube body and a furnace bottom, a bottom of the furnace tube body being connected to the furnace bottom to form a reaction chamber; and a carrying structure including a pedestal and a plurality of cassettes disposed on the pedestal, the pedestal being disposed on the furnace bottom. By disposing the plurality of the cassettes, a height of the furnace tube body can be decreased and a width of the furnace tube body can be increased, thus enlarging a space of equipment repair and maintenance, which is favorable for the repair and maintenance of the equipment.

A vertical batch furnace assembly, comprising a core tube, an outer casing, a cooling chamber bounded and enclosed by the outer casing and the core tube, and at least one cooling gas supply emanating in the cooling chamber. The core tube has an elongated circumferential wall extending in a longitudinal direction, and is configured to accommodate wafers for processing in the vertical batch furnace. The outer casing extends around the core tube and comprises a heating element for applying a thermal treatment to wafers accommodated in the core tube. The at least one cooling gas supply comprises at least one cooling gas supply opening which is arranged such that the cooling gas enters the cooling chamber with a flow direction which is substantially tangent to the circumferential wall.

A multi-opening oven assembly for simultaneously heating a plurality of blanks, for example aluminum blanks, before forming the heated blanks in a production line is provided. The oven assembly includes vertically aligned shelves to present a plurality of chambers for heating the blanks. A table including an entry side platform and an exit side platform moves vertically along the oven assembly. A rail system extends along the platforms and the shelves to convey the blanks in and out of the chambers. Once one set of heated blanks is removed from a first chamber, the table moves vertically to a second chamber and is ready to receive the next set of heated blanks. A continuous supply of heated blanks is provided for high throughput. The oven assembly is preferably disposed in a press adjacent a forming station of an existing production line and thus, no additional floor space is required.

The present invention provides an electric furnace including: a cylindrical furnace wall; a furnace cover that is provided at an upper end of the furnace wall; and a furnace bottom that is provided at a lower end of the furnace wall and includes a deep bottom portion and a shallow bottom portion as a region having a height of 150 mm to 500 mm from a deepest point of the deep bottom portion, in which a slag pouring port into which molten slag or a solidified slag lump is capable of being poured from a slag transport container directly or through a tilting trough is provided, the slag pouring port overlaps the shallow bottom portion in a plan view, and the area ratio of the shallow bottom portion to the furnace bottom in a plan view is 5% to 40%.

The present invention relates to a furnace device for heating a plate, in particular a metal plate, by convection. The furnace device has a housing, in which a temperature control region for temperature-controlling a component part and an adjustment region are formed, wherein the adjustment region has a temperature control device for adjusting a temperature of a temperature control fluid. Further, the furnace device has a positioning device for positioning the plate in the temperature control region in a predetermined orientation, and a ventilator, which is arranged in the housing and which is adapted to circulate the temperature control fluid in the housing between the temperature control region and the adjustment region such that the temperature control fluid is flowable in a flow direction along a surface of the plate.

Certain embodiments of the inventive technology may be described as apparatus for melting and reshaping metal from a first shape into a second shape in a microgravity or zero gravity environment, such as a space foundry, where such apparatus includes feedstock input componentry (5) configured to accept conductive metal feedstock (7) having the first shape, a furnace and a furnace pre-stage (22) established upflow of the furnace, a plurality of electromagnetic field generators (10), each of which is configured to generate an electromagnetic field, to, e.g., steer, melt and/or move the metal, whether melt or otherwise, and casting componentry (15) configured to reshape molten metal to the second shape. Certain embodiments may achieve a high degree of control over electromagnetic fields by offering individual adjustment of one or more electrical parameters of the electromagnetic field generators (10).

Sleeve for mounting a ceramic roller in a roller hearth furnace, the sleeve has a receptacle for one end of the ceramic roller, the receptacle being surrounded by a lateral wall. The lateral wall has, in the axial direction, a waist portion and a clamping portion, wherein a wall thickness (d) of the lateral wall in the waist portion is smaller than in the vicinity of the waist portion, and a cross-sectional area of the receptacle in the clamping portion is smaller than in the vicinity of the clamping portion.

A ceramic roller can be mounted in a roller hearth furnace by the sleeve, even at high temperature. During production, the sleeve is provided with a reduced cross-sectional area in the clamping portion. When the sleeve is pressed axially onto the end of a ceramic roller, the reduced cross-sectional area produces an elastic force, with the sleeve being held on the ceramic roller.

Sleeve for mounting a ceramic roller in a roller hearth furnace, the sleeve has a receptacle for one end of the ceramic roller, the receptacle being surrounded by a lateral wall. The lateral wall has, in the axial direction, a waist portion and a clamping portion, wherein a wall thickness (d) of the lateral wall in the waist portion is smaller than in the vicinity of the waist portion, and a cross-sectional area of the receptacle in the clamping portion is smaller than in the vicinity of the clamping portion.

A ceramic roller can be mounted in a roller hearth furnace by the sleeve, even at high temperature. During production, the sleeve is provided with a reduced cross-sectional area in the clamping portion. When the sleeve is pressed axially onto the end of a ceramic roller, the reduced cross-sectional area produces an elastic force, with the sleeve being held on the ceramic roller.

A scrap submergence device for mixing molten metal in a furnace may include an upper structure, a shaft extending down from the upper structure, and an impeller at a lower end of the shaft. The impeller may include a plurality of blades and a plate. Each of the plurality of blades may have a blade height and a blade radius. A ratio of a blade height to a blade radius may be approximately 0.3 to approximately 1.

A scrap submergence device for mixing molten metal in a furnace may include an upper structure, a shaft extending down from the upper structure, and an impeller at a lower end of the shaft. The impeller may include a plurality of blades and a plate. Each of the plurality of blades may have a blade height and a blade radius. A ratio of a blade height to a blade radius may be approximately 0.3 to approximately 1.