A furnace for annealing a sheet includes: a first section; a second vertical section, the second vertical section including openings supplied with an oxidizing medium, an opening facing each side of the sheet, and means for separately controlling a flow of the oxidizing medium on each side of the sheet; and a third section. The second vertical section is located in a distinct casing and separated from the first and third sections with sealing devices. The second vertical section includes extraction openings for extracting the oxidizing medium not consumed by the sheet, an extraction opening facing each side of the sheet. The openings supplied with an oxidizing medium are located transversally at one end of the second vertical section. The extraction openings are located transversally at an other end of the second vertical section.

A method for the thermal treatment of mineral raw materials such as limestone or dolomite is shown and described, which includes at least the following steps of a. providing a mineral bulk material and a conductive material and b. placing the mineral bulk material and the conductive material into a kiln, generating an electromagnetic field inside the kiln, thermally treating the mineral bulk material in the kiln by means of electromagnetic excitation of the conductive material in the electromagnetic field, and removing the thermally treated mineral bulk material and the conductive material from the kiln. Using the method described, even large quantities of mineral bulk material can be efficiently converted.

A method for the thermal treatment of mineral raw materials such as limestone or dolomite is shown and described, which includes at least the following steps of a. providing a mineral bulk material and a conductive material and b. placing the mineral bulk material and the conductive material into a kiln, generating an electromagnetic field inside the kiln, thermally treating the mineral bulk material in the kiln by means of electromagnetic excitation of the conductive material in the electromagnetic field, and removing the thermally treated mineral bulk material and the conductive material from the kiln. Using the method described, even large quantities of mineral bulk material can be efficiently converted.

In an embodiment, a heating apparatus for heating an electrode group structure includes a chamber, a heat conduction plate, a temperature adjustment unit, a pressure adjustment unit, and a controller. In a state where the heat conduction plate is in contact with the current collectors of a plurality of the electrode group structures in a heating room inside chamber, the heat conduction plate enables heat to be conducted to the current collectors of the electrode group structures. The controller controls operation of the temperature adjustment unit and the pressure adjustment unit in a state where the heat conduction plate is in contact with the current collectors of the electrode group structures.

The present invention generally relates to a heating apparatus, method of using and making the same that can be used to heat a thermoformable prosthetic socket.

The present invention generally relates to a heating apparatus, method of using and making the same that can be used to heat a thermoformable prosthetic socket.

A device (1) for homogenizing a gas distribution in a process chamber (2). The device (1) has a aperture shield (3) and a linear drive (4) for moving the aperture shield (3) in a reciprocating manner in two mutually opposite linear movement directions (5) between two terminal positions. The aperture shield (3) is able to be heated by at least one heating installation (6) of the device (1), and the aperture shield (3) by way of at least one interposed compensation element (7) of the device (1) is connected to the linear drive (4). The compensation element (7) enables a relative movement between the aperture shield (3) and the linear drive (4) in at least one direction (8) transverse, preferably orthogonal, to the linear movement directions (5) of the aperture shield (3).

A device (1) for homogenizing a gas distribution in a process chamber (2). The device (1) has a aperture shield (3) and a linear drive (4) for moving the aperture shield (3) in a reciprocating manner in two mutually opposite linear movement directions (5) between two terminal positions. The aperture shield (3) is able to be heated by at least one heating installation (6) of the device (1), and the aperture shield (3) by way of at least one interposed compensation element (7) of the device (1) is connected to the linear drive (4). The compensation element (7) enables a relative movement between the aperture shield (3) and the linear drive (4) in at least one direction (8) transverse, preferably orthogonal, to the linear movement directions (5) of the aperture shield (3).

An industrial oven includes an oven chamber configured to receive a plurality of work pieces. A heater box of the oven has a heating element therein operable to heat air for delivery to the oven chamber. A circulation system of the oven is operable to force hot air from the heater box into the oven chamber. The circulation system includes a delivery manifold extending from the heater box to the oven chamber. A duct has an inlet coupled with an outlet of the delivery manifold, and the duct has a plurality of hot air outlet apertures therein for expelling hot air into the oven chamber. The duct is constructed of fabric sheet and suspended within the oven chamber.

An industrial oven includes an oven chamber configured to receive a plurality of work pieces. A heater box of the oven has a heating element therein operable to heat air for delivery to the oven chamber. A circulation system of the oven is operable to force hot air from the heater box into the oven chamber. The circulation system includes a delivery manifold extending from the heater box to the oven chamber. A duct has an inlet coupled with an outlet of the delivery manifold, and the duct has a plurality of hot air outlet apertures therein for expelling hot air into the oven chamber. The duct is constructed of fabric sheet and suspended within the oven chamber.