The disclosure relates to a method for opening up electrochemical energy storage devices in connection with a subsequent recovery of valuable materials contained therein as secondary raw materials, in which method the energy storage devices are opened up by means of a thermal treatment system to remove the electrolytes and reactive substances, before the thermally treated material is subjected to processing, whereby secondary raw materials in the thermally treated material are separated from one another. The thermal treatment is performed in an indirectly heated furnace 2 under atmospheric pressure conditions or a slight overpressure relative to the ambient pressure of up to 20 mbar in a reducing atmosphere, and influence is exerted on the course of the thermal treatment process via the reducing atmosphere, as a control variable. Furthermore, a thermal treatment system is described for removing electrolytes and reactive substances in electrochemical energy storage devices and consequently for pyrolytic opening.

The disclosure relates to a method for opening up electrochemical energy storage devices in connection with a subsequent recovery of valuable materials contained therein as secondary raw materials, in which method the energy storage devices are opened up by means of a thermal treatment system to remove the electrolytes and reactive substances, before the thermally treated material is subjected to processing, whereby secondary raw materials in the thermally treated material are separated from one another. The thermal treatment is performed in an indirectly heated furnace 2 under atmospheric pressure conditions or a slight overpressure relative to the ambient pressure of up to 20 mbar in a reducing atmosphere, and influence is exerted on the course of the thermal treatment process via the reducing atmosphere, as a control variable. Furthermore, a thermal treatment system is described for removing electrolytes and reactive substances in electrochemical energy storage devices and consequently for pyrolytic opening.

A method of thermally processing work pieces including providing an insulated chamber having a first end, an opposing second end, and a middle portion disposed between the first and second ends, wherein the first end is inclined with respect to middle portion, creating a thermal gradient within an interior of the insulated chamber, and providing a means for gradually moving a workpiece from the first end to the second end within the created thermal gradient.

A method of thermally processing work pieces including providing an insulated chamber having a first end, an opposing second end, and a middle portion disposed between the first and second ends, wherein the first end is inclined with respect to middle portion, creating a thermal gradient within an interior of the insulated chamber, and providing a means for gradually moving a workpiece from the first end to the second end within the created thermal gradient.

An oven for elimination of harmful organisms which pose phytosanitary risks and are present in material of plant origin in the form of particles is provided. The oven includes: a said oven comprising (a) first and second circular plates mounted in rotation about an axis Z, the surface of said plates being perforated and permeable to air and water, (b) a means for transferring the collected particles from the first plate to the second plate, and (c) a gas-blowing means forming a closed gas cycle. The gas-blowing means includes a blower for accelerating a flow of gas and directing it towards a heating station in order to heat the gas and directing it parallel to the axis Z towards the first plate, passing through the perforated surface of the first plate, then directly afterwards through the perforated surface of the second plate, in order to return to the blower and recommence the gas cycle.

An oven for elimination of harmful organisms which pose phytosanitary risks and are present in material of plant origin in the form of particles is provided. The oven includes: a said oven comprising (a) first and second circular plates mounted in rotation about an axis Z, the surface of said plates being perforated and permeable to air and water, (b) a means for transferring the collected particles from the first plate to the second plate, and (c) a gas-blowing means forming a closed gas cycle. The gas-blowing means includes a blower for accelerating a flow of gas and directing it towards a heating station in order to heat the gas and directing it parallel to the axis Z towards the first plate, passing through the perforated surface of the first plate, then directly afterwards through the perforated surface of the second plate, in order to return to the blower and recommence the gas cycle.

There are provided a method for producing a photovoltaic element with stabilised efficiency, and a device which may be used to carry out the method, for example in the form of a specially adapted continuous furnace. A silicon substrate to be provided with an emitter layer and electrical contacts is thereby subjected to a stabilisation treatment step. In that step, hydrogen, for example from a hydrogenated silicon nitride layer, is introduced into the silicon substrate, for example within a zone (2) of maximum temperature. The silicon substrate may then purposively be cooled rapidly in a zone (3) in order to avoid hydrogen effusion. The silicon substrate may then purposively be maintained, for example in a zone (4), within a temperature range of from 230 C. to 450 C. for a period of, for example, at least 10 seconds. The previously introduced hydrogen may thereby assume an advantageous bond state. At the same time or subsequently, a regeneration may be carried out by generating excess minority charge carriers in the substrate at a temperature of at least 90 C., preferably at least 230 C. Overall, with the proposed method, a regeneration process in the production of a photovoltaic element may be accelerated significantly so that it may be carried out, for example, in a suitably modified continuous furnace.

There are provided a method for producing a photovoltaic element with stabilised efficiency, and a device which may be used to carry out the method, for example in the form of a specially adapted continuous furnace. A silicon substrate to be provided with an emitter layer and electrical contacts is thereby subjected to a stabilisation treatment step. In that step, hydrogen, for example from a hydrogenated silicon nitride layer, is introduced into the silicon substrate, for example within a zone (2) of maximum temperature. The silicon substrate may then purposively be cooled rapidly in a zone (3) in order to avoid hydrogen effusion. The silicon substrate may then purposively be maintained, for example in a zone (4), within a temperature range of from 230 C. to 450 C. for a period of, for example, at least 10 seconds. The previously introduced hydrogen may thereby assume an advantageous bond state. At the same time or subsequently, a regeneration may be carried out by generating excess minority charge carriers in the substrate at a temperature of at least 90 C., preferably at least 230 C. Overall, with the proposed method, a regeneration process in the production of a photovoltaic element may be accelerated significantly so that it may be carried out, for example, in a suitably modified continuous furnace.

A furnace for the heat treatment of a metal product includes constitutive elements, each having a thermal inertia property determined from physical parameters. The constitutive elements include walls delimiting at least partially the furnace, a heating unit for heating the metal product, and a rapid heating element for heating the metal product. The furnace also includes a control circuit for controlling the heating unit and/or the rapid heating element, based on one or more thermal inertia properties of one or more constitutive elements of the furnace, and at least based on a ground of a constitutive element of said furnace.

A furnace for the heat treatment of a metal product includes constitutive elements, each having a thermal inertia property determined from physical parameters. The constitutive elements include walls delimiting at least partially the furnace, a heating unit for heating the metal product, and a rapid heating element for heating the metal product. The furnace also includes a control circuit for controlling the heating unit and/or the rapid heating element, based on one or more thermal inertia properties of one or more constitutive elements of the furnace, and at least based on a ground of a constitutive element of said furnace.