A modular oven includes a plurality of interlockable insulated panels for user assembly into a cubic structure of an oven. The panels include a top panel, a bottom panel, a left panel, a right panel, a back panel, and a front panel. The front panel can be pivotally mounted to the left or right panel and serves as a door for the modular oven. The top panel and the bottom panel are selectively coupled to the left, back, and right panels by mounting pegs. The bottom panel is provided with a heating element on one side and a plurality of casters on the other side to facilitate transporting the oven. A control module is selectively coupled to one of the panels to control operations of the oven. The oven may also be provided with a trolley system to facilitate transport of workpieces to and from the oven.

A sample heating device includes: an opening/closing cover provided to be movable in a horizontal direction between a position above an opening of a mounting port and a position displaced from the position above the opening, and a cover sliding mechanism that is engaged with a part of a sample boat conveying portion when the sample boat conveying portion comes to a predetermined position in a horizontal plane and moves the opening/closing cover in the horizontal direction according to upward and downward movements of the sample boat conveying portion so that the opening/closing cover is provided at the position directly above the opening of the mounting port when the sample boat conveying portion comes to a predetermined height.

A push gate for a scrap metal furnace with a volatizing chamber and a doorway into that chamber. The push gate includes a door plate to seal against the doorway, a scoop sized to fit in the volatizing chamber, and a plunger attached to the scoop that extends through the door plate. The push gate is movable. When the push gate is positioned such that the door plate seals against the doorway, the plunger can controllably move the scoop in and out of the chamber to push scrap metal to predetermined positions in the chamber for predetermined periods of time.

In a door structure of a heat treatment furnace performing a heat treatment of a workpiece, there are provided: a first opening member and a second opening member in which workpiece passing ports where the transferred workpiece passes are formed; and a sheet shutter, the sheet shutter is provided with a winding portion and a shutter portion, the shutter portion is disposed between the first opening member and the second opening member, the shutter portion is provided with a first sheet portion which covers the workpiece passing port of the first opening member and a second sheet portion which covers the workpiece passing port of the second opening member at a time that the shutter portion is closed, and it is configured that a gas storage portion is formed between the first opening member and the second opening member at the time that the shutter portion is closed.

A sintering apparatus is provided. The sintering apparatus includes a case having an internal space formed therein and including a door provided in a front portion thereof to open and close the internal space, a magnetron coupled to the case and oscillating microwaves toward the internal space, a heat insulating unit disposed in the internal space to form a chamber space and blocking transmission of heat of the chamber space to the internal space, a susceptor unit disposed in the chamber space and having a sintering space in which a to-be-sintered material is accommodated, and a cooling unit cooling at least one of the case or the chamber space.

The invention relates to a furnace for the treatment of material, in particular for the oxidative treatment of fiber material, in particular for producing carbon fibers, comprising a housing (12) having a housing inner space (14), which is gas-tight with the exception of passage areas (18, 20) for the fibers (22). In the housing inner space (14) of the housing (12), a process chamber (28) is located. A hot working atmosphere (40) can be generated by means of an atmosphere device (42). The atmosphere device (42) comprises a flow system (46) having flow channels (48), which are arranged in the housing inner space (14) each defining one flow chamber (50), and are provided with flow passages such that the respective flow chambers (50) are fluidically connected to the process chamber (28) in such a way that hot working atmosphere (40) can be delivered to the process chamber (28) in at least one main flow direction (44) and can be discharged from the process chamber (28). A revision system (72) is provided, through which flow chambers (50) of flow channels (48) are accessible through the housing (12).

A method and apparatus closing a slag doorway and cleaning the slag doorway and channel of a metallurgical furnace including walls defining a slag doorway and a slag channel that crosses the slag doorway and has a bottom. The apparatus includes a support structure associable with the furnace, at least one slag-breaking body including a lower border that, under mounting conditions of the apparatus on the furnace, is directed towards the bottom and at a definable height, the slag-breaking body being associated with the support structure in a movable manner along the slag channel away and/or towards the slag doorway to wipe, with its lower border, the bottom or a parallel plane, and a vibrating or oscillating mechanism associated with the slag-breaking body to confer a vibrating or oscillating movement with non null component incident the bottom, during a travel performed during its movement away or towards the slag doorway.

A system and/or method for heat treatment of substrates. The system includes a housing that defines a heating chamber and a door assembly that encloses an opening of the heating chamber. The door assembly may be opened and closed. When opened, the door assembly defines a loading slot for loading substrates into and unloading substrates from the heating chamber. The door assembly is coupled to a first actuator and a control unit is coupled to the actuator to move the door assembly between a plurality of loading positions. The system may also include a loading assembly mounted to the door assembly to facilitate insertion and removal of substrates from the heating chamber.

A sample heating device includes: an opening/closing cover provided to be movable in a horizontal direction between a position above an opening of a mounting port and a position displaced from the position above the opening, and a cover sliding mechanism that is engaged with a part of a sample boat conveying portion when the sample boat conveying portion comes to a predetermined position in a horizontal plane and moves the opening/closing cover in the horizontal direction according to upward and downward movements of the sample boat conveying portion so that the opening/closing cover is provided at the position directly above the opening of the mounting port when the sample boat conveying portion comes to a predetermined height.

A mobile removable hearth skid for a furnace and/or cooling chamber including: a base, the base including a top horizontal surface supporting a refractory platform which possesses a perimeter edge including a front perimeter edge, a rear perimeter edge, and at least two side perimeter edges. The rear perimeter edge and the at least two side perimeter edges form a continuous shoulder extending beyond the base perimeter edge. Also disclosed is a furnace and/or cooling chamber including a refractory lining with a continuous ledge at the bottom edges of the refractory linings mounted on the rear wall and the at least two side walls. A gap is formed by the furnace supports between a bottom surface of the ledge and a surface supporting the furnace supports. The shoulder and ledge form a removable refractory seal.