A closure mechanism to inhibit escape of heat from an oven chamber of a conveyor oven having a conveyor hanger. The closure mechanism includes a plurality of plates configured to couple to a first and second pluralities of connection tabs of a conveyor oven. Each of the plurality of plates include a connection portion, an angled portion configured to extend downward from the connection portion within a slot of the conveyor oven and an engagement portion extending downward from the angled portion to form an engagement surface.

A heat treatment system may include a heat treatment furnace; a supply device; a stack device configured to stack saggars in an up-down direction; a first conveyor configured to convey the saggars to the heat treatment furnace; an unstack device configured to unstack the stacked saggars; a recovery device; and a second conveyor configured to convey the saggars from the heat treatment furnace to the unstack device. At least one of the recovery device and the supply device may include at least a first conveyor mechanism and a second conveyor mechanism. The recovery device may further include a first recovery unit disposed on the first conveying path and a second recovery unit disposed on the second conveying path, or the supply device may further include a first supply unit disposed on the first conveying path and a second supply unit disposed on the second conveying path.

A heat treatment system may include a heat treatment furnace configured to heat treat a material in a saggar, the saggar including a saggar body and a lid; a lid removing device configured to remove the lid from the saggar; a body conveyor configured to convey the saggar body; a lid conveyor configured to convey the lid; a recovery device configured to recover the material from the saggar body; a supply device configured to supply a non-heat-treated material to the saggar body; and a lid attaching device configured to attach the lid to the saggar body. A conveying time for the lid to be conveyed from an entrance to an exit of a conveying path of the lid conveyor may be shorter than a conveying time for the saggar body to be conveyed from an entrance to an exit of a conveying path of the body conveyor.

An apparatus, a process and a system for treating petroleum coke are provided. The apparatus includes an activation unit that is an annular furnace reactor. The system includes a first reactor, the apparatus as a second reactor, a washing and separating unit, a cooling unit, a dissolving and separating unit, a washing and drying unit, optionally a regenerating unit, optionally a drying and calcining unit and optionally an evaporation-crystallization unit. The process for producing carbon materials uses the system for treating petroleum coke. The apparatus, the process and the system can achieve continuous production, and have advantages of high activation efficiency and stable properties of the resultant carbon material products.

A system for melting a pelleted charge material including a furnace having a feed end configured to receive a solid pelleted charge material and a discharge end opposite the feed end configured to discharge a molten charge material and a slag, a conveyor configured to feed the pelleted charge material into the feed end of the furnace, at least one oxy-fuel burner positioned to direct heat into a melting zone near the feed end to heat and at least partially melt the pelleted charge material to form the molten charge material and slag, wherein the oxy-fuel burner uses an oxidant having at least 70% molecular oxygen, and at least one flue for exhausting burner combustion products from the furnace.

A kiln for firing ceramic slabs (T) comprising: a heating module (2), a firing module (3), a cooling module (4), consecutively connected to each other along an advancement direction (Y) of the slabs (L), which define a process chamber (C) provided with an inlet opening (A) and an outlet opening (B); a transport system (T1, T2) arranged along the process chamber (C) from the inlet opening to the outlet opening, structured to transport the slabs (L) along the advancement direction (Y) the process chamber (C) comprises at least a first channel (C1) and at least a second channel (C2), thermally isolated from one another, cach of which extends along the advancement direction (Y) from the inlet opening (A) to the outlet opening (B); the transport system (T1, T2) comprises at least a first line (T1) and at least a second line (T2), respectively arranged along the first channel (C1) and along the second channel (C2) from the inlet opening (A) to the outlet opening (B).

A sintering furnace can have a housing, one or more heating elements, and a conveying assembly. Each heating element can be disposed within the housing and can subject a heating zone to a thermal shock temperature profile. A substrate with one or more precursors thereon can be moved by the conveying assembly through an inlet of the housing to the heating zone, where it is subjected to a first temperature of at least 500? C. for a first time period. The conveying assembly can then move the substrate with one or more sintered materials thereon from the heating zone and through an outlet of the housing.

Disclosed is a thermal reduction apparatus. The thermal reduction apparatus according to the exemplary embodiment includes: a preheating unit which preheats a to-be-reduced material and loads the to-be-reduced material into a reducing unit; the reducing unit which is connected to the preheating unit and in which a thermal reduction reaction of the to-be-reduced material occurs; a cooling unit which is connected to the reducing unit and from which the to-be-reduced material flowing into the cooling unit is unloaded to the outside; a gate device which is installed between the preheating unit and the reducing unit; a gate device which is installed between the reducing unit and the cooling unit; a condensing device which is connected to the reducing unit and condenses a metal vapor; a first blocking unit which is installed in the reducing unit; and a second blocking unit which is installed in the reducing unit so as to be spaced apart from the first blocking unit.

A disclosed method includes serially moving a plurality of dies through a series of interconnected chambers that are selectively sealable from each other. Through the series of interconnected chambers, each of the dies is introduced into a controlled gas environment, each of the dies is introduced into a controlled temperature environment, a process-environment-sensitive material is pressurized in each of the dies, and each of the dies is cooled. A disclosed apparatus includes a series of interconnected chambers that are selectively sealable from each other. A first one of the chambers is configured to establish a controlled gas environment therein, a second one of the chambers is configured to establish a controlled temperature environment therein, a third one of the chambers is configured to pressurize a process-environment-sensitive material and a fourth one of the chambers is configured to cool the process-environment-sensitive material.

In the present disclosure, a motor core can be degreased prior to straightening annealing without a heating device or a vacuum device dedicated to degreasing being provided. A heat treatment furnace according to an embodiment of the present disclosure includes a degreasing chamber for degreasing a motor core, a heating chamber with which the degreasing chamber directly communicates and which is configured to anneal the motor core that has passed through the degreasing chamber, by using a converted gas generated by a converted gas generation device, as an in-furnace atmosphere gas, and a gas flow formation section GF configured in such a manner that the converted gas in the heating chamber flows toward the degreasing chamber.