There is disclosed a biochar processor for a continuous pyrolysis processing of organic material into biochar. In an embodiment, the biochar processor has a biochar processor interior space divided into a first combustion chamber and a second combustion chamber. A pyrolysis reactor passageway is disposed in the biochar processor interior space. The pyrolysis reactor tube has a conveyor drive to move the organic material from the first combustion chamber to the second combustion chamber. A vent tube is in communication with a plurality of vents in the first combustion chamber and the second combustion chamber. In an embodiment, a method of making a biochar processor is provided for the continuous pyrolysis of organic material into biochar. In an embodiment, a method of using a biochar processor is provided for continuously producing biochar from the biochar processor. Other embodiments are also disclosed.

There is disclosed a biochar processor for a continuous pyrolysis processing of organic material into biochar. In an embodiment, the biochar processor has a biochar processor interior space divided into a first combustion chamber and a second combustion chamber. A pyrolysis reactor passageway is disposed in the biochar processor interior space. The pyrolysis reactor tube has a conveyor drive to move the organic material from the first combustion chamber to the second combustion chamber. A vent tube is in communication with a plurality of vents in the first combustion chamber and the second combustion chamber. In an embodiment, a method of making a biochar processor is provided for the continuous pyrolysis of organic material into biochar. In an embodiment, a method of using a biochar processor is provided for continuously producing biochar from the biochar processor. Other embodiments are also disclosed.

Systems and apparatuses for controlling oven draft within a coke oven. A representative system includes an uptake damper coupled to an uptake duct that receives exhaust gases from the coke oven and provides the exhaust gases to a common tunnel for further processing. The uptake damper includes a damper plate pivotably coupled to a refractory surface of the uptake duct and an actuator assembly coupled to the damper plate. The damper plate is positioned completely within the uptake duct and the actuator assembly moves the damper plate between a plurality of different configurations by causing the damper plate to rotate relative to the uptake duct. Moving the uptake damper between the different configurations changes the flow rate and pressure of the exhaust gases through the uptake duct, which affects an oven draft within the coke oven.

Systems and apparatuses for controlling oven draft within a coke oven. A representative system includes an uptake damper coupled to an uptake duct that receives exhaust gases from the coke oven and provides the exhaust gases to a common tunnel for further processing. The uptake damper includes a damper plate pivotably coupled to a refractory surface of the uptake duct and an actuator assembly coupled to the damper plate. The damper plate is positioned completely within the uptake duct and the actuator assembly moves the damper plate between a plurality of different configurations by causing the damper plate to rotate relative to the uptake duct. Moving the uptake damper between the different configurations changes the flow rate and pressure of the exhaust gases through the uptake duct, which affects an oven draft within the coke oven.

Systems and apparatuses for controlling oven draft within a coke oven. A representative system includes an uptake damper coupled to an uptake duct that receives exhaust gases from the coke oven and provides the exhaust gases to a common tunnel for further processing. The uptake damper includes a damper plate pivotably coupled to a refractory surface of the uptake duct and an actuator assembly coupled to the damper plate. The damper plate is positioned completely within the uptake duct and the actuator assembly moves the damper plate between a plurality of different configurations by causing the damper plate to rotate relative to the uptake duct. Moving the uptake damper between the different configurations changes the flow rate and pressure of the exhaust gases through the uptake duct, which affects an oven draft within the coke oven.

Systems and apparatuses for controlling oven draft within a coke oven. A representative system includes an uptake damper coupled to an uptake duct that receives exhaust gases from the coke oven and provides the exhaust gases to a common tunnel for further processing. The uptake damper includes a damper plate pivotably coupled to a refractory surface of the uptake duct and an actuator assembly coupled to the damper plate. The damper plate is positioned completely within the uptake duct and the actuator assembly moves the damper plate between a plurality of different configurations by causing the damper plate to rotate relative to the uptake duct. Moving the uptake damper between the different configurations changes the flow rate and pressure of the exhaust gases through the uptake duct, which affects an oven draft within the coke oven.

There is disclosed a biochar processor for a continuous pyrolysis processing of organic material into biochar. In an embodiment, the biochar processor has a biochar processor interior space divided into a first combustion chamber and a second combustion chamber. A pyrolysis reactor passageway is disposed in the biochar processor interior space. The pyrolysis reactor tube has a conveyor drive to move the organic material from the first combustion chamber to the second combustion chamber. A vent tube is in communication with a plurality of vents in the first combustion chamber and the second combustion chamber. In an embodiment, a method of making a biochar processor is provided for the continuous pyrolysis of organic material into biochar. In an embodiment, a method of using a biochar processor is provided for continuously producing biochar from the biochar processor. Other embodiments are also disclosed.

There is disclosed a biochar processor for a continuous pyrolysis processing of organic material into biochar. In an embodiment, the biochar processor has a biochar processor interior space divided into a first combustion chamber and a second combustion chamber. A pyrolysis reactor passageway is disposed in the biochar processor interior space. The pyrolysis reactor tube has a conveyor drive to move the organic material from the first combustion chamber to the second combustion chamber. A vent tube is in communication with a plurality of vents in the first combustion chamber and the second combustion chamber. In an embodiment, a method of making a biochar processor is provided for the continuous pyrolysis of organic material into biochar. In an embodiment, a method of using a biochar processor is provided for continuously producing biochar from the biochar processor. Other embodiments are also disclosed.

A thermal cycle continuous automated coal pyrolyzing furnace, includes a furnace body, a coal feeding device, a preheating device, an inputting coal regulating bunker, an inputting coal cooling device, a coal pyrolyzation coking device, a coke modification device, a dry quenching device and a raw gas exporting device; wherein the coal feeding device, the pre-heating device, the inputting coal regulating bunker, the inputting coal cooling device, the coal pyrolyzation coking device, the coke modification device, the dry quenching device and the raw gas exporting device are all integrated on the furnace body; the coal pyrolyzation coking device includes a coking chamber, an external combustion gas heating device, an internal combustion gas heating device and a flame path bow. Utilizing the coal pyrolyzing furnace is capable of achieving continuously quenching, so as to improve quenching efficiency and decrease quenching cost.

A thermal cycle continuous automated coal pyrolyzing furnace, includes a furnace body, a coal feeding device, a preheating device, an inputting coal regulating bunker, an inputting coal cooling device, a coal pyrolyzation coking device, a coke modification device, a dry quenching device and a raw gas exporting device; wherein the coal feeding device, the pre-heating device, the inputting coal regulating bunker, the inputting coal cooling device, the coal pyrolyzation coking device, the coke modification device, the dry quenching device and the raw gas exporting device are all integrated on the furnace body; the coal pyrolyzation coking device includes a coking chamber, an external combustion gas heating device, an internal combustion gas heating device and a flame path bow. Utilizing the coal pyrolyzing furnace is capable of achieving continuously quenching, so as to improve quenching efficiency and decrease quenching cost.