A biochar apparatus and a related biochar module may have a horizontal table-shaking mechanism and a tapered channel for causing biochar pieces generated in a firebox to fall through openings in the table to a conveyor system below. The table may be configured with replaceable grate panels. A quenching reservoir pan for holding quenching liquid receives a drainage basket at a discharge end of the conveyor system for quenching hot pieces of biochar and allowing easy retrieval of the quenched pieces.

Disclosed is a coupling system of biomass gasification and waste incineration. A carbon pipeline is communicated between a biomass carbon outlet of a circulating fluidized bed gasifier and an activated carbon injection port of a waste incineration assembly. The activated carbon generated by reaction in the circulating fluidized bed gasifier is sent to the activated carbon injection port through the carbon pipeline to capture harmful substances containing heavy metals and dioxins in flue gas generated by the waste incineration assembly. According to the present application, the activated carbon generated by the circulating fluidized bed gasifier is supplied to the waste incineration assembly, and a mutual coupling between the circulating fluidized bed gasifier and the waste incineration assembly is thereby realized, thus reducing the amount of the activated carbon additionally supplied to the wasted incineration assembly.

A bulk material comprising at least one substance to be removed from the bulk material is treated. The method includes introducing the bulk material into a heating chamber. The heating chamber is in a partial vacuum. The method further includes heating the bulk material in the heating chamber and in the presence of the partial vacuum to cause the at least one substance to vaporize. The method further includes extracting the bulk material, with the at least one vaporized substance separated therefrom, from the heating chamber.

A bulk material comprising at least one substance to be removed from the bulk material is treated. The method includes introducing the bulk material into a heating chamber. The heating chamber is in a partial vacuum. The method further includes heating the bulk material in the heating chamber and in the presence of the partial vacuum to cause the at least one substance to vaporize. The method further includes extracting the bulk material, with the at least one vaporized substance separated therefrom, from the heating chamber.

An apparatus comprises a vessel having an interior chamber formed by a vessel wall. The vessel wall comprises a double-walled structure having an inner wall and an outer wall. A moveable lid is configured to form an airtight seal with the interior chamber in a closed position. A basket is positioned within the chamber. One or more vibration devices, such as transducers, are attached to the basket, and are configured to shake the mesh basket to cause decomposed material to fall through the mesh basket to a reactor vessel floor. A heating coil is positioned within the chamber and surrounding the basket. The heating coil is configured to heat the basket using induction heating. An airtight space is formed between the inner wall and the outer wall and is filled with a gas. The temperature within the chamber may be lowered by cooling the gas.

A grate line bordering element for a combustion grate for burning waste, including a channel element and a channel covering for covering the element including at least one covering element and one termination element with a locking device; wherein the termination element has a support surface which points away from the channel element and a first engaging element which is oriented towards the covering element; the covering element has a support surface which points away from the channel element, a retaining element which is oriented towards the channel element, a second engaging element which is oriented towards the termination element and is configured to receive the first engaging element, and a cut-out which is oriented towards the termination element for receiving the locking device of the closure element; and wherein the locking device is configured in such a way that it locks the termination element releasably in the channel element.

Various implementations include a combustor system including an inner wall, a fuel grate, an ash grinder, an igniter, and a fan. The inner wall defines a combustion chamber and has a longitudinal axis and first and second ends. The inner wall defines primary and secondary air inlets. The primary air inlets are defined closer than the secondary air inlets to the first end. The fuel grate is disposed within the combustion chamber between the primary and secondary air inlets and is configured to support fuel disposed within the combustion chamber. The ash grinder is disposed between the fuel grate and the secondary air inlets and is rotatable about the longitudinal axis relative to the fuel grate. The igniter provides energy to the combustion chamber. The fan is configured to cause air to flow from the primary and secondary air inlets through the second end of the combustion chamber.

An incineration system is adapted for burning an incineration matter, and for generating a regenerative matter by hydrolyzing a hydrolysis matter. The incineration system includes an incineration device, a boiler device, a power generating device, and a thermal hydrolysis device. The incineration device includes an incinerator that is adapted for receiving the incineration matter and for burning the incineration matter to thereby generate heated air. The boiler device receives the heated air from the incinerator and generates steam via the heated air. The power generating device receives the steam from the boiler device to generate electric power. The thermal hydrolysis device includes a tank that is adapted for receiving the hydrolysis matter and the steam. The thermal hydrolysis device is adapted for hydrolyzing the hydrolysis matter via the steam, for generating the regenerative matter by hydrolyzing the hydrolysis matter, and for outputting the regenerative matter.

The present invention discloses an industrial solid waste incinerator and flue gas treatment apparatus, comprising a water-cooled feed hopper, a water-cooled grate and a chamber which are connected in sequence. A front arch, a rear arch and side walls which are formed of membrane water-cooled walls, are provided between the water-cooled grate and the chamber, and a dechlorination tower is arranged behind the chamber. Two sets of rear secondary air pipes, which comprise an upper set of rear secondary air pipes and a lower set of rear secondary air pipes, are arranged on the rear arch, and a dry desulfurization device is arranged between the two sets of rear secondary air pipes, so that the reaction medium and the flue gas are sufficiently disturbed and mixed, and stroke is extended.

A hybrid feeding device for automatically adjusting a co-firing amount of decaying garbage. The device comprises a mechanical grate furnace, a hybrid garbage conveying device, a raw garbage feeding device, a decaying garbage feeding device, a hybrid garbage crushing device, and a control center. The raw garbage feeding device, the decaying garbage feeding device, and the hybrid garbage conveying device are all connected to the control center. The decaying garbage feeding device is used for transporting decaying garbage to the raw garbage feeding device. The raw garbage feeding device is positioned between the decaying garbage feeding device and the hybrid garbage conveying device. The hybrid garbage crushing device is used for crushing garbage and inputting the garbage to the mechanical grate furnace. The mechanical grate furnace is internally provided with a plurality of temperature sensors, and the plurality of temperature sensors are connected to the control center.