A method for pressurized pyrolysis of biomass in a pressurized pyrolysis furnace, including: 1) crushing and screening biomass; collecting biomass having desired particle sizes; and delivering the biomass having desired particle sizes to a pulse-type feeding system; 2) transporting the biomass to a pyrolysis furnace via the pulse-type feeding system; synchronously initiating microwave and a plasma torch, the microwave producing a microwave field in the pyrolysis furnace, working gas of the plasma torch being ionized for the first time to produce plasma jet entering the pyrolysis furnace; and 3) allowing the syngas generated in 2) to continue moving upwards and introducing the syngas out from the top of the pyrolysis furnace; chilling the syngas; introducing the syngas to a cyclone separator to separate residues; and then cooling and purifying the syngas using a cooling device and a purifying device, respectively, to produce clean syngas.

A gasifier including a vertically disposed furnace body, a feeder disposed in a middle part of the furnace body and communicating with the furnace body, one or two layers of microwave plasma generators, an external heater configured to supply external thermal energy for the gasifier, and a monitoring unit. The furnace body includes an upper nozzle for spraying vapor, a lower nozzle for spraying CO.sub.2/vapor, a syngas outlet disposed at a top of the furnace body. The upper nozzle for spraying vapor is disposed in a clearance zone of the furnace body, and the lower nozzle for spraying CO.sub.2/vapor is disposed in a bed zone of the furnace body. The monitoring unit is disposed close to the syngas outlet. The one or two layers of microwave plasma generators are disposed above the upper nozzle in the clearance zone of the gasifier.

A gasifier including a vertically disposed furnace body, a feeder disposed in a middle part of the furnace body and communicating with the furnace body, one or two layers of microwave plasma generators, an external heater configured to supply external thermal energy for the gasifier, and a monitoring unit. The furnace body includes an upper nozzle for spraying vapor, a lower nozzle for spraying CO.sub.2/vapor, a syngas outlet disposed at a top of the furnace body. The upper nozzle for spraying vapor is disposed in a clearance zone of the furnace body, and the lower nozzle for spraying CO.sub.2/vapor is disposed in a bed zone of the furnace body. The monitoring unit is disposed close to the syngas outlet. The one or two layers of microwave plasma generators are disposed above the upper nozzle in the clearance zone of the gasifier.

A system and method of thermally processing carbonaceous materials, and especially sustainably cultivated woody biomass or cellulosic biomass sorted from municipal solid waste, to produce green fuel, such as diesel, sustainable aviation fuel and other beneficial by-products, including biochar. Synthesis gas is made by gasifying sustainably grown biomass, the thermal energy from which is used to create steam for treatment of biochar by-product to produce higher value activated carbon. Oxygen for the gasifier and hydrogen for a Fischer Tropsch (FT) or other catalytic synthesis stage of the process are generated by electrolysis of water using sustainably produced electricity. The gasification and electrolysis processes are operated to produce a 2:1 ratio of hydrogen to carbon monoxide needed for FT or other catalytic synthesis. The hydrocarbon product is distilled as required to produce either green alcohols or green diesel fuel and sustainable aviation fuel.

Gasifiers are disclosed that include multiple chambers, multiple microwave sources and multiple arc plasma torches. Such gasifiers may be configured to have a drain, an exhaust port and a path of fluid communication between the exhaust port and the drain. Under appropriate conditions, the gasifiers may eliminate undesired waste while at the same time delivering a significant net energy benefit to the operator of the gasifier.

A method and system for cost effectively converting a feedstock using thermal plasma, or other styles of gassifiers, into a feedwater energy transfer system. The feedstock can be any organic material, or fossil fuel. The energy transferred in the feedwater is converted into steam which is then injected into the low turbine of a combined cycle power plant. Heat is extracted from gas product issued by a gassifier and delivered to a power plant via its feedwater system. The gassifier is a plasma gassifier and the gas product is syngas. In a further embodiment, prior to performing the step of extracting heat energy, there is provided the further step of combusting the syngas in an afterburner. An air flow, and/or EGR flow is provided to the afterburner at a rate that is varied in response to an operating characteristic of the afterburner. The air flow to the afterburner is heated.

A method and system for cost effectively converting a feedstock using thermal plasma, or other styles of gassifiers, into a feedwater energy transfer system. The feedstock can be any organic material, or fossil fuel. The energy transferred in the feedwater is converted into steam which is then injected into the low turbine of a combined cycle power plant. Heat is extracted from gas product issued by a gassifier and delivered to a power plant via its feedwater system. The gassifier is a plasma gassifier and the gas product is syngas. In a further embodiment, prior to performing the step of extracting heat energy, there is provided the further step of combusting the syngas in an afterburner. An air flow, and/or EGR flow is provided to the afterburner at a rate that is varied in response to an operating characteristic of the afterburner. The air flow to the afterburner is heated.

Gasifiers are disclosed that include multiple chambers, multiple microwave sources and multiple arc plasma torches. Such gasifiers may be configured to have a drain, an exhaust port and a path of fluid communication between the exhaust port and the drain. Under appropriate conditions, the gasifiers may eliminate undesired waste while at the same time delivering a significant net energy benefit to the operator of the gasifier.

A system comprising a plasma assisted vitrifier (8) configured to produce vitrified product. A feed pipe (4) can be fluidly connected to the plasma assisted vitrifier (8). The feed pipe (4) can be configured to deliver a feedstock into the plasma assisted vitrifier. A heated combustion air conduit (34) can be fluidly connected to the plasma assisted vitrifier (8). A spinning fiberizer can be disposed next to the plasma assisted vitrifier (8) and configured to receive the vitrified product (24). An emissions attenuation device can be fluidly connected to the plasma-assisted vitrifier (8) and configured to treat gaseous emissions generated by the plasma-assisted vitrifier (8).

A system comprising a plasma assisted vitrifier (8) configured to produce vitrified product. A feed pipe (4) can be fluidly connected to the plasma assisted vitrifier (8). The feed pipe (4) can be configured to deliver a feedstock into the plasma assisted vitrifier. A heated combustion air conduit (34) can be fluidly connected to the plasma assisted vitrifier (8). A spinning fiberizer can be disposed next to the plasma assisted vitrifier (8) and configured to receive the vitrified product (24). An emissions attenuation device can be fluidly connected to the plasma-assisted vitrifier (8) and configured to treat gaseous emissions generated by the plasma-assisted vitrifier (8).