Provided is a microwave plasma device, including: a hollow tube that is hollow and irradiated with a microwave; a swirl gas inlet that is located at a lower end portion of the hollow tube and injected with a swirl gas; an axial gas inlet that penetrates through the lower end portion of the hollow tube and injected with an axial gas; and a swirl gas barrier that is located inside the hollow tube, located near where the swirl gas is injected, and extends in a longitudinal direction of the hollow tube, in which a gap g is formed between the swirl gas barrier and the hollow tube, and plasma is generated inside the hollow tube and nitrogen oxide is generated inside the hollow tube.

The embodiments disclosed herein are directed to systems, methods, and devices for producing materials having desired characteristics using microwave plasma. In some embodiments, performing an iterative process may be used to produce a material having desired characteristics, the process comprising forming a microwave plasma within the reaction chamber, analyzing the plasma to determine if properties of the plasma are within a range expected to produce the desired characteristics of the material; and adjusting, based on the analysis of the plasma, one or more parameters. In some embodiments, an extension tube is provided within a microwave plasma apparatus to extend the length of a microwave plasma.

An apparatus for depolymerization of polymers, in particular polyesters, polyamides, polyurethanes and polycarbonates, comprises a microwave depolymerization reactor having a reaction chamber; a microwave generation and transport system to send microwaves into the reaction chamber and comprising a microwave generator and a guide device housed in the reaction chamber to convey and distribute microwaves in the reaction chamber; a mixing device, rotating around the axis in the reaction chamber and configured so as to dynamically distribute inside the reaction chamber a mixture of liquids and solids contained in the reaction chamber; and a pressurization system configured to vary the pressure within the reaction chamber.

The present disclosure provides an opening-closing type microwave catalytic reaction apparatus, including a microwave system, a microwave cavity, a protective cover, a cooling system, and a vertical furnace tube, where two ends of the furnace tube are respectively stretched out of the microwave cavity, the microwave system includes a plurality of microwave transmitting units, and the microwave transmitting unit includes a microwave transmitter; the furnace tube is provided with a gas inlet on a top and a gas outlet on a bottom; a compression hinge and a cavity cover capable of being opened or closed are arranged on the microwave cavity, a convex edge plate is disposed at an edge of the cavity cover, the compression hinge can compress the cavity cover such that the convex edge plate is tightly attached to a concave edge plate on the microwave cavity, and the protective cover can cover the entire cavity cover.

Disclosed apparatuses, systems, and materials relate to the disassociation of feedstock species (such as those in gaseous form) into constituent components, and may include an energy generator configured to provide a microwave energy. A first chamber defines a first volume and is configured to guide the microwave energy along the first chamber as a sinusoidal wave having an energy maxima at a point along the first chamber. A second chamber contains a plasma plume and is positioned substantially proximal to the first chamber, and is configured to enable propagation of the microwave energy through the first chamber and the second chamber such that the microwave energy demonstrates, at a radial center of the second chamber, a coaxial energy maxima configured to ignite the plasma plume contained in the second chamber. Carbon-containing materials may be formed by controlling flow parameters of the feedstock species into the first or second chamber.

The present disclosure provides an opening-closing type microwave catalytic reaction apparatus, including a microwave system, a microwave cavity, a protective cover, a cooling system, and a vertical furnace tube, where two ends of the furnace tube are respectively stretched out of the microwave cavity, the microwave system includes a plurality of microwave transmitting units, and the microwave transmitting unit includes a microwave transmitter; the furnace tube is provided with a gas inlet on a top and a gas outlet on a bottom; a compression hinge and a cavity cover capable of being opened or closed are arranged on the microwave cavity, a convex edge plate is disposed at an edge of the cavity cover, the compression hinge can compress the cavity cover such that the convex edge plate is tightly attached to a concave edge plate on the microwave cavity, and the protective cover can cover the entire cavity cover.

A system for producing carbonaceous materials is disclosed that includes an energy source configured to emit microwave energy and a plasma reactor coupled to receive the microwave energy and configured to produce plasma in response to exposure of one or more process gases to the microwave energy. In some instances, the plasma reactor includes a first chamber having a rectangular cross-section and configured to receive the microwave energy from the energy source as sinusoidal waveform, a second chamber having a cylindrical cross-section and configured to receive microwave energy from the first chamber as a radial waveform having an energy maxima at a radial center of the cylindrical cross-section, the second chamber including an opening to receive one or more process gases and configured to ignite a plasma plume, and a gas-solid separator configured to separate solid materials from the plasma plume.

A non-thermal plasma is generated to selectively convert a precursor to a product. More specifically, plasma forming material and a precursor material are provided to a reaction zone of a vessel. The reaction zone is exposed to microwave radiation, including exposing the plasma forming material and the precursor material to the microwave radiation. The exposure of the plasma forming material to the microwave radiation selectively converts the plasma forming material to a non-thermal plasma including formation of one or more streamers. The precursor material is mixed with the plasma forming material and the precursor material is exposed to the non-thermal plasma including exposing the precursor material to the one or more streamers. The exposure of the precursor material to the streamers and the microwave radiation selectively converts the precursor material to a product.

An apparatus for processing graphite particles is disclosed. The apparatus may comprise an electromagnetic radiation emitting device including a microwave device coupled to the reaction chamber for the creation of electromagnetic waves, the electromagnetic waves comprising microwaves. The apparatus may also comprise an inlet attached to the reaction chamber for introducing graphite particles, and an outlet attached to the reaction chamber for allowing processed graphite particles to exit the reaction chamber. The graphite particles in the reaction chamber thermally altered by exposure to the electromagnetic radiation such that the graphite particles are heated

The present invention relates to a pressure vessel system (1), comprising: —a pressure vessel (2) having a reaction chamber (3) in the form of a pressure chamber for initiating and/or promoting chemical and/or physical pressurized reactions of samples (P) received in the reaction chamber (3); and —a rail (50), which is rigidly connected to one pail of the pressure vessel (2) and has a first connection point (51) for admitting fluid, a second connection point (52) for discharging fluid and a fluid line (53), which fluidically connects the first connection point (51) to the second connection point (52), the fluid line (53) being fluidically connected to the reaction chamber (3) via the second connection point (52), and the rail (50) comprising at least one third connection point (55), which is fluidically connected to the fluid line (53) and can be connected to a device (56) such that the device (56) is fluidically connected to the fluid line (53) and thus to the reaction chamber (3).