An electrostatic filter, for filtering solid and liquid particles in gases composed of a case (3); concentric collectors (15), concentric diffusers (10); electrodes (2); insulated supports (7), distributor disc (8), thermal insulator (17), electrical resistors (4), main collector (9), filter cap (1); the concentric diffusers (10) host along their internal and external wall the electrodes (2); the insulated supports connect the filter cap (1) to the distributor disc (8) which in turn supports the concentric diffusers (10); the electrical resistors (4) are located around the case (3) as clamps and are covered by the thermal insulator (17); so that the gas flows through the filter from the filter inlet (14) located tangentially at the external face of the case (3), towards the insulated outlet (5) located in the central part between the distributor disc (8) and the filter cap (1), thus optimizing the space and surface of the constituent materials and a very high filtration efficiency of liquid and solid micron particles contained in gases at any temperature up to 900 C.

A gas purifying apparatus has: a compressing unit for corn pressing a gas in which an atmosphere or inert gas and a substance vaporized by heating have been mixed; and an expanding unit for liquefying the substance by expanding the gas compressed by the compressing unit, wherein the gas in which the substance has been reduced is obtained

A carbon capture system using an efficient method of capturing carbon dioxide is disclosed herein. The carbon capture system described is scalable in shape and size and can be adjusted to achieve different volumetric airflow rates. This method is efficient due to the maximum surface area to volume ratio achievable in a carbon capture system with the distribution of equally or randomly spaced spray nozzles configured to distribute carbon capture substance throughout the interior of the system. The substance interacts with air and absorbs carbon dioxide, as a result, large amounts of carbon dioxide are captured within the system. The system gains further efficiency by filtering the carbon capture substance laden with carbon dioxide through one or more separating elements in conjunction with one or more air moving elements, designed to maximize the flow of air through the separating element while simultaneously maximizing the ability to separate carbon capture substance from the air before exiting the system. The carbon capture system may or may not reuse carbon capture substance to minimize waste.

A carbon capture system using an efficient method of capturing carbon dioxide is disclosed herein. The carbon capture system described is scalable in shape and size and can be adjusted to achieve different volumetric airflow rates. This method is efficient due to the maximum surface area to volume ratio achievable in a carbon capture system with the distribution of equally or randomly spaced spray nozzles configured to distribute carbon capture substance throughout the interior of the system. The substance interacts with air and absorbs carbon dioxide, as a result, large amounts of carbon dioxide are captured within the system. The system gains further efficiency by filtering the carbon capture substance laden with carbon dioxide through one or more separating elements in conjunction with one or more air moving elements, designed to maximize the flow of air through the separating element while simultaneously maximizing the ability to separate carbon capture substance from the air before exiting the system. The carbon capture system may or may not reuse carbon capture substance to minimize waste.

An air purifier includes an air inlet through which contaminated air is introduced, a plasma reaction unit connected in fluid communication with the air inlet and including a predetermined discharge region generating discharge plasma, and a dust collector that is connected in fluid communication with the plasma reaction unit and collects and removes contaminants from first purified air discharged from the plasma reaction unit.

An air purifier includes an air inlet through which contaminated air is introduced, a plasma reaction unit connected in fluid communication with the air inlet and including a predetermined discharge region generating discharge plasma, and a dust collector that is connected in fluid communication with the plasma reaction unit and collects and removes contaminants from first purified air discharged from the plasma reaction unit.

Provided are a solvent separation method, a solvent separation apparatus, and a solvent separation system that make it possible to easily collect a solvent removed from an exhaust atmosphere and that make it possible to easily carry out maintenance of exhaust gas pathways. An impeller placed in a storage space of a casing is rotated to introduce a gas including a volatilized solvent from an inlet of the casing into the storage space, and the volatilized solvent is cooled and devolatilized by a collection face that has been cooled so as to have a surface temperature lower than the temperature of the gas, to thereby separate the solvent from the gas.

Provided are a solvent separation method, a solvent separation apparatus, and a solvent separation system that make it possible to easily collect a solvent removed from an exhaust atmosphere and that make it possible to easily carry out maintenance of exhaust gas pathways. An impeller placed in a storage space of a casing is rotated to introduce a gas including a volatilized solvent from an inlet of the casing into the storage space, and the volatilized solvent is cooled and devolatilized by a collection face that has been cooled so as to have a surface temperature lower than the temperature of the gas, to thereby separate the solvent from the gas.

A gas treatment includes: a gas scrubber chamber operable to receive an effluent gas stream originating from a manufacturing process tool to be scrubbed therewithin to provide a scrubbed gas stream; and an electrostatic precipitation chamber operable to receive the scrubbed gas stream to be treated therewithin to provide a treated gas stream, one of the gas scrubber chamber and the electrostatic precipitation chamber defining a first chamber and another of the gas scrubber chamber and the electrostatic precipitation chamber defining a second chamber, the first chamber being configured to surround the second chamber. In this way, the first chamber and the second chamber can share the same volume.

A gas treatment includes: a gas scrubber chamber operable to receive an effluent gas stream originating from a manufacturing process tool to be scrubbed therewithin to provide a scrubbed gas stream; and an electrostatic precipitation chamber operable to receive the scrubbed gas stream to be treated therewithin to provide a treated gas stream, one of the gas scrubber chamber and the electrostatic precipitation chamber defining a first chamber and another of the gas scrubber chamber and the electrostatic precipitation chamber defining a second chamber, the first chamber being configured to surround the second chamber. In this way, the first chamber and the second chamber can share the same volume.