The present invention relates to an advanced system for the removal of air pollutants from combustion and non-combustion processes that generate air pollutants that are regulated by environmental agencies. The pollutants include, but are not limited to, particulate matter; acid gases including sulphur dioxide, hydrogen chloride and hydrogen fluoride; metals such as mercury, dioxins, VOCs and reagents such as ammonia. The system collects and processes the polluted gas stream through two forms of wet method scrubbing technology. The gas is first passed through a wet scrubbing reactor capable of complete interaction between the gas and the selected liquid scrubbing reagent at one or more interfaces. The scrubbing medium is selected for its reactivity with the pollutants targeted in the process, its cost and impact on the environment. From the exit of the scrubbing reactor the gas is directed through a wet electrostatic precipitator to remove the remaining targeted pollutants to very high removal efficiency.

The present invention relates to an advanced system for the removal of air pollutants from combustion and non-combustion processes that generate air pollutants that are regulated by environmental agencies. The pollutants include, but are not limited to, particulate matter; acid gases including sulphur dioxide, hydrogen chloride and hydrogen fluoride; metals such as mercury, dioxins, VOCs and reagents such as ammonia. The system collects and processes the polluted gas stream through two forms of wet method scrubbing technology. The gas is first passed through a wet scrubbing reactor capable of complete interaction between the gas and the selected liquid scrubbing reagent at one or more interfaces. The scrubbing medium is selected for its reactivity with the pollutants targeted in the process, its cost and impact on the environment. From the exit of the scrubbing reactor the gas is directed through a wet electrostatic precipitator to remove the remaining targeted pollutants to very high removal efficiency.

The invention relates to a housing (1) for a wet electrostatic precipitator (100), comprising an inlet (2) and an outlet (3) for an exhaust gas stream and a base body (4) which is designed as an elongated hollow body, said housing being made of plastic or a plastic-containing material, wherein the inlet (2) and the outlet (3) are spaced apart from one another in the direction of the longitudinal extension of the base body (4). According to the invention, the base body (4) has a plurality of connecting points (5) which are arranged in a distributed manner over the outer periphery of the base body (4) and are designed for securing tie-rod elements or other connecting elements transmitting tensile forces. The invention further relates to a wet electrostatic precipitator (100) having a housing (1) of said type.

The invention relates to a housing (1) for a wet electrostatic precipitator (100), comprising an inlet (2) and an outlet (3) for an exhaust gas stream and a base body (4) which is designed as an elongated hollow body, said housing being made of plastic or a plastic-containing material, wherein the inlet (2) and the outlet (3) are spaced apart from one another in the direction of the longitudinal extension of the base body (4). According to the invention, the base body (4) has a plurality of connecting points (5) which are arranged in a distributed manner over the outer periphery of the base body (4) and are designed for securing tie-rod elements or other connecting elements transmitting tensile forces. The invention further relates to a wet electrostatic precipitator (100) having a housing (1) of said type.

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.

In a method and device for separating components in a corona discharge zone an air stream containing water molecules is passed between at least one ionizing electrode and at least one non-ionizing electrode; and high voltage is applied to the electrodes to create a corona discharge zone consisting of a plasma region wherein ozone is formed and a dark region where predominantly hydrogen peroxide is formed. The air flow entering the corona discharge zone is divided into two separate air flows, a first of which passes through the corona discharge plasma region, and a second of which passes through the dark corona discharge region; and a negative pressure gradient is applied to the plasma region only so as to remove the ozone and thereby separate the ozone from the hydrogen peroxide.

In a method and device for separating components in a corona discharge zone an air stream containing water molecules is passed between at least one ionizing electrode and at least one non-ionizing electrode; and high voltage is applied to the electrodes to create a corona discharge zone consisting of a plasma region wherein ozone is formed and a dark region where predominantly hydrogen peroxide is formed. The air flow entering the corona discharge zone is divided into two separate air flows, a first of which passes through the corona discharge plasma region, and a second of which passes through the dark corona discharge region; and a negative pressure gradient is applied to the plasma region only so as to remove the ozone and thereby separate the ozone from the hydrogen peroxide.

An air purifier is provided, including a box body and a filter screen inside the box body, an air suction device, a water mist generator, the water mist generator being disposed at one side of the filter screen, the air suction device being configured to inhale outdoor air into an interior of the box body, and the water mist generator being configured to form an ionized water layer.

An air purifier is provided, including a box body and a filter screen inside the box body, an air suction device, a water mist generator, the water mist generator being disposed at one side of the filter screen, the air suction device being configured to inhale outdoor air into an interior of the box body, and the water mist generator being configured to form an ionized water layer.