An electric dust collecting device is provided. The electric dust collecting device according to an embodiment includes a mixing part into which outside air flows, an electrostatic sprayer configured to spray droplet charged to the mixing part to be combined with contaminants contained in outside air, a dust collecting part configured to form an electric field and adsorb droplet combined with contaminants, and a draining part combined with the dust collection part to discharge the droplet adsorbed in the dust collecting part.

An apparatus and method for purification of air, is disclosed. The apparatus includes: (a) a mist generator, is configured to generate water micro droplets, (b) a charging chamber, is configured to transfer electric charges to the micro droplets, (c) an interacting space is configured to act as a physical barrier and provide sufficient space for adsorption of air pollutants, (d) a collecting chamber is configured to collect the contaminated micro droplets and convert them to a liquid form, (e) and a water recycling section, is configured to remove the contaminations and provide a usable clean water for the mist generator. The collecting chamber of the apparatus is incorporated with a plastic grid enhanced with surface modified nanofibers to promote the micro droplet collecting efficiency. Further, a method of fabricating a plastic grid enhanced with surface modified nanofibers for an air purifier apparatus is also disclosed.

An apparatus and method for purification of air, is disclosed. The apparatus includes: (a) a mist generator, is configured to generate water micro droplets, (b) a charging chamber, is configured to transfer electric charges to the micro droplets, (c) an interacting space is configured to act as a physical barrier and provide sufficient space for adsorption of air pollutants, (d) a collecting chamber is configured to collect the contaminated micro droplets and convert them to a liquid form, (e) and a water recycling section, is configured to remove the contaminations and provide a usable clean water for the mist generator. The collecting chamber of the apparatus is incorporated with a plastic grid enhanced with surface modified nanofibers to promote the micro droplet collecting efficiency. Further, a method of fabricating a plastic grid enhanced with surface modified nanofibers for an air purifier apparatus is also disclosed.

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 volumes of airflow. 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 inject electrically charged carbon capture fluid throughout the interior of the system. The fluid interacts and then combines with air and as a result, large amounts of carbon dioxide are captured within the system. The finer the particulate of carbon capture fluid, the larger the volume ratio which results in an efficient carbon capture system.

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 volumes of airflow. 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 inject electrically charged carbon capture fluid throughout the interior of the system. The fluid interacts and then combines with air and as a result, large amounts of carbon dioxide are captured within the system. The finer the particulate of carbon capture fluid, the larger the volume ratio which results in an efficient carbon capture system.

Provided is a solvent separation method and a solvent separation apparatus that make it possible to efficiently retrieve the thermal energy possessed by an exhaust atmosphere released in a solvent-removal step to suppress reductions in a temperature of the exhaust atmosphere. In the solvent separation method and the solvent separation apparatus, a vaporized solvent is removed from a gas while heat exchange between the gas within a condensation part and the gas within a dust-collection part is conducted by using a heat exchange part that is placed between the condensation part that introduces the gas into a first direction and the dust-collection part that introduce the gas into a second direction opposite to the first direction the gas discharged from a downstream side of the condensation part.

A surface condensation process and device for efficiently removing coal combustion fly ash micro spheres are provided. The device is comprised of a patterned-plate type atomizer, a flow meter, an ultrasonic drive power source, an automatic temperature controller, a heat-tracing pipeline, a condensation sleeve, an electrically heated water storage tank, a water pump and an electrostatic precipitator.

A surface condensation process and device for efficiently removing coal combustion fly ash micro spheres are provided. The device is comprised of a patterned-plate type atomizer, a flow meter, an ultrasonic drive power source, an automatic temperature controller, a heat-tracing pipeline, a condensation sleeve, an electrically heated water storage tank, a water pump and an electrostatic precipitator.

A dust-containing gas treatment apparatus includes a cylindrical treatment room configured to introduce gas containing dust and remove the dust from the gas, a catcher including a brush with hair planted in a support in the cylindrical treatment room and configured to catch the dust contained in the gas, a liquid sprayer in the cylindrical treatment room, a rotary driver configured to rotate the catcher and a stirrer, a gas introduction portion configured to introduce the gas containing the dust, a gas discharge portion configured to discharge the gas and the removed dust from the cylindrical treatment room, and a liquid discharge portion configured to discharge a liquid containing the removed dust.

A dust-containing gas treatment apparatus includes a cylindrical treatment room configured to introduce gas containing dust and remove the dust from the gas, a catcher including a brush with hair planted in a support in the cylindrical treatment room and configured to catch the dust contained in the gas, a liquid sprayer in the cylindrical treatment room, a rotary driver configured to rotate the catcher and a stirrer, a gas introduction portion configured to introduce the gas containing the dust, a gas discharge portion configured to discharge the gas and the removed dust from the cylindrical treatment room, and a liquid discharge portion configured to discharge a liquid containing the removed dust.