A system for controlling an electrostatic precipitator includes a computer control system with a computer and a controller in operative communication with an electrostatic precipitator. The computer control system is operative to control performance of the electrostatic precipitator by controlling one or more of: a) a power supply that controls voltage between an electrically grounded vertical plate and a metallic wire electrode in the electrostatic precipitator; b) a first feeder valve and a second feeder valve in a hopper; and c) a power supply to an electrical coil in operative communication with a rapper.

A method for reducing dust removal electric field couplings includes the following steps: selecting a ratio between a dust collection area of a dust removal electric field anode and a discharge area of a dust removal electric field cathode to be 1.667:1-1680:1. A dust removal electric field anode and/or dust removal electric field cathode size is selected so that the number of electric field couplings is less than or equal to 3. The number of electric field couplings is reduced, electric field energy consumption is low, electric field coupling consumption for an aerosol, water mist, oil mist and loose smooth particulate matter is reduced, and electric field energy is saved.

Disclosed herein are embodiments of an invention relating to pathogen transfer mitigation and prevention apparatuses. Described herein are embodiments comprising one or more charged particle emitters, collectors, power circuits, and controllers. The invention described herein can effectively, for example, prevent, stop, and/or minimize the transfer of pathogens such as, for example, viruses, bacteria, fungi, protozoa, and/or worms. The invention described herein has application in many fields, including, for example, the agriculture, restaurant, food, livestock, pet, sports, entertainment, travel, and/or transportation industries. The invention described herein is of particular relevance given the recent and ongoing international coronavirus disease (COVID) pandemic.

Disclosed herein are embodiments of an invention relating to pathogen transfer mitigation and prevention apparatuses. Described herein are embodiments comprising one or more charged particle emitters, collectors, power circuits, and controllers. The invention described herein can effectively, for example, prevent, stop, and/or minimize the transfer of pathogens such as, for example, viruses, bacteria, fungi, protozoa, and/or worms. The invention described herein has application in many fields, including, for example, the agriculture, restaurant, food, livestock, pet, sports, entertainment, travel, and/or transportation industries. The invention described herein is of particular relevance given the recent and ongoing international coronavirus disease (COVID) pandemic.

An air blower device of an air-conditioning system for a vehicle including: a blower case including a duct part having an indoor air inlet and an outdoor air inlet, an air blowing part connected with an inlet of an air-conditioning case and a connection part for connecting the duct part with the air blowing part, the connection part having an insertion part of which the certain area is hollowed; an indoor and outdoor air converting door disposed inside the duct part of the blower case to open and close the indoor air inlet and the outdoor air inlet; an air blower is disposed inside the air blowing part of the blower case to forcedly blow air; an electric dust collector located at the connection part through the insertion part of the blower case; and a cover for opening and closing the insertion part of the blower case.

An air blower device of an air-conditioning system for a vehicle including: a blower case including a duct part having an indoor air inlet and an outdoor air inlet, an air blowing part connected with an inlet of an air-conditioning case and a connection part for connecting the duct part with the air blowing part, the connection part having an insertion part of which the certain area is hollowed; an indoor and outdoor air converting door disposed inside the duct part of the blower case to open and close the indoor air inlet and the outdoor air inlet; an air blower is disposed inside the air blowing part of the blower case to forcedly blow air; an electric dust collector located at the connection part through the insertion part of the blower case; and a cover for opening and closing the insertion part of the blower case.

An emitter to deliver an electron flow towards particulate matter includes a base, a conductive track fixed to the base, and a plurality of conductive pins fixed to the base and extending therefrom in a predetermined direction and electrically coupled to the track so as to receive a negative electric charge therefrom. The emitter also includes a plurality of tubes, fixed to the base, and extending therefrom in said direction, with each of the tubes having an interior extending away from the base to an open end, and with each tube having at least one of the pins located in the interior thereof.

An emitter to deliver an electron flow towards particulate matter includes a base, a conductive track fixed to the base, and a plurality of conductive pins fixed to the base and extending therefrom in a predetermined direction and electrically coupled to the track so as to receive a negative electric charge therefrom. The emitter also includes a plurality of tubes, fixed to the base, and extending therefrom in said direction, with each of the tubes having an interior extending away from the base to an open end, and with each tube having at least one of the pins located in the interior thereof.

An aerosol condensing system is provided. The aerosol condensing system includes a source electrode electrically connected to an electrical source that applies an electrical voltage to the source electrode, a condenser including a sink electrode to collect aerosol contained in an air stream to the sink electrode, and a duct configured to direct the aerosol to the condenser. The source electrode and the sink electrode creates an electrical field within the duct.

An aerosol condensing system is provided. The aerosol condensing system includes a source electrode electrically connected to an electrical source that applies an electrical voltage to the source electrode, a condenser including a sink electrode to collect aerosol contained in an air stream to the sink electrode, and a duct configured to direct the aerosol to the condenser. The source electrode and the sink electrode creates an electrical field within the duct.