An air purifier device is disclosed. The device includes at least one first collector, an ionizing device configured to ionize fine particles in the air, an agglomeration chamber configured to aggregate the ionized fine particles, and a frame configured to enclose the ionizing device, agglomeration chamber, and first collector. The first collector includes a non-insulating material first surface of a size greater than 1 square meter, a non-insulating material first reference surface, and a first electric generator configured to apply to the first surface a potential relative to the reference surface between 5 kV and 500 kV. The at least one first collector is configured to collect at least some of the aggregates of the fine particles. The ionizing device includes multiple spikes, a grating, and an electric generator configured to apply to the spikes a predetermined potential relative to the grating of at least 100 kV/m.

An air purifier having an electret module for capturing airborne particles, the electret module includes an electret element which generates a static field for capturing airborne particles. The electret module is positioned incorporated into the air purifier such that the static field helps prevent the inhalation of the airborne particles.

An air purifier having an electret module for capturing airborne particles, the electret module includes an electret element which generates a static field for capturing airborne particles. The electret module is positioned incorporated into the air purifier such that the static field helps prevent the inhalation of the airborne particles.

Disclosed is an air cleaning device for air conditioners. The air cleaning device includes a charging unit, and a dust collector including ground bodies and high voltage applied bodies forming a potential difference with the ground bodies, and disposed after the charging unit in an air flow direction, the charging unit includes a charging unit body and carbon fiber electrodes installed on the charging unit body, and a hydrophilic layer is formed on the outer surface of at least one of the ground bodies and the high voltage applied bodies. The air cleaning device may minimize an amount of generated ozone and an amount of generated ions, as compared to a case having a charging unit in which electrical discharge wires and opposite electrodes are alternately disposed, and increase dust collection efficiency with a simple structure and at low costs.

Disclosed is an air cleaning device for air conditioners. The air cleaning device includes a charging unit, and a dust collector including ground bodies and high voltage applied bodies forming a potential difference with the ground bodies, and disposed after the charging unit in an air flow direction, the charging unit includes a charging unit body and carbon fiber electrodes installed on the charging unit body, and a hydrophilic layer is formed on the outer surface of at least one of the ground bodies and the high voltage applied bodies. The air cleaning device may minimize an amount of generated ozone and an amount of generated ions, as compared to a case having a charging unit in which electrical discharge wires and opposite electrodes are alternately disposed, and increase dust collection efficiency with a simple structure and at low costs.

A portable ionization unit for attachment to an overhead airflow nozzle is disclosed. The ionization unit includes a housing. A rechargeable self-contained ionizer is positioned inside the housing. The housing is attachable to the overhead airflow nozzle. Once the ionization unit is attached to the overhead airflow nozzle, a dome of bipolar ionized air is created above the seated passenger.

A portable ionization unit for attachment to an overhead airflow nozzle is disclosed. The ionization unit includes a housing. A rechargeable self-contained ionizer is positioned inside the housing. The housing is attachable to the overhead airflow nozzle. Once the ionization unit is attached to the overhead airflow nozzle, a dome of bipolar ionized air is created above the seated passenger.

A personal protective equipment face covering includes at least one layer. Each of the at least one layers includes at least one fabric material. Wherein, each of the at least one layers of the at least one fabric material including an inherently ionic material. Wherein an ionic charge on the inherently charged ionic material comes from a molecular structure, not from electrostatic charge or triboelectricity.

A personal protective equipment face covering includes at least one layer. Each of the at least one layers includes at least one fabric material. Wherein, each of the at least one layers of the at least one fabric material including an inherently ionic material. Wherein an ionic charge on the inherently charged ionic material comes from a molecular structure, not from electrostatic charge or triboelectricity.

A collection device includes an acquisition device, a control device, and a detection device. The acquisition device acquires information inside a space of a target region. The control device sets a detection path for a collection device based on an unreachable region within the space of the target region. The detection device acquires environmental data including environmental data of the unreachable region detected when the collection device moves along the detection path in the space of the target region.