An active air filter device for disrupting or destroying bacteria and/or viruses, the filter including at least one layer of porous conductive material, and energy source creating current and/or voltage and/or electric field and/or magnetic field, propagated throughout the conductive material.

A head covering device comprising a rigid component comprising a transparent face shield, a fabric component, wherein the face shield and fabric combine to cover an entire head of a user and form a seal around the user's neck, an intake port with an inlet filter, an exhaust port with an exhaust filter, an air mover causing filtered air to enter the intake port and exhaust air to exit the exhaust port, and an environmental control component to condition air within the device.

Self-sterilizing filtration materials are disclosed that include at least one polydopamine-functionalized layer. The at least one polydopamine-functionalized layer is configured to heat to a sterilization temperature when illuminated by light with a light intensity. The self-sterilizing filtration materials may be included in a filtering respirator mask. Methods of sterilizing filtration materials and filtering respirator masks containing at least one polydopamine-functionalized layer by exposing to sunlight are also disclosed. In addition, methods of producing a self-sterilizing filtering respirator mask by polydopamine-functionalizing at least one layer of the filtration material in an existing filtering respirator mask.

A fluid control device includes a support structure configured to be deployed in a borehole, and a filtration component disposed at the support structure, the filtration component including a porous medium made from a thermoplastic polymer material, the porous medium including an open cell foam. The porous medium has a porosity selected to cause the porous medium to exhibit shape memory behavior, and the porous medium is configured to be compacted from an initial shape to a compacted shape, deployed in the borehole, and subsequently expanded due to a downhole temperature to conform to a surface of the borehole.

Disclosed is a particulate matter (PM) capturing and collecting filter device having a target-coated liquid film. More specifically, disclosed is a PM particle capturing and collecting filter device having a target-coated liquid film in which a spreading phenomenon in which a liquid material spreads outside the filter is suppressed. Disclosed is a filter device for capturing and collecting PM particles, in which a liquid film having interface energy control and capillary force induction is used for effective PM particle capturing and collecting, and a surrounding portion is formed for preventing spreading of a liquid material on a substrate.

A nucleic acid collection column collects a nucleic acid from a liquid sample containing the nucleic acid. The nucleic acid collection column includes a sample injection portion having an opening into which the liquid sample containing the nucleic acid is injected, a support adsorption portion that houses a support for adsorbing the nucleic acid and in which the nucleic acid is adsorbed on the support, and a discharge portion that discharges a liquid passed through the support adsorption portion. The support includes aluminum oxide having a surface where a water-soluble neutral polymer is adsorbed. A space that houses the support in the support adsorption portion has a cylindrical shape, and has a volume of 0.13 μL or more and 13.5 μL or less. An aspect ratio (d.sub.1/d.sub.2) of the space satisfies 1.0≤d.sub.1/d.sub.2<15.0.

According to a first aspect, the present invention is embodied as a method of processing a filtered liquid with a microfluidic device. The method includes positioning a porous filtering medium with respect to the microfluidic device, so as to allow a flow path between the filtering medium and a channel of the microfluidic device. The method further includes introducing a liquid in the porous filtering medium for the liquid to advance along the filtering medium and be filtered by the medium. The method further includes applying compression to the filtering medium to extract a given volume of the filtered liquid from the filtering medium, where the extracted liquid volume reaches said channel via the flow path. The method further includes processing the extracted volume with the microfluidic device.

The Kachina Aholi is a device invented out of three main components. The three components are: a drone or other aerial load lifting apparatus, a air filter (varying in the passage intensity of molecular material, graded filters) and a Super or Ultra hydrophobic spray (e.g. WATERBEADER™). These three components combined make a device that is flown up to clouds that are dense with water molecules and “bead” those molecules up along the air filter and cause premature precipitation. This method of premature precipitation can be used to irrigate farms, prevent flash floods, prevent landslides, wildfire prevention or reduction, increase accessibility in low water/dry areas, and climate control.

An object of the present disclosure is to provide a filter medium for air filters that has a high PF value and high water repellency in addition to stiffness and strength that are practically sufficient, and to provide the filter medium with an easy production method. The filter medium, composed of a wet-laid nonwoven fabric including a glass fiber, for air filters according to the present disclosure includes a cationic binder resin, a fluororesin, and a cationic surfactant, and the solid content mass ratio of the fluororesin to the cationic surfactant is within a range of 30/70 to 80/20.

An erosion, sediment and pollution control product comprises a geotextile which includes cellulose based threads treated to be hydrophobic and cellulose based filler within the tubular geotextile. The geotextile may be knitted and may include lyocell threads and wherein the lyocell threads are treated to be hydrophobic, and are treated with food grade mineral oil. A method of making a tubular knitted geotextile comprises the steps of: supplying cellulose based threads to a circular knitting machine and knitting a tubular substrate, treating the cellulose based threads with one of mineral oil, beeswax, paraffin, petroleum jelly, lanolin, plant-based oils, and combinations thereof, whereby the threads are rendered hydrophobic.