The present disclosure provides for a method of filtering pollutants from a contaminated fluid stream. The method includes disposing unprepared humic shale in a container, contacting the unprepared humic shale with an aqueous solution, maintaining the aqueous composition in contact with the unprepared humic shale for a period of time, drying the humic shale, and then placing polluted water in contact with the humic shale until pollutants have been removed from the fluid.

A personal air-purifying (PAP) mask includes a fan assembly; a plasma driven catalyst (PDC) assembly including an anti-microbial catalyst, wherein the anti-microbial catalyst is incorporated within a nanofiber layer of the PDC assembly; and a pre-filter, wherein the pre-filter also includes the anti-microbial catalyst incorporated therewith; wherein the PDC assembly is positioned between the fan assembly and the pre-filter, and wherein the fan assembly, the PDC assembly, and the pre-filter are within a main body of the PAP mask.

A personal air-purifying (PAP) mask includes a fan assembly; a plasma driven catalyst (PDC) assembly including an anti-microbial catalyst, wherein the anti-microbial catalyst is incorporated within a nanofiber layer of the PDC assembly; and a pre-filter, wherein the pre-filter also includes the anti-microbial catalyst incorporated therewith; wherein the PDC assembly is positioned between the fan assembly and the pre-filter, and wherein the fan assembly, the PDC assembly, and the pre-filter are within a main body of the PAP mask.

A filter may remove PM.sub.2.5 and/or other airborne pollutants, which filter has fibers of an average diameter of no more than 500 nm, the fibers of at least 90 wt. % polyacrylonitrile, relative to all fibers in the filter; and a catalyst of at least 90 wt. % TiO.sub.2, relative to all catalytic metals in the filter, dispersed onto the fibers. The fibers need not be charged. The TiO.sub.2 may be condensed or precipitated onto the fibers out of a liquid containing the TiO.sub.2 and the fibers by simple methods. The catalyst may be activated by UV irradiation to decompose particulate matter having an average particle size of 2.5 μm or less, i.e., PM.sub.2.5, and/or other airborne pollutants from air. Such filters may be implemented around areas of vehicle traffic, e.g., as elements of traffic lights, and may be used to controllably purify polluted air.

A filtering apparatus has a volume-changeable filtering chamber having one or more flexible enclosing walls and receiving therein a compressible porous filtering medium, a fluid inlet coupled to the filtering chamber for introducing an input fluid stream with impurities into the filtering chamber, a fluid outlet coupled to the filtering chamber for discharging a filtered fluid stream from the filtering chamber, and a volume-changing structure coupled to or in association with the filtering chamber, adapted to permit increasing or decreasing of the volume of the filtering chamber so as to compress or decompress the compressible porous filtering medium therein so as to correspondingly adjust the pore size of the compressible porous filtering medium in said filtering chamber. A method for flushing a compressible filter media, and a method of variably adjusting the amount of filtering, is further disclosed and claimed.

A filtering apparatus has a volume-changeable filtering chamber having one or more flexible enclosing walls and receiving therein a compressible porous filtering medium, a fluid inlet coupled to the filtering chamber for introducing an input fluid stream with impurities into the filtering chamber, a fluid outlet coupled to the filtering chamber for discharging a filtered fluid stream from the filtering chamber, and a volume-changing structure coupled to or in association with the filtering chamber, adapted to permit increasing or decreasing of the volume of the filtering chamber so as to compress or decompress the compressible porous filtering medium therein so as to correspondingly adjust the pore size of the compressible porous filtering medium in said filtering chamber. A method for flushing a compressible filter media, and a method of variably adjusting the amount of filtering, is further disclosed and claimed.

Disclosed is a storage-type modular data center. The storage-type modular data center includes a box, a dust removing module, an evaporative cooling module, and an air supply module. The box is provided with an air inlet and an air outlet. A server is disposed between the air inlet and the air outlet. The dust removing module is disposed between the server and the air inlet. The evaporative cooling module is disposed between the server and the air inlet, and includes an evaporative media and a water sprinkling tray module. One end of the evaporative media is immersed in liquid contained in the water sprinkling tray module. The air supply module is operative to drive air to flow between the air inlet and the air outlet.

Disclosed is a storage-type modular data center. The storage-type modular data center includes a box, a dust removing module, an evaporative cooling module, and an air supply module. The box is provided with an air inlet and an air outlet. A server is disposed between the air inlet and the air outlet. The dust removing module is disposed between the server and the air inlet. The evaporative cooling module is disposed between the server and the air inlet, and includes an evaporative media and a water sprinkling tray module. One end of the evaporative media is immersed in liquid contained in the water sprinkling tray module. The air supply module is operative to drive air to flow between the air inlet and the air outlet.

Filter media including out-of-plane solid elements are generally described. Inventive methods of forming them and uses thereof are also described.

Filter media including out-of-plane solid elements are generally described. Inventive methods of forming them and uses thereof are also described.