An air cleaner system for filtering an input air into a treated air output is disclosed. Comprising an air dryer assembly configured to cool and condense moisture from incoming compressed air. A fan configured to facilitate airflow through the air dryer assembly. An air input assembly configured to receive external air. A filter assembly comprising a moisture separator and a coalescing filter, configured to remove contaminants and moisture from the compressed air. An air output assembly configured to provide treated air to a target equipment. A power supply configured to operate the air cleaner system using either AC power or a battery. A controller configured to monitor conditions within the air cleaner system and adjust the performance of the air dryer assembly and the fan. An air dryer assembly configured to cool and condense moisture from incoming compressed air. A fan configured to facilitate airflow through the air dryer assembly.

Described are assemblies of porous polymeric filter membranes that include two polymeric filter membranes in series, i.e., as part of a membrane assembly; filter components and filter products that include the two polymeric filter membrane layers; methods of assembling the polymeric filter membranes, filter components, and filter products; and methods of using the polymeric filter membranes to remove particles from a liquid such as a semiconductor processing liquid fluid.

A contaminant trap system of a reactor system may comprise a baffle plate stack comprising at least one baffle plate comprising an aperture spanning through a baffle plate body of the baffle plate, and a solid body portion; and at least one complementary baffle plate comprising a complementary aperture spanning through a complementary baffle plate body of the complementary baffle plate, and a complementary solid body portion. The at least one baffle plate and the at least one complementary baffle plate may be disposed in a baffle plate order between a first end and a second end of the baffle plate stack in which the baffle plates alternate with the complementary baffle plates, such that no two baffle plates or no two complementary baffle plates are adjacent in the baffle plate order.

Provided is a condensation device capable of removing water vapor from a larger amount of gas without making a size larger than in related art. A condensation device 700 according to the present invention includes an outer cooling unit 720 including one or two or more inner tubes 722, an outer tube 724 located outside the one or two or more inner tubes 722, and a first flow path 726 through which a first cooling medium passes between the one or two or more inner tubes 722 and the outer tube 724.

Described are porous, sintered metal bodies that include multiple layers made from different metal particles and that may be useful as porous filter membranes, as well as methods of making and using the porous, sintered metal bodies.

A method of supplying a processing solution includes shutting off a feed line supplying the processing solution to a chemical filter, installing a dry chemical filter in a filter housing of the chemical filter, closing an output line from the filter housing to a nozzle configured to dispense the processing solution (either before or after installing the dry chemical filter), applying a vacuum to the filter housing while the feed line remains shut, and opening the feed line while locking in the vacuum within the filter housing. Shutting off the feed line and closing the output line may be accomplished by closing respective valves. Before installing the dry filter, a valve to the vacuum may be closed. The method may be performed by a processor executing a program stored in a non-transitory computer-readable medium.

An air channel membrane distiller (1) comprises a hot surface (12), a cooling section (20) and a hydrophobic membrane (30). The hot surface and the hydrophobic membrane define a sealed evaporation channel (40). A surface (22) of the cooling section and the hydrophobic membrane define a sealed condensation channel (50). A water supply tubing (42) is connected to the evaporation channel. A water discharge tubing (46) is connected to the evaporation channel. A purified-water discharge tubing (56) is connected to the condensation channel. The surface of the cooling section is given a temperature lower than a temperature of water in the evaporation channel. A gas supply arrangement (60) for inert gas comprises a heater (62). A gas pipe system (64) is arranged to a gas inlet (55) of the condensation channel for enabling flushing of at least the condensation channel with the inert gas.

A cleaning system includes a planar material beneath a soiled grow table. The planar material is non-porous except for a drain. Above the planar material is a plate layer including at least two layers of runners arranged in a grid where each successive layer is offset at an angle with respect to the grid of a previous layer. The plate layer rests upon the non-porous material. An upper layer covers the plate layer and has a plurality of holes. A roller table is provided for slideably supporting the grow table. Nozzles are positioned over the grow table and is/are interfaced to a pump for receiving and spraying liquid from the pump downwardly towards the grow table. The liquid and impurities (e.g., soil, leaves) fall to the upper layer and through the plurality of holes for cleaning and filtering the liquid before the liquid is returned to the pump.

A contaminant trap system of a reactor system may comprise a baffle plate stack comprising at least one baffle plate comprising an aperture spanning through a baffle plate body of the baffle plate, and a solid body portion; and at least one complementary baffle plate comprising a complementary aperture spanning through a complementary baffle plate body of the complementary baffle plate, and a complementary solid body portion. The at least one baffle plate and the at least one complementary baffle plate may be disposed in a baffle plate order between a first end and a second end of the baffle plate stack in which the baffle plates alternate with the complementary baffle plates, such that no two baffle plates or no two complementary baffle plates are adjacent in the baffle plate order.

A thermal management system having a thermal fluid water separator assembly, and which is configured to circulate a thermal fluid in at least an immersion-cooled system, including a battery system for a vehicle, among other systems and machines. The thermal management system can be configured to control a temperature of one or more electric devices, such as, for example, a plurality of battery cells, of the associated system. The thermal fluid water separator assembly can include a media, and a water collection portion configured to collect water separated by the thermal fluid water separator assembly from the thermal fluid. The thermal fluid water separator assembly can be selectively operated in conjunction with either or both a primary pump and a secondary pump to further optimize water removal during periods of activity and/or inactivity of the associated system or machine, as well as under different conditions.