A dynamic filtration system and method for solid-fluid separation to eliminate or substantially reduce media blinding includes: a fluid inlet through which to receive an inlet flow of fluid to be filtered; a filter membrane; a rotatable mechanical barrier, disposed within an outer shell, to contain the filter membrane and through which to receive and filter the inlet flow of the fluid, the rotatable mechanical barrier configured to rotate dynamically along an axis, to create a high shear flow, thereby to prevent an accumulation of solids on the filter membrane, and whereby a resultant centrifugal force propels any solids and slurry onto the outer shell to be continuously removed from the dynamic filter system; a fluid outlet through which to disperse a filtered fluid; and a solids and slurry outlet through which to disperse solids and slurry collected in filtration when propelled to the outer shell of the mechanical barrier.

A separator has a mesh drum configured as a cylinder that can rotate and has mesh in at least part of the side; and a case that houses the mesh drum. The case has a supply port and a recovery port that communicate with an inside area, which is the inside of the mesh drum; a discharge port that communicates with a discharge area, which is outside the side of the mesh drum; and an inside wall segregating at least part of the inside area, forming a material recovery area. First screened material is supplied from the supply port to the inside area. In the material recovery area, the separator recovers accreted material, which is first screened material that was supplied through the supply port and accreted on the inside surface of the mesh drum, from the recovery port.

A sheet fabrication apparatus includes: a fiber separation unit that micronizes an ingredient; a first sensor unit that measures a temperature in a first space including the fiber separation unit; a first air conditioning unit that adjusts the temperature in the first space; a fabrication unit that works the fiber separated articles obtained by micronizing the ingredient by the fiber separation unit; a second sensor unit that measures at least either a temperature or a humidity at a mounting position of the fabrication unit; and a control unit that controls the first air conditioning unit on the basis of at least any of measurement results of the first sensor unit and the second sensor unit.

Disclosed herein is an air cleaner capable of being coupled or separated in a vertical direction to improve space utilization. An air cleaner may include a first air cleaning module provided with a first connection unit, and a second air cleaning module detachably coupled to the first air cleaning module and provided with a second connection unit, wherein the second connection unit is configured to be detachably coupled to the first connection unit, and configured to be rotatable with respect to the first connection unit when the second connection unit is coupled to the first connection unit.

A rotating crankcase ventilation system comprises a housing comprising an inlet and an outlet, a motor comprising a stator and a rotor, and a shaft. A first end of the shaft is coupled to the rotor and configured to rotate in response to rotation of the rotor. A filter element is coupled to the shaft. A sensor is configured to measure at least one operating parameter of the rotating crankcase ventilation system. A controller is operatively coupled to the sensor and the motor, the controller configured to receive the at least one operating parameter and selectively adjust operation of the motor to adjust rotation of the rotor, and thereby, the filter element based on the at least one operating parameter.

A rotating separator includes a filter housing extending axially along a longitudinal axis and a filter element positioned within the filter housing. The filter element includes a first endplate and a second endplate operatively coupled to the first endplate, a first element core and a second element core positioned between the first endplate and the second endplate and configured to filter a contaminate from a fluid. An interior cavity is defined between the first endplate, the second endplate, the first element core, and the second element core. Fluid flowing through the filter element enters the interior cavity and is split between and flows in parallel through the first element core and the second element core.

Various example embodiments relate to rotating coalescers. One embodiment includes a housing comprising a first housing section having a blowby gas inlet structured to receive crankcase blowby gases from a crankcase. The housing further comprises an oil outlet. The rotating coalescer includes an endcap and filter media. The filter media is arranged in a cylindrical shape and is coupled to and positioned between the first housing section and endcap. The filter media is structured to filter the crankcase blowby gases passing through the filter media by coalescing and separating oils and aerosols contained in the crankcase blowby gases. The rotating coalescer includes a hollow shaft extending through the housing and positioned radially inside of the filter media. The hollow shaft forms a blowby gas outlet structured to route filtered crankcase blowby gases out of the housing. The rotating coalescer further includes a drive mechanism operatively coupled to the hollow shaft.

A rotatingly driven filter element for filtering incoming air is to be arranged in a machine part upstream of an intake chamber of a cooling system or of a combustion air distribution device of an internal combustion engine of a self-propelled working machine. The filter element has a rim area with a circumferentially extending section provided with air guiding elements oriented toward and projecting into the intake chamber. The rim area, when the filter element is arranged in the machine part, is positioned at a minimal spacing relative to the machine part and an air gap is formed between the rim area and the machine part. The air guiding elements guide purified inflow air out of the intake chamber into a region of the air gap to effect a sealing action of the air gap.

Provided is a technology for preventing leakage of mist through a gap in a mist collector. A mist collector configured to collect mist generated in processing of a workpiece includes: a rotary filter configured to catch the mist; a drive unit configured to drive the rotary filter in such a manner as to rotate about a rotation axis passing through the center of the rotary filter; and a housing including a tubular portion. The housing houses the rotary filter in the tubular portion. A radial direction of the rotary filter is orthogonal to an inner surface of the tubular portion. An inflow preventing mechanism configured to prevent the mist from flowing into a gap between the tubular portion and the rotary filter is provided in housing.

The presently disclosed subject matter is generally directed to a device that is releasably or permanently mountable on at least one blade of a conventional ceiling fan to reduce the number of particulates in the air. Specifically, the device cooperates with a filter to remove a wide variety of impurities from the air, such as dust, pollen, smoke, pet dander, and the like. The disclosed system comprises a device and a filter. The device includes a support that provides a base for the attachment of the filter. The device further includes an adaptor that cooperates with a series of joints to allow the size and shape of the support to be customized for a particular ceiling fan blade. Advantageously, the device can be coupled to a wide variety of ceiling fan blades to enable an associated filter to clean the air as the fan blades rotate, thereby reducing the number of particulates in the air.