A cleaning assembly may include a chuck. The cleaning assembly may include a plurality of lift pins positioned proximate to the chuck. The plurality of lift pins may be configured to engage a cleaning substrate and translate the cleaning substrate to allow the cleaning substrate to capture one or more particles from the surface of the chuck via at least one of electrostatic attraction or mechanical trapping when the cleaning substrate is positioned in the second position. The cleaning assembly may include a replaceable top skin coupled to the chuck and configured to capture the one or more particles.

An equipment cleaning apparatus for an extraplanetary environment includes a cleaner vessel positioned at an exterior of an extraplanetary habitat, and an exterior hatch located outside of the extraplanetary habitat and allowing access to an interior of the cleaner vessel. The cleaning apparatus is operable in one or more cleaning cycles to clean equipment located in the cleaner vessel. A method of cleaning equipment in an extraplanetary environment includes providing a cleaner vessel at an extraplanetary habitat, placing one or more articles of equipment into an interior of the cleaner vessel through an exterior hatch located outside of the extraplanetary habitat, closing the exterior hatch, and operating one or more cleaning cycles on the equipment in the cleaner vessel.

A fume hood control system includes a fume food. The fume hood includes a first baffle, a sash and a hood enclosure positioned within an environment. The hood enclosure includes a plurality of sidewalls forming a work chamber, a first aperture configured to permit an airflow between the environment and the work chamber, and a second aperture configured to permit the airflow between the work chamber. The sash is configured to at least partially cover the first aperture. The first baffle is configured to direct a path of the airflow within the work chamber. The first baffle is transitionable between a first number of positions. The fume hood control system includes a controller configured to determine, via a sash sensor, a current position of the sash. The controller is further configured to determine, via a baffle position sensor, a current position of the first baffle. The controller is further configured to control the operation of the first baffle to transition between the current position of the first baffle and an updated position of the first baffle in response to the current position of the sash, the current position of the first baffle, and one or more pressure measurements.

A housing assembly for selectively receiving a part includes a platform and a pad fixed to the platform. The pad has a frictional surface for maintaining a position of the part relative to the pad when the part is disposed on the frictional surface. The housing assembly includes a door apparatus coupled to the platform. The door apparatus surrounds the pad. The door apparatus is movable to an open position in which the frictional surface of the pad is exposed outside of the door apparatus for receiving the part and a closed position in which the frictional surface of the pad is concealed inside of the door apparatus. A method of removing particles from a frictional surface of a pad before performing a manufacturing process has a door apparatus disposed in a closed position to present a chamber that encloses the pad.

A wastewater collection system of a water wash system includes a collection duct configured to attach to a gas turbine engine for receiving a mixture of air and wash liquid from the gas turbine engine during washing. The wastewater collection system additionally includes a separation assembly, the separation assembly including a shaft, one or more impellers mounted to the shaft, and a casing. The casing at least partially encloses the shaft and encloses the one or more impellers. The casing defines an inlet for fluidly connecting with the collection duct, an air outlet, and a liquid outlet. The air outlet is disposed opposite the one or more impellers from the inlet and the liquid outlet.

A cooking smoke shielding and guiding apparatus comprises: a housing including an outer casing, a storing chamber defined in the outer casing and having a slot formed in an end portion of the outer casing, and a plurality of fixing elements formed on said outer casing adapted for fixing the outer casing on a kitchen object by the fixing elements; a shielding plate slidably retractably stored in the storing chamber of the housing or slidably extended outwardly through the slot of the outer casing for shielding and guiding cooking smoke; and a driving mechanism mounted in the storing chamber and operatively extending the shielding plate outwardly from the storing chamber, or operatively retracting the shielding plate inwardly into the storing chamber.

A cooking smoke shielding and guiding apparatus comprises: a housing including an outer casing, a storing chamber defined in the outer casing and having a slot formed in an end portion of the outer casing, and a plurality of fixing elements formed on said outer casing adapted for fixing the outer casing on a kitchen object by the fixing elements; a shielding plate slidably retractably stored in the storing chamber of the housing or slidably extended outwardly through the slot of the outer casing for shielding and guiding cooking smoke; and a driving mechanism mounted in the storing chamber and operatively extending the shielding plate outwardly from the storing chamber, or operatively retracting the shielding plate inwardly into the storing chamber.

In examples, systems and methods for using skewed waveforms to eject debris using electromagnetic propulsion are disclosed. The systems and methods include a first electronic device having a surface. The systems and methods also include a signal generator configured to generate a skewed signal configured to cause a movement of particles on the surface of the first electronic device. Additionally, the systems and methods include an antenna coupled to the signal generator, where the antenna is configured to receive the skewed signal from the signal generator and radiate the skewed signal as electromagnetic energy proximate to the surface of the first electronic device.

In examples, systems and methods for using skewed waveforms to eject debris using electromagnetic propulsion are disclosed. The systems and methods include a first electronic device having a surface. The systems and methods also include a signal generator configured to generate a skewed signal configured to cause a movement of particles on the surface of the first electronic device. Additionally, the systems and methods include an antenna coupled to the signal generator, where the antenna is configured to receive the skewed signal from the signal generator and radiate the skewed signal as electromagnetic energy proximate to the surface of the first electronic device.

An example flush station includes an upper cabinet and a lower cabinet. At least one cleaning head is mounted in the upper cabinet, and has an anchoring attachment, a cleaning solution inlet to dispense cleaning solution, and a compressed air inlet to dispense compressed air. A vacuum system may be provided in the upper cabinet to entrain airborne particulates. A catch basin formed in the lower cabinet receives spent cleaning solution from the upper cabinet. At least one settling tank in the lower cabinet receives spent cleaning solution from the catch basin for settling at least some suspended particulate matter in the spent cleaning solution. A grate at an interface between the upper section and the lower cabinet provides a cleaning deck for filters and/or other components to be cleaned during the cleaning operation. During the cleaning operation, cleaning solution and/or compressed air are dispensed through the filters and/or other components.