The present invention provides devices and methods to capture airborne agents, microbes, including viruses, and microbial antigens, toxins and allergens and prevent the spread of infection from direct contact with contaminated surfaces (contact contamination), from large droplets of infectious material that fall out of the air, or from small droplets that can be carried by the air stream throughout the environment (airborne contamination).

A semiconductor manufacturing equipment has a support platform and a substrate disposed over the support platform. A first electrical component is disposed over a first surface of the substrate. A second electrical component is disposed over a second surface of the substrate opposite the first surface of the substrate. A suction hood is disposed over the substrate. A gas is introduced over the substrate to circulate residue while drawing the residue vertically into the suction hood. The gas can be introduced with a gas nozzle or air knife. The gas can be introduced from a gas conduit disposed at least partially around the substrate. The gas conduit can extend completely around the substrate. The gas nozzles are sequentially placed around the gas conduit. The gas can be a stable or inert gas. The residue is displaced away from the second electrical component.

A semiconductor manufacturing equipment has a support platform and a substrate disposed over the support platform. A first electrical component is disposed over a first surface of the substrate. A second electrical component is disposed over a second surface of the substrate opposite the first surface of the substrate. A suction hood is disposed over the substrate. A gas is introduced over the substrate to circulate residue while drawing the residue vertically into the suction hood. The gas can be introduced with a gas nozzle or air knife. The gas can be introduced from a gas conduit disposed at least partially around the substrate. The gas conduit can extend completely around the substrate. The gas nozzles are sequentially placed around the gas conduit. The gas can be a stable or inert gas. The residue is displaced away from the second electrical component.

Presented is a rail track cleaner vehicle configured for cleaning rail area. The rail track cleaner vehicle includes a wheel assembly, a main frame, a liquid sprayer assembly, an air blower assembly, a vacuum assembly and an electric motor assembly. The rail track cleaner vehicle comprises a plurality of optical camera to capture real time image of the rail area. The rail track cleaner vehicle efficiently and effectively clean the rail area and enables a remote personnel to inspect the cleaning process. The rail track cleaner vehicle substantially reduces manual labor and effort to clean the rail area.

Presented is a rail track cleaner vehicle configured for cleaning rail area. The rail track cleaner vehicle includes a wheel assembly, a main frame, a liquid sprayer assembly, an air blower assembly, a vacuum assembly and an electric motor assembly. The rail track cleaner vehicle comprises a plurality of optical camera to capture real time image of the rail area. The rail track cleaner vehicle efficiently and effectively clean the rail area and enables a remote personnel to inspect the cleaning process. The rail track cleaner vehicle substantially reduces manual labor and effort to clean the rail area.

A fume cupboard, of the type comprising a framework with two front uprights (2a,2b), two rear uprights (3a,3b), a rear panel (11), two side panels (6,7), an upper panel (8) and a sash (4) consisting of a frame (12) and at least one panel (13) for closing an inner chamber (1 0) of said fume cupboard (1). The fume cupboard of the invention comprises a transmission system (14) for transmission of the vertical movements of said sash (4) located inside the abovementioned front uprights (2a,2b), or inside said front uprights (2a,2b) and said rear uprights (3a,3b).

A protective apparatus for use in medical and dental procedures to prevent exposure and exchange of harmful substances between an area isolated by the apparatus and the environment of use. The apparatus includes a physical shield, a vacuum barrier, and an adjustable support frame. The apparatus further includes a vacuum connector for connecting the apparatus to a vacuum source, a vacuum conduit for flow communicating with the air around the perimeter of the physical shield such that the vacuum source draws air along with solid and liquid matter entrained in the air into the vacuum conduit, and a plurality of vacuum apertures located along the vacuum conduit for communicating the vacuum source with the air. The apparatus provides protection for persons in proximity to a source of harmful substances such as aerosols derived from patients infected with viruses or the like and more in particular corona viruses.

An extractor system includes a negative pressure gas stream source, a negative pressure conduit, a positive pressure gas stream source, a plurality of positive pressure gas stream manifolds, and an operator interface. The negative pressure conduit is conveys the negative pressure gas stream from a work area. A first end of the negative pressure conduit is coupled to the negative pressure gas stream source, such that the negative pressure gas stream flows from the work area through a second end of the negative pressure conduit and toward the first end of the negative pressure conduit. The positive pressure gas stream manifolds are disposed about the negative pressure conduit at the second end of the negative pressure conduit, and fluidly coupled to the positive pressure gas stream source. The positive pressure gas stream is directed through the plurality of positive pressure gas stream manifolds. The operator interface allows a user to control the positive pressure gas stream through each of the plurality of positive pressure gas stream manifolds.

An extractor system includes a negative pressure gas stream source, a negative pressure conduit, a positive pressure gas stream source, a plurality of positive pressure gas stream manifolds, and an operator interface. The negative pressure conduit is conveys the negative pressure gas stream from a work area. A first end of the negative pressure conduit is coupled to the negative pressure gas stream source, such that the negative pressure gas stream flows from the work area through a second end of the negative pressure conduit and toward the first end of the negative pressure conduit. The positive pressure gas stream manifolds are disposed about the negative pressure conduit at the second end of the negative pressure conduit, and fluidly coupled to the positive pressure gas stream source. The positive pressure gas stream is directed through the plurality of positive pressure gas stream manifolds. The operator interface allows a user to control the positive pressure gas stream through each of the plurality of positive pressure gas stream manifolds.

A device for the decontamination of materiel, notably an aircraft such as a military helicopter, using a nuclear, biological and/or chemical decontaminant. The device includes a protective cover that can be adapted to the shape of the materiel, able to form a fluid tight decontamination tunnel around the materiel; at least one decontamination module able to eliminate the contamination from the materiel arranged inside the tunnel formed by the protective cover; an air-blowing module able to be arranged at the entrance to the tunnel formed by the protective cover in order to dispatch air into the said tunnel; and a filtration module able to be positioned at the exit from the tunnel formed by the protective cover in order to destroy contaminated air vapours and/or to recover the decontaminant at the exit from the said tunnel.