A solvent containment and solvent handling process interlocking system is described that can be used as a ventilation and spill management system for the storage and use of hazardous and volatile chemicals and solvents in an ordinary or non-hazardous location. The vented solvent containment system has a containment tray for secondary solvent containment and air regulatory to supply negative air pressure to draw in any evaporated solvent from the containment tray to a safe exhaust location. A safety sensor in the solvent containment system is interlocked with the solvent handling and solvent control system to slow or stop solvent flow in the event of a potentially hazardous solvent leak.

A solvent containment and solvent handling process interlocking system is described that can be used as a ventilation and spill management system for the storage and use of hazardous and volatile chemicals and solvents in an ordinary or non-hazardous location. The vented solvent containment system has a containment tray for secondary solvent containment and air regulatory to supply negative air pressure to draw in any evaporated solvent from the containment tray to a safe exhaust location. A safety sensor in the solvent containment system is interlocked with the solvent handling and solvent control system to slow or stop solvent flow in the event of a potentially hazardous solvent leak.

Machine (1) for distributing a product stored in a container (30) comprising a storage zone (2) delimiting locations (4) for housing a container (30), a metering station (5) delimiting a chamber (6) housing a support (7) for accepting a collecting vessel (33), this support (7) being positioned vertically in line with an opening (8) providing access to the chamber (6), which opening is arranged in an upper part (61) of the chamber (6), the machine (1) further comprising a system (10) for emptying each location (4) for housing a container (30) through the opening (8) providing access to the chamber (6), and a unit (14) for controlling the machine (1). The metering station (5) comprises a sensor (13) for detecting the presence of a collecting vessel (33) inside said chamber (6). The control unit (14) is configured to operate the machine (1) on the basis of data supplied by said sensor (13), and the metering station (5) is equipped with a circuit (15) for the circulation of gaseous fluid providing communication between the chamber (6) and the outside of said chamber (6) through a forced circulation of air.

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.

An apparatus is provided for preventing the spread of air-borne contaminants in a defined space. The apparatus comprises an air flow outlet adjacent to or within the defined space, an air flow inlet adjacent to or within the defined space, and a conduit for transporting air from the air flow inlet to the air flow outlet. An air treatment module is provided within or adjacent the conduit for extracting air-borne contaminants from air transported from the air flow inlet to the air flow outlet. The air flow outlet deposits air into the defined space substantially evenly across an outlet area.

The disclosure provides for cleaning three-dimensional (3D) components printed in a powder bed from adhering powder particles. The 3D-printed components are cleaned with a negative pressure-induced volumetric flow. The 3D-printed components are first removed from the powder bed after their manufacture, then positioned on a feed device and moved together with the feed device into a pressure-tight sealable chamber. In the interior of the chamber negative pressure is subsequently built up and a fluid volumetric flow is applied to the 3D-printed component to be cleaned which results in the powder particles being detached from the 3D-printed component. The powder particles are removed from the sealed chamber in a pressure tight manner via at least one channel conduit which is subjected to negative pressure and are fed to a separation device. The chamber is subsequently released of pressure and then opened for removal of the cleaned 3D-printed component.

The disclosure provides for cleaning three-dimensional (3D) components printed in a powder bed from adhering powder particles. The 3D-printed components are cleaned with a negative pressure-induced volumetric flow. The 3D-printed components are first removed from the powder bed after their manufacture, then positioned on a feed device and moved together with the feed device into a pressure-tight sealable chamber. In the interior of the chamber negative pressure is subsequently built up and a fluid volumetric flow is applied to the 3D-printed component to be cleaned which results in the powder particles being detached from the 3D-printed component. The powder particles are removed from the sealed chamber in a pressure tight manner via at least one channel conduit which is subjected to negative pressure and are fed to a separation device. The chamber is subsequently released of pressure and then opened for removal of the cleaned 3D-printed component.

Embodiments of the present application provide a waste collecting device, which relates to the technical field of lithium cell manufacturing. The waste collecting device includes a frame, a waste buffer box, a negative pressure flow-equalizing box and a waste collecting box. The waste buffer box is arranged in an upper part of the frame and the waste buffer box is provided with a waste pipeline. The negative pressure flow-equalizing box is arranged on the top of the waste buffer box, the negative pressure flow-equalizing box is communicated with the waste buffer box, and the negative pressure flow-equalizing box is provided with a negative pressure pipeline. The waste collecting box is movably arranged in the lower part of the frame and is selectively communicated with the waste buffer box.

A lighting system with vacuum intake is provided, having a lighting structure including at least one light-emitting element dimensioned to illuminate a region, and a lighting support structure extending at a first end thereof from the lighting structure and enabling repositioning of the lighting structure relative to a second end of the lighting support structure. The lighting support structure hays an air conduit extending therealong and connectable or connected towards the second end of the lighting support structure to a vacuum system, the air conduit being in fluid communication with a vacuum intake positioned towards the lighting structure.