An exhaust hood may have an exhaust inlet; a shroud having a lower edge and being movable, the shroud being configured to define an enclosed space over and adjacent a cooking surface, the enclosed space being in communication with the exhaust inlet. The shroud is movable to a first position providing clearance between the cooking surface and the shroud lower edge and a second position providing substantially less than the clearance provided by the first position. A vertical jet at the lower edge is aimed upwardly and along an inside of the shroud when the shroud is in the second position and the vertical jet is in the enclosed space. A horizontal jet is provided at a top of the shroud and aimed along an inside of the shroud when the shroud is in the second position and the vertical jet being in the enclosed space.

The present invention relates to a system for handling sensitive products, in particular for filling and sealing medicaments in containers, comprising an enclosed space (2) in which the sensitive products are handled, a device (3) for monitoring the air in the enclosed space (2) with a measuring point (6) and at least one Petri dish (30), wherein the Petri dish (30) comprises a lower receptacle (31) and a removable lid (32), and an automatic handling device (4), wherein the automatic handling device (4) is designed to automatically transport the Petri dish to the measuring point (6) and back and to remove the lid (32) from the lower receptacle (31) of the Petri dish (30) and put it back on.

A solids charging containment apparatus and method for mixing a solvent with a dry powder, comprising a dual compartment isolator for safely removing the dry powder from a dry powder container, a mixing vessel, and a negative cascading pressure controller. The dual compartment isolator comprises a staging compartment, a charging compartment and a raw material entry port, which is connected to the staging compartment and configured to isolate the dry powder container from the surrounding atmosphere. The mixing vessel includes a mixing chamber and a solids charging port fluidly connecting the mixing chamber to a containment valve in the charging compartment of the dual compartment isolator. The negative cascading pressure controller generates negative pressure in both the staging compartment and the charging compartment. The containment apparatus and method may be used to produce a slurry or solution mixture of solvent and dry powder during drug processing.

A method for removing substrate material from a part produced by a 3-D printer. The machine includes a housing having a working chamber defined therein. A spray header is disposed along at least a portion of the perimeter of the working chamber. A pump is configured and arranged to convey a fluid at varying pressures through the spray header. The fluid contacts the part and then flows to the bottom of the working chamber to a fluid outlet.

Provided is a safety cabinet that prevents oversights in airtightness tests and HEPA filter penetration ratio tests even if a pathogen or the like leaks from a workspace wall surface in the interior of the safety cabinet. The safety cabinet includes: a work surface at the bottom of a workspace; a front panel at the front of the workspace; a work opening section below the front panel; and a first air purification means that filters exhaust air that is air discharged from within the workspace. The safety cabinet is characterized in that the non-workspace sides of a side wall surface and a back wall surface of the workspace are formed by an outer wall of a device with prescribed airtightness performance.

A low-cost drug compounding system that can practically fit inside of a fume hood or the like is provided. The system can use a single pump operable in forward and reverse directions (or multiple pumps) to compound complex mixtures particularly including those requiring the creation of solutions from dry or powdered ingredients. A wireless link allows operation of the system remotely. In one embodiment, the system uses a disposable mixing tube set that can be discarded after mixing while still attached to the base ingredient containers used for the compounding thereby minimize the chance of personnel exposure.

Fume extraction device, in particular laboratory fume extraction device, including a housing with an operating chamber that is accessible to an operator through an operating hole in the housing; the operating chamber is defined by a base, side walls and a cover; the operating hole and/or at least one fresh air supply hole in the area of the operating hole is/are provided for allowing fresh air to flow into the operating chamber, and at least one waste air hole in the area of the cover is provided for allowing waste air to escape. At least one filter holder for accommodating at least one filter element is placed upstream of the at least one waste air hole; the at least one filter holder is accessible through the operating hole such that the filter element is accessible and replaceable from the operating chamber.

Methods, systems, and apparatus are described which can safely reduce a laboratory fume hood's minimum airflow and energy consumption when it is determined that the fume hood is not in active use, based on a condition monitoring approach. The condition monitoring approach may incorporate a combination of setback criteria to reliably determine if the fume hood is or is not in use. When a determination has been made that a fume hood is not in use, energy reduction is achieved via automatic methods of hood minimum airflow setback. Fume hood minimum flow reductions are automatically disabled when it is determined that the hood is in active use.

The apparatus for collecting by-products of the present disclosure includes: a cylindrical housing that has a top plate having a gas inlet and a bottom plate having a gas outlet extending and protruding inside the housing, and receives and then discharges an exhaust gas flowing inside; and a flow path change-type vertical internal collection tower that is installed in a hanging state inside the housing and includes a disc type collector, a diffusion plate, a cylindrical collector, and a cylindrical filter collector for collecting by-products in an exhaust gas flowing inside.

A sealed and ventilated receptacle for storing equipment, such as firefighter turnout gear, includes a base, at least one sidewall extending from the base, and a top wall that covers the opposite end of the sidewall. A sealable door may be positioned on the sidewall to access the inside of the receptacle and to prevent any contaminants from exiting the receptacle. The receptacle may also include an intake fan and exhaust fan that are each connected to a duct for providing fresh air to and removing contaminated air from the inside of the receptacle. The receptacle may further include a temperature control unit for regulating the temperature inside of the receptacle. Additionally, a hook for hanging a firefighter coat, trousers, or other items may also be included on the inside of the receptacle.