The present invention relates to a safety workbench having a work space surrounded by a housing having a work opening located in the housing front side and adjustable with an adjustable front panel for admitting into the work space an air inlet flow, an exhaust blower and a circulating air blower for conveying an air flow in the safety workbench, which are designed such that a partial air flow drawn in by the exhaust blower is filtered through an exhaust air filter as exhaust air flow from the safety workbench and a partial air flow drawn in by the circulating air blower through a circulating air filter as downwardly directed circulating air flow into the work space, and a control device, a differential pressure sensor (16) and two pressure transducers connected thereto which are designed to measure a pressure at two different positions within the safety workbench d, wherein a first of the pressure transducers is arranged in the immediate vicinity of the fan blades on the low pressure side of the circulating air blower and a second of the pressure transducers is arranged in a low-flow area, on the low pressure side of the circulating air blower. The present invention further relates to a method of operating a safety workbench according to any of the preceding claims, comprising the steps of: a) determining a pressure difference between the first pressure transducer and the second pressure transducer by means of the differential pressure sensor, b1) comparing the pressure difference determined in a) with a nominal pressure difference stored in the control device, which corresponds to a nominal volume flow, or b2) converting the pressure difference measured in a) into an associated volume flow and comparing the calculated volume flow with one nominal volume flow stored in the control device, and c) regulating the circulating air blower such that the nominal volume flow is conveyed.

The cyclone separation device has a case (1), a space partition plate (7), and a cylindrical member (11). The case (1) is formed into a cylindrical shape and has a first intake port (4), an outflow port (6), and a second intake port (5). The first intake port (4) has a circumferential opening (2) circumferentially formed in a side surface on a side of the one end of the case (1), and a fixed blade (3) arranged along the circumferential opening (2). The outflow port (6) is disposed on a surface on the side of the one end and discharges the swirling airflow fed through the first intake port (4). The second intake port (5) is disposed on a side surface on a side of the other end opposite to the one end.

An environmental window apparatus includes at least two dry open window (DOW) assemblies stacked on top of each other. Each DOW assembly includes a dry open window (DOW) structure having a plurality of louvers which, when viewed in cross section, have V or W shapes that enable air to pass through a window opening while limiting passage of precipitation, the precipitation being captured by the louvers for collection or drainage and a plurality of vertical members supporting the louvers in a spaced apart arrangement. A plurality of vertical rods are fixed to the vertical members of each DOW assembly by fasteners in a spaced apart arrangement to hold the DOW assemblies in place.

A foundation venting device for use in a wall that is constructed with queen size bricks includes a pipe that is rectangularly shaped and is configured to be inserted by a first end into a hole that positioned in the wall. The pipe has a second end that is closed. A plurality of apertures that is positioned in the second end of the pipe is configured to vent a space behind the wall. A flange that is coupled to and extends substantially perpendicularly from a perimeter of the second end of the pipe is configured to cover a gap between the pipe and at least one of an upper course and a lower course of the queen-sized bricks that define the hole in the wall.

A dry wall extrusion grille comprising a frame, a linear bar grille, indented slots, and a flexible mounting flange.

A dry wall extrusion grille comprising a frame, a linear bar grille, indented slots, and a flexible mounting flange.

A ventilation and air conditioning system (6) is for a room (2) containing a heat source and the ventilation and air conditioning system (6) comprising a cooled air supply (12) and a ventilation duct (10). The ventilation duct (10) includes a primary inlet (24) connected to the cooled air supply (12) and an outlet (14) leading into the room (2). A number of heat storage elements (30) is arranged inside the ventilation duct (10) between the primary inlet (24) and the outlet (14), such that during operation of the cooled air supply (12) there is a forced stream of cooled air through the ventilation duct (10), thereby cooling and preferably freezing the heat storage elements (30). A secondary inlet (36) into the ventilation duct (10) is in flow communication with the room (2) and during operation of the cooled air supply (12) is closed by a damper (40). The damper (40) is designed to automatically open in a passive manner when the forced stream of cooled air from the cooled air supply (12) stops, such that a natural convection airflow through the ventilation duct (10) is supported, and the natural convection airflow is cooled by transferring heat to the heat storage elements (30).

The present invention relates in general to a compact air handling system to supply conditioned air to a space including but not limited to, building rooms and data center server space. The present invention relates to the design and layout of the system for air handling unit system applications.

A wall exhaust vent (e.g., for a dryer or other HVAC system) can include a housing defining a vent opening, and one or more bumpers on or at least partially within the housing and configured contact a door of the wall exhaust vent in a closed position. The one or more bumpers can include a bumper body, and a magnet disposed at least partially within the bumper body that is configured to magnetically interact with the door of the wall exhaust vent to bias the door to the closed position.

The indoor ventilation exhaust system is configured for use in a domestic space. The indoor ventilation exhaust system is configured for use with second-hand smoke. The indoor ventilation exhaust system draws atmospheric gases containing second-hand smoke out of a domestic space. The indoor ventilation exhaust system comprises an manifold, discharge system, and a collection network. The discharge system attaches to the manifold. Each of one or more collection networks attach to the manifolds. The discharge system creates a partial vacuum that draws the second-hand smoke of out the domestic space into the collection network. The second-hand smoke is aggregated in the manifold and is then discharged from the domestic structure containing the domestic space through the discharge system. The discharge system creates the partial vacuum that transports the second-hand smoke.