A damper is configured for placement within a ductwork system that includes a duct supplying conditioned air through a register boot to a register vent within a room of a building. The damper includes a damper body and a damper blade pivotally secured relative to the damper body and a resilient seal extending radially outwardly from the damper blade, the damper blade being pivotally movable between a first position in which air flow is restricted and a second position in which air flow is less restricted. A drive motor is secured relative to the damper body and is configured to move the damper blade between the first position and the second position. A deployment strap extends downstream from the damper body and facilitates placement of the damper body in a duct from an installation location within or downstream of the register boot.

A damper assembly for use in a forced air duct feeding one or more air register vents includes a damper frame having an outer frame periphery and an inner frame periphery, the inner frame periphery defining an air flow aperture, and a damper blade that is pivotally secured relative to the damper frame and is pivotable between an open position and a closed position. An outer seal extends radially outwardly from the outer frame periphery of the damper frame and is configured to make a seal against an inner surface of the forced air duct when the damper assembly is deployed within the forced air duct.

An overfill valve associated with a drop tube segment fluidly connected to a fluid reservoir and a structure for securing drop tube segments are described. The overfill valve includes a valve body positioned within the drop tube segment and, in certain embodiments, a non-contact valve actuator positioned exterior to the drop tube segment and operable to actuate the valve body from an open position to a closed position without requiring any physical penetration through the wall of the drop tube segment. A variety of internal actuators are used to actuate the valve body within the drop tube segment. The structure for securing drop tube segments provides a first drop tube segment with a groove into which the wall of a second drop tube segment can to deformed to seal and fasten the two drop tube segments to each other.

Embodiments of the present disclosure present a valve assembly that includes a valve body having a gas passage bore, a valving bore extending along a longitudinal axis and intersecting the gas passage bore, a first bearing surface concentric with the longitudinal axis and a radially spaced apart second bearing surface concentric with the longitudinal axis, wherein an interface of the gas passage bore and the valving bore defines a flow port radially intermediate the first bearing surface and the second bearing surface. The valve assembly further includes a shaft valve extending along the longitudinal axis and rotatably mounted in the valving bore.

A pool wave generator having a pool area and a plurality of chambers for generating a wave in the pool area. Exemplary embodiments include using exhaust valves in each chamber to control the performance of fans. Measuring the power consumed by the fans in real time allows determination of the amount of air to be evacuated from the pneumatic system (and thus an opening angle of the exhaust valves) so that the fans operate at maximum efficiency and with less instability. In an exemplary embodiment, a valve mounted on the fan inlet allows the incoming air flow to be controlled, thereby allow the motors to continue rotating at a given speed with little or no energy consumption when the valve is partially or fully closed.

Embodiments of the disclosure generally relate to a flapper valve. The flapper valve may be used with processing chambers, such as semiconductor substrate processing chambers. In one embodiment, a flapper valve includes a housing having a first opening at a first end thereof and a second opening at a second end thereof, a first flapper pivotably disposed in the housing, and a second flapper pivotably disposed in the housing. The first and second flappers are movable to selectively open and close at least one of the first opening and the second opening.

An opening/closing valve structure for an engine is provided with a valve body for opening and closing an intake passage or an exhaust passage of the engine; a pair of bush members mounted on axial ends of the valve body; and a shaft member axially passing through one of the bush members and projecting from the bush member by a predetermined length within one end of the valve body. Each of the bush members is mounted in such a manner that a part of the bush member is axially received in an end of the valve body and the remaining part thereof axially projects from the end of the valve body. A portion of the shaft member projecting from the one of the bush members is connected to the valve body in such a manner that relative rotation of the shaft member with respect to the valve body is disabled.

A louver type blast valve making use of an aerodynamically configured blade, independently activated by air flow to block a blast shock wave and a subsequent return suction wave. The blast valve (FIG. 6) including a frame and at least one aerodynamically configured blade, independently activated by air flow to block a blast shock and a potentially following return wave. The aerodynamically configured blade having an elongated shape, including at least a steep convex surface and a flat or shallow concave surface, forming a leading edge and a trailing edge at the intersection of the surfaces. The blade being hinged to the frame about a longitudinal axis passing between the steep convex surface and the flat or shallow concave surface.

A magnetic particle separating valve that includes a valve body adapted for allowing particulate matter to flow vertically through the valve from an upstream to a downstream side. A discharge flow control apparatus is positioned in the valve body and includes a plurality of blades positioned in the valve body and movable between a fully open to a fully closed position to control the rate of discharge of material from the valve. Each of the plurality of blades includes a magnet positioned on the respective blade in a flow proximity position to attract and remove magnetically attractable particles from the particulate matter flowing past the blades.

An electromechanical actuating drive (1) for a bulk-goods shut-off element, comprising an electric motor (2) and a control and drive electronics unit (3) associated with the electric motor (2), wherein the electromechanical actuating drive (1) comprises a mechanism for storing energy.