A cold regulating valve for a heat exchanger system of an aircraft propulsion system, where the cold regulating valve includes an open frame which delimits an opening, two shutters with an external convex shape slidably mounted on the open frame between a closed position and an open position, a mechanism linked to the shutters and mobile between a first position and a second position, and wherein the mechanism moves the shutters from the closed position to the open position when it moves from the first position to the second position and vice versa, and an actuator acting on the mechanism to move it from the first position to the second position and vice versa. The specific embodiment of the cold regulating valve generates a low drag when the shutters are in a closed position.

The disclosure relates to a valve assembly 10 for controlling a volute connecting opening 324 of a multi-channel turbine 500. The valve assembly 10 comprises a housing portion 300, a valve body 100 and an internal lever 200. The housing portion 300 defines a first volute channel 312, a second volute channel 314 and a volute connecting region 320. The housing portion 300 further comprises a cavity 340. The cavity 340 is separated from the volutes 312, 314 and can be accessed from outside the housing portion 300 via a housing opening 342 which extends from outside the housing portion 300 into the cavity 340. The volute connection region 320 is located between the first volute channel 312 and the second volute channel 314 and defines a volute connecting opening 324. The valve body 100 is inserted in the cavity 340 of the housing portion 300 and comprises at least one fin 120. The internal lever 200 is coupled with the valve body 100 and configured to pivotably move the valve body 100 between a first position and a second position. In the first position of the valve body 100, the fin 120 blocks the volute connecting opening 324.

A liquid sampler for use in sampling the liquid in a well. The sampler has a tube for containing the sample and an inlet at the bottom and an outlet at the top. An inlet check valve is located at the inlet which has a door configured autonomously to move between open and closed configurations in response to fluid flow through the inlet. In the open configuration, the door is aligned with the axis of the tube to allow fluid to flow into the tube through the inlet from below, and in the closed configuration, the door is positioned transverse to the axis of the tube to block fluid flow from the tube out through the inlet thereby retaining fluid within the tube as the sampler is raised up.

A variable bleed valve system for use in a turbofan engine includes a plurality of circumferentially spaced variable bleed valve assemblies. Each variable bleed valve assembly includes a plurality of circumferentially spaced variable bleed valve assemblies. Each variable bleed valve assembly includes a variable bleed valve door that is selectively adjustable through a range of intermediate positions between a closed position and an open position. The variable bleed valve door is configured to maintain any of the intermediate positions. Each variable bleed valve assembly also includes an actuator operatively coupled to the variable bleed valve door. The actuator is configured to selectively adjust a position of the variable bleed valve door through the range of intermediate positions between the closed position and the open position.

An airflow control valve structure includes a metallic pivot shaft-and a valve body. The valve body includes a connection portion connected to the pivot shaft and a resin valve portion. The pivot shaft includes first and second pivot shaft side press-fit portions. The connection portion includes a first valve side press-fit portion formed integrally with the valve portion and a metallic fitting member including a second valve side press-fit portion. The first valve side press-fit portion is fitted to the first pivot shaft side press-fit portion at an angular position at which a phase of the valve portion is matched with a phase of the pivot shaft. The second valve side press-fit portion is fitted to the second pivot shaft side press-fit portion. The first pivot shaft side press-fit portion is longer than the second valve side press-fit portion.

An air shut-off valve apparatus for a fuel cell system is provided. The apparatus includes a valve body having an inlet-side air passage through which supply air flows and an outlet-side air passage through which exhaust air flows. A valve flap is installed in the valve body to open or close the inlet-side air passage and the outlet-side air passage. An inlet-side check valve is opened when pressure of the supply air is greater than or equal to a predetermined pressure, to guide the supply air into the fuel cell stack through the inlet-side air passage even while the valve flap is closed. An outlet-side check valve is opened when pressure of the exhaust air is greater than or equal to a predetermined pressure, to guide the exhaust air released from the fuel cell stack to flow through the outlet-side air passage even while the valve flap is closed.

This disclosure relates to a valve assembly for a motor vehicle, such as a pressure relief valve (i.e., an air extractor), and a method of using the same. In an example, the valve assembly includes a flap moveable to between an open position and a closed position, a slider moveable along an axis and including an integrally formed arm in contact with the flap, and an electromagnet configured to be selectively activated to move the slider along the axis.

A passive explosion isolation valve (10) is provided that comprises vertically-oriented gate members (40, 42) configured to close automatically in response to an energetic event occurring downstream of the valve. The valve (10) may be optionally equipped with a valve seat cleaning assembly (46) configured to removed accumulated particulate material away from the area of the valve seat (48) and/or one or more latch assemblies (44) configured to secure the gate members (40, 42) in the closed position following closure of the valve (10) in response to an energetic event.

The present disclosure generally relates to an isolation device for use in processing systems. The isolation device has a body with an inlet opening disposed at a first end coupled to a processing system component such as a remote plasma source and outlet openings, for example two, disposed at a second end which are coupled to a processing system component such as a process chamber. Flaps disposed within the body are actuatable to an open position from a closed position or to a closed position from an open position, to selectively allow or prevent passage of a fluid from the processing system component coupled to the isolation device to the other processing system component coupled thereto.

A mechanical closure device comprises an enclosure having four sides, a top and bottom and defining a discharge opening at the bottom. A floodgate assembly is interiorly removably mounted to the enclosure and comprises a pair of doors pivoted on a hinge assembly between an opened position and closed position. In the closed position, the doors seal against the flange to prevent passage of water through the discharge opening. A discharge drain assembly is preferably disposed on one door and has an opened and a closed position. An appendage is provided to facilitate opening and of the door. Upon removal, the floodgate assembly is stably positionable on a multipositionable service rack. A multipurpose tool is employed unlatching the floodgate doors and slidably removing the floodgate assembly.