A device (1) for controlling the flow of fluid through a conduit from an upstream side (3) to a downstream side (5). The device includes a housing (4) with a wall (6) having valve apertures (8) through which the flow of fluid is selectively controlled. A valve member (10) is mounted on one side of the wall of the housing and is arranged to move reciprocally to selectively open and close the valve apertures. A removable insert (12) is mounted on the opposite side of the wall of the housing from the valve member. The removable insert is arranged to cover some of the valve apertures.

A valve comprises a valve seat and a rotary valve element. The valve seat comprises a valve opening having a sealing surface. The valve element is mounted with respect to said valve seat for rotation about an axis of rotation between a closed position in which the valve element substantially closes the valve opening and an open position in which the valve element permits flow through the valve opening. The valve opening is elliptical in shape, having spaced apart upper and lower edges the upper and lower edges being generated as respective ellipses formed by parallel sections through a conical surface. The valve seat sealing surface is defined between said upper and lower edges.

A valve comprises a valve seat and a rotary valve element. The valve seat comprises a valve opening having a sealing surface. The valve element is mounted with respect to said valve seat for rotation about an axis of rotation between a closed position in which the valve element substantially closes the valve opening and an open position in which the valve element permits flow through the valve opening. The valve opening is elliptical in shape, having spaced apart upper and lower edges the upper and lower edges being generated as respective ellipses formed by parallel sections through a conical surface. The valve seat sealing surface is defined between said upper and lower edges.

A fluid flow control device includes a valve body defining an inlet, an outlet, and a fluid flow path extending therebetween, a rotatable valve member at least partially disposed in the valve body, an attenuator operably coupled to the valve body, and a retention member disposed within the valve body. The rotatable valve member is rotatable within the fluid flow path from a shut-off position to an open position for controlling the flow of fluid through the fluid flow path. The attenuator defines an attenuator body that includes a plurality of noise-reducing apertures. The retention member is positioned against a portion of the attenuator body to retain the attenuator within the valve body.

To suppress increase of a pressure loss in a channel and blocking of the channel due to water adhering to a rectification mesh provided downstream of a butterfly valve. A fuel cell system includes: a butterfly valve provided on a pipe between a fuel cell and another component; and a rectification mesh provided on a downstream side of gas flowing in the pipe relative to the butterfly valve, a mesh that rectifies a flow of the gas being formed in the rectification mesh. The rectification mesh has, in its lower end part in a vertical direction, a first opening part in which the mesh is not formed.

To suppress increase of a pressure loss in a channel and blocking of the channel due to water adhering to a rectification mesh provided downstream of a butterfly valve. A fuel cell system includes: a butterfly valve provided on a pipe between a fuel cell and another component; and a rectification mesh provided on a downstream side of gas flowing in the pipe relative to the butterfly valve, a mesh that rectifies a flow of the gas being formed in the rectification mesh. The rectification mesh has, in its lower end part in a vertical direction, a first opening part in which the mesh is not formed.

A hydrostatic bearing assembly including a bearing and two membrane throttles is provided. The bearing is adapted to be movably disposed on a slide rail and includes two sub-bearing portions that are disposed opposite to each other on two opposite sides of the slide rail. The two membrane throttles are adapted to be connected to a pump. The pump is adapted to supply a fluid through the two membrane throttles to flow between the two sub-bearing portions and the slide rail, and each of the membrane throttles includes a casing and a throttling membrane piece. At least one of the casing and the corresponding sub-bearing portion includes a chamber, an inlet and an outlet communicating with the chamber, and an outlet surface, wherein the pump is adapted to be connected to the inlet, and the slide rail is adapted to be disposed adjacent to the outlet. The throttling membrane piece is being positioned in the chamber covers on the outlet surface.

A cage for a fluid valve. The cage includes a first cage ring, a second cage ring, and a lattice structure disposed between the first cage ring and the second cage ring. The lattice structure defines a plurality of interconnected flow paths between an internal surface of the lattice structure and an external surface of the lattice structure. The lattice structure has a non-uniform density.

A cage for a fluid valve. The cage includes a first cage ring, a second cage ring, and a lattice structure disposed between the first cage ring and the second cage ring. The lattice structure defines a plurality of interconnected flow paths between an internal surface of the lattice structure and an external surface of the lattice structure. The lattice structure has a non-uniform density.

A pressure control system configured to respond to high-pressure conditions in a fluid conduit is disclosed. The system generally includes first and second flow restrictors positionable inline on a fluid conduit and configured to block fluid flow in the conduit and respond to a high-pressure event to allow fluid flow therethrough. The first flow restrictor is position upstream from the second flow restrictor and may open to allow fluid flow in response to the high-pressure event. The second flow restrictor provides adjustable flow of fluid therethrough or may open a bypass line in response to the high-pressure event to allow unrestricted fluid flow therethrough.