A valve unit has a fluid housing through which a fluid duct extends from a first opening across a valve seat to a second opening, a valve drive connected to the fluid housing and configured to drive a valve closing body cooperating with the valve seat, the valve closing body coming into contact with the fluid in operation on the face side facing the valve seat and on a side facing away from the valve seat, and a connecting plate having a connecting surface to which the fluid housing can be mounted and in which a fluid supply duct and a fluid outlet duct are formed. The fluid housing is adapted to be mounted to the connecting plate in a first position and in a second position rotated in relation to the first position through 180 degrees relative to an imaginary axis of rotation extending perpendicularly to the connecting surface, wherein during operation of the valve unit, with a direction of flow of the fluid through the connecting plate remaining unchanged, a flow over the seat takes place in the first position and a flow under the seat takes place in the second position.

A modular valve assembly can include a core spool module and a plurality of end connection modules. The end connection modules can be configured to be secured to the core spool module at one or more of a core inlet or a core outlet of the core spool module to provide one or more respective, different flow configurations for the modular valve assembly. The core spool module can include a bonnet portion that is integrally formed with the core inlet and the core outlet and a seat ring configured to provide a seal against flow of process fluid through the modular valve assembly.

An electropneumatic switch arrangement having an actuation device plurality of pneumatic outlets for connection to fluid-fillable devices, and a pneumatic supply connection for connection to a pressure source, the actuation device being connected to a sealing device, the actuation device being designed in such a way that, when it is actuated, it opens a predefined flow path between the supply connection and at least one of the outlets and, in doing so, closes a current path for actuating the pressure source, characterized in that the sealing device is mechanically coupled to the actuation device in such a way that at least a part of the sealing device is moved, in particular displaced, by the actuation device when this is actuated, thereby opening a flow path between the supply connection and at least one of the outlets.

A valve configuration parts kit for providing at least two valve configurations, including: a first plate-shaped main body, a plurality of wall-type webs attached to the plate-shaped main body which, conjointly with the plate-shaped main body, at least in part define fluid paths, and a second main body attached to the first main body, or a third main body attached to the first main body. The second main body contacts a first sub-quantity of the plurality of webs such that the first main body, the second main body, and the first sub-quantity define a first fluid path system for providing a first valve configuration. The third main body contacts a second sub-quantity of the plurality of webs such that the first main body, the third main body, and the second sub-quantity define a second fluid path system for providing a second valve configuration.

The invention relates to a method for producing a central housing part (1) of a high-pressure slide gate valve from high-temperature steel, in the case of which two die-forged central-housing-part half-shells (1a, 1b) with forged-on connectors (4a, 4b) are welded to one another, using electron-beam welding without any welding filler material, by a butt weld seam (2), which runs in a plane (3) which runs transversely to the connectors (4a, 4b) and subdivides the central housing part (1). In order to increase the creep resistance, and to reduce the weight, of such a central housing part, the production costs at the same time being advantageous, the invention proposes that the wall thicknesses of the central-housing-part half-shells (1a, 1b) should be designed overall on the basis of a weld strength factor (WSF=1), and that, once the weld seam (2) has been produced, the entire central housing part (1) should be subjected to a rigorous heat treatment involving heating to beyond the transformation temperature, quenching and tempering.

A valve device with a built-in orifice is manufacturable with low-cost. The valve body defines an accommodation recess which opens at the surface of the valve body and contains a valve element therein, a primary flow path and a secondary flow path connected to the accommodation recess, the valve element having a sealing portion for blocking direct communication between the primary flow path and the secondary flow path through the accommodation recess, and a through flow passage for making the primary flow path and the secondary flow path communicate through the valve element, wherein an orifice is formed in the through flow passage.

A modular valve assembly can include a core spool module and a plurality of end connection modules. The end connection modules can be configured to be secured to the core spool module at one or more of a core inlet or a core outlet of the core spool module to provide one or more respective, different flow configurations for the modular valve assembly. The core spool module can include a bonnet portion that is integrally formed with the core inlet and the core outlet and a seat ring configured to provide a seal against flow of process fluid through the modular valve assembly.

A valve unit has a fluid housing through which a fluid duct extends from a first opening across a valve seat to a second opening, a valve drive connected to the fluid housing and configured to drive a valve closing body cooperating with the valve seat, the valve closing body coming into contact with the fluid in operation on the face side facing the valve seat and on a side facing away from the valve seat, and a connecting plate having a connecting surface to which the fluid housing can be mounted and in which a fluid supply duct and a fluid outlet duct are formed. The fluid housing is adapted to be mounted to the connecting plate in a first position and in a second position rotated in relation to the first position through 180 degrees relative to an imaginary axis of rotation extending perpendicularly to the connecting surface, wherein during operation of the valve unit, with a direction of flow of the fluid through the connecting plate remaining unchanged, a flow over the seat takes place in the first position and a flow under the seat takes place in the second position.

A water part module for attaching to a piston pump, which has a support unit that can be releasably attached to the piston pump and at least respectively one suction module and pressure module that is releasably connected to the support unit. The support unit and each suction module and each pressure module are designed such that the suction and pressure modules are interchangeable with one another. Each suction and pressure module have at least two planed side faces of which one acts as a lower connection face and a side face adjoining the lower connection face acts as a lateral connection face. A duct inside the respective suction and pressure module, which can be closed and opened by a valve in the respective suction and pressure module, ends on one side in the lower connection face and on the other side in the lateral connection face.

A digital water timer may include a main body, a water valve, a locating base, a driving base, and a timer. The main body has a water inlet and a water outlet, and a valve tube protrudes from a lateral side of the main body. The water valve connected to the main body is controlled by the timer to achieve on/off operation of channels inside the main body. The locating base is secured on the main body, and the driving base is adapted to have rotation relative to the locating base and be secured at a specific position after rotated. The timer installed in the driving base comprises a display panel and an operation interface which are exposed externally for operation. The driving base with the timer is rotated relative to the locating base, and the display panel is adjusted as needed to provide an optimal view for operation.