A shut-off valve that has a closure orifice, a closure member to open and close a gas passage through the shut-off valve, an electromagnetic actuator including a movable assembly attached to the closure member, the closure member, and an electromagnetic filed generator magnetically associated with the movable assembly. The shut-off valve also includes a manual actuator for acting on the movable assembly, the manual actuator comprising an open position in which it is decoupled from the movable assembly, the electromagnetic actuator thus being able to act on the closure member to cause its closure.

A shut-off valve that has a closure orifice, a closure member to open and close a gas passage through the shut-off valve, an electromagnetic actuator including a movable assembly attached to the closure member, the closure member, and an electromagnetic filed generator magnetically associated with the movable assembly. The shut-off valve also includes a manual actuator for acting on the movable assembly, the manual actuator comprising an open position in which it is decoupled from the movable assembly, the electromagnetic actuator thus being able to act on the closure member to cause its closure.

A gas shut-off valve assembly designed to automatically close gas flow in a gas conduit in response to a seismic vibration comprises a door which may be parallel to a port in the conduit and a weight above the door. In some embodiments, the door may be mostly out of the conduit passageway and out of the gas flow allowing for improved gas flow efficiency in the normally open state. Upon sensing a seismic vibration, the weight falls from a platform onto the door causing the door to move into the conduit passageway sealing the passageway. In some embodiments, a port in the passageway is perpendicular to the door's default position in the open state. When the door closes the passageway, the door rotates ninety degrees about an axis into the second closed position to become parallel with the port.

A gas shut-off valve assembly designed to automatically close gas flow in a gas conduit in response to a seismic vibration comprises a door which may be parallel to a port in the conduit and a weight above the door. In some embodiments, the door may be mostly out of the conduit passageway and out of the gas flow allowing for improved gas flow efficiency in the normally open state. Upon sensing a seismic vibration, the weight falls from a platform onto the door causing the door to move into the conduit passageway sealing the passageway. In some embodiments, a port in the passageway is perpendicular to the door's default position in the open state. When the door closes the passageway, the door rotates ninety degrees about an axis into the second closed position to become parallel with the port.

Piston valve (10) with a hollow housing (13), an inlet (11) and an outlet (12) communicating with the inlet only through the piston valve (10), and a pushbutton (27) that can be moved in and out direction of the housing. A control valve (30) is also arranged in the inner cavity of the housing (13) spaced axially from the valve seat (14), and the opening and closing of the control valve (30) is controlled by the position of the pushbutton.

Piston valve (10) with a hollow housing (13), an inlet (11) and an outlet (12) communicating with the inlet only through the piston valve (10), and a pushbutton (27) that can be moved in and out direction of the housing. A control valve (30) is also arranged in the inner cavity of the housing (13) spaced axially from the valve seat (14), and the opening and closing of the control valve (30) is controlled by the position of the pushbutton.

A valve may have a fluid inlet and a fluid outlet. The valve may include a valve stem having a lumen extending from a first opening at a proximal portion of the valve stem to a second opening at a distal end of the valve stem. A plurality of seals may be positioned relative to the valve stem. The valve stem and seals may be configured so that a fluid entering the inlet is prevented from flowing to the outlet in a first position of the valve stem and relative to the inlet and the outlet. The valve stem and the seals may be configured so that a fluid entering the inlet flows to the outlet in a second position of the valve stem relative to the inlet and the outlet, the second position being more distal than the first position relative to the inlet and the outlet.

Actuator for actuating a valve device comprising an electric drive (14) being operatively engaged to an actuating element (1) of the valve device, the electric drive (14) comprising at least one torque motor (2) which drives a hollow shaft (3) as an internal rotor, that positions a threaded drive (4) having a screw nut (6) and a threaded spindle (5) for converting the rotational movement of the hollow shaft (3) into a translational movement of the threaded spindle (5), and the threaded spindle (5) acts upon the actuating element (1) for displacing the same, wherein the threaded drive (4) comprises an inverted roller screw (4.1), and the screw nut (6) of the inverted roller screw (4.1) houses the threaded spindle (5) as a push rod.

Valve element for an exhaust-gas turbocharger, having a spindle which has a longitudinal extent, a lever which extends from the spindle laterally in relation to the longitudinal extent of said spindle and which has a through opening, a valve flap plate, a substantially disc-shaped fastening element, and a shank which extends through the through opening and which connects the valve flap plate to the fastening element, wherein the valve flap plate and the fastening element are connected to one another by way of a shank extending through the through opening of the lever, and wherein a spring element is provided for generating a preload between shank and lever.

Valve element for an exhaust-gas turbocharger, having a spindle which has a longitudinal extent, a lever which extends from the spindle laterally in relation to the longitudinal extent of said spindle and which has a through opening, a valve flap plate, a substantially disc-shaped fastening element, and a shank which extends through the through opening and which connects the valve flap plate to the fastening element, wherein the valve flap plate and the fastening element are connected to one another by way of a shank extending through the through opening of the lever, and wherein a spring element is provided for generating a preload between shank and lever.