Improved flow control assemblies for fluid systems (e.g., industrial and/or commercial systems) are provided. More particularly, the present disclosure provides for advantageous ball valve assemblies for fluid systems. In exemplary embodiments, the present disclosure provides for improved ball valve assemblies and related features, systems and methods of use. Exemplary ball valve assemblies of the present disclosure offer advantages over conventional assemblies including, without limitation, advantages in the sealing mechanisms of the ball valve assemblies, and advantages with the user interfaces of the ball valve assemblies (e.g., advantages with the lockout mechanisms). Improved, convenient and effective systems and methods for utilizing improved ball valve assemblies in fluid systems are provided.

A pressure compensation device for a housing, in particular of a motor vehicle, having at least one pressure compensation valve, which has a casing surface on the inner circumference delimiting a volume of the pressure compensation valve through which a gaseous medium can flow, a casing surface on the outer circumference facing away from the casing surface on the inner circumference, and at least one pressure compensation opening, through which the medium can flow and which is delimited by wall regions of the pressure compensation valve formed from an elastically deformable material, and having at least one protective cap.

A pressure compensation device for a housing, in particular of a motor vehicle, having at least one pressure compensation valve, which has a casing surface on the inner circumference delimiting a volume of the pressure compensation valve through which a gaseous medium can flow, a casing surface on the outer circumference facing away from the casing surface on the inner circumference, and at least one pressure compensation opening, through which the medium can flow and which is delimited by wall regions of the pressure compensation valve formed from an elastically deformable material, and having at least one protective cap.

A valve assembly including a valve housing and a handle that is movable about an actuation axis to actuate a valve actuator within the valve housing between an open position and a closed position. The handle has a first opening and the valve housing has a second opening. When the valve actuator is in the closed position the first opening aligns with the second opening to enable receipt of a lockout member that prevents movement of the valve actuator from the closed position to the open position.

A valve assembly including a valve housing and a handle that is movable about an actuation axis to actuate a valve actuator within the valve housing between an open position and a closed position. The handle has a first opening and the valve housing has a second opening. When the valve actuator is in the closed position the first opening aligns with the second opening to enable receipt of a lockout member that prevents movement of the valve actuator from the closed position to the open position.

A system for exhausting hazardous stored energy from a pneumatic subsystem of a railcar, comprises: an air supply for delivering air to the pneumatic subsystem of the railcar; and an isolation valve interposed between the air supply and the pneumatic subsystem of the railcar. When the isolation valve is in a normal operating position, a supply port and a delivery port of the isolation valve are in fluid communication with one another, but when the sliding shoe is in the second position, the sliding shoe effectively closes access to the supply port, and the delivery port is in fluid communication with an exhaust port of the isolation valve. The isolation valve further includes a means for locking the sliding shoe in the second position.

A system for exhausting hazardous stored energy from a pneumatic subsystem of a railcar, comprises: an air supply for delivering air to the pneumatic subsystem of the railcar; and an isolation valve interposed between the air supply and the pneumatic subsystem of the railcar. When the isolation valve is in a normal operating position, a supply port and a delivery port of the isolation valve are in fluid communication with one another, but when the sliding shoe is in the second position, the sliding shoe effectively closes access to the supply port, and the delivery port is in fluid communication with an exhaust port of the isolation valve. The isolation valve further includes a means for locking the sliding shoe in the second position.

Segment isolating valves assembled on the lower back of the elevated guideway (1), the plug base (2) being hinged on a housing (3) fixed to the elevated guideway (1) by a flange (4) for fast connection and disconnection. The housing (3) is equipped with a rainwater runoff tank (5). The segment isolating valve comprises a plug (2) mounted in a housing (3) affixed to the elevated guideway by means of a flange (4) for fast connection and disconnection. The plug (2) is moved by means of a linear actuator (6), whose rod exerts force on an articulation (7), which is pivoted above on the plug (2) and below on a frame (8) affixed to the housing base (3). The assembly is mechanically locked through a closed position locking cam (9), displaced automatically by springs (10). A safety locking pin (11) is actuated by a release solenoid (12).

Segment isolating valves assembled on the lower back of the elevated guideway (1), the plug base (2) being hinged on a housing (3) fixed to the elevated guideway (1) by a flange (4) for fast connection and disconnection. The housing (3) is equipped with a rainwater runoff tank (5). The segment isolating valve comprises a plug (2) mounted in a housing (3) affixed to the elevated guideway by means of a flange (4) for fast connection and disconnection. The plug (2) is moved by means of a linear actuator (6), whose rod exerts force on an articulation (7), which is pivoted above on the plug (2) and below on a frame (8) affixed to the housing base (3). The assembly is mechanically locked through a closed position locking cam (9), displaced automatically by springs (10). A safety locking pin (11) is actuated by a release solenoid (12).

A fluid flow control unit adapted to control flow of fluid from a tap is disclosed. The fluid flow control unit comprises a vertical piece (101) extending along the length of the tap; and a horizontal piece (102) extending along a handle of the tap, wherein the vertical piece (101) and the horizontal piece (102) are sheet structures attached together at a predetermined angle, wherein one of sides (101a) of the vertical piece (101) is attached to one of sides (102a) of horizontal piece, and wherein a point of attachment of the vertical piece (101) and the horizontal piece is above the handle (105) of the tap.