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.

Example aspects of a valve key, a meter valve, and a method for securing a valve key of a meter valve are disclosed. The valve key for a meter valve can comprise a key body defining an upper key body end and a lower key body end, a key head extending from the upper key body end, and a key stem extending from the lower key body end, wherein the key stem, key head, and key body define a monolithic structure, the key stem defining an extension portion and a securing portion, the securing portion defining a securing portion engagement surface.

Example aspects of a valve key, a meter valve, and a method for securing a valve key of a meter valve are disclosed. The valve key for a meter valve can comprise a key body defining an upper key body end and a lower key body end, a key head extending from the upper key body end, and a key stem extending from the lower key body end, wherein the key stem, key head, and key body define a monolithic structure, the key stem defining an extension portion and a securing portion, the securing portion defining a securing portion engagement surface.

A method of preventing tampering with a hydrant includes inserting an operating stem of the hydrant through a central bore of an operating nut to mount the operating nut on the operating stem; and rotatably threading a grooved nut onto a threaded distal end of the operating stem, the grooved nut defining an indentation in an outer surface of the grooved nut, wherein: rotatably threading the grooved nut onto the threaded distal end of the operating stem comprises engaging the indentation with a mating groove tool and rotating the grooved nut with the mating groove tool.

A method of preventing tampering with a hydrant includes inserting an operating stem of the hydrant through a central bore of an operating nut to mount the operating nut on the operating stem; and rotatably threading a grooved nut onto a threaded distal end of the operating stem, the grooved nut defining an indentation in an outer surface of the grooved nut, wherein: rotatably threading the grooved nut onto the threaded distal end of the operating stem comprises engaging the indentation with a mating groove tool and rotating the grooved nut with the mating groove tool.

The present invention is an improved fluid valve control device which attaches to a pre-existing and pre-installed hex head valve. The valve control device has at least one lever which can be used to turn the valve on or off. This device can be attached to a manifold assembly that has a valve which typically requires a tool to control so that it eliminates the need for a separate tool being used to turn the valve on or off after installation at relatively low cost.

A connector assembly includes a first and a second component. Each of the components including a connector body, a valve, a handle, a handle lock, and a connector lock. The handles open and close respective valves. Each of the handles has locked and unlocked positions. The handle locks prevent or inhibit the respective handles from being moved between open and closed positions. The handle locks in unlocked positions enable the respective handles to be moved between open and closed positions. The first and second components are configured to be releasably assembled with each other. The connector locks in their respective closed positions assist in preventing or inhibiting the disassembling of the first and second components.

A connector assembly includes a first and a second component. Each of the components including a connector body, a valve, a handle, a handle lock, and a connector lock. The handles open and close respective valves. Each of the handles has locked and unlocked positions. The handle locks prevent or inhibit the respective handles from being moved between open and closed positions. The handle locks in unlocked positions enable the respective handles to be moved between open and closed positions. The first and second components are configured to be releasably assembled with each other. The connector locks in their respective closed positions assist in preventing or inhibiting the disassembling of the first and second components.

A lockout system and method are provided. The lockout system prevents unauthorized and inadvertent operation of any system requiring energy isolation by locking out and tagging out the controls. The lockout system includes a housing and a twist member that allows for selective configuration of the lockout system between a release and retention configuration. In the release configuration, the lockout system is adapted to be selectively positioned within the pipe and removed from the pipe. In the retention configuration, the lockout system is semi-permanently secured to the interior of the pipe via an engagement member. The housing and the twist member each comprise an aperture sized to align and receive a lock wherein once received the twist member is cooperatively secured to the housing via the lock in a locked configuration. In the locked configuration, the lockout system is secured to the pipe and prevents access to the pipe.