A split body, rotary C gate, removeable stem vacuum valve using an input assembly with handle extensions that allow for hand movement of the incoming pipe to access an inner aperture body with a curved sealing face that directly seals to a C shaped gasketless gate that can be rotated into and out of the inner body aperture for easy cleaning. The gasketless gate is held in position using gate axles with an outer axle stem connected to a polygon lower body that mates into a matching polygon aperture on the gasketless gate. The middle valve assembly's gasketless housing body defines upper and lower axle washer pockets for locating the axles for proper operation and simple axle pins for securing the axles in position.

Methods and apparatus to load a valve packing are described. An example load apparatus to load a valve packing includes a guide including a flange and a wall protruding from the flange. The wall defines a cavity to receive a biasing element and a stop movable between a non-active state and an active state. The stop in the non-active state to enable movement of the guide in a first rectilinear direction relative to a longitudinal axis of a packing bore of a fluid valve and the stop in the active state to prevent movement of the guide in the first rectilinear direction. The stop to control an amount of deflection of the biasing element in the first rectilinear direction when the stop is in the active state.

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.

Integrated flow meter and control valve (1) including a flow tube (11); a substantially watertight meter housing (12) providing a compartment (121), extending from the flow tube; a metering unit (139 arranged inside the compartment for measuring the flow of a medium flowing though the flow channel, and an electrical valve actuator (18) arranged inside the compartment and adapted to control a flow control element (19) arranged inside the flow channel, wherein that meter housing is formed as an integrated part of the flow tube with the compartment having a primary opening (124) for insertion of the metering unit and a secondary sealable opening (125) for insertion of the electrical valve actuator.

A ball valve with internal sealing arrangement for use in motor vehicle refrigerant circuits The ball valve includes an actuator, a shaft with shaft bearing, a ball with a ball passage conduit, and a valve housing with refrigerant connections. The ball is supported in the valve housing in a floating manner and is arranged between two ball seal seats. A first ball seal seat is received by the valve housing and is supported in a sealing manner against the valve housing by a first sealing seat seal. A second ball seal seat is received by a closure part in the opposing valve housing and is supported in a sealing manner against the valve housing by a second sealing seat seal. A first expansion notch and a second expansion notch extend from the ball passage conduit toward a chamber formed in the valve housing.

A ball valve structure includes a valve body having a valve chamber therein. A valve ball is accommodated in the valve chamber. The valve ball defines a flow hole therein. Two gaskets are in close contact with two opposite side surfaces of the valve ball, so that the valve ball can rotate around a fixed point in the valve chamber. One side of one of the two gaskets abuts against a washer and a compression spring, so that the gasket is elastically pressed against a surface of the valve ball. A valve stem is connected to the valve ball through the valve body for driving the valve ball to rotate, enabling the flow hole to be opened.

Methods and apparatus to load a valve packing are described. An example load apparatus to load a valve packing includes a guide including a flange and a wall protruding from the flange. The wall defines a cavity to receive a biasing element and a stop movable between a non-active state and an active state. The stop in the non-active state to enable movement of the guide in a first rectilinear direction relative to a longitudinal axis of a packing bore of a fluid valve and the stop in the active state to prevent movement of the guide in the first rectilinear direction. The stop to control an amount of deflection of the biasing element in the first rectilinear direction when the stop is in the active state.

A valve for regulating a fluid flow includes a body portion, a tail portion, and a coupling mechanism joining the body portion to the tail portion. The coupling mechanism includes a plurality of body portion lugs, each body portion lug being separated from an adjacent body portion lug by a body portion opening. The coupling mechanism also includes a plurality of tail portion lugs, each tail portion lug being separated from an adjacent tail portion lug by a tail portion opening. In operation, each body portion lug is adapted to axially move through a corresponding tail portion opening to transition an axial position of the tail portion relative to the body portion, at least one of the tail portion or the body portion being rotatable axially a body portion lug with a tail portion lug to block axial movement of the tail portion relative to the body portion.

A valve for regulating a fluid flow includes a body portion, a tail portion, and a coupling mechanism joining the body portion to the tail portion. The coupling mechanism includes a plurality of body portion lugs, each body portion lug being separated from an adjacent body portion lug by a body portion opening. The coupling mechanism also includes a plurality of tail portion lugs, each tail portion lug being separated from an adjacent tail portion lug by a tail portion opening. In operation, each body portion lug is adapted to axially move through a corresponding tail portion opening to transition an axial position of the tail portion relative to the body portion, at least one of the tail portion or the body portion being rotatable axially a body portion lug with a tail portion lug to block axial movement of the tail portion relative to the body portion.

The present invention is to provide a valve state grasping system that can be easily retrofitted to any of various existing or operating valves (rotary valves) and actuators, and in particular, even facilities to which commercial power is not supplied, and allows detailed and accurate state grasping and diagnosis or failure prediction for the valve or actuator. The valve state grasping system is configured to perform, based on angular velocity data of a valve stem which opens and closes the valve, state monitoring, diagnosis, and life prediction of this valve. To the valve stem, a monitoring unit having at least a semiconductor-type gyro sensor is attachably and detachably fixed. The angular velocity data includes angular velocity data acquired from this monitoring unit in accordance with a rotational motion of a valve body from being fully open or fully closed to fully closed or fully open.