The present invention relates to an emergency control device for a spring return valve actuator, the device including: a power source unit for receiving an alternating current (AC) power source, converting and stepping down an AC voltage of the received AC power source to a given direct current (DC) voltage, and supplying the DC voltage, and transmitting a signal as to whether the power source is supplied; a charge unit for receiving the DC voltage from the power source unit to store electrical energy with a given voltage; and a control unit for receiving the DC voltage from the power source unit to supply the received DC voltage to the electromagnetic brake, and if a power source cutoff signal is received from the power source unit, for supplying the electrical energy stored in the charge unit to the electromagnetic brake for a given set time.

A multi-orifice plate flow valve system is disclosed which comprises a flow control valve including a multi-orifice plate and a plurality of gear wheels. The flow rate through the valve system can be adjusted through a gear train manually via a handle and/or automatically via a motor. Orifices having different size apertures can be rotated into the transport path within the same flow control valve. The multi-orifice plate can include setting indicators, which visually communicates to a user the size of orifice aperture in the transport path. In some embodiments, a pressure transducer and/or gear position sensor can provide determination of flow rate through the valve system.

An actuator mounting kit and method for mounting an automatic valve actuator to a manually operated valve. The mounting kit includes a mounting bracket and a stem driver. The mounting bracket is connectable to the valve and has a bottom portion with a stem aperture through which a valve stem is extendable and a tongue matingly engageable with a slot of the valve body. The mounting bracket has an upper portion with a driver aperture aligned with the stem aperture. The stem driver has a first end matingly engageable with the valve stem and a second end extendable through the driver aperture in a way that the actuator is matingly enageable with the second end of the stem driver when the actuator is connected to the upper portion of the mounting bracket.

An apparatus, system, and method are disclosed for optimizing a valve orifice shape. According to one representative embodiment, a method includes determining a specified relationship between a valve position and an output characteristic, and determining an orifice profile. The method also includes determining a relationship of an orifice area to the output characteristic. Further, the method includes shaping an orifice in a valve based on the orifice profile and the specified relationship between the valve position and the output characteristic. According to the method, the valve should approximately exhibit the specified relationship.

A starter air valve has a valve member and an actuator. A rotary spool valve has a rotatable valve body and an outer housing to selectively provide three modes of operation for the starter air valve. A first mode of operation connects air through the rotatable valve body to communicate with an actuator control, and to receive air back from the actuator control. The rotatable valve body then communicates the air to the actuator. In a second mode the rotatable valve body blocks communication between the actuator control and the actuator, and delivers air through a variable area port in a wall of the rotatable valve body to bypass the valve member. In a third mode the rotatable valve body blocks communication between the actuator and the actuator control, and connects air to the actuator without having passed to the actuator control. A starter air system is also disclosed.

A valve actuator assembly that include an actuator and an actuator mounting assembly. The actuator mounting assembly may be secured to a valve shaft without the actuator present, and the actuator may be secured to the actuator mounting assembly later. This can make it easier to mount the actuator mounting assembly, especially in cramped spaces. In some cases, the actuator may be wired where it is convenient, and then moved to the actuator mounting assembly and secured to the mounted actuator mounting assembly, sometimes with a simple snap attachment. In some cases, a button, lever or other mechanism may release the actuator from the actuator mounting assembly for easy removal.

A leak detection and prevention system includes a gear motor linkage assembly. The gear motor linkage assembly includes a gear motor and a gear motor controller/driver module that controls operation of the gear motor. The gear motor linkage assembly also includes a push lever attached to a shaft of the gear motor, the push lever in a home position, wherein when a signal indicating that a leak has been detected is received the gear motor controller/driver module controls the gear motor to rotate the push lever so that the push level non-captively engages a handle of a valve and pushes the handle to a closed position, then the gear motor controller/driver module controls the gear motor to rotate the push lever to the home position.

The specification describes methods and apparatus for coupling a rotary-actuated valve to a valve actuator that is configured to rotate a valve member within the valve. A shaft coupling assembly is used to provide a rotatable connection between the valve actuator and a valve actuation shaft through use of a clamp assembly which is moveable from non-engagement with the valve actuation shaft to secure engagement with opposing flats on the valve actuation shaft. Also described is a novel bracket assembly configured to support a valve and valve actuator in a desired spaced relation to one another which is sufficient to accommodate the described shaft coupling assembly.

A failsafe module comprising an input member (310), an output member (312), and a coupling mechanism for coupling the input member to the output member. The coupling mechanism comprises an intermediate member (316a) movable relative to the output member to energise an energy storage device and a latch mechanism (318, 320) to hold the energy storage device in an energised state. When the latch mechanism is engaged, the input and output members are coupled together and the energy storage device is held in an energised state and isolated from the coupling between the input and output members. When the latch mechanism is released, the energy storage device can release its energy to drive the output member to a predetermined position.

An electric actuator includes a housing, an electric driving unit, an selector member being rotatable about a rotation axis and moving in a direction of the rotation axis, a position holding member and detection object provided in the selector member, a detector, an engagement groove provided on a cooperation surface inside the housing, and a biasing member biasing the selector member in the direction of the rotation axis to make the position holding member approach the cooperation surface. The engagement groove is formed so that the detection object is positioned in one of a detectable area and an undetectable area when the position holding member is engaged with the engagement groove, and the detector is configured to switch between supply and cutoff of power to the electric driving unit in accordance with whether or not the detection object is detected.