A diverter valve drive mechanism is provided with a valve body and a driving main body, wherein a valve piece is arranged inside the valve body, and by adjusting the rotation angle of the valve piece, the fluid flow through the valve body can be controlled, and the valve piece is controlled Driven by the drive main body connected to the valve body; the drive main body is provided with a driving assembly, the driving assembly is composed of a motor, a plurality of gear sets and a hand wheel, and the rotation angle of the valve piece can be controlled by a motor Adjusted or adjusted via hand wheel control, the driving assembly is provided with a Bluetooth module that allows the motor to be controlled and driven via the remote.

A valve actuator has an actuator body and a valve attachment part. Further, the actuator body has a case, a motor, a belt transmission part, and a worm reduction gear. Further, the actuator body has a bracket part.

A valve actuator has an actuator body and a valve attachment part. Further, the actuator body has a case, a motor, a belt transmission part, and a worm reduction gear. Further, the actuator body has a bracket part.

A valve actuator has an actuator body and a valve attachment part. Further, the actuator body has a case, a motor, a belt transmission part, and a worm reduction gear. Further, the actuator body has a bracket part.

A valve actuator has an actuator body and a valve attachment part. Further, the actuator body has a case, a motor, a belt transmission part, and a worm reduction gear. Further, the actuator body has a bracket part.

A fluid-drive device includes a base, a fluid container, a pressing mechanism, and a rotation mechanism. The fluid container is disposed on the base. The pressing mechanism is disposed on the base, and configured to press the fluid container. The rotation mechanism is connected to the pressing mechanism. The pressing mechanism presses the fluid container by rotating the rotation mechanism. The fluid-drive device may guide the flow of the detection fluid in the fluid container in a non-contact manner to reduce the contamination of the fluid specimen and increase the reliability of the detection.

A method for automatically opening or closing a gas barrel valve, includes: loading and aligning a gas barrel in a cabinet; separating an end cap from the gas barrel; screw-coupling a connector holder to a gas spray nozzle, from which the ends cap has been removed; winding a spring around a first shaft by enabling forward rotation of the first shaft while suppressing reverse rotation of the first shaft, which is installed in a valve handle holder so as to idle; opening a valve by enabling reverse rotation of a valve handle of the gas barrel while preventing forward rotation of the valve handle holder; and automatically closing the valve at the time of replacement of the gas barrel or when a gas leak is detected.

A wellhead valve control system includes a removable actuator adapted to couple to a valve, the valve being operable via a first operational mode. The system also includes an actuator element associated with the removable actuator, the actuator element operable to modify the first operational mode of the valve to a second operational mode, the second operational mode being different from the first operational mode. The system further includes a control panel, positioned remotely from the valve, the control panel configured to control the actuator element to adjust a valve position in the second operational mode.

Provided is a butterfly valve configured so that the sealing performance of the butterfly valve is ensured even if the butterfly valve is exposed to high-temperature fluid and is installed in a high radiation environment. A butterfly valve has: a valve body-side valve seat section which is formed on the outer periphery of a valve body; a valve box-side valve seat section which is formed on a valve box; and a valve movement mechanism which, as a valve shaft pivots, moves the valve body in the direction of extension of a flow passage, between a blocking position at which the valve body-side valve seat section and the valve box-side valve seat section are in contact with each other to close a flow passage, and an open position at which the valve body-side valve seat section and the valve box-side valve seat section are separated from each other to open the flow passage. The valve body-side valve seat section is formed from a laminated material comprising a stainless steel plate and a plate-shaped body which consists of expanded graphite.

A valve assembly includes a housing, an actuator, a plunger, a cover, a valve body, and a manual override unit. The actuator is received within the housing and is disposed between a first annular wall and a second annular wall. The plunger is movably disposed within a plunger cavity that is defined by the base and the second annular wall. The cover is disposed on the housing. The valve body is connected to the housing. The valve body has an end wall that defines an outlet port, an annular wall that axially extends from the end wall and defines an inlet port, and a flange that extends from the end wall and engages the cover. The manual override unit is operatively connected to the plunger.