Disclosed is a system and method for monitoring flow rate of a regulating valve based on an acoustic sensor. The system includes: the regulating valve installed in a fluid pipeline, the regulating valve including an actuator and a valve body and being a regulating valve calibrated by an experimental platform; the acoustic sensor installed at the regulating valve and configured to collect an acoustic signal of the regulating valve and transmit the acoustic signal to a signal transmission apparatus; the signal transmission apparatus configured to receive the acoustic signal collected by the acoustic sensor and transmit the acoustic signal to an acoustic data analysis platform; and the acoustic data analysis platform configured to monitor flow rate of the regulating valve by receiving the acoustic signal transmitted by the signal transmission apparatus.

A multi-piece ball valve includes a body, a first closure piece attached to the body, the first closure piece and the body together defining an interior cavity. A ball is disposed in the interior cavity, the ball defining a bore extending through the ball. A load sensor ring is disposed in an annular cavity defined in an outer surface of the body between the body and the first closure piece. A pressure sensor is operable to sense fluid pressure between the body and the first closure piece. An electronic control system is in communication with the load sensor ring and the pressure sensor.

The present invention discloses a valve structure with a built-in valve seat of a pre-action warning valve, including: a valve body, a valve cap, a valve seat, and a membrane clack. The pre-action warning valve provided in the present invention has the advantages of being simple, reliable, and low in manufacturing costs.

A gas safety valve for controlling a gas flow includes a valve body providing a body inlet port for coupling to a first gas supply and a body outlet port for coupling to an appliance, the valve body extending along a longitudinal axis between the body inlet port and the body outlet port, the valve body further providing an inlet bore extending downstream from the body inlet port, and an outlet bore extending to the body outlet port. A valve has a valve chamber having a valve inlet and a valve outlet, a ball located within the valve chamber and a valve seat provided at the valve outlet such that the ball is retained in the valve chamber upstream of the valve seat. The valve body includes an internal junction positioned upstream of the valve inlet, and a side inlet port.

A diverter valve for an appliance such as a washing machine or the like provides a valve plate that can be moved by a DC motor both rotationally about an axis and axially along the axis to allow the valve plate to be retracted from engagement with a valve seat before rotation and reengaged after rotation permitting operation with a low-power DC motor.

Systems and methods to vent a tank to enhance transporting asphalt when positioned in the tank may include connecting a vapor box to a tank. The vapor box may include one or more vents apertures and a valve associated with the one or more vent apertures and positioned to provide fluid flow between the interior of the vapor box and the exterior. The systems and methods may also include communication via a selector with the valve to cause the valve to switch between an open condition and a closed condition. The selector may be located remotely from the valve, and the systems and methods may also include communication with an indicator via one or more of the valve or the selector to provide an indication of one or more of the valve in the open condition or the valve in the closed condition.

A valve assembly has a housing and a valve shaft rotatable in the housing. A sensor assembly detects the position of the valve shaft. The sensor assembly has an indicator on the housing; and a position sensor on the valve shaft configured to detect a feature of the indicator to determine the position of the valve shaft.

A system can include a solenoid manifold including a plurality of solenoid valves to control fluid flow between a tube and a plurality of nozzles, wherein one end of the tube is connected to a pump and the other end of the tube is connected to an inlet of the solenoid manifold; and a controller programmed to determine whether at least one solenoid valve of the plurality of solenoid valves is incorrectly in an open position based on pressure measurements representing a fluid pressure within the tube.

An overpressure indicator is defined by a housing sized and configured for attachment within a compartment interior, such as an aircraft nacelle. A pressure sensing element disposed within the housing is coupled to an indicator element and is configured to detect a pressure differential between the interior and exterior of the compartment. The indicator element is caused to move in response to a predetermined change in pressure exceeding a threshold pressure differential. The indicator element includes a distal end that is moved to a position exterior of the housing and the compartment, providing a visual indication of an overpressure condition. A reset feature provided on the indicator can only be accessed by first opening the compartment in which the indicator has been mounted. A spring can be provided to assist in the triggering of the indicator member after the threshold pressure differential has been detected.

A technique facilitates control over a downhole well operation. The technique utilizes an electronic control system for controlling actuation of a valve downhole. The valve, in turn, is operated to enable selective control over fluid flows governing the actuation of a downhole tool and/or other downhole operations. In some embodiments, the electronic control system may work in cooperation with a downhole hydraulic system to provide a downhole electro-hydraulically actuated valve system. A monitoring system provides feedback regarding the valve position and/or status of the downhole operation.