A system for igniting a grill can include a solenoid valve, a flame rectification sensor, an igniter, and a control circuit connected to the solenoid valve and the flame rectification sensor. The solenoid valve controls flow of gas to the grill's burner and includes a switch that closes when a handle connected to the switch opens the solenoid valve. The control circuit sends current to the solenoid valve when the switch is closed to hold the solenoid valve open. After the switch closes, the igniter is ignited. After ignition, the control circuit monitors the presence of a flame with a flame rectification sensor. If no flame is detected after a certain amount of time, the control circuit stops sending current to the solenoid valve to close the solenoid valve.

A butterfly valve has a rod connected to a DD motor and disposed along a direction orthogonal to a flow path, and a butterfly valve body that is linked to the rod and that opens and closes the flow path due to the rod being rotated by the DD motor, wherein a linking body center of gravity, which is the center of gravity of a rotating liking body having at least the rod and the butterfly valve body as constituent members, is positioned on an axial line of a rotating shaft of the DD motor.

A pressure relief valve configured to vent a pressurized tank in the event of a fire is provided. The pressure relief valve includes a body, a vent passage, a plug and a latch. The vent passage is disposed through the body. The vent passage can be placed in fluid communication with an internal volume of a tank and with the atmosphere. The plug is moveably mounted in the vent passage. The latch has a blocking member disposed in contact with a control end of the plug in a first configuration and out of contact with the control end in a second configuration. The second configuration allows movement of the plug in the vent passage. One or both of a shape memory alloy wire and a trigger piston is configured to actuate the latch from the first to the second configuration. The shape memory alloy wire is configured to shorten when exposed to a temperature above a threshold temperature. The trigger piston moves, e.g., by a pressurized gas, in a trigger actuation passage to actuate the latch from the first configuration to the second configuration.

An emergency shutdown (ESD) system for a process control system includes an air supply coupled to a solenoid valve used to control a pneumatically-operated emergency isolation valve (ZV) via a switchover kit, a smart valve positioner coupled to the solenoid valve via the switchover kit, and an ESD controller. The ESD controller is configured to: control the supply of air from the air supply by the solenoid valve to open and close the ZV, and control the smart valve positioner so as to perform a partial stroke test on the ZV. The switchover kit includes a manifold having a plurality of valves coupling the air supply, the solenoid valve, and the smart valve positioner such that: based on a first setting of the plurality of valves, a first air flow path through the manifold connects the air supply directly to the solenoid valve, and based on a second setting of the plurality of valves, a second air flow path through the manifold connects the air supply to the solenoid valve through the smart valve positioner.

Provided is a fluid drive valve, which facilitates continuation of monitoring all the time, and which allows detection of leakage of an operation fluid from an actuator even when the actuator is operating. A pressure sensor is disposed on a pressure receiving surface, inside an actuator, on which pressure of an operation fluid acts. A pressure sensor is disposed on a non-pressure receiving surface, inside the actuator, on which pressure of the operation fluid does not act. In addition, a position sensor is disposed to detect the position of a valve stem.

In one embodiment, a multi-purpose sensor may couple to a machine operating in an industrial environment and include numerous sensors disposed within the multi-purpose sensor to acquire sets of data associated with the machine or an environment surrounding the machine. A first portion of the sets of data may include historical sensor measurements over time for each of the sensors, and a second portion of the sets of data may include sensor measurements subsequent to when the first portion is acquired for each of the sensors. A processor of the multi-purpose sensor may determine a baseline collective signature based on the first portion, determine a subsequent collective signature based on the second portion, determine whether the collective signatures vary, and generate signals when a variance exists. The signals may cause a computing device, a cloud-based computing system, and/or a control/monitoring device to perform various actions.

A device for discharging fuel vapor from a fuel supply system for an internal combustion engine has a container which is situated in the fuel supply system and contains liquid fuel under an upwardly limited pressure. A discharge line, which leads to a tank venting system, leads out of the container. The device also has a detector for detecting vaporous fuel in the container and a blocking device which is coupled to the detector and with which the discharge line can be opened or blocked depending on the detection. A method for discharging fuel vapor from a fuel supply system for an internal combustion engine continuously detects whether vaporous fuel is also present in the container which is situated in the fuel supply system and contains the liquid fuel under an upwardly limited pressure; opens the discharge line if the vaporous fuel has been detected and blocks the discharge line if no vaporous fuel has been detected; and discharges the vaporous fuel through the opened discharge line while retaining the liquid fuel.

A diaphragm valve having a movable diaphragm (20) configured as a closure element has a valve housing (6) and an actuator (8), the diaphragm (20) being clamped between a flange (18) of the valve housing and a base (10) of the actuator (8) and being provided with a first identification means (32) in which data which are adapted to be read out wirelessly are stored. A further identification means (50, 56) is also fastened to the flange (18) and/or the base (10). The read-out surfaces of the further identification means (50, 56) are substantially at right angles to the read-out surface of the identification means (32) on the diaphragm (20).

A valve system includes a bellows-type pressure relief valve and an attachment assembly. The bellows-type pressure relief valve includes a main housing defining a main chamber, an inlet opening, and an outlet opening, a bonnet housing defining a bonnet chamber and a bonnet vent in the bonnet housing, and a bellows structure defining a bellows chamber fluidly connected to the bonnet chamber. The attachment assembly is coupled to the bonnet vent to selectively plug the bonnet vent. The attachment assembly include a coupling to couple to the bonnet vent, a pressure sensor to detect a pressure in the bonnet chamber, and a vent structure including a vent valve to selectively open in response to an applied force or in response to the pressure sensor detecting a pressure in the bonnet chamber reaching a pressure threshold.

A valve actuator (18) for a valve (10) is described, comprising a dielectric elastomer converter module (20) having two opposite ends (20a, 20b). Each end (20a, 20b) is provided with at least one connection element (22) for coupling the valve actuator (18) to a retaining part (24) and an actuating part (26) of the valve (10), respectively. Each end (20a, 20b) is connected to the respectively associated connection element (22) via an adhesive bond. Furthermore, a valve (10) having such a valve actuator (18) is presented.