A fault diagnosis method is provided for an evaporated fuel processing device including a canister including a charge port connected to an upper space of a fuel tank, a purge passage connecting a purge port of the canister and an intake system, and including a purge control valve, a drain passage including a drain cut valve, and a pressure sensor. The pressure sensor is configured to sense, as a purge passage pressure, a pressure between the purge control valve and the canister in the purge passage. The fault diagnosis method includes performing a purge by opening the purge control valve in a state in which the drain cut valve is controlled to be opened; measuring an actual pressure variation by the pressure sensor; and diagnosing a closing fixation of the drain cut valve by comparing a predetermined pressure variation and the actual pressure variation.

A device for inspecting a semiconductor equipment air valve for leaking is provided. The device includes: an air valve configured to generate a high vacuum state; an inspection device body installed on a first side of the air valve; a sensor part installed on a first side of the inspection device body to sense audio data, pressure data, video data, displacement data, infrared data, and ultrasound data of the air valve; an MCU installed inside the inspection device body; a screen output part installed outside the inspection device body to output image data; and a voice output part installed on the first side of the inspection device body to output voice data.

A plasma processing apparatus in which each of a plurality of source gas supply paths includes a first valve, a second valve disposed on an upstream side of the first valve, a flow rate regulator disposed between the first valve and the second valve, and a connection unit between the source gas supply path and an inert gas supply path. For each of the source gas supply paths, leakage in the first valve is sequentially determined, in a first inspection step, using a flow rate of the inert gas passing through the flow rate regulator, and in a second inspection step of, supplying the inert gas and detecting the leakage of the first valve on the source gas supply path using a change amount of a pressure of the inert gas if it is not determined in the first inspection step that there is a leakage in the first valve.

A process for aging gas lift valves utilizing a controlled decompression to prevent damage to seals of the gas lift valves. The process includes pressuring one or more gas lift valves to a predetermined pressure (e.g., 5000 psig) and maintaining this pressure for a predetermined time (e.g. five minutes). After this time period, decompression is performed in discrete steps. For instance, the pressure of the pressure vessel may be reduced in predetermined pressure increments (i.e. reductions). After each pressure reduction, the reduced pressure is maintained for a predetermined time. This allows gasses and fluids within the elastomeric O-rings time to dissipate without causing damage to the seals.

An arrangement for detecting a hydrogen leak in a hydrogen supply system includes a hydrogen tank for providing hydrogen, a hydrogen supply line for supplying the hydrogen from the hydrogen tank to a hydrogen consumption unit, and a restrictor unit arranged in the supply line for limiting the flow of the hydrogen in the supply line. A pressure difference sensor unit generates a pressure difference signal representing a pressure difference across the restrictor unit. A control unit coupled to the pressure difference sensor unit compares the pressure difference signal with a predefined threshold value and provides a leak detection signal if the pressure difference signal exceeds the threshold value.

A system includes: a state module configured to selectively set a present state to a first state; a valve control module configured to determine first target open and closed states for valves of a suspension system based on the present state and to open and close the valves according to the first target open and closed states, respectively; a pump control module configured to, when the valves are in the first target open and closed states, respectively, selectively operate an electric pump in a first direction to increase hydraulic fluid pressure in a first portion of the suspension system; and a leak module configured to selectively diagnose a leak in a first one of the valves associated with the first state based on a first pressure in the first portion of the suspension system while the valves are open and closed according to the first target open and closed states.

A state module selectively sets a present state to a first state in a predetermined order of states; a valve control module determines first target open and closed states for valves of a suspension system based on the present state and opens and closes the valves according to the first target open and closed states, respectively; a pump control module configured to, when the valves are in the first target open and closed states, respectively, selectively operate an electric pump of the suspension system in a first direction and pump hydraulic fluid toward the suspension system; and a diagnosis module configured to: record first and second values of pressures within the suspension system measured using pressure sensors, respectively, before and after the operation of the electric pump in the first direction, respectively; and selectively diagnose faults in a first subset of the valves based on whether pressure increases occurred.

A diaphragm assembly for a pressure relief valve can include a disc guide that is configured to receive a portion of a disc holder, a bonnet adapter, and a diaphragm that is clamped at an outer edge between the disc guide and the bonnet adapter. The diaphragm assembly can be positioned between a bonnet of the pressure relief valve and a valve body of the pressure relief valve to convert the pressure relief valve to a backpressure-balanced pressure relief valve by counterbalancing a backpressure that acts upon the disc holder.

Embodiments of air admittance valve assembly and plumbing system incorporating the same are provided herein. In some embodiments, a valve assembly to allow or stop a flow for use with enclosed environment includes a housing having, an inlet disposed at a first end of the housing fluidly coupled to environment surrounding housing, an outlet disposed at a second end of housing fluidly coupled to enclosed environment, and an interior volume divided into a first zone, a second zone, and a third zone, a first valve having a first valve seat and a first sealing member urged by an existing force between a closed or open position; and a second valve having a second valve seat and a second sealing member urged by an existing force between a closed or open position.

A detection system includes a pressure sensor configured to contact an annular elastomer component of an annular BOP, wherein the pressure sensor is configured to generate a first signal indicative of a contact pressure with the annular elastomer component. The detection system also includes a piston stroke sensor configured to generate a second signal indicative of a piston stroke distance. The detection system further includes a controller configured to receive the first signal from the pressure sensor and the second signal from the piston stroke sensor and analyze respective changes in the contact pressure and respective changes in the piston stroke distance to determine a condition of the annular BOP.