A self-draining transmitter mount head includes a head body with a transmitter process coupling port in the head body, an impulse port in the head body, and an impulse passage coupled to the impulse port. An impulse drain passage is coupled between the pressure transmitter port and the impulse passage. The impulse drain passage is positioned at an angle to the impulse passage, and relative to a head installation angle that positions the impulse drain passage to drain away from the transmitter process coupling port through a range of head installation angles.

Embodiments described herein are directed to regulating pressure and/or fluid flow within a system. In one scenario, a system for regulating pressure includes a controller, a pneumatic pressure regulator with a dome that adjusts pressure within the system, a current-to-pneumatic converter that converts an electrical current signal to a pneumatic pressure signal, and a pressure transducer. The controller receives an outlet pressure signal from the pressure transducer indicating a current level of system pressure, compares the current system pressure level to a desired system pressure level and, upon determining that the current system pressure level is above or below the desired system pressure level, sends an electrical current signal to the current-to-pneumatic converter that converts the electrical current signal to a pneumatic pressure signal that is sent to the dome of the pneumatic pressure regulator to raise or lower system pressure to the desired system pressure level.

An advance pneumatic detector to indicate pressure changes in an environment includes a switch, a pressure tube, an endcap, a piston, and a magnet. The pressure tube is connected to the switch. The endcap is disposed on an end of the pressure tube opposite from the switch. The piston is disposed within and forms a seal against the pressure tube. The piston is slidably engaged with the pressure tube. The magnet is slidably attached to and surrounds a portion of the pressure tube. The magnet is configured to control the positioning of the piston within the pressure tube.

Methods of compensating for undesired influences in a pressure transmitter wherein the pressure transmitter comprises a body for housing a low-pressure sensor and a high-pressure sensor each of which is in fluid communication with a port and in further fluid communication with each other through a connector tube containing a fill fluid. Various embodiments of the compensation process use one of the high-pressure and the low-pressure sensor as a common reference, compensating for changes in calibration, such as changes in the effective areas or spring rates of the non-reference sensor.

A testing device for vehicles includes a pressure gauge, a multidirectional joint, a quick combination unit, and a deflation valve unit. The pressure gauge has a main body provided with a connecting portion. The multidirectional joint has at least three openings communicating with each other. The multidirectional joint is directly disposed on the connecting portion of the main body, enabling gas to flow into the pressure gauge through one of the openings. The quick combination unit and the deflation valve unit are disposed on the other two openings respectively. Because the multidirectional joint is directly disposed on the main body of the pressure gauge, the main body uses the connecting portion thereof to be combined with the multidirectional joint, so that the component cost and the manufacturing time are effectively reduced, the manufacturing cost is lowered, the production yield rate and the product quality are highly improved.

There is provided a pressure measuring device including: a first pressure gauge connected to a processing chamber configured to process a process target and configured to measure an internal pressure of the processing chamber when the process target is being processed; a second pressure gauge connected to the processing chamber; and a first switching valve configured to disconnect the second pressure gauge from the processing chamber when the process target is being processed inside the processing chamber.

An apparatus and associated method, for controlling signal passage, includes a first passageway for a first fluid, a second passageway for a second fluid, and an interposed chamber. A first, movable diaphragm at a first chamber junction and a second, movable diaphragm at a second chamber junction, with a third fluid bound there between and interposed between the first and second passageways. A device varies a volume of the third fluid bound between the diaphragms and thus moves the diaphragms. A movable member and a reservoir of the device are configured such that the movable member is sufficiently movable to increase the volume of the reservoir to remove a sufficient portion of the third fluid bound between the first and second diaphragms from the chamber to cause the first and second diaphragms to be pressed against the first and second walls, respectively.

An apparatus and associated method, for controlling signal passage, includes a first passageway for a first fluid, a second passageway for a second fluid, and an interposed chamber. A first, movable diaphragm at a first chamber junction and a second, movable diaphragm at a second chamber junction, with a third fluid bound there between and interposed between the first and second passageways. A device varies a volume of the third fluid bound between the diaphragms and thus moves the diaphragms. A movable member and a reservoir of the device are configured such that the movable member is sufficiently movable to increase the volume of the reservoir to remove a sufficient portion of the third fluid bound between the first and second diaphragms from the chamber to cause the first and second diaphragms to be pressed against the first and second walls, respectively.

Methods of compensating for undesired influences in a pressure transmitter wherein the pressure transmitter comprises a body for housing a low-pressure sensor and a high-pressure sensor each of which is in fluid communication with a port and in further fluid communication with each other through a connector tube containing a fill fluid. Various embodiments of the compensation process use one of the high-pressure and the low-pressure sensor as a common reference, compensating for changes in calibration, such as changes in the effective areas or spring rates of the non-reference sensor.

A valved tap is disclosed comprising a tap body having a through bore from a threaded input end to an output end thereof. A globe valve is positioned in the valve body so as to interrupt the flow of fluid in the through bore. The output end of the tap body may comprise a flanged portion connectable to a manifold.