A MEMS photoacoustic gas sensor includes a first membrane and a second membrane opposing the first membrane and spaced apart from the first membrane by a sensing volume. The MEMS photoacoustic gas sensor includes an electromagnetic source and communication with the sensing volume to deflect the first membrane and the second membrane.

The present invention relates to a differential pressure sensor for a leak detection device comprising: at least two bodies in which a cavity is created; a membrane that is arranged between the two bodies and separates said cavity so as to define a test chamber in each one of said bodies; at least one electrode arranged in each one of the test chambers and facing said membrane so as to form therewith a capacitor;
characterised in that said sensor comprises at least two seals arranged between each of said bodies and the membrane.

Pressure sensor systems that include a pressure sensor die and other components in a small, space-efficient package, where the package allow gas or liquid to reach either or both sides of a membranes of the pressure sensor die. A package can include a substrate and a cap, where either or both the substrate and the cap divide the package internally into two chambers. The substrate can have a solid bottom layer, a middle layer having a slot or path running a portion of the length of the layer, and a top layer having two through-holes that provide access to the slot or path. The cap can have two ports. A first port can lead to a first chamber where a top side of a pressure sensor is in the first chamber. A second port can lead to a second chamber and the slot or path, where the slot or path leads to a bottom side of the pressure sensor.

A micromechanical component for a pressure and inertial sensor device. The component includes a substrate having an upper substrate surface; a diaphragm having an inner diaphragm side oriented towards the upper substrate surface and an outer diaphragm side pointing away from the upper substrate surface, the inner diaphragm side bordering on an inner volume, in which a reference pressure is enclosed, and the diaphragm being able to be warped using a pressure difference between a pressure prevailing on its outer diaphragm side and the reference pressure; and a seismic mass situated in the inner volume, a sensor electrode, which projects out on the inner diaphragm side and extends into the inner volume, being displaceable with respect to the substrate due to a warping of the diaphragm. A pressure and inertial sensor device, and a method of manufacturing a micromechanical component for a pressure and inertial sensor device, are also described.

A sensing device includes a body having a first chamber, a second chamber, and a liquid path which are filled with a liquid, the liquid path communicates with the second chamber, a pressure difference detection chip installed in the first chamber, and a pressure detection chip installed in the first chamber. The pressure difference detection chip seals an opening of the liquid path disposed on a bottom surface of the first chamber. The pressure difference detection chip detects a liquid pressure difference between the first chamber and the second chamber. The pressure detection chip detects a liquid pressure in the first chamber.

A spiral wound membrane module including a specialized endcap assembly including a connecting conduit defining a passageway extending radially inward from its outer periphery, and a differential pressure sensor connected to the passageway of the connecting conduit.

A pressure sensor chip includes a base, a first layer including a first cavity and joined to an upper surface of the base, a second layer joined to an upper surface of the first layer, a third layer including a second cavity and joined to an upper surface of the second layer, and a fourth layer including a third cavity and joined to an upper surface of the third layer. The second layer includes a first diaphragm between the first and second cavities. The fourth layer includes a second diaphragm between the second cavity and a space in communication with outside. A top end of the third cavity is in communication with outside. The bottom end of the third cavity is in communication with the second cavity. The first cavity is sealed. The pressure in the first cavity is lower than the pressure in the second cavity.

The present disclosure relates to differential pressure transducers. The teachings thereof may be embodied in diaphragm-beam configurations for measuring small values of differential pressure and/or a bridge circuit for converting mechanical strains into an electric output signal. For example, a diaphragm-beam structure for measuring differential pressure may include: a frame; a paddle; a resilient beam member; a diaphragm; and a gap defined between the paddle and the frame. The diaphragm flexes under pressure on one surface. The resilient beam member anchors the paddle to the frame. The second surface of the diaphragm is mounted to the first surface of the paddle and the frame to bridge the gap. The paddle moves due to flexure of the diaphragm. The resilient beam member bends due to movement of the paddle. The thickness of the diaphragm is less than 50 micrometers.

An air pressure sensing system including a first sensing unit and a second sensing unit is provided. The first sensing unit includes a substrate, a diaphragm, and a supporting member. The substrate has a cavity connected with an exterior environment. The diaphragm is movably and deformably disposed at the substrate and suspended in the cavity. An electrostatic force is provided to the substrate and the diaphragm to move the diaphragm, such that a portion of the base, the supporting member and the diaphragm are contacted with each other and a closed space is formed therebetween in the cavity. The closed space and the exterior environment are divided by the diaphragm, and the diaphragm is deformed due to an air pressure difference between the closed space and the exterior environment. An air pressure sensing method is also provided.

Various embodiments are directed to a pressure sensor and method of using the same. A pressure sensor may comprise a substrate having a substrate thickness extending between a first substrate surface and a second substrate surface, wherein the first substrate surface and the second substrate surface define opposing ends of the substrate thickness; a first pressure sensing assembly attached to the first substrate surface and configured to detect a first pressure force associated with a first fluid volume, wherein a portion of the first substrate surface adjacent the first pressure sensing assembly is fluidly isolated from the first volume of fluid; and a second pressure sensing assembly attached to the second substrate surface and configured to detect a second pressure force associated with a second volume of fluid, wherein a portion of the second substrate surface adjacent the second pressure sensing assembly is fluidly isolated from the second fluid volume.