A pressure sensor module detects a fluid pressure on the basis of a differential pressure between a reference pressure and the fluid pressure, and includes: a housing; a sensor element that can contact each of the reference pressure and the fluid pressure; a support member that supports the sensor element and is held in the housing; a first pressure passage that guides the fluid pressure to a first contact surface of the sensor element; and a second pressure passage that is sealed from the first pressure passage and guides the reference pressure to a second contact surface of the sensor element.

The present disclosure is provided with a measuring element (M) and a measuring device. The measuring element includes a base body, a diaphragm and a permeation resistant layer, the diaphragm is fixedly connected to the base body, with a sealed cavity being defined between the diaphragm and the base body. The permeation resistant layer is arranged on an inner side surface, facing the sealed cavity, of the diaphragm, and extended continuously on the inner side surface of the diaphragm at least beyond a connection region of the diaphragm with the base body. The measuring device includes the measuring element (M).

A pressure sensor is proposed. The pressure sensor has a main body housing (10) and a cover housing (30). The main body housing (10) has an inner space (16) and a substrate (28) having a sensing element (29). The cover housing (30) has a seal (41) integrally formed therein so as to encompass part of the sensing element (29) so that the sensing element communicates with a communicating passage (33) but does not communicate with the inner space (16). A discharge path (36) is formed on the communicating passage (33) so as to allow the inside of a tube communicating with the communicating passage (33) to be maintained at atmospheric pressure normally. An inflow orifice (34) is in the downstream side of the communicating passage (33) and a discharge orifice (37) is in the downstream side of the discharge path (36) so that the flow of the fluid is rapid.

A pressure measuring device is disclosed that includes a housing, a pressure measuring cell, evaluation electronics for processing measurement signals generated by the pressure measuring cell, a plug connection formed at the housing for transmitting the processed measurement signals to an external receiving unit, and an air passage which enables pressure compensation between the interior of the housing and the exterior of the housing. The plug connection includes a cylindrical sleeve and an insert part disposed therein, wherein the air passage is formed as a two-part barrier having a first liquid barrier formed as a duct system from the interior of the housing via the plug connection and a second liquid barrier having a liquid-repellent diaphragm and disposed in an area within the duct system, and wherein the insert part has a first recess into which the diaphragm is inserted. The insert part has a second recess, which is arranged at a distance from the first recess and in which a light-emitting diode signalling a status of the measuring device is inserted, wherein the cylindrical sleeve also has a recess at the side opposite the light-emitting diode, which recess on the one hand, acting as a part of the duct system or air passage, allows pressure compensation and, on the other hand, allows the light-emitting diode to be visible.

This application relates to a portable electronic device that includes an integrated pressure sensor. The portable electronic device includes a housing that defines a cavity with a number of components disposed therein. The cavity is sealed to form a volume of air within the cavity that is vented to the external environment through a barometric vent fluidly coupled to a first opening in the housing. A sensor measures a characteristic of a second volume of air within an isolated chamber that is vented to the external environment through a second opening in the housing. The second volume of air is isolated from the first volume of air within the housing of the portable electronic device. In some embodiments, the portable electronic device is a mobile phone and the sensor is a pressure transducer.

A pneumatic pressure probe comprises an orifice tube extending through a plastic bushing that seals a pressure chamber. The orifice tube has a passage shaped substantially like a converging/diverging de Laval nozzle to reduce turbulence in fluid flow through the probe. More laminar fluid flow reduces noise and inaccuracy in the output of the probe. Laminar flow also reduces user dependent results. The plastic bushing and a specially shaped probe tip reduce extraneous fluid leakages from the probe.

A pressure sensing device comprising a body assembly, a connector assembly, an electronic circuit, and a pressure sensor is provided. The pressure sensing device is a compact device allowing for improved assembly. Moreover, the pressure sensing device allows for a leakage test and an electronic circuit control test to be performed before the assembly of the device thereby improving reliability and precision.

A sensor includes a substrate, an oxide layer, a membrane, an electrode, and a trench. The oxide layer is disposed on the substrate. The membrane is positioned on the oxide layer. The membrane with the oxide layer and the substrate forms an enclosed cavity therein. The membrane comprises a rigid portion and a deformable portion wherein the deformable portion of the membrane deforms responsive to stimuli. The oxide layer forms side walls of the cavity. The electrode is positioned on the substrate and within the cavity. The trench is formed in the oxide layer, and wherein the trench is covered with barrier material.

The present disclosure relates to a piston diaphragm seal for transmitting a pressure of a medium to a pressure-measuring sensor a base body having a recess and a bore which is connected to the recess. The recess and the bore can be filled with a pressure transfer medium. A piston is arranged in the recess and can be moved within a predetermined region in the recess. A surface of the piston facing the medium can be loaded with the pressure of the medium, wherein the piston is separated by at least two sealing elements from the medium and the pressure transfer medium. A cavity is arranged in the piston between the at least two sealing elements. An attachment region is provided for connecting the piston diaphragm seal to the pressure-measuring sensor. A monitoring unit is designed to determine and/or monitor entry of medium and/or pressure transfer medium into the cavity.

A pressure sensor includes a cylindrical member configured to be attached to a body having a fluid passage, and a pressure sensor unit connected to the cylindrical member for detecting a pressure of a fluid flowing through the fluid passage, wherein the cylindrical member is made of a nickel-molybdenum-chromium alloy material or a stainless steel material, wherein the pressure sensor unit includes a sensor body closed at one end with a diaphragm and a pressure detecting element for outputting displacement of the diaphragm as pressure, and wherein the sensor body is made of a cobalt-nickel alloy material, and is connected at an opening side end portion to one end portion of the cylindrical member.