Abstract: A gage pressure transducer comprising a first pressure sensing assembly exposed to a main pressure and a second pressure sensing assembly exposed to a reference pressure. The pressure sensing assemblies comprise half-bridge sensors and means for using an alignment glass plate with each sensor which reduces the amount of oil required for operation, which consequently reduces the back pressures caused by large volumes of oil. The pressure sensor assemblies are hermetically sealed using glass frits, therefore enabling the gage pressure transducer to robustly and accurately measure pressure in harsh environments.

Abstract: A process fluid pressure measurement system is provided. The system includes a process fluid pressure transmitter having a pair of process fluid ports disposed coplanar with one another on a bottom surface thereof. The process fluid pressure transmitter is configured to measure a differential pressure between the pair of process fluid ports and provide an indication of the measured differential pressure over a process communication loop. A process fluid flange has a first surface configured to mount to the surface of the process fluid pressure transmitter, a second surface opposed to the first surface, and at least one lateral sidewall extending between the first and second surface. A plurality of fins are disposed proximate the lateral surface.

Abstract: A pressure measuring cell includes at least one ceramic measuring membrane body; and at least one ceramic platform, wherein the measuring membrane body is connected with the platform along an annular, peripheral joint. The joint is formed as a welded connection between the measuring membrane body and the platform, wherein the measuring membrane body has a pressure-dependently deformable measuring membrane. A pressure sensor includes a pressure measuring cell and a housing, wherein the pressure measuring cell is held by the housing, and wherein the pressure measuring cell closes a housing opening, through which the pressure measuring cell communicates with an environment of the housing. A seal is clamped between a sealing surface surrounding the opening of the housing and a sealing surface of the pressure measuring cell.

Abstract: A pressure transducer assembly including: a pressure sensor header; a transducer assembly member; and a joining arrangement disposed at an interface of the header and the transducer assembly member, for joining the header with the transducer assembly member, the joining arrangement including: a recessed female joining element formed in one of the header and the transducer assembly member; and a protruding male joining element formed on the other of the header and the transducer assembly member, the male joining element received in the female joining element.

Abstract: Embodiments of an ultra miniature pressure probe are disclosed. The pressure probe can include a probe body, a plurality of transducer ports, and a plurality of transducers. The probe body can be a longitudinal tubular body having a front conical end. The transducer ports can be disposed about the front end of the body. The transducers can be leadless SOI transducers, each having an active deflection area associated with a semiconductor substrate. Each transducer can be in communication with a header for supporting the transducer. The header can have a thickness substantially less than the probe diameter and can comprise a flange about an edge of the header. Each of the plurality of transducer ports can define an aperture and a counter-bore, wherein each transducer is positionable in an associated transducer port with the flange of the header of the transducer being welded to the counter-bore of the transducer port.

Abstract: The invention relates to a clamp element for a temperature-independent turgor pressure measurement device for measuring the turgor pressure in a plant sample.

Abstract: The invention relates to a measuring apparatus for measuring a measurement variable of a fluid, particularly a sensor, such as a pressure sensor or a displacement sensor. The measuring apparatus comprises a housing, a diaphragm arranged in and/or on the housing, and a resilient element formed in the manner of a leaf spring for restoring the diaphragm. A signal transmitter is operatively connected to the diaphragm and/or the resilient element, and a signal receiver cooperates with the signal transmitter. The resilient element is fastened on the housing at the edge of the resilient element, more specifically in particular only at parts of the edge.

Abstract: A pressure transducer mounting device may include a support member and a pressure transducer holder. In use, the support member may attach to a support surface, such as a housing of a power injection device, while the pressure transducer holder is moveably connected to the support member. The pressure transducer holder may expand open to receive one of a plurality of different sized pressure transducers and bias closed to hold a received one of the plurality of different sized pressure transducers. In addition, the pressure transducer holder may move relative to the support member to one of a plurality of different vertically elevated positions. The pressure transducer mounting device may accommodate different pressure transducers, providing a universal mounting device that can adapt to different medical provider preferences and different pressure transducer sourcing options.

Abstract: An indicator gauge has a housing with a front face and a sensor mounted in the housing. The front dial face has a first sensor indicator thereon for displaying an amount detected by the sensor. The housing has a side wall with a second sensor indicator shown thereon for displaying the amount detected by the sensor.

Abstract: A pressure transducer assembly, and a method of making the same, comprising a header having a first connection portion; a port having a corresponding second connection portion, wherein the first connection portion of the header is attached to the second connection portion of the port to create a header-port interface; and an integral back up ring defined in one of the header and port, wherein the integral back up ring is separated from the header-port interface by a cavity. The first connection portion of the header is attached to the second connection portion of the port by a full penetration weld and the integral back up ring is adapted to block the full penetration weld from damaging the header and thus minimize, if not eliminate, crack propagation.

Abstract: A gage having a motion detection mechanism magnetically attached to a pressure sensing diaphragm. The motion detection mechanism is magnetically coupled to a pointer rotation mechanism configured to indicate the position of the diaphragm and the corresponding pressure sensed by the diaphragm.

Abstract: A device for measuring pressure or temperature in a heating or a cooling system and where the device is a measuring needle complete (1) comprising a measuring needle housing (6) with one cavity (20) and a spring-loaded non return valve (8), where the non return valve, in a measuring position, has an open communication with the probe (10) via the measuring needle housing and a hose nipple, via a hose, to a measuring instrument. This open communication is closed immediately as soon as the measuring is completed and the measuring needle (1) is removed from the measuring nipple. After measuring, due to this immediate closing, leakage of the enclosed fluid that exists in the complete measuring needle (1) and the measuring hose (5) is prevented.

Abstract: A method for manufacturing a micromechanical component is described, the micromechanical component having a medium. The medium has settable and changeable volume-elastic properties and generally completely encloses a sensor module and/or a module housing. The medium preferably has a low-pass response.

Abstract: The present disclosure relates to pressure sensor assemblies and methods. The pressure sensor assembly may include a first substrate, a second substrate and a sense die. The first substrate may be connected to the second substrate, such that an aperture in the first substrate is in fluid communication with an aperture in the second substrate. The second substrate may be connected to the sense die, such that the aperture in the second substrate is in fluid communication with a sense diaphragm on the second substrate. The pressure sensor assembly may include a media path that extends through the aperture in the first substrate, through the aperture in the second substrate, and to the sense die. In some cases, the first substrate, the second substrate and the sense die may be connected in a manner that does not include an adhesive.

Abstract: A gage having a motion detection mechanism magnetically attached to a pressure sensing diaphragm. The motion detection mechanism is magnetically coupled to a pointer rotation mechanism configured to indicate the position of the diaphragm and the corresponding pressure sensed by the diaphragm.

Abstract: A pressure sensor device comprises a casing (2a, 3 a) defining a chamber (20) and an inlet passage (14a, 14b) of the chamber. Accommodated in the chamber (20) is a pressure sensor (17) having a sensor body with a cavity and a membrane capable of deformation under pressure action of a fluid present in the inlet passage (14a, 14b). The device further comprises a circuit arrangement (26, 27, 30) to which the pressure sensor (17) is electrically connected, the circuit arrangement including a circuit support at least partially accommodated in the chamber (20). The sensor body is not rigidly associated to the casing (2a, 3 a) and/or to other parts of the device (26, 27, 30, 35), i.e. it is mounted elastically or in a moveable manner with respect to the casing (2a, 3 a) and/or to said other parts (26, 27, 30, 35) inside the chamber (20).

Abstract: A pressure belt comprising a flexible belt, and a flat pack assembly removably attached to the flexible belt, wherein each flat pack assembly comprises at least one sensing element. Further, each flat pack assembly also comprises a memory component associated with the sensing element thereon, wherein the memory component houses data specific to the corresponding sensing element. Unlike prior art structures, each flat pack assembly is individually removable. Therefore, if one sensing element malfunctions, it may be replaced by removing the flat pack assembly comprising the malfunctioning sensing element and swapping it out for a flat pack assembly comprising an operable sensing element. This is an improvement over the prior art as it eliminates the need for replacing and recalibrating the entire pressure belt when one sensing element malfunctions, which can be both time consuming and costly.

Abstract: In a pressure sensor that detects the pressure of liquid flowing in a main fluid flow path, a pressure measuring unit is installed by providing a pressure measuring space at a position branching from a straight-pipe portion of the main fluid flow path, and, in addition, the main fluid flow path and the pressure measuring space are connected with an inlet pipe and an outlet pipe whose pipe diameters are smaller than the main fluid flow path.

Abstract: A method for manufacturing a single-wire anemometric probe, or an n-wire (n>1) probe, for making measurements near a surface, comprising, for at least one of the wires: a) positioning and holding of a straight portion of the wire, comprising a metal core surrounded by a protective sheath, on two surfaces; b) elimination of a part of the sheath, to expose an active wire measurement zone; and c) the wire is soldered on two pins of the probe body.

Abstract: A device for determining a physical value of a liquid flowing in a pipe, without contact with said liquid, said device comprising: a sensor (3) for said physical value; a connector (2) to insert into said pipe and comprising: an internal passage (13) extending between two apertures (11, 12), a flexible membrane (6) for a pressure sensor, forming a wall of said internal passage (13); and means (27, 62) for fastening said sensor (3) onto said connector (2); characterized in that said sensor is a temperature sensor (3) fastened to said connector (2) with the sensitive part of said sensor (3) turned towards said membrane (6).

Abstract: A pressure transmitter includes a sensor assembly having a hollow body housing a pressure sensor. The pressure transmitter also includes a support body which is made of a first material, and an interface body which is connected to the support body and which is made of a second material different from the first material. A first isolation diaphragm is fixed onto the interface body and is made of the same material of the interface body. The first isolation diaphragm is in fluid communication with the pressure sensor and is configured for interfacing with a process fluid.

Abstract: A pressure sensor device comprises: —a casing (2a, 3a) defining a cavity (7) with an inlet passage (8a, 8b), —a pressure sensor (30) having a body accommodated in the cavity (7), for detecting the pressure of a fluid present in the inlet passage (8a, 8b), —a circuit arrangement including a circuit support (20) at least partially accommodated in the cavity (7) according to a respective laying plane, the pressure sensor (30) being mounted on the circuit support (20). Associated to the circuit support (20) is a protection body (31) surrounding the pressure sensor (30), the protection body (31) externally defining a seat for positioning a respective seal member (35), in particular a radial seal gasket, intended to cooperate with an internal surface of the casing (2a, 3 a).

Abstract: The present disclosure relates to sensors including pressure sensors, humidity sensors, flow sensors, etc. In some cases, a sensor assembly may include a pressure port connected to a sensor unit, an electrical connector connected to the sensor unit and an outer housing encompassing at least portions of the pressure port, sensor unit and electrical connector. In some instances, the sensor unit may include pressure signal output terminals electrically connected to electrical terminals of the electrical connector.

Abstract: A pressure-sensor device (1) comprises: —a pressure-sensitive component (9) having a body, defined in which is a blind cavity, and having a membrane portion (9a), operatively associated to which is a detection element (R); and —a connection structure (2), which has a duct in communication with the cavity of the pressure-sensitive component (9) and is to receive a fluid, a pressure of which is to be detected. The connection structure (2) comprises a supporting body (2a) of the pressure-sensitive component (9), which defines a respective passage (2b), and a compressible element (12, 18) that is designed to be in contact with the fluid and is configured for compensating possible variations of volume thereof. The compressible element (12, 18) is positioned at least in part within the cavity (11) of the pressure-sensitive component (9) and/or in a stretch of the passage (2b) of the supporting body (2a) that is close to the cavity (11) of the pressure-sensitive component (9).

Abstract: An apparatus for determining and/or monitoring a physical and/or chemical, measured variable of a medium, including a housing, especially an elongated housing, and a sensor arranged in the housing. The sensor serves for registering the measured variable, wherein the housing has at least one opening, through which the sensor comes in contact with the medium. The housing has a first housing section, in which the sensor and a sensor electronics are arranged. The sensor electronics is arranged on a first carrier element. The sensor electronics serves for changing the measured variable into an analog electrical signal. An insert is applied in the first housing section, in which the sensor electronics is arranged. The insert is tubular.

Abstract: A very robust sensor element for an absolute-pressure measurement is described, which is suitable for high temperatures and able to be miniaturized to a large extent. The micromechanical pressure-sensor element includes a sensor diaphragm having a rear-side pressure connection and at least one dielectrically insulated piezo resistor for signal acquisition. Furthermore, the pressure-sensor element has a front-side reference volume, which is sealed by a cap structure spanning the sensor diaphragm. The cap structure is realized as thin-film structure.

Abstract: A pressure gauge adapter for sanitary conduit accepts a standard pressure gauge with a male threaded stem. The adapter has a flange to mate with an upper flange of a tubular stub where a diaphragm is positioned to serve as fluid barrier to block process liquid from leaving, and to serve as a seal gland. A hollow cylindrical wall rises from the flange member, with a sealing flange at its upper end. An elongated piston is situated within the hollow cylindrical wall with a lower head upon the lower diaphragm, and an upper head reaching the top end of the cylinder. A cap or dome situated above the cylinder has a flange member that mates with the upper flange member of the cylinder, with an upper diaphragm therebetween. The cap defines a space above the upper diaphragm, and is filled with a transfer liquid. A threaded bore in the cap accepts the threaded stem of the pressure gauge.

Abstract: A pressure sensor device (1) comprises: a pressure sensor (9) having a sensor body (9a) defined in which is a cavity (11) with a bottom surface (11a) belonging to a membrane portion (9?) of the body itself, a detection element operatively being associated to the membrane portion (9?), a connection structure (2) having a duct (2a, 15, 19) in communication with the abovementioned cavity (11), designed to receive a fluid a pressure of which is to be detected. The connection structure comprises a body (2) for supporting the pressure sensor (9), defining at least one respective passage (2a), and one compressible element (12) designed to be in contact with the fluid and configured to compensate possible volume variations thereof, the compressible element (12) being positioned at least partially within the cavity (11), in such a manner to substantially divide it into two opposite regions.

Abstract: The invention relates to a fastening device for fastening an assembly (5) in an opening (1.1) of a wall (1) of a vehicle. Said fastening device comprises a support element (2) to be placed on the wall (1) and a retaining element (3) having at least one retaining wing (3.1) for fastening the fastening device in the opening (1.1) of the wall, which retaining element (3) for fastening the fastening device is arranged so as to be rotatable relative to the support element (2) along a predetermined path of rotation. This means fastening is achieved by way of a bayonet-type rotational movement. According to the invention, however, a sealing element (4.1) is interposed between the support element (2) and the retaining element (3), and the support element (2) and/or the retaining element (3) and/or the sealing element (4) are designed relative to one another such that in a first section of the path of rotation, a play (4.

Abstract: Conventional pressure sensor units require time-consuming work including bonding and welding in assembly work and affixing a pressure sensor to a holder, and therefore a pressure sensor unit in which a pressure sensor can be easily affixed to a holder is needed. Disclosed is a pressure sensor unit wherein a holder comprises a first holder member and a second holder member, and by fitting a fitting groove of the first holder member and a fitting claw of the second holder member with each other while housing a pressure sensor in housing holes provided in the two holder members, the two holder members are affixed, and the pressure sensor is affixed to the holder.

Abstract: An electric part protection member for a projecting contact terminal which projects from a supporting portion of an electric part, includes a bottomed cylindrical cap portion, adapted to be detachably placed over the supporting portion, wherein: the cap portion is formed of a conductive member; and when the cap portion is placed over the supporting portion, the cap portion is electrically connected to a housing of the electric part, and the contact terminals are spaced apart from the cap portion.

Abstract: The invention relates to an assembly, in particular for measuring a process variable, which consists of a measuring instrument having a process connection and a housing, which is partially rotationally symmetrical at least in the region of the process connection, and of an adapter having a through-hole, which extends in the axial direction, and a sealing web in the through-hole. The measuring instrument and the adapter are connected to each other in a releasable and sealed manner via two sealing surfaces. According to the invention, at least one of the sealing surfaces then has a coating composed of parylene. The invention furthermore relates to an assembly for the releasable and sealed connection of two medium-carrying parts, in particular pipelines.

Abstract: An external pressure measuring device having a base and a tubing system bent with various radii. Pressure inside the bent tubing causes the tubing to move in such a way that can be measured and can provide an indication of internal pressure.

Abstract: A measurement arrangement for measuring and/or monitoring a physical property, comprising a measurement device comprising: at least one primary sensing element to be exposed to a product at a measurement site, a remotely located secondary measurement device, and transmission lines connecting said primary sensing elements to said secondary measuring device, suitable for applications wherein the primary sensing elements may be exposed to strong vibrations at the measurement sites, is described, wherein said secondary measurement device is mounted above all primary sensing elements and wherein said transmission lines comprise an inner core, an outer tubular protection conduit enclosing said core, and a vibration absorbing medium filling an interior of said outer protection conduit surrounding said inner core.

Abstract: A pressure transmitter with pressure sensor mount includes pressure measurement circuitry. A metal body of the pressure transmitter has a pressure coupling configured to couple to a process pressure. A pressure sensor is configured to provide an output related to an applied pressure to the pressure measurement circuitry. A conduit is coupled to the pressure sensor and configured to apply an applied pressure corresponding to the process pressure to pressure sensor. A non-conductive spacer is configured to electrically isolate the conduit from the metal body. The non-conductive spacer has an opening formed therein and is arranged to convey the applied from the metal body to the conduit.

Abstract: A media isolated pressure sensor is disclosed that helps improve performance and reduce cost. In one illustrative embodiment, a pressure sensor may include a carrier having one or more holes defined therein. The carrier may be coupled to a diaphragm on one side, and a pressure sensing die on the other, with the pressure sensing die in fluid communication with the hole in the carrier. The carrier, diaphragm and pressure sense die may form a transfer fluid cavity, which is filled with a pressure transfer fluid. An input pressure from a media to be sensed may be provided to the diaphragm, which transmits the pressure to the pressure sensing die via the pressure transfer fluid. The pressure sensing die remains isolated from the media to be sensed.

Abstract: The present disclosure relates to sensors including pressure sensors, humidity sensors, flow sensors, etc. In some illustrative cases, a sensor assembly may include a pressure port connected to a sensor unit, an electrical connector connected to the sensor unit and an outer housing encompassing at least portions of the pressure port, sensor unit and electrical connector. In one example, the sensor unit may include a carrier carrying a sense element, where the carrier may extend into a recess of the pressure port and may be secured to the pressure port at an internal side thereof through the use of an adhesive layer.

Abstract: According to one configuration, a base component of a pressure sensor assembly includes a hollowed volume (e.g., chamber, bore, space, etc.) in which to house components such as a pressure sensor element and pressure sensor circuitry. Opposite an opening to the hollowed volume, the base component further includes a port through which to receive a fluid. An inside wall of the first end of the metallic base component includes grooves. The grooves can be created on the inner wall based on a metalworking operation known as broaching. To produce the pressure sensor assembly, at least a portion of the first end of the metallic base component including the grooves is crimped inward to fixedly couple a connector component to the metallic base component and retain the pressure sensor electronics and pressure sensor circuitry within the hollowed volume.

Abstract: A surface mounted instrument (20) that is easily installed to seal (110, 120) against a mounting surface (150) in spite of imprecise installation of a standard rough-in box (145) or irregularities in the surface. A cover plate (60) overlays the installed instrument housing (10) without the use of outwardly visible mechanical connectors by use of a pawl (65) that engages the housing. An oversized display (50) is mounted for easy replacement on a moveable display module (45) for unobstructed access to the interior (35) of the housing. Subsurface channels (90) formed in the housing are used to deliver a working fluid from a measured location to a sensor (85) inside the housing.

Abstract: A three-valves manifold for a differential pressure type flow meter includes a valve unit and a housing. The valve unit includes a shaft portion, a first valve portion having a first through hole and first to third grooves and a second valve portion having a second through hole and fourth and fifth grooves. The housing includes a space in which the shaft portion and valve portions are rotatably arranged. The first and second through holes and first to fifth grooves are formed at positions such that the first and second through holes communicate differently with first and second inlet and outlet openings of the housing in each of first, second, and third rotational positions.

Abstract: A pressure gauge adapter for sanitary conduit accepts a standard pressure gauge with a male threaded stem. The adapter has a flange to mate with an upper flange of a tubular stub where a diaphragm is positioned to serve as fluid barrier to block process liquid from leaving, and to serve as a seal gland. A hollow cylindrical wall rises from the flange member, with a sealing flange at its upper end. An elongated piston is situated within the hollow cylindrical wall with a lower head upon the lower diaphragm, and an upper head reaching the top end of the cylinder. A cap or dome situated above the cylinder has a flange member that mates with the upper flange member of the cylinder, with an upper diaphragm therebetween. The cap defines a space above the upper diaphragm, and is filled with a transfer liquid. A threaded bore in the cap accepts the threaded stem of the pressure gauge.

Abstract: A fast-fit device for fluidically connecting a pressure sensor to a water collecting tank of an electric household appliance including: a supporting body securable to a housing of the electric household appliance and carrying a first, blind tubular element, having a first open end, opposite to a second blind end; a second tubular element integrally obtained in one piece with a casing of the pressure sensor, which overhangingly extends therefrom for the entire length thereof and which displays external diameter and length smaller than the internal diameter and length of the first tubular element; a closing plug of the first end provided with a through hole which fluid-tightly receives in use the second tubular element; and first and second fastening means which are reciprocally complementary and integrally carried by the supporting body and the casing of the sensor, respectively.

Abstract: According to one configuration, a base component of a pressure sensor assembly includes a hollowed volume (e.g., chamber, bore, space, etc.) in which to house components such as a pressure sensor element and pressure sensor circuitry. Opposite an opening to the hollowed volume, the base component further includes a port through which to receive a fluid. An inside wall of the first end of the metallic base component includes grooves. The grooves can be created on the inner wall based on a metalworking operation known as broaching. To produce the pressure sensor assembly, at least a portion of the first end of the metallic base component including the grooves is crimped inward to fixedly couple a connector component to the metallic base component and retain the pressure sensor electronics and pressure sensor circuitry within the hollowed volume.

Abstract: A gage having a motion detection mechanism magnetically attached to a pressure sensing diaphragm. The motion detection mechanism is magnetically coupled to a pointer rotation mechanism configured to indicate the position of the diaphragm and the corresponding pressure sensed by the diaphragm.

Abstract: Some embodiments of the present disclosure relate to improved package assemblies for pressure sensing elements. Rather than leaving a pressure sensing element unabashedly exposed to the ambient environment in a manner that makes it susceptible to damage from stray wires, dirt, and the like; the improved package assemblies disclosed herein include a cover that helps form an enclosure around the pressure sensing element. The cover includes a fluid-flow channel with a blocking member arranged therein. The fluid-flow channel puts the pressure sensing element in fluid communication with the external environment so pressure measurements can be taken, while the blocking member helps protect the pressure sensing element from the external environment (e.g., stray wires and dirt to some extent). In this way, the package assemblies disclosed herein help promote more accurate and reliable pressure measurements than previous implementations.

Abstract: A dual port pressure sensor has a lead frame having a flag having a first opening and a second opening. The lead frame has a flag having a first opening and a second opening. An encapsulant holds the lead frame. The encapsulant is over a top of the flag and a bottom of the flag is uncovered by the encapsulant. A first opening in the encapsulant is aligned with and larger than the first opening in the flag, and a second opening in the encapsulant is aligned with the second opening in the flag. A pressure sensor transducer is attached to the bottom of the flag and covers the first opening in the flag and provides an electrically detectable correlation to a pressure differential based on a first pressure received on its top side and a second pressure received on its bottom side. An integrated circuit is attached to the bottom of the flag and is electrically coupled to the pressure sensor. A lid forming an enclosure with the bottom of the flag.

Abstract: A gage having a motion detection mechanism magnetically attached to a pressure sensing diaphragm. The motion detection mechanism is magnetically coupled to a pointer rotation mechanism configured to indicate the position of the diaphragm and the corresponding pressure sensed by the diaphragm.

Abstract: A pressure connection concept for pressure sensor modules is provided, using which the influence of assembly-related stresses in the sensor system on the sensor diaphragm and accordingly on the measuring signal detection is kept very low. The sensor system includes a sensor module for pressure detection and a connecting piece and at least one seal for coupling the sensor module to a measuring system. The sensor module includes at least one sensor element having a diaphragm and means for signal detection. Together with the means for signal detection, the sensor element is provided with packaging having a pressure connection opening and electrical contacts. A pressure channel is provided in the connecting piece, the pressure channel being coupled to the pressure connection opening of the sensor module using the seal. The packaging of the sensor module includes a tube-shaped projection which forms the pressure connection opening, and the pressure channel of the connecting piece terminates in a connecting tube.

Abstract: An object of the present invention is to solve problems in that aluminum electrodes, aluminum wires, and I/O terminals are corroded by corrosive gasses when a pressure of a pressure medium containing corrosive matters such as exhaust gas is measured with a semiconductor sensor; and improve not only the corrosion resistance of the sensor chip but also the corrosion resistance of the portion particularly functioning as the pressure receiver. Each of the aluminum electrodes that is likely to be corroded portions is prevented from being corroded by forming a titanium-tungsten layer and gold layer on the aluminum electrode. The connecting wires are prevented from being corroded by corrosive matters by using gold wires. The I/O terminals are also prevented from being corroded by applying gold plating.

Abstract: A device for determining a physical value of a liquid flowing in a pipe, without contact with the liquid. The device includes: a sensor for the physical value; a connector to insert into the pipe and including: an internal passage extending between two apertures, a flexible membrane for a pressure sensor, forming a wall of the internal passage; and a fastening mechanism for fastening the sensor onto the connector. The sensor is a temperature sensor fastened to the connector with the sensitive part of the sensor turned towards the membrane.