A pressure sensor includes a pressure detection element; a substrate on which the pressure detection element is mounted; and a cap in a tubular shape, the cap being attached to the attachment surface of the substrate with an adhesive, the attachment surface enclosing the periphery of the pressure detection element. An attracting concave part is in the end face of the cap, the end face facing the attachment surface, so as to have an inclined surface the distance of which from the attachment surface is increased in a direction from the outer circumferential surface of the cap toward its inner circumferential surface. Part of the adhesive is embedded in the interior of the attracting concave part.

A corrosion protection element is described, with which in simple and cost effective manner a reliable corrosion protection of field devices can be provided, which field devices comprise at least one component of stainless steel in contact with an environment of the field device. Corrosion protection elements of the invention are distinguished by features including that they are embodied as sacrificial anodes comprising iron or rustable steel and have a form, which is embodied in such a manner that they can be applied to the component of the field device in such a manner that the sacrificial anode is in electrically conducting contact with the component.

The measuring device comprises a sensor element with an electrical transducer for providing a primary signal dependent on the measured variable and a sensor body with a flat surface portion. The measuring device also includes a measurement and operation circuit for driving the transducer and processing the primary signals. The measurement and operation circuit comprises at least one carrier, a plurality of circuit components including at least one integrated circuit, and passive components. The carrier comprises an electrically insulating carrier body and conductor paths which extend in the carrier body or on its surface. The integrated circuit and the passive component are arranged on the carrier body surface and contacted by the conductor paths. The carrier body is fixed to the surface portion, and the transducer is electrically connected to circuit components of the measurement and operation circuit via conductor paths, the components being encapsulated with a molding compound.

The measuring device comprises a sensor element with an electrical transducer for providing a primary signal dependent on the measured variable and a sensor body with a flat surface portion. The measuring device also includes a measurement and operation circuit for driving the transducer and processing the primary signals. The measurement and operation circuit comprises at least one carrier, a plurality of circuit components including at least one integrated circuit, and passive components. The carrier comprises an electrically insulating carrier body and conductor paths which extend in the carrier body or on its surface. The integrated circuit and the passive component are arranged on the carrier body surface and contacted by the conductor paths. The carrier body is fixed to the surface portion, and the transducer is electrically connected to circuit components of the measurement and operation circuit via conductor paths, the components being encapsulated with a molding compound.

A device includes a housing unit with an internal volume. The device further includes a sensor coupled to a substrate via an electrical coupling, wherein the sensor is disposed within the internal volume of the housing unit, and wherein the sensor is in communication with an external environment of the housing unit from a side other than a side associated with the substrate. The device also includes a moisture detection unit electrically coupled to the sensor, wherein the moisture detection unit comprises at least two looped wires at different heights, and wherein the moisture detection unit is configured to detect presence of a moisture within an interior environment of the housing unit when the moisture detection unit becomes in direct contact with the moisture.

A package structure for a differential pressure sensor, and an electronic device are provided. The package structure includes: a substrate and a housing, an edge of the housing is fixed to a front side of the substrate and defines a first chamber with the substrate; and a pressure sensing element fixed to the front side of the substrate and disposed in the first chamber, the pressure sensing element is provided with a second chamber and a pressure sensing layer, the pressure sensing layer being disposed between the first chamber and the second chamber. The first chamber is connected with the outside via a first through hole, and the second chamber is connected with the outside via a second through hole.

In an example, a method for on-board maintenance of an aircraft is described. The method includes measuring, by a pressure sensor, a pressure in a tube associated with an engine of an aircraft. The method also includes determining, by a control system and based on the pressure measured by the pressure sensor, that the tube is at least partially blocked by moisture. Additionally, the method includes, responsive to determining that the tube is at least partially blocked by the moisture, providing an alert signal from the control system to a flight deck of the aircraft. The method also includes, responsive to the alert signal, operating an actuation switch at the flight deck to actuate a valve to an open state. The method further includes, responsive to actuating the valve to the open state, supplying an inert gas from an inert gas supply to the tube to expel the moisture.

A pressure sensor device comprises a device package (110) arranged to define a cavity (116) having an opening for fluid communication with an internal volume thereof. The cavity (116) comprises a side wall (114, 115). An elongate pressure sensor element (100) is provided and has a proximal end (120) and a distal end (122). The side wall (114, 115) is arranged to hold fixedly the proximal end (120) of the pressure sensor element (100) therein so that the pressure sensor element (100) is cantilever-suspended from the side wall (114, 115) within the cavity (116).

A pressure measurement device (1) comprising a housing (20) extending around an electronic card (30) provided with a pressure sensor (40); the housing (20) co-operating with a first face (31) of the electronic card (30) to define a first sealed volume (3); the housing (20) also co-operating with a second face (32) of the electronic card (30) that is opposite from the first face (31) to define a second sealed volume (4); the housing (20) including at least one first channel (24) putting the medium (5) outside the housing (20) into fluid flow communication with the first sealed volume (3); the electronic card (30) including at least one second channel (33) putting the first volume (3) into fluid flow communication with the second volume (4); and the connection between the housing (20) and the electronic card (30) being arranged to allow relative movement between the housing (20) and the electronic card.

A sensor element is provided for detecting at least one property of a fluid medium. The sensor element comprises at least one housing having at least one inflow opening accessible to the fluid medium. At least one pressure sensor for detecting a pressure of the fluid medium is situated in the inflow opening. In the inflow opening in front of the pressure sensor, a plurality of ribs project from at least one wall of the inflow opening into the inflow opening.