An apparatus for monitoring a power capacitor having a housing with a housing interior to be gas-tightly closed off at a housing opening, includes a sensor device outputting a signal as a function of a gas pressure in the housing. An adapter mechanically connects the sensor device to the housing at the housing opening and fluidically connects it to the housing interior. The adapter has a cylindrical adapter body divided into a plurality of functional longitudinal sections and a feed-through for the fluidic connection extending over the plurality of longitudinal sections. A first longitudinal section, disposed in a region of the housing opening after connecting the adapter to the housing, caps or closes off the feed-through in a plane perpendicular to a longitudinal axis of the adapter body and fluidically connects it to the housing interior in at least one plane parallel to the longitudinal axis.

Provided is a pressure sensor including: a housing portion including a housing part housing a pressure sensor module, a concave portion facing the housing part across an inner wall, and a through hole part formed in the inner wall; a filter covering the through hole part; and a cover mounted on the housing portion while covering the concave portion and including cutout parts. The concave portion includes a bottom surface that is one surface of the inner wall, and two side surfaces perpendicular to the bottom surface and opposed to each other. The cover is formed with a rectangular upper plate and two rectangular side plates continuous with edges of the upper plate in a vertical direction and opposed to each other. The upper plate is arranged to face the bottom surface. The two side plates are arranged between the two side surfaces opposed to each other.

A measurement chamber that is essentially dome shaped and has a base area with a membrane and has at least two connection points fora fluid flow. The measurement chamber has two outer webs opposite each other, one of the webs engaging a clamping edge of a coupling element.

A pressure sensor includes a housing, an isolator positioned at a first end of the housing, and a first cavity formed between the first end of the housing and the isolator. The pressure sensor further includes a second cavity formed in the housing and a channel with a first end fluidly connected to the first cavity and a second end fluidly coupled to the second cavity. A pressure sensor chip is positioned in the second cavity and includes a first diaphragm positioned at a top side of the pressure sensor chip laterally outwards from the second end of the channel to prevent a fluid from jetting onto the first diaphragm.

The present disclosure relates to a process connection for connecting a sensor to a process inlet via a process seal and a fixing element. The process connection includes a sensor housing and a clamping element. The sensor housing has a housing body configured to receive the sensor and a housing collar that extends around the housing body and has a first sealing section, which encircles the housing body, and a contact area. The housing collar is formed integrally with the housing body. The first sealing section is suitable for receiving the process seal to connect the process inlet to the housing collar in a fluid-tight manner. The clamping element has a contact area which is suitable for coming into contact with the contact area of the housing collar to press the housing collar onto the process seal.

A method for measuring pressure includes securing a flow channel to a chassis of a measurement device, the flow channel having a flexible wall with a first mechanical engagement feature presented from an external surface thereof. The method also includes engaging the mechanical engagement feature with a complementary engagement member connected to a force transducer, the securing being effective to immobilize the flow channel relative to the force transducer, and detecting at least one of the position and orientation of the of the flow channel relative to transducer and comparing to at least one of a predefined position and orientation. Further, the method includes generating a signal responsive to the detecting, flowing a fluid through the flow channel, and transmitting forces caused by displacement of the flexible wall through the complementary engagement member to the force transducer. Further, electrical signals are generated responsively to a state of the force transducer.

To enable easy alignment of a leakage outlet according to known guidelines, a connecting device (1) for connecting a sensor (3) to a unit (2) containing a fluid is provided, comprising a first mounting portion (1a) to which the sensor (3) is mountable, a second mounting portion (1b) which is mountable to the unit (2), a central portion (1c) located between the first and second mounting portions (1a and 1b) and a leakage ring (1e) covering the bore (1d) of the central portion (1c), the leakage ring (1e) being sealed and rotatable relative to the central portion (1c), wherein the leakage ring (1e) has a leakage outlet (1f) on its periphery, the leakage outlet (1f) being provided to be located in the region of a lowest position of the periphery of the leakage ring (1e) in an operating position to allow any fluid present to drain.

A pressure sensor for determining a pressure of a medium is configured to be screwed into a hydraulic control block, and includes a sleeve-shaped connector stub and sensor element. The stub has a plurality of axial sections, and an axial through bore configured to receive the medium. The axial sections include a threaded section, flange section, carrier section, and tapered portion. The flange section has an annular face facing the threaded section and configured to bear against a surface of the control block. The carrier section includes an inner opening that opens into the bore. The sensor element is positioned on the opening to sealingly close the opening, and is configured to measure the pressure of the medium. The tapered portion defines a reduction in a radial external diameter of the stub between the flange section and the carrier section.

A connection socket for fluid-conducting line systems, and including a fluid channel extending along a fluid channel axis. The fluid channel may be connected to guide channels on at least a first and second connection ends of the connection socket. A measurement section is located between the first and second connection ends and a sensor system is provided therein to measure the pressure of a medium flowing within the fluid channel. The sensor system includes a connection interface for connecting to a control unit and measuring pressure in the fluid channel. For pressure measurement, at least two strain measurement sensors are arranged around the fluid channel axis on an outer wall of the measurement section. A control unit may be connected to the sensor system for measuring the pressure of a fluid in the connection socket.

A capacitance diaphragm gauge (CDG) assembly includes a CDG sensor positioned within a vacuum enclosure, which is maintained at a vacuum. The CDG sensor generates sensor signals responsive to a pressure of an applied gas. The vacuum enclosure provides thermal insulation around the CDG sensor. The CDG sensor is maintained at a selected operating temperature using an internal heater positioned on the CDG sensor. The internal heater is responsive to external heater control signals. The temperature of the CDG sensor is monitored using an internal temperature sensor mounted on the CDG sensor. The temperature sensor generates a temperature signal. The vacuum enclosure includes an end cap that seals the vacuum enclosure. Connectors positioned through the end cap communicate the sensor signals, the heater control signals and the temperature signals through the end cap. The connectors are hermetically sealed to the end cap to maintain the vacuum within the vacuum enclosure.