A pressure sensor assembly includes an external housing unit; a sensor unit received within the external housing unit, the external housing unit has an external surface including a mounting surface; a sensing element mounted within the sensor unit and including a pressure-sensing surface; a substrate upon which the mounting surface is mounted; an air passage to enable air to impinge on the sensing element; and a filling passage, separate from the air flow passage, for the introduction of an encapsulation material onto the sensor unit, during assembly. The encapsulation material covers at least a part of the external surface of the sensor unit but does not cover the pressure-sensing surface of the sensing element which remains directly exposed to air within the air passage.

A housing is disclosed. In an embodiment a housing includes a housing opening, a pressure-compensating element mounted on an inner side of the housing opening, a protective wall mounted on an outer side of the housing opening surrounding the housing opening and a bridge arranged over the outer side of the housing opening and protruding beyond the housing opening, wherein the bridge is shaped and arranged such that a projection of the bridge at least partially covers the housing opening.

Methods, systems, and apparatuses are provided for detecting and determining conditions of and conditions within a fluid conduit.

An electronic pressure and temperature sensor includes a chamber disposed within a housing. The pressure and temperature sensor are disposed at a chamber first end. An opening is disposed at a chamber second end, wherein the opening is configured to be in fluidic communication with the fluid media. A viscous gel is disposed within a portion of the chamber and encloses the pressure and temperature sensor apart from the fluid media. A second temperature sensor is at least partially disposed within the housing and is not disposed within the chamber. The first temperature sensor is configured to measure a temperature of the viscous gel, where the temperature of the viscous gel configured for use in temperature compensation calculations used to determine the pressure of the fluid media. The second temperature sensor is configured to measure a temperature of the flow of the fluid media.

A pressure monitoring system for a wet barrel hydrant includes an outer housing defining a sidewall shell and a cap coupled to the sidewall shell; a sensor housing defining a connector, a housing cavity, and an opening formed through the sensor housing and allowing access to the housing cavity, the connector configured to couple the pressure monitoring system to a wet barrel hydrant; and a base assembly coupled to the sidewall shell and defining a central support and a cylindrical wall, the cylindrical wall extending from the central support towards the cap, the sensor housing coupled to the central support opposite the cylindrical wall.

A noise resistance of a pressure sensor is improved while avoiding a hetero metal bonding. A pressure detection device includes a metal case having the diaphragm which is deformed due to a pressure received from a pressure medium, a sensor element which detects a pressure by detecting the deformation of the diaphragm, a lead frame which is electrically connected to the sensor element, and a connection member which holds the lead frame. A first surface of the lead frame, that is, the surface on a side near the metal case in the parallel plate region, and a second surface of the metal case, that is, the upper surface of the base member interpose at least one of the resin of the connection member being an insulator and the insulating adhesive and are disposed to face each other with a predetermined gap therebetween.

A MEMS pressure sensor includes a monolithic body of semiconductor material having a first face and a second face and housing a first buried cavity and a second buried cavity, arranged under the first buried cavity and projecting laterally therefrom. A first sensitive region is formed between the first buried cavity and the first face at a first depth, and a second sensitive region is formed between the second buried cavity and the first face at a second depth greater than the first depth. The monolithic body also houses a first piezoresistive sensing element and a second piezoresistive sensing element, integrated in the first and second sensitive regions, respectively.

A sensor package 1 includes a sensor carrier 2 with a sensor element 4, a pre-moulded tray part 10 with an exposed cavity 12, the sensor carrier 2 with the sensor element 4 being positioned in a recess 21 of the pre-moulded tray part 10 part to extend into the exposed cavity 12. A lead frame 6 is arranged to provide external connections of the sensor package 1, an over-moulding package part 8, arranged around the lead frame 6 and the pre-moulded tray part 10 and having an aperture 12a aligned with the exposed cavity 12.

A manifold assembly configured to measure differential pressure of fluid. The manifold assembly may have a monolithic body with an internally drilled fluid pathway. The body supports a differential pressure transducer that communicates, on either end, with the internally drilled fluid pathway. This configuration can generate data that defines pressure drop across impellers or other mechanisms on metrology hardware (or “gas meters”). Utilities can use this data to diagnose health or other conditions on the gas meter in the field.

Example aspects of a pressure monitoring system for a wet barrel hydrant, a pressure monitoring and leak detection system for a wet barrel hydrant, and a method for using a pressure monitoring and leak detection system are disclosed. The pressure monitoring system for a wet barrel hydrant can comprise a pressure sensor assembly comprising a pressure sensor and a connector, the pressure sensor configured to measure the pressure of a fluid received in the wet barrel hydrant, the connector configured to attach the pressure monitoring system to the wet barrel hydrant; a mounting flange coupled to the pressure sensor assembly; a main PCB configured to process pressure data measured by the pressure sensor; an antenna configured to send a signal representative of the pressure data; and a housing coupled to the mounting flange, the housing enclosing the processor and the antenna.