A balancing valve for adjusting the flow rate of a fluid flowing inside a pipe from upstream to downstream in a longitudinal direction of flow. The balancing valve includes: a check valve and a tubular element simulating a Venturi tube, said valve and element being coaxially connected, respectively, from upstream to downstream in the longitudinal direction of flow of the fluid; a device for detecting the difference in pressure which occurs inside the valve; a valve for adjusting the flow rate of the fluid which flows inside the pipe; wherein: the detection device is arranged between the inside of a first upstream chamber of the check valve and the inside of a central cylindrical portion of the tubular element.

An airflow sensor for a heat sink has a first portion having a first electrical point of contact, a second portion have a second electrical point of contact, and a deformable portion made of an electroactive material electrically coupled to the first and second portions. The deformable portion has first electrical properties measured between the first and second electrical points of contact when there is no airflow and the deformable portion is in a first position, and has second electrical properties different than the first electrical properties when a source of airflow blows air against the deformable portion, thereby causing the deformable portion to extend to a second position farther away from the source of airflow than the first position. The airflow sensor can be incorporated into a heat sink for an electronic component.

A pressure sensor includes a housing that includes an interior surface and an axially symmetric liner disposed along the interior surface of the housing, where the liner includes an interior surface and an exterior surface. The pressure sensor further includes a sensing member that includes an interior surface and an exterior surface, where the interior surface of the sensing member is adjacent to the exterior surface of the liner, and the sensing member is configured to expand with the liner. The pressure sensor further includes a strain gauge affixed to the exterior surface of the sensing member.

A fluid flow velocity sensor using a differential pressure measurement includes a stack having a tip pointing in a first direction, the stack including first and second plates arranged in parallel one another along the first direction; and a pressure-sensitive diaphragm arranged between the first and second plates along the first direction, the pressure-sensitive diaphragm being spaced apart from the first plate by a first cavity and from the second plate by a second cavity. The first cavity is entirely sealed, except at the tip of the stack, so as to be under a stagnation pressure during operation of the fluid flow velocity sensor. The second cavity is opened so as to be under a reference pressure during operation of the fluid flow velocity sensor. The fluid flow velocity sensor includes a detector to measure a parameter representative of the differential pressure between the first and the second cavities.

A fluid resistance element is disposed on a flow path along which flows a fluid, and in which a resistance flow path is formed. A fluid receiving portion is provided on the flow path and is hit by the fluid flowing from upstream of the fluid resistance element so as to cause the fluid to flow to a side. Flexible components support the fluid resistance element and deform in accordance with a flow rate of the fluid. A displacement sensor measures a displacement of the flexible components, and a flow rate calculation unit calculates a flow rate of the fluid based on the displacement. The fluid that is made to flow to the side by the fluid receiving portion flows along the resistance flow path of the fluid resistance element.

A flow sensor includes a fluid chamber configured to receive a fluid. A diaphragm assembly is configured to be displaced whenever the fluid within the fluid chamber is displaced. A transducer assembly is configured to monitor the displacement of the diaphragm assembly and generate a signal based, at least in part, upon the quantity of fluid displaced within the fluid chamber.

A flow control device for controlling flow in a heating, ventilation, or air conditioning (HVAC) system is shown. The flow control device includes a valve body including an inlet path, an outlet path, a valve member, and a valve stem coupled to the valve member. The flow control device includes a first sensor configured to obtain pressure measurements within the valve body, a second sensor configured to obtain displacement measurements of the valve stem, and a controller including a processing circuit configured to determine a flowrate based at least on the pressure measurements from the first sensor and the displacement measurements from the second sensor.

A flow control device for controlling flow in a heating, ventilation, or air conditioning (HVAC) system is shown. The flow control device includes a valve body including an inlet path, an outlet path, a valve member, and a valve stem coupled to the valve member. The flow control device includes a first sensor configured to obtain pressure measurements within the valve body, a second sensor configured to obtain displacement measurements of the valve stem, and a controller including a processing circuit configured to determine a flowrate based at least on the pressure measurements from the first sensor and the displacement measurements from the second sensor.

A valve body for a diaphragm valve having a valve seat is disclosed, wherein at least two walls of the valve body converge on one another towards the valve seat, wherein the at least two walls at least partly delimit a common dry space, and wherein at least one of the walls comprises a recess which is closed fluid-tightly by a sensor device for providing at least one sensor signal.