A fluid sensor for sensing a concentration or composition of a fluid, the sensor comprising: a semiconductor substrate comprising a first etched portion; a dielectric region located on the semiconductor substrate, wherein the dielectric region comprises a first dielectric membrane located over the first etched portion of the semiconductor substrate; a first heating element located within the first dielectric membrane; and a second heating element; wherein the first heating element is arranged to thermally shield the second heating element from ambient temperature changes; wherein the first heating element or the second heating element is configured to operate as a temperature sensing element; wherein the first heating element is configured to operate in a constant temperature or constant resistance mode; wherein the second heating element is configured to operate in a constant current or constant voltage mode or constant power mode; and wherein the sensor is configured to determine a thermal conductivity of the fluid using the temperature sensing element to determine said concentration or composition of the fluid.

A liquid extraction control method includes: acquiring a current temperature value of liquid to be extracted; determining whether the current temperature value is within a predetermined temperature value range; opening a liquid flow channel when the current temperature value is within the predetermined temperature range, and closing the liquid flow channel when the current temperature value is outside the predetermined temperature range. The temperature range of the liquid to be extracted can therefore be controlled, reducing probability of injuries caused by overly hot or cold liquid through a straw, and facilitating control of the temperature and extraction amount suitable for users, so as to achieve smart and quantitative fluid extraction.

A wet gas flow meter includes an input pipe section; a vibration measurement pipe; an output pipe section; a differential pressure sensor; a pressure sensor; a transducer; and a temperature sensor. The input pipe section, the vibration measurement pipe, and the output pipe section are connected sequentially one by one. The input pipe section includes a first pressure tap, and the output pipe section include a second pressure tap; the differential pressure sensor communicates with the input pipe section and the output pipe section via the first pressure tap and the second pressure tap, respectively. The pressure sensor communicates with the input pipe section and/or the output pipe section via the first pressure tap and/or the second pressure tap, respectively. The transducer is disposed on the vibration measurement pipe. The temperature sensor is disposed on the vibration measurement pipe and/or the input pipe section and/or the output pipe section.

A sensor assembly is provided including a housing including a tubular portion, a membrane, a cable, an ultrasonic sensor, and a further sensor. The tubular portion includes a first end. The tubular portion connects to the membrane at the first end of the tubular portion. The ultrasonic sensor includes a piezoelectric transducer and a wrap-around electrode. The piezoelectric transducer includes a first side and a second side, the second side of the piezoelectric transducer being disposed opposite the first side of the piezoelectric transducer. The first side of the piezoelectric transducer is mounted to the membrane. The wrap-around electrode includes a first side and a second side, the second portion of the wrap-around electrode being disposed opposite the first portion of the wrap-around electrode.

Conductivity probe fluid property measurement systems and related methods are disclosed herein. An example apparatus includes a flow meter and a fluid conduit to provide a flow path for a fluid relative to the flow meter. The example apparatus includes a conductivity probe coupled to the fluid conduit to generate brine conductivity data of the fluid during flow of the fluid through the fluid conduit. The example apparatus includes a processor to modify fluid flow data generated by the flow meter based on the brine conductivity data.

A flow meter for a fluid with a pulsating flow includes a piezo transducer for receiving and converting fluid pulses into electrical pulses, a AC/DC converter circuit for cumulatively storing the pulse energies of the electrical pulses in an energy store, a counter for counting the electrical pulses during a time interval, an evaluation device for determining a pulse parameter indicative of the flow rate of at least one of the electrical pulses and for determining a flow value based on the electrical pulses counted within the time interval and the determined pulse parameter, a communication device for the preferably wireless transmission of the determined flow value and a power supply device for the exclusive power supply of the flow meter with the energy stored in the energy store.

A method and a high-pressure system for determining a flow control variable of a fluid flow flowing through a high-pressure-side high-pressure pump outlet of a high-pressure pump are provided. An externally arranged ultrasonic measuring device measures a flow speed of a fluid flow flowing through a pipe of the high-pressure-side high-pressure pump outlet. A use of an ultrasonic measuring device is provided for determining a flow value to be achieved of a fluid flow flowing through a thick-walled pipe. The ultrasonic measuring device is arranged on the outside on the thick-walled pipe of the high-pressure pump outlet. The pipe has a ratio of the internal diameter to the external diameter of 1:1.5 to 1:5. The ultrasonic measuring device dynamically measures the flow speed of the fluid flow and transmits this measured flow speed to an evaluation unit to compute a current flow value and the flow control variable.

A method for verifying accurate operation for a flow meter (5) is provided. The method entails receiving a vibrational response from the flow meter (5), wherein the vibrational response comprises a response to a vibration of the flow meter (5) at a substantially resonant frequency. At least one gain decay variable is measured. It is then determined whether the gain decay variable is outside a predetermined range. A filter used in a stiffness calculation is adjusted if the gain decay variable is outside the predetermined range. The ability to detect and/or quantify any changes to the stiffness of the meter assembly in order to maintain a high level of accuracy is an improvement in the field of flow meters.

Methods, apparatuses, and computer program products associated with flow sensing devices are provided. An example flow sensing device may comprise a controller component in electronic communication with a flow sensing component that is configured to: monitor at least one flow sensing component output, detect an air bubble at a location adjacent a surface of the flow sensing component based at least in part on the at least one flow sensing component output, and determine whether the air bubble satisfies an air bubble condition defining one or more predetermined characteristics.

We disclose herein a flow and thermal conductivity sensor comprising a semiconductor substrate comprising an etched portion, a dielectric region located on the semiconductor substrate, wherein the dielectric region comprises at least one dielectric membrane located over the etched portion of the semiconductor substrate and a heating element located within the dielectric membrane. The dielectric membrane comprises one or more discontinuities located between the heating element and an edge of the dielectric membrane.