An apparatus for measuring flow of a fluid flowing using the magneto-inductive measuring principle, comprising a measuring tube having at least two subsections, wherein the subsections differ in diameter and/or geometry of cross sectional area; at least one magnet system having at least two coils for producing a magnetic field directed essentially perpendicularly to the flow direction of the fluid; at least two measuring electrode pairs for sensing induced voltage, wherein at least one measuring electrode pair is arranged in a first subsection and a second measuring electrode pair in a second subsection, wherein each measuring electrode pair includes first and second measuring electrodes, which lie opposite one another in the measuring tube and the respective connecting lines of the measuring electrodes are perpendicular to the tube axis and perpendicular to the magnetic field, and an electronics unit for signal registration and/or evaluation and for power supply of the coils, wherein the electronics unit is so embodied that it determines from the induced voltage the flow velocity of the fluid and/or the flow rate of the fluid for at least one subsection.

A method is provided to measure a distribution of axial velocities and a flowrate in a pipe or a vessel. The method comprises selecting a single cross-section at a stable-flow segment in a pipe or a vessel, installing a plurality of acoustic wave sensors along a peripheral wall of the pipe or the vessel to form a plurality of effective sound wave paths; measuring sound wave travelling time on each sound wave path; substituting the measured sound wave travelling time data into the model formulas based on a sound path refraction principle for reconstruction calculation to obtain a distribution of axial velocity in the measured cross-section of the pipe or the vessel, u(x,y); and integrating the distribution of the axial velocity u(x,y) along the cross-section to obtain a flow rate. A system is also provided to measure an axial velocity distribution and a flow rate in a pipe.

A method is provided to measure a distribution of axial velocities and a flowrate in a pipe or a vessel. The method comprises selecting a single cross-section at a stable-flow segment in a pipe or a vessel, installing a plurality of acoustic wave sensors along a peripheral wall of the pipe or the vessel to form a plurality of effective sound wave paths; measuring sound wave travelling time on each sound wave path; substituting the measured sound wave travelling time data into the model formulas based on a sound path refraction principle for reconstruction calculation to obtain a distribution of axial velocity in the measured cross-section of the pipe or the vessel, u(x,y); and integrating the distribution of the axial velocity u(x,y) along the cross-section to obtain a flow rate. A system is also provided to measure an axial velocity distribution and a flow rate in a pipe.

A method for calibrating a multiple flow conduit flow meter (200) is provided according to an embodiment of the invention. The multiple flow conduit flow meter (200) includes a first flow conduit (201) conducting a first flow stream and a pair of first pickoff sensors (215, 215′) affixed to the first flow conduit (201). The multiple flow conduit flow meter (200) further includes at least one additional flow conduit (202) conducting at least one additional flow stream and at least one pair of additional pickoff sensors (216, 216′) affixed to the at least one additional flow conduit (202).

The present invention relates to a system for estimating the individual water consumption of a plurality of devices supplied by the secondary fluid distribution network of a user. The system comprises a sleeve able to be fitted around the supply pipe of the secondary network and comprises an electromechanical sensor placed against the outside wall of the supply pipe, and a processor for analyzing the signals delivered by the electromechanical sensor with a view to extracting information characterizing the individual consumption of the devices supplied by the secondary network.

A flow measurement device includes a first sensor device that responds to stimulus from fluid medium flowing through a measurement section by registering a measure representing a physical characteristic, a processor, and a data storage including a look-up table containing a first collection of values representing a first value of flow of a first fluid or a first value of flow of a second fluid, and a second look-up table containing a second collection of the values representing a second value of the flow of the first fluid or a second value of the flow of the second fluid, the processor receiving the measures registered during a measurement time interval and estimating a flow pattern of the fluid medium during the measurement interval where the flow pattern describes how the first and second fluids are distributed in the measurement section over the measurement time interval.

A flow measuring device includes a first sensor device that responds to one stimulus caused by a fluid medium flowing through a measurement section by registering a first measure representing a first type of physical characteristic of the fluid medium, and a second sensor device that responds to another stimulus caused by the fluid medium by registering a second measure representing a second type of physical characteristic of the fluid medium, the second measure being independent from the first measure, and the first and second measures both being dependent on the flow of the first fluid and on the flow of the second fluid in the fluid medium in the measurement section, the first measure and the second measure being sufficient to solve both a first function that defines the flow of the first fluid and a second function that defines the flow of the second fluid.

The present disclosure provides a fluid sensor and a mass flow controller. The fluid sensor comprises at least two measuring tubes whose diameters have a proportional relationship. The fluid sensor provided by the present disclosure can guarantee measurement accuracy in a whole measurement range and also can improve device reliability.

The present disclosure provides a fluid sensor and a mass flow controller. The fluid sensor comprises at least two measuring tubes whose diameters have a proportional relationship. The fluid sensor provided by the present disclosure can guarantee measurement accuracy in a whole measurement range and also can improve device reliability.

Embodiments of systems and methods are provided to monitor operation of a compound water meter comprising a low flow meter and a high flow meter. In the disclosed embodiments, a first sensor package is coupled to the low flow meter to generate a first set of sensor data for monitoring operation of the low flow meter, and a second sensor package is coupled to the high flow meter to generate a second set of sensor data for monitoring operation of the high flow meter. The first and second sensor packages may each include, e.g., an optical sensor, a magnetic sensor and a vibration sensor. In the disclosed embodiments, the first and second sets of sensor data are analyzed to detect various potential problems within the compound water meter, such as a register failure, a crossover failure, a measurement failure, a bypass open condition and/or an incorrect flow meter size.