A fluid flow rate measurement device includes: a manifold element including a first fluid conduit extending from a surface thereof and terminating in a first port opening at a first lateral surface thereof and a second port opening at a second lateral surface thereof, and a second fluid conduit extending from a surface thereof and terminating in a third port opening at the first lateral surface and a fourth port opening at the second lateral surface; a fluid restriction element fixed to the first lateral surface and arranged to provide a sealed fluid pathway between the first port and the third port; and—a pressure sensor assembly fixed to the second lateral surface and including a first pressure sensor in fluidic communication with the second port, and a second pressure sensor in fluidic communication with the fourth port.

A system and method for dividing a single mass flow into secondary flows of desired ratios to total flow. Each secondary flow line includes a pressure drop element, an absolute pressure sensor and a differential pressure sensor. The nonlinear relationship between flow and pressures can be transformed into a function of the absolute and differential pressures that has a linear relationship with the flow.

An apparatus for measuring a pressure of a corrosive or high temperature process liquid includes a pressure sensor in communication with the process liquid via a vertical tube. A buffer gas injected into the vertical tube forms a liquid/gas interface at a desired height. The buffer gas supply is then either isolated or regulated so as to cause the buffer gas pressure within the vertical tube to remain equal with the process liquid pressure. The pressure sensor indirectly measures the process liquid pressure by measuring the buffer gas pressure within the vertical tube, while remaining chemically and thermally protected from the process liquid. In embodiments, pressure measurements from a pair of gas buffered pressure sensors located upstream and downstream of a valve are combined with measurements of the process liquid temperature to determine a flow rate of the process liquid through the valve.

An inhaler comprises a housing, an air channel extending between at least one air inlet opening and a suction opening in the housing, a dispensing element for vaporizing or nebulizing liquid supplied to the dispensing element for admixing with air flowing in the air channel, an electronic control device, an electronic data memory, and a sensor system comprising a flow measuring device for measuring the volumetric and/or mass flow of air flowing through the air channel. The electronic control device is adapted to capture a plurality of airflow measurement values over at least a portion of the duration of an inhalation puff by means of the flow measurement device, compare the plurality of airflow measurement values to a puff profile stored in the data memory, and output a control signal based on the comparison of the plurality of airflow measurement values to the stored puff profile.

An apparatus for measuring a pressure of a corrosive or high temperature process liquid includes a pressure sensor in communication with the process liquid via a vertical tube. A buffer gas injected into the vertical tube forms a liquid/gas interface at a desired height. The buffer gas supply is then either isolated or regulated so as to cause the buffer gas pressure within the vertical tube to remain equal with the process liquid pressure. The pressure sensor indirectly measures the process liquid pressure by measuring the buffer gas pressure within the vertical tube, while remaining chemically and thermally protected from the process liquid. In embodiments, pressure measurements from a pair of gas buffered pressure sensors located upstream and downstream of a valve are combined with measurements of the process liquid temperature to determine a flow rate of the process liquid through the valve.

A flow rate assembly can include a fluid flow interface portion having a front facing wall and a back facing wall. The flow interface portion can include an inlet passage within the fluid flow interface portion, an outlet passage within the fluid flow interface portion, at least one inlet aperture extending through the front facing wall of the fluid flow interface portion into the inlet passage, and at least one outlet aperture extending through the back facing wall of the fluid flow interface portion into the outlet passage. In some cases, the fluid flow interface portion includes a plug forming at least a portion of the inlet passage.

A flow rate assembly can include a fluid flow interface portion having a front facing wall and a back facing wall. The flow interface portion can include an inlet passage within the fluid flow interface portion, an outlet passage within the fluid flow interface portion, at least one inlet aperture extending through the front facing wall of the fluid flow interface portion into the inlet passage, and at least one outlet aperture extending through the back facing wall of the fluid flow interface portion into the outlet passage. In some cases, the fluid flow interface portion includes a plug forming at least a portion of the inlet passage.

A fluid flow rate measurement device includes: a manifold element including a first fluid conduit extending from a surface thereof and terminating in a first port opening at a first lateral surface thereof and a second port opening at a second lateral surface thereof, and a second fluid conduit extending from a surface thereof and terminating in a third port opening at the first lateral surface and a fourth port opening at the second lateral surface; a fluid restriction element fixed to the first lateral surface and arranged to provide a sealed fluid pathway between the first port and the third port; and—a pressure sensor assembly fixed to the second lateral surface and including a first pressure sensor in fluidic communication with the second port, and a second pressure sensor in fluidic communication with the fourth port.

A flow rate assembly can include a fluid flow interface portion having a front facing wall and a back facing wall. The flow interface portion can include an inlet passage within the fluid flow interface portion, an outlet passage within the fluid flow interface portion, at least one inlet aperture extending through the front facing wall of the fluid flow interface portion into the inlet passage, and at least one outlet aperture extending through the back facing wall of the fluid flow interface portion into the outlet passage. In some cases, the fluid flow interface portion includes a plug forming at least a portion of the inlet passage.

A multiphase fluid is flowed from a flow pipe to a U-bend. Several differential pressures of the multiphase fluid flowing through the flow pipe and U-bend are measured. A total flow rate of the multiphase fluid is determined at least based on the measured differential pressures. In some cases, flow rates of each of the phases of the multiphase fluid can be determined at least based on the measured differential pressures.